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+{"image": "doclay/doclay_21517.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "As of December 31, 2010\nAs of December 31, 2009 2010 2011 (in gigabits per second, or Gbps) Total bandwidth 1,069.4 1,486.4 1,705.7\nprivate networks and by telecommunications service providers to establish networks to offer telecommunications services. \nWe provide data transmission services to major corporate customers in Taiwan. We also provide leased lines to other mobile  and fixed line service operators for interconnection with our fixed line network and for connection within their networks. \nThe following table shows the bandwidth of local and domestic long distance lines leased to third parties as of each of the  dates indicated. \nRental fees for local leased lines are generally based on transmission speed while domestic long distance leased line rental  fees are generally based on transmission speed and distance. \nWe continue to experience a decline in rental fees for all of our leased line products. The decline in rental fees since 2000  has been substantial partly as a result of broadband services substitution and other service providers constructing their own lines. In  response, we continue to implement marketing and service campaigns to retain our high-value corporate customers. \nWe launched our wireless local area network service in May 2002. As of December 31, 2011, we had a total of approximately  657,007 residential and business customers that lease our access points. In addition, we have established 21,216 hot spots in public  areas, such as convenience stores, airports and international convention centers, where individuals can access our wireless local area  network. \nWe launched our multimedia-on-demand, or MOD, service in Taipei County and Keelung City in March 2004. We have  expanded this service to all 18 counties and cities of Taiwan in December 2007. Using video streaming technology through a set top  box that connects to our FTTx and ADSL data connections, our customers can access TV programs, VOD and other services. We  had over 133 broadcasting channels and over 12,000 hours worth of on-demand programs and served approximately 1.05 million  customers as of December 31, 2011. In addition, our video-on-demand service provides movies, dramas, animations, documentaries,  e-learning and music programs for home entertainment. Also, we currently offer 43 high definition, or HD, channels and other HD  video-on-demand programming, such as sports, movies and knowledge materials. We offered “family package” channels in 2010  to enhance our service content and satisfy our customers’ needs. MOD revenues accounted for NT$0.9 billion, NT$1.1 billion and  NT$1.4 billion (US$47.4 million) in 2009, 2010 and 2011, respectively. \nOur domestic other services include information and communication technology services, corporate solution and bill handling  services. \nMobile communications services are one of our principal business activities. Our mobile communications services include  mobile services, sales of mobile handsets and data cards and mobile other services. \n31\nMobile Communications Business \nDomestic Other Services \nMultimedia on Demand Services \nWi-Fi Services \nP AR T I"}]}
+{"image": "doclay/doclay_60460.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "The continuation sheet\nChecking your first draft\nWRITING LETTERS / 139\nyou can produce. Think carefully about what you want to say and for whom it is intended. Note down the points you wish to make, put them in order and write your first draft avoiding any unnecessary words or ‘flowery’ language.\nIf your letter is longer than a page, use a plain sheet of paper of the same size and colour as the first. It should be plain and not headed notepaper. Under no circumstances write or type on the back of the first sheet.\nLeave three spaces at the top of the new page. Then against the left-hand ‘margin’ type in ‘2’. Leaving a line space, write the date and, after another line, space put the name of the addressee. Leave three line spaces before continuing the letter.\n◆ Don’t use technical facts and figures unless you are sure your reader will understand them.\n◆ Keep your paragraphs short.\n◆ Don’t use slang or jargon.\n◆ Don’t ‘embroider’ your facts. Keep them simple.\n◆ Make sure you have a beginning, a middle and an end."}]}
+{"image": "doclay/doclay_79411.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "CHAPTER 58. PERLMODLIB\n58.1. THE PERL MODULE LIBRARY\nPerlIO::via::QuotedPrint\nPod::Checker\nPod::Find\nPod::Functions\nPod::Html\nPod::InputObjects\nPod::LaTeX\nPod::Man\nPod::ParseLink\nPod::ParseUtils\nPod::Parser\nPod::Perldoc::ToChecker\nPod::Perldoc::ToMan\nPod::Perldoc::ToNro ff\nPod::Perldoc::ToPod\nPod::Perldoc::ToRtf\nPod::Perldoc::ToText\nPod::Perldoc::ToTk\nPod::Perldoc::ToXml\n918\nLet Perldoc render Pod as XML\nLet Perldoc use Tk::Pod to render Pod\nLet Perldoc render Pod as plaintext\nLet Perldoc render Pod as RTF\nLet Perldoc render Pod as ... Pod!\nLet Perldoc convert Pod to nro ff\nLet Perldoc render Pod as man pages\nLet Perldoc check Pod for errors\nBase class for creating POD filters and translators\nHelpers for POD parsing and conversion\nParse an L <> formatting code in POD text\nConvert POD data to formatted *ro ff input\nConvert Pod data to formatted Latex\nObjects representing POD input paragraphs, commands, etc.\nModule to convert pod files to HTML\nGroup Perl’s functions a la perlfunc.pod\nFind POD documents in directory trees\nCheck pod documents for syntax errors\nPerlIO layer for quoted-printable strings"}]}
+{"image": "doclay/doclay_8290.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "ALLIANZ GROUP 16\nAllocations to the budget available for increases of agreed pension benefits are primarily dependent on the economic per- formance of the company. When a member of Board of Man- agement retires from the Board at the end of his mandate, old- age pension is paid no earlier than upon completion of the 60th year of age, except for cases of professional disability or general disability for medical reasons, or payments to a beneficiary in the case of death. If the mandate is terminated for other reasons before the retirement age has been reached, a non-expiring pen- sion claim is maintained. But this claim does not include a right to the immediate payment of benefits.\nThe amount of the total compensation for a given year depends on the relative success of the Group as a whole and on the Board member’s respective area of responsibility, as well as on the development of the share price. If one establishes a ranking of the average remuneration paid to the Board of Management at comparable German and European companies in recent years, the compensation of the Board of Allianz AG would fall approx- imately into the second third. If this listing takes into account criteria such as market capitalization, number of employees or complexity of the company, the average compensation of the Board of Allianz AG falls into the mid range. \nThe remuneration of the Supervisory Board was decided by the Annual General Meeting and is defined in article 9 of the Arti- cles of Association.\nThe remuneration of the Supervisory Board is based on the size of the company, the functions and responsibilities of the members of the Supervisory Board and the economic situation of the company. For the most part, it is related to the dividend paid. The chairman and the deputy chairman of the Supervisory Board as well as the chairmen and members of its committees receive an additional remuneration.\nThe remuneration of the members of the Supervisory Board includes two components: a fixed amount of 4,000 euros and a variable amount dependent on the dividend. This amount is calculated as follows: for each cent by which the dividend per share exceeds the amount of 15 cents, an additional remune- ration of 500 euros is paid. The amount of the dividend is de- termined by the appropriation of profit decided by the Annual General Meeting. The chairman of the Supervisory Board re- ceives double, and his deputy one and a half times the amount of this remuneration. The remuneration of the members of the Personnel Committee and of the Standing Committee is in-\ncreased by 25 percent, that of the chairmen of these commit- tees by 50 percent. To prevent a conflict of interest on the part of the members of the Audit Committee with respect to the div- idend proposal of the Supervisory Board, these members merely receive a fixed annual remuneration of 30,000 euros for their work in this committee, while the chairman receives a fixed amount of 45,000 euros. \nThe additional remuneration of the committee members is capped by an upper limit. This limits takes effect when the re- muneration of the chairman of the Supervisory Board has reached triple and that of the other members of the Supervisory Board double the basic remuneration. Since the dividend policy of the Allianz Group is oriented toward the long-term, the re- muneration of the Supervisory Board contains no additional component that is based on the long-term performance of the company.\nAmount of compensation\nRemuneration of the Supervisory Board"}]}
+{"image": "doclay/doclay_44207.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Glossary\nAborted takeoff.  A takeoff that is terminated prematurely  when it is determined that some condition exists that makes  takeoff or further flight dangerous.\nAbsolute pressure.  Pressure measured from zero pressure  or a vacuum.\nAbsolute pressure regulator.  A valve used in a pneumatic  system at the pump inlet to regulate the compressor inlet  air pressure to prevent excessive speed variation and/or  overspeeding of the compressor.\nAbsolute zero.  The point at which all molecular motion  ceases. Absolute zero is –460 °F and –273 °C.\nAccumulator.  A hydraulic component that consists of two  compartments separated by a movable component, such as  a piston, diaphragm, or bladder. One compartment is filled  with compressed air or nitrogen, and the other is filled with  hydraulic fluid and is connected into the system pressure  manifold. An accumulator allows an incompressible fluid  to be stored under pressure by the force produced by a  compressible fluid. Its primary purposes are to act as a shock  absorber in the system, and to provide a source of additional  hydraulic power when heavy demands are placed on the  system.\nActuator.  A fluid power device that changes fluid pressure  into mechanical motion.\nADC.  Air data computer.\nADF.  Automatic direction finder.\nADI.  Attitude director indicator.\nAdvancing blade.  The blade on a helicopter rotor whose  tip is moving in the same direction the helicopter is moving.\nAdverse yaw.  A condition of flight at the beginning of a  turn in which the nose of an airplane momentarily yaws in  the opposite direction from the direction in which the turn  is to be made. \nAerodynamic drag.  The total resistance to the movement of  an object through the air. Aerodynamic drag is composed of  both induced drag and parasite drag. See induced drag and  parasite drag.\nAerodynamic lift.  The force produced by air moving over  a specially shaped surface called an airfoil. Aerodynamic  lift acts in a direction perpendicular to the direction the air  is moving.\nAeronautical Radio Incorporated (ARINC).  A corporation  whose principal stockholders are the airlines. Its function is  to operate certain communication links between airliners  in flight and the airline ground facilities. ARINC also sets  standards for communication equipment used by the airlines.\nAging.  A change in the characteristics of a material with time.  Certain aluminum alloys do not have their full strength when  they are first removed from the quench bath after they have  been heat-treated, but they gain this strength after a few days  by the natural process of aging.\nAgonic line.  A line drawn on an aeronautical chart along  which there is no angular difference between the magnetic  and geographic north poles.\nAir carrier.  An organization or person involved in  the business of transporting people or cargo by air for  compensation or hire.\nAir-cycle cooling system.  A system for cooling the air in  the cabin of a turbojet-powered aircraft. Compressor bleed  air passes through two heat exchangers where it gives up  some of its heat; then, it drives an expansion turbine where  it loses still more of its heat energy as the turbine drives a  compressor. When the air leaves the turbine, it expands and  its pressure and temperature are both low.\nG-1"}]}
+{"image": "doclay/doclay_2588.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Contract no: [complete] \nEC - FWC services Dec 2018 \nII.13.2. Licensing rights on pre-existing materials \nUnless provided otherwise in the special conditions, the Union does not acquire ownership of  pre- existing rights  under this FWC.\nThe contractor licenses the  pre-existing rights  on a royalty-free, non-exclusive and irrevocable basis to  the Union, which may use the  pre-existing materials  for all the modes of exploitation set out in this FWC  or in  specific contracts . Unless otherwise agreed, the licence is non-transferable and cannot be sub- licensed, except as provided hereafter: \nAll  pre-existing rights  are licensed to the Union from the moment the  results  are delivered and approved  by the contracting authority.\nThe licensing of  pre-existing rights  to the Union under this FWC covers all territories worldwide and is  valid for the duration of intellectual property rights protection. \nThe payment of the price as set out in the  specific contracts  is deemed to also include any fees payable  to the contractor in relation to the licensing of  pre-existing rights  to the Union, including for all forms of  exploitation and of use of the  results . \nWhere  implementation of the FWC  requires that the contractor uses  pre-existing materials  belonging to  the contracting authority, the contracting authority may request that the contractor signs an adequate  licence agreement. Such use by the contractor will not entail any transfer of rights to the contractor and  is limited to the needs of this FWC. \nThe Union acquires the following exclusive rights:\na) the pre-existing rights  can be sub-licensed by the contracting authority to persons and entities  working for it or cooperating with it, including contractors and subcontractors, whether legal or  natural persons, but only for the purpose of their mission for the Union;  b) if the result  is a \"document\" such as a report or a study, and it is meant to be published, the \nnatural persons, but only for the purpose of their mission for the Union;  b) if the result  is a \"document\" such as a report or a study, and it is meant to be published, the  existence of  pre-existing materials  in the  result  may not prevent the publication of the document,  its translation or its \"reuse\", it being understood however that the \"reuse\" may only be made of  the  result  as a whole and not of the  pre-existing materials  taken separately from the  result ; for  the sake of this provision, \"reuse\" and \"document\" have the meaning given by the Commission  Decision of 12 December 2011 on the reuse of Commission documents (2011/833/EU). \na) reproduction: the right to authorise or prohibit direct or indirect, temporary or permanent  reproduction of the  results  by any means (mechanical, digital or other) and in any form, in whole  or in part; b)  communication to the public: the exclusive right to authorise or prohibit any display, performance \nor in part; b)  communication to the public: the exclusive right to authorise or prohibit any display, performance  or communication to the public, by wire or wireless means, including the making available to the  public of the  results  in such a way that members of the public may access them from a place  and at a time individually chosen by them; this also includes the communication on Internet and  broadcasting by cable or by satellite;  c)  distribution: the exclusive right to authorise or prohibit any form of distribution of  results  or copies \nbroadcasting by cable or by satellite;  c)  distribution: the exclusive right to authorise or prohibit any form of distribution of  results  or copies  of the  results  to the public, by sale or otherwise;  d) rental: the exclusive right to authorise or prohibit rental or lending of the  results  or of copies of \nof the  results  to the public, by sale or otherwise;  d) rental: the exclusive right to authorise or prohibit rental or lending of the  results  or of copies of  the  results ;  e) adaptation: the exclusive right to authorise or prohibit any modification of the  results ;\nthe  results ;  e) adaptation: the exclusive right to authorise or prohibit any modification of the  results ; f)  translation: the exclusive right to authorise or prohibit any translation, adaptation, arrangement, \ne) adaptation: the exclusive right to authorise or prohibit any modification of the  results ; f)  translation: the exclusive right to authorise or prohibit any translation, adaptation, arrangement,  creation of derivative works based on the  results , and any other alteration of the  results , subject  to the respect of moral rights of authors, where applicable; \n22\nII.13.3. Exclusive rights"}]}
+{"image": "doclay/doclay_54248.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Replication and Binary Logging Options and Variables\nEnabling this variable causes the source to verify events read from the binary log by examining checksums, and to stop with an error in the event of a mismatch.  master_verify_checksum  is disabled by default; in this case, the source uses the event length from the binary log to verify events, so that only complete events are read from the binary log.\nIf a transaction requires more than this many bytes of memory, the server generates a  Multi- statement transaction required more than ’max_binlog_cache_size’ bytes of storage  error. The minimum value is 4096. The maximum possible value is 16EiB (exbibytes). The maximum recommended value is 4GB; this is due to the fact that MySQL currently cannot work with binary log positions greater than 4GB. The value must be a multiple of 4096.\nmax_binlog_cache_size  sets the size for the transaction cache only; the upper limit for the statement cache is governed by the  max_binlog_stmt_cache_size  system variable.\nThe visibility to sessions of  max_binlog_cache_size  matches that of the  binlog_cache_size system variable; in other words, changing its value affects only new sessions that are started after the value is changed.\n3566\n• max_binlog_size\n• max_binlog_cache_size\nDefault Value OFF\nCommand-Line Format --max-binlog-cache-size=# System Variable max_binlog_cache_size Scope Global Dynamic Yes SET_VAR  Hint Applies No Type Integer Default Value 18446744073709547520 Minimum Value 4096 Maximum Value 18446744073709547520 Block Size 4096\nCommand-Line Format --max-binlog-size=# System Variable max_binlog_size Scope Global Dynamic Yes SET_VAR  Hint Applies No Type Integer Default Value 1073741824 Minimum Value 4096 Maximum Value 1073741824"}]}
+{"image": "doclay/doclay_61425.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "EP 3 800 021 A1\nfläche des Werkstücks erstreckt.Durch eine JustiermöglichkeitderTastelemente innerhalb derEbene kann eine präzise und zugleich flexible Justierung der Stellelemente ermöglicht sein, bei welcher die Tastelemente durch die beiden Linearantriebe stufenlose in einer beliebigen Position innerhalb der Ebene justiert werden können. [0017] Eine vorteilhafte Weiterbildung des Kantenfräsaggregats kann eine Sensoreinrichtung vorsehen,durch welche\nLinearantriebe stufenlose in einer beliebigen Position innerhalb der Ebene justiert werden können. [0017] Eine vorteilhafte Weiterbildung des Kantenfräsaggregats kann eine Sensoreinrichtung vorsehen,durch welche eine Position der Tastelemente zur abzutastenden Werkstückkontur und/oder zum Bearbeitungswerkzeug erfassbar ist, und vorzugsweise in Abhängigkeit von der erfassten Position eine automatisierte Justierung der Tastelemente zur abzutastenden Werkstückkontur und/oder zum Bearbeitungswerkzeug vorgesehen ist. Durch eine solche Sensorein- richtung kann zur Verbesserung der Prozesssicherheit eine Überwachung des Bearbeitungsvorgangs erreicht sein. Ebenso kann durch die Sensoreinrichtung eine Erhöhung des Automatisierungsgrades des Bearbeitungsvorgangs um- gesetzt werden. [0018] In einer weiteren Ausgestaltung des Kantenfräsaggregats kann die Tasteinrichtung modular ausgebildet sein\n5\n10\n15\n20\ngesetzt werden. [0018] In einer weiteren Ausgestaltung des Kantenfräsaggregats kann die Tasteinrichtung modular ausgebildet sein und über eine Schnittstelle auswechselbar an dem Bearbeitungswerkzeug und/oder Kantenfräsaggregat anordenbar ist. Durch eine solche modulare Ausgestaltung kann das Anbringen und/oder Auswechseln der Tasteinrichtung an verschiedenen bzw. an bestehenden Kantenfräsaggregaten ermöglicht sein, sodass eine kostengünstige Umrüstung von Kantenfräsaggregaten ermöglicht sein kann. Indem die Tasteinrichtung über eine Schnittstelle an dem Kantenfrä- saggregat anbringbar ist, kann zudem ein einfacher und schneller Umrüstvorgang erreicht sein. [0019] Die Aufgabe wird zudemdurch eine Holzbearbeitungseinrichtung miteinemKantenfräsaggregatzumBearbei-\nsaggregat anbringbar ist, kann zudem ein einfacher und schneller Umrüstvorgang erreicht sein. [0019] Die Aufgabe wird zudemdurch eine Holzbearbeitungseinrichtung miteinemKantenfräsaggregatzumBearbei- ten von plattenförmigen Werkstücken, die in einer Durchlaufrichtung relativ zu einem Bearbeitungswerkzeug des Kan- tenfräsaggregats bewegbar sind und die wenigstens an einer dem Bearbeitungswerkzeug zugewandten Schmalfläche ein Schmalflächenbeschichtungsmaterial aufweisen, das zumindest bereichsweise gegenüber einer die Schmalfläche begrenzenden Werkstückkante übersteht, wobei das Bearbeitungswerkzeug relativ zu dem in Durchlaufrichtung be- wegbaren Werkstück verfahrbar vorgesehen ist, um zumindest das gegenüber der Werkstückkante überstehende Schmalflächenbeschichtungsmaterialspannehmend zubearbeiten,gelöst,wobeidas Kantenfräsaggregatgemäß einer derzuvorbeschriebenen Ausführungsformenausgebildetist.Eine Holzbearbeitungseinrichtung miteinemsolchenKan- tenfräsaggregat ermöglicht das Bearbeiten von Werkstücken im Durchlaufverfahren, wobei das Kantenfräsaggregat eine spannehmende Bearbeitung zumindest von Überständen des Schmalflächenbeschichtungsmaterials an wenigs- tens zweiAbschnitten derdie Schmalfläche begrenzenden WerkstückkantewährendderDurchlaufbewegung derWerk- stücke ermöglicht.Aufdiese Weise kann durch dieHolzbearbeitungseinrichtung eineeffiziente Kantenbearbeitungeiner großen Anzahl von Werkstücken ermöglicht sein. [0020] Die Aufgabe wird des Weiteren durch ein Verfahren zum Bearbeiten von plattenförmigen Werkstücken mit\n25\n30\n35\n40\ngroßen Anzahl von Werkstücken ermöglicht sein. [0020] Die Aufgabe wird des Weiteren durch ein Verfahren zum Bearbeiten von plattenförmigen Werkstücken mit einem Kantenfräsaggregat, insbesondere einem Kantenfräsaggregat nach einem der zuvor beschriebenen Ausfüh- rungsformen gelöst, wobei die Werkstücke in einer Durchlaufrichtung relativ zu einem Bearbeitungswerkzeug des Kan- tenfräsaggregats bewegtwerden,wobeidie Werkstücke wenigstensaneinerdemBearbeitungswerkzeug zugewandten Schmalfläche ein Schmalflächenbeschichtungsmaterial aufweisen, das zumindest bereichsweise gegenüber einer die Schmalfläche begrenzenden Werkstückkante übersteht, ein erstes Tastelement einer Tasteinrichtung während der Durchlaufbewegung des Werkstücks aus einer Warteposition in eine Tastposition überführt wird und einen ersten Ab- schnitteinerzurSchmalfläche benachbarten Werkstückkonturabtastet,und das Bearbeitungswerkzeug in Abhängigkeit von der ersten abgetasteten Werkstückkontur entlang eines Abschnitts der zur abgetasteten Werkstückkontur benach- barten Werkstückkante verfahren wird, um zumindest das gegenüber der Werkstückkante überstehende Schmalflä- chenbeschichtungsmaterial während der Durchlaufbewegung des Werkstücks spannehmend zu bearbeiten, das erste TastelementnachdemAbtasten des ersten Abschnitts der Werkstückkontur in die Warteposition überführtwird und das zweite Tastelement aus einer Warteposition in eine weitere Tastposition überführt wird und einen zweiten Abschnitt der zur Schmalfläche benachbarten Werkstückkontur abtastet, und das Bearbeitungswerkzeug in Abhängigkeit von der zweiten abgetasteten Werkstückkontur entlang eines Abschnitts der zur abgetasteten Werkstückkontur benachbarten Werkstückkante verfahren wird, um zumindest das gegenüber der Werkstückkante überstehende Schmalflächenbe- schichtungsmaterialwährend derDurchlaufbewegung des Werkstücks spannehmend zu bearbeiten. Durch dieses Ver- fahren kann ein zeit- und kosteneffizientes Bearbeiten von Überständen des Schmalflächenbeschichtungsmaterials an wenigstens zwei Abschnitten der die Schmalfläche begrenzenden Werkstückkante im Durchlaufverfahren ermöglicht sein. Indem die beiden Tastelemente wechselseitig in verschiedene Tastposition überführt werden können, kann das Abtasten der Werkstückkontur und gleichzeitige Bearbeiten der Werkstückkante dabei nacheinander an wenigstens zwei verschiedenen Abschnitten des Werkstücks erfolgen. [0021] In einer vorteilhaften Weiterbildung des Verfahrens kann vorgesehen sein, dass durch das erste Tastelement\n45\n50\n55\nzwei verschiedenen Abschnitten des Werkstücks erfolgen. [0021] In einer vorteilhaften Weiterbildung des Verfahrens kann vorgesehen sein, dass durch das erste Tastelement die Werkstücckontur einer an die Schmalfläche angrenzenden ersten Längsseite des Werkstücks abgetastet wird und darauffolgend durch das zweite Tastelement die Werkstückkontur einerzweiten Längsseite abgetastetwird, welche der ersten Längsseite gegenüberliegt,und vorzugsweise durch die Tastelemente eine imWesentlichen konkav ausgebildete Werkstückkontur abgetastet wird. Auf diese Weise können die Werkstückkonturen der in gegensätzliche Richtungen ausgerichteten Längsseiten abgetastet werden.Indem die Tastelemente auch eine konkave Werkstückkontur,d.h.eine als Vertiefung oder NutausgebildeteProfilierung,abtasten können,kann durch das Verfahren eine Bearbeitung entlang\n4"}]}
+{"image": "doclay/doclay_80589.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "SIGNATURES\nPursuant to the requirements of Section 13 or 15(d) of the Securities Exchange Act of 1934, the registrant has duly caused this report to be signed on its behalf by the undersigned, thereunto duly authorized.\nPursuant to the requirements of the Securities Exchange Act of 1934, this report has been signed below by the following persons on behalf of the registrant and in the capacities and on the dates indicated.\n34\nSignature Title Date /s/ JOHN D. WREN Chairman and Chief Executive Officer and Director (Principal Executive Officer) February 12, 2019 John D. Wren /s/ PHILIP J. ANGELASTRO Executive Vice President and Chief Financial Officer (Principal Financial Officer) February 12, 2019 Philip J. Angelastro /s/ ANDREW L. CASTELLANETA Senior Vice President, Chief Accounting Officer (Principal Accounting Officer) February 12, 2019 Andrew L. Castellaneta /s/ ALAN R. BATKIN Director February 12, 2019 Alan R. Batkin /s/ MARY C. CHOKSI Director February 12, 2019 Mary C. Choksi /s/ ROBERT CHARLES CLARK Director February 12, 2019 Robert Charles Clark /s/ LEONARD S. COLEMAN, JR. Director February 12, 2019 Leonard S. Coleman, Jr. /s/ SUSAN S. DENISON Director February 12, 2019 Susan S. Denison /s/ RONNIE S. HAWKINS Director February 12, 2019 Ronnie S. Hawkins /s/ DEBORAH J. KISSIRE Director February 12, 2019 Deborah J. Kissire /s/ GRACIA C. MARTORE Director February 12, 2019 Gracia C. Martore /s/ LINDA JOHNSON RICE Director February 12, 2019 Linda Johnson Rice /s/ VALERIE M. WILLIAMS Director February 12, 2019 Valerie M. Williams\nFebruary 12, 2019\nPhilip J. Angelastro Executive Vice President and Chief Financial Officer\nBY:\nOMNICOM GROUP INC. /s/ PHILIP J. ANGELASTRO"}]}
+{"image": "doclay/doclay_24642.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "scalability can be achieved because, under the conditional independence assumption, the Hessian of the log posterior is sparse, with a predictable sparsity pattern.\nUnder the conditional independence assumption, the log posterior density is the sum of the logs of Equations 2 and 3, with a heterogeneous component\nand a homogeneous component log $_{p}$($_{a}$ ) . This homogeneous component is the hyperprior on the population-level parameters, so its computation does not depend on N , while each additional household adds another element to the summation in Equation 17. Therefore, computation of the log posterior grows linearly in N . In the subsequent text, let k be the number of elements in each b i and let p be the number of elements in a . Using the notation from Section 2, q is a vector that concatenates all of the b i together, along with a .\nThere are two reasons why we might need to compute the gradient and Hessian of the log posterior, namely to use in a derivative-based optimization algorithm to find the posterior mode, and for estimating the precision matrix of an MVN proposal distribution. 3 Ideally, we would derive the gradient and Hessian analytically, and write code to estimate it efficiently. For com- plicated models, the required effort for coding analytic gradients may not be worthwhile. An alternative would be numerical approximation through finite differencing. The fastest, yet least accurate, method for finite differencing for gradients, using either forward or backward differ- ences, requires Nk + p + 1 evaluations of the log posterior. Since the computational cost of the log posterior also grows linearly with N , computing the gradient this way will grow quadratically in N . The cost of estimating a Hessian using finite differencing grow even faster in N . Also, if the Hessian is estimated by taking finite differences of gradients, and those gradients themselves were finite-differences, the accumulated numerical error can be so large that the Hessian estimates are useless.\n4.1 Computing Log Posteriors, Gradients and Hessians\nN GLYPH<229> i log f$_{i}$ ( y$_{i}$ |$_{b}$$_{i}$ , $_{a}$) + log p $_{i}$($_{b}$$_{i}$ |$_{a}$ ) (17)\n20\n$^{3}$We do not require either derivative-based optimization or using MVN proposals, but these are most likely reason- able choices for differentiable, unimodal posteriors."}]}
+{"image": "doclay/doclay_57027.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Comparison of B-Tree and Hash Indexes\nsome of those statements modify the table, MySQL may collect statistics. (This may occur for bulk inserts or deletes, or some  ALTER TABLE  statements, for example.) If this happens, the statistics are collected using whatever value  innodb_stats_method  or  myisam_stats_method  has at the time. Thus, if you collect statistics using one method, but the system variable is set to the other method when a table’s statistics are collected automatically later, the other method is used.\nUnderstanding the B-tree and hash data structures can help predict how different queries perform on different storage engines that use these data structures in their indexes, particularly for the  MEMORY storage engine that lets you choose B-tree or hash indexes.\nA B-tree index can be used for column comparisons in expressions that use the  = ,  > ,  >= ,  < ,  <= , or BETWEEN  operators. The index also can be used for  LIKE  comparisons if the argument to  LIKE  is a constant string that does not start with a wildcard character. For example, the following  SELECT  statements use indexes:\nSELECT * FROM  tbl_name  WHERE  key_col  LIKE ’Patrick%’; SELECT * FROM  tbl_name  WHERE  key_col  LIKE ’Pat%_ck%’;\nIn the first statement, only rows with  ’Patrick’ <=  key_col  < ’Patricl’  are considered. In the second statement, only rows with  ’Pat’ <=  key_col  < ’Pau’  are considered.\nThe following  SELECT  statements do not use indexes:\nSELECT * FROM  tbl_name  WHERE  key_col  LIKE ’%Patrick%’; SELECT * FROM  tbl_name  WHERE  key_col  LIKE  other_col ;\nIn the first statement, the  LIKE  value begins with a wildcard character. In the second statement, the  LIKE value is not a constant.\nIf you use  ... LIKE ’% string %’  and  string  is longer than three characters, MySQL uses the  Turbo Boyer-Moore algorithm  to initialize the pattern for the string and then uses this pattern to perform the search more quickly.\nA search using  col_name  IS NULL  employs indexes if  col_name  is indexed.\nAny index that does not span all  AND  levels in the  WHERE  clause is not used to optimize the query. In other words, to be able to use an index, a prefix of the index must be used in every  AND  group.\nThe following  WHERE  clauses use indexes:\n... WHERE  index_part1 =1 AND  index_part2 =2 AND  other_column =3 /*  index  = 1 OR  index  = 2 */ ... WHERE  index =1 OR A=10 AND  index =2 /* optimized like \" index_part1 =’hello’\" */\n1722\nB-Tree Index Characteristics\n8.3.9 Comparison of B-Tree and Hash Indexes\n•There is no way to tell which method was used to generate statistics for a given table.\n•These variables apply only to  InnoDB  and  MyISAM  tables. Other storage engines have only one method for collecting table statistics. Usually it is closer to the  nulls_equal  method.\n•B-Tree Index Characteristics\n•Hash Index Characteristics"}]}
+{"image": "doclay/doclay_22183.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "The following asset allocation guidelines apply to the Return-Seeking Assets:\nAsset Category Percentage Range Public Equity 70% - 90% Growth Fixed Income 0% - 15% Alternatives 0% - 15% Cash 0% - 10%\nThe asset allocations of our Company-sponsored pension plans by asset category for both Long Duration and  Return-Seeking Assets, as of December 28, 2014, were as follows:\nAsset Category Percentage Public Equity 32% Fixed Income 57% Alternatives 4% Cash 7%\nThe specified target allocation of assets and ranges set forth above are maintained and reviewed on a periodic  basis by the pension investment committee. The pension investment committee may direct the transfer of assets  between investment managers in order to rebalance the portfolio in accordance with approved asset allocation ranges  to accomplish the investment objectives for the pension plan assets.\nFair Value of Plan Assets\nThe fair value of the assets underlying our Company-sponsored qualified pension plans and The New York  Times Newspaper Guild pension plan by asset category are as follows:\nGLYPH<160> Fair Value Measurement at December 28, 2014 (In thousands) QuotedGLYPH<160>Prices Markets for IdenticalGLYPH<160>Assets Significant Observable Inputs Significant Unobservable Inputs GLYPH<160> Asset Category (1) (Level 1) (Level 2) (Level 3) Total Equity Securities: U.S. Equities $ 48,640 $ GLYPH<151> $ GLYPH<151> $ 48,640 International Equities 51,154 GLYPH<151> GLYPH<151> 51,154 Common/Collective Funds (2) GLYPH<151> 697,075 GLYPH<151> 697,075 Fixed Income Securities: Corporate Bonds GLYPH<151> 539,098 GLYPH<151> 539,098 U.S. Treasury and Other Government Securities GLYPH<151> 150,496 GLYPH<151> 150,496 Group Annuity Contract GLYPH<151> 76,290 GLYPH<151> 76,290 Municipal and Provincial Bonds GLYPH<151> 47,046 GLYPH<151> 47,046 Government Sponsored Enterprises (3) GLYPH<151> 9,517 GLYPH<151> 9,517 Other GLYPH<151> 22,951 GLYPH<151> 22,951 Cash and Cash Equivalents 52 127,910 GLYPH<151> 127,962 Private Equity GLYPH<151> GLYPH<151> 35,727 35,727 Hedge Fund GLYPH<151> GLYPH<151> 31,294 31,294 Assets at Fair Value $ 99,846 $ 1,670,383 $ 67,021 $1,837,250\n(1)  Includes the assets of The Guild-Times Adjustable Pension Plan and the Retirement Annuity Plan which are not part of the Master Trust.\n(2)  The underlying assets of the common/collective funds are primarily comprised of equity and fixed income securities.The fair value in the  above table represents our ownership share of the net asset value of the underlying funds.\n(3)  Represents investments that are not backed by the full faith and credit of the United States government.\nTHE NEW YORK TIMES COMPANY – P. 83"}]}
+{"image": "doclay/doclay_8842.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "re:defining GLOBAL DELIVERY\nCognizant Technology Solutions\nAnnual Report 2004\n"}]}
+{"image": "doclay/doclay_17599.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "33\nCaribbean Utilities Company, Ltd.  2011  Annual Report Financial Statements\nStatements of Cash Flows\n(Expressed in thousands of United States dollars)\nTwelve  Twelve months ended months ended December 31, 2011 December 31, 2010 $ $ Operating Activities Earnings for the period  20,390 19,879 Items not affecting cash: Depreciation of property, plant and equipment  20,570 20,034 Amortization of intangible assets  308 336 Non-cash pension expenses  - 120 Amortization of deferred financing costs  187 182 Stock-based compensation  47 47 41,502 40,598 Net change in non-cash working capital balances related to operations  116 159 Net change in regulatory deferrals  (4,466) 10 Cash flow related to operating activities 37,152  40,767 Investing Activities Purchase of property, plant and equipment  (39,624) (20,173) Costs related to intangible assets  (554) (292) Insurance funds received  4,771  - Proceeds on sale of property, plant and equipment  19 26 Cash flow related to investing activities (35,388) (20,439) Financing Activities Proceeds from debt financing  46,000 9,000 Repayment of debt  (32,500) (14,000) Increase in bank overdraft  1,059 -  Dividends paid  (19,757) (19,529) Net proceeds from share issues  1,495  1,637 Cash flow related to financing activities ( 3,703) (22,892) Decrease in cash and cash equivalents (1,939) (2,564) Cash and cash equivalents - beginning of period 2,363 4,927 Cash and cash equivalents - end of period 424 2,363 Supplemental disclosure of cash flow information: Interest paid during the period  12,079 11,995\nSee accompanying Notes to Financial Statements"}]}
+{"image": "doclay/doclay_59305.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "UNIT ONE Nouns: gender and number\nGender: masculine and feminine\n1 All Italian nouns are either masculine or feminine. The best way to remem- ber the gender of a noun is to learn it along with its de fi nite article (i.e. the word meaning ‘the’). In this unit, nouns will therefore be given along with their de fi nite articles, but there will be no discussion of the articles as such. De fi nite and inde fi nite articles are the subject of Unit 2.\nMost nouns in the singular end in  -o ,  -a , or  -e .\n2 Italian nouns ending in  -o  are usually masculine:\n3 Italian nouns ending in  -a  are usually feminine:\n4 Italian nouns ending in  -e  can be either masculine or feminine. Unless a noun ending in  -e  denotes a person whose gender is de fi ned (e.g. ‘husband’, ‘wife’), there are virtually no rules to determine its gender, which must there- fore be learned by heart or checked in a dictionary:\nl’uomo  [m] il fratello  [m] il pomeriggio  [m] il treno  [m] man brother afternoon train\nla donna  [f] la sorella  [f] la sera  [f] la bicicletta  [f] woman sister evening bicycle"}]}
+{"image": "doclay/doclay_63081.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "58 \nUS 8,614,033 B2 \nneA’  ,,,,:  (  ___l___Qil+  C 4 F9S03- ~  113  A$_{3 }$\n(z14)  ,  0  neA’  ,,,,: \n(z13)  p  113  A3 \n(z12)  p  ~s c,,,so,  ~  b  mA’  p \n(  +otS’  c,c,so,  (zll)  113  A3  p \n-continued  (zlO)  127  A 3  +otS’ \n(z9)  O  p  M  O  U  * C  C  C  T03S  F  F  127  A 3 \nb  (zS)  216A 3 \n’’\"  P  so  --0-s  c,cnso,  b  ,, \n(z6)  -q CF3  (  ot3  s+  -03S  O  CF3  ’’\" \n303  A 3 -continued "}]}
+{"image": "doclay/doclay_18054.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Note 22. Segment Information  (continued)\n(b) Operating Segments\nNOTES TO THE FINANCIAL STATEMENTS CONTINUED FOR THE FINANCIAL YEAR ENDED 30 JUNE 2011\n66 Karoon Gas Australia Ltd  Annual Report 2011\nAll Other  Australia  Brazil  Peru  Segments Consolidated Segment Performance  $  $  $  $  $ Revenue for financial year ended 30 June 2011 Segment revenue  -  -  -  - - Interest income from unrelated entities  -  -  -  14,225,048  14,225,048 Total revenue  14,225,048 Result for financial year ended 30 June 2011 Segment result  (4,448,680)  (32,449)  (18,277)  (163,148)  (4,662,554) Interest income from unrelated entities  -  -  -  14,225,048  14,225,048 Net foreign currency losses  -  -  -  (10,440,658)  (10,440,658) Finance costs  -  -  -  (456,290)  (456,290) Employee benefits expense (net)  -  -  -  (8,529,761)  (8,529,761) Administration and other operating expenses  -  -  -  (12,133,822)  (12,133,822) Depreciation and amortisation expense  -  -  -  (531,245)  (531,245) Property costs  -  -  -  (775,632)  (775,632) Loss before income tax  (23,304,914) Income tax expense  - Loss for financial year  (23,304,914) Revenue for financial year ended 30 June 2010 Segment revenue  -  -  -  - - Interest income from unrelated entities  -  -  -  6,459,623  6,459,623 Total revenue  6,459,623 Result for financial year ended 30 June 2010 Segment result  (70,705)  (12,207)  (3,001)  (49,985)  (135,898) Interest income from unrelated entities  -  -  -  6,459,623  6,459,623 Net foreign currency losses  -  -  -  (8,514,337)  (8,514,337) Finance costs  -  -  -  (244,275)  (244,275) Employee benefits expense (net)  -  -  -  (6,719,729)  (6,719,729) Administration and other operating expenses  -  -  -  (4,820,088)  (4,820,088) Depreciation and amortisation expense  -  -  -  (415,667)  (415,667) Property costs  -  -  -  (274,646)  (274,646) Loss before income tax  (14,665,017) Income tax expense  (228,822) Loss for previous financial year  (14,893,839"}]}
+{"image": "doclay/doclay_56960.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "NDB API Statistics Counters and Variables\n| NDB_API_UK_OP_COUNT | 0 | | NDB_API_TABLE_SCAN_COUNT | 1 | | NDB_API_RANGE_SCAN_COUNT | 0 | | NDB_API_PRUNED_SCAN_COUNT | 0 | | NDB_API_SCAN_BATCH_COUNT | 0 | | NDB_API_READ_ROW_COUNT | 2 | | NDB_API_TRANS_LOCAL_READ_ROW_COUNT | 2 | | NDB_API_EVENT_DATA_COUNT | 0 | | NDB_API_EVENT_NONDATA_COUNT | 0 | | NDB_API_EVENT_BYTES_COUNT | 0 | +--------------------------------------------+----------------+ 60 rows in set (0.00 sec)\nEach  Ndb  object has its own counters. NDB API applications can read the values of the counters for use in optimization or monitoring. For multithreaded clients which use more than one  Ndb  object concurrently, it is also possible to obtain a summed view of counters from all  Ndb  objects belonging to a given  Ndb_cluster_connection .\nFour sets of these counters are exposed. One set applies to the current session only; the other 3 are global.  This is in spite of the fact that their values can be obtained as either session or global status variables in the  mysql  client . This means that specifying the  SESSION  or  GLOBAL  keyword with  SHOW STATUS  has no effect on the values reported for NDB API statistics status variables, and the value for each of these variables is the same whether the value is obtained from the equivalent column of the session_status  or the  global_status  table.\nSession counters relate to the  Ndb  objects in use by (only) the current session. Use of such objects by other MySQL clients does not influence these counts.\nIn order to minimize confusion with standard MySQL session variables, we refer to the variables that correspond to these NDB API session counters as “ _session  variables” , with a leading underscore.\nThis set of counters relates to the  Ndb  objects used by the replica SQL thread, if any. If this  mysqld does not act as a replica, or does not use  NDB  tables, then all of these counts are 0.\nWe refer to the related status variables as “ _slave  variables”  (with a leading underscore).\nInjector counters relate to the  Ndb  object used to listen to cluster events by the binary log injector thread. Even when not writing a binary log,  mysqld  processes attached to an NDB Cluster continue to listen for some events, such as schema changes.\nWe refer to the status variables that correspond to NDB API injector counters as “ _injector  variables” (with a leading underscore).\nThis set of counters relates to all  Ndb  objects currently used by this  mysqld . This includes all MySQL client applications, the replica SQL thread (if any), the binary log injector, and the  NDB  utility thread.\nWe refer to the status variables that correspond to these counters as “global variables”  or “ mysqld -level variables” .\n4512\n• Session counters (session specific)\n• Replica counters (global)\n• Injector counters (global)\n• Server (Global) counters (global)"}]}
+{"image": "doclay/doclay_72994.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Impact of derivatives on the Consolidated balance sheets The following table summarizes information on derivative receivables and payables (before and after netting adjustments) that are reflected on the\nImpact of derivatives on the Consolidated balance sheets The following table summarizes information on derivative receivables and payables (before and after netting adjustments) that are reflected on the Firm’s Consolidated balance sheets as of December 31, 2018 and 2017, by accounting designation (e.g., whether the derivatives were designated in qualifying hedge accounting relationships or not) and contract type.\nGross derivative receivables Gross derivative payables December 31, 2018 (in millions) Not designated as hedges Designated as hedges Total derivative receivables Net derivative receivables (b) Not designated as hedges Designated as hedges Total derivative payables Net derivative payables (b) Trading assets and liabilities Interest rate $ 267,871 $ 833 $ 268,704 $ 23,214 $ 242,782 $ — $ 242,782 $ 7,784 Credit 20,095 — 20,095 612 20,276 — 20,276 1,667 Foreign exchange 167,057 628 167,685 13,450 164,392 825 165,217 12,785 Equity 49,285 — 49,285 9,946 51,195 — 51,195 10,161 Commodity 20,223 247 20,470 6,991 22,297 121 22,418 9,372 Total fair value of trading assets and liabilities $ 524,531 $ 1,708 $ 526,239 $ 54,213 $ 500,942 $ 946 $ 501,888 $ 41,769\nGross derivative receivables Gross derivative payables December 31, 2017 (in millions) Not designated as hedges Designated as hedges Total derivative receivables Net derivative receivables (b) Not designated as hedges Designated as hedges Total derivative payables Net derivative payables (b) Trading assets and liabilities Interest rate $ 314,962 (c) $ 1,030 (c) $ 315,992 $ 24,673 $ 284,433 $^{(c)}$  $ 3 (c) $ 284,436 $ 7,129 Credit 23,205 — 23,205 869 23,252 — 23,252 1,299 Foreign exchange 159,740 491 160,231 16,151 154,601 1,221 155,822 12,473 Equity 40,040 — 40,040 7,882 45,395 — 45,395 9,192 Commodity 20,066 19 20,085 6,948 21,498 403 21,901 7,684 Total fair value of trading assets and liabilities $ 558,013 (c) $ 1,540 (c) $ 559,553 $ 56,523 $ 529,179 $^{(c)}$  $ 1,627 (c) $ 530,806 $ 37,777\n(a) Balances exclude structured notes for which the fair value option has been elected. Refer to Note 3 for further information. (b) As permitted under U.S. GAAP, the Firm has elected to net derivative receivables and derivative payables and the related cash collateral receivables and payables when a\n(a) Balances exclude structured notes for which the fair value option has been elected. Refer to Note 3 for further information. (b) As permitted under U.S. GAAP, the Firm has elected to net derivative receivables and derivative payables and the related cash collateral receivables and payables when a legally enforceable master netting agreement exists. (c) The prior period amounts have been revised to conform with the current period presentation.\nlegally enforceable master netting agreement exists. (c) The prior period amounts have been revised to conform with the current period presentation.\nJPMorgan Chase & Co./2018 Form 10-K\n188\nNotes to consolidated financial statements\nFree-standing derivative receivables and payables (a)"}]}
+{"image": "doclay/doclay_10015.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Profile\nFinancial Highlights 1 Report to Stockholders 2 Mill Services 4 Access Services 6 Gas & Fluid Control Products 8 Other Infrastructure Products & Services 10 Guiding Principles 12 Directors and Officers 13 Principal Offices 14 Form 10-K Annual Report 15\nThe forward-looking statements expressed or implied in this report are based on current expectations regarding important factors which, among others, could cause future results to differ materially. Please refer to the “Forward-Looking Statements” section under Item 7 of the Form 10-K Annual Report.\nCautionary Notice with Respect to  Forward-Looking Statements\nHarsco Corporation provides high-value industrial services and engineered products to major global industries, including steel, construction, gas and energy, and railway transportation.\nThe Company's market-leading businesses are organized in four market sectors, with approximately 55% of total revenues generated outside the United States. Harsco's mission is to achieve consistent, superior financial returns from operations, complemented by targeted and prudent growth in markets and technologies familiar to the Company. Harsco common stock is listed on the New York and Pacific Stock Exchanges under the symbol HSC.\nSGB GROUP and PATENT CONSTRUCTION SYSTEMS lead the access industry as the world's most complete providers of scaffolding, shoring, forming and other access solutions. Principal markets include non-residential construction projects and industrial plant maintenance. The HARSCO GAS AND FLUID CONTROL GROUP manufactures the world's broadest range of internationally-compliant tanks, cylinders and valves for the containment and control of pressurized gases. The Group also manufactures the industry's leading custom-designed air-cooled heat exchangers for the natural gas sector. 30% $587.9 million $696.8 million $350.6 million 35% 18% HECKETT MULTISERV is the world's largest provider of on-site, outsourced mill services to the makers of carbon and stainless steel. Operating under long-term, renewable contracts, Heckett MultiServ's customized services enhance critical areas of the steelmaking process. Similar services are provided on a growing scale to the non-ferrous metals industry. This category serves a diverse set of markets. HARSCO TRACK TECHNOLOGIES is a global leader for equipment and services to maintain, repair, and construct railway track. REED MINERALS produces high-quality roofing granules and industrial abrasives. IKG INDUSTRIES manufactures an extensive line of industrial grating products, and PATTERSON-KELLEY is a leader in powder processing equipment and heat transfer products. $341.4 million 17% Mill Services Access Services Gas & Fluid Control Products Other Infrastructure Products & Services Total Revenues"}]}
+{"image": "doclay/doclay_70536.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Draft Document for Review February 7, 2020 3:15 pm\n8464ch11_Monitoring.fm\nIn this example, the maximum total data transfer value is 497 MBps (MiB/s Total Xfer), but that  value is mainly driven by the premigration read task (MiB/s Fr_TVC PreMig). If premigration  causes an performance issue, review the PMPRIOR and PMTHLVL setting for tuning. \nIn addition to daily and monthly summary reports per cluster, VEHSTATS provides a  side-by-side comparison of all clusters for the entire measurement interval. Examine this  report for an overall view of the grid, and for significant or unexpected differences between  the clusters. \nSummary reports\n11.5.6 Performance evaluation tool for VEHSTATS reports\nAfter you collect the statistics data from your clusters, you can use available tools to format  and plot the binary data.\nFor more information, see  IBM Virtualization Engine TS7700 Series Best Practices -  Understanding, Monitoring and Tuning the TS7700 Performance , WP101465.\nWhen evaluating performance, a graph that reveals a significant amount of information  succinctly is the  cache throughput  for a cluster graph.\nPerformance tools are available on the IBM Techdocs website that take 24 hours of 15-minute  VEHSTATS data, seven days of 1-hour VEHSTATS data, or 90 days of daily summary data  and create a set of charts for you. \nThe material does not contain any information about the specifics of a Tape Attach model.  However, the other information is still valuable, and did not change, especially how to create  the excel spreadsheet and the charts.\nSee the following Techdocs sites for the performance tools, and the class replay for detailed  information about how to use the performance tools: \nGLYPH<SM590000> Tools \nGLYPH<SM590000> Class replay \nThe 24-hour, 15-minute data spreadsheets include the cache throughput chart. Figure 11-31  shows the cache throughput that was plotted from VEHSTATS. \nFigure 11-31 Cache throughput plotted from VEHSTATS\nChapter 11. Monitoring  679\n"}]}
+{"image": "doclay/doclay_14301.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Other Operations Segment\nSegment Description\nResults of Operations\nFinancial Summary\nRevenues\nCorporate\nDescription\n50 CIGNA CORPORATION -  2012 Form  10-K\nCorporate reflects amounts not allocated to operating segments, such as net interest expense (defined as interest on corporate debt less net investment income on investments not supporting segment operations), interest on uncertain tax positions, certain litigation matters, intersegment eliminations, compensation cost for stock options and certain corporate overhead expenses such as directors’ expenses and pension expense related to the Company’s frozen pension plans.\nSegment earnings decreased 8% in 2012 compared with 2011, primarily reflecting lower COLI interest margins and mortality gains and the continued decline in deferred gain amortization associated with the sold businesses.\nSegment earnings increased in 2011 compared with 2010, reflecting a $4 million increase from completing the Company’s 2007 and 2008 IRS examination during the first quarter of 2011.\nPremiums and fees  reflect fees charged primarily on universal life insurance policies in the COLI business. Premiums and fees decreased 12% in 2012, compared with 2011 due to lower policyholder death benefit exposures.\nNet investment income  decreased 3% in 2012 compared with 2011, primarily reflecting lower average yields and decreased 1% in 2011 compared with 2010 due to lower portfolio yields partially offset by higher average invested assets.\nFor more information regarding the sale of these businesses see Note 8 to the Consolidated Financial Statements.\nBenefits and expenses  decreased 7% in 2012 compared with 2011 primarily due to favorable COLI claims experience and lower policyholder death benefit coverage and the absence of a charge recorded in the first quarter of 2011 to reimburse the buyer of the retirement benefits business with a portion of the tax benefits resulting from the completion of the 2007 and 2008 IRS examination as required under a tax sharing agreement.\nOther revenues  were flat in 2012 compared with 2011 and decreased 8% in 2011 compared with 2010 primarily due to lower deferred gain amortization related to the sold retirement benefits and individual life insurance and annuity businesses. 2012 results were partially offset by higher investment management fees.\nFinancial Summary (In millions) 2012 2011 2010 Premiums and fees $ 100 $ 114 $ 114 Net investment income 388 400 404 Other revenues 55 55 60 Segment revenues 543 569 578 Benefits and expenses 418 451 454 Income before taxes 125 118 124 Income taxes 43 29 39 SEGMENT EARNINGS 82 89 85 Completion of IRS examination (See Note 20 to the Consolidated Financial Statements) - 4 - ADJUSTED INCOME FROM OPERATIONS $ 82 $ 85 $ 85 Realized investment gains, net of taxes $ 2 $ 6 $ 5\nCigna’s Other Operations segment includes the results of the following businesses:\ncorporate-owned life insurance (‘‘COLI’’); GLYPH<127>\ndeferred gains recognized from the sale of the retirement benefits and individual life insurance and annuity businesses; and GLYPH<127>\nrun-off settlement annuity business. GLYPH<127>\nPART II\nITEM 7 Management’s Discussion and Analysis of Financial Condition and Results of Operations"}]}
+{"image": "doclay/doclay_34749.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "12\nof the following 19 [= D $^{TI}$( L = 30)] RVM functions:\nD. Five bosons\nΦ REM 6+4 $_{k}$(0 , 4) Q 12 − 2 k 2 , with k = 0 , 1 , 2 , 3 , 4 , 5 , 6; Φ REM 6+3 $_{k}$(1 , 3) Q 12 − 3 k/ 2 2 , with k = 2 , 4 , 6; Φ REM 6+4 $_{k}$(0 , 4) Q 8 − 4 k/ 3 3 , with k = 0 , 3; Φ REM 6+3 $_{k}$(1 , 3) Q 8 − k 3 , with k = 2 , 3 , 4 , 5 , 6 , 7 , 8 . (49)\nΦ $^{MR}$[ z ] = S ∏ i<j ∈ A ( z$_{i}$ − z$_{j}$ ) 2 ∏ k<l ∈ B ( z$_{k}$ − z$_{l}$ ) $^{2}$, (50)\nFor N = 5 spinless bosons, one needs to consider rovi- brational states [see Eq. (33)] for three distinct molecular configurations, i.e., Φ RBM 5 k (0 , 5) Q m λ , Φ REM 4 k (1 , 4) Q m λ , and Φ REM 3 k (2 , 3) Q m λ . Vibrations with ≥ 2 must also be con- sidered; since the RVM states are not always orthogonal, a Gram-Schmidt orthogonalization is implemented. TA- BLE IV summarizes the quantal molecular description in the start of the LLL spectrum (0 ≤ L ≤ 12). Of particular interest is the L = 8 case, since it corre-\n≤ ≤ Of particular interest is the L = 8 case, since it corre- sponds to the bosonic Moore-Read state, given [24, 31] by the analytic expression:\nDiagonalization of the Coulomb interaction in the above TI subspace yielded an energy 0.25084902 e $^{2}$/ ( κl$_{B}$ ) per electron for the yrast state; this value agrees again, within machine precision, with the EXD result. The most sophisticated variants of the composite-fermion the- ory [including composite-fermion diagonalization (CFD), composite-fermion crystal (CFC), and mixed liquid-CFC states [11, 17–19]] fall short in this respect. Indeed the following higher energies were found [17, 61]: 0.250863(6) (CFD), 0.25094(4) (mixed), 0.25101(4) (CFC). The CFD basis is not translationally invariant [18, 19]. Conse- quently, to achieve machine-precision accuracy, the CFD will have to be performed in the larger space of dimension D $^{EXD}$( L = 30) = 169.\nBased on sizeable overlaps with the EXD wave func- tions [24, 31], the bosonic Moore-Read states [7] are thought to represent the yrast states in the lowest Lan- dau level with the same angular momentum, i.e., L =\nwhere sets A and B contain ( N − 1) / 2 and ( N + 1) / 2 particles, respectively, if N is odd. (For N even, both sets contain N/ 2 particles.) S symmetrizes over all possible ways of carrying such a division of N particles into the two sets.\nthe RVM diagonalization agree with the corresponding EXD ones within machine precision. L D $^{EXD}$( D $^{TI}$) [( n 1 , n 2 ) { k, λ, m } ] Energy eigenvalues (RVM diag. or EXD $^{TI}$) 0 1(1) [(0,5) { 0, λ ,0 } ] 5.00000000[1] 2 2(1) [(0,5) { 0,2,1 } ] 3.75000000[1] 3 3(1) [(0,5) { 0,3,1 } ] 3.12500000[1] 4 5(2) [(1,4) { 1, λ ,0 } ] [(0,5) { 0,2,2 } ] 2.50000000[1] 3.18750000[3] 5 7(2) [(0,5) { 1, λ ,0 } ] [(0,5) { 0,5,1 } ] 1.87500000[1] 3.03125000[3] 6 10(3) [(1,4) { 1,2,1 } ] [(0,5) { 0,2,3 } ] [(0,5) { 0,3,2 } ] 1.90664171[2] 2.42925914[3] 3.02347415[5] 7 13(3) [(1,4) { 1,3,1 } ] [(0,5) { 1,2,1 } ] [(2,3) { 1,2,2 } ] 1.77354877[1] 2.07258062[4] 3.00543311[7] 8 18(5) [(1,4) { 2, λ ,0 } ] [(1,4) { 1,2,2 } ] [(0,5) { 1,3,1 } ] 1.18821986[1] 1.60795253[2] 1.91688009[6] [(0,5) { 0,2,4 } ] [(2,3) { 2,2,1 } ] 2.24905854[8] 3.00273273[11] 9 23(5) [(1,4) { 1,5,1 } ] [(0,5) { 1,2,2 } ] [(2,3) { 3, λ ,0 } ] 1.12895814[1] 1.52195553[3] 1.89102917[7] [(2,3) { 2,3,1 } ] [(2,3) { 1,3,2 } ] 2.06074601[10] 3.00082677[15] 10 30(7) [(0,5) { 2, λ ,0 } ] [(0,5) { 1,5,1 } ] [(0,5) { 0,5,2 } ] 0.90026059[1] 1.29362646[4] 1.51398054[5] [(1,4) { 2,2,1 } ] [(1,4) { 1,2,3 } ] [(1,4) { 1,3,2 } ] 1.66194766[8] 1.95923264[14] 2.12274862[17] [(2,3) { 2,2,2 } ] 3.00035191[21] 11 37(7) [(0,5) { 1,3,2 } ] [(0,5) { 1,2,3 } ] [(1,4) { 2,3,1 } ] 1.03755324[2] 1.07552423[3] 1.50429489[7] [(2,3) { 3,2,1 } ] [(2,3) { 2,5,1 } ] [(2,3) { 1,2,4 } ] 1.58737738[10] 1.94750687[18] 2.03365831[20] [(2,3) { 1,4,2 } ] 3.00012024[27] 12 47(10) [(0,5) { 2,2,1 } ] [(1,4) { 3, λ ,0 } ] [(1,4) { 2,2,2 } ] 0.61480761[1] 0.93028069[3] 1.05066256[5] [(1,4) { 2,4,1 } ] [(1,4) { 1,4,2 } ] [(1,4) { 1,2,4 } ] 1.34022509[10] 1.50000444[11] 1.50755634[13] [(2,3) { 4, λ ,0 } ] [(2,3) { 3,3,1 } ] [(2,3) { 1,3,3 } ] 1.64279523[18] 1.98164620[27] 2.05477689[29] [(2,3) { 0,4,3 } ] 3.00004768[36]\nTABLE IV: LLL spectra of five spinless bosons interacting via a repulsive contact interaction gδ ( z i − z j ) . Second column: Dimensions of the full EXD and the nonspurious TI (in parenthesis) spaces (the EXD space is spanned by uncorrelated permanents of Darwin-Fock orbitals). Last three columns: Energy eigenvalues [in units of g/ ( π Λ $^{2}$)] from the diagonalization of the contact interaction in the TI subspace spanned by the trial functions Φ RBM 5 k (0 , 5) Q m λ , Φ RBM 4 k (1 , 4) Q m λ , and Φ RBM 3 k (2 , 3) Q m λ (RVM digonalization). Third to sixth columns: the molecular configurations ( n 1 , n 2 ) and the quantum numbers k , λ and m are indicated within brackets. There is no nonspurious state with L = 1. The full EXD spectrum at a given L is constructed by including, in addition to the listed TI energy eigenvalues [ D $^{TI}$( L ) in number], all the energies associated with angular momenta smaller than L . An integer in square brackets indicates the energy ordering in the full EXD spectrum [including both spurious and TI states (EXD $^{TI}$)], with [1] denoting an yrast state. Eight decimal digits are displayed, but the energy eigenvalues from the RVM diagonalization agree with the corresponding EXD TI ones within machine precision."}]}
+{"image": "doclay/doclay_57087.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "ndb_mgmd — The NDB Cluster Management Server Daemon\nFormat Description Added, Deprecated, or Removed --ndb-mgmd- host=connection-string , -c Same as --ndb-connectstring (Supported in all NDB releases based on MySQL 8.0) --ndb-nodeid=# Set node ID for this node, overriding any ID set by --ndb- connectstring (Supported in all NDB releases based on MySQL 8.0) --ndb-optimized-node- selection Enable optimizations for selection of nodes for transactions. Enabled by default; use --skip-ndb- optimized-node-selection to disable (Supported in all NDB releases based on MySQL 8.0) --no-defaults Do not read default options from any option file other than login file (Supported in all NDB releases based on MySQL 8.0) --no-nodeid-checks Do not provide any node ID checks (Supported in all NDB releases based on MySQL 8.0) --nodaemon Do not run ndb_mgmd as a daemon (Supported in all NDB releases based on MySQL 8.0) --nowait-nodes=list Do not wait for management nodes specified when starting this management server; requires -- ndb-nodeid option (Supported in all NDB releases based on MySQL 8.0) --print-defaults Print program argument list and exit (Supported in all NDB releases based on MySQL 8.0) --print-full-config , -P Print full configuration and exit (Supported in all NDB releases based on MySQL 8.0) --reload Causes management server to compare configuration file with configuration cache (Supported in all NDB releases based on MySQL 8.0) --remove[=name] Used to remove management server process that was previously installed as Windows service, optionally specifying name of service to be removed; does not apply on other platforms (Supported in all NDB releases based on MySQL 8.0) --usage , -? Display help text and exit; same as --help (Supported in all NDB releases based on MySQL 8.0) --skip-config-file Do not use configuration file (Supported in all NDB releases based on MySQL 8.0) --verbose , -v Write additional information to log (Supported in all NDB releases based on MySQL 8.0) --version , -V Display version information and exit (Supported in all NDB releases based on MySQL 8.0)\n4257"}]}
+{"image": "doclay/doclay_36462.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "10 0 10 1 10 2 10 3 10 4 10 -2 10 -1 10 0 10 1 10 2 10 3 10 4 dN/dln E, dN/dln  ∈ E,  ∈  (MeV) e $^{+}$e - pairs Photons 10 -1 10 0 10 1 10 2 10 3 10 4 E,  ∈  (MeV) e $^{+}$e - pairs Photons 10 -1 10 0 10 1 10 2 10 3 10 4 10 5 E,  ∈  (MeV) e $^{+}$e - pairs Photons\nPair cascades of strongly-magnetized neutron stars 17\nFigure 9. The final photon and pair spectra of photon-initiated cascades for a non-dipole magnetosphere with local radius of curvature R$_{c}$ = R , for surface magnetic fields B$_{p,}$$_{12}$ = 1 (left panel), 10 (middle panel), and 100 (right panel). Here, the primary photon has ϵ$_{0}$ = 10 4 MeV and ICS is active from a hot spot with T$_{6}$ = 1, θ$_{spot}$ = 0 . 3.\nTable 1. Pair multiplicity N$_{E}$ when resonant ICS is the dominant photon emission process of the primary electron. For simplicity, all photons are assumed to be upscattered from the thermal peak ( γ$_{crit}$ ; see text). Each entry in the table gives N$_{E}$ = N$_{0}$n$_{E}$ for a different surface magnetic field strength B$_{p}$ , radius of curvature (either R$_{c}$ = R or a dipole field curvature with the pulsar spin period P$_{0}$ is specified), and hot spot temperature T and size θ$_{spot}$ . The pair multiplicity is zero for B$_{p,}$$_{12}$ = 1 and the hot spot models used here, even when R$_{c}$ = R ; we therefore omitted these entries from the table.\nT$_{6}$ = 1, θ$_{spot}$ = 0 . 3 T$_{6}$ = 3, θ$_{spot}$ = 0 . 1 P$_{0}$ = 10 P$_{0}$ = 1 R$_{c}$ = R P$_{0}$ = 10 P$_{0}$ = 1 R$_{c}$ = R B$_{p,}$$_{12}$ = 10 0 0 14 0 0 220 B$_{p,}$$_{12}$ = 100 2.2 1.2 1.2 35 6.2 31 B$_{p,}$$_{12}$ = 1000 0.7 0.1 0.1 11 1.9 4.4\nof a secondary electron/positron, ¯ E = E $_{tot}$/N$_{E}$ , is directly proportional to the total cascade energy (i.e., ¯ E ∝ γ$_{0}$ ), but depends only weakly on B$_{p}$ , P , and R c (e.g., ¯ E is approx- imately the same for R c = R and γ$_{0}$ = 2 × 10 7 as in the dipole case for γ$_{0}$ = 2 × 10 $^{7}$).\nriod for dipole fields or the curvature radius for multipole fields, the surface field strength B$_{p}$ and the primary electron energy γ$_{0}$m$_{e}$c $^{2}$), we give γ$_{f}$m$_{e}$c 2 (the final energy of the pri- mary electron when it escapes the light cylinder), ε$_{tot}$ (the total energy of the cascade photons), E tot (the total energy of the secondary e $^{+}$e − pairs), and N$_{E}$ (the multiplicity of e $^{+}$e − pairs produced per primary electron). Note that the total cascade energy must satisfy γ$_{0}$m$_{e}$c 2 = γ$_{f}$m$_{e}$c 2 + E tot + ε$_{tot}$ . We find that N$_{E}$ is largest for cascades with strong sur- face fields, short rotation periods, multipole geometries, or large initial energies for the primary electron, but that re- gardless of cascade parameters the particle multiplicity sat- urates at N$_{E}$ ∼ 10 $^{4}$. Increasing B$_{p}$ or γ$_{0}$ , or decreasing P or R $_{c}$, tends to increase the ratio f$_{E}$ = E $_{tot}$/ ( ε$_{tot}$ + E $_{tot}$); i.e., under these conditions a larger fraction of the “secondary” energy, γ$_{0}$m$_{e}$c 2 − γ$_{f}$m$_{e}$c $^{2}$, is transfered from the photons to the pairs. At low fields only a small fraction of the secondary energy is held by the secondary pairs (e.g., for B$_{p,}$$_{12}$ = 1, f$_{E}$ < ∼ 0 . 05), but at high fields this fraction is typically above 50% (e.g,, for B$_{p,}$$_{12}$ = 1000, f$_{E}$ > ∼ 0 . 8). The average energy\nFigure 10 shows the secondary pair multiplicities N$_{E}$ as a function of γ$_{0}$ , for various field strengths and periods/field geometries. We find that for dipole geometries N$_{E}$ is a strong function of both γ$_{0}$ and the ratio B$_{p}$P − 2 (i.e., the polar cap voltage), but depends very weakly on either P or B$_{p}$ alone. For example, the N$_{E}$ versus γ$_{0}$ curves for B$_{p,}$$_{12}$ = 1 , P$_{0}$ = 1 and B$_{p,}$$_{12}$ = 100 , P$_{0}$ = 10 are nearly the same, as is shown in Fig. 10. Assuming that a dense secondary pair plasma is a necessary ingredient in pulsed radio emission from neutron stars (see Section 1), we can use our pair multiplicity results to estimate the conditions for pulsar “death” — the condi- tions under which a NS is no longer active as a radio pulsar: For a particular set of cascade parameters B$_{p}$ , P , and R $_{c}$, we define γ$_{death}$ to be the value of γ$_{0}$ at which on average only one electron/positron is created per primary electron;"}]}
+{"image": "doclay/doclay_17697.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Part II  iteM 7 Management’s Discussion and analysis of Financial Condition and results of operations\nSegment results\nAgricultural Products\nCertain Regulatory Issues\nasset impairments, Last-in, First-out (“LIFO”) inventory adjustments,  amortization of inventory step-up from business acquisitions and other  related inventory adjustments, pension settlement charge adjustments  and other income and expense items.\nInformation about how each of these items relates to our businesses  at the segment level and results by segment are discussed below and  in Note 19 to our consolidated financial statements included in this  Form 10-K.\nFor management purposes, segment operating profit is defined as  segment revenue less segment operating expenses (segment operating  expenses consist of costs of sales and services, selling, general and  administrative expenses and research and development expenses). We  have excluded the following items from segment operating profit:  corporate staff expense, interest income and expense associated with  corporate debt facilities and investments, income taxes, gains (or  losses) on divestitures of businesses, restructuring and other charges  (income), investment gains and losses, loss on extinguishment of debt, \nRevenue of $1,241.8 million increased 18 percent versus the prior year,  as higher sales were recognized in North America, Latin America and  Asia. North America revenue increased 15 percent to $252.0 million due  to strong demand for our proprietary herbicides, growth from new and  recently introduced products, particularly our newly acquired herbicide,  fluthiacet-methyl, and improving market conditions in some non-crop  segments. Europe, Middle East and Africa revenue of $158.7 million were  flat year over year. Latin America revenue of $628.9 million increased  24 percent due to improved market conditions, particularly in the  sugarcane, cotton, soybeans, corn and tobacco segments, and growth  in new and recently introduced products. Revenue in Asia increased  21 percent to $202.1 million reflecting better market conditions, the  introduction of new products and growth in most countries particularly  India, Indonesia, Australia and China.\nSegment operating profit of $309.5 million increased seven percent  compared to the prior year period, reflecting strong sales performance  partially offset by higher first-half inventory and distribution costs, and  selling and administrative expenses. Higher selling and administrative  expenses were primarily due to foreign exchange impacts, higher spending  on growth initiatives and increased people-related costs.\nIn 2011, we expect full-year revenue growth in the high-single digits  driven by increased volumes in most regions, particularly Latin America  and Asia, due to expected strong market conditions and growth in new  and recently introduced products. Full-year segment operating profit  growth is expected in the high-single digits reflecting the sales gains  partially offset by higher spending on growth initiatives and higher  raw material costs.\nIn our Agricultural Products segment, several products are undergoing  re-registration in the U.S. and/or a comparable regulatory review by the  European Union (“EU”) governmental authorities. In August 2006,  the U.S. Environmental Protection Agency (“EPA”) issued its “Interim  Reregistration Eligibility Decision” (“IRED”) for our carbofuran  insecticide under the U.S. federal pesticide law. The IRED proposed  cancellation of all carbofuran uses in the United States, subject to a phase  out period for certain minor crop uses, while maintaining tolerances  for imported commodities (bananas, coffee, rice and sugarcane). The  EPA reiterated its proposal in January 2008, with the issuance of a draft  Notice of Intent to cancel carbofuran use (“Notice”). In February 2008,  the EPA convened a Scientific Advisory Panel meeting to evaluate \nIn the EU, following an administrative appeals process, the European  Commission’s proposal to exclude our bifenthrin product from the  European Commission’s official list of approved pesticides, was adopted  on November 30, 2009. FMC had an additional six months to sell  bifenthrin in the EU (i.e., through end-May 2010), and subsequently,  in most EU countries, there is up to 6-12 months for further sale by  distributors or dealers, and use by farmers. We have re-submitted for  reconsideration and the product dossier is now being reviewed by  relevant European authorities. On December 30, 2010, the French  Ministry of Agriculture issued a notice adding bifenthrin, along with  eight other pesticidal active ingredients, to the “Grenelle” list of  pesticides prohibited for sale in France. We believe that such listing \nscientific issues relevant to the Notice. Separately, the U.S. Department  of Agriculture issued its comments on the Notice, stating that carbofuran  should continue to be registered. On July 24, 2008, the EPA published  a proposal to revoke all carbofuran tolerances under the Federal Food  Drug and Cosmetic Act in advance of any issuance of a final Notice  under the federal pesticide law. We responded to that notice, expressing  our strong disagreement with the EPA’s proposal to revoke tolerances  and our belief that carbofuran residues on food do not pose a threat  to human health. In May 2009, the EPA published its final revocation  of all carbofuran tolerances effective December 31, 2009. We filed  our objections to this revocation and requested a hearing before an  administrative law judge. On October 30, 2009, the EPA denied our  objections and our request for a hearing. We believe that we are entitled  to a hearing and we have challenged this decision by seeking judicial  review in the U.S. federal courts. On July 23, 2010, the U.S. Court  of Appeals for the D.C. Circuit ruled that the EPA acted arbitrarily  and capriciously in revoking the import tolerances, and ordered that  those tolerances be reinstated. However, the Court did not extend its  rationale to the domestic tolerances and instead ruled that the EPA  had the right to deny our request for administrative hearing. In mid- February 2011, we filed a petition for writ of certiorari, seeking review  before the U.S. Supreme Court. In light of the December 31, 2009,  tolerance revocation, FMC ceased sales of carbofuran in the United States  in 2009. FMC’s sales of our carbofuran products in the United States  were not significant and termination of such U.S. sales did not have  a material effect on the Company’s financial condition or results of  operations. We do not know the EPA’s timing on a final Notice of  Intent to Cancel the carbofuran registration, though the EPA has said  it intends to issue such notice after the tolerance revocation decision  is finally resolved.\n21 FMC Corporation    2010 Form 10K\n(in Millions) Year Ended December 31, Increase/(Decrease) 2010 2009 $ % Revenue $1,241.8 $1,051.6 $190.2 18% Operating Profit 309.5 289.0 20.5 7"}]}
+{"image": "doclay/doclay_15267.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "PART I ITEM 1A Risk Factors\nSubstantially all of the Company’s investment assets are in fixed interest-yielding  debt  securities  of  varying  maturities,  fixed redeemable preferred securities and commercial mortgage loans. The value of these investment assets can fluctuate significantly with changes in market conditions. A rise in interest rates could reduce the value of the Company’s investment portfolio and increase interest expense if Cigna were to access its available lines of credit.\ngrowth depend, in part, on its ability to compete effectively in its markets, set rates appropriately in highly competitive markets to keep or increase its market share, increase membership as planned, and avoid losing accounts with favorable medical cost experience while retaining or increasing membership in accounts with unfavorable medical cost experience.\nThe Company is also exposed to interest rate and equity risk associated with the Company’s pension and other post-retirement obligations. Sustained declines in interest rates could have an adverse impact on the funded status of the Company’s pension plans and the Company’s reinvestment yield on new investments.\nCigna’s profitability depends, in part, on its ability to accurately predict and control future health care costs through underwriting criteria, provider contracting, utilization management and product design. Premiums in the health care business are generally fixed for one-year periods. Accordingly, future cost increases in excess of medical cost projections reflected in pricing cannot generally be recovered in the current contract year through higher premiums. Although Cigna bases the premiums it charges on its estimate of future health care costs over the fixed premium period, actual costs may exceed what was estimated and reflected in premiums. Factors that may cause actual costs to exceed premiums include: medical cost inflation; higher than expected utilization of medical services; the introduction of new or costly treatments and technology; and membership mix.\nFinancial strength, claims paying ability and debt ratings by recognized rating organizations are an important factor in establishing the competitive position of insurance companies and health benefits companies. Ratings information by nationally recognized ratings agencies is broadly disseminated and generally used throughout the industry. Cigna believes the claims paying ability and financial strength ratings of its principal insurance subsidiaries are an important factor in marketing its products to certain of Cigna’s customers. In addition, Cigna Corporation’s debt ratings impact both the cost and availability of future borrowings, and accordingly, its cost of capital. Each of the rating agencies reviews Cigna’s ratings periodically and there can be no assurance that current ratings will be maintained in the future. In addition, a downgrade of these ratings could make it more difficult to raise capital and to support business growth at Cigna’s insurance subsidiaries.\nA downgrade in the financial strength ratings of Cigna’s insurance subsidiaries could adversely affect new sales and retention of current business, and a downgrade in Cigna’s debt ratings would increase the cost of borrowed funds and affect the Company’s ability to access capital.\nSignificant stock market declines could result in additional pension obligations, increased funding for those obligations, and increased pension plan expenses.\nCigna records medical claims reserves for estimated future payments. The Company continually reviews estimates of future payments relating to medical claims costs for services incurred in the current and prior periods and makes necessary adjustments to its reserves. However, actual health care costs may exceed what was estimated.\nCigna currently has unfunded obligations in its frozen pension plans. A significant decline in the value of the plan’s equity and fixed income investments or unfavorable changes in applicable laws or regulations could materially increase Cigna’s expenses and change the timing and amount of required plan funding that could reduce the cash available to Cigna, including its subsidiaries. See Note 10 to Cigna’s Consolidated Financial Statements for more information on the Company’s obligations under the pension plan.\nInsurance ratings represent the opinions of the rating agencies on the financial strength of a company and its capacity to meet the obligations of insurance policies. The principal agencies that rate Cigna’s insurance subsidiaries characterize their insurance rating scales as follows:\nAs an insurer, Cigna has substantial investment assets that support insurance and contractholder deposit liabilities. Generally low levels of interest rates on investments, such as those experienced in United States and foreign financial markets during recent years, have negatively impacted the level of investment income earned by the Company in recent periods, and such lower levels of investment income would continue if these lower interest rates were to continue.\nSignificant changes in market interest rates affect the value of Cigna’s financial instruments that promise a fixed return or benefit and the value of particular assets and liabilities.\nA.M. Best Company, Inc. (‘‘A.M. Best’’), A++ to S (‘‘Superior’’ to ‘‘Suspended’’); GLYPH<127>\nMoody’s Investors Service (‘‘Moody’s’’), Aaa to C (‘‘Exceptional’’ to ‘‘Lowest’’); GLYPH<127>\nStandard & Poor’s Corp. (‘‘S&P’’), AAA to R (‘‘Extremely Strong’’ to ‘‘Regulatory Action’’); and GLYPH<127>\nFitch, Inc. (‘‘Fitch’’), AAA to D (‘‘Exceptionally Strong’’ to ‘‘Order of Liquidation’’). GLYPH<127>\nCIGNA CORPORATION -  2012 Form  10-K 25"}]}
+{"image": "doclay/doclay_41605.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Cumulus Stage (3–5 mile height)  Mature Stage (5–10 mile height)  Dissipating Stage (5–7 mile height)  32 °F  0 °C  Equilibrium level  40,000 ft.  30,000 ft.  20,000 ft.  10,000 ft.  5,000 ft. \nFigure 12-28.  Life cycle of a thunderstorm. \nA squall line is a narrow band of active thunderstorms. Often  it develops on or ahead of a cold front in moist, unstable  air, but it may develop in unstable air far removed from  any front. The line may be too long to detour easily and too  wide and severe to penetrate. It often contains steady-state  thunderstorms and presents the single most intense weather  hazard to aircraft. It usually forms rapidly, generally reaching  maximum intensity during the late afternoon and the first  few hours of darkness. \nleast 20 nautical miles (NM) since hail may fall for miles  outside of the clouds. If flying around a thunderstorm is not  an option, stay on the ground until it passes. \nFor a thunderstorm to form, the air must have sufficient water  vapor, an unstable lapse rate, and an initial lifting action to  start the storm process. Some storms occur at random in  unstable air, last for only an hour or two, and produce only  moderate wind gusts and rainfall. These are known as air  mass thunderstorms and are generally a result of surface  heating. Steady-state thunderstorms are associated with  weather systems. Fronts, converging winds, and troughs  aloft force upward motion spawning these storms that often  form into squall lines. In the mature stage, updrafts become  stronger and last much longer than in air mass storms, hence  the name steady state.  [Figure 12-29] \nThe most violent thunderstorms draw air into their cloud  bases with great vigor. If the incoming air has any initial  rotating motion, it often forms an extremely concentrated  vortex from the surface well into the cloud. Meteorologists  have estimated that wind in such a vortex can exceed 200  knots with pressure inside the vortex quite low. The strong  winds gather dust and debris and the low pressure generates  a funnel-shaped cloud extending downward from the  cumulonimbus base. If the cloud does not reach the surface,  it is a funnel cloud; if it touches a land surface, it is a tornado;  and if it touches water, it is a “waterspout.” \nKnowledge of thunderstorms and the hazards associated with  them is critical to the safety of flight. \nAll thunderstorms have conditions that are a hazard to aviation.  These hazards occur in numerous combinations. While not  every thunderstorm contains all hazards, it is not possible to  visually determine which hazards a thunderstorm contains. \n12-23 \nTornadoes \nSquall Line \nHazards "}]}
+{"image": "doclay/doclay_71020.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Customers\nNatural Gas Transportation, Storage and Supply\nConstruction\n50\nAn application was filed in September 2019 to authorize additional exports from the CCL Project to FTA countries for a 25-year term and to non-FTA countries for a 20-year term in an amount up to the equivalent of approximately 108 Bcf/yr of natural gas, for a total CCL Project export of 875.16 Bcf/yr. The terms of the authorizations are requested to commence on the date of first commercial export from the CCL Project of the volumes contemplated in the application. The application is currently pending before DOE.\nCCL has entered into fixed price long-term SPAs generally with terms of 20 years (plus extension rights) with nine third parties for Trains 1 through 3 of the CCL Project. Under these SPAs, the customers will purchase LNG from CCL on a FOB basis for a price consisting of a fixed fee per MMBtu of LNG (a portion of which is subject to annual adjustment for inflation) plus a variable fee per MMBtu of LNG equal to approximately 115% of Henry Hub. The customers may elect to cancel or suspend deliveries of LNG cargoes, with advance notice as governed by each respective SPA, in which case the customers would still be required to pay the fixed fee with respect to the contracted volumes that are not delivered as a result of such cancellation or suspension. We refer to the fee component that is applicable regardless of a cancellation or suspension of LNG cargo deliveries under the SPAs as the fixed fee component of the price under our SPAs. We refer to the fee component that is applicable only in connection with LNG cargo deliveries as the variable fee component of the price under our SPAs. The variable fee under CCL’s SPAs entered into in connection with the development of the CCL Project was sized at the time of entry into each SPA with the intent to cover the costs of gas purchases and transportation and liquefaction fuel to produce the LNG to be sold under each such SPA. The SPAs and contracted volumes to be made available under the SPAs are not tied to a specific Train; however, the term of each SPA generally commences upon the date of first commercial delivery for the applicable Train, as specified in each SPA.\nIn aggregate, the minimum fixed fee portion to be paid by the third-party SPA customers is approximately $550 million for Train 1, increasing to approximately $1.4 billion upon the date of first commercial delivery for Train 2 and further increasing to approximately $1.8 billion following the substantial completion of Train 3 of the CCL Project.\nIn addition, Cheniere Marketing has agreements with CCL to purchase: (1) 15 TBtu per annum of LNG with an approximate term of 23 years, (2) any LNG produced by CCL in excess of that required for other customers at Cheniere Marketing’s option and (3) 0.85 mtpa of LNG with a term of up to seven years associated with the IPM gas supply agreement between CCL and EOG. See  Marketing section for additional information regarding agreements entered into by Cheniere Marketing.\nTo ensure CCL is able to transport adequate natural gas feedstock to the Corpus Christi LNG terminal, it has entered into transportation precedent agreements to secure firm pipeline transportation capacity with CCP and certain third-party pipeline companies. CCL has entered into a firm storage services agreement with a third party to assist in managing variability in natural gas needs for the CCL Project. CCL has also entered into enabling agreements and long-term natural gas supply contracts with third parties, and will continue to enter into such agreements, in order to secure natural gas feedstock for the CCL Project. As of December 31, 2019, CCL had secured up to approximately 2,999 TBtu of natural gas feedstock through long-term natural gas supply contracts with remaining terms that range up to eight years, a portion of which is subject to the achievement of certain project milestones and other conditions precedent.\nCCL Stage III has also entered into long-term natural gas supply contracts with third parties, and anticipates continuing to enter into such agreements, in order to secure natural gas feedstock for Corpus Christi Stage 3. As of December 31, 2019, CCL Stage III had secured up to approximately 2,361 TBtu of natural gas feedstock through long-term natural gas supply contracts with remaining terms that range up to approximately 15 years, which is subject to the achievement of certain project milestones and other conditions precedent.\nA portion of the natural gas feedstock transactions for CCL and CCL Stage III are IPM transactions, in which the natural gas producers are paid based on a global gas market price less a fixed liquefaction fee and certain costs incurred by us.\nCCL entered into separate lump sum turnkey contracts with Bechtel for the engineering, procurement and construction of Trains 1 through 3 of the CCL Project under which Bechtel charges a lump sum for all work performed and generally bears project"}]}
+{"image": "doclay/doclay_46276.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Access screw Wire core Cover To battery negative To booster terminal of magneto Contact spring To starter side of start switch Internal grounding strip Primary winding Condenser Vibrator moving contact Vibrator stationary contact External ground  through mounting bolt\nFigure 4-24.  Booster coil.\nFigure 4-25.  Booster coil schematic. \n4-16\nacts as an electromagnet only when current flows in the  primary coil, it loses its magnetism as soon as the primary  coil circuit is broken. This permits the action of the spring  to close the contact points and again complete the primary coil circuit. This remagnetizes the coil core, and again  attracts the movable contact point, which again opens the  primary coil circuit. This action causes the movable contact  point to vibrate rapidly, as long as the start switch is held  in the closed, or on, position. The result of this action is a  continuously expanding and collapsing magnetic field that  links the secondary coil of the booster coil. With several \nFigure 4-25  illustrates, in schematic form, the booster coil  components shown in  Figure 4-24 . In operation, battery  voltage is applied to the positive (+) terminal of the booster  coil through the start switch. This causes current to flow  through the closed contact points to the primary coil and  ground.  [Figure 4-25]  Current flow through the primary coil  sets up a magnetic field about the coil that magnetizes the  coil core. As the core is magnetized, it attracts the movable  contact point, which is normally held against the stationary  contact point by a spring.\nAs the movable contact point is pulled toward the iron  core, the primary circuit is broken, collapsing the magnetic  field that extended about the coil core. Since the coil core \nSince the regular distributor terminal is grounded through  the primary or secondary coil of a high-tension magneto,  the high-voltage furnished by the booster coil must be  distributed by a separate circuit in the distributor rotor. This  is accomplished by using two electrodes in one distributor  rotor. The main electrode, or finger, carries the magneto  output voltage; the auxiliary electrode or trailing finger,  distributes only the output of the booster coil. The auxiliary  electrode is always located so that it trails the main electrode,  thus retarding the spark during the starting period. \nother terminated at a high-tension terminal. The high-tension  terminal is connected to an electrode in the distributor by an  ignition cable.\nCoil core Primary winding Stationary  contact point Moving  contact point + Secondary winding Internal grounding strip Movable contact spring Condenser"}]}
+{"image": "doclay/doclay_21182.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Notes to the consolidated financial statements of Aegon N.V.  Note 21 222\n21 Intangible assets\nNet book value Goodwill VOBA Future  servicing  rights Software Other Total At January 1, 2012 259 2,000 397 26 13 2,695 At December 31, 2012 266 1,777 383 50 9 2,485 At December 31, 2013 211 1,742 239 50 4 2,246 Cost At January 1, 2013 393 7,085 621 266 80 8,445 Additions - 4 - 20 - 24 Acquisitions through business combinations 12 3 - - - 15 Capitalized subsequent expenditure - - - 2 - 2 Disposals - - (1) (2) - (3) Disposal of a business - - - (1) (8) (9) Net exchange differences (17) (334) (23) (9) (3) (385) Other movements - - - 1 - 2 At December 31, 2013 388 6,758 596 278 69 8,090 Accumulated amortization, depreciation  and impairment losses At January 1, 2013 127 5,308 238 216 71 5,960 Amortization / depreciation through income  statement - 109 19 15 1 145 Shadow accounting adjustments - (152) - - - (152) Disposals - - - (2) - (2) Disposal of a business - - - (1) (4) (5) Impairment losses 53 - 110 4 1 168 Net exchange differences (4) (250) (9) (6) (3) (271) Other movements - - - 2 - 1 At December 31, 2013 177 5,017 358 228 66 5,845 Cost At January 1, 2012 388 7,149 616 232 80 8,465 Additions - - - 31 1 32 Acquisitions through business combinations 1 5 - - - 6 Capitalized subsequent expenditure - - - 4 - 4 Disposals - - - (8) - (8) Net exchange differences 4 (60) 5 8 (1) (44) Other movements - (9) - (1) - (10) At December 31, 2012 393 7,085 621 266 80 8,445 Accumulated amortization, depreciation  and impairment losses At January 1, 2012 129 5,149 219 206 67 5,770 Amortization / depreciation through income  statement - 142 20 11 4 177 Shadow accounting adjustments - 85 - - - 85 Disposals - - - (7) - (7) Net exchange differences (2) (59) (1) 7 - (55) Other movements - (9) - (1) - (10) At December 31, 2012 127 5,308 238 216 71 5,960\nAnnual Report 2013"}]}
+{"image": "doclay/doclay_45064.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "2.1 NM 3.3 NM 25 seconds 40 seconds 20 NM RA issued  for 300 KT TA issed  Closure Surveillance Range Targets displayed on-screen (TCAS I & II) Traffic advisory (TA)  region (TCAS I & II) TA Region RA Region (TCAS II only) Resolution advisory (RA) region (TCAS II only) Pilot commanded to  take evasive action Pilot alerted to traffic in range Range criterion Intruder Intruder Altitude criterion 1200' 850' 1200' 850'\n11-59\nFigure 11-131.  Traffic collision and avoidance system (TCAS) uses an aircraft’s transponder to interrogate and receive replies from  other aircraft in close proximity. The TCAS computer alerts the pilot as to the presence of an intruder aircraft and displays the aircraft on  a screen in the cockpit. Additionally, TCAS II equipped aircraft receive evasive maneuver commands from the computer that calculates  trajectories of the aircraft to predict potential collisions or near misses before they become unavoidable. \nThere are two classes of TCAS. TCAS I was developed to  accommodate the general aviation community and regional  airlines. This system identifies traffic in a 35–40 mile range  of the aircraft and issues Traffic Advisories (TA) to assist  pilots in visual acquisition of intruder aircraft. TCAS I is  mandated on aircraft with 10 to 30 seats. \nTCAS II is a more sophisticated system. It is required  internationally in aircraft with more than 30 seats or weighing  more than 15,000 kg. TCAS II provides the information  of TCAS I, but also analyzes the projected flightpath of  approaching aircraft. If a collision or near miss is imminent, the  TCAS II computer issues a Resolution Advisory (RA). This is \nan aural command to the pilot to take a specific evasive action  (i.e., DESCEND). The computer is programmed such that the  pilot in the encroaching aircraft receives an RA for evasive  action in the opposite direction (if it is TCAS II equipped).  [Figure 11-131] \nThe transponder of an aircraft with TCAS is able to  interrogate the transponders of other aircraft nearby using  SSR technology (Mode C and Mode S). This is done with  a 1030 MHz signal. Interrogated aircraft transponders  reply with an encoded 1090 MHz signal that allows the  TCAS computer to display the position and altitude of each  aircraft. Should the aircraft come within the horizontal or "}]}
+{"image": "doclay/doclay_73715.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "In addition, to reduce the risk of a potential adverse effect on our ability to use our NOL Carryforwards and certain other tax attributes for federal income tax purposes, our Certificate of Incorporation contains certain restrictions on the acquisition and disposition of our common stock by substantial stockholders (generally holders of more than 4.75%).\nSee Part I, Item 1A. Risk Factors –  “AAG’s Certificate of Incorporation and Bylaws include provisions that limit voting and acquisition and disposition of our equity interests.”  Also see AAG’s Certification of Incorporation and Bylaws, which are filed as Exhibits 3.1, 3.2 and 3.3 hereto, for the full text of the foregoing restrictions.\n42"}]}
+{"image": "doclay/doclay_13071.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "4\nSuccess Drivers\nThere are six drivers of P&G’s success: consumer focus, strategic choices, operational  excellence, financial discipline, organizational structure and brand building capability. excellence, financial discipline, organizational structure and brand-building capability.\nConsumer focus.  The consumer is boss and we put the consumer at the heart of all we do.  First and foremost, this means getting the consumer value equation right on all our brands.  It also means delivering superior, consumer-meaningful innovation. Competitive pressures  make this a continuing challenge, but we are working hard in every part of our business to  deliver a continual stream of innovation that meets consumer needs in ways that reset  performance expectations and represent superior value.\nWe are also making sure that P&G business leaders – including me – get out of the office  and into stores and homes to talk directly with people who buy and use our products. No  other real-world experience clarifies the choices we must make as much as these  conversations with consumers. \nStrategic choices.  We’ve focused on P&G’s core categories, leading brands, and the biggest  retail customers and country markets. And, we’re investing in faster-growing, higher-margin,  more asset-efficient businesses. A good example is the acquisition of Clairol, which  complements the core Hair Care business and helps P&G enter the fast-growing hair colorant  category. Strategic choices like these are paying off. For example, about one-fourth of total  gross margin improvement in fiscal 2002 came from our emphasis on faster-growing, higher- margin businesses such as Beauty Care and Health Care.\nOperational excellence.  Execution determines success, and we’ve placed heightened  emphasis on operational excellence at P&G. Again, Clairol is a good example. We closed this  deal in less than six months and fully integrated business operations seven months later.  Most important, we accomplished a smooth integration and we’re on track to deliver the  committed synergy savings ahead of schedule.\nFinancial discipline.  We have reinforced P&G’s long-standing commitment to financial  discipline. Our efforts are seen most clearly in the Company’s business results. Even before  the highly publicized accounting failures at several companies, we took a number of specific \nRecent P&G innovations include  Pampers Baby Stages of Development  diapers, Crest SpinBrush and White  Strips, Olay Daily Facials and Total  Effects, Tampax Pearl, Tide and Downy  Clean Breeze, Swiffer and many others. Recent P&G innovations include Pampers  Baby Stages of Development diapers,  Crest SpinBrush and Whitestrips,  Olay Daily Facials and Total Effects,  Tampax Pearl, Tide and Downy Clean  Breeze, Swiffer and many others.\nIams in North America is another great  example of operational excellence.  Starting with a 25,000 store, 3,000  truck launch – P&G’s largest ever –  Iams has delivered nine consecutive  quarters of market share growth. \n"}]}
+{"image": "doclay/doclay_75021.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "our array of tools for predicting, dissecting and explaining portfolio performance. In November 2002, we held our second Annual Portfolio Manager’s Workstation User Conference in Atlanta, which was attended by more than one hundred clients. The third annual conference which was held from November 5 through 8, 2003, in San Diego, was equally successful.\nDuring fiscal 2003, we released a series of upgrades to Marquee. Marquee users can access quotes from all major U.S. stock exchanges, a variety of newswires and Wall Street research reports. Key new features include the  ability to set up news and price movement alerts, display  NASDAQ Level II quotes and to display the real-time contributions to return for a client portfolio versus a  benchmark portfolio. The application works in concert with Directions, our flagship application, to create a  powerful environment that merges the latest information from stock exchanges with the deep historical libraries accessible via Directions. All new clients will receive Marquee as part of the basic workstation feature-set,  making the basic FactSet service ever more valuable. Existing clients have the option to upgrade any or all of their workstations to this higher level of service.\nOur Data Warehousing group, which facilitates the flow  of client proprietary content to and from the FactSet online system, experienced healthy growth during 2003. Using FactSet’s Data Central application, our clients can upload portfolio holdings, stock ratings, earnings estimates and other numerical and textual information to our data  centers. This information is not only warehoused at\nThe most challenging sector of our business was investment banking. Layoffs continued at most major banks through- out the year, though we did see some hiring in the industry during the summer of 2003. Recent stock market perform- ance has begun to revive the stagnant initial public offering market, which may translate into a more healthy 2004. Client subscription growth on the investment banking side was flat during fiscal 2003. Nevertheless, our efforts in terms of personnel and new product development for the sell-side continued unabated, so that we will be well- positioned once that business sector returns to more robust levels. Product releases have included a new version of our Active Publishing Workstation and Public Information Book (PIB) Builder – an application used by bankers to rapidly assemble a detailed overview of selected companies. \nR eal-time Quotes\nInvestment Banking\nD ata Warehousing\n2001 FactSet acquires LionShares$^{®}$,an institutional ownership database, offering a wide scope of holdings data. | FactSet launches a state-of-the-art data center in Manchester, New Hampshire. | FactSet increases its European presence by opening the Frankfurt office. | Chicago office and training facility open.\n2002 Data Central application is released, allowing clients to easily store, create and manage proprietary time-series databases. | FactSet Marquee TM is released, allowing clients to combine traditional security-level analysis and streaming real-time news and quotes.\nFactSet hosts its first FactSet PMW User Conference,  helping PMW clients to get more value from FactSet’s Portfolio Analytics tools.\n7\n2000’s The millennium marked FactSet’s commitment to client needs with extensive product innovations. In addition to our core applications, such as  Data Downloading and Universal Screening, FactSet now offers real-time news and data, unparalled portfolio analysis and comprehensive sell-side solutions.  By expanding our product offerings and suite of data content, FactSet continues to provide new tools and more value to clients."}]}
+{"image": "doclay/doclay_46225.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Dew and Frost \nFog \nClouds \n12-15 \nFigure 12-21.  Radiation fog. \nFog is a cloud that is on the surface. It typically occurs when  the temperature of air near the ground is cooled to the air’s  dew point. At this point, water vapor in the air condenses and  becomes visible in the form of fog. Fog is classified according  to the manner in which it forms and is dependent upon the  current temperature and the amount of water vapor in the air. \nOn clear nights, with relatively little to no wind present,  radiation fog may develop.  [Figure 12-21]  Usually, it forms  in low-lying areas like mountain valleys. This type of fog  occurs when the ground cools rapidly due to terrestrial  radiation, and the surrounding air temperature reaches its  dew point. As the sun rises and the temperature increases,  radiation fog lifts and eventually burns off. Any increase in  wind also speeds the dissipation of radiation fog. If radiation  fog is less than 20 feet thick, it is known as ground fog. \nWhen a layer of warm, moist air moves over a cold surface,  advection fog is likely to occur. Unlike radiation fog, wind  is required to form advection fog. Winds of up to 15 knots \nLow clouds are those that form near the Earth’s surface and  extend up to about 6,500 feet AGL. They are made primarily  of water droplets but can include supercooled water droplets  that induce hazardous aircraft icing. Typical low clouds  are stratus, stratocumulus, and nimbostratus. Fog is also  classified as a type of low cloud formation. Clouds in this  family create low ceilings, hamper visibility, and can change  rapidly. Because of this, they influence flight planning and  can make visual flight rules (VFR) flight impossible. \nCloud type is determined by its height, shape, and  characteristics. They are classified according to the height of  their bases as low, middle, or high clouds, as well as clouds  with vertical development.  [Figure 12-22] \nClouds are visible indicators and are often indicative of  future weather. For clouds to form, there must be adequate  water vapor and condensation nuclei, as well as a method by  which the air can be cooled. When the air cools and reaches  its saturation point, the invisible water vapor changes into  a visible state. Through the processes of deposition (also  referred to as sublimation) and condensation, moisture  condenses or sublimates onto miniscule particles of matter  like dust, salt, and smoke known as condensation nuclei. The  nuclei are important because they provide a means for the  moisture to change from one state to another. \nIce fog occurs in cold weather when the temperature is  much below freezing and water vapor forms directly into ice  crystals. Conditions favorable for its formation are the same  as for radiation fog except for cold temperature, usually –25  °F or colder. It occurs mostly in the arctic regions but is not  unknown in middle latitudes during the cold season. \nSteam fog, or sea smoke, forms when cold, dry air moves over  warm water. As the water evaporates, it rises and resembles  smoke. This type of fog is common over bodies of water  during the coldest times of the year. Low-level turbulence  and icing are commonly associated with steam fog. \nUpslope fog occurs when moist, stable air is forced up sloping  land features like a mountain range. This type of fog also  requires wind for formation and continued existence. Upslope  and advection fog, unlike radiation fog, may not burn off with  the morning sun but instead can persist for days. They can  also extend to greater heights than radiation fog. \nallow the fog to form and intensify; above a speed of 15 knots,  the fog usually lifts and forms low stratus clouds. Advection  fog is common in coastal areas where sea breezes can blow  the air over cooler landmasses. On cool, clear, calm nights, the temperature of the ground  and objects on the surface can cause temperatures of the  surrounding air to drop below the dew point. When this  occurs, the moisture in the air condenses and deposits itself on  the ground, buildings, and other objects like cars and aircraft. \nThis moisture is known as dew and sometimes can be seen  on grass and other objects in the morning. If the temperature  is below freezing, the moisture is deposited in the form of  frost. While dew poses no threat to an aircraft, frost poses a  definite flight safety hazard. Frost disrupts the flow of air over  the wing and can drastically reduce the production of lift. It  also increases drag, which when combined with lowered lift  production, can adversely affect the ability to take off. An  aircraft must be thoroughly cleaned and free of frost prior  to beginning a flight. "}]}
+{"image": "doclay/doclay_68165.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Figure 4-8 shows the difference between VMs and containers.\nFigure 4-8 Difference between virtual machines and containers 3\nA key characteristic of a container is that it is small and fast because it uses some of the  underlying host operating system’s resources to run rather than containing a whole OS of its  own. As such, many more containers can be placed on hardware than VMs. Furthermore,  their lightweight nature enables a radically different approach to how they are managed and  scaled, which align perfectly with the needs of cloud-native applications. \nContainerization is the act of readying an application for distribution in a container by  packaging its various runtime components together. These components include the relevant  configuration files, libraries, and software dependencies. The result is a container image that  can then be run on a container platform. For more information about this process, see this  YouTube video.\nThe following sections describe the basic container concepts.\nA container image is the base for every container that you want to run. Container images are  built from a  Docker file , which is a text file that defines how to build the image and what build  artifacts to include in it, such as the app, the app’s configuration, and its dependencies. \nImages are normally made from other images, making them quicker to build. Let someone  else do the bulk of the work on an image and then tweak it for your use.\nA container is a running instance of a container image. You can make multiple containers  from the same image. For example, you might do this to create a set of replicas to scale a  container horizontally. Every container is created from an image, so a container is a packaged  app with all of its dependencies, and the app can be moved between environments and run  without changes. Unlike VMs, the running container does not need to virtualize a device, its  operating system, and the underlying hardware. Only the app code, run time, system tools,  libraries, and settings are packaged inside the container. Containers run as isolated  processes on Linux compute hosts and share the host operating system and its hardware  resources. This approach makes a container much more lightweight, portable, and efficient  than a VM, and many more containers can be run on a hosts’ resources than can VMs.\nContainer image \nContainer\n3 Source:  https://www.docker.com/what-container\n106  Accelerating Modernization with Agile Integration\n/ Ŷ Ĩ ƌ Ă Ɛ ƚ ƌ Ƶ Đ ƚ Ƶ ƌ Ğ  , Ž Ɛ ƚ K ^ Ž Đ Ŭ Ğ ƌ  Ž Ŷ ƚ Ă ŝ Ŷ Ğ ƌ  ŝ Ŷ Ɛ ͬ > ŝ ď Ɛ  9 L U W X D O 0 D F K L Q H V & R Q W D L Q H U V Ɖ Ɖ  / Ŷ Ĩ ƌ Ă Ɛ ƚ ƌ Ƶ Đ ƚ Ƶ ƌ Ğ  , LJ Ɖ Ğ ƌ ǀ ŝ Ɛ Ž ƌ  s D ' Ƶ Ğ Ɛ ƚ K ^ ŝ Ŷ Ɛ ͬ > ŝ ď Ɛ  Ɖ Ɖ  Ɖ Ɖ  s D ' Ƶ Ğ Ɛ ƚ K ^ ŝ Ŷ Ɛ ͬ > ŝ ď Ɛ  Ɖ Ɖ  Ɖ Ɖ  Ž Ŷ ƚ Ă ŝ Ŷ Ğ ƌ  ŝ Ŷ Ɛ ͬ > ŝ ď Ɛ  Ɖ Ɖ  Ž Ŷ ƚ Ă ŝ Ŷ Ğ ƌ  ŝ Ŷ Ɛ ͬ > ŝ ď Ɛ  Ɖ Ɖ  Ž Ŷ ƚ Ă ŝ Ŷ Ğ ƌ  ŝ Ŷ Ɛ ͬ > ŝ ď Ɛ  Ɖ Ɖ "}]}
+{"image": "doclay/doclay_72338.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Part I\nITEM 1. BUSINESS, continued\nPackaging and Specialty Plastics The packaging and specialty plastics product line specializes in resins and films used in packaging and industrial polymer applications,\nElectronics and Imaging The electronics and imaging product line supplies differentiated materials and systems for consumer electronics, photovoltaics (\"PV\"),\nIndustrial Biosciences The industrial biosciences product line offers a broad portfolio of bio-based products, including enzymes that add value and functionality to\nNutrition and Health The nutrition and health product line offers a wide range of sustainable, bio-based ingredients, providing innovative solutions including the\nSafety and Construction The safety and construction product line offers innovation engineered products and integrated systems for a number of industry verticals\nTransportation and Advanced Polymers The transportation and advanced polymers product line offers a broad range of polymer-based materials and expert application development\nSales by geographic region are included within Part II, Item 7 \"Management's Discussion and Analysis of Financial Condition and Results of Operations\", \"Analysis of Operations\" and Note 22 to the Consolidated Financial Statements.\nSee Note 5 to the Consolidated Financial Statements for net sales by major product line.\nTransportation and Advanced Polymers The transportation and advanced polymers product line offers a broad range of polymer-based materials and expert application development assistance to enhance the performance, reduce the total system cost and optimize the sustainability of their products. The portfolio of high performance renewably-sourced and sustainable polymers includes engineering resins, adhesives, lubricants and parts used by customers to fabricate components for mechanical, chemical and electrical systems. Key brands and technologies include DuPont™ Zytel ® long chain nylon polymers, Zytel$^{®}$ HTN nylon resins, Zytel$^{®}$ nylon resins, Crastin$^{®}$ PBT polymer resins, Rynite$^{®}$ PET polymer resins, Delrin$^{®}$ acetal resins, Hytrel ®  polyester thermoplastic elastomer resins, Vespel ® parts and shapes, Vamac ® ethylene acrylic elastomer and Kalrez ® perfluoroelastomer.\nSafety and Construction The safety and construction product line offers innovation engineered products and integrated systems for a number of industry verticals including construction, worker safety, energy, oil and gas and transportation. The product line addresses the growing global needs of businesses, governments, and consumers for solutions that make life safer, healthier and better. Key brands and technologies include DuPont™ Kevlar$^{® }$fiber, DuPont™ Nomex$^{®}$ fiber and paper, DuPont™ Tyvek$^{®}$ protective materials, DuPont™ Tychem$^{®}$ protective suits and DuPont™ Corian$^{®}$ solid and quartz surfaces.\nNutrition and Health The nutrition and health product line offers a wide range of sustainable, bio-based ingredients, providing innovative solutions including the wide-range of DuPont™ Danisco ® food ingredients such as cultures and probiotics, notably Howaru$^{®}$, pharmaceutical excipients, emulsifiers, texturants, natural sweeteners such as Xivia®, Supro® soy-based food ingredients, and pharmaceutical ingredients for the formulation of excipients. These ingredients hold leading market positions based on industry leading innovation, knowledge and experience, relevant product portfolios and close-partnering with the world's food manufacturers and pharmaceutical companies. In November 2016, Historical DuPont announced an investment to expand probiotics production capacity in the United States, due to the rapidly growing global demand for probiotics. Phase one was complete as of the end of 2017. The second phase represents an investment of approximately $100 million to increase Historical DuPont's probiotics production capacity by an additional 70 percent and is expected to be complete in the first quarter of 2019.\nIndustrial Biosciences The industrial biosciences product line offers a broad portfolio of bio-based products, including enzymes that add value and functionality to processes and products across a broad range of markets such as animal nutrition, detergents, food manufacturing, ethanol production and industrial applications. The product line also includes DuPont™ Sorona ® PTT renewably sourced polymer for use in carpet and apparel fibers and clean technologies offerings to help reduce sulfur and other emissions, formulate cleaner fuels, and dispose of liquid waste.\nElectronics and Imaging The electronics and imaging product line supplies differentiated materials and systems for consumer electronics, photovoltaics (\"PV\"), displays and advanced printing that enable superior performance and lower total cost of ownership for customers. The company targets growth opportunities in circuit and semiconductor fabrication and packaging materials, PV materials, display materials, packaging graphics, and digital printing.\nPackaging and Specialty Plastics The packaging and specialty plastics product line specializes in resins and films used in packaging and industrial polymer applications, sealants and adhesives and sporting goods. Key brands and technologies include DuPont™ Surlyn$^{®}$ ionomer resins, Bynel$^{®}$ coextrudable adhesive resins, Elvax$^{®}$ EVA resins, Nucrel$^{® }$Elvaloy$^{®}$polymer modifiers and Elvaloy$^{®}$ copolymer resins.\n5"}]}
+{"image": "doclay/doclay_61988.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "I 1111111111111111 11111 1111111111 11111 111111111111111 IIIII IIIIII IIII IIII IIII \n1111111111111111 11111 1111111111 11111 111111111111111 IIIII IIIIII IIII IIII IIII  US009285679B2 \n(IO)  Patent No.:  US 9,285,679 B2 \n(45)  Date of Patent:  Mar.15,2016 \nc12)  United States Patent  Tsuchimura et al. \n(54)  ACTINIC RAY-SENSITIVE OR  RADIATION-SENSITIVE COMPOSITION,  AND RESIST FILM, RESIST-COATED MASK  BLANKS, RESIST PATTERN FORMING  METHOD AND PHOTO MASK EACH USING  THE COMPOSITION \n(71)  Applicant:  FUJIFILM CORPORATION,  Tokyo  (JP) \n(72)  Inventors:  Tomotaka Tsuchimura,  Shizuoka (JP);  Takuya Tsuruta,  Shizuoka (JP);  Takeshi Inasaki,  Shizuoka (JP);  Koutarou Takahashi,  Shizuoka (JP) \n(73)  Assignee:  FUJIFILM Corporation,  Tokyo (JP) \n( *)  Notice:  Subject to any disclaimer, the term of this  patent is extended or adjusted under 35  U.S.C. 154(b) by  O  days. \n(21)  Appl. No.:  14/497,560 \n(22)  Filed:  Sep.26,2014 \n(63)  Continuation of application No. PCT/JP2013/058852,  filed on Mar. 26, 2013. \n(51)  Int. Cl. \n(65)  Prior Publication Data \n(30)  Foreign Application Priority Data \nUS 2015/0010855 Al  Jan. 8, 2015  Related U.S. Application Data \nUS 2015/0010855 Al  Jan. 8, 2015  Related U.S. Application Data \nThere is provided an actinic ray-sensitive or radiation-sensi› tive composition containing  (a)  a compound represented by  the formula ( al) capable of generating an acid having a size of  200  A $^{3 }$or more in volume and (~) a compound capable of  generating an acid upon irradiation with an actinic ray or  radiation, and the formula ( al) is defined as herein, \nPrimary Examiner  - Anca Eoff \n(74)  Attorney, Agent, or Firm  - Sughrue Mion, PLLC \n(Continued) \nOffice Action dated Sep. 9, 2014 issued by the Japanese Patent Office  in counterpart Japanese Application No.2012-078094. \nSeth Kruger et al., \"Can Acid Amplifiers Help Beat the Resolution,  Line Edge Roughness, and Sensitivity Trade-Off?\", Japanese Journal  of Applied Physics, 49, Apr. 20, 2010, pp. 041602-1-041602-5.  Kazuaki  Kudo  et  al.,  \"3-Phenyl-3,3-ethylenedioxy-l-propyl  Sulfonates as Acid Amplifiers to Enhance the Photosensitivity of  Positive-Working Photoresists\", Chemistry of Materials, 11, Jul. 7,  1999,pp.2119-2125. \nCommunication issued on Mar. 1, 2015 by the Korean Intellectual  Property Office in related KR application No. 10-2014-7026957.  International Search Report dated Jun. 25, 2013 issued in Interna› tional Application No. PCT/JP2013/058852 (PCT/ISA/210).  Written Opinion dated Jun. 25, 2013 issued in International Appli› cation No. PCT/JP2013/058852 (PCT/ISA/237). \nKruger, S.A., Riggings, C., Cardineau, B., Younkin,  T.  R., Brainard,  R.L. -Catalytic andAutocatalytic Mechanisms of Acid Amplifiers for  Use in EUV Photoresists, Chem. Mater, 2010, 22, pp. 5609-5616.*  Communication issued on Mar. 10, 2015 by the Japanese Patent  Office in related application No. 2012072540. \n(Continued) \n(Continued) \nand a resist film formed using the actinic ray-sensitive or  radiation-sensitive composition, a resist-coated mask  blanks coated with the resist film, a resist pattern form› ing method comprising exposing the resist film and  developing the exposed film, a photomask obtained by  exposing and developing the resist-coated mask blanks,  a method for manufacturing an electronic device, com› prising the resist pattern forming method and an elec› tronic device manufactured by the manufacturing  method of an electronic device. \n(52)  U.S. Cl.  CPC ................  G03F  71027  (2013.01);  C08F  12122  (2013.01);  C08F  12124  (2013.01);  C08F  12126  (2013.01);  C08F  12130  (2013.01);  C08F  12132  (2013.01);  C08F  212114  (2013.01);  C09D  125118  (2013.01);  G03F 1100  (2013.01);  G03F  1120  (2013.01);  G03F  1122  (2013.01);  G03F  71004  (2013.01);  G03F  710045  (2013.01);  G03F  710382  (2013.01);  G03F  710388  (2013.01);  G03F  710392  (2013.01);  G03F  710397  (2013.01);  G03F  712037  (2013.01);  G03F  712039  (2013.01) \n(58)  Field of Classification Search  CPC .......... G03F 7/004; G03F 7/027; G03F 7/039  See application file for complete search history. \n(56)  References Cited \nU.S. PATENT DOCUMENTS \nFOREIGN PATENT DOCUMENTS \nOTHER PUBLICATIONS \n(57)  ABSTRACT \n36 Claims, No Drawings \nMar. 27, 2012  Mar. 29, 2012  (JP) ................................. 2012-072540  (JP) ................................. 2012-078094 \nG03F  71039  G03F  71028  G03F  71027  C08F  12124  G03F  71004  G03F  71038  G03F 1100  G03F  1120  G03F  1122  G03F  7120  C08F 12122  C08F 12126  C08F 12130  C08F 12132  C08F 212114  C09D 125118  (2006.01)  (2006.01)  (2006.01)  (2006.01)  (2006.01)  (2006.01)  (2012.01)  (2012.01)  (2012.01)  (2006.01)  (2006.01)  (2006.01)  (2006.01)  (2006.01)  (2006.01)  (2006.01) \n5,082,755 A *  1/1992 Liu ................................... 430/5  2001/0044054 Al* 11/2001 Kaneko et al ..................... 430/5  2003/0027061 Al  2/2003 Cameron et al. \nJP  JP  8-248561 A  11-158118 A  9/1996  6/1999 \n(al)  0  0  II  A-S-0  II  r  r  )lR.  0  R2  H  Rs "}]}
+{"image": "doclay/doclay_66551.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "230 304 372 466 587 676 231 305 374 469 591 677 233 308 377 474 599 678 234 309 378 475 602 680 235 313 383 476 607 687 237 314 384 477 609 690 239 315 385 478 610 691 242 319 386 479 612 694 245 320 391 482 613 699 246 321 393 487 614 701 247 322 394 493 618 706 250 323 395 499 619 707 252 325 396 503 621 713 253 326 398 505 622 715 254 327 402 508 625 716 255 331 403 511 628 717 257 332 405 512 630 719 258 335 407 520 631 720 259 339 413 522 632 721 260 340 416 523 633 723 261 341 417 524 634 726 262 344 419 525 635 727 265 345 424 527 639 728 266 346 426 528 644 729 267 347 429 529 645 734 268 353 431 533 649 735 270 354 433 534 650 737 273 355 435 540 653 739 278 358 436 542 655 740 279 359 438 543 656 742 282 360 443 544 657 745 284 361 446 545 658 748 285 363 447 546 659 749 286 364 449 551 661 752 290 365 452 556 662 754 293 366 453 558 663 757 296 367 458 568 664 759 766 898 961 1062 1196 1312 768 902 966 1063 1204 1313 769 903 967 1065 1205 1314 772 906 968 1066 1208 1316 773 908 970 1067 1209 1322 774 910 971 1068 1212 1324\nCopy right 2012 CD Technologies Asia, Inc. and Accesslaw, Inc. Philippine Law Encyclopedia 2011\n879"}]}
+{"image": "doclay/doclay_56594.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "and stored routines, 3665 and temporary tables, 3673 and time zones, 3674 and TIMESTAMP, 3654 and transactions, 3674, 3677 and triggers, 3665, 3678 and TRUNCATE TABLE, 3679 and user name length, 3679 and variables, 3679 and views, 3681 attribute demotion, 3659 attribute promotion, 3659 BLACKHOLE, 3655 circular, 4612 crashes, 3671 delayed, 3651 group, 3687 in NDB Cluster, 4609 (see also NDB Cluster replication) new features, 28 nondeterministic functions, 1689 relay log, 3599 replication metadata repositories, 3599 resource groups, 1008 row-based vs statement-based, 3585 safe and unsafe statements, 3590 semisynchronous, 3645 shutdown and restart, 3671, 3673 statements incompatible with STATEMENT format, 3586 thread states, 1854, 1855, 1856 timeouts, 3674 unexpected halt, 3632 with differing tables on source and replica, 3657 replication channel commands, 3593 compatibility, 3594 naming conventions, 3595 startup options, 3594 replication channel based filters, 3611 replication channels, 3592 REPLICATION CLIENT privilege, 1192 replication filtering options and case sensitivity, 3606 replication formats compared, 3585 replication functions asynchronous_connection_failover_add_managed(), 2783 asynchronous_connection_failover_add_source(), 2782 asynchronous_connection_failover_delete_managed(), 2784 asynchronous_connection_failover_delete_source(), 2782 replication implementation, 3584 replication limitations, 3654 replication metadata repositories, 3599 replication mode, 3475\n5530"}]}
+{"image": "doclay/doclay_62405.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "164 \nUS 9,869,931 B2 \n163 \nTABLE I-continued \nPolymer  (pbw)  Metal complex  (pbw)  Acid  generator  (pbw)  Quencher  (pbw)  7 Polymer 1 scandium(III) trifluoromethanesulfonate  (100)  (10.1)  8 Polymer 1 yttrium(III) trifluoromethanesulfonate  (100)  (11.2)  9 Polymer 1 lanthanum(III) trifluoromethanesulfonate  (100)  (10.2)  10 Polymer 1 neodymium(III) trifluoromethanesulfonate  (100)  (10.3)  11 Polymer 1 thulium(III) trifluoromethanesulfonate  (100)  (10.2)  12 Polymer 1 silver trifluoromethanesulfonate  (100)  (1.2)  13 Polymer 1 indium(III)  (100)  tris(trifluoromethanesulfonimide)  (12.2)  14 Polymer 1 barium(II)  (100)  bis(trifluoromethanesulfonimide)  (14.2)  15 Polymer 1 scandium(III)  (100)  tris(trifluoromethanesulfonimide)  (15.2)  16 Polymer 1 copper(II)  (100)  bis(trifluoromethanesulfonimide)  (8.5)  17 Polymer 1 hafnium(IV)  (100)  tetra(trifluoromethanesulfonimide)  (7.8)  18 Polymer 1 zirconium(IV)  (100)  tetra(trifluoromethanesulfonimide)  (8.6)  19 Polymer 1 zirconium(IV)  (100)  tetra(trifluoromethanesulfonimide)  (8.6)  20 Polymer 1 zirconium(IV)  (100)  tetra(trifluoromethanesulfonimide)  (8.6)  PAGl  (5.5)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  hafnium  carboxyethyl› acrylate  (1.0)  cesiwn  pivalate  (0.8)  Organic  solvent  (pbw)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  PGME (300)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200) \nResist  Polymer  Metal complex  (pbw)  (pbw)  21 Polymer 1 rubidium(!) 1,1,2,2,3,3- (100)  hexafluoropropane-1,3-disulfonimide  (8.6)  22 Polymer 1 strontium(II) bis(l ,1,2,2,3,3- (100)  hexafluoropropane-1,3-disulfonimide)  (8.6)  23 Polymer 1 barium(II) nonafluorobutanesulfonate  (100)  (6.0)  24 Polymer 1 barium(II) trifluoromethanesulfonate  (100)  (3.2)  25 Polymer 1 barium(II) bis(l ,1,2,2,3,3- (100)  hexafluoropropane-1,3-disulfonimide)  (6.5)  26 Polymer 1 barium(II)  (100)  bis (trifluoromethanesulfonemethide)  (7.0)  27 Polymer 1  barium pentafluorobenzenesulfonate  (100)  (6.5)  Acid  generator  Quencher  (pbw)  (pbw)  PAGl  Amine!  (5.5)  (1.3)  PAGl  Amine!  (5.5)  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Amine!  (1.3)  Organic  solvent  (pbw)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200)  PGMEA (1,000)  CyH (1,000)  GBL (200) \nTABLE 2 "}]}
+{"image": "doclay/doclay_30102.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "be periodic insertion and removal. In this case, one inserts a particle into the first well (when empty) at intervals of τ /α , and checks for occupancy of the final well at intervals of τ /β , removing the particle if the well is occupied.\nA preliminary study of the continuous-space model using periodic insertion and removal confirms that the three TASEP phases are again found. The density profiles under periodic and random particle transfer are very similar in the maximum current phase, where the density profile is insensitive to small changes in the insertion and removal rates. Small systematic differences do however appear in the other phases, as shown in Fig. 12.\nFIG. 12: Comparison of density profiles obtained using periodic (black) and random (red) insertion and removal, L = 100.\nAlthough our study strongly suggests the feasibility of a laboratory realization of the TASEP, a number of additional features would have to be included in the model, before a quantitative comparison with experiment could be made. The principal\n24\n46 48 50 52 54 i 0.57 0.575 0.58 α  = 1, β  = 1.4 maximum current phase\n0 20 40 60 80 100 0.5 1 α  = 2, β  = 1 maximum current phase\n0 20 40 60 80 100 i 0.04 0.08 0.12 ρ (i) α  = 0.1, β  = 1.4 low density phase\n0 20 40 60 80 100 0.9 0.93 0.96 ρ (i) periodic random α  = 2, β  = 0.1 high density phase"}]}
+{"image": "doclay/doclay_34782.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "and hence δk = 0 and the M1 transition is completely suppressed. In practice, E − = E + − δ E due to the small but nonzero transmission of the back mirror in the cavity. Since | δ E| ≪ E , | δk | ≈ | δ E / E| ≪ 1. Thus, although the M1 transition amplitude is not strictly zero, it is highly suppressed.\nWithout loss of generality, the quantities β , ζ , and M are assumed to be real. In general, the rate R$_{M}$ given by Eq. (1) includes terms proportional to β M (Stark-M1 interference) and βζ (Stark-PV interference).\nA careful choice of field geometry allows for additional suppression of undesirable Stark-M1 interference. From Eq. (3), it is evident that the Stark-PV interference is proportional to the rotational invariant\n︸︷︷︸ ︸ ︷︷ ︸ which is P-odd and T-even. In the present experimental apparatus the electric field, E , is applied orthogonally to the magnetic field, B , and collinearly with the axis of the linearly-polarized standing light wave, as shown in Fig. 2.\nThis geometry is such that the M1 and Stark-induced amplitudes are out of phase. Thus, they do not interfere and therefore do not produce spurious PV-mimicking ef- fects (see Section IV).\nFIG. 2: (color online) Orientation of fields for PV-Stark in- terference experiment and schematic of the present APV ap- paratus. Not shown is the vacuum chamber containing all the depicted elements, except the photomultiplier (PMT) and the photodiode (PD). PBC–power buildup cavity. Light is ap- plied collinearly with x .\nIn the ideal case where we neglect the apparatus im- perfections, the static magnetic and electric fields are B = B ˆ z and E = E ˆ x , respectively, and the light stand- ing wave has an electric field\nIII. PV SIGNATURE: IDEAL CASE\nTo obtain the PV term from the measured first- and second-harmonic transition rates, we first normalize the first-harmonic signals R [1] M by their second-harmonic\nFor an arbitrary polarization angle θ , all three Zee- man components of the transition, as shown in Fig. 3a, are present while scanning over the spectral profile of the transition. The first-harmonic signal due to Stark-PV in- terference has a characteristic signature: the sign of the oscillating terms for the two extreme components of the transition is opposite to that of the central component. The second-harmonic signal provides a reference for the lineshape since it is free from interference effects linear in E (Fig. 3b). With a non-zero DC component present in the applied electric field, a signature identical to that in the second harmonic will also appear in the first har- monic, Fig. 3c. The latter can be used to increase the first-harmonic signal above the noise, which makes the profile analysis more reliable.\nwhere R [ n ] M is the amplitude of the n th harmonic of the transition rate R$_{M}$ . The dominant Stark-induced con- tribution, which oscillates at twice the modulation fre- quency, is\nIn order to isolate the Stark-PV interference term from the dominant Stark-induced transition rate, we modulate the electric field: E = E$_{dc}$ + ˜ E$_{0}$ cos( ωt ), where ˜ E$_{0}$ is the modulation amplitude, ω is the modulation frequency, and E$_{dc}$ provides a DC bias. Then Eqs. (7) and (8) become\nwhere terms of order ζ 2 and higher are neglected, and δk = 0 is assumed.\nWith this field orientation (see Fig. 2), Eqs. (1) through (4) yield\n3\nOn the other hand, the amplitude R [1] M contains the Stark-PV interference term:\nE = E (sin θ ˆ y + cos θ ˆ z ) . (6)\nR [0] 0 = 4 E 2 ( β $^{2}$( ˜ E 2 0 + E 2 $_{dc}$) sin 2 θ + 4 ζβE$_{dc}$ sin θ cos θ ) , R [0] ± 1 = 2 E 2 β $^{2}$( ˜ E 2 0 + E 2 $_{dc}$) cos 2 θ − 4 ζβE$_{dc}$ sin θ cos θ .\nR [1] 0 = 8 E 2 ( β 2 ˜ E$_{0}$E$_{dc}$ sin 2 θ + ζβ ˜ E$_{0}$ sin θ cos θ ) , (12) R [1] ± 1 = 4 E 2 β 2 ˜ E$_{0}$E$_{dc}$ cos 2 θ − ζβ ˜ E$_{0}$ sin θ cos θ . (13)\nThe term R [0] M is a constant “background”:\n( E ︸︷︷︸ PV · B )[( E × E ) ︸ ︷︷ ︸ Stark · B ] , (5) which is P-odd and T-even. In the present experimentalR [2] 0 = 2 β 2 ˜ E 2 0 E $^{2}$sin 2 θ, (10) R [2] ± 1 = β 2 ˜ E 2 0 E 2 cos 2 θ. (11)\nR$_{M}$ = R [0] M + R [1] $_{M}$cos( ωt ) + R [2] $_{M}$cos(2 ωt ) , (9)\nR$_{0}$ = 4 E 2 ( β $^{2}$E$^{2}$sin 2 θ + 2 ζ βE sin θ cos θ ) , (7) R$_{±}$$_{1}$ = 2 2 β $^{2}$E$^{2}$cos2 θ − 2 ζ βE sin θ cos θ , (8)"}]}
+{"image": "doclay/doclay_36336.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Scattering Theory of Current-Induced Spin Polarization\narXiv:1001.1125v2 [cond-mat.mes-hall] 10 Feb 2010\nI. INTRODUCTION\nA. Electric generation of spin polarization\nPh. Jacquod 1\n$^{1}$Physics Department, University of Arizona, 1118 E. 4 th Street, Tucson, AZ 85721, USA\n(Dated: November 13, 2018)\nWe construct a novel scattering theory to investigate magnetoelectrically induced spin polariza- tions. Local spin polarizations generated by electric currents passing through a spin-orbit coupled mesoscopic system are measured by an external probe. The electrochemical and spin-dependent chemical potentials on the probe are controllable and tuned to values ensuring that neither charge nor spin current flow between the system and the probe, on time-average. For the relevant case of a single-channel probe, we find that the resulting potentials are exactly independent of the trans- parency of the contact between the probe and the system. Assuming that spin relaxation processes are absent in the probe, we therefore identify the local spin-dependent potentials in the sample at the probe position, and hence the local current-induced spin polarization, with the spin-dependent potentials in the probe itself. The statistics of these local chemical potentials is calculated within random matrix theory. While they vanish on spatial and mesoscopic average, they exhibit large fluctuations, and we show that single systems typically have spin polarizations exceeding all known current-induced spin polarizations by a parametrically large factor. Our theory allows to calculate quantum correlations between spin polarizations inside the sample and spin currents flowing out of it. We show that these large polarizations correlate only weakly with spin currents in external leads, and that only a fraction of them can be converted into a spin current in the linear regime of transport, which is consistent with the mesoscopic universality of spin conductance fluctuations. We numerically confirm the theory.\nPACS numbers: 72.25.Dc, 73.23.-b, 85.75.-d\nTwo purely electric mechanisms have been proposed to generate spin accumulations in electronic systems with spin-orbit interaction (SOI). They are current-induced spin polarization [1, 2] and the spin Hall effect [3, 4]. Both phenomena appear when a spin-orbit coupled con- ductor is traversed by an electric current. Current- induced spin polarization manifests itself in a weak bulk polarization of the electronic spins in a direction deter- mined by the electric current and the SOI, while the spin Hall effect manifests itself in a spin accumulation at the lateral edges of the sample. Though the resulting polar- izations are usually rather weak, both effects have been demonstrated experimentally [5–9]. They offer an elegant alternative to spin injection and manipulation with fer- romagnets, Zeeman fields or by optical means, and pave the way toward spintronic devices with purely electric control of electronic spins.\nA dual aspect of these magnetoelectric effects is that they are accompanied by spin currents, flowing either inside the sample or leaving it. Early analytical investi- gations of these spin currents have been devoted to cal- culations of bulk spin conductivities, but it was soon re- alized that the latter are not always related to physically relevant quantities. Local approaches based on classi- cal kinetic equations have been used to investigate the conversion of magnetoelectric spin accumulations at the edge of a spin-orbit coupled sample into spin currents leaving the sample [4, 10–14]. These quasiclassical the-\nTo that end we construct a spin-probe model , which connects local spin-dependent chemical potentials to those imposed on a nearby probe. In this way, we are able to express local current-induced spin polarizations in terms of transmission coefficients deriving from the scat- tering matrix. Focusing on chaotic ballistic mesoscopic systems, we then use random matrix theory [24, 25] to calculate the statistics of these polarizations. We find that, while the ensemble average polarization vanishes, it fluctuates from position to position (in a given sam- ple) and from sample to sample. For sufficiently large systems, the amplitude of these fluctuations by far ex- ceeds the magnitude of all current-induced polarizations investigated to date. Simultaneously, we show that this polarization is mostly uncorrelated with spin currents in\nories have been quite successful, however they neglect coherent effects and, in their present form, are not appro- priate to investigate local fluctuations and spatial corre- lations of spin polarization. Coherent mesoscopic effects on spin currents have recently attracted quite some the- oretical attention, both analytically [15–20] and numeri- cally [21, 22], in both diffusive and ballistic systems, while so far only mesoscopic fluctuations of sample-integrated spin polarizations in the diffusive regime have been inves- tigated [23]. At present, little is known about local coher- ent fluctuations of spin polarizations, the scale on which they occur, how they are correlated, and how they in- fluence spin currents and their fluctuations, neither have current-induced spin polarizations in chaotic ballistic sys- tems been investigated so far. It is the purpose of this ar- ticle to start filling these gaps, by investigating the mag- netoelectric generation of spin polarizations in ballistic mesoscopic samples."}]}
+{"image": "doclay/doclay_47372.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "EXPLANATORY NOTE \n(This note is not part of the Order) \nPart III of the Transport Act 2000 authorises the Secretary of State to make, amend or revoke a  trunk road charging scheme in respect of roads for which a strategic highways company is the  traffic authority, and which are carried by a bridge, or pass through a tunnel, of at least 600 metres  in length. Subject to the exceptions outlined in the Appointment of a Strategic Highways  Company Order 2015 (S.I. 2015/376), Highways England Company Limited (company number  9346363) was appointed as the highway authority for all highways within England for which the  Secretary of State was the highway authority immediately before that Order, which includes the  A282. Highways England Company Limited is also the traffic authority for these roads by virtue  of section 121A(1AB) of the Road Traffic Regulation Act 1984 (c. 27). \nThe A282 Trunk Road (Dartford-Thurrock Crossing Charging Scheme) Order 2013 (“the 2013  Order”) introduced the current charging scheme in respect of the roads carried by the Dartford  Crossing. The 2013 Order, by virtue of article 1(2), was to cease to have effect at the end of the  period of seven years from 1st October 2013. Article 3 of this Order removes that provision and,  instead, provides that the 2013 Order will remain in force indefinitely. \nA full impact assessment has not been produced for this instrument as it amends provision relating  to a charge and so, by virtue of section 22(4)(a) of the Small Business, Enterprise and  Employment Act 2015 (c. 26), is not a “regulatory provision” for the purpose of the Business  Impact Target pursuant to sections 21 and 23 to 25 of that Act. The impact assessment that  accompanied the 2013 Order is available on www.legislation.gov.uk, or a hard copy can be  obtained from Peter Steele at the Road Investment Strategy Futures Division, Department for  Transport, Great Minster House, 33 Horseferry Rd, London, SW1P 4DR. \nThis instrument is available on www.legislation.gov.uk. \n© Crown copyright 2020 \nPrinted and published in the UK by The Stationery Office Limited under the authority and superintendence of Jeff James,  Controller of Her Majesty’s Stationery Office and Queen’s Printer of Acts of Parliament. \n£4.90 \nUK202002061010 02/2020 19585 \nhttp://www.legislation.gov.uk/id/uksi/2020/126 \nISBN 978-0-11-119299-3"}]}
+{"image": "doclay/doclay_4405.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "INTERNATIONAL SEARCH REPORT\nInformation on patent family members\nInternational application No.\nForm PCT/ISA/21 0 (patent family annex) (July 201 9)\nPCT/SG201 9/05051 1"}]}
+{"image": "doclay/doclay_30742.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "distance from the surface, z ∗ , which is found from the condition m$_{e}$ − V ( z ∗ ) = µ , see Eq. (4). The value of µ is determined from the condition of global charge neutrality:\nwhere σ$_{+}$ and σ − are the areal densities of positive and negative charges accumulated at z < z$_{0}$ and z > z$_{0}$ respectively. Since calculated µ values are very close to m$_{e}$ , we use µ = m$_{e}$ for our estimates.\nAnother boundary condition follows from the requirement that far inside the star the electron charge density must completely compensate the positive charge density, i.e. ρ$_{ch}$ ( z → −∞ ) = 0, that means that k$_{Fe}$ ( z → −∞ ) ≡ k$_{F}$$_{0}$ = (3 π $^{2}$ρ$_{p}$$_{0}$ ) 1 / 3 and\ne ∞ ∫ −∞ [ ρ$_{p}$ ( z ) − ρ$_{e}$ ( z )] dz ≡ σ$_{+}$ + σ − = 0 , (7)\nV ( z → −∞ ) = √ k 2 F 0 + m 2 e − µ = √ (3 π $^{2}$ρ$_{p}$$_{0}$ ) 2 / 3 + m 2 e − µ . (8)\nThese conditions are sufficient to determine the electron density distribution ρ$_{e}$ ( z ). Unfor- tunately, no analytical solution can be found without further approximations, and therefore numerical methods must be applied.\nWe have performed numerical calculations for different values of the diffuseness parameter a ranging from 1 fm, typical for nuclear surfaces, up to 1 nm, typical for solid-state surfaces. As an example, in Fig. 1 we present results for a =5 fm which is rather close to a “sharp surface” limit. The upper, middle and lower panels show, respectively, the electron density, electric potential and electric field calculated for the given proton density (dashed line in the upper panel). One can clearly see the deviation of the electron density from the proton one in the layer of ± 50 fm around the surface. This gives rise to a sharp fall of the potential, and as a consequence, to a very strong electric field generated in this layer. The maximum of the field, about 1.5 MV/fm, is reached at z = z$_{0}$ . This value is almost 600 times higher than the critical electric field for spontaneous electron-positron pair production [19], E$_{c}$ = 2 m $^{2}$c$^{3}$/e ℏ = 0 . 0026 MV/fm=2 . 6 · 10 16 V/cm. However, in the considered system the pair production does not happen because all electron states with ϵ$_{e}$ ( k, z ) < m$_{e}$ are occupied and therefore Pauli- blocked.\nThis situation is clarified in Fig. 2, where the electron levels in a strong electric potential, − V ( z ), are shown schematically. As explained above, the negative potential inside the medium ( z < z$_{0}$ ) is generated by the charge separation at the surface. In the vacuum such\n4"}]}
+{"image": "doclay/doclay_77915.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\nAbschnitt 7 Kosten\n§ 80 Umfang der Kostenpflicht\n§ 81 Grundsatz der Kostenpflicht\n§ 82 Zeitpunkt der Kostenentscheidung\n§ 83 Kostenpflicht bei Vergleich, Erledigung und Rücknahme\n§ 84 Rechtsmittelkosten\n§ 85 Kostenfestsetzung\nAbschnitt 8 Vollstreckung\nUnterabschnitt 1\nKosten sind die Gerichtskosten (Gebühren und Auslagen) und die zur Durchführung des Verfahrens notwendigen Aufwendungen der Beteiligten. § 91 Abs. 1 Satz 2 der Zivilprozessordnung gilt entsprechend.\n(1) Das Gericht kann die Kosten des Verfahrens nach billigem Ermessen den Beteiligten ganz oder zum Teil auferlegen. Es kann auch anordnen, dass von der Erhebung der Kosten abzusehen ist. In Familiensachen ist stets über die Kosten zu entscheiden.\n(2) Das Gericht soll die Kosten des Verfahrens ganz oder teilweise einem Beteiligten auferlegen, wenn\n(3) Einem minderjährigen Beteiligten können Kosten in Kindschaftssachen, die seine Person betreffen, nicht auferlegt werden.\n(4) Einem Dritten können Kosten des Verfahrens nur auferlegt werden, soweit die Tätigkeit des Gerichts durch ihn veranlasst wurde und ihn ein grobes Verschulden trifft.\n(5) Bundesrechtliche Vorschriften, die die Kostenpflicht abweichend regeln, bleiben unberührt.\n1. der Beteiligte durch grobes Verschulden Anlass für das Verfahren gegeben hat;\n2. der Antrag des Beteiligten von vornherein keine Aussicht auf Erfolg hatte und der Beteiligte dies erkennen musste;\n3. der Beteiligte zu einer wesentlichen Tatsache schuldhaft unwahre Angaben gemacht hat;\n4. der Beteiligte durch schuldhaftes Verletzen seiner Mitwirkungspflichten das Verfahren erheblich verzögert hat;\n5. der Beteiligte einer richterlichen Anordnung zur Teilnahme an einem kostenfreien Informationsgespräch über Mediation oder über eine sonstige Möglichkeit der außergerichtlichen Konfliktbeilegung nach § 156 Absatz 1 Satz 3 oder einer richterlichen Anordnung zur Teilnahme an einer Beratung nach § 156 Absatz 1 Satz 4 nicht nachgekommen ist, sofern der Beteiligte dies nicht genügend entschuldigt hat.\nErgeht eine Entscheidung über die Kosten, hat das Gericht hierüber in der Endentscheidung zu entscheiden.\n(1) Wird das Verfahren durch Vergleich erledigt und haben die Beteiligten keine Bestimmung über die Kosten getroffen, fallen die Gerichtskosten jedem Teil zu gleichen Teilen zur Last. Die außergerichtlichen Kosten trägt jeder Beteiligte selbst.\n(2) Ist das Verfahren auf sonstige Weise erledigt oder wird der Antrag zurückgenommen, gilt § 81 entsprechend.\nDas Gericht soll die Kosten eines ohne Erfolg eingelegten Rechtsmittels dem Beteiligten auferlegen, der es eingelegt hat.\nDie §§ 103 bis 107 der Zivilprozessordnung über die Festsetzung des zu erstattenden Betrags sind entsprechend anzuwenden.\n- Seite 39 von 129 -"}]}
+{"image": "doclay/doclay_15404.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Fair Value Hierarchy Levels \n2013 ANNUAL REPORT 111\nFair values determined using valuation models (level 3 financial assets and liabilities) require the use of assumptions concerning  the amount and timing of estimated future cash flows and discount rates. In determining those assumptions, the company looks  primarily to readily observable external market inputs such as interest rate yield curves, currency rates, and price and rate  volatilities, as applicable. \nThere were no transfers between level 1 and level 2 in 2013 or 2012. \nFair values for financial instruments are determined by reference to quoted bid or ask prices, as appropriate. Where bid and ask  prices are unavailable, the closing price of the most recent transaction of that instrument is used. In the absence of an active  market, fair values are determined based on prevailing market rates for instruments with similar characteristics and risk profiles  or internal or external valuation models, such as option pricing models and discounted cash flow analysis, using observable  market inputs.\nLevel 2 financial assets and financial liabilities include foreign currency forward contracts, interest rate swap agreements, energy  derivatives, interests of others in consolidated funds and equity derivatives.\nThe following table summarizes the valuation techniques and key inputs used in the fair value measurement of level 2 financial  instruments:\nType of asset/liability Valuation technique(s) and key input(s) Foreign currency forward  contracts  Discounted cash flow model – forward exchange rates (from observable forward exchange rates at  the end of the reporting period) and discounted at credit adjusted rate Interest rate contracts  Discounted cash flow model – forward interest rates (from observable yield curves) and applicable  credit spreads discounted at a credit adjusted rate  Energy derivatives  Quoted market prices, or in their absence internal valuation models corroborated with observable  market data Interest of others in  consolidated funds  Adjusted public pricing\nDec. 31, 2013 Dec. 31, 2012 (MILLIONS) Level 1 Level 2 Level 3 Level 1 Level 2 Level 3 Financial assets Other financial assets Government bonds  $  41 $  138 $  — $  52 $  126 $  — Corporate bonds  20 299 — 59 179 — Fixed income securities  44 55 113 88 — 57 Common shares and warrants  838 1 1,919 423 — 1,611 Loans and notes receivables  — 23 8 — 25 10 Accounts receivable and other  131 343 689 — 112 656 $ 1,074 $ 859 $ 2,729 $ 622 $ 442 $ 2,334 Financial liabilities Accounts payable and other  $ 117 $ 1,046 $ 142 $ 262 $ 697 $ 328 Interests of others in consolidated funds  — 139 947 — 73 352 $ 117 $ 1,185 $ 1,089 $ 262 $ 770 $ 680\nAssets and liabilities measured at fair value on a recurring basis include $2,729 million (2012 – $2,334 million) of financial  assets and $1,089 million (2012 – $680 million) of financial liabilities which are measured at fair value using unobservable  valuation inputs or based on management’s best estimates. The following table categorizes financial assets and liabilities, which  are carried at fair value, based upon the fair value hierarchy levels:"}]}
+{"image": "doclay/doclay_65738.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "- receive input data divided into a plurality of blocks;\n- overfit a first neural encoder network for a first block of the data based on a baseline encoder network;\n- encode the first block by the first overfitted neural encoder network\n- overfit a second neural encoder network for at least one subsequent block of the data based on a combination of neural networks used for previous blocks and/or the baseline encoder network; and\n- encode the at least one subsequent block by the second overfitted neural encoder network.\n- determine which one of the overfitted neural encoder networks performs the best; and\n- select such overfitted neural encoder network for a current block of the data.\n7. The apparatus of claim 6, further being caused to:\n8. The apparatus according to claim 7, wherein the performance is determined according to one or both of the following aspects: a reconstruction quality or a bitrate.\n9. The apparatus according to any of the claims 6 to 8, wherein the data comprises image data, video data, or audio data.\n10.An apparatus comprising at least one processor, memory including computer program code, the memory and the computer program code configured to, with the at least one processor, cause the apparatus to:\n- receive a block residual defining a difference between an original block of data and a decoded block of the data;\n- based on the residual, recover the original block to be used as ground- truth data; and\n- overfit the neural decoder network based on the ground-truth data.\n11.The apparatus according to claim 10, further being caused to\n- receive a weight residual from a transmitter, the weight residual defining the difference between weights of the decoder before and after an overfitting."}]}
+{"image": "doclay/doclay_14692.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Business Information\npage 2\nThe Bank has loans outstanding to borrowers in all industries within its PSA. Any adverse economic or other  conditions affecting these industries would also likely have an adverse effect on the local workforce, other local businesses,  and individuals in the community that have entered into loans with the Bank. However, management believes that due to the  diversified mix of industries located within the Bank’s PSA, adverse changes in one industry may not necessarily affect other  area industries to the same degree or within the same time frame. The Bank’s PSA is also subject to both local and national  economic conditions and fluctuations. While most loans are made within the PSA, residential mortgage loans are originated  outside the PSA, and the Bank has from time to time purchased loans and loan participations from outside its PSA.\nThe Bank makes loans for commercial, financial and agricultural purposes, as well as for real estate mortgages, real  estate acquisition, construction and development and consumer purposes. While there are certain risks unique to each type of  lending, management believes that there is more risk associated with commercial, real estate acquisition, construction and  development, agricultural and consumer lending than with residential real estate mortgage loans. To help manage these risks,  the Bank has established underwriting standards used in evaluating each extension of credit on an individual basis, which are  substantially similar for each type of loan. These standards include a review of the economic conditions affecting the  borrower, the borrower’s financial strength and capacity to repay the debt, the underlying collateral and the borrower’s past  credit performance. These standards are used to determine the creditworthiness of the borrower at the time a loan is made and are monitored periodically throughout the life of the loan. See “Legislative and Regulatory Changes” for a discussion of  regulatory guidance on commercial real estate lending. \nLoans and Loan Concentrations \nServices \nThe Bank offers checking, savings, transaction deposit accounts and certificates of deposit, and is an active residential  mortgage lender in its primary service area (“PSA”). The Bank’s PSA includes the cities of Auburn and Opelika, Alabama  and nearby surrounding areas in East Alabama, primarily in Lee County. The Bank also offers commercial, financial,  agricultural, real estate construction and consumer loan products and other financial services. The Bank is one of the largest providers of automated teller services in East Alabama and operates ATM machines in 13 locations in its PSA. The Bank  offers Visa ® Checkcards, which are debit cards with the Visa logo that work like checks but can be used anywhere Visa is  accepted, including ATMs. The Bank’s Visa Checkcards can be used internationally through the Cirrus ® network. The Bank  offers online banking and bill payment services through its Internet website,  www.auburnbank.com .\nThe Company’s principal executive offices are located at 100 N. Gay Street, Auburn, Alabama 36830, and its  telephone number at such address is (334) 821-9200. The Company maintains an Internet website at  www.auburnbank.com . The Company is not incorporating the information on that website into this report, and the website and the information  appearing on the website are not included in, and are not part of, this report. The Company files annual, quarterly and current  reports, proxy statements, and other information with the SEC. You may read and copy any document we file with the SEC at  the SEC’s public reference room at 100 F Street, N.E., Washington, DC 20549. Please call the SEC at 1-800-SEC-0330 for  more information on the operation of the public reference rooms. The SEC maintains an Internet site that contains reports,  proxy, and other information Our SEC filings are also available to the public free of charge from the SEC’s web site at  www.sec.gov .\nAuburn National Bancorporation, Inc. (the “Company”) is a bank holding company registered with the Board of  Governors of the Federal Reserve System (the “Federal Reserve”) under the Bank Holding Company Act of 1956, as  amended (the “BHC Act”). The Company was incorporated in Delaware in 1990, and in 1994 it succeeded its Alabama  predecessor as the bank holding company controlling AuburnBank, an Alabama state member bank with its principal office  in Auburn, Alabama (the “Bank”). The Company and its predecessor have controlled the Bank since 1984. As a bank holding  company, the Company may diversify into a broader range of financial services and other business activities than currently  are permitted to the Bank under applicable laws, regulations and rules. The holding company structure also provides greater  financial and operating flexibility than is presently permitted to the Bank. \nBUSINESS INFORMATION"}]}
+{"image": "doclay/doclay_65827.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "whiteboard items (e.g. by transcribing digital ink on a whiteboard canvas and creating to-do items from the transcription) and, as a result, savings in time and utilization of computing resources can be realized. Other technical benefits not specifically mentioned herein can also be realized through implementations of the disclosed subject matter.\n[0006] In order to provide the technical benefits described above, and potentially others, a digital whiteboard application is configured to present a user interface (“UI”) that includes a whiteboard canvas (“canvas”) upon which heterogenous objects can be placed in a free-form manner. For example, the canvas might be configured to accept digital ink in the form of text or shapes, sticky notes (“notes”), images, documents, and other types of digital objects. The objects can be placed anywhere on the canvas, and the canvas can grow in order to accommodate the objects.\n[0007] The canvas can also present dynamic templates and regions. Dynamic templates can include one or more regions that together provide structure to objects contained therein, and behavior that is typically based upon a purpose or desired outcome. For example, and without limitation, a template can be defined and placed on a whiteboard canvas that includes regions configured for performing a retrospective analysis for a project (e.g. what went well, what didn’t go well, what can be improved). As another example, a template might include regions for tracking the status of to-do items in a project (e.g. not started, in-progress, or complete). Templates including other types and arrangements of regions for performing other types of functions can be utilized in other configurations.\n[0008] Objects, such as those on a canvas or contained within regions of a template, have associated logical representations. The logical representation for an object maintains semantic data (e.g. metadata) about the object such as, for example, data indicating the type of object, the creator, the creation date and time, and/or other types of information. Templates and regions can modify the logical representations associated with objects in order to create semantic context for the objects.\n[0009] Templates and regions can also generate visual representations of objects based upon their associated logical representations. For example, and without limitation, a template might define a region on the canvas that is configured to present an object in a first visual representation (e.g. in a particular color, format, or arrangement) that is based upon the logical representation associated with the object. In this example, a user might create an object (e.g. a note containing text) on the canvas and move the object (e.g. by “dragging” the object) to the region. In response thereto, the template or the region can modify the logical representation associated with the object and present the object in the first region"}]}
+{"image": "doclay/doclay_37597.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Annex 2. Declaration on Honour on exclusion and selection criteria \nI – SITUATION OF EXCLUSION CONCERNING THE PERSON \nThe undersigned [ insert name of the signatory of this form ], representing: \nThe person is not required to submit the declaration on exclusion criteria if the same declaration  has already been submitted for the purposes of another award procedure of the same contracting  authority$^{31}$, provided the situation has not changed, and that the time that has elapsed since the  issuing date of the declaration does not exceed one year. \nIn this case, the signatory declares that the person has already provided the same declaration on  exclusion criteria for a previous procedure and confirms that there has been no change in its  situation:\n(1) declares that the above-mentioned person is in one of the following  situations:  YES  NO  (a) it is bankrupt, subject to insolvency or winding-up procedures, its assets are  being administered by a liquidator or by a court, it is in an arrangement with  creditors, its business activities are suspended or it is in any analogous situation  arising from a similar procedure provided for under Union or national law;  (b) it has been established by a final judgement or a final administrative decision  that the person is in breach of its obligations relating to the payment of taxes or  social security contributions in accordance with the applicable law;  (c) it has been established by a final judgement or a final administrative decision  that the person is guilty of grave professional misconduct by having violated  applicable laws or regulations or ethical standards of the profession to which  the person belongs, or by having engaged in any wrongful conduct which has \n( only  for  natural  persons )  himself or herself  ( only for legal persons ) the following legal person: ID or passport number: (‘the person’)  Full official name: Official legal form: Statutory registration number : Full official address:  VAT registration number: (‘the person’) \nDate of the declaration  Full reference to previous procedure \n$^{31}$ The same EU institution, agency, body or office.\nPage  39  of  51"}]}
+{"image": "doclay/doclay_18126.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Ending Occupancy Levels and Average Base Minimum Rent per Square Foot.  Ending occupancy is the percentage of gross  leasable area, or GLA, which is leased as of the last day of the reporting period. We include all company owned space except  for regional mall anchors and regional mall majors in the calculation. Base minimum rent per square foot is the average base  minimum rent charge in effect for the reporting period for all tenants that would qualify to be included in ending occupancy.\nTotal Sales per Square Foot.  Total sales include total reported retail tenant sales at owned GLA (for mall and freestanding  stores with less than 10,000 square feet) in the regional malls and all reporting tenants at the Premium Outlets and The Mills.  Retail sales at owned GLA affect revenue and profitability levels because sales determine the amount of minimum rent that can  be charged, the percentage rent realized, and the recoverable expenses (common area maintenance, real estate taxes, etc.) that  tenants can afford to pay.\nThe following are selected key operating statistics for certain of our international properties  (1) .\n(1) Does not include statistics for European operations as we sold our entire interest in Gallerie Commerciali Italia, S.p.A., or GCI, on January 9, 2012.\n(2) Information supplied by the managing venture partner.\n(3) Does not include our centers in Mexico (Premium Outlets Punta Norte), Malaysia (Johor Premium Outlets), and South Korea (Yeoju and Paju Premium Outlets).\n(4) Does not include Sendai-Izumi Premium Outlets in Japan as the property was closed for repair due to damages from the earthquake in Japan in March 2011.  The center re-opened on June 17, 2011.\nThe preparation of financial statements in conformity with accounting principles generally accepted in the United States of  America, or GAAP, requires management to use judgment in the application of accounting policies, including making estimates  and assumptions. We base our estimates on historical experience and on various other assumptions believed to be reasonable  under the circumstances. These judgments affect the reported amounts of assets and liabilities, disclosure of contingent assets  and liabilities at the dates of the financial statements and the reported amounts of revenue, and expenses during the reporting  periods. If our judgment or interpretation of the facts and circumstances relating to various transactions had been different,  it is possible that different accounting policies would have been applied resulting in a different presentation of our financial  statements. From time to time, we reevaluate our estimates and assumptions. In the event estimates or assumptions prove to  be different from actual results, adjustments are made in subsequent periods to reflect more current information. Below is a  discussion of accounting policies that we consider critical in that they may require complex judgment in their application or require  estimates about matters that are inherently uncertain. For a summary of our significant accounting policies, see Note 3 of the  Notes to Consolidated Financial Statements.\nCritical Accounting Policies\n● We, as a lessor, retain substantially all of the risks and benefits of ownership of the investment properties and account  for our leases as operating leases. We accrue minimum rents on a straight-line basis over the terms of their respective  leases. Substantially all of our retail tenants are also required to pay overage rents based on sales over a stated base  amount during the lease year. We recognize overage rents only when each tenant’s sales exceed its sales threshold.\n2011 Annual Report 13\nInternational Property Data\n2011  % Change  2010  % Change  2009 International Premium Outlets (2) (3) Ending Occupancy   100.0% 99.8% 99.6% Comparable Sales per Square Foot  (4) ¥ 85,488  –4.1% ¥ 89,139  –5.6%  ¥94,468 Average Base Minimum Rent per Square Foot  ¥ 4,834 1.4% ¥ 4,766 1.1% ¥ 4,714"}]}
+{"image": "doclay/doclay_67229.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "shall not allow forest products to be laden aboard a vessel clearing for a foreign port until the shipper shall produce a receipt from an internal-revenue official showing that the forest ch arges upon such products have been paid or a certificate from a proper official of the Bureau of Forestry showing that the products were taken from private lands properly registered in the Bureau of Forestry.\n[165-1, 2.]\nSECTION  1395 . Lading of Fibrous Products . — A collector of customs shall not permit abacá, maguey, or sisal or other fibrous products for which standard grades have been established by the Director of Agriculture to be laden aboard a vessel clearing for a f oreign port, unless the shipment conforms to the requirements of law relative to the shipment of such fibers.\nSECTION  1396 . Detention of Warlike Vessel Containing Arms and Munitions . — Collectors shall detain any vessel of commercial register manifestly built for warlike purposes and about to depart from the Philippine Islands with a cargo consisting principally of  arms and munitions of war when the number of men shipped on board or other circumstances render it probable that such vessel is intended to be employed by the owner or owners to cruise or commit hostilities upon the subjects, citizens, or property of any f oreign prince or state, or of any colony, district, or people with whom the United States are at peace, until the decision of the Governor-General of the Islands be had thereon, or until the owner or owners shall give bond or security, in double the valu e of the vessel and cargo, that she will not be so employed, if in the discretion of the collector of customs such bond will prevent the violation of the provisions of this section.\n[355-114.]\nImportation of Merchandise in General \nSECTION  1397 . Merchandise to be Imported Only Through Customhouse . — All merchandise introduced into the Philippine Islands, whether subject to duty or not, shall be entered through a customhouse at a port of entry.\n[355-397.]\nSECTION  1398 . Special Surveillance for Protection of Customs and Prevention of Smuggling . — In order to prevent smuggling and to secure the collection of the legal duties the customs service shall exercise surveillance over the coast, beginning when a vess el enters Philippine waters and concluding when the merchandise imported therein has been legally passed through the\nCopyright 2012 CD Technologies Asia, Inc. and Accesslaw, Inc. Philippine Law Encyclopedia 2011\n410\nARTICLE  VII"}]}
+{"image": "doclay/doclay_6467.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Management’s goal is to limit expenditures to those that directly con- tribute to increase the efficiency and profitability of the Corporation. This control over other operating expenses has been an important factor con- tributing to the increase in earnings in recent years. The Corporation’s effi- ciency ratio, which is the ratio of other operating expenses to the sum of net interest income and other income, improved to 41.81% for 2001 as compared to 46.95% and 46.33% for 2000 and 1999, respectively.\nThe increase in operating expenses for 2001 is mainly the result of the investments made in new technology and infrastructure to provide the lat- est in delivery channels for its commercial and consumer lending business, and to support the significant growth in earning assets.The occupancy and equipment category consists of expenses associated with premises, office and computer equipment, and other automated banking equipment. The increase in the past three years results also from the enhancement of hard- ware and software through system conversions, which have enabled the Corporation to offer new products, and improve customer service and portfolio servicing.\nThe salary and benefits category was affected by annual increases in salary and fringe benefits and an increase of 3% in the number of employees.\nThe provision for income tax amounted to $20 million (or 19% of pre-tax earnings) for 2001 as compared to $15 million (or 18% of pre-tax earnings) in 2000, and $7 million (or 11% of pre-tax earnings) in 1999. The increase in the effective tax rate results from the growth in the residential real estate and commercial line of business. The Corporation has maintained an effective tax rate lower than the statutory rate of 39% mainly by invest- ing in obligations exempt from federal and Puerto Rico income tax. For additional information relating to income taxes, see Note 25 of the Corporation’s financial statements - “Income Taxes.”\nIncome Tax Expense The provision for income tax amounted to $20 million (or 19% of pre-tax >.\nOther Operating Expense Other operating expenses amounted to $121 million for 2001 as com- >.\nOther operating expenses amounted to $121 million for 2001 as com- pared to $113 million for 2000 and $101 million for 1999. The following table presents the components of other operating expenses.\nYear ended December 31, 2001 2000 1999 (In thousands) Salaries and benefits $54,703 $ 50,014 $ 48,546 Occupancy and equipment 24,992 22,792 20,137 Deposit insurance premium 645 547 1,096 Other taxes and insurance 7,804 6,355 5,683 Professional and service fees 7,931 8,740 6,672 Business promotion 7,506 8,468 5,896 Communications 5,395 5,573 4,667 Real estate owned operations cost (gain) 352 79 (303 Expense of rental equipment  1,578 1,525 1,478 Other 9,948 8,957 7,400 Total $120,854 $113,050 $101,272 )\n0 34\nFirst BanCorp.> 2001"}]}
+{"image": "doclay/doclay_36988.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Performance Audit Report on the Control of F MD\nNo subsequent action plans were developed to clearly demonstrate time and  resource allocation for implementation of such interventions. The only time  bound intervention in the document was the Endorsement of the FMD Control  Strategy by the OIE under which it was stated that the Department shall submit  the FMD control Strategy in 2014 to the OIE.\nSuch action plans could specify the specific actions the DVS needed to take to  address each of the top departmental issues and to attain each of the associated  goals. In addition, the action plans could clearly specify who will complete each  action and when. In the absence of such a well-coordinated planning framework,  the Department lacked clear guide and commitment to implementation of key  strategies regarding FMD control. Developing strategies without subsequent  action plans also made it difficult for the department to appropriately monitor  implementation of its long term objectives in controlling the FMD as well as to  effectively plan and prioritise resource allocation and utilisation particularly at  district level. Therefore, OAG found it difficult to evaluate performance of the  DVS in implementing the strategic interventions captured in different strategy  documents as there were no clear performance yardsticks to measure against. \nNevertheless, the OAG appreciates the Department’s efforts in developing action  plan for routine activities like surveillance (e.g. Surveillance Plan, October 2014-  March  2016)  and  vaccinations  (campaign  schedules).  The  OAG  also  acknowledges the fact that implementation of some of the above mentioned key  interventions was underway at the time of audit. The establishment of the  Ngamiland Protection Zone and Prioritised Disease Control Infrastructure  Maintenance were already being implemented at the time of audit, despite  absence of clear action plans for such interventions. \n25 |  P a g e"}]}
+{"image": "doclay/doclay_40115.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "EUROPEAN COMMISSION  DIRECTORATE-GENERALENVIRONMENT \nDirectorateB – Green Growth & Circular Economy Unit B.1 – Sustainable Production, Products & Consumption\nRef. Ares(2021)2953911 - 04/05/2021Call for tenders ENV/2021/OP/0003 \n1 \nOpen procedure\nTENDER SPECIFICATIONS \nSupporting the development of a roadmap for the  reduction of whole life carbon of buildings "}]}
+{"image": "doclay/doclay_28224.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "convergence. This is so at least in situations in which the height-difference correlation is well defined; otherwise a different scaling is possible even locally in space [16]. This makes precise and generalizes our previous results [13] in the following way: a fast growth rate will make the interface weakly converge to a hypersphere. We have further found the scaling relation α = β$_{r}$z , which quantitatively relates the center of mass fluctuations, growth rate and rate of (weak) convergence to/divergence from the hyperspherical profile. These results, together with our previous ones [16, 20], suggest the following generalization of the critical exponents for arbitrary values of γ\nwhich should be valid for linear models as well as some nonlinear equations as the VLDS one, which present a conserved drift and its critical behavior is accessible to dimensional analysis. For the KPZ equation, which nonlinearity introduces both mass and fluctuations into the system, we expect a different behavior. As we have seen, the amount of mass entering the interface (and of course the way it is introduced) may change the critical behavior. We have explicitly shown this by means of the linear models in absence and presence of dilution, which gave respectively rise to correlations (6) and (11).\nWe have summarized the different morphologies that can appear in Table I (see also Fig. 2 in [16]). In the first column, for small γ , we have placed the regime in which the classical values of the exponents are recovered. The other three columns represent situations in which this is not the case. The “roughness” column describes the situation in which the radial fluctuations do not average each other out for long times, so in this regime the overall appearance of the cluster deviates from the hyperspherical profile. The “super-roughness” column states a particular case of this last regime, in which the amplitude of the radial fluctuations grows faster than the arc-length sustaining them. In both cases roughness should be understood as the degree of weak divergence (as opposed to weak convergence) from the hyperspherical profile. Finally, the last column describes the regime in which the weak convergence to the hyperspherical profile is reached asymptotically in time.\n12\nγ < 1 z$_{c}$ 1 z$_{c}$ < γ < 1 d 1 z$_{c}$ < γ < 1 d +2 γ > max { 1 $_{d}$, 1 z$_{c}$ } Classical exponents Roughness Super-roughness Weak convergence to the hyperspherical profile\nTABLE I: Morphologies for different spatial dimensions and exponents.\nα = z − d 2 , β := α z = 1 2 − d 2 z , for z = min$^{{}$ z$_{c}$, 1 γ$^{}}$ , (19)"}]}
+{"image": "doclay/doclay_73124.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Table of Contents 71\n(10.53)* Mortgagee's Subordination and Consent, dated January 23, 2015, by and between Wells Fargo Capital Finance, LLC, as Agent, and The Dixie Group, Inc. and it subsidiaries, as Borrower, and First Tennessee Bank National Association, as Mortgagee. (Incorporated by reference to Exhibit (10.77) to Dixie's Annual Report on Form 10-K for the year ended December 27, 2014.) (10.54)* Amended and Restated Mortgagee's Subordination and Consent, dated January 23, 2015, by and between Wells Fargo Capital Finance, LLC, as Agent, and The Dixie Group, Inc. and it subsidiaries, as Borrower, and First Tennessee Bank National Association, as Mortgagee. (Incorporated by reference to Exhibit (10.78) to Dixie's Annual Report on Form 10-K for the year ended December 27, 2014.) (10.55)* Amendment to Deed to Secure Debt, Assignment of Rents and Leases, Security Agreement and Fixture Filing, dated January 23, 2015, between TDG Operations, LLC, a Georgia limited liability company, and First Tennessee Bank National Association. (Incorporated by reference to Exhibit (10.79) to Dixie's Annual Report on Form 10-K for the year ended December 27, 2014.) (10.56)* Stock Purchase Agreement between TDG Operations, LLC, a wholly owned subsidiary of The Dixie Group, Inc. and James Horwich, Trustee under the Horwich Trust of 1973, to purchase all outstanding capital stock of Atlas Carpet Mills, Inc. (Incorporated by reference to Exhibit (10.2) to Dixie's Current Report on Form 8-K dated March 20, 2014.) (10.57)* Summary of Annual Incentive Compensation Plan Applicable to 2015. (Incorporated by reference to Exhibit (10.1) to Dixie's Current Report on Form 8-K dated March 13, 2015.)** (10.58)* Form of LTIP award (B shareholder). (Incorporated by reference to Exhibit (10.2) to Dixie's Current Report on Form 8-K dated March 13, 2015.)** (10.59)* Form of LTIP award (common only). (Incorporated by reference to Exhibit (10.3) to Dixie's Current Report on Form 8-K dated March 13, 2015.)** (10.60)* Form of Career Share award (B shareholder). (Incorporated by reference to Exhibit (10.4) to Dixie's Current Report on Form 8-K dated March 13, 2015.)** (10.61)* Form of Career Share award (common only). (Incorporated by reference to Exhibit (10.5) to Dixie's Current Report on Form 8-K dated March 13, 2015.)** (10.62)* Form of Retention Grant (Service Condition only). (Incorporated by reference to Exhibit (10.6) to Dixie's Current Report on Form 8-K dated March 13, 2015.)** (10.63)* Form of Retention Grant (Performance Condition and Service Condition). (Incorporated by reference to Exhibit (10.7) to Dixie's Current Report on Form 8-K dated March 13, 2015.)** (10.64)* Form of Award of 100,000 share of Restricted Stock under the 2006 Stock Awards Plan to Daniel K. Frierson. (Incorporated by Reference to Exhibit (10.1) to Dixie's Current Report on Form 8-K dated April 30, 2015.)** (10.65)* Thornton Edge LLC Lease for Reed Road Facility. (Incorporated by reference to Exhibit (10.1) to Dixie's Current Report on Form 10-Q dated November 4, 2015.) (10.66)* Thornton Edge LLC First Lease Amendment for Reed Road Facility. (Incorporated by reference to Exhibit (10.2) to Dixie's Current Report on Form 10-Q dated November 4, 2015.) (10.67)* Thornton Edge LLC Second Lease Amendment for Reed Road Facility. (Incorporated by reference to Exhibit (10.3) to Dixie's Current Report on Form 10-Q dated November 4, 2015.) (10.68)* 2016 Incentive Compensation Plan. (Incorporate by reference to Appendix A to Dixie's Proxy Statement for the Registrant's Annual Meeting of Shareholders held May 3, 2016.)** (10.69)* Summary of Incentive Plan for 2016. (Incorporated by Reference to Exhibit (10.1) to Dixie's Current Report on Form 8-K dated March 11, 2016.)** (10.70)* Long Term Incentive Plan Award B Shareholder. (Incorporated by Reference to Exhibit (10.2) to Dixie's Current Report on Form 8-K dated March 11, 2016.)** (10.71)* Long Term Incentive Plan Award Common. (Incorporated by Reference to Exhibit (10.3) to Dixie's Current Report on Form 8-K dated March 11, 2016.)** (10.72)* Career Shares B Shareholder. (Incorporated by Reference to Exhibit (10.4) to Dixie's Current Report on Form 8-K dated March 11, 2016.)** (10.73)* Career Shares Common. (Incorporated by Reference to Exhibit (10.5) to Dixie's Current Report on Form 8-K dated March 11, 2016.)** (10.74)* Tenth Amendment to Credit Agreement, First Amendment to Security Agreement, and First Amendment to Guaranty. (Incorporated by Reference to Exhibit (10.1) to Dixie's Current Report on Form 8-K dated September 26, 2016.) (10.75)* Summary of Incentive Plan for 2017. (Incorporated by Reference to Exhibit (10.1) to Dixie's Current Report on Form 8-K dated March 10, 2017.)** (10.76)* Form of Stock Option Agreement - Common Stock - 2016 Stock Plan. (Incorporated by Reference to Exhibit (10.1) to Dixie's Current Report on Form 8-K dated May 31, 2017.)** (10.77)* Form of Stock Option Agreement - Class B Holder - 2016 Stock Plan. (Incorporated by Reference to Exhibit (10.2) to Dixie's Current Report on Form 8-K dated May 31, 2017.)** (10.78)* Royalty Carpet Mills Lease for Porterville, California Facility. (Incorporated by Reference to Exhibit (10.78) to Dixie's Current Report on Form 10-K dated March 13, 2018.)"}]}
+{"image": "doclay/doclay_46916.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "The brake housing must be inspected thoroughly. Scratches,  gouges, corrosion, or other blemishes may be dressed out and  the surface treated to prevent corrosion. Minimal material  should be removed when doing so. Most important is that  there are no cracks in the housing. Fluorescent dye penetrant  is typically used to inspect for cracks. If a crack is found, the  housing must be replaced. The cylinder area(s) of the housing  must be dimensionally checked for wear. Limits are specified  in the manufacturer’s maintenance manual. \nexcessive key slot wear are grounds for rejection. Brake wear  pads or linings must also be inspected for wear while the  brake assembly is removed from the aircraft. Signs of uneven  wear should be investigated, and the problem corrected. The  pads may be replaced if worn beyond limits as long as the  stationary disc upon which they mount passes inspection.  Follow the manufacturer’s procedures for inspections and  for pad replacement.\nRotating discs must be similarly inspected. The general  condition of the disc must be observed. Glazing can occur  when a disc or part of a disc is overheated. It causes brake  squeal and chatter. It is possible to resurface a glazed disc  if the manufacturer allows it. Rotating discs must also be  inspected in the drive key slot or drive tang area for wear and  deformation. Little damage is allowed before replacement  is required. \nThe brake pistons that fit into the cylinders in the housing  must also be checked for corrosion, scratches, burrs, etc.  Pistons are also dimensionally checked for wear limits  specified in the maintenance data. Some pistons have  insulators on the bottom. They should not be cracked and  should be of a minimal thickness. A file can be used to smooth  out minor irregularities. \nThe pressure plate and back plate on multiple disc brakes  must be inspected for freedom of movement, cracks, general  condition, and warping. New linings may be riveted to the  plates if the old linings are worn and the condition of the  plate is good. Note that replacing brake pads and linings by  riveting may require specific tools and technique as described  in the maintenance manual to ensure secure attachment.  Minor warping can be straightened on some brake assemblies.\nBrake seals are very important. Without properly functioning  seals, brake operation will be compromised, or the brakes  will fail. Over time, heat and pressure mold a seal into the  seal groove and harden the material. Eventually, resilience  is reduced and the seal leaks. New seals should be used to  replace all seals in the brake assembly. Acquire seals by  part number in a sealed package from a reputable supplier to  avoid bogus seals and ensure the correct seals for the brake  assembly in question. Check to ensure the new seals have  not exceeded their shelf life, which is typically three years  from the cure date.\nA malfunctioning automatic adjuster assembly can cause the  brakes to drag on the rotating disc(s) by not fully releasing  and pulling the lining away from the disc. This can lead to  excessive, uneven lining wear and disc glazing. The return  pin must be straight with no surface damage so it can pass  through the grip without binding. Damage under the head  can weaken the pin and cause failure. Magnetic inspection  is sometimes used to inspect for cracks. \nMany brakes use back-up rings in the seal groove to support  the O-ring seals and reduce the tendency of the seal to extrude  into the space which it is meant to seal. These are often made  of Teflon® or similar material. Back-up seals are installed  on the side of the O-ring away from the fluid pressure.  [Figure 13-121]  They are often reusable. \nThe components of the grip and tube assembly must be in  good condition. Clean and inspect in accordance with the  manufacturer’s maintenance instructions. The grip must  move with the force specified and must move through its  full range of travel.\nIn general aviation, replacement of brake linings is commonly  done in the hangar. The general procedure used on two  common brake assemblies is given. Follow the actual  manufacturer’s instruction when replacing brake linings on  any aircraft brake assembly.\nA sound torque tube is necessary to hold the brake assembly  stable on the landing gear. General visual inspection should  be made for wear, burrs, and scratches. Magnetic particle  inspection is used to check for cracks. The key areas should  be checked for dimension and wear. All limits of damage  are referenced in the manufacturer’s maintenance data. The  torque tube should be replaced if a limit is exceeded.\nTo replace the linings on a Goodyear single disc brake  assembly, the aircraft must be jacked and supported.  Detach the anti-rattle clips that help center the disc in the  wheel before removing the wheel from the axle. The disc \nGoodyear Brakes\nReplacement of Brake Linings\nTorque Tube\nAutomatic Adjuster Pins\nSeal Condition\nBrake Housing and Piston Condition\n13-72"}]}
+{"image": "doclay/doclay_66834.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "778 911 974 1079 1219 1328 781 914 976 1090 1230 1330 783 915 977 1091 1232 1331 785 916 982 1095 1233 1333 789 917 983 1098 1235 1334 815 925 984 1099 1236 1336 819 930 985 1103 1237 1337 820 931 986 1104 1239 1338 823 932 987 1105 1240 1340 836 933 993 1113 1241 1341 837 934 994 1118 1244 1344 838 935 999 1124 1245 1345 839 936 1001 1125 1249 1346 840 938 1002 1126 1254 1347 841 939 1003 1127 1255 1354 842 940 1004 1129 1269 1355 843 941 1005 1131 1270 1363 844 942 1008 1135 1271 1365 848 943 1009 1136 1273 1366 849 944 1013 1139 1278 1370 850 945 1019 1141 1279 1372 851 946 1023 1148 1280 1373 863 947 1024 1149 1282 1374 864 948 1026 1150 1288 1383 866 951 1027 1153 1291 1387 872 952 1029 1154 1293 1394 874 953 1032 1156 1298 1396 875 954 1038 1157 1299 1397 877 955 1041 1160 1300 1401 878 956 1042 1165 1304 1403 884 957 1044 1177 1306 1404 888 958 1054 1179 1308 1405 895 959 1056 1182 1309 1407 897 960 1060 1184 1311 1409 1411 1516 1594 1679 1742 1818 1413 1520 1595 1681 1746 1819 1414 1521 1598 1682 1747 1822 1415 1525 1600 1683 1748 1823 1416 1526 1604 1684 1752 1824 1417 1528 1605 1687 1753 1825 1432 1529 1606 1689 1760 1828 1433 1530 1609 1690 1765 1830 1440 1531 1611 1691 1766 1832\nCopy right 2012 CD Technologies Asia, Inc. and Accesslaw, Inc.\nPhilippine Law Encyclopedia 2011\n880"}]}
+{"image": "doclay/doclay_44913.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "For situations in which an increase in the descent angle is  needed for the intended landing spot, the normal procedure  is to increase speed above the best L$_{D}$ speed in order to  descend. The greater the speed is, the greater the parasitic  drag and descent angle. \nEach design has different descent rates based on the parasitic  drag of the wing and carriage. For example, a single surface  with an exposed crossbar wing and a stick carriage (no  streamlined cowling) increases the descent angle quickly  because of the dramatic increases in drag with increased  speed. A double surface wing with a streamlined carriage  does not develop parasitic drag as fast with increased speed  and is less able to achieve a steep angle with increased speed.  The pilot should understand that this characteristic is unique  to the make/model being flown. This steep angle technique is  the optimum steep approach procedure because the aircraft  is lined up on the runway and the pilot can easily judge the  glideslope using the stabilized approach method covered  earlier.  [Figure 11-29]\nIncrease speed as required to obtain the descent angle for  the intended touchdown point. Use the stabilized approach  technique to obtain the increased angle for the aiming  point. At the higher speeds and greater descent, slow to the  normal approach speed, intersect the normal fi nal approach  path, and perform the landing required for that particular  situation (calm air/crosswinds/turbulent air). As the student  gains proficiency at steep approach techniques, the altitude  to transition from the high speed steep angle to the normal  approach speed can be lowered and eventually combined  into one continuous roundout for landing started at a higher  altitude than the normal approach and roundout. For this  situation, note that with the increased speed the roundout \ncovers additional distance that should be accounted for as  the speed is decreased. \nIf at a height at which a steep approach is necessary, but  the aircraft is too high to obtain an angle steep enough to  make the intended landing area, alternating turns can be  made to decrease altitude to a point at which the steep angle  technique could be applied for the remainder of the descent.  These alternating turns should be performed no lower than  400 feet above ground level (AGL). The turns should be  an equal distance from the runway centerline extension to  keep track and maintain the relative position on the runway  centerline. The bank and direction of turns across the runway  centerline should be determined by how much altitude must  be lost to position the WSC aircraft for utilization of the steep  angle technique for the remainder of the steep approach, if  required.  [Figure 11-30]\nPower-off accuracy approaches are made by gliding with  the engine idling through a specific pattern to a touchdown  beyond and within 200 feet of a designated line or mark on  the runway. The objective is to instill in the pilot the judgment  and knowledge of procedures necessary for accurate fl ight,  without power, to a safe landing. This simulates procedures  for an emergency engine-out situation. The ability to estimate  the distance an aircraft glides to a landing is the real basis of  all power-off accuracy approaches and landings. This largely  determines the amount of maneuvering that may be done from  a given altitude. In addition to the ability to estimate distance,  the ability to maintain the proper glide while maneuvering  the aircraft is required.\n Steep Angle\n Alternating Turns\n Power-Off Accuracy Approaches\n34 Normal Final Approach Steep Normal Approach Speed Approach Decrease speed and intersect normal Touchdown\nFigure 11-29. Steep approach—steep angle technique.\n11-21"}]}
+{"image": "doclay/doclay_50227.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Bit Operations Prior to MySQL 8.0\nIn MySQL 8.0, bit functions and operators permit binary string type arguments ( BINARY ,  VARBINARY , and the  BLOB  types) and return a value of like type, which enables them to take arguments and produce return values larger than 64 bits. Nonbinary string arguments are converted to  BIGINT  and processed as such, as before.\nAn implication of this change in behavior is that bit operations on binary string arguments might produce a different result in MySQL 8.0 than in 5.7. For information about how to prepare in MySQL 5.7 for potential incompatibilities between MySQL 5.7 and 8.0, see Bit Functions and Operators, in MySQL 5.7 Reference Manual.\n•Bit Operations Prior to MySQL 8.0\n•Bit Operations in MySQL 8.0\n•Binary String Bit-Operation Examples\n•Bitwise AND, OR, and XOR Operations\n•Bitwise Complement and Shift Operations\n•BIT_COUNT() Operations\n•BIT_AND(), BIT_OR(), and BIT_XOR() Operations\n•Special Handling of Hexadecimal Literals, Bit Literals, and NULL Literals\n•Bit-Operation Incompatibilities with MySQL 5.7\n•This statement operates on numeric literals, treated as unsigned 64-bit integers:\n•This statement performs to-number conversions on the string arguments ( ’127’  to  127 , and so forth) before performing the same operations as the first statement and producing the same results:\n•This statement uses hexadecimal literals for the bit-operation arguments. MySQL by default treats hexadecimal literals as binary strings, but in numeric context evaluates them as numbers (see Section 9.1.4, “Hexadecimal Literals” ). Prior to MySQL 8.0, numeric context includes bit operations. Examples:\nBit Operations Prior to MySQL 8.0\nBit operations prior to MySQL 8.0 handle only unsigned 64-bit integer argument and result values (that is, unsigned  BIGINT  values). Conversion of arguments of other types to  BIGINT  occurs as necessary. Examples:\nmysql>  SELECT X’7F’ | X’80’, X’80’ << 2, BIT_COUNT(X’0F’);\nmysql>  SELECT 127 | 128, 128 << 2, BIT_COUNT(15); +-----------+----------+---------------+ | 127 | 128 | 128 << 2 | BIT_COUNT(15) | +-----------+----------+---------------+ | 255 | 512 | 4 | +-----------+----------+---------------+\nmysql>  SELECT ’127’ | ’128’, ’128’ << 2, BIT_COUNT(’15’); +---------------+------------+-----------------+ | ’127’ | ’128’ | ’128’ << 2 | BIT_COUNT(’15’) | +---------------+------------+-----------------+ | 255 | 512 | 4 | +---------------+------------+-----------------+\n2259"}]}
+{"image": "doclay/doclay_7219.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "costs is proportional to the total period of operation of the active waste disposal areas. Alcoa estimated its liability for the active disposal areas by making certain assumptions about the period of operation; the amount of material placed in the area prior to closure; and the appropriate technology, engineering, and regulatory status applicable to final closure. The most probable cost for remediation has been reserved. It is reasonably possible that an additional liability, not expected to exceed $75, may be incurred if actual experience varies from the original assumptions used.\nBased on the foregoing, it is possible that Alcoa’s results of operations, in a particular period, could be materially affected by matters relating to these sites. However, based on facts currently available, management believes that adequate reserves have been provided and that the disposition of these matters will not have a materially adverse effect on the financial position or liquidity of the company.\nAlcoa’s remediation reserve balance at the end of 2004 and 2003was$391and$395(ofwhich$73and$65wasclassified as a current liability), respectively, and reflects the most probable costs to remediate identified environmental conditions for which costs can be reasonably estimated. Remediation expenses charged to the reserve were approximately $46 in 2004, $32 in 2003, and $50 in 2002. These amounts include expenditures currently mandated, as well as those not required by any regulatory authority or third party. The reserve balance was increased by $42 in 2004, principally for the additional reserve recorded for the Grasse River site. In 2003, the reserve balance was reduced by approximately $9, primarily for adjustments based on recent assessments of remaining work required at certain sites.\nIncluded in annual operating expenses are the recurring costs of managing hazardous substances and environmental programs. These costs are estimated to be about 2% of cost of goods sold.\nAlcoa takes a disciplined approach to cash management and strengthening its balance sheet, as it undertook aggressive capital controls, management of working capital, and continued focus on its divestiture plan in 2004. These actions helped the company to retire approximately $2,000 of debt over the past two years. Capital spending increased 32%, as Alcoa made continued progress on brownfield expansions in refining and smelting and broke ground on the greenfield smelter construc- tion in Iceland. Increased sales contributed to Alcoa’s cash from operations of $2,199 in 2004. Additionally, progress on the divestiture program with the sales of the automotive fasteners business, the packaging equipment business, and the specialty chemicals business in 2004, facilitated payments of debt, which aided in a reduction in the debt-to-capital ratio from 35.1% in 2003 to 30.0% in 2004.\nCash provided from operations and from the divestiture plan is anticipated to be adequate to cover dividends, debt repayments, capital expenditures, and other business needs over the next 12 months.\n34\nIn connection with the sale of the Sherwin alumina refinery in Texas, which was required to be divested as part of the Reynolds merger in 2000, Alcoa has agreed to retain responsibility for the remediation of then existing environmental conditions, as wellasaproratashareofthefinalclosureoftheactivewaste disposal areas, which remain in use. Alcoa’s share of the closure\nThe EPA’s ultimate selection of a remedy could result in additional liability. Alcoa may be required to record a subsequent reserve adjustment at the time the EPA’s Record of Decision is issued.\nAlcoa adjusted the reserves in the second quarter of 2004 to include the $35 for the ROPS. This is in addition to the $30 previously reserved. With the exception of the natural recovery remedy, none of the existing alternatives in the 2002 Analysis of Alternatives Report is currently more probable than the others and the results of the ROPS are necessary to revise the scope and estimated cost of many of the current alternatives.\nIn May of 2004, Alcoa agreed to perform the study at an estimated cost of $35. Most of the work should be completed by the fourth quarter of 2005. It is anticipated that a report offindingswillbeissuedtothe EPA in 2006. Subsequent to this submittal, a revised Analysis of Alternatives Report will be submitted to the EPA at a date to be determined. This infor- mation will be used by the EPA to propose a remedy for the entire river.\nIn June of 2003, based on river observations during the spring of 2003, the EPA requested that Alcoa gather additional field data to assess the potential for sediment erosion from winter river ice formation and breakup. The results of these additional studies, submitted in a report to the EPA in April of 2004, suggest that this phenomenon has the potential to occur approximately every 10 years and may impact sediments in certain portions of the river under all remedial scenarios. The EPA informed Alcoa that a final remedial decision for the river could not be made without substantially more information, including river pilot studies on the effects of ice formation and breakup on each of the remedial techniques. The EPA requested that Alcoa consider a Remedial Options Pilot Study (ROPS) to gather this information. The scope of this study includes sediment removal and capping, the installation of an ice control structure, and significant monitoring.\nIn 2002, Alcoa submitted an Analysis of Alternatives Report that detailed a variety of remedial alternatives with estimated costs ranging from $2 to $525. Because the selection of the $2 alternative (natural recovery) was considered remote, Alcoa adjustedthereservefortheGrasseRiverin2002to$30 representing the low end of the range of possible alternatives, as no single alternative could be identified as more probable than the others.\nAlcoa has been conducting investigations and studies of the Grasse River, adjacent to Alcoa’s Massena, New York plant site, under order from the U.S. Environmental Protection Agency (EPA) issued under the Comprehensive Environmental Response, Compensation and Liability Act, also known as Superfund. Sediments and fish in the river contain varying levels of polychlorinated biphenyl (PCB).\nLiquidity and Capital Resources"}]}
+{"image": "doclay/doclay_69464.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "2.6.1 Input/output configuration program\n2.6.2 Worldwide Port Name Prediction Tool\n2.6.3 Coupling Facility Structure Sizer (CFSizer)\nWWPN Persistence\nNote:  Verify ICP/IOCP version for z15 support.\nICP IOCP Version 5 Release 5.0 or later is required for a z15 server. You can define the z15  configuration by using only IOCP. However, HCD is suggested because of its verification and  validation capabilities. By using ICP IOCP, it is possible to write an IOCDS in preparation for a  CPC upgrade.\nFor more information about the changes and requirements for ICP IOCP, see  IBM Z  Input/Output Configuration Program User’s Guide for ICP IOCP , SB10-7172.\nThe worldwide port name (WWPN) Tool for IBM Z Fibre Channel Protocol (FCP) Channels  helps prepare configuration files that are required or generated by the IBM Z platform when  FCP Channels are installed. In particular, this tool helps during the installation of new  systems and system upgrades.\nOne of the most important configuration parameters are WWPNs, which uniquely identify  physical or virtual Fibre Channel ports. They are typically used in Fibre Channel Storage Area  Network (SAN) switches to assign the corresponding ports to zones of a SAN. They are used  in storage subsystems to grant access from these ports to specific storage devices that are  identified by logical unit numbers (LUNs).\nThe capability of the WWPN Prediction Tool is extended to calculate and show WWPNs for  both virtual and physical ports before system installation.\nThe WWPN Prediction Tool is available for download from IBM Resource Link and is  applicable to all FICON channels defined as CHPID type FCP (for communication with SCSI  devices) on z15. You can access the tool at this web page using your IBMid.\nThe FCP WWPNs are determined based on the I/O serial number of the CPC, the IOCDS  configuration details (for NPIV WWPNs), and the PCHID values (for physical WWPNs). With  the introduction of the z13, WWPN Persistence configuration option has been introduced.  When FC 0099 (WWPN Persistence) is ordered as part of a new or upgraded configuration  for a z15, the I/O serial number part of the WWPN for the new z15 is the same serial number  as for the source machine configuration.\nFor more information, see the Techdocs website.\nMoving to a new z15 means migrating to a higher Coupling Facility Control Code level (CFCC  level 24). If your existing CF data structures are adequately sized, and you want to know how  much these structures might need to grow to accommodate the same workload at the new  CFCC level, you can use the current structure sizes to calculate the new sizes. The CFSizer  Tool helps you evaluate the sizing of the CF structures.\nUse the CFSizer tool to plan the amount of storage that must be allocated for coupling facility  partitions more accurately. You can access the tool from the CFSizer page.\nChapter 2. Planning considerations for CPC in PR/SM mode  13\n8860ch02.fm\nDraft Document for Review September 23, 2019 1:36 am"}]}
+{"image": "doclay/doclay_66452.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "drawing of any kind,  or that any person or company is conducting any scheme, device, or enterprise for obtaining money or property of any kind through the mails by means of false or fraudulent pretenses, representations, or promises, the Director of Posts may instruct any postm aster or other officer or employee of the Bureau to return to the person depositing same in the mails, with the word \"fraudulent\" plainly written or stamped upon the outside cover thereof, any mail matter of whatever class mailed by or addressed to such p erson or company or the representative or agent of such person or company. The public advertisement by the person or company conducting such lottery, enterprise, scheme, or device, that remittances for the same may be made by registered letters to any othe r person, firm, bank, corporation or association named therein shall be held to be  prima facie evidence of the existence of said agency by all the parties named therein, but the Director of Posts shall not be precluded from ascertaining the existence of such agency in any other lawful manner satisfactory to himself. CTEacH\nSECTION  1213 . Deprivation of Use of Money-Order System . — The Director of Posts may, upon evidence satisfactory to him that any person or company is engaged in conducting any lottery, gift enterprise, or scheme for the distribution of money, or of any real  or personal property by lot, chance, or drawing of any kind, or that any person or company is conducting any scheme, device, or enterprise for obtaining money or property of any kind through the mails by means of false or fraudulent pretenses, representat ions, or promises, forbid the issue or payment by any postmaster of any postal money order to said person or company or to the agent of any such person or company, whether such agent is acting as an individual or as a firm, bank, corporation, or associatio n of any kind and may provide by regulation for the return to the remitters of the sums named in money orders drawn in favor of such person or company or its agent. The public advertisement by such person or company so conducting any such lottery, enterpri se, scheme, or device, that remittances for the same may be made by means of postal money orders to any other person, firm, bank, corporation, or association named therein shall be held to be  prima facie  evidence of the existence of said agency by all the  parties named therein; but the Director shall not be precluded from ascertaining the existence of such agency in any other lawful manner. DTEcSa\nSECTION  1214 . Destruction of Certain Forfeited Matter . — When any article which is dangerous to be kept or handled or which is devoid of value or incapable of legitimate use is forfeited under the provisions of this chapter, it may upon seizure be forthwit h destroyed. HaDEIc\nSECTION  1215 . Notice of Seizure . — In case of the seizure of a forfeited article which is of value and capable of legitimate use, notice shall be given to the owner or sender if known.\n361\nCopyright 2012 CD Technologies Asia, Inc. and Accesslaw, Inc. Philippine Law Encyclopedia 2011"}]}
+{"image": "doclay/doclay_13339.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "GA FL SC NC VA  NJ PA MA NY  NH VT DE Refinery Terminals  Marketing HOVENSA Port Reading\nBUILDING THE HESS BRAND\nOur Refining and Marketing business  is focused on the East Coast with a  growing convenience stor e network,  an expanding energy marketing business,  a world class merchant r efinery and  strategically located terminals.\n7"}]}
+{"image": "doclay/doclay_12513.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Washington Trust Bancorp, Inc. 2002 Annual Report23 Broad Street, Westerly, Rhode Island 02891 www.washtrust.com"}]}
+{"image": "doclay/doclay_2101.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Submitted to Phys. Rev. A\nLocal-field excitations in 2D lattices of resonant atoms\n(Dated: February 12, 2010)\nS. N. Volkov and A. E. Kaplan\nWe study excitations of the local field (locsitons) in nanoscale two-dimensional (2D) lattices of strongly interacting resonant atoms and various unusual effects associated with them. Locsitons in low-dimensional systems and the resulting spatial strata and more complex patterns on a scale of just a few atoms were predicted by us earlier [A. E. Kaplan and S. N. Volkov, Phys. Rev. Lett. 101 , 133902 (2008)]. These effects present a radical departure from the classical Lorentz-Lorenz theory of the local field (LF), which assumes that the LF is virtually uniform on this scale. We demonstrate that the strata and patterns in the 2D lattices may be described as an interference of plane-wave locsitons, build an analytic model for such unbounded locsitons, and derive and analyze dispersion relations for the locsitons in an equilateral triangular lattice. We draw useful analogies between one-dimensional and 2D locsitons, but also show that the 2D case enables locsitons with the most diverse and unusual properties. Using the nearest-neighbor approximation, we find the locsiton frequency band for different mutual orientations of the lattice and the incident field. We demonstrate a formation of distinct vector locsiton patterns consisting of multiple vortices in the LF distribution and suggest a way to design finite 2D lattices that exhibit such patterns at certain frequencies. We illustrate the role of lattice defects in supporting localized locsitons and also demonstrate the existence of “magic shapes”, for which the LF suppression at the exact atomic resonance is cancelled.\nPACS numbers: 42.65.Pc, 85.50.-n\narXiv:1002.2663v1 [physics.optics] 13 Feb 2010\nAbstract\n1\nDept. of Electrical and Computer Engineering,\nJohns Hopkins University, Baltimore, MD 21218"}]}
+{"image": "doclay/doclay_5483.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "The following table provides an overview of bonds issued by Allianz AG 1) :\nCAPITALAND FINANCING 33\nAllianz AG bond issues 1)\n1) Bonds and exchangeable bonds issued or guaranteed by Allianz AG, excluding private placements\n2) Includes coupon payment and option premium at amortized cost\n3. Exchangeable Bonds Interest 2.0 % exchangeable bond issued by Allianz Finance B. V.,  paid Amsterdam in 2003 Exchangeable for  Siemens AG shares Volume  ¤ 1.7 bn Year of issue  2000 Maturity date  3/23/2005 Current exchange price  ¤ 149.64 SIN 452 540 ISIN  DE 000 452 540 7 Interest cost 2) ¤ 84.2 mn Received option premium at issue ¤ 256.8 mn  Index-linked exchangeable bond (Miles)  issued by Allianz Finance II B. V., Amsterdam At the issuer’s discretion, exchangeable or repayable  in shares of  E.ON AG, BASF AG, Münchener Rückversicherungs- Gesellschaft AG or  certain other shares Volume  ¤ 1.0 bn Year of issue  2001 Maturity date  2/20/2004 Exchange ratio  Relevant DAX reference price divided by the relevant reference price of the shares selected Outperformance bonus  1.25% p.a. of the relevant DAX reference price SIN 600 385 ISIN  DE 000 600 385 8 Interest cost ¤ 17.7 mn 1.25 % exchangeable bond issued by Allianz Finance B. V., Amsterdam Exchangeable for RWE AG shares Volume ¤ 1.1 bn Year of issue  2001 Maturity date  12/20/2006 Current exchange price  ¤ 50.16 SIN 825 371 ISIN XS 013 976 180 2 Interest cost 2) ¤ 49.6 mn Received option premium at issue ¤ 178.1  mn Total interest cost for exchangeable bonds ¤ 151.6 mn 4. Participation certificate Allianz AG participation certificate Nominal amount  ¤ 31.2 mn Payout per certificate for 2002 ¤ 3.60  Current redemption price  ¤ 72.39 SIN  840 405 ISIN  DE 000 840 405 4 Issues that reached maturity in 2003 6.0 % bond issued by Allianz Finance B. V., Amsterdam ISIN  DE 000 132 275 8 Matured on  5/14/2003 Interest cost ¤ 17.4 mn 3.0 % exchangeable bond issued by Allianz Finance B. V., Amsterdam ISIN  DE 000 197 280 0 Matured on 2/4/2003 Interest cost ¤ 3.7 mn Total interest cost 2003 for matured issues ¤ 21.1 mn Total interest cost ¤ 681.4 mn 1. Senior Bonds Interest 5.75 % bond issued by Allianz Finance B. V., Amsterdam paid Volume  ¤ 1.1 bn in 2003 Year of issue  1997/2000 Maturity date  7/30/2007 SIN 194 000 ISIN  DE 000 194 000 5 Interest cost ¤ 63.7 mn 5.0 % bond issued by Allianz Finance B. V., Amsterdam Volume  ¤ 1.6 bn Year of issue  1998 Maturity date 3/25/2008 SIN 230 600 ISIN DE 000 230 600 8 Interest cost ¤ 84.5 mn 3.0 % bond issued by Allianz Finance B. V., Amsterdam Volume  CHF 1.5 bn Year of issue 1999/2000 Maturity date 8/26/2005 SIN 830 806 ISIN  CH 000 830 806 3 Interest cost ¤ 34.1 mn 4.625 % bond issued by Allianz Finance II B. V., Amsterdam Volume ¤ 1.1 bn Year of issue  2002 Maturity date  11/29/2007 SIN  250 035 ISIN  XS 015 878 835 5 Interest cost ¤ 52.5 mn 5.625 % bond issued by Allianz Finance II B. V., Amsterdam Volume  ¤ 0.9 bn Year of issue 2002 Maturity date  11/29/2012 SIN  250 036 ISIN  XS 015 879 238 1 Interest cost ¤ 51.2 mn Total interest cost for senior bonds ¤ 286.0 mn 2. Subordinated Bonds 6.125 % bond issued by Allianz Finance II B. V., Amsterdam Volume  ¤ 2 bn Year of issue  2002 Maturity date  5/31/2022 SIN  858 420 ISIN XS 014 888 756 4 Interest cost ¤ 123.6 mn 7.25 % bond issued by Allianz Finance II B. V., Amsterdam Volume  $ 0.5 bn Year of issue  2002 Maturity date  Perpetual Bond SIN  369 290 ISIN XS 015 915 072 0 Interest cost ¤ 33.0 mn 6.5 % bond issued by Allianz Finance II B. V., Amsterdam Volume  ¤ 1 bn Year of issue  2002 Maturity date  1/13/2025 SIN  377 799 ISIN  XS 015 952 750 5 Interest cost ¤ 66.1 mn Total interest cost for subordinated bonds ¤ 222.6 mn"}]}
+{"image": "doclay/doclay_35782.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "FIG. 1: Feynman diagrams for γ + N → K + Σ ∗ ( 3 2 $^{+}$). (a) t-channel; (b) s-channel; (c) u-channel; (d) contact term.\nΣ $^{∗}$, respectively. From the investigation of Ref. [12], the main contributions come from the t-channel K meson ex- change, the s-channel N and Δ as well as their resonances exchange, the u-channel Λ (for neutral propagator only) and Σ $^{∗}$( 3 2 $^{+}$) exchange and the contact term. For the t-channel K meson exchange, the relevant ef-\n2 For the t-channel K meson exchange, the relevant ef- fective Lagrangians are\nwith the isospin structure of K Σ $^{∗}$N coupling\nwhere f$_{KN}$$_{Σ}$ ∗ is the coupling constant and is taken as f$_{KN}$$_{Σ}$ ∗ = − 3 . 22 from the SU(3) flavor symmetry relation as in Ref. [12]; m$_{K}$ is the mass for K meson.\nFor the s-channel nucleon exchange, the effective La- grangians for the interactions contain Eq. (2) as well as\nwhere Q$_{N}$ is the electric charge (in unite of e ), and κ$_{N}$ denotes the magnetic moment of the nucleon. 3 5\ndenotes the magnetic moment of the nucleon. For the s-channel spin- 3 2 and spin- 5 2 resonances ex- change, the effective Lagrangians for the interactions are\ntaken. The reaction γp → K $^{+}$Σ ∗ 0 contains the u-channel Λ(1116) exchange. The effective Lagrangians are\nWe consider 3 PDG resonances in s-channel, namely, N 3 2$^{−}$ (2080), Δ 3 2$^{−}$ (1940) and Δ 5 2 + (2000), which are the most prominent ones as stated in Ref. [12]. The cou- pling constants f$_{1}$ and f$_{2}$ can be calculated from the helicity amplitudes in PDG [19] or model predictions with Eq.(B3) of Ref. [12]. For γN Δ coupling, we have f$_{1}$ = 4 . 04 and f$_{2}$ = 3 . 87. From the predicted helicity am- plitudes in Ref. [20], one gets f$_{1}$ = − 1 . 25 and f$_{2}$ = 1 . 21 for γpN $^{∗}$(2080) coupling; f$_{1}$ = 0 . 381 and f$_{2}$ = − 0 . 256 for γnN $^{∗}$(2080) coupling; f$_{1}$ = 0 . 39 and f$_{2}$ = 0 . 57 for γN Δ(1940) coupling, and f$_{1}$ = − 0 . 68, f$_{2}$ = − 0 . 062 for γN Δ(2000) coupling. For Δ K Σ ∗ coupling, h$_{1}$ = 2 . 0 and h$_{2}$ = 0 are used from h$_{1}$ = − f$_{K}$$_{ΔΣ}$ ∗ $_{/}$√$_{3 with}$ f$_{K}$$_{ΔΣ}$ ∗ = − 3 . 46 [21]. For the resonances coupling to K Σ $^{∗}$, the coupling constants h$_{1}$ and h$_{2}$ can be calculated from Eq.(B11)-(B18) of Ref. [12] from the model pre- dicted amplitudes G ( l ) [22]. In our concrete calculation, h$_{1}$ = 0 . 24 and h$_{2}$ = − 0 . 54 for N $^{∗}$(2080) K Σ ∗ coupling, h$_{1}$ = − 0 . 68 and h$_{2}$ = 1 . 0 for Δ(1940) K Σ ∗ coupling, and h$_{1}$ = 1 . 1 and h$_{2}$ = 0 . 21 for Δ(2000) K Σ ∗ coupling are taken. ∗ 0\nFor Δ and Δ resonances of isospin-3/2, the effective La- grangians have the isospin structure\nwhere F µν = ∂ $^{µ}$Aν − ∂ $^{ν}$A$^{µ}$; R$_{µ}$ and R$_{µα}$ denote the spin- 3 2 and spin- 5 2 fields, respectively, and\n2\nand\nL RK Σ ∗ ( 3 2$^{±}$ ) = − h$_{1}$ m$_{K}$ ∂ $^{α}$K Σ ∗ $^{µ}$Γ ( ± ) α R$_{µ}$ + ih$_{2}$ ( m$_{K}$ ) $_{2}$∂ $^{µ}$∂$^{α}$K Σ ∗ $_{α}$Γ ( ± $^{)}$R$_{µ}$ + H . c ., (7)\nL RK Σ ∗ ( 5 2$^{±}$ ) = ih$_{1}$ m 2 K ∂ $^{µ}$∂$^{β}$K Σ ∗ $^{α}$Γ ( ∓ ) µ R$_{αβ}$ − h$_{2}$ ( m$_{K}$ ) $_{3}$∂ $^{µ}$∂$^{α}$∂$^{β}$K Σ ∗ $_{µ}$Γ ( ∓ $^{)}$R$_{αβ}$ + H . c ., (8)\nΓ ( ± ) µ = ( γ$_{µ}$γ$_{5}$ γ$_{µ}$ ) , Γ ( ± ) = ( γ$_{5}$ 1 ) . (9)\nK Σ ∗ · T ( 1 2 , 3 2 )Δ = √$_{3}$$_{K}$ $^{−}$Σ ∗ $^{+}$Δ ++ − √$_{2}$$_{K}$ $^{−}$Σ ∗ $^{0}$Δ + − K $^{−}$Σ$^{∗−}$Δ 0 + K $^{0}$Σ ∗ $^{+}$Δ + − √$_{2}$$_{K}$ $^{0}$Σ ∗ $^{0}$Δ 0 √$_{3}$$_{K}$ $^{0}$Σ $^{∗−}$Δ$^{−}$. (10)\nL γ ΛΣ ∗ = − ief$_{1}$ 2 M$_{Λ}$ Λ γ$_{ν}$γ$_{5}$F $^{µν}$Σ ∗ µ − ef$_{2}$ (2 M$_{Λ}$ ) $_{2}$∂$_{ν}$ Λ γ$_{5}$F $^{µν}$Σ ∗ µ + H . c ., (11)\nL KN Λ = g$_{KN}$$_{Λ}$ M$_{N}$ + M$_{Λ}$ Nγ $^{µ}$γ$_{5}$ Λ ∂$_{µ}$K + H . c ., (12)\nL $_{γNR}$( 3 2$^{±}$ ) = − ief$_{1}$ 2 M$_{N}$ N Γ ( ± ) ν F $^{µν}$R$_{µ}$ − ef$_{2}$ (2 M$_{N}$ ) $_{2}$∂$_{ν}$ N Γ ( ± $^{)}$F $^{µν}$R$_{µ}$ + H . c ., (5)\nL $_{γNR}$( 5 2$^{±}$ ) = ef$_{1}$ (2 M$_{N}$ ) $_{2}$N Γ ( ∓ ) ν ∂ $^{α}$F $^{µν}$R$_{µα}$ − ief$_{2}$ (2 M$_{N}$ ) $_{3}$∂$_{ν}$ N Γ ( ∓ $^{)}$∂ $^{α}$F $^{µν}$R$_{µα}$ + H . c ., (6)\nL γNN = − eN ( γ $^{µ}$A$_{µ}$ Q$_{N}$ − κ$_{N}$ 2 M$_{N}$ σ $^{µν}$∂$_{ν}$ A$_{µ}$ ) N , (4)\nK = ( K $^{−}$, K $^{0}$) , Σ · τ = ( Σ 0 √$_{2Σ}$ + √$_{2Σ}$ − − Σ 0 ) , N = ( p n ) , (3)\nL γKK = ieA$_{µ}$ ( K $^{−}$∂ $^{µ}$K + − ∂ $^{µ}$K $^{−}$K $^{+}$) , (1)\nL KN Σ ∗ = f$_{KN}$$_{Σ}$ ∗ m$_{K}$ ∂$_{µ}$K Σ ∗ µ · τN + H.c. , (2)\n"}]}
+{"image": "doclay/doclay_45448.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Equipment List\n7-2\nFigure 7-1.  A typical 14 CFR part 23 weight and balance record.\nNotes: Unless otherwise indicated, true values (not net  change values) for the weight and arm are shown. Positive  arms are distances aft of the airplane datum; negative  arms are distances forward of the datum. Asterisks (*) in  the weight and arm column indicate complete assembly  installations. Some major components of the assembly are  listed on the lines immediately following. The sum of these  major components does not necessarily equal the complete  assembly installation.\nIn the Item No column, each item is assigned a coded number.  The first two digits of the code represent the assignment  of an equipment item within the ATA Specification 100  breakdown (Chapter 11 for Placards, Chapter 21 for Air  Conditioning, Chapter 77 for Engine Indicating, etc.). These  assignments also correspond to the Maintenance Manual  chapter breakdown for the airplane. Items receive a unique  sequence number (01, 02, 03, etc.). After the sequence  number (and hyphen), a suffix letter is assigned to identify \nThe comprehensive equipment list provides the following  information in column form:\nIn the Wt and Arm columns, you find the weight in pounds  and arm in inches of the equipment item.\nNote: Additional equipment must be installed in accordance  with the reference drawing, service bulletin, or a separate  FAA approval.\nFigure 7-2  is a comprehensive list of all Cessna equipment  that is available for the Model 182S airplane. It should  not be confused with the airplane-specific equipment list.  An airplane-s pecifi c list is provided with each individual  airplane at delivery and is typically found at the end of the  Pilot’s Operating Handbook. The following comprehensive  equipment list and the airplane-specific list have a similar  order of listing.\nIn the Ref Drawing column, a drawing number is provided  that corresponds to the item.\nIn the Equipment List Description column, each item is  assigned a descriptive name to help identify its function. \nThe Federal Aviation Administration (FAA) considers  the addition or removal of equipment included in the  Comprehensive Equipment List to be a minor alteration.  The weights and arms are included with the items in the  equipment list, and these minor alterations can be done and the  aircraft approved for return to service by an FAA-certificate mechanic or repairman. The only documentation required is an  entry in the aircraft maintenance records and the appropriate  change to the weight and balance record in the POH/AFM.  [Figure 7-1]\nan equipment item as required, standard, or optional. Suffix letters are as follows:\n–R = required item or equipment for FAA certificatio\n–S = standard equipment item\n–O = optional equipment item replacing required or standard item(s)\n–A = optional equipment item that is in addition to required or standard items\nWeight and Balance Record (Continuous history of changes in structure or equipment affecting weight and balance) Airplane Model Serial Number Page Number Date Item No. In Out Description of Article or Modification Weight Change Running Basic Empty Weight Added (+) Removed (−) Wt. (lb) Wt. (lb) Arm (in) Moment/ 1,000 Wt. (lb) Arm (in) Moment/ 1,000 Moment/ 1,000 As delivered  1,876  67.8  8-7-09  Alteration per F AA Form 337  Dated 8-7-09  7.38  .346  1,883.4 68.1  34-XX  Turn coordinator   –2.5  15.0  –.037  1,880.9 68.1  34-XX  Directional gyro   –3.12  13.5  –.042  1,877.8 68.1  22-XX  Autopilot system   13.0  32.7  .425  1,890.8 68.5 Cessna 182L 1 18259080"}]}
+{"image": "doclay/doclay_16380.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "8. EXPENSES\nNOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS CONT\n3 months to  31 Mar 2013 $000 12 months to  31 Dec 2012 $000 3 months to  31 Mar 2012 $000 (reviewed) (a) Depreciation  Depreciation of: - Buildings and leasehold improvements 1,157 3,546  877 - Plant and equipment 1,571 5,859 1,326 Total depreciation 2,728 9,405 2,203 (b) Net finance costs Bank loans and overdrafts 6,459 28,061 6,583 Other financing charges   252 1,290  505 Total finance costs 6,711 29,351 7,088 Mark to market valuation of interest rate swaps - (2,219) (778) Net finance costs 6,711 27,132 6,310 (c) Other expenses Provision for employee benefits - Annual leave  337 1,083 301 - Long service leave 68  178 60 Total provision for employee benefits  405 1,261  361 Minimum lease payments – operating leases  2,186 5,433 1,095 Research and development expenses charged directly to administration expense  22 48 - (d) Employee expenses Salaries and wages 8,344 27,052 5,715 Workers’ compensation expense 477 1,493  357 Defined contribution superannuation expense 605 2,387  454 Other employment benefits 334  952  250 Share-based payments expense 130  751 60 Payroll tax 401 1,589  320 10,291 34,224 7,156 (e) Administration and other non-station operating costs Administration and other 5,143 (352) 3,357 Commodity and foreign currency trading expense/(benefit) 851 (3,680) (96) 5,994 (4,032) 3,261\nAnnual Report 2013 77"}]}
+{"image": "doclay/doclay_3617.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Chapter 12. Print Database File Member\nStart Printing from Work with PFD Definitions Display\nOnce you have designed your Print Format Utility application, you can run the application using any of the three following methods:\nv By selecting Print database file from the Work with PFD Definitions display. To get to the Work with PFD Definitions display, use the STRPFU command or STRAFPU option 11.\nv By selecting Print database file from the APFU menu.\nv By running the PRTPFDDTA command.\nTo start printing database file members from the Work with PFD Definitions display, type 9 in the Opt column beside the PFD definition you want to use to print a database file member and then press the Enter key.\nWork with PFD Definitions\nFile . . ........ PFDFILE Name, F4 for list Library........ MYLIB Name, *LIBL, *CURLIB PFD definition ..... *ALL Name, generic*, *ALL Position to....... Starting characters Type options, press Enter. 1=Create 2=Change 3=Copy 4=Delete 6=Print PFD definition 7=Rename 9=Print database file PFD Opt Definition Text Changed 9 PRODUCTLBL PFD exercise 12/13/90 Bottom Parameters or command ===> F3=Exit F4=Prompt F5=Refresh F9=Retrieve F11=Display names only F12=Cancel\n215"}]}
+{"image": "doclay/doclay_42436.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Damage area Insertion Splice angles Damaged area cut out smooth Assembled repair\nDamage area Reinforcements Rib repaired Damaged skin cut  back to smooth contour  with corner radii Assembled repair Stringer insertion Damaged area cut  back so joints will be staggered Section A-A Skin Rib\nFigure 4-186.  Stringer repair by insertion when damage affects  only one stringer. \nFigure 4-187.  Stringer repair by insertion when damage affects  more than one stringer. \nMost damages involve two or more members, but only one  member may be damaged and need repairing. Generally,  if the web is damaged, cleaning out the damaged area and  installing a patch plate are all that is required.\nThe patch plate should be of sufficient size to ensure room for  at least two rows of rivets around the perimeter of the damage  that includes proper edge distance, pitch, and transverse pitch  for the rivets. The patch plate should be of material having the  same thickness and composition as the original member. If  any forming is necessary when making the patch plate, such  as fitting the contour of a lightning hole, use material in the  “0” condition and then heat treat it after forming. \nDamage to ribs and webs, that require a repair larger than a  simple plate, probably needs a patch plate, splice plates, or  angles and an insertion.  [Figure 4-191]\nThe leading edge is the front section of a wing, stabilizer, or  other airfoil. The purpose of the leading edge is to streamline  the forward section of the wings or control surfaces to \nensure effective airflow. The space within the leading edge  is sometimes used to store fuel. This space may also house  extra equipment, such as landing lights, plumbing lines, or  thermal anti-icing systems.\nThe construction of the leading edge section varies with the  type of aircraft. Generally, it consists of cap strips, nose ribs,  stringers, and skin. The cap strips are the main lengthwise \nLeading Edge Repair\n4-106"}]}
+{"image": "doclay/doclay_1231.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Notes to the Consolidated Financial Statements Dollar amounts are in thousands of Canadian dollars (except share and per share amounts)\nNotes to the Consolidated Financial Statements Dollar amounts are in thousands of Canadian dollars (except share and per share amounts)\n10. Other Current Assets\n11. Accounts Payable and Other Liabilities\n12. Mortgages and Loans Payable\nMortgages are collateralized by a first charge on the properties of the Company and vendor mortgages are collateralized by either a  second charge on the property and/or a general corporate guarantee. \nAs of December 31, 2013, unamortized deferred financing costs of $11.9 million (December 31, 2012 ‑ $9.6 million) and mark‑to‑market  premiums on mortgages assumed on acquisition of $1.7 million (December 31, 2012 – $1.7 million) are netted against mortgages and  loans payable.\nRestricted cash consists of security deposits, funds held in trust and property tax reserves.\nAs at December 31,  2013 December 31,  2012 Prepaid property tax $1,389 $1,282 Prepaid insurance 376 335 other prepaids 720 704 restricted cash 6,818 9,979 $9,303 $12,300\nAs at December 31,  2013 December 31,  2012 accounts payable $6,024 $7,450 mortgage interest payable 2,162 1,924 accrued payables 5,015 7,606 rent received in advance 915 808 Dividends payable 2,638 2,609 Taxes payable 1,451 ‑ security deposits 4,195 3,677 Promissory note payable 255 255 $22,655 $24,329\nAs at December 31, 2013 December 31, 2012 Weighted  Average Interest Debt  Balance Weighted  average interest Debt  Balance mortgages and loans payable Fixed rate 4.05% $694,789 4.44% $621,397 Variable rate 4.18% 3,853 4.13% 2,802 Vendor financing 7.10% 488 6.85% 882 Total  $699,130 $625,081 current 153,589 105,369 Non‑current 545,541 519,712 $699,130 $625,081\nKillam ProPerties inc | 2013 83"}]}
+{"image": "doclay/doclay_80178.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "decision, act or certificate of a majority of the  inspectors shall be effective in all respects as the  decision, act or certificate of all. The inspectors of  election shall determine the number of policyholders,  the voting power of each, the policyholders represented  at the meeting or voting by mail, the existence of a  quorum and the authenticity, validity and effect of  proxies. They shall receive votes, hear and determme  all challenges and questions in any way arIsing in  connection with the right to vote, count and tabulate  all votes, determine the result, and do such other  acts as are proper to conduct the vote with fairness  to all polIcyholders. The inspectors of election shall,  before commencing performance of their duties,  subscribe to and file with the insurer and with the  Commissioner an oath that they, and each of them,  will perform their duties impartially, in good faith,  to the best of their ability and as expeditiously as is  practicable. On the request of the insurer, the  Commissioner, a policyholder oi’ his proxy, the  inspectors shall make a report in writing of any  challenge or question or matter determined by them  and execute a certificate of any fact found by them.  They shall also certifY the result of such vote to the  insurer and to the Commissioner. Any report or  certificate made by them shall be  prima facie  evidence of facts stated therein. All necessary  expenses incurred in connection with such election  shall be paid by the insurer. For the purpose of this  section, a quorum shall consist offive percent  (5%)  of the policyholders of such insurer entitled to vote  at such election. \n\"SEC. 272. In carrying out any such plan, the  insurer may acquire any shares of its own stock by  gift, bequest or purchase. Any shares so acquired  shall, unless as a result of such acquisition all of the  shares of the insurer shall have been acquired, be  acquired in trust for the policyholders of the class or  classes for whose benefit the plan provides that the  stock of the insurer shall be acquired as hereinafter  provided. Such shares shall be assigned and  transferred on the books of such insurer and approved \n\"Upon the termination of any such voting trust,  either in accordance with its terms or as hereinabove  provided, such plan of mutualization shall terminate,  unless theretofore completed. Upon such termination,  unless the plan of mutualization provides for the  disposition of the shares acquired by the insurer under  such plan or for the disposition of the proceeds thereof,  the shares held by such trustees shall be disposed of  in accordance with an order of the court of competent  jurisdiction in the judicial district in which is located  the principal office of such insurer, made upon a  verified petition ofthe Commissioner.  . \nby the Commissioner. Such trustees shall hold such  stock in trust until all of the outstanding shares of  capital stock of such insurer have been acquired, but.  for not longer than thirty (30) years with such  extensions of not more than five (5) years each as  may be granted by the Commissioner. Such  extensions may be granted by the Commissioner  if  the plan so provides and if in his opinion the plan of  acquisition of  all  of such stock can be completed within  a reasonable period. Such trustees shall vote such  stock at  all  corporate meetings at which stockholders  have the right to vote. When all the outstanding  shares of capital stock of such insurer have been  acquired, all said shares shall be cancelled., the  certificate of amendment of the insurer’s articles of  incorporation giving effect thereto shall be filed in  accordance with the provisions of the Corporation  Code, and the insurer shall become a nonstock  corporation for the profit of its members and such  trust shall thereupon terminate. Thereafter such  corporation shall be conducted for the mutual benefit,  ratably, of its policyholders of the class or classes for  whose benefit the stock was acquired and shall have  power to issue non-assessable policies on a reserve  basis subject to all provisions of law applicable to  incorporated life insurers issuing non-assessable  policies on a reserve basis. Policies so issued may be  upon the basis of full or partial participation therein  as agreed between the insurer and the insured. \n105 \n104 "}]}
+{"image": "doclay/doclay_67876.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "It is only represented as an  image-type volume  after it reaches the state where it is a  straight-through mapping. An image-type volume cannot be expanded.\nImage-type  disks are used to migrate existing data to an IBM FlashSystem 9100 and to  migrate data out of virtualization. In general, the reason for migrating a volume to an image  type volume is to move the data on the disk to a non virtualized environment.\nIf the migration is interrupted by a cluster recovery, the migration resumes after the recovery  completes.\nThe  migratetoimage  command migrates the data of a user-specified volume by consolidating  its extents (which might be on one or more MDisks) onto the extents of the target MDisk that  you specify. After migration is complete, the volume is classified as an image type volume,  and the corresponding MDisk is classified as an image mode MDisk.\nThe managed disk that is specified as the target must be in an  unmanaged  state at the time  that the command is run. Running this command results in the inclusion of the MDisk into the  user-specified storage pool.\nRemember:  This command cannot be used if the source volume copy is in a child pool or  if the target MDisk group that is specified is a child pool. This command does not work if  the volume is fast formatting.\nThe  migratetoimage  command fails if the target or source volume is offline. Correct the offline  condition before attempting to migrate the volume.\nIf the volume (or volume copy) is a target of a FlashCopy mapping with a source volume in an  active-active relationship, the new managed disk group must be in the same site as the  source volume. If the volume is in an active-active relationship, the new managed disk group  must be located in the same site as the source volume. Additionally, the site information for  the MDisk being added must be well-defined and match the site information for other MDisks  in the storage pool.\nNote:  You cannot migrate a volume or volume image between storage pools if cloud  snapshot is enabled on the volume.\nAn encryption key cannot be used when migrating an image mode MDisk. To use encryption  (when the MDisk has an encryption key), the MDisk must be self-encrypting before  configuring storage pool.\nThe  migratetoimage  command is useful when you want to use your system as a  data mover .  To better understand all requirements and specifications for that command, see IBM  Knowledge Center.\nIf you want to migrate volumes to DRP, you can move them with volume mirroring between  standard pool and DRP. Hosts I/O operations are not disrupted during migration. It is not  supported to change from standard pool to DRP without disruption. Figure 5-14 on page 127  shows volume mirroring migration to change pool types and volume types.\n5.8.3 Migration from Standard Pool to Data Reduction Pool\n126  IBM FlashSystem 9200 and 9100 Best Practices and Performance Guidelines"}]}
+{"image": "doclay/doclay_61562.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "EP 3 800 019 A1\n23\n"}]}
+{"image": "doclay/doclay_38290.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "PART 2 – TERMS OF REFERENCE for LOT 3 \n19. PROVISION OF SERVICES - RE-OPENING OF COMPETITION\nAt the conclusion of this tender procedure, at least 3 contractors will be awarded multiple framework  contracts. These contractors will then be eligible to bid for specific future projects based on the ‘Re- opening of Competition’ procedure, which is explained below: \n ENISA launches a ‘Request for Proposals’ (tender procedure) on a specific subject matter to each of the  contractors awarded a framework contract. The proposal shall only consist of a technical offer and will  not require any administrative paperwork or proof of economic stability to be re-submitted.\n The Framework Contractors will be required to respond typically within 10 - 14 working days with a  detailed technical proposal. This offer will contain all aspects regarding:\n Technical content relevant to the specific subject matter \n Experts proposed ( they should be from the pool of experts already included in the  contract but alternatives can be proposed in exceptional circumstances which are well  documented ) \n A project plan\n Proposed duration of consultancy in person-days \n Cost \n ENISA will evaluate all offers received by the closing date for reception of proposals. A Specific  Contract will be awarded to the best offer in terms of the following award criteria:\n  Quality of the proposal to provide the requested services:  50%\n  Compliance with the technical description:  50%\n Number of person-days and price per person-day required to complete the project  (can be lower  but NOT higher than prices given in original tender) \nPB  = (Person-days x person-day price)\nThe Quality/Price ratio will be set at 70/30. \nFor each Specific Contract the contractor will designate a Project Manager. The Project Manager will be  responsible for overall management of the assignment, the timely completion of the activities and the  quality and timely delivery of the deliverables.\nPrice: \nQuality: \npage 14 of 25 \nF-COD-20-T03:  LOT 3  Audio-visual material development, Journalistic, Public Affairs and Back Office Support"}]}
+{"image": "doclay/doclay_51277.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Introduction\nINFORMATION_SCHEMA  provides access to database  metadata , information about the MySQL server such as the name of a database or table, the data type of a column, or access privileges. Other terms that are sometimes used for this information are  data dictionary  and  system catalog .\nINFORMATION_SCHEMA  provides access to database  metadata , information about the MySQL server such as the name of a database or table, the data type of a column, or access privileges. Other terms that are sometimes used for this information are  data dictionary  and  system catalog .\nINFORMATION_SCHEMA  is a database within each MySQL instance, the place that stores information about all the other databases that the MySQL server maintains. The  INFORMATION_SCHEMA  database contains several read-only tables. They are actually views, not base tables, so there are no files associated with them, and you cannot set triggers on them. Also, there is no database directory with that name.\nAlthough you can select  INFORMATION_SCHEMA  as the default database with a  USE  statement, you can only read the contents of tables, not perform  INSERT ,  UPDATE , or  DELETE  operations on them.\nHere is an example of a statement that retrieves information from  INFORMATION_SCHEMA :\n26.1 Introduction\nINFORMATION_SCHEMA Usage Notes\n•INFORMATION_SCHEMA Usage Notes\n•Character Set Considerations\n•INFORMATION_SCHEMA as Alternative to SHOW Statements\n•INFORMATION_SCHEMA and Privileges\n•Performance Considerations\n•Standards Considerations\n•Conventions in the INFORMATION_SCHEMA Reference Sections\n•Related Information\nmysql>  SELECT table_name, table_type, engine FROM information_schema.tables WHERE table_schema = ’db5’ ORDER BY table_name;\n+------------+------------+--------+ | table_name | table_type | engine | +------------+------------+--------+ | fk | BASE TABLE | InnoDB | | fk2 | BASE TABLE | InnoDB | | goto | BASE TABLE | MyISAM | | into | BASE TABLE | MyISAM | | k | BASE TABLE | MyISAM | | kurs | BASE TABLE | MyISAM | | loop | BASE TABLE | MyISAM | | pk | BASE TABLE | InnoDB | | t | BASE TABLE | MyISAM | | t2 | BASE TABLE | MyISAM | | t3 | BASE TABLE | MyISAM | | t7 | BASE TABLE | MyISAM | | tables | BASE TABLE | MyISAM | | v | VIEW | NULL | | v2 | VIEW | NULL | | v3 | VIEW | NULL | | v56 | VIEW | NULL |\n4769"}]}
+{"image": "doclay/doclay_16600.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "56\nDirectors’ Report 2012\n5.  Key Management Personnel AGL’s key management personnel are responsible for planning, directing and controlling AGL’s activities.\n5.  Key Management Personnel AGL’s key management personnel are responsible for planning, directing and controlling AGL’s activities. Key Management Personnel (KMP) are the people who have authority and responsibility for planning, directing and controlling the activities \nAGL’s key management personnel are responsible for planning, directing and controlling AGL’s activities. Key Management Personnel (KMP) are the people who have authority and responsibility for planning, directing and controlling the activities  of AGL. They are:\nAGL’s KMP during the financial year are listed below. Unless otherwise indicated, they were KMP for the entire period.\nDetails of the KMPs’ remuneration for the financial year are set out below.\n(a) Earned in respect of 2011/2012 financial year and paid in September 2012.\n(b) Includes the value of benefits such as cars, representational spouse travel and entertainment and Fringe Benefits Tax.\n(c) The fair value of LTI SPRs has been calculated using the Black-Scholes and Monte Carlo simulation methods.\n(d) Value of shares acquired under the AGL Share Purchase Plan and other deferred share based payments.\nAll executives are entitled to four weeks annual leave and long service leave based on statutory entitlements.\n(e) Includes salary sacrifice contributions.\n> the Managing Director, who is the Chief Executive Officer\n> the Executives\n> the non-executive Directors of the Board.\nName Position Directors Jeremy Maycock Chairman Les Hosking Non-executive Director Belinda Hutchinson Non-executive Director Sandra McPhee Non-executive Director Max Ould Non-executive Director Bruce Phillips Non-executive Director John Stanhope Non-executive Director Managing Director and Chief Executive Officer Michael Fraser Managing Director and Chief Executive Officer Executives Anthony Fowler Group General Manager Merchant Energy Ken Hodgson  Group General Manager Retail Energy Paul McWilliams Group Head of Corporate Support Services and Company Secretary Stephen Mikkelsen Chief Financial Officer Michael Moraza Group General Manager Upstream Gas\nShort-Term Benefits Post-  Employment Benefits Other Long-Term  Benefits Termination  Benefits Share Based Payments Executives Cash Salary  & Fees  $ Short-  Term   Incentives  $ Non- Monetary  (a) Benefits   $ Other  Short- Term (b)  Benefits $ Super- annuation  $ Retire- ment  Benefits  $ $ $ Rights $ Other Share  (c) Plans  $$^{(d)}$ Total  $ Value of  Equity as a  percentage  of Total Anthony Fowler 646,712  441,000  8,713   –  38,755  (e)  –   –   –  344,746   –  1,479,926  23.3% Michael Fraser 1,609,417 1,976,000  34,339   – 457,250   –   –   – 2,209,095   –  6,286,101  35.1% Ken Hodgson 687,485  475,200   –   –  29,515  (e)  –   –   –  359,582   –  1,551,782  23.2% Paul McWilliams  497,016  256,500  24,142   –  48,775  (e)  –   –   –  170,427 256,500  1,253,360  34.1% Stephen Mikkelsen  754,225  468,000   –   –  15,775   –   –   –  400,964   –  1,638,964  24.5% Michael Moraza 565,308  292,500   –   –  98,727   –   –   –  333,699   –  1,290,234  25.9% Total 4,760,163 3,909,200  67,194   – 688,797   –   –   – 3,818,513 256,500 13,500,367 \nRemuneration of Key Management Personnel for year ended 30 June 2012 (Senior Executives)\n6.  Remuneration disclosures: KMP"}]}
+{"image": "doclay/doclay_11958.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Subaru Automotive Business Unit\nAerospace Company\nIndustrial Products Company\nEco Technologies Company\nOther\nFHI takes pride in offering the highly distinctive and appealing Subaru brand. These automobiles offer superb driving pleasure and safety based on advanced technologies, including our Horizontally-Opposed Engine (“Boxer”), the symmetrical All Wheel Drive (AWD) system and the intelligent continuously variable transmission (I-CVT).\nFHI’s years of know-how and experience in manufacturing large passenger planes, helicopters and unmanned craft form a solid foundation for our continuing R&D in space shuttle technology and other areas. FHI is aiming to become a distinct aircraft manufacturer with a global presence.\nFHI develops and manufactures high-performance engines that constitute the heart of industrial and leisure products. Through our global sales network, Robin brand engines have gained a worldwide reputation for their reliability in a variety of products that people depend on for work and pleasure.\nFHI makes sanitation trucks and separation as a part of its commitment to protecting the environment. Other environmental business includes waste disposal and recycling system as well as cleaning robots and wind turbine generation system.\nAfter-service and renewal of bus bodies and rail cars were the focus of efforts in transportation; as housing, the concentration is on the sale and manufacture of prefabricated units and nursing care rooms. These businesses have terminated new production in 2003.\nUnit1992 First successful recycling in the automobile industry of painted bumpers into exterior/interior parts/Subaru Impreza introduced \n1993 New Legacy series introduced \n1994 OEM supply of “ADvan” from Nissan Motor Co., Ltd., starts \n• Coating-film removal technology using a roller developed \n1995 FHI and SIA receive ISO 9002 certification for quality  management and quality assurance \n• Subaru Sambar EV introduced in Japan \n• Vivio Bistro, a classic-type minicar, launched \n• Subaru captured the Manufacturer’s and Driver’s titles in the World Rally Championship (WRC) \n1996 Based on new coating-film removal technology employing the roller method, bumper-to-bumper recycling introduced \n• Sambar Transcare, a vehicle with an electric lifter for the dis- abled, launched \n• Bumper recovery from domestic market through independ- ent system begun \n• Subaru Development & Engineering Division receives ISO 9002 certification for quality management and assurance \n• Subaru captured third consecutive Manufacturer’s Title in WRC\n1997 Subaru Forester introduced \n• All New Legacy launched\n2003 B11S concept car makes world premier at Geneva motor show \n• Forester full-model change \n2002 Subaru Europe established\n• Traviq launched \n• Sambar nursing care car launched \n2001 Subaru vehicles sold at GM Autoworld in the Philippines and Indonesia \n• Pleo Nicot introduced \n2000 Impreza series full-model change \n• Cumulative production of Subaru AWD vehicles hits 5 million units \n• Gunma Manufacturing Division receives ISO 14001 environ- mental management systems certification \n1999 Sambar series full-model change \n• Legacy B4 introduced \n• Legacy Station Wagon selected 1998-1999 RJC New Car of the Year; Pleo takes first place in the minicar category \n• Subaru Pleo introduced in accordance with changes in minicar standards \n1998 New Century Legacy series launched "}]}
+{"image": "doclay/doclay_59365.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "mysqldump — A Database Backup Program\n• --tz-utc\n• --xml ,  -X\nThis option enables  TIMESTAMP  columns to be dumped and reloaded between servers in different time zones.  mysqldump  sets its connection time zone to UTC and adds  SET TIME_ZONE=’+00:00’  to the dump file. Without this option,  TIMESTAMP  columns are dumped and reloaded in the time zones local to the source and destination servers, which can cause the values to change if the servers are in different time zones.  --tz-utc  also protects against changes due to daylight saving time.  --tz-utc  is enabled by default. To disable it, use  --skip-tz-utc .\nWrite dump output as well-formed XML.\nNULL ,  ’NULL’ , and Empty Values : For a column named  column_name , the  NULL  value, an empty string, and the string value  ’NULL’  are distinguished from one another in the output generated by this option as follows.\nThe output from the  mysql  client when run using the  --xml  option also follows the preceding rules. (See Section 4.5.1.1, “mysql Client Options” .)\nXML output from  mysqldump  includes the XML namespace, as shown here:\nshell>  mysqldump --xml -u root world City <?xml version=\"1.0\"?> <mysqldump xmlns:xsi=\"http://www.w3.org/2001/XMLSchema-instance\"> <database name=\"world\"> <table_structure name=\"City\"> <field Field=\"ID\" Type=\"int(11)\" Null=\"NO\" Key=\"PRI\" Extra=\"auto_increment\" /> <field Field=\"Name\" Type=\"char(35)\" Null=\"NO\" Key=\"\" Default=\"\" Extra=\"\" /> <field Field=\"CountryCode\" Type=\"char(3)\" Null=\"NO\" Key=\"\" Default=\"\" Extra=\"\" /> <field Field=\"District\" Type=\"char(20)\" Null=\"NO\" Key=\"\" Default=\"\" Extra=\"\" /> <field Field=\"Population\" Type=\"int(11)\" Null=\"NO\" Key=\"\" Default=\"0\" Extra=\"\" /> <key Table=\"City\" Non_unique=\"0\" Key_name=\"PRIMARY\" Seq_in_index=\"1\" Column_name=\"ID\" Collation=\"A\" Cardinality=\"4079\" Null=\"\" Index_type=\"BTREE\" Comment=\"\" /> <options Name=\"City\" Engine=\"MyISAM\" Version=\"10\" Row_format=\"Fixed\" Rows=\"4079\" Avg_row_length=\"67\" Data_length=\"273293\" Max_data_length=\"18858823439613951\" Index_length=\"43008\" Data_free=\"0\" Auto_increment=\"4080\" Create_time=\"2007-03-31 01:47:01\" Update_time=\"2007-03-31 01:47:02\" Collation=\"latin1_swedish_ci\" Create_options=\"\" Comment=\"\" /> </table_structure> <table_data name=\"City\"> <row> <field name=\"ID\">1</field> <field name=\"Name\">Kabul</field> <field name=\"CountryCode\">AFG</field> <field name=\"District\">Kabol</field> <field name=\"Population\">1780000</field> </row> ... <row> <field name=\"ID\">4079</field>\nValue: XML Representation: NULL  ( unknown value ) <field name=\" column_name \" xsi:nil=\"true\" /> ’’  ( empty string ) <field name=\" column_name \"></field> ’NULL’  ( string value ) <field name=\" column_name \">NULL</ field>\n494"}]}
+{"image": "doclay/doclay_19212.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "SECTION 7  STAFF COSTS AND REMUNERATION\n7.3  Retirement benefit obligations and similar obligations\nRetirement benefit obligations and similar  obligations comprise payments to retired directors that are not covered by an insur- ance company. The plan is unfunded.\nThe actuarial assumptions underlying the calculations are based on local economic conditions and labour market  conditions.\nThe interest rate cost, DKK 0m, is recognised in the income statement, while the actuarial losses, DKK 3m, are  recognised in other comprehensive income.\nParent Company SECTION 7: STAFF COSTS AND REMUNERATION 157\nCarlsberg Group Annual Report 2013\nOBLIGATIONS\nDKK million 2013 2012 Total obligations at 1 January 45 45 Interest cost - 1 Actuarial losses  3 2 Benefits paid -3 -3 Total obligations at 31 December 45 45 OBLIGATIONS\n2013 2012 Discount rate 1.0% 1.0% Future retirement benefit increases 2.0% 2.0% ASSUMPTIONS APPLIED\nMATURITY OF PENSION OBLIGATIONS DKK million <1  year 1-5  years >5 years Total Pension benefits 3 14 28 45\nASSUMPTIONS APPLIED\nMATURITY OF PENSION OBLIGATIONS"}]}
+{"image": "doclay/doclay_7421.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Statements of Consolidated Shareholders’ Equity\nThe J.M. Smucker Company\n■ ■ ■\nAccumulated Other  Deferred Amount Compre- Total Common Additional Retained Compen- Due From hensive Shareholders’ (Dollars in thousands)  Shares Capital Income sation ESOP Trust Loss Equity Balance at May 1, 2000 $ 7,081 $ 17,190 $317,978 $(3,091) $(9,223) $ (9,327) $ 320,608 Net income 27,206 27,206 Foreign currency translation  adjustment (7,308) (7,308) Comprehensive Income 19,898 Purchase of treasury shares (1,074) (4,027) (75,863) (80,964) Stock plans 83 4,820 843 5,746 Cash dividends declared –  $0.68 a share  (16,095)  (16,095) Tax benefit of stock plans 1,295 1,295 Other 297 297 Balance at April 30, 2001 6,090 19,278 253,226 (2,248) (8,926) (16,635) 250,785 Net income 30,851 30,851 Foreign currency translation  adjustment 1,669 1,669 Minimum pension liability  (797) (797) Comprehensive Income 31,723 Purchase of treasury shares (11) (483) (634) (1,128) Stock plans 138 11,590 (477) 11,251 Cash dividends declared –  $0.68 a share  (15,650)  (15,650) Tax benefit of stock plans 2,799 2,799 Other 364 364 Balance at April 30, 2002 6,217 33,184 267,793 (2,725) (8,562) (15,763) 280,144 Net income 96,342 96,342 Foreign currency translation  adjustment 8,268 8,268 Minimum pension liability  (8,629) (8,629) Loss on available-for-sale securities (296) (296) Gains on cash flow hedging derivatives 236 236 Comprehensive Income 95,921 Merger share exchange (341) 341 — Business acquired 6,506 774,979 781,485 Stock plans 60 5,628 (100) 5,588 Cash dividends declared –  $0.83 a share (41,071) (41,071) Tax benefit of stock plans 1,635 1,635 Other 469 469 Balance at April 30, 2003 $12,442 $815,767 $323,064 $(2,825) $(8,093) $(16,184) $1,124,171\n23\nSee notes to consolidated financial statements."}]}
+{"image": "doclay/doclay_18552.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "49Performance metrics, operation  and standards EBIT and revenue: 75% of each award \nThe table below provides other scenarios, in the absence of any election by the CEO to defer  additional shares. The number of shares is an  assumption based on the closing share price as at 31 December 2012 of €13.30 and a £/€ exchange rate of 1.22.\nIn 2012, the CEO was awarded 97,603  performance shares (in the form of nominal  price options).\nSince the first operation of the EIP, the grant to the CEO has been set by reference to a  percentage of the available pool, rather than by reference to salary. The Committee continues  to believe that de-linking salary and grant  level allows:\nNotes: *Together with a basic award, this takes the maximum award for the CEO would not exceed 160,000 shares.\nNotes: *Together with a basic award, this takes the maximum award for the CEO would not exceed 160,000 shares.\nThe Committee has determined that the  appropriate level of award for the CEO is  normally 20% of the available annual pool,  which represents 0.15% of the issued share  capital of the Company. For 2013, the  Committee determined that this level of award remains appropriate, and is termed the  basic award .\nin total As part of the Shareholders’ approval for the EIP in  2010, the Committee undertook to ensure that the  level of stringency with regard to the attainment  of the performance targets is maintained for  each and every grant under the EIP. To give  comfort to Shareholders that there is integrity in the process, the Committee undertook to  provide full retrospective details of the annual  targets each year. This is set out below.\nThese corporate performance conditions are set annually over the three-year holding period.  For each annual period, a third of this part of  the award (i.e. ¹/ ³  of 75%) is determined based  on the actual performance against the targets  set at the beginning of each year.\nThis is illustrated in the diagram below: \nAs noted in the annual bonus section above, the Committee has introduced a mechanism  that links the amount of deferred shares from the annual bonus plan to the level of  award under the EIP. For each share deferred  (whether compulsorily or voluntarily) an  additional share will be awarded under the EIP.  This will be termed the  invested award .\nBased on the current base pay and bonus  structure, the maximum value of the invested  award is equivalent to 200% of salary. This only  occurs if a maximum bonus is earned and the  CEO elects to take it all in deferred shares.\nand standards EBIT and revenue: 75% of each award  in total As part of the Shareholders’ approval for the EIP in \n■ For more independence between elements  of pay, thereby avoiding an unnecessary  ratchet of pay;\n■ An incentive for the share price to increase;  and\n■ Avoiding overgranting of value if share price  were to dip at the time of grant.\nAny remaining options lapse Exercise period Vested options can be exercised up to  three years after end of holding period Year 3 Measurement period 3 Year 2 Measurement period 2 Year 1 Measurement period 1 Start of  holding period End of  holding period Year 1 revenue  and EBIT  targets set Year 2 revenue  and EBIT  targets set Year 3 revenue  and EBIT  targets set Revenue growth  and EBIT  measured Options vest based on corporate performance\nDeferred EIP invested Invested  Cash shares award award  Bonus earned (% of salary)  % of salary  % of salary  % of salary  shares* Target 100  0  0  0 Target with maximum voluntary deferral  0  100  100  30,954 Maximum 100  100  100  30,954 Maximum with maximum voluntary deferral 0  200  200  61,908"}]}
+{"image": "doclay/doclay_53.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "MGM MIRAGE DEFINES MOMENTUM\nTO OUR SHAREHOLDERS\n“Your company has undergone several defining moments throughout its history.”\nDefining Momentum for Las Vegas\nrom its roots some 35 years ago with the opening of the International Hotel, we have played a  leading role in continuously redefining the Las Vegas experience. F\nWe announced two significant initiatives in 2004 that, taken together, give your company unrivaled momentum  to set industry standards for creativity, performance and responsibility for decades to come. \nOur merger agreement with Mandalay Resort Group and our plans to develop Project CityCenter on the Las Vegas Strip are among the most significant announcements in Las Vegas history. As this fabled city begins its second hundred years, MGM MIRAGE is positioned like no other company to take advantage of unsurpassed growth oppor- tunities in the most dynamic gaming and entertainment market in the world.\nProject CityCenter will uniquely re-position Las Vegas like no other project before it. Far more than simply another casino-hotel, Project CityCenter encompasses a\nmyriad of elements that will propel Las Vegas into a new generation of urban sophistication.\nWhile additional details of this extraordinary develop- ment will come in the months ahead, I am pleased to tell you that we have secured the services of the internationally acclaimed architect Cesar Pelli to design our anchor resort at the heart of Project CityCenter.\nCesar Pelli & Associates has worked with corporate, government and private clients to design major public spaces, museums, airports, research centers, performing arts centers, academic buildings, hotels, office and residential towers and mixed-use projects.\nThe work of Cesar Pelli is not constrained by a personal style or a signature that would limit his architecture; instead, it celebrates the unique characteristics of each project. Using this approach, he has designed several exceptional buildings in the United States and abroad. \nWe are very excited about our partnership with Mr. Pelli and his colleagues and believe they will deliver for MGM MIRAGE and the residents of Southern Nevada  a building of iconic stature around the world.\n02\nBELLAGIO SPA TOWER  The quintessential luxury hotel is now even more opulent. This expansion includes 928 rooms and suites, 80,000 square feet of convention space, retail outlets, and restaurants. \nSHIBUYA  MGM GRAND Designed by superstar team Yabu Pushelberg, Shibuya  features stellar sushi and the widest sake selection this side of the Pacific, all served in a sleek, airy ambiance.CRAVINGS  THE MIRAGE The zenith of all-you-can-eat. Designed by Adam Tihany, Cravings boasts 11 cooking stations, a street of unique restaurants,  and an array of temptations in what’s unquestionably the ultimate buffet dining experience. \nJ. TERRENCE LANNI  Chairman & Chief Executive Officer\n"}]}
+{"image": "doclay/doclay_50661.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "9.2.3 Replica Set High Availability\nFailover Processes\nReplica Set Elections\nFactors and Conditions that Affect Elections\nReplica sets use elections to determine which set member will become primary . Elections occur after initiating a replica set, and also any time the primary becomes unavailable. The primary is the only member in the set that can accept write operations. If a primary becomes unavailable, elections allow the set to recover normal operations without manual intervention. Elections are part of the failover process (page 580).\nIn the following three-member replica set, the primary is unavailable. The remaining secondaries hold an election to choose a new primary.\nBehavior Elections are essential for independent operation of a replica set; however, elections take time to complete. While an election is in process, the replica set has no primary and cannot accept writes and all remaining members become read-only. MongoDB avoids elections unless necessary.\nIf a majority of the replica set is inaccessible or unavailable, the replica set cannot accept writes and all remaining members become read-only.\nHeartbeats Replica set members send heartbeats (pings) to each other every two seconds. If a heartbeat does not return within 10 seconds, the other members mark the delinquent member as inaccessible.\nThe replica set recovers from the loss of a primary by holding an election. Consider the following:\nThe deployment of a replica set affects the outcome of failover situations. To support effective failover, ensure that one facility can elect a primary if needed. Choose the facility that hosts the core application systems to host the majority of the replica set. Place a majority of voting members and all the members that can become primary in this facility. Otherwise, network partitions could prevent the set from being able to form a majority.\nReplica sets provide high availability using automatic failover . Failover allows a secondary member to become pri- mary if primary is unavailable. Failover, in most situations does not require manual intervention.\nReplica set members keep the same data set but are otherwise independent. If the primary becomes unavailable, the replica set holds an election (page 580) to select a new primary. In some situations, the failover process may require a rollback (page 584). 9\n• Webinar: Multi-Data Center Deployment 8\nReplica Set Elections (page 580) Elections occur when the primary becomes unavailable and the replica set members autonomously select a new primary.\nRollbacks During Replica Set Failover (page 584) A rollback reverts write operations on a former primary when the member rejoins the replica set after a failover.\nMongoDB Documentation, Release 3.0.4\nChapter 9. Replication\n580\n$^{8}$https://www.mongodb.com/presentations/webinar-multi-data-center-deployment?jmp=docs\n9 Replica sets remove “rollback” data when needed without intervention. Administrators must apply or discard rollback data manually."}]}
+{"image": "doclay/doclay_45012.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "9.1_SMSM_201904  Originally published April 2019  Uncontrolled copy when downloaded \nDefinitions and Acronyms \nSection 9 \nSafety Promotion. The communication and distribution of information to improve the safety  culture and support the integration and continuous improvement of the SMS within ATO. Safety  Promotion allows ATO to share successes and lessons learned. \nSafety Requirement. A planned or proposed means to reduce a hazard’s causes or effects. \nSafety Requirement Approval. Certification that the safety requirements can and will be  implemented. \nSRM Document. A documented safety analysis for a proposed NAS change or an existing  safety issue. It documents the evidence to support whether or not the proposed NAS change /  existing safety issue is mitigated to an acceptable level from a safety risk perspective.\nSafety Risk Management (SRM).\nSRM Document Approval. Indication that the SRM document was developed properly; that  hazards were systematically looked for and identified if applicable; and if a hazard was identified  or safety risk was negatively impacted, that: 1) risk was appropriately assigned, 2) valid safety  requirements were proposed, and an effective implementation and monitoring plan was  prepared. SRM document approval does not constitute acceptance of the risk associated with  the NAS change or approval to implement the NAS change.  SRM Panel. A diverse group of representatives, stakeholders, and subject matter experts from  the various organizations affected by the NAS change. They conduct an objective safety  analysis and provide findings and recommendations to decision-makers in an SRM document. \nSRM Panel Co-Facilitator. A person who shares responsibilities with the SRM facilitator in  supporting the SRM panel.\nSRM Panel Facilitator. A trained expert on the SRM process who moderates the deliberations  of the SRM panel members from a neutral position. He or she captures the decisions of the  panel members, mediates any disagreements, documents any dissenting opinions, and remains  neutral throughout the process without advocating for a specific outcome. The  facilitator/co-facilitator (or his or her designee) may write the safety document describing the  safety findings of the SRM panel meeting.\nSRM Panel Member. An SRM panel member is a stakeholder who represents the program,  facility, organization, or constituency potentially affected by the safety risk and/or potential  safety requirements associated with the NAS change and/or identified existing safety risk. The  SRM panel members are selected at the discretion of the change proponent and/or panel  facilitator. \nSRM Panel Observer. An SRM panel observer is someone attempting to gain a better  understanding of the SRM process, not the specific NAS change being assessed. An observer  is not an active member of the SRM panel meeting and does not provide input during the  deliberations. SRM panel observers are permitted at the discretion of the change proponent.\n11 8 \n• ATO Definition. The processes and practices used to assess safety risk within the NAS, document NAS changes, and define strategies for monitoring the safety risk of the NAS. SRM complements Safety Assurance.\n• FAA Definition. A process within the SMS composed of describing the system; identifying the hazards; and analyzing, assessing, and controlling risk."}]}
+{"image": "doclay/doclay_62957.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Nov. 17,  2016 \n40 \nUS 2016/0334706 Al \ntrated under reduced pressure. The concentrate was washed  with diisopropyl ether, obtaining 16.8 g of the target com› pound, tetrabutylammonium 2-(24-nor-5-cholane-3,7,12- trion-23-y lcarbony loxy )-1, 1,3 ,3 ,3-pentafluoropropane-1- sulfonate (Additive-4), as oily matter (yield 98%). \n[0154]  The target compound was analyzed by spectros› copy. The data of IR and TOFMS are shown below. The  NMR spectra, $^{1}$H- and $^{19}$F-NMR in DMSO-d$_{6 }$ are shown in  FIGS.  7  and  8.  On lH-NMR analysis, trace amounts of  residual solvents (diisopropyl ether and methyl isobutyl  ketone) and water in DMSO-d$_{6 }$ were observed. \n[0155]  IR (D-ATR): 2963, 2876, 1769, 1711, 1467, 1381,  1250, 1215, 1183, 1168, 1119, 1070, 992, 735, 642 cm- 1 \n[0156]  TOFMS (MALDI) \n[0157]  Positive M+ 242 (corresponding to C$_{16}$H$_{36}$N+) \n[0158]  Negative M- 613  (corresponding to  CF$_{3}$CH  (OCO----C$_{23}$H$_{33}$O$_{3}$ )CF 2 SO$_{3 }$-) \n[0159]  In a flask under nitrogen atmosphere, 32.9 g of  tripheny lsulfonium 2-methacryloy loxy-1, 1,3 ,3 ,3-pentafluo› ropropane-1-sulfonate, 24.1 g of 3-ethyl-3-exo-tetracyclo› [ 4.4.0.12•5 .l 7•10]dodecanyl methacrylate, 10.4 g of 4-hy› droxyphenyl methacrylate, 19.7 g of 4,8-dioxatricyclo-[4.2.  1.0 3 • 7 ]nonan-5-on-2-yl methacrylate, 3.4 g of dimethyl 2,2’› azobis(isobutyrate), 0.69 g of2-mercaptoethanol, and 175 g  of methyl ethyl ketone (MEK) were mixed to form a  monomer solution. Another flask under nitrogen atmosphere  was charged with 58 g ofMEK, which was heated at 80°  C.  with stirring. With stirring, the monomer solution was added  dropwise to the other flask over 4 hours. After the comple› tion of dropwise addition, the polymerization solution was  continuously stirred for 2 hours while maintaining the  temperature of 80° C. The polymerization solution was  cooled to room temperature, whereupon it was added drop› wise to a mixture of 100 g MEK and 900 g hexane. The  precipitate was collected by filtration, washed twice with  600 g of hexane, and vacuum dried at 50°  C. for 20 hours,  obtaining a polymer (P-1) in white powder solid form.  Amount 77 .5 g, yield 89%. The polymer (P-1) has the  structure shown below. \n[0160]  Polymers (or resins) were synthesized by the same  procedure as in Synthesis Example 2-1 aside from changing  the type and amount of monomers. Table 1 shows the  proportion (in molar ratio) of units incorporated in these  polymers, and Tables 2 to 4 show the structure of recurring  units. \nTABLE 1 \nSynthesis Examples 2-2 to 2-15 \nSynthesis of Polymers P-2 to P-15 \nSynthesis of Polymer P-1 \nSynthesis Example 2-1 \nUnit 1  Unit 2  Unit 3  Unit4  Unit 5  Resin  (molar ratio)  (molar ratio) (molar ratio) (molar ratio) (molar ratio)  P-1  PAG Monomer-! (0.20)  A-1 (0.30)  B-1 (0.20)  B-5 (0.30)  P-2  PAG Monomer-2 (0.20)  A-1 (0.30)  B-1 (0.20)  B-5 (0.30)  P-3  PAG Monomer-3 (0.20)  A-1 (0.30)  B-1 (0.20)  B-5 (0.30)  P-4  PAG Monomer-4 (0.20)  A-1 (0.30)  B-1 (0.20)  B-5 (0.30)  P-5  PAG Monomer-5 (0.20)  A-1 (0.30)  B-1 (0.20)  B-5 (0.30)  P-6  PAG Monomer-6 (0.20)  A-1 (0.30)  B-1 (0.20)  B-5 (0.30)  P-7  PAG Monomer-2 (0.20)  A-2 (0.30)  B-1 (0.20)  B-3 (0.30)  P-8  PAG Monomer-2 (0.20)  A-1 (0.20)  A-4 (0.20)  B-1 (0.20)  B-5 (0.20)  P-9  PAG Monomer-2 (0.20)  A-1 (0.20)  A-5 (0.20)  B-1 (0.20)  B-5 (0.20)  P-10  PAG Monomer-2 (0.20)  A-1 (0.20)  A-6 (0.20)  B-1 (0.20)  B-5 (0.20)  P-11  PAG Monomer-2 (0.20)  A-1 (0.20)  A-4 (0.20)  B-5 (0.20)  B-6 (0.20)  P-12  A-3 (0.40)  B-2 (0.10)  B-5 (0.50)  P-13  A-2 (0.40)  B-2 (0.10)  B-3 (0.50)  P-14  A-1 (0.40)  B-2 (0.10)  B-4 (0.50)  P-15  A-1 (0.20)  A-2 (0.30)  B-2 (0.10)  B-5 (0.40) \n(P-1)  cU)a  /  ’j==o  0  Q  usu  ,,e’y,  SO3- cUlb  /  ’j==o  0  cU)c  /  ’j==o  cUJd  /  ’j==o  0  0  Q  OH  0  a~ 0.20, b  ~  0.30, c  ~  -.30, d  ~  0.20 "}]}
+{"image": "doclay/doclay_55413.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "sys Schema Stored Procedures\nGiven a schema name, this procedure creates a synonym schema containing views that refer to all the tables and views in the original schema. This can be used, for example, to create a shorter name by which to refer to a schema with a long name (such as  info  rather than  INFORMATION_SCHEMA ).\nCreates a report of the current server status for diagnostic purposes.\nThis procedure disables binary logging during its execution by manipulating the session value of the sql_log_bin  system variable. That is a restricted operation, so the procedure requires privileges sufficient to set restricted session variables. See Section 5.1.9.1, “System Variable Privileges” .\nData collected for  diagnostics()  includes this information:\n28.4.4.2 The diagnostics() Procedure\nExample\nParameters\n• in_db_name VARCHAR(64) : The name of the schema for which to create the synonym.\n• in_synonym VARCHAR(64) : The name to use for the synonym schema. This schema must not already exist.\n•Information from the  metrics  view (see Section 28.4.3.21, “The metrics View” )\n5183\nmysql>  SHOW DATABASES;\n+--------------------+ | Database | +--------------------+ | information_schema | | mysql | | performance_schema | | sys | | world | +--------------------+\n+---------------------------------------+ | summary | +---------------------------------------+ | Created 63 views in the info database | +---------------------------------------+\n+--------------------+ | Database | +--------------------+ | information_schema | | info | | mysql | | performance_schema | | sys | | world | +--------------------+\n+---------------------------------------+------------+ | Tables_in_info | Table_type | +---------------------------------------+------------+ | character_sets | VIEW | | collation_character_set_applicability | VIEW | | collations | VIEW | | column_privileges | VIEW | | columns | VIEW | ...\nmysql>  CALL sys.create_synonym_db(’INFORMATION_SCHEMA’, ’info’);\nmysql>  SHOW DATABASES;\nmysql>  SHOW FULL TABLES FROM info;"}]}
+{"image": "doclay/doclay_25362.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "of visual cortical processing, setting the balance between opponent ‘On’ and ‘Off’ responses in different locations of the visual receptive field [44]. On the other hand, shunting neural networks are important for various engineering applications [11],[45]-[53]. For example, in vision, shunting lateral inhibition enhances edges and contrast, mediates directional selectivity, and causes adaptation of the organization of the spatial receptive field and of the contrast sensitivity function [11],[45]-[50]. Moreover, such networks are appropriate to be used in medical diagnosis [53]. Therefore, the investigation of the dynamics of $_{SICNNs,}$which are biologically inspired networks designed upon the shunting inhibition concept [11], is important for the improvement of the techniques used in medical diagnosis, adaptive pattern recognition, image processing etc. [45]-[53] and may shed light on neuronal activities concerning shunting inhibition [42]-[44].\nExponential stability of neural networks has been widely studied in the literature (see, for example, [15]-[18],[54]-[60]). According to Liao et al. [54], the exponential stability has importance in neural net- works when the exponentially convergence rate is used to determine the speed of neural computations. The studies [54, 55] were concerned with the exponential stability and estimation of exponential conver- gence rates in neural networks. In the paper [54], Lyapunov-Krasovskii functionals and the linear matrix inequality (LMI) approaches were combined to investigate the problem, whereas the boundedness of the Dini derivative of the neuron input output activations was required in [55]. The exponential stabilization problem of memristive neural networks was considered in [56] by means of the Lyapunov-Krasovskii func- tional and free weighting matrix techniques. Additionally, the Lyapunov-Krasovskii functional method was considered by Wen et al. [61] to analyze the passivity of stochastic impulsive memristor-based piece- wise linear systems, and the free weighting matrix approach was utilized in [57] to derive an LMI based delay dependent exponential stability criterion for neural networks with a time varying delay. On the other hand, exponential stability criteria were derived by Dan et al. [58] for an error system in order to achieve lag synchronization of coupled delayed chaotic neural networks. The concept of lag synchro- nization was taken into account also within the scope of the papers [62] and [63] for memristive neural networks and for a class of switched neural networks with time-varying delays, respectively. Furthermore, the Banach fixed point theorem and the variant of a certain integral inequality with explicit estimate were used to investigate the global exponential stability of pseudo almost periodic solutions of$_{SICNNs}$ with mixed delays in the study [16].\nAlmost periodic and in particular quasi-periodic motions are important for the theory of neural net- works. According to Pasemann et al. [64], periodic and quasi-periodic solutions have many fundamental importances in biological and artificial systems, as they are associated with central pattern generators, establishing stability properties and bifurcations (leading to the discovery of periodic solutions). Besides, the sinusoidal shape of neural output signals is, in general, associated with appropriate quasi-periodic attractors for discrete-time dynamical systems. In the book [65], the dynamics of the brain activity is\n3"}]}
+{"image": "doclay/doclay_11153.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "2003 FORM 10-K\nZIMMER HOLDINGS, INC. AND SUBSIDIARIES\nThe Company will continue to identify and capitalize on external sources of innovative technologies through possible acquisitions of other complementary products, businesses, technology licensing arrangements and strategic alliances. The Zimmer Institute, and the Company’s affiliations with medical teaching institutions, will continue to play an integral role in facilitating training for surgeons, sales associates and other medical professionals on the procedures for applying MIS  techniques to orthopaedic surgery. In addition, the Company has developed and maintains close relationships with a number of orthopaedic surgeons who assist in product research and development.\nAs part of its focused research and development efforts and desire to create breakthrough orthopaedic treatments, the Company has established an Orthobiologics group with its own full-time staff and projects. The Company is actively involved in the field of biologics and is committed to investing in biologics research activities, with a short-term focus on developing products for the spine market, such as a  CopiOs $^{TM}$ calcium phosphate bone void filler. The Company is working to develop biological materials to repair and reinforce damaged or degenerated tissues. These materials potentially could transform treatment of damaged joints by biological regeneration rather than replacement with inert materials.\nOrthobiologics products that are currently marketed for sale include the following: 1) CMI, 2)  Collagraft ˛  Bone Graft Matrix, which is a bone void filler material made of HA/TCP and bovine collagen, and 3)  Denovo ˛ -C, which is an autologous cell implantation service for articular cartilage repair. The Company has also publicly announced certain active or pending research and development activities of the Orthobiologics group. For instance, the Company is collaborating with ISTO Technologies on a project to develop a chondral and osteochondral cartilage graft for cartilage tissue repair and regeneration. The Company is also working with Tissue Science Laboratories plc, a company based in the United Kingdom (‘‘TSL’’), with respect to final development and distribution of the Rotator Cuff Repair Patch, an innovative, nonresorbable biological collagen patch for repair of rotator cuff injuries in the shoulder. This product is being developed and manufactured by TSL.\nThe Company is subject to government regulation with regard to its products and operations in the countries in which it conducts business. It is the policy of the Company to comply with all regulatory requirements applicable to its products and operations.\nIn the United States, numerous regulations govern the development, testing, manufacturing, marketing and distribution of medical devices, including, among others, the Federal Food, Drug and Cosmetic Act and regulations issued or proposed thereunder. The FDA regulates product safety and efficacy, laboratory and manufacturing practices, labeling\nThe Company is subject to various government regulations pertaining to healthcare fraud and abuse, including anti-kickback laws and physician self-referral laws. Violations of these laws are punishable by criminal and/or civil sanctions, including, in some instances, fines, imprisonment and, within the United States, exclusion from participation in government healthcare programs, including Medicare, Medicaid, Veterans Administration (VA) health programs and Civilian Health and Medical Program Uniformed Service (CHAMPUS). The scope and enforcement of these laws and regulations are uncertain and subject to rapid change, especially in light of the lack of applicable precedent and regulations. The Company believes that its operations are in material compliance with these laws.\nGovernment agencies and legislative bodies in the United States and throughout the world influence or regulate medical device payment. The Company believes that its experience in dealing with governmental regulatory requirements, its efficient means of distribution and its emphasis on the ongoing development of efficacious, cost effective and technologically advanced products should enable it to continue to compete effectively within this regulated environment.\nRegulatory requirements affecting the Company and its products have continued to increase. It is the policy of the Company to comply with all regulatory requirements governing its operations and products, and the Company believes that the manufacturing, quality control and internal control procedures that it employs are in material compliance with all applicable regulations.\nIn many of the foreign countries in which the Company markets its products, the Company is subject to local regulations affecting, among other things, product standards, packaging requirements, labeling requirements and import. Many of the regulations applicable to the Company’s devices and products in these countries are similar to those of the FDA. The member countries of the European Union have adopted the European Medical Device Directives, which create a single set of medical device regulations for all member countries. These regulations require companies that wish to manufacture and distribute medical devices in European Union member countries to obtain CE Marks for their products. The Company maintains a certified status with the European and Canadian Notified Bodies, which provides for CE marking of products for these markets.\nand record keeping for medical devices and review of required manufacturers’ reports of adverse experience to identify potential problems with marketed medical devices. A few of the devices developed and marketed by the Company are in a category for which the FDA has implemented stringent clinical investigation and pre-market approval requirements. The FDA has the authority to halt the distribution of certain medical devices; detain or seize adulterated or misbranded medical devices; or order the repair, replacement or refund of the costs of such devices. There are also certain requirements of state, local and foreign governments that must be complied with in the manufacture and marketing of the Company’s products.\nORTHOBIOLOGICS\nGOVERNMENT REGULATIONS AND QUALITY SYSTEMS\n12"}]}
+{"image": "doclay/doclay_3588.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Basic English Language Skills\nASSIGNMENT\n1.  Identify the verb in the following sentence: The grey elephant drinks water from the largest lake in Africa.\n2.  Identify the collective noun in the following sentence: The board of directors voted in favour of the decision.\n3.  Correct the punctuation in the following sentence:\nAnthea will you please buy bread milk and eggs when you go to the  shop. \n4.  Choose the correct word:\nCharles was accepted/excepted into the engineering studies course at  Oxbridge Academy.\n5.  Choose the correct word:\nIts/It’s time to go home now.\n6.  Choose the correct word:\nThey were late for work, because there/their train was delayed.\n7.  Choose the correct word:\nYou’re/Your going to write your exam next week."}]}
+{"image": "doclay/doclay_71540.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "SCHEDULE I AEP TRANSMISSION COMPANY, LLC (AEPTCo Parent) CONDENSED FINANCIAL INFORMATION\nAEP TRANSMISSION COMPANY, LLC (AEPTCo Parent) CONDENSED FINANCIAL INFORMATION CONDENSED STATEMENTS OF CASH FLOWS For the Years Ended December 31, 2020, 2019 and 2018\nCONDENSED STATEMENTS OF CASH FLOWS For the Years Ended December 31, 2020, 2019 and 2018 (in millions)\nSee Condensed Notes to Condensed Financial Information beginning on page S- 18 .\nS-17\nYears Ended December 31, 2020 2019 2018 OPERATING ACTIVITIES Net Income $ 423.4  $ 439.7  $ 315.9  Adjustments to Reconcile Net Income to Net Cash Flows from (Used for) Operating Activities: Equity Earnings of Unconsolidated Subsidiaries (422.3) (438.6) (314.9) Change in Other Noncurrent Liabilities 5.6  11.9  —  Changes in Certain Components of Working Capital: Accounts Receivable, Net (3.4) (6.0) 0.2  Accounts Payable 5.3  18.8  (6.4) Accrued Interest 4.7  3.3  0.9  Other Current Liabilities 32.5  34.6  (1.2) Net Cash Flows from (Used for) Operating Activities 45.8  63.7  (5.5) INVESTING ACTIVITIES Change in Advances to Affiliates, Net (40.3) (51.7) 5.5  Issuance of Notes Receivable to Affiliated Companies (525.0) (615.0) (271.0) Return of Capital Contributions from Unconsolidated Subsidiaries 5.0  —  —  Capital Contributions to Subsidiaries (335.0) —  (664.0) Net Cash Flows Used for Investing Activities (895.3) (666.7) (929.5) FINANCING ACTIVITIES Capital Contributions from Member 335.0  —  664.0  Issuance of Long-term Debt – Nonaffiliated 519.5  688.0  321.0  Retirement of Long-term Debt – Nonaffiliated —  (85.0) (50.0) Dividends Paid to Member (5.0) —  —  Net Cash Flows from Financing Activities 849.5  603.0  935.0  Net Change in Cash and Cash Equivalents —  —  —  Cash and Cash Equivalents at Beginning of Period —  —  —  Cash and Cash Equivalents at End of Period $ —  $ —  $ — "}]}
+{"image": "doclay/doclay_59739.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": " Chapter 1: Understanding Cloud Fundamentals and the Cloud Continuum\n9\nThe term self-service is important here too. With self-service,  the developer of an application, for example, is able to use a  browser or portal interface to acquire appropriate resources  needed to build or operate an application. This just-in-time  model is a more efficient way to ensure that the IT organization  can be responsive to business change.\nA cloud service has to provide a way to measure and meter a  service. Consequently a cloud environment includes a built-in  service that tracks how many resources a customer uses. In  a public cloud, customers are charged for units of resources  consumed. In a private cloud, IT management may implement  a charge back mechanism for departments leveraging services.\nThe cloud is a federated (distributed) environment that pools  resources so they can work together. Making this happen  requires that these resources be optimized to work as though  they were an integrated well-tuned environment comprised of  a variety of workloads. A  workload  is an independent service or  collection of code that can be executed. It’s important in the  cloud that workloads be designed to support the right task  with the right cloud services. For example, some workloads  need to be placed in a private cloud because they require fast  transaction management and a high level of security. Other  workloads may not be so mission critical and can be placed in  a public cloud.\nMany management services are mandatory for ensuring that  cloud computing is a well-managed platform. Security and  governance are key services to ensure that your applications  and data are protected. Data management is also critical  because data may be moving between cloud environments.  All of these services have to be managed and monitored to  ensure that an organization’s level of service is maintained.\nThese materials are the copyright of John Wiley & Sons, Inc. and any  dissemination, distribution, or unauthorized use is strictly prohibited.\nManagement services\nWorkload management\nBilling and metering of service usage\n"}]}
+{"image": "doclay/doclay_80633.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Table of Contents\nITEM 8. FINANCIAL STATEMENTS AND SUPPLEMENTARY DATA\nPART II\nAs noted, the majority of our revenues are generated from the domestic sale of beer, wine, and spirits to wholesale distributors in the U.S. Our other revenue generating activities include the export of certain of our products to select international markets, as well as the sale of our products through state alcohol beverage control agencies and on-premise, retail locations in certain markets. We have evaluated these other revenue generating activities under the disaggregation disclosure criteria outlined within the amended guidance and concluded that these other revenue generating activities are immaterial for separate disclosure. See Note 23 for disclosure of net sales by product type.\nSales reflect reductions attributable to consideration given to customers in various customer incentive programs, including pricing discounts on single transactions, volume discounts, promotional and advertising allowances, coupons, and rebates. This variable consideration is recognized as a reduction of the transaction price based upon expected amounts at the time revenue for the corresponding product sale is recognized. For example, customer promotional discount programs are entered into with certain distributors for certain periods of time. The amount ultimately reimbursed to distributors is determined based upon agreed-upon promotional discounts which are applied to distributors’ sales to retailers. Other common forms of variable consideration include volume rebates for meeting established sales targets, and coupons and mail-in rebates offered to the end consumer. The determination of the reduction of the transaction price for variable consideration requires that we make certain estimates and assumptions that affect the timing and amounts of revenue and liabilities recognized. We estimate this variable consideration by taking into account factors such as the nature of the promotional activity, historical information, and current trends, availability of actual results and expectations of customer and consumer behavior.\nExcise taxes remitted to tax authorities are government-imposed excise taxes on our beverage alcohol products. Excise taxes are shown on a separate line item as a reduction of sales and are recognized in our results of operations when the related product sale is recognized. Excise taxes are recognized as a current liability in other accrued expenses and liabilities, with the liability subsequently reduced when the taxes are remitted to the tax authority.\nCost of product sold The types of costs included in cost of product sold are raw materials, packaging materials, manufacturing costs, plant administrative support and overheads, and freight and warehouse costs (including distribution network costs). Distribution network costs include inbound freight charges and outbound shipping and handling costs, purchasing and receiving costs, inspection costs, warehousing and internal transfer costs.\nSelling, general, and administrative expenses The types of costs included in selling, general, and administrative expenses consist predominately of advertising and non- manufacturing administrative and overhead costs. Distribution network costs are included in cost of product sold. We expense advertising costs as incurred, shown, or distributed. Advertising expense for the years ended February 29, 2020, February 28, 2019, and February 28, 2018, was $769.5 million, $700.8 million, and $615.7 million, respectively.\nForeign currency translation The functional currency of our foreign subsidiaries is generally the respective local currency. The translation from the applicable foreign currencies to U.S. dollars is performed for balance sheet accounts using exchange rates in effect at the balance sheet date and for revenue and expense accounts using a weighted average exchange rate for the period. The resulting translation adjustments are recognized as a component of Accumulated Other Comprehensive Income (Loss) (“AOCI”). Gains or losses resulting from foreign currency denominated transactions are included in selling, general, and administrative expenses.\nCash and cash equivalents Cash equivalents consist of highly liquid investments with an original maturity when purchased of three months or less and are stated at cost, which approximates fair value.\nCash and cash equivalents Cash equivalents consist of highly liquid investments with an original maturity when purchased of three months or less and\nForeign currency translation The functional currency of our foreign subsidiaries is generally the respective local currency. The translation from the\nSelling, general, and administrative expenses The types of costs included in selling, general, and administrative expenses consist predominately of advertising and non-\nCost of product sold The types of costs included in cost of product sold are raw materials, packaging materials, manufacturing costs, plant\n71\n#WORTHREACHINGFOR\nConstellation Brands, Inc. FY 2020 Form 10-K"}]}
+{"image": "doclay/doclay_36541.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "lisions , World Scientific Co., Singapore,1994.\n4\n[11] Z. G. Tan, S. Terranova and A. Bonasera, Int. J. Mod. Phys. E17 No 8(2008)1577-1589;\n[12] Z. G. Tan, A. Bonasera, C. B. Yang, D. M. Zhou and S. Terranova. Int. J. Mod. Phys. E16, Nos.7&8 (2007) 2269-2275"}]}
+{"image": "doclay/doclay_64503.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "US 9,993,863 B2 \n34 \n33 \n(S-3) optionally adjustment of the desired pH value with  an inorganic base, \n(S-4) addition of one or a plurality of compounds that can  react with any formaldehyde still present \n(S-5) preheating of the reaction mixture resulting from the  preceding steps to a temperature in the range from 10  to 50°  C. \n(S-6) optionally addition of further constituents. \n26.  Method according to claim  23,  wherein the total  amount offurfuryl alcohol used is at least 50 wt.% wherein 10  the percentages by weight are relative to the total weight of  the resultant mixture. \n28.  Kit, comprising \nas a first component, a mixture according to claim  1, \nas a second component, an aqueous solution of an acid, \nC. \n*  *  *  *  * \n5 \nC., wherein the reaction mixture comprises a content of free  formaldehyde of max. 0.4 wt. %, and wherein the percent› ages by weight are relative to the total weight of the reaction  mixture; wherein curing preferably takes place at a tempera- ture below 60°  C. "}]}
+{"image": "doclay/doclay_51337.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Performance Schema Replication Tables\nA timestamp in  ’ YYYY-MM-DD hh:mm:ss [. fraction ]’  format that shows when the last transaction processed by this coordinator was committed on the immediate source.\nA timestamp in  ’ YYYY-MM-DD hh:mm:ss [. fraction ]’  format that shows when this coordinator thread started writing the last transaction to the buffer of a worker thread.\n• LAST_PROCESSED_TRANSACTION_START_BUFFER_TIMESTAMP\n• LAST_PROCESSED_TRANSACTION_END_BUFFER_TIMESTAMP\n• PROCESSING_TRANSACTION\n• PROCESSING_TRANSACTION_ORIGINAL_COMMIT_TIMESTAMP\nA timestamp in  ’ YYYY-MM-DD hh:mm:ss [. fraction ]’  format that shows when the last transaction was written to the buffer of a worker thread by this coordinator thread.\nThe global transaction ID (GTID) of the transaction that this coordinator thread is currently processing.\nA timestamp in  ’ YYYY-MM-DD hh:mm:ss [. fraction ]’  format that shows when the currently processing transaction was committed on the original source.\nA timestamp in  ’ YYYY-MM-DD hh:mm:ss [. fraction ]’  format that shows when the currently processing transaction was committed on the immediate source.\nA timestamp in  ’ YYYY-MM-DD hh:mm:ss [. fraction ]’  format that shows when this coordinator thread started writing the currently processing transaction to the buffer of a worker thread.\n• PROCESSING_TRANSACTION_START_BUFFER_TIMESTAMP\n• PROCESSING_TRANSACTION_IMMEDIATE_COMMIT_TIMESTAMP\nWhen the Performance Schema is disabled, local timing information is not collected, so the fields showing the start and end timestamps for buffered transactions are zero.\nThe  replication_applier_status_by_coordinator  table has these indexes:\n•Primary key on ( CHANNEL_NAME )\n•Index on ( THREAD_ID )\nThe following table shows the correspondence between replication_applier_status_by_coordinator  columns and  SHOW REPLICA | SLAVE STATUS columns.\nreplication_applier_status_by_coordinator Column SHOW REPLICA | SLAVE STATUS  Column THREAD_ID None SERVICE_STATE Replica_SQL_Running LAST_ERROR_NUMBER Last_SQL_Errno LAST_ERROR_MESSAGE Last_SQL_Error LAST_ERROR_TIMESTAMP Last_SQL_Error_Timestamp\n27.12.11.8 The replication_applier_status_by_worker Table\n5011"}]}
+{"image": "doclay/doclay_43498.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "However, it also afforded the pilot the opportunity to  use the extra protected airspace to mitigate the need to  conduct a high descent rate, unstabilized approach that  was often necessary as a result of the previous criteria for  the Circling Approach Radius (CAR). For example, under  FAA Order 8260.3 Change 21, a sea level airport with  a 1,500 ft HAA will have CAT C CAR of 2.86 NM, a 1.16  NM (68.5%) increase over pre-Change 21 CAR for CAT C.  This extra protected airspace can be used by the pilot to  maneuver the aircraft instead of being forced to use high  descent rates which are often necessary for high HAA  circling approaches. \nMost commercial operators dictate standard procedures for  conducting instrument approaches in their FAA-approved  manuals. These standards designate company callouts,  flight profiles, configurations, and other specific duties  for each flight deck crewmember during the conduct of  an instrument approach. \nBeginning in February 2000, the FAA began issuing the  current format for instrument approach charts. This chart  was developed by the Department of Transportation  (DOT), Volpe National Transportation Systems Center and  is commonly referred to as the Pilot Briefing Information  format. The FAA chart format is presented in a logical order,  facilitating pilot briefing of the procedures. [Figure 4-3] \nIndividual FAA charts are identified on both the top and  bottom of the page by their procedure name (based on the  NAVAIDs required for the final approach), runway served,  and airport location. The identifier for the airport is also  listed immediately after the airport name. [Figure 4-4] \nThere are several types of approach procedures that may  cause some confusion for flight crews unfamiliar with the  naming conventions. Although specific information about  each type of approach is covered later in this chapter, listed  below are a few procedure names that can cause confusion. \nWhen two or more straight-in approaches with the same  type of guidance exist for a runway, a letter suffix is added  to the title of the approach so that it can be more easily  identified. These approach charts start with the letter Z  and continue in reverse alphabetical order. For example,  consider the (RNAV) (GPS) Z RWY 13C and RNAV (RNP) Y  RWY 13C approaches at Chicago Midway International  Airport. [Figure 4-5] Although these two approaches can  be flown with a global positioning system (GPS) to the \n4-9 \nThe FAA Order 8260.3 Change 21 to the circling protected  airspace afforded much greater obstacle protection. \nPrior to FAA Order 8260.3 Change 21, pilots were often  faced with the challenge of descending using a stabilized  approach concept if the CMDA height above airport  (HAA) exceeded 1,200 feet. Once the HAA approached  1,200 feet, pilots were often forced to increase their rates  of descent in order to arrive at the appropriate “in-slot”  position. “In-slot” being defined as at a minimum, a CAT C  or CAT D turbine-powered airplane should be wings level  on a three degree - 318 ft/NM descent path not less than 1  NM from the touchdown point (1,000 feet beyond runway  threshold). This was due to the small size of the circling  protected airspace that the aircrews must remain within  to ensure obstacle clearance. \nA minimum of 300 feet of obstacle clearance is provided  in the circling segment. Pilots should remain at or above  the circling altitude until the aircraft is continuously in a  position from which a descent to a landing on the intended  runway can be made at a normal rate of descent and using  normal maneuvers. Since an approach category can make  a difference in the approach and weather minimums and,  in some cases, prohibit flight crews from initiating an  approach, the approach speed should be calculated and  the effects on the approach determined and briefed in  the preflight planning phase, as well as reviewed prior to  commencing an approach. \nInstrument Approach Charts \nApproach Chart Naming Conventions \nStraight-In Procedures \nFigure 4-2. Construction of circling approach area. \nA  B  C  D  E  1.3  1.5  1.7  2.3  4.5  Approach category  Radius (miles)  RADII (r) defining size of areas, vary  with the approach category  Circling  approach area  r r r r r"}]}
+{"image": "doclay/doclay_43318.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Chapter 10: Aeronautical Decision-Making and Judgment \nFigure 10-2.  The five hazardous attitudes identified through past and contemporary study.\nRisk  During each flight, the single pilot makes many decisions under hazardous conditions. To fly safely,  the pilot needs to assess the degree of risk and determine the best course of action to mitigate the  risk.\nFor the single pilot, assessing risk is not as simple as it sounds. For example, the pilot acts as his or  her own quality control in making decisions. If a fatigued pilot who has flown 16 hours is asked if  he or she is too tired to continue flying, the answer may be “no.” Most pilots are goal oriented  and when asked to accept a flight, there is a tendency to deny personal limitations while adding  weight to issues not germane to the mission. For example, pilots of helicopter emergency  services (EMS) have been known (more than other groups) to make flight decisions that add  significant weight to the patient’s welfare. These pilots add weight to intangible factors (the  patient in this case) and fail to appropriately quantify actual hazards, such as fatigue or weather,  when making flight decisions. The single pilot who has no other crew member for consultation  must wrestle with the intangible factors that draw one into a hazardous position. Therefore, he  or she has a greater vulnerability than a full crew.\nRisk  During each flight, the single pilot makes many decisions under hazardous conditions. To fly safely, \nAssessing Risk\nRemote Pilot – Small Unmanned Aircraft Systems Study Guide \n54\n"}]}
+{"image": "doclay/doclay_20713.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Macquarie Group Limited and its subsidiaries \n2014 Annual Financial Report \nmacquarie.com.au \nNote 1  Summary of significant accounting policies  continued \n(v) Foreign currency translation\n(vi) Revenue and expense recognition\n106 \nOn consolidation, exchange differences arising from the  translation of any net investment in foreign operations and  of borrowings and other foreign currency instruments  designated as hedges of such investments, are taken to  the foreign currency translation reserve through OCI. When a  foreign operation is disposed of or any borrowings forming part  of the net investment are repaid, such exchange differences are  recognised in the income statement as part of the gain or loss  on disposal.\nGoodwill and fair value adjustments arising on the acquisition  of a foreign entity are treated as assets and liabilities of the  foreign entity and translated at the closing rate.\nDividends and distributions are recognised as income when  the Consolidated Entity becomes entitled to the dividend or  distribution. Dividends from subsidiaries, associates and joint  ventures are recognised in the income statement when the  Company’s right to receive the dividend is established. \nWhen accounting for a dividend or distribution, judgement is  required about whether it is recognised as income or a return  of capital. The range of factors that are considered include: \nNet trading income comprises gains and losses related to  trading assets and liabilities and include all realised and  unrealised fair value changes, dividends and foreign  exchange differences.\nDividends and distributions \nNet trading income \nFees charged for performing a significant act in relation to funds  managed by the Consolidated Entity are recognised as revenue  when that act has been completed. \nOther fee and commission income, including fees from fund  management, brokerage, account servicing, corporate advisory,  underwriting and securitisation arrangements is recognised as  the related services are performed. Where commissions and  fees are subject to clawback or meeting certain performance  hurdles, they are recognised as income at the point when  those conditions can no longer affect the outcome. \nThe results and financial position of all foreign operations that  have a functional currency other than Australian dollars are  translated into Australian dollars as follows: \nSubsidiaries and other entities \nTranslation differences on non-monetary items (such as  equities) held at fair value through profit or loss, are reported as  part of the fair value gain or loss in the income statement.  Translation differences on non-monetary items classified as  available for sale financial assets are included in the available for  sale reserve in equity, unless they form part of fair value hedge  relationships in which case the translation differences  are recognised in the income statement (see note 1(xi)). \nFee and commission income and expenses that are integral  to the effective interest rate on a financial asset or liability  are capitalised and included in the effective interest rate and  recognised in the income statement over the expected life  of the instrument. \nFee and commission income \nTransactions and balances \nForeign currency transactions are recorded in the functional  currency using the exchange rates prevailing at the dates of  the transactions. Foreign exchange gains and losses resulting  from the settlement of such transactions and from the  translation at year end exchange rates of monetary assets and  liabilities denominated in foreign currencies are recognised in  the income statement, except when deferred in OCI as a result  of meeting cash flow hedge or net investment hedge  accounting requirements (see note 1(xi)). \nInterest income is brought to account using the effective  interest method. The effective interest method calculates  the amortised cost of a financial instrument and allocates the  interest income or interest expense over the relevant period.  The effective interest rate is the rate that discounts estimated  future cash receipts or payments through the expected life of  the financial instrument or, when appropriate, a shorter period,  to the net carrying amount of the financial asset or liability. Fees  and transaction costs associated with loans are capitalised and  included in the effective interest rate and recognised in the  income statement over the expected life of the instrument.  Interest income on finance leases is brought to account  progressively over the life of the lease consistent with the  outstanding investment balance.\nRevenue is measured at the fair value of the consideration  received or receivable. Revenue is recognised for each major  revenue stream as follows: \nNet interest income\nFunctional and presentation currency \nItems included in the financial statements of foreign operations  are measured using the currency of the primary economic  environment in which the foreign operation operates (the  functional currency). The Company’s and Consolidated  Entity’s financial statements are presented in Australian  dollars (the presentation currency), which is also the  Company’s functional currency. \n– whether the payment follows a legal process to reduce  either the number of outstanding shares or the amount  of share capital;\n– assets and liabilities for each statement of financial  position presented are translated at the closing exchange  rate at the date of that statement of financial position;  – income and expenses for each income statement are \nrate at the date of that statement of financial position;  – income and expenses for each income statement are  translated at actual exchange rates at the dates of the  transactions; and  – all resulting exchange differences are recognised in OCI \ntransactions; and  – all resulting exchange differences are recognised in OCI  within a separate component of equity – the foreign  currency translation reserve. \nNotes to the financial statements  for the financial year ended 31 March 2014  continued "}]}
+{"image": "doclay/doclay_12488.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "78\nInterest Expense\nAsset Writedown\nOther Revenue\nIncome Taxes\nEquity Earnings from Investees\nNet Income (Loss)\nInterest expense increased from $16.8 million in 1998 to $27.0 million in 1999,  an increase of 60.7%. Interest expense has been allocated to Corus based on an average debt of $300 million in 1999 and an average debt of $187 million in 1998, at Shaw’s average cost of borrowing of 9%.\nIn 1998 Corus recorded a $22.3 million writedown in the carrying value of the invest- ment in Liberty Digital Inc. due to prolonged periods of the carrying value being in excess of market value.\nOther revenue consists of interest and dividend income received from investments. Other revenue was $2.0 million in 1999, compared to $2.9 million in 1998, a decrease of 31%. The decrease was a result of WIC suspending dividend payments in the second quarter of fiscal 1999.\nIncome tax expense in fiscal 1999 of $4.7 million was comprised of current income tax expense of $7.0 million and future income tax recovery of $2.3 million. This repre- sented 44% of income before income taxes. The difference from the statutory tax rate of approximately 45% related to dividend income which is not taxable of $0.9 million, offset by depreciation and amortization on amounts assigned to capital assets on business acquisitions not deductible for tax purposes of $0.8 million.\nEquity earnings from investees increased $1.1 million or 275% to $1.5 million in fiscal 1999 from $0.4 million in fiscal 1998. This increase was primarily a result of improved earnings from TELETOON.\nNet income of Corus increased $11.7 million to $7.4 million in fiscal 1999 from a net loss of $4.3 million in fiscal 1998, as a result of the reasons noted above."}]}
+{"image": "doclay/doclay_31684.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Large microwave generation from d.c. driven magnetic vortex oscillators in magnetic tunnel junctions\nA. Dussaux, 1 B. Georges, 1 J. Grollier, 1 V. Cros, 1 A. V. Khvalkovskiy, 1, 2 A. Fukushima, 3 M.\nKonoto, 3 H. Kubota, 3 K. Yakushiji, 3 S. Yuasa, 3 K.A. Zvezdin, 2, 4 K. Ando, 3 and A. Fert 1\nSpin polarized current can excite the magnetization of a ferromagnet through the transfer of spin angular momentum to the local spin system. This pure spin-related transport phenomena leads to alluring possibilities for the achievement of a nanometer scale, CMOS compatible and tunable microwave generator operating at low bias for future wireless communications. Microwave emission generated by the persitent motion of magnetic vortices induced by spin transfer effect seems to be a unique manner to reach appropriate spectral linewidth. However, in metallic systems, where such vortex oscillations have been observed, the resulting microwave power is much too small. Here we present experimental evidences of spin-transfer induced core vortex precessions in MgO- based magnetic tunnel junctions with similar good spectral quality but an emitted power at least one order of magnitude stronger. More importantly, unlike to others spin transfer excitations, the thorough comparison between experimental results and models provide a clear textbook illustration of the mechanisms of vortex precessions induced by spin transfer.\n1\nAbstract\narXiv:1001.4933v1 [cond-mat.mtrl-sci] 27 Jan 2010\n$^{1}$Unit´ e Mixte de Physique CNRS/Thales and Universit´ e Paris Sud 11, 1 ave A. Fresnel, 91767 Palaiseau, France\n$^{2}$A.M. Prokhorov General Physics Institute of RAS, Vavilova str. 38, 119991 Moscow, Russia\n$^{3}$National Institute of Advanced Industrial Science and Technology (AIST) 1-1-1 Umezono, Tsukuba, Ibaraki 305-8568, Japan\n$^{4}$Istituto P.M. s.r.l., via Cernaia 24, 10122 Torino, Italy"}]}
+{"image": "doclay/doclay_73901.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "relevant AEP System utility affiliates will continue to be affiliates of AEPTCo, (b) suitable replacement arrangements can be obtained in the event that the relevant AEP System utility affiliates are not its affiliates and (c) the underlying easements and other rights are sufficient to permit AEPTCo to operate its assets in a manner free from interruption.\nOperations are subject to extensive federal, state and local environmental statutes, rules and regulations relating to air quality, water quality, waste management, natural resources and health and safety. A majority of the electricity generated by the AEP System is produced by the combustion of fossil fuels. Emissions of nitrogen and sulfur oxides, mercury and particulates and the discharge and disposal of solid waste (including coal-combustion residuals or CCR) resulting from fossil fueled generation plants are subject to increased regulations, controls and mitigation expenses. Compliance with these legal requirements requires AEP to commit significant capital toward environmental monitoring, installation of pollution control equipment, emission fees, disposal and permits at AEP facilities and could cause AEP to retire generating capacity prior to the end of its estimated useful life. Costs of compliance with environmental statutes and regulations could reduce future net income and negatively impact financial condition, especially if emission, CCR waste and/or discharge obligations are tightened, more extensive operating and/or permitting requirements are imposed or additional substances become regulated. Although AEP typically recovers expenditures for pollution control technologies, replacement generation, undepreciated plant balances and associated operating costs from customers, there can be no assurance in the future that AEP will recover the remaining costs associated with such plants. Failure to recover these costs could reduce future net income and cash flows and possibly harm financial condition. \nIn 2014, the Federal EPA issued standards for new, modified and reconstructed units, and a guideline for the development of SIPs that would reduce carbon CO emissions from existing utility units (the Clean Power Plan). In 2019, the Federal EPA repealed the Clean Power Plan, and replaced it with new guidelines called the Affordable Clean Energy (ACE) rule. In January 2021, the U.S. Court of Appeals for the District of Columbia Circuit vacated the ACE Rule and remanded it to the Federal EPA. The new administration has announced addressing climate change as a policy priority. Costs of compliance with the environmental regulation of CO emissions, if any, could reduce future net income and negatively impact financial condition and/or could cause AEP to retire generating capacity prior to the end of its estimated useful life. Although AEP typically recovers environmental expenditures, there can be no assurance in the future that AEP can recover such costs which could reduce future net income and cash flows and possibly harm financial condition. 2 2\nRISKS RELATED TO OWNING AND OPERATING GENERATION ASSETS AND SELLING POWER\nCosts of compliance with existing environmental laws are significant. (Applies to all Registrants except AEP Texas, AEPTCo and OPCo)\nRegulation of CO emissions could materially increase costs to AEP and its customers or cause some electric generating units to be uneconomical to operate or maintain. (Applies to all Registrants except AEP Texas, AEPTCo and OPCo) 2\nCourts adjudicating nuisance and other similar claims in the future may order AEP to pay damages or to limit or reduce emissions. (Applies to all Registrants except AEP Texas, AEPTCo and OPCo)\nIn the past, there have been several cases seeking damages based on allegations of federal and state common law nuisance in which AEP, among others, were defendants. In general, the actions allege that emissions from the defendants’ power plants constitute a public nuisance. The plaintiffs in these actions generally seek recovery of damages and other relief. If future actions are resolved against AEP, substantial modifications or retirement of AEP’s existing coal-fired power plants could be required, and AEP might be required to purchase power from third-parties to fulfill AEP’s commitments to supply power to AEP customers. This could have a material impact on revenues. In addition, AEP could be required to invest significantly in additional emission control equipment, accelerate the timing of capital expenditures, pay damages or penalties and/or halt operations. Unless recovered, those costs could reduce future net income and cash flows and harm financial condition. Moreover, results of operations and financial position could be reduced due to the timing of recovery of these investments and the expense of ongoing litigation.\n44"}]}
+{"image": "doclay/doclay_75650.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "CORPORATE GOVERNANCE\nCompensation\n7\nExpiration date Exercise price (3) (in euro) Terms of exercise Cumulative number  of shares purchased  as of Aug. 31, 2013 Cumulative  number of options  cancelled (5) Options  out-standing as of  Aug. 31, 2013 December 12, 2017 51.40 25% at each  anniversary date 6,500 4,750 46,750 December 12, 2017 51.40 17.5% at each anniversary  date 50% at the  3rd anniversary date (4) 40,493 13,384 429,623 December 12, 2017 51.40 12.5% at each anniversary  date 30% at the  3rd anniversary date (4) 6,875 0 48,125\n7\n319\nSodexo  - Registration Document Fiscal 2013\nExercise price (1) (in USD) Exercise terms Number of options  exercised as  of Aug. 31, 2013 Cumulative  number of options  canceled (2) Options outstanding  as of Aug. 31, 2013 29.9890 25% at each  anniversary date 101,899 12,791 0"}]}
+{"image": "doclay/doclay_39495.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "\nYou must submit your tender electronically via e-Submission available from the e-Tendering website before  the time limit for receipt of tenders. \nThe e-Submission application allows economic operators to respond to calls for tenders by preparing their  tenders electronically in a structured and secured way, and submitting their tenders electronically. The TED e- Tendering is the starting point for launching the e-Submission application. \nMake sure you submit your tender on time: you are advised to start completing your tender early. To  avoid any complications with regard to late receipt/non receipt of tenders within the deadline, please  ensure that you submit your tender several hours before the deadline. A tender received after the  deadline indicated in the procurement documents will be rejected.\n1.  How to Submit your Tender in e-Submission \nYou can access e-Submission via the corresponding call for tender in TED e-Tendering, as specified in  Section 12 of the Tender Specifications. \nIn order to have access to e-Submission, you will need to \"Subscribe to call for tenders\" on TED e-Tendering  first. To subscribe, you will need to login with your an EU Login$^{1}$. In case you don't have an EU Login, you can  create an account at any moment. For more information see the EU login help. After logging in with your EU  Login password, the e-Tendering will then display a button ‘Submit your tender’ and you will be able to access  the e-Submission. \nIn order to submit a tender using e-Submission, tenderers (each member of the group in the case of a joint  tender) will need to register in the European Commission's Participant Register - an online register of  organisations participating in EU calls for tenders or proposals. On registering each organisation obtains a  Participant Identification Code (PIC, 9-digit number) which acts as its unique identifier in the above  register. Instructions on how to create a PIC can be found in the PIC-management Quick Guide for Economic  Operators. Tenderers already registered in the Participant Register shall reuse their existing PICs when  preparing tenders in e-Submission. \n2.  Information to be filled in \n■  Signed Declaration of Honour  (DoH):  All members of a joint tender, including subcontractors (if  applicable) must upload the signed and dated DoH(s) available at  https://emsa.europa.eu/work/procurement/calls.html,\nIn e-Submission fill in and upload all necessary fields and documents as appropriate. All tenders must be  clear, complete and consistent with all the requirements laid down in the Tender Specifications, including: \n$^{1}$ Previously called European Commission authentication system (ECAS) \nAppendix I to the Tender Specifications\nPage 1 of 4 \nAPPENDIX I – e-Submission Guidelines"}]}
+{"image": "doclay/doclay_33447.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "2\nH (4) = ∑ a [ − ⃗ p 4 a 8 + πZ 2 δ $^{3}$( r$_{a}$ ) + Z 4 ⃗ σ$_{a}$ · ⃗ r$_{a}$ r 3 a × ⃗ p$_{a}$ ] + a<b { − π δ $^{3}$( r$_{ab}$ ) − 1 2 p i a ( δ ij r$_{ab}$ + r i ab r j ab r 3 ab ) p j b − 2 π 3 ⃗ σ$_{a}$ · ⃗ σ$_{b}$ δ $^{3}$( r$_{ab}$ ) + σ i a σ j b 4 r 3 ab ( δ ij − 3 r i ab r j ab r 2 ab ) + 1 4 r 3 ab [ 2 ( ⃗ σ$_{a}$ · ⃗ r$_{ab}$ × ⃗ p$_{b}$ − ⃗ σ$_{b}$ · ⃗ r$_{ab}$ × ⃗ p$_{a}$ ) + ( ⃗ σ$_{b}$ · ⃗ r$_{ab}$ × ⃗ p$_{b}$ − ⃗ σ$_{a}$ · ⃗ r$_{ab}$ × ⃗ p$_{a}$ )] } . (7) The finite nuclear mass correction to the Breit contri-\nE ( n ) = E ( n ) ∞ + E ( n ) M + E ( n ) M 2 + . . . , (2)\nH (4) rec = Zm 2 M ∑ ab [ ⃗ r$_{a}$ r 3 a × ⃗ p$_{b}$ · ⃗ σ$_{a}$ − p i a ( δ ij r$_{a}$ + r i $_{a}$r j a r 3 a ) p j b ] . (8)\nH (2) ≡ H$_{0}$ = ∑ a ( ⃗ p 2 a 2 − Z r$_{a}$ ) + ∑ a<b 1 r$_{ab}$ . (3)\nE E (5) ∞ (log) = 14 3 ln( Zα ) ∑ $_{a<b}$〈 δ $^{3}$( r$_{ab}$ ) 〉 + 4 Z 3 ln [ ( Zα ) − 2 ] ∑ a 〈 δ $^{3}$( r$_{a}$ ) 〉 , (9)\nE (5) ∞ (nlog) = 164 15 ∑ $_{a<b}$〈 δ $^{3}$( r$_{ab}$ ) 〉 − 14 3 ∑ a<b ˜ Q$_{ab}$ + [ 19 30 − ln ( k$_{0}$ Z 2 )] 4 Z 3 a 〈 δ $^{3}$( r$_{a}$ ) 〉 + 〈 H (5) fs 〉 , (10)\nE (2) M = − m M E (2) ∞ + 〈 H (2) rec 〉 , (4)\nE (2) M 2 = ( m M ) 2 E (2) ∞ − 2 m M 〈 H (2) rec 〉 + 〈 H (2) rec 1 ( E 0 − H$_{0}$ ) $_{′}$H (2) rec 〉 , (5)\n˜ Q$_{ab}$ = 〈 1 4 πr 3 ab + δ $^{3}$( r$_{ab}$ ) ln Z 〉 , (11) and the singular operator r − 3 is defined by\n〈 1 r 3 〉 ≡ lim a → 0 ∫ d $^{3}$r φ $^{∗}$( ⃗ r ) φ ( ⃗ r ) × [ 1 r 3 Θ( r − a ) + 4 π δ $^{3}$( r ) ( γ + ln a ) ] , (12)\nH (2) rec = m M ∑ a<b ⃗ p$_{a}$ · ⃗ p$_{b}$ (6)\n[9],\nwhere E ( n ) ≡ mα $^{n}$E ( n ) is a contribution of order α n and may include powers of ln α . Each of E ( n ) is in turn ex- panded in powers of the electron-to-nucleus mass ratio m/M\nwhere E ( n ) M denotes the correction of first order in m/M and E ( n ) M 2 is the second-order correction. To note, for the nonrelativistic energy, it is more natural to expand in m$_{r}$/M (where m$_{r}$ is the reduced mass) rather than in m/M , since such expansion has smaller coefficients. For the relativistic corrections, however, the natural recoil expansion parameter is m/M , so for consistency we use it for the nonrelativistic energy as well.\n( )] The finite nuclear mass correction to the Breit contri- bution E (4) M is conveniently separated into the mass scal- ing, the mass polarization, and the operator parts. The mass scaling prefactor is ( m$_{r}$/m ) 4 for the first term in Eq. (7) and ( m$_{r}$/m ) $^{3}$, for all the others. The mass po- larization part represents the first-order perturbation of E (4) ∞ by the mass-polarization operator (6). The opera- tor part is given by the expectation value of the recoil addition to the Breit-Pauli Hamiltonian,\nThe terms of the double perturbation expansion (1) and (2) are expressed as expectation values of some effec- tive Hamiltonians (in some cases, of nonlocal operators) and as second- and higher-order perturbation corrections induced by these Hamiltonians (operators). It is note- worthy that the expansion (1) is employed also for the states that are mixed by the relativistic effects, namely 2 $^{1}$P$_{1}$ and 2 $^{3}$P$_{1}$ . The mixing effects are treated pertur- batively. (So, the leading effect due to the 2 $^{1}$P$_{1}$ − 2 $^{3}$P$_{1}$ mixing appears naturally as the second-order mα 6 cor- rection, together with contributions from other interme- diate states.) This differs from the approach used, e.g., in Ref. [5], where a two-by-two matrix was constructed for this pair of states and the energies were obtained by a diagonalization.\nE (5) ∞ is the leading QED correction [2, 3]. We divide it into the logarithmic and the nonlogarithmic parts, E (5) ∞ = E (5) ∞ (log) + E (5) ∞ (nlog), which are given by ∑\nThe leading contribution to the energy E (2) ∞ ≡ E 0 is the eigenvalue of the nonrelativistic Hamiltonian,\nand\nwhere\nThe first- and second-order recoil corrections to the non- relativistic energy are given by\nwhere\n˜ and the singular operator r − 3 is defined by\nis the mass polarization operator.\nThe leading relativistic correction E (4) ∞ is given by the expectation value of the Breit-Pauli Hamiltonian H (4)"}]}
+{"image": "doclay/doclay_63584.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "149 \nUS 9,904,167 B2 \n150 \nTABLE 2-continued \nCompound (for Examples)  Compound (A13)  Compound (A14)  Compound (A15)  Compound (A16)  Chemical Formula  0-1--0  e  ~ ~  r?’i  03S  )tJ-:1  0  Q  cx::o "}]}
+{"image": "doclay/doclay_63310.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "153 \nUS 9,958,775 B2 \n154 \n-CH9  0  I  O=S=O  F*F  F  F  F  F  SO3  0  -continued  Ab-247  20  25  30  35  40  45  50  Ab-248 55  60  65 \nCH3  I  ---f-CH2-C+-- OAO  ¢  OH  0  I  O=S=O  F*F  F  F  F  F  CC:D  O=S=O  I  00 \nAb-249 \n[Chem. 92] \n-continued \n-CH9  -continued "}]}
+{"image": "doclay/doclay_50498.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "NumInteriorRings(), 45 NumPoints(), 45 old_passwords, 43 ORACLE, 45 Overlaps(), 45 PASSWORD(), 43 performance_timers, 47 perror, 50 PointFromText(), 45 PointFromWKB(), 45 PointN(), 45 PolyFromText(), 45 PolyFromWKB(), 45 PolygonFromText(), 45 PolygonFromWKB(), 45 POSTGRESQL, 45 pre-5.1 database name conversion, 46 PROCEDURE ANALYSE(), 46 Qcache_free_blocks, 44 Qcache_free_memory, 44 Qcache_inserts, 44, 44 Qcache_lowmem_prunes, 44 Qcache_not_cached, 44 Qcache_queries_in_cache, 44 Qcache_total_blocks, 44 query cache, 43 query_cache_limit, 44 query_cache_min_res_unit, 44 query_cache_size, 44 query_cache_type, 44 query_cache_wlock_invalidate, 44 RESET QUERY CACHE, 43 resolveip, 47 resolve_stack_dump, 48 secure_auth, 44 SESSION_STATUS, 47 SESSION_VARIABLES, 47 setup_timers, 47 show_compatibility_56, 47 Slave_heartbeat_period, 47 Slave_last_heartbeat, 47 Slave_received_heartbeats, 47 Slave_retried_transactions, 47 Slave_running, 47 spatial functions, 45 SQL mode, 45 SQL_CACHE, 44 sql_log_bin, 44 SRID(), 45 StartPoint(), 45 sync_frm, 44 thread states, 44 time_format, 44 Touches(), 45\n5527"}]}
+{"image": "doclay/doclay_32857.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "GLYPH<s45>GLYPH<s56> GLYPH<s45>GLYPH<s52> GLYPH<s48> GLYPH<s52> GLYPH<s56> GLYPH<s48> GLYPH<s53> GLYPH<s49>GLYPH<s48> GLYPH<s49>GLYPH<s53> GLYPH<s48> GLYPH<s49> GLYPH<s50> GLYPH<s51> GLYPH<s52> GLYPH<s48> GLYPH<s51> GLYPH<s54> GLYPH<s57> GLYPH<s32> GLYPH<s32> GLYPH<s69> GLYPH<s98> GLYPH<s32> GLYPH<s47> GLYPH<s32> GLYPH<s107> GLYPH<s66> GLYPH<s84> GLYPH<s97> GLYPH<s49>GLYPH<s32>GLYPH<s47>GLYPH<s32> GLYPH<s110> GLYPH<s49>GLYPH<s47>GLYPH<s51> GLYPH<s97> GLYPH<s115> GLYPH<s32> GLYPH<s32> GLYPH<s32> GLYPH<s77>GLYPH<s70> GLYPH<s32> GLYPH<s84> GLYPH<s32> GLYPH<s61> GLYPH<s32> GLYPH<s84> GLYPH<s112> GLYPH<s32> GLYPH<s32> GLYPH<s32> GLYPH<s32> GLYPH<s77>GLYPH<s70> GLYPH<s32> GLYPH<s84> GLYPH<s32> GLYPH<s61> GLYPH<s32> GLYPH<s32> GLYPH<s48> GLYPH<s32> GLYPH<s32> GLYPH<s32> GLYPH<s32> GLYPH<s118>GLYPH<s97>GLYPH<s99>GLYPH<s117>GLYPH<s117>GLYPH<s109>GLYPH<s32> GLYPH<s53> GLYPH<s48> GLYPH<s50> GLYPH<s51> GLYPH<s51>GLYPH<s46>GLYPH<s57>GLYPH<s52> GLYPH<s32> GLYPH<s32> GLYPH<s69> GLYPH<s98> GLYPH<s32> GLYPH<s47> GLYPH<s32> GLYPH<s107> GLYPH<s66> GLYPH<s84> GLYPH<s97> GLYPH<s84> GLYPH<s32> GLYPH<s47>GLYPH<s32> GLYPH<s84> GLYPH<s97> GLYPH<s49> GLYPH<s32> GLYPH<s47> GLYPH<s32> GLYPH<s110> GLYPH<s49> GLYPH<s47> GLYPH<s51> GLYPH<s97> GLYPH<s115> GLYPH<s32> GLYPH<s61>GLYPH<s32> GLYPH<s32> GLYPH<s53>GLYPH<s46>GLYPH<s53> GLYPH<s52>GLYPH<s46>GLYPH<s53>\nFIG. 1: Binding energy of Feshbach molecules in molecular-BEC state. The solid and dashed lines are binding energies at T = T$_{p}$ and T = 0K. The dotted line is the binding energy in vacuum, E$_{b}$$_{0}$ = ¯ h $^{2}$/ ( ma 2 $_{s}$). The inset shows the temperature dependence of the binding energy for different n 1 / $^{3}$a$_{s}$ .\nwhere I is the identity matrix. The molecular excitation is gapless in the long-wavelength limit, k = 0 and ω = 0, following Eq. (4). At small k and ω , to the leading order of k , the molecular excitation frequency is linearly dispersed. The detail of molecular excitations will be studied in our future work.\nThe binding energy E$_{b}$ of a Feshbach molecule in the molecular-BEC state is defined as the energy difference between two atomic and one molecular excitations at k = 0. Since the molecular excitation energy is gapless in the molecular-BEC state, the binding energy of Feshbach molecules is twice the energy gap of atomic excitations, E$_{b}$ = 2 E$_{0}$ . Due to many-body effect, the binding energy E$_{b}$ is different from its vacuum value E$_{b}$$_{0}$ = ¯ h $^{2}$/ ( ma 2 $_{s}$). At the superfluid transition temperature T$_{p}$ , the binding energy is given by E$_{b}$ ( T$_{p}$ ) = − 2 µ $^{′}$. In the limit of weakly-attractive interaction, n 1 / $^{3}$a$_{s}$ → 0 $^{−}$, we obtain\nC. Binding energy\nE$_{b}$ ( T$_{p}$ ) = 16 πζ − 2 / $^{3}$(3 / 2) n 2 3 | a$_{s}$ | $^{2}$k$_{B}$ T$_{a}$,\nwhere ζ ( x ) is the Riemann-zeta function and T$_{a}$ is the ideal BEC temperature, T$_{a}$ = (2 π ¯ h $^{2}$/mk$_{B}$ )[ n/ζ (3 / 2)] 2 / $^{3}$; in the limit of weakly repulsion, n 1 / $^{3}$a$_{s}$ → 0 $^{+}$, the binding en-\n5"}]}
+{"image": "doclay/doclay_65882.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "that are online are currently viewing the same content and/or the same section).\n[0066] FIG. 6B illustrates an example user interface 604 that visually notifies a user of a section of a shared data unit that has received a high level of attention (e.g., a large number of users have recently switched to view content in a “hot” or “popular” section of a shared data unit). Again, in this example, graphical representations of users that have access to the shared data unit (e.g., a digital canvas) are dispersed around the edge of the user interface 604 in order to identify the users, their presence or lack thereof, and/or the location of the different content being edited relative to the content currently displayed.\n[0067] In this example, the visual appearance of one of the graphical representations (e.g., “KL”) is altered to indicate that the content and/or the section currently being worked on by “KL” has recently received, a high level of attention 606. Similar to the discussion above, an altered visual appearance can include flashing, a change in colors, a change in fill pattern, a change in size, etc.\n[0068] To determine whether a high level of attention has been reached in this example, the system may track the number of users that have viewed the content and/or a particular section over a time period (e.g., the most recent ten minutes, the most recent thirty minutes, the most recent day, the most recent week, etc.) and compare the number of users to a threshold number. If the number exceeds the threshold, then the content and/or the section qualifies as having received a high level of attention. In some instances, the threshold can be established based on a predetermined percentage of a total number of users that have access to the shared data unit (e.g., 10%, 20%, 30%, 40%, 50%, etc.).\n[0069] FIG. 7 illustrates an example user interface 700 that contains a dashboard of shared data units to which a user has access. As shown, the user interface 700 can separate shared data units for which attention is requested from a user from other shared data units. That is, a first section 702 may prioritize shared data units for which a user (e.g., “AB”) is being requested to review content, and a second section 704 may contain data units with content for which the user (e.g., “AB”) is not being requested to review content. As shown via the graphical elements on the data units, user “DS” is requesting that user “ AB”review content in “DataXYZ”, user “GR” is requesting that user “AB” review content in “DataABC”, and users “CB” and “LW” are requesting that user “AB” review content in “Datal23”. Accordingly, the dashboard can provide a quick snapshot of how many people are requesting the attention of “AB”, as well as a number of data units that need attention.\n[0070] In various examples, the notification (e.g., the user interface element) indicating that a user’sattention has been requested is configured to persist on a display screen for a"}]}
+{"image": "doclay/doclay_72641.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Critical Audit Matters\nThe critical audit matters communicated below are matters arising from the current period audit of the consolidated financial statements that were communicated or required to be communicated to the audit committee and that: (1) relate to accounts or disclosures that are material to the consolidated financial statements and (2) involved our especially challenging, subjective, or complex judgments. The communication of critical audit matters does not alter in any way our opinion on the consolidated financial statements, taken as a whole, and we are not, by communicating the critical audit matters below, providing separate opinions on the critical audit matters or on the accounts or disclosures to which they relate.\nAs discussed in Note 1(k) to the consolidated financial statements, the Company recorded passenger travel revenue of $38.8 billion for the year ended December 31, 2019. Passenger travel revenue includes an estimate for the amount of revenue recognized for tickets that will expire unused in whole or in part. The percentage of passenger tickets that are expected to expire unused is estimated based on an analysis of the Company’s historical data.\nWe identified the evaluation of estimated passenger travel revenue as a critical audit matter. A high degree of auditor judgment was required to assess the underlying assumption made by the Company to develop this estimate.\nThe primary procedures we performed to address this critical audit matter included the following. We tested certain internal controls over the Company’s passenger revenue recognition process, including controls related to the estimation of the percentage of passenger tickets that are expected to expire unused. We assessed the Company’s estimate of the percentage of passenger tickets expected to expire unused by comparing previous years’ estimates to the actual percentage of passenger tickets expired unused for the year. We evaluated the estimated amount of revenue recorded in the current year related to passenger tickets that are expected to expire unused by developing an independent expectation using actual historical ticket expirations. We compared our independent expectation to that of the Company.\nAs discussed in Note 1(k) to the consolidated financial statements, the Company applies a relative selling price approach whereby the total amount collected from each applicable passenger ticket sale is allocated between the air transportation and the mileage credits earned. The mileage credits earned are deferred and recognized in passenger revenue at the time mileage credits are redeemed and transportation is provided. The Company estimates the selling price of mileage credits earned through travel using an approach based on inputs and assumptions derived from historical data. Additionally, an adjustment is made to the estimated selling price of mileage credits earned to account for the estimate of mileage credits not expected to be redeemed. The Company’s loyalty program liability was $8.6 billion as of December 31, 2019, and the associated passenger revenue for mileage credits redeemed for travel was $3.2 billion for the year ended December 31, 2019.\nWe identified the assessment of the estimated selling price for mileage credits earned through travel, including the estimated number of mileage credits not expected to be redeemed, as a critical audit matter. A high degree of auditor judgment was required to evaluate the historical data used to develop the estimate.\nThe primary procedures we performed to address this critical audit matter included the following. We tested certain internal controls over the Company’s loyalty program accounting process, including controls related to the estimation of the selling price for mileage credits earned through travel. We evaluated that the Company’s methodology used to develop the estimated selling price of mileage credits earned through travel, including estimated mileage credits not expected to be redeemed, was consistent with that of historical periods. We performed sensitivity analyses over the estimated selling price of mileage credits earned through travel, including estimated mileage credits not expected to be redeemed. We assessed the results of the sensitivity analyses to the Company’s recorded amount of loyalty program liability and the associated passenger revenue. We compared the Company’s estimate of mileage credits not expected to be redeemed to that of other airlines within the industry.\n/s/ KPMG LLP\nWe have served as the Company’s auditor since 2014.\nDallas, Texas February 19, 2020\n71\nEvaluation of estimated passenger travel revenue\nAssessment of the estimated selling price for mileage credits earned through travel"}]}
+{"image": "doclay/doclay_14433.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Radian Group Inc.\nNotes to Consolidated Financial Statements - (Continued)\nThe effect of unrecognized tax benefits on our consolidated balance sheets and results of operations is as follows: \nA reconciliation of the beginning and ending unrecognized tax benefits is as follows: \nWe have taken a position in various jurisdictions that we are not required to remit taxes with regard to the income  generated from our investment in certain partnership interests.  Although we believe that these tax positions are more likely than  not to succeed if adjudicated in a court of last resort, measurement under this standard of the potential amount of liability for  state and local taxes and the potential for penalty and interest thereon is performed on a quarterly basis. Our net unrecognized  tax benefits related to prior years increased by approximately  $23.0 million. This net increase primarily reflects the impact of  unrecognized tax benefits associated with our recognition of certain premium income.  Although unrecognized tax benefits for  this item decreased by approximately $23.3 million due to the expiration of the applicable statute of limitations for the taxable  period ended December 31, 2008, the related amounts continued to impact subsequent years resulting in a corresponding  increase to the unrecognized tax benefits related primarily to the 2009 taxable year .\nIn January 2013, we were notified that  Appeals rejected our latest settlement of fer and plans to issue a formal notice of  deficiency within three to six months. Based on these recent developments, we do not currently believe that a settlement is  likely, in which case we would likely litigate the disputed amounts. Over the next twelve months, if we determine that a  compromised settlement cannot be reached with  Appeals, then it is estimated that approximately  $65.2 million of unrecognized  tax benefits in the above tabular reconciliation may be reversed pursuant to the accounting standard for uncertain tax positions.\nIn the event we are not successful in defense of our tax positions taken for U.S. Federal income tax purposes, and for  which we have recorded unrecognized tax benefits, then such adjustments originating in NOL  or NOL carryback years may  serve as a reduction to our existing NOL. \n244\nYear Ended December 31, (In thousands) 2012 2011 Balance at beginning of period. . . . . . . . . . . . . . . . . . . . . . . . $ 125,757 $ 92,845 Tax positions related to the current year: Increases. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1,209 1,268 Decreases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (1,624 ) (2,005 ) Tax positions related to prior years: Increases. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27,302 51,480 Decreases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (4,243 ) (17,831 ) Lapses of applicable statute of limitation. . . . . . . . . . . . . . . . (34,388 ) — Balance at end of period. . . . . . . . . . . . . . . . . . . . . . . . . . . . . $ 114,013 $ 125,757\n(In thousands) December 31, 2011 Decrease December 31, 2012 Unrecognized tax benefits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . $ 125,757 $ (11,744 ) $ 114,013 Unrecognized tax benefits that, if recognized, would affect the effective tax rate. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . $ 61,901 $ (2,907 ) $ 58,994 Interest and penalties accrued. . . . . . . . . . . . . . . . . . . . . . . . . . . . . $ 53,842 $ (840 ) $ 53,002 Interest and penalties charged to income tax benefit. . . . . . . . . . . $ (840 )"}]}
+{"image": "doclay/doclay_43546.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "the landing gear retracted when there is a positive rate of  climb and no chance of runway contact. The remaining flaps  should then be retracted.  [Figure 12-10]\nfield approach and landing procedure, some AFM/POHs  recommend a slightly slower than normal approach airspeed.  If no such slower speed is published, use the AFM/POH- recommended normal approach speed.\nIf the go-around was initiated due to conflicting traffic on the  ground or aloft, the pilot should maneuver to the side so as to  keep the conflicting traffic in sight. This may involve a shallow  bank turn to offset and then parallel the runway/landing area.\nFull flaps are used to provide the steepest approach angle.  If obstacles are present, the approach should be planned so  that no drastic power reductions are required after they are  cleared. The power should be smoothly reduced to idle in  the round out prior to touchdown. Pilots should keep in mind  that the propeller blast blows over the wings providing some  lift in addition to thrust. Reducing power significantly, just  after obstacle clearance, usually results in a sudden, high  sink rate that may lead to a hard landing. After the short- field touchdown, maximum stopping effort is achieved by  retracting the wing flaps, adding back pressure to the elevator/ stabilator, and applying heavy braking. However, if the  runway length permits, the wing flaps should be left in the  extended position until the airplane has been stopped clear  of the runway. There is always a significant risk of retracting  the landing gear instead of the wing flaps when flap retraction  is attempted on the landing rollout.\nIf the airplane was in trim for the landing approach when the  go-around was commenced, it soon requires a great deal of  forward elevator/stabilator pressure as the airplane accelerates  away in a climb. The pilot should apply appropriate forward  pressure to maintain the desired pitch attitude. Trim should  be commenced immediately. The Balked Landing checklist  should be reviewed as work load permits.\nMany multiengine airplanes have a landing gear retraction  speed significantly less than the extension speed. Care should  be exercised during the go-around not to exceed the retraction  speed. If the pilot desires to return for a landing, it is essential  to re-accomplish the entire Before Landing checklist. An  interruption to a pilot’s habit patterns, such as a go-around,  is a classic scenario for a subsequent gear up landing.\nLanding conditions that involve a short-field, high-winds, or  strong crosswinds are just about the only situations where  flap retraction on the landing rollout should be considered.  When there is an operational need to retract the flaps just  after touchdown, it must be done deliberately with the flap  handle positively identified before it is moved.\nWhen the decision to go around is made, the throttles should  be advanced to takeoff power. With adequate airspeed, the  airplane should be placed in a climb pitch attitude. These  actions, which are accomplished simultaneously, arrest the  sink rate and place the airplane in the proper attitude for  transition to a climb. The initial target airspeed is V$_{Y}$ or V$_{X}$  if obstructions are present. With sufficient airspeed, the flaps  should be retracted from full to an intermediate position and \nThe preceding discussion about doing a go-around assumes  that the maneuver was initiated from normal approach speeds  or faster. If the go-around was initiated from a low airspeed,  the initial pitch up to a climb attitude must be tempered with  the necessity of maintaining adequate flying speed throughout  the maneuver. Examples of where this applies include a  go-around initiated from the landing round out or recovery \nFlaps should be retracted before the landing gear for two  reasons. First, on most airplanes, full flaps produce more drag  than the extended landing gear. Secondly, the airplane tends  to settle somewhat with flap retraction, and the landing gear  should be down in the event of an inadvertent, momentary  touchdown.\nGo-Around\nFigure 12-10.  Go-around procedure.\n12-18\nTimely decision to make go-around Apply max power adjust pitch attitude to arrest sink rate Flaps to intermediate Retract remaining flaps 500’ Cruise climb Positive rate of climb, retract gear, climb at V$_{Y}$"}]}
+{"image": "doclay/doclay_75678.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Directors’ Report – Remuneration Report \nRemuneration Report – audited The directors of Orica Limited present the Remuneration Report (which forms part of the Directors’ Report) prepared in accordance \nKey developments and summary of performance for 2012  Orica is a company that enjoys a strong performance based culture which the Board has sought to foster through rewarding \nRemuneration Report – audited The directors of Orica Limited present the Remuneration Report (which forms part of the Directors’ Report) prepared in accordance  with section 300A of the Corporations Act for the Company and its controlled entities for the year ended 30 September 2012. \nKey developments and summary of performance for 2012  Orica is a company that enjoys a strong performance based culture which the Board has sought to foster through rewarding  executives for the achievement of the Company’s short-term and long-term strategy and business objectives with a view to  generating above average returns for shareholders.\nThis report explains how the Company’s performance for the 2012 Financial Year has driven remuneration outcomes for our senior  executives. EBIT is defined as earnings before interest, tax and individually material items. NPAT is defined as Net Profit After Tax  before individually material items attributable to shareholders of Orica Limited.\n-40% -20% 0% 20% 40% 2008 2009 2010 2011 2012 TSR % Cumulative TotalShareholders Return (since2008).Years 2008 to 2010includes  DuluxGroup. TSR Orica TSR ASX100\n0.0  5.0  10.0  15.0  20.0  25.0  30.0  35.0  0  20  40  60  80  100  120  140  160  180  200  2008 2009 2010 2011 2012 Y/EShare pric e  $ EPS Cents EPSand Year End Share price.Years 2008 to  2010 includes DuluxGroup. EPS Y/E Share Price\n0  20  40  60  80  100  120  520  540  560  580  600  620  640  660  680  700  2008 2009 2010 2011 2012 DPS cents NPAT $M NPAT and Dividends. Years 2008to 2010  includes DuluxGroup. NPAT Dividends\n0  200  400  600  800  1,000 1,200 2008 2009 2010 2011 2012 EBIT $M EBIT  EBIT excl.DuluxGroup DuluxGroup EBIT\n0  2,000  4,000  6,000  8,000  2008 2009 2010 2011 2012 Sales $M Sales Sales excl. DuluxGroup DuluxGroup Sales\nOrica Limited 24"}]}
+{"image": "doclay/doclay_60502.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "max_join_size\nmax_length_for_sort_data\nmax_points_in_geometry\nmax_prepared_stmt_count\nmax_relay_log_size\nmax_seeks_for_key\nmax_sort_length\nmax_sp_recursion_depth\nmax_user_connections\nSection 8.8.2, “EXPLAIN Output Format” Section 4.5.1.6, “mysql Client Tips” Section 5.1.8, “Server System Variables” Section 13.7.6.1, “SET Syntax for Variable Assignment”\nSection 8.2.1.16, “ORDER BY Optimization” Section 5.1.8, “Server System Variables” Section 1.3, “What Is New in MySQL 8.0”\nSection 5.1.8, “Server System Variables” Section 12.17.8, “Spatial Operator Functions”\nSection 8.10.3, “Caching of Prepared Statements and Stored Programs” Section 13.5.3, “DEALLOCATE PREPARE Statement” Section 27.15, “Performance Schema System Variables” Section 13.5, “Prepared Statements” Section 5.1.10, “Server Status Variables” Section 5.1.8, “Server System Variables”\nSection 17.1.6.4, “Binary Logging Options and Variables” Section 17.1.6.3, “Replica Server Options and Variables” Section 17.2.4.1, “The Relay Log”\nSection 13.7.3.1, “ANALYZE TABLE Statement” Section 5.1.8, “Server System Variables”\nSection B.3.7, “Known Issues in MySQL” Section 8.2.1.16, “ORDER BY Optimization” Section 13.2.10, “SELECT Statement” Section 5.1.8, “Server System Variables” Section 11.3.4, “The BLOB and TEXT Types” Section 11.5, “The JSON Data Type”\nSection 5.1.8, “Server System Variables” Section 25.2.1, “Stored Routine Syntax”\nSection 13.7.1.1, “ALTER USER Statement” Section 13.7.1.3, “CREATE USER Statement” Section 13.7.8.3, “FLUSH Statement” Section 6.1.3, “Making MySQL Secure Against Attackers” Section 5.1.8, “Server System Variables” Section 6.2.20, “Setting Account Resource Limits”\n6089"}]}
+{"image": "doclay/doclay_61659.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Jul.  30,  2020 \n11 \nUS 2020/0241418 Al \nI  ,-D-ov’~-(  ~o  ,-q-:0:  ,-q-> _  _r<:  I  ,◊)--0---(  ~o  I  , 0  }--0---(  ~o  I  ,-q-cP  o- 1  ,-q-::r  o-\n-continued  >=>-<~o  0  y-{~o  y--{}-o  I  O  I  1 ~’  0  ,-q-o\\__{  ’  /)  N\\  ’  0  I  ro- 1  0  I  ,-q-\\_{  I  I  ,-D-~o  ~o  ,-q-:0:  I  ,-q-)-0-o \n-continued \n-continued "}]}
+{"image": "doclay/doclay_15747.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Bristol-Myers Squibb \nCONSOLIDATED STATEMENTS OF COMPREHENSIVE INCOME \nDollars in Millions \nYear Ended December 31,  COMPREHENSIVE INCOME  2012 2011 2010 Net Earnings  $  2,501  $   5,260 $  4,513  Other Comprehensive Income/(Loss), net of taxes:  Derivatives qualifying as cash flow hedges:  Unrealized gains   9   24  15  Realized gains   (36)  32  (5) Pension and postretirement benefits:  Actuarial losses   (311)  (830)  (88) Amortization   90   81  67  Settlements and curtailments   103   7  16  Available for sale securities:  Unrealized gains   12   28  44  Realized gains   (9)  -  -  Foreign currency translation   (7)  (27)  37  Foreign currency translation on net investment hedges   (8)  11  84  Total Other Comprehensive Income/(Loss), net of taxes   (157)  (674)  170  Comprehensive Income   2,344   4,586  4,683  Comprehensive Income Attributable to Noncontrolling Interest   535   1,558  1,411  Comprehensive Income Attributable to BMS  $  1,809  $   3,028 $  3,272 \nThe accompanying notes are an integral part of these consolidated financial statements.  30"}]}
+{"image": "doclay/doclay_3418.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "prior to the enforcement of this Cabinet Order, the provisions then in force  remain applicable. \n(Effective Date) \nThis Cabinet Order comes into effect as of November 12, 1998. \n(Transitional Measures Concerning Penal Provision) \n(Effective Date) \n(Transitional Measures Concerning Penal Provision) \n(Effective Date) \n(Transitional Measures Concerning Penal Provision) \n(1) This Cabinet Order comes into effect as of the date of promulgation; provided,  however, that the provisions revising Appended Table 2 come into effect as of  August 29, 1998. \n(2) With regard to the application of penal provision to acts committed prior to  the enforcement of this Cabinet Order, the provisions then in force remain  applicable. \n(1) This Cabinet Order comes into effect as of April 1, 1999. \n(2) With regard to the application of penal provision to acts committed prior to  the enforcement of this Cabinet Order, the provisions then in force remain  applicable. \n(1) This Cabinet Order comes into effect as of the date of promulgation; provided,  however, that the provisions listed as follows come into effect as of the date  specified in the corresponding item: \n(ii) the part of the provisions of Article 2 that revises row 16 of Appended Table  1 of the Export Trade Control Order: July 18, 1999. \n(2) With regard to the application of penal provision to acts committed prior to \n35 \nSupplementary Provisions [Cabinet Order No. 287 of August 26, 1998] \nSupplementary Provisions [Cabinet Order No. 359 of November 5, 1998] \nSupplementary Provisions [Cabinet Order No. 130 of March 31, 1999] \nSupplementary Provisions [Cabinet Order No. 190 of June 18, 1999] [Extract] "}]}
+{"image": "doclay/doclay_65871.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "[0099] Clause 9. The computer-readable storage medium of clause 8, having further computer-executable instructions stored thereupon to transmit the transcription of the audio of the meeting to one or more computing devices for presentation in a user interface (UI) during a time of the meeting.\n[00100] Clause 10. The computer-readable storage medium of clauses 8 or 9, wherein the meeting-specific data comprises one or more of messages associated with the attendees of the meeting, attachments to the messages, names of the attendees, or files associated with the attendees.\n[00101] Clause 11. The computer-readable storage medium of any of clauses 8- 10, wherein the transcription of the audio of the meeting is further generated, at least in part, using a base statistical language model.\n[00102] Clause 12. The computer-readable storage medium of any of clauses 8- 11, wherein generation of the meeting-specific statistical language model occurs in response to receiving a pre-meeting signal comprising data identifying a start time for the meeting.\n[00103] Clause 13. The computer-readable storage medium of any of clauses 8- 12, wherein the pre-meeting signal is generated a predetermined amount of time prior to the start time of the meeting.\n[00104] Clause 14. The computer-readable storage medium of any of clauses 8- 13, wherein the pre-meeting signal is generated responsive to receiving meeting change event notifications.\n[00105] Clause 15. An apparatus for generating a transcription of audio of a meeting, the apparatus comprising: means for retrieving meeting-specific data associated with the meeting, the meeting-specific data comprising data associated with attendees of the meeting; means for generating a meeting-specific statistical language model based on the meeting-specific data; and means for generating a transcription of the audio of the meeting using the meeting-specific statistical language model.\n[00106] Clause 16. The apparatus of clause 15, further comprising means for providing the transcription of the audio of the meeting to one or more computing devices for presentation in a user interface (UI) during the meeting.\n[00107] Clause 17. The apparatus of clauses 15 or 16, wherein the meeting- specific data associated with the meeting is retrieved responsive to receiving a signal generated on a predefined schedule prior to the meeting.\n[00108] Clause 18. The apparatus of any of clauses 15-17, wherein the meeting- specific data associated with the meeting is retrieved responsive to receiving an event"}]}
+{"image": "doclay/doclay_54385.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Server System Variable Reference\nName Cmd-Line Option File System Var Var Scope Dynamic thread_stack Yes Yes Yes Global No time_zone Yes Both Yes timestamp Yes Session Yes tls_ciphersuites Yes Yes Yes Global Yes tls_version Yes Yes Yes Global Varies tmp_table_size Yes Yes Yes Both Yes tmpdir Yes Yes Yes Global No transaction_alloc_block_size Yes Yes Yes Both Yes transaction_allow_batching Yes Session Yes transaction_isolation Yes Yes Yes Both Yes transaction_prealloc_size Yes Yes Yes Both Yes transaction_read_only Yes Yes Yes Both Yes transaction_write_set_extraction Yes Yes Yes Both Yes unique_checks Yes Both Yes updatable_views_with_limit Yes Yes Yes Both Yes use_secondary_engine Yes Session Yes validate_password_check_user_name Yes Yes Yes Global Yes validate_password_dictionary_file Yes Yes Yes Global Yes validate_password_length Yes Yes Yes Global Yes validate_password_mixed_case_count Yes Yes Yes Global Yes validate_password_number_count Yes Yes Yes Global Yes validate_password_policy Yes Yes Yes Global Yes validate_password_special_char_count Yes Yes Yes Global Yes validate_password.check_user_name Yes Yes Yes Global Yes validate_password.dictionary_file Yes Yes Yes Global Yes validate_password.length Yes Yes Yes Global Yes validate_password.mixed_case_count Yes Yes Yes Global Yes validate_password.number_count Yes Yes Yes Global Yes validate_password.policy Yes Yes Yes Global Yes validate_password.special_char_count Yes Yes Yes Global Yes version Yes Global No version_comment Yes Global No version_compile_machine Yes Global No version_compile_os Yes Global No version_compile_zlib Yes Global No version_tokens_session Yes Yes Yes Both Yes version_tokens_session_number Yes Yes Yes Both No wait_timeout Yes Yes Yes Both Yes\n714"}]}
+{"image": "doclay/doclay_40027.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "In June 2014, the EU and its Member States on the one side, and Ukraine on the other side, signed  the EU-Ukraine Association Agreement which, inter alia:\n(i) encourages the two parties to intensify their cooperation in the field of transport;\n(ii) aims at facilitating the restructuring and modernisation of Ukraine's transport sector;\n(iii) assists Ukraine towards achievement of efficient, safe and secure transport; and\n(iv) promotes a gradual approximation towards operating standards and policies comparable to those  in the EU.\nIn the field of railway transport, Ukraine shall, for instance, implement the provisions of Directive  2008/57/EC of the European Parliament and of the Council of 17 $^{th}$ June 2008, as amended, on the  interoperability of the rail system within the Union. \nIn that context, financial support is needed to ensure the implementation of the provisions of the  agreement and the reform of the sector. Indeed, Ukraine is currently engaged in a sectoral reform  that follows the National Target Program on Railway Reform 2010-2019, approved by the Cabinet of  Ministers of Ukraine on 16 th December 2009. In particular, the Joint Stock Company “Ukrainian  railways” (Ukrzaliznytsia), the former State Administration of Railway Transport of Ukraine, was  established as a Public Joint Stock Company on 1 $^{st}$ December 2015 and subsequently reorganised  as Joint Stock Company on 31 $^{st}$ October 2018. \nThe network of railways of Ukraine is the largest in Europe with approximately 21,600 kilometres of  tracks, of which about 45% are electrified. The networks is the fourth largest by volume of traffic in  Europe. The railway network in Ukraine is of great strategic importance for Ukrainian trade and  import-export industries.\nAt present, the transport sector in general meets only basic demands of the economy and society.  The levels of safety, quality and efficiency of passenger and freight transportation as well as energy  efficiency and impact on environment compare poorly with EU standards. The existing transit  potential resulting from its favourable geographical location of the country is not fully exploited. These  factors result in a high share of transport costs in the delivered cost of products.\nUkraine is undertaking a project concerning the electrification of the Dolynska - Mykolaiv section and  the Mykolaiv - Kolosivka section of the railway network in the southern part of Ukraine, together with  the modernisation of signalling and telecommunication systems in stations and on open lines. \nThis electrification project is in line with the strategy formulated by the European Commission on  “Improving transport connectivity with the EU-Neighbourhood East region” focusing on the extension  of the TEN-T network in the Eastern Partnership region. \nAs the ppoject shall provide the missing link of the electrified comprehensive extended TEN-T railway  corridor in Ukraine, as well as it is in compliance with the maritime port’s development strategy of  Ukraine, the Project has been identified as a priority investment under Ukraine’s National Transport  Strategy to 2020 prepared with support from an EU-financed technical assistance programme. It is  also on the priority project pipeline established in the context of the Eastern Partnership Transport  Panel and located on the Eastern Partnership regional transport network.\nThe project safeguards and develops Ukraine’s export and transit freight flows by modernising lines.  The project will result in increased traffic capacity and higher speed on the modernised lines,  therefore relieving traffic and congestion in the corridor and reducing transit time. It will also lower  energy, operating and maintenance costs and will allow traffic to circulate using a more fuel efficient  and environmentally friendly mode, reducing emissions.\nThe total investment costs are expected to be approximately EUR 306 million including contingencies  and without VAT. The Promoter intends to finance this project using the proceeds of the loans from  the EIB and the EBRD (“the Banks”) in amount of approximately EUR 150 m each. NIP grant of  EUR6 million has been made available to finance the supervision services. \nPage 4 of 18\nAA-000799-002 Terms of reference \n1.4.1  General\nCurrent situation in the sector "}]}
+{"image": "doclay/doclay_65028.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Patent Application Publication \nOct. 8, 2020  Sheet 8 of 10 \nUS 2020/0319555 Al \nFIG. 8 \nExample 10  Example 11  (Using N-Methyldipropylamine quencher)  (Using N,N-diisopropylethylamine quencher) "}]}
+{"image": "doclay/doclay_31273.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "τ$_{c}$/τ$_{e}$ is similar to that presented in Ref. [13]:\nwhere γ is the degeneracy factor, 〈 E$_{Z}$ 〉 = E T $_{Z}$+ E C Z 2 is the average value of the two Zeeman splittings of the channel and of the trap respectively, δ = ∣ E T Z − E C Z ∣ and Δ$_{ST}$ is the en- ergy gap between the singlet and the triplet energy levels in the doubly occupied defect. The generalized temperature for such system extracted from the fitting is T$_{fit}$ = 0 . 80(1) K. Δ$_{ST}$ =150(5) µ eV is due to the different charging energy caused by the different orbital symmetry of the electron wavefunction for the singlet and the triplet states. The differ- ence between the generalized electron temperature and the lattice temperature which is in thermal equilibrium with the $^{3}$He at 310 mK is consistent with other reported values in similar systems. To conclude, we experimentally determined the generalized temperature of a system of few electrons at cryogenic temperature. We have shown that below 10 K the capture and the emission of a point defect may be thermally activated and we discussed the role of phonons. We realized such mesoscopic system in a n-MOSFET, where a point defect exchanges one electron with the 2DES at the Si/SiO$_{2}$ interface. The generalized tem- perature is extracted from the probability of occupation of a mesoscopic system constituted by a point defect capable of containing either 1 or 2 electrons in thermal contact with a dilute electron system, in the limit of finite N , with the help of a static magnetic field. This method provides an estimate of the temperature of a system consisting of a localized electron in thermal exchange with a small number of electrons confined in two dimensions.\n5\n[1] H. Sellier et al., Phys. Rev. Lett. 97 , 206805 (2006)\n[2] G. P. Lansbergen et al., Nature Physics, doi:10.1038/nphys994 (2008)\n[3] E. Prati et al., Phys. Rev. B80, 165331 (2009)\n[4] F. Giazotto et al., Rev. Mod. Phys. 78, 217 (2006)\n[5] E. Prati et al., J. Appl. Phys., 103, 123707 (2008)\n[6] M.Sanquer et al., Phys. Rev. B. 61 , 7249 (2000)\n[7] L. Landau, L. Lifshitz, Statistical Physics (Course of Theoretical Physics, Volume 5) 3ed., Pergamon (1980)\nτ$_{c}$ τ$_{e}$ = γe β ( E T +Δ 12 $_{−}$µ ( N ) ( 1+ 3 2 N $^{))}$( cosh β 〈 E$_{Z}$ 〉 + cosh β δ $_{2}$) 1 + e $_{−}$β Δ ST (1 + 2 cosh βE T $_{Z}$) (2)"}]}
+{"image": "doclay/doclay_6722.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "The following table presents certain consolidated earnings data as a percentage of net sales:\nYEAR ENDED JUNE 30 2003 2002 2001 Net sales 100.0% 100.0% 100.0% Cost of sales 26.1 26.8 26.3 Gross profit 73.9 73.2 73.7 Operating expenses: Selling, general and administrative 63.4 63.3 61.5 Restructuring — 2.3 0.8 Special charges 0.4 — 0.3  Related party royalties 0.4 0.4 0.5 64.2 66.0 63.1 Operating income 9.7 7.2 10.6 Interest expense, net 0.2 0.2 0.2 Earnings before income taxes, minority interest and accounting change 9.5 7.0 10.4 Provision for income taxes 3.1 2.4 3.7 Minority interest, net of tax (0.1) (0.1) (0.1) Net earnings before accounting change 6.3 4.5 6.6 Cumulative effect of a change in accounting principle, net of tax — (0.4) (0.1) Net earnings 6.3% 4.1% 6.5%\nThe following tables present reconciliations of our financial results for the fiscal years ended June 30, 2003, 2002 and 2001 as reported in conformity with generally accepted accounting principles in the United States (“GAAP”) and those results adjusted to exclude certain charges described above each table. We have presented these reconciliations because of the special nature of the charges or the fact that they are not necessarily comparable from period to period. We believe that such measures provide investors with a view of our ongoing business trends and results of operations. This is consistent with the approach used by management in its evaluation and monitoring of such trends and results and provides investors with a base for evaluating future periods.\nWhile we consider the non-GAAP financial measures useful in analyzing our results, it is not intended to replace, or act as a substitute for, any presentation included in the consolidated financial statements prepared in conformity with GAAP.\nThe table below reconciles the fiscal 2003 results as reported and results prior to adjustment for a special pre-tax charge of $22.0 million, or $13.5 million after-tax, equal to $.06 per diluted common share, in connection with the proposed settlement of a class action lawsuit brought against us and a number of other defendants (see “Item 3. Legal Proceedings.”). The amount of the charge in this case is significantly larger than similar charges we have incurred individually or in the aggregate for legal proceedings in any prior year and we do not expect to take a charge of a similar magnitude for a single matter like it in the near future.\nYEAR ENDED JUNE 30, 2003 Results as Reported Reconciling Items Non-GAAP Results (In millions, except per share data) Net sales $5,117.6 $ — $5,117.6 Cost of sales 1,335.7 — 1,335.7 Gross profit 3,781.9 — 3,781.9 Gross margin  73.9% 73.9% Operating expenses 3,286.8 22.0 3,264.8 Operating expense margin 64.2% 63.8% Operating income 495.1 22.0 517.1 Operating income margin 9.7% 10.1% Provision (benefit) for income taxes 160.5 (8.5) 169.0 Net earnings $ 319.8 $13.5 $ 333.3 Diluted net earnings per common share $ 1.26 $ .06 $ 1.32\nThe table below reconciles the fiscal 2002 results as reported and results prior to adjustment for (i) pre-tax restructuring charges of $117.4 million, or $76.9 million after-tax, equal to $.32 per diluted common share (see “Results of Operations —\nTHEEST{E LAUDER COMPANIES INC.\n42"}]}
+{"image": "doclay/doclay_52211.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Appendix B. Automating the installation using preseeding\nAdditional options that may be of interest while attempting to automate an install while using DHCP are: interface=auto netcfg/dhcp_timeout=60 which makes the machine choose the first vi- able NIC and be more patient about getting a reply to its DHCP query.\nTip: An extensive example of how to use this framework, including example scripts and classes, can be found on the website of its developer (http://hands.com/d-i/). The examples available there also show many other nice effects that can be achieved by creative use of preconfiguration.\nThe following aliases can be useful when using (auto mode) preseeding. Note that these are sim- ply short aliases for question names, and you always need to specify a value as well: for example, auto=true or interface=eth0 .\nIt’s also possible to use DHCP to specify a preconfiguration file to download from the network. DHCP allows specifying a filename. Normally this is a file to netboot, but if it appears to be an URL then installation media that support network preseeding will download the file from the URL and use it as a preconfiguration file. Here is an example of how to set it up in the dhcpd.conf for version 3 of the\nB.2.5. Using a DHCP server to specify preconfiguration files\n89\nB.2.4. Aliases useful with preseeding\npriority debconf/priority fb debian-installer/framebuffer language debian-installer/language country debian-installer/country locale debian-installer/locale theme debian-installer/theme auto auto-install/enable classes auto-install/classes file preseed/file url preseed/url domain netcfg/get_domain hostname netcfg/get_hostname interface netcfg/choose_interface protocol mirror/protocol suite mirror/suite modules anna/choose_modules recommends base-installer/install-recommends tasks tasksel:tasksel/first desktop tasksel:tasksel/desktop dmraid disk-detect/dmraid/enable keymap keyboard-configuration/xkb-keymap preseed-md5 preseed/file/checksum"}]}
+{"image": "doclay/doclay_7028.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\nexpected cash flows from the forecasted transactions. No gains or losses related to ineffectiveness of cash flow hedges were recognized  in earnings for the years ended December 31, 2003 and 2002.\nManagement has evaluated the expected timing of the hedged fore- casted transactions to deliver the underlying shares to settle the forward contracts, and believes that these forecasted transactions are probable  of occurring in the periods specified in the related hedge documentation or within an additional two-month period of time thereafter.\nU.S. Cellular reported a derivative liability of $55.7 million and  $8.7 million at December 31, 2003 and 2002, respectively. These amounts are included in the balance sheet caption Deferred Liabilities and Credits.\nNOTE 16 MINORITY INTEREST IN SUBSIDIARIES\nNOTE 17 COMMON SHAREHOLDERS’ EQUITY\nEmployee Benefit Plans\nTax-Deferred Savings Plan\nStock-based Compensation Plans\nUnder SFAS No. 150 “Accounting for Certain Financial Instruments with Characteristics of both Liabilities and Equity,” certain minority interests in consolidated entities with finite lives may meet the standard’s defini- tion of a mandatorily redeemable financial instrument and thus require reclassification as liabilities and remeasurement at the estimated amount of cash that would be due and payable to settle such minority interests under the applicable entity’s organization agreement, assuming an orderly liquidation of the finite-lived entity, net of estimated liquida- tion costs (the “settlement value”). U.S. Cellular’s consolidated financial statements include such minority interests that meet the standard’s definition of mandatorily redeemable financial instruments. These mandatorily redeemable minority interests represent interests held by third parties in consolidated partnerships and limited liability companies (“LLCs”), where the terms of the underlying partnership or LLC agree- ment provide for a defined termination date at which time the assets  of the subsidiary are to be sold, the liabilities are to be extinguished and the remaining net proceeds are to be distributed to the minority interest holders and U.S. Cellular in accordance with the respective partnership and LLC agreements. The termination dates of U.S. Cellular’s mandatorily redeemable minority interests range from 2042 to 2100.\nOn November 7, 2003, the FASB issued FASB Staff Position (“FSP”)  No. FAS 150-3, “Effective Date, Disclosures, and Transition for Mandatorily Redeemable Financial Instruments of Certain Nonpublic Entities and Certain Mandatorily Redeemable Noncontrolling Interests” under FASB Statement No. 150 “Accounting for Certain Financial Instruments with Characteristics of Both Liabilities and Equity.” The FSP indefinitely deferred the classification and measurement provisions of SFAS No. 150 related to the mandatorily redeemable minority interests associated with finite-lived subsidiaries, but retained the related disclo- sure provisions. The settlement value of U.S. Cellular’s mandatorily redeemable minority interests is estimated to be $104.7 million at December 31, 2003. This represents the estimated amount of cash that would be due and payable to settle minority interests assuming an orderly liquidation of the finite-lived consolidated partnerships and LLCs on December 31, 2003, net of estimated liquidation costs. This amount is being disclosed pursuant to the requirements of FSP FAS 150-3; U.S. Cellular has no current plans or intentions to liquidate any of \nU.S. Cellular accounts for stock options, restricted stock awards and employee stock purchase plans under APB Opinion No. 25. No compen- sation costs have been recognized for the stock option and employee stock purchase plans. Compensation costs were recognized for restricted stock awards as expenses in the statements of operations.\nA summary of the status of U.S. Cellular’s stock option plans at December 31, 2003, 2002 and 2001 and changes during the years  then ended is presented in the table and narrative as follows:\nU.S. Cellular has reserved 67,215 Common Shares for issuance under the TDS Tax-Deferred Savings Plan, a qualified profit-sharing plan pur- suant to Sections 401(a) and 401(k) of the Internal Revenue Code.\nParticipating employees have the option of investing their contributions in a U.S. Cellular Common Share fund, a TDS Common Share fund, or seven nonaffiliated funds.\nThe following table summarizes Common Shares issued, including reissued Treasury Shares, for the employee benefit plans described  as follows:\nThe FASB plans to reconsider certain implementation issues and perhaps the classification or measurement guidance for mandatorily redeemable minority interests during the deferral period. The outcome of their deliberations cannot be determined at this point. Accordingly, it is possible that the FASB could require the recognition and measurement of mandatorily redeemable minority interests at their settlement value at a later date.\nthe related partnerships or LLCs prior to their scheduled termination dates. The corresponding carrying value of the minority interests in finite-lived consolidated partnerships and LLCs at December 31, 2003  is $35.2 million, and is included in the balance sheet caption Minority Interest. The excess of the aggregate settlement value over the aggre- gate carrying value of the mandatorily redeemable minority interests  of $69.5 million is primarily due to the unrecognized appreciation  of the minority interest holders’ share of the underlying net assets in the consolidated partnerships and LLCs. Neither the minority interest holders’ share, nor U.S. Cellular’s share, of the appreciation of the  underlying net assets of these subsidiaries is reflected in the consoli- dated financial statements under GAAP. The estimate of settlement value was based on certain factors and assumptions. A change in those factors and assumptions could result in a materially larger or smaller settlement amount.\n59\nYear Ended December 31, 2003 2002 Employee stock options and awards 13,917 42,207 Employee Stock Purchase Plan 11,437 26,222 25,354 68,429"}]}
+{"image": "doclay/doclay_58186.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "InnoDB and MySQL Replication\nQuery OK, 3 rows affected (0.19 sec) Records: 3 Duplicates: 0 Warnings: 0\nAt this point, on both the source and the replica, table  fc1  contains 2 rows, and table  fc2  contains 3 rows, as shown here:\nsource>  SELECT * FROM fc1; +---+------+ | i | j | +---+------+ | 1 | 1 | | 2 | 2 | +---+------+ 2 rows in set (0.00 sec)\nsource>  SELECT * FROM fc2; +---+------+ | m | n | +---+------+ | 1 | 1 | | 2 | 2 | | 3 | 1 | +---+------+ 3 rows in set (0.00 sec)\nreplica>  SELECT * FROM fc1; +---+------+ | i | j | +---+------+ | 1 | 1 | | 2 | 2 | +---+------+ 2 rows in set (0.00 sec)\nreplica>  SELECT * FROM fc2; +---+------+ | m | n | +---+------+ | 1 | 1 | | 2 | 2 | | 3 | 1 | +---+------+ 3 rows in set (0.00 sec)\nNow suppose that you perform the following  DELETE  statement on the source:\nsource>  DELETE FROM fc1 WHERE i=1; Query OK, 1 row affected (0.09 sec)\nDue to the cascade, table  fc2  on the source now contains only 1 row:\nsource>  SELECT * FROM fc2; +---+---+ | m | n | +---+---+ | 2 | 2 | +---+---+ 1 row in set (0.00 sec)\nHowever, the cascade does not propagate on the replica because on the replica the  DELETE  for  fc1 deletes no rows from  fc2 . The replica’s copy of  fc2  still contains all of the rows that were originally inserted:\nreplica>  SELECT * FROM fc2;\n3351"}]}
+{"image": "doclay/doclay_68159.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "If you use a proxy, enter the remote support center proxy information in the window, as shown  on Figure 4-33. Then, click  Apply and Next .\nIf you do not want to set up remote support, select the  Set up remote support assistance  later  option and click  Apply and Next .\nIf you are configuring remote access, you must choose when the support center can access  the system, as shown in Figure 4-34 on page 125. Select an option and click  Apply and  Next .\nConfiguring access settings\nFigure 4-33 Support center proxy information124  Implementing IBM FlashSystem 900 Model AE3"}]}
+{"image": "doclay/doclay_28636.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "VII. SCHR ¨ ODINGER’S CAT\nIt is instructive to use the formalism of subsystems developed here to analyze the classic example of macroscopic entanglement: Schr¨ odinger’s Cat. The Schr¨ odinger’s Cat thought experiment can be divided into five subsystems:\nThe experiment is presumed to have a finite duration, so that, as before, the complete hypervolume V = E ∪ B ∪ C ∪ D ∪ R has both upper and lower time bounds. Let | Ψ$_{I}$ 〉 be an initial state in which the box already exists, with the cat, atom and\nV E ∪ B ∪ C ∪ D ∪ R Let | Ψ$_{I}$ 〉 0 be an initial state in which the box already exists, with the cat, atom and detector sealed inside it. That is,\nConsider first the interior of the box, consisting of I = R ∪ D ∪ C . Clearly,\nThe key issue in the Schr¨ odinger’s Cat scenario is, of course, whether opening the box has any relevance to the state of the interior of the box (i.e., by “collapsing the wave function”). Initially, the box is closed. However, at some time during the course of the experiment, the box may be opened, presumably by an experimenter who is part of the environment. But,\n26\nˆ G$_{I}$ = ˆ P alive C ˆ G$_{C}$ ˆ P no D ˆ G$_{D}$ ˆ P no R ˆ G$_{R}$ | Ψ$_{I}$ 〉 0 + ˆ P dead C ˆ G$_{C}$ ˆ P yes D ˆ G$_{D}$ ˆ P yes R ˆ G$_{R}$ | Ψ$_{I}$ 〉 0 = ψ no R | r $^{no}$, d$^{no}$, c$^{alive}$〉 0 + ψ yes R | r $^{yes}$, d$^{yes}$, c$^{dead}$〉$_{0}$. (41)\nˆ P no R | Ψ$_{I}$ 〉 0 = ˆ P no D | Ψ$_{I}$ 〉 0 = ˆ P alive C | Ψ$_{I}$ 〉 0 = ˆ P closed B | Ψ$_{I}$ 〉 0 = | Ψ$_{I}$ 〉 $_{0}$.\n• E , the environment with projection operators ˆ P closed E , ˆ P alive E and ˆ P dead E indicating that either that the box is closed or it is open and the cat is alive or dead.\n• B , the box (consisting of just the bounding container but not its interior), with pro- jection operators ˆ P open B and ˆ P closed B indicating that the box is open or closed.\n• C , the cat, with projection operators ˆ P alive C and ˆ P dead C indicating that the cat is alive or dead.\n• D , a detector/poison gas apparatus, with projection operators ˆ P yes D and ˆ P no D indicating that a decay product has been detected, with a consequent release of poison gas, or not.\n• R , a radioactive atom, with projection operators ˆ P yes R and ˆ P no R indicating that it has or has not decayed."}]}
+{"image": "doclay/doclay_70179.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "However, the referencing SELECT requires P2.P_PARTKEY only (for the SELECT list and  ON clause). Because of the materialization of the UNION ALL table expression in Db2 11, all  columns from the PART table (for example, if the table has 10 columns) are accessed and  materialized to the work file. As the outer query is retrieving from that work file, only  P_PARTKEY is retrieved.\nThe example that is shown in Figure 8-5 on page 250 is repeated in Figure 8-6. Db2 12  prunes the unnecessary columns and requires only P_PARTKEY to be returned from each  UNION ALL leg, whereas Db2 11 returned all columns. If the UNION ALL table expression is  materialized, only P_PARTKEY is retrieved and written or materialized to work file compared  with all (10) columns in Db2 11. \nIf P_PARTKEY is indexed, the optimizer can choose a non-matching index scan in Db2 12  rather than a table space scan in Db2 11. Similarly, if the join predicates were pushed down in  Db2 12 and matching index access was chosen on P_PARTKEY, index-only is possible  because only P_PARTKEY is required.\nAnother benefit of column pruning is that it can open other table pruning opportunities. In Db2  10, an enhancement was delivered to prune OUTER JOIN tables if no columns were required  from that table and it was guaranteed that the table did not introduce duplicates. In Db2 12,  this pruning enhancement is extended from OUTER JOINs to views or table expressions that  are guaranteed not to return duplicates and no columns are required from the view or table  expression.\nThe example that is shown in Figure 8-7 on page 252 might appear convoluted, but it is a  simplified example from an actual ERP workload on Db2 for z/OS. Before explaining the  example, it is an interesting question to ask why you might build a query that references  tables from which columns are not actually required. \nThis type of construct is becoming more common as views are built to hide the complexity  and present a simplified representation to the user, such that they can select from a view,  rather than writing a complex query themselves. Similarly, for query generators it is required  that the select from the views and the underlying table relationships can be set up or altered  without affecting the query generation. \nChapter 8. Query performance  251\nTable pruning\nFigure 8-6 Db2 12 pruning unreferenced columns with optional join pushdown\n"}]}
+{"image": "doclay/doclay_37024.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "2.3 Working Capital\n3.0 Management letter\n3.1 Fully Depreciated Assets \n137. Botswana Institute for Technology Research and Innovation\nThe Institute is funded by Government grants, and in the year  under review the grant was P20.61 million, representing 77% of  the total income, compared to P19.55 million in the previous  year. The Institute also generated revenue from sale of services  (P5.53 million) and Investment Income (P7.61 million).\nThe working capital position of the Institute as at 31 March 2018  showed total current assets of P30.59 million and total current  liabilities of P12.30 million resulting in a net current assets position  of P18.29 million. \nThe following were some of the matters raised by the auditors  and the management responses thereto: \nThe auditors noted that the Institute had fully depreciated assets  which did not have estimated residual values but were still in use,  hence economic benefits were still being derived from them.  These assets were carried at nil book values. This was in breach of  requirements of International Accounting Standard 16, that depreciable value of an asset should be depreciated over its  useful life, and that useful lives and residual values be reviewed  at every year-end. \nIn response management stated that BIDPA had assets whose  values could be reliably and independently obtained as the  standard required, such as buildings and motor vehicles. Other  assets like furniture and fittings with no reliable values, had been  maintained at cost. Management endeavoured to provide values in the past, however the practice was not accepted on  account of being immaterial, not reliable and independent.\nManagement however noted the auditors’ comments and stated that they would come up with required estimates. \nThe financial statements of Botswana Institute for Technology Research  and Innovation for the financial year ended 31 March 2018 were  audited by Messrs Ernst & Young, Certified Auditors, who were appointed by the Board. \n132 "}]}
+{"image": "doclay/doclay_26018.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "36\n50 100 150 200 250 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 Number of users  Ergodic Network Capacity (in bps/sec/Hz) Monte−Carlo Simulations Analytical Model; Round Robin Analytical Model; Location based Round Robin Analytical Model; Greedy Round Robin W=6 Analytical Model; Proportional Fair Analytical Model; Greedy Round Robin W=3 Analytical Model; Greedy\nFig. 5. Network ergodic capacity for different number of users considering different scheduling schemes with β = 2 . 6 , χ ∼ Gamma(3 / 2 , 2 / 3) , C =60 dB, P max =1W, σ $^{2}$=-174 dBm/Hz."}]}
+{"image": "doclay/doclay_14557.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "MONUMENT MINING LIMITED\nNotes to Consolidated Financial Statements For the years ended June 30, 2010 and 2009\n12. Share Capital (continued)\nStock option activity is as follows: \nNumber of common shares under option  Weighted average exercise price  Balance, June 30, 2008  4,370,000  $ 0.50  Granted  18,306,000  $ 0.38  Forfeited  (3,000,000)  $ 0.42  Balance, June 30, 2009  19,676,000  $ 0.40  Granted  2,930,000  $ 0.30  Forfeited  (5,000)  $ 0.25  Balance, June 30, 2010  22,601,000  $ 0.39 \nThe following table summarizes the stock options outstanding at June 30, 2010: \nOptions outstanding  Options exercisable  Exercise  Price  Number of  common  shares  Expiry date  Weighted  average  life  (years)  Weighted  average  number  exercisable  Weighted  average  exercise  price  $ 0.50  3,300,000  Jul 05, 2012  2.02  3,300,000  $ 0.50  $ 0.58  70,000  Feb 18, 2011  0.64  70,000  $ 0.58  $ 0.40  13,390,000  Aug 15, 2013  3.14  8,229,451  $ 0.40  $ 0.50  400,000  Dec 05, 2013  3.44  400,000  $ 0.50  $ 0.40  230,000  Dec 05, 2013  3.44  115,000  $ 0.40  $ 0.25  1,731,000   Dec 05, 2013  3.44  1,681,000  $ 0.25  $ 0.25  550,000  Feb 09, 2014  3.62  275,000  $ 0.25  $ 0.30  800,000   Jul 29, 2012  2.08  800,000  $ 0.30  $ 0.39  30,000   Dec 17, 2014  4.47  -  -  $ 0.30  1,600,000   Jun 08, 2013  2.94  -  -  $ 0.30  500,000  Jun 10, 2015  4.95  -  -  Total  22,601,000  3.00  14,870,451  $ 0.40 \nThe following table summarizes the stock options outstanding at June 30, 2009: \nOptions outstanding  Options exercisable  Exercise  Price  Number of  common  shares  Expiry date  Weighted  average  life  (years)  Weighted  average  number  exercisable  Weighted  average  exercise  price  $ 0.50  3,300,000  Jul 05, 2012  3.02  3,300,000  $ 0.50  $ 0.58  70,000  Feb 18, 2011  1.64  70,000  $ 0.58  $ 0.40  13,390,000  Aug 15, 2013  4.14  2,715,569  $ 0.40  $ 0.50  400,000  Dec 05, 2013  4.44  400,000  $ 0.50  $ 0.40  230,000  Dec 05, 2013  4.44  -  -  $ 0.25  1,736,000   Dec 05, 2013  4.44  -  -  $ 0.25  550,000  Feb 09, 2014  4.62  -  -  Total  19,676,000  4.00  6,485,569  $ 0.46 \nThe exercise prices of all stock options granted during the year were equal to the closing market prices at the grant date. The  options outstanding have various vesting dates that range from 0 to 3 years. \n38 | P a g e"}]}
+{"image": "doclay/doclay_32993.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Identifying influential spreaders in complex networks\nMaksim Kitsak, 1, 2 Lazaros K. Gallos, 3 Shlomo Havlin, 4 Fredrik Liljeros, 5\nLev Muchnik, 6 H. Eugene Stanley, 1 and Hern´ an A. Makse 3\n$^{1}$Center for Polymer Studies and Physics Department, Boston University, Boston, Massachusetts 02215, USA\n$^{2}$Cooperative Association for Internet Data Analysis (CAIDA), University of California-San Diego, La Jolla, California 92093, USA\n$^{3}$Levich Institute and Physics Department, City College of New York, New York, New York 10031, USA\n$^{4}$Minerva Center and Department of Physics, Bar-Ilan University, Ramat Gan, Israel\n$^{5}$Department of Sociology, Stockholm University, S-10691, Stockholm, Sweden\n$^{6}$Information Operations and Management Sciences Department, Stern School of Business, New York University, New York, New York 10012, USA\n(Dated: October 5, 2011)\n1\narXiv:1001.5285v3 [physics.soc-ph] 4 Oct 2011"}]}
+{"image": "doclay/doclay_55289.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "FROM mysql.innodb_index_stats WHERE table_name like ’t1’; +------------+--------------+------------+-----------------------------------+ | index_name | stat_name | stat_value | stat_description | +------------+--------------+------------+-----------------------------------+ | PRIMARY | n_diff_pfx01 | 1 | a | | PRIMARY | n_diff_pfx02 | 5 | a,b | | PRIMARY | n_leaf_pages | 1 | Number of leaf pages in the index | | PRIMARY | size | 1 | Number of pages in the index | | i1 | n_diff_pfx01 | 1 | c | | i1 | n_diff_pfx02 | 2 | c,d | | i1 | n_diff_pfx03 | 2 | c,d,a | | i1 | n_diff_pfx04 | 5 | c,d,a,b | | i1 | n_leaf_pages | 1 | Number of leaf pages in the index | | i1 | size | 1 | Number of pages in the index | | i2uniq | n_diff_pfx01 | 2 | e | | i2uniq | n_diff_pfx02 | 5 | e,f | | i2uniq | n_leaf_pages | 1 | Number of leaf pages in the index | | i2uniq | size | 1 | Number of pages in the index | +------------+--------------+------------+-----------------------------------+\nConfiguring Optimizer Statistics for InnoDB\nThe  stat_name  column shows the following types of statistics:\n• size : Where  stat_name = size , the  stat_value  column displays the total number of pages in the index.\n• n_leaf_pages : Where  stat_name = n_leaf_pages , the  stat_value  column displays the number of leaf pages in the index.\n• n_diff_pfx NN : Where  stat_name = n_diff_pfx01 , the  stat_value  column displays the number of distinct values in the first column of the index. Where  stat_name = n_diff_pfx02 , the  stat_value column displays the number of distinct values in the first two columns of the index, and so on. Where stat_name = n_diff_pfx NN , the  stat_description  column shows a comma separated list of the index columns that are counted.\nTo further illustrate the  n_diff_pfx NN  statistic, which provides cardinality data, consider once again the t1  table example that was introduced previously. As shown below, the  t1  table is created with a primary index (columns  a ,  b ), a secondary index (columns  c ,  d ), and a unique index (columns  e ,  f ):\nCREATE TABLE t1 ( a INT, b INT, c INT, d INT, e INT, f INT, PRIMARY KEY (a, b), KEY i1 (c, d), UNIQUE KEY i2uniq (e, f) ) ENGINE=INNODB;\nAfter inserting five rows of sample data, table  t1  appears as follows:\nmysql>  SELECT * FROM t1; +---+---+------+------+------+------+ | a | b | c | d | e | f | +---+---+------+------+------+------+ | 1 | 1 | 10 | 11 | 100 | 101 | | 1 | 2 | 10 | 11 | 200 | 102 | | 1 | 3 | 10 | 11 | 100 | 103 | | 1 | 4 | 10 | 12 | 200 | 104 | | 1 | 5 | 10 | 12 | 100 | 105 | +---+---+------+------+------+------+\nmysql>  SELECT index_name, stat_name, stat_value, stat_description FROM mysql.innodb_index_stats WHERE table_name like ’t1’ AND stat_name LIKE ’n_diff%’;\nWhen you query the  index_name ,  stat_name ,  stat_value , and  stat_description , where stat_name LIKE ’n_diff%’ , the following result set is returned:\n3136"}]}
+{"image": "doclay/doclay_26021.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "instead of just considering the duality as being constructed on the boundary of the AdS$_{5}$ × S 5 space, we are free to look at the duality at any value of r : each different choice of r simply represents the same field theory at a different energy scale.\nFrom here onwards, the r coordinate is referred to as the energy scale. The small r limit is called the infrared (IR), and the high r limit is called the UV (ultraviolet).\nThe correspondence will only be useful if there is a prescribed way of cal- culating physical quantities on each side. The way to do this was first suggested in [55], and the postulate is that the generating functional for correlation functions with some source φ$_{0}$ ( x ) is equal to the supergravity partition function whose fields φ ( x ) tend to φ$_{0}$ ( x ) at the boundary of the AdS$_{5}$ × S 5 space:\nSo, in simple terms, the boundary values for supergravity fields correspond to sources for the field theory operators.\nThe LHS side of (2.9) is independent of the global symmetries of the conformal field theory. So, the entity ∫ d $^{4}$x φ$_{0}$ ( x ) O ( x ) must be a singlet under all the symmetries of the dual field theory. This is how we go about identifying which fields in the supergravity match with which operators in the CFT, which we address next.\n41\n2.6 Explicit Correspondence\n〈 Exp (∫ d $^{4}$xφ$_{0}$ ( x ) O ( x ) ) 〉 AdS 5 × S 5 ∣ φ ( x, ∞ )= φ 0 ( x ) = Z $_{string}$[ φ$_{0}$ ( x )] (2.9)"}]}
+{"image": "doclay/doclay_61026.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "182\n200510079024. 1\na“ HW #$ # 527/98 WL\nZH EMF"}]}
+{"image": "doclay/doclay_69376.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "As for the rest of the components, currently there are no automatic recovery actions that can  be performed. In the current release, the  ltfsee info nodes  command has been updated to  also report any node errors that might be occurring. If GPFS, rpcbind, or rsyslog are having  problems, the issues can be viewed by using the updated command.\nExample 7-31 shows output from running  ltfsee info nodes  when one node has not started  rpcbind . To correct this error, start  rpcbind  on the designated node and EE will refresh itself  and the node will become available.\nExample 7-31 The ltfsee info nodes output \nIn addition to the automatic failover, there is also an option to perform a manual failover by  running the  ltfsee failover  command. This command is used to fail over the MMM process  to a redundant control node. This command is only available for use when a redundant control  node exists. Example 7-32 shows output from running the  ltfsee failover  command.\nThis section describes how to use  ltfsee  commands to add and remove tape drives and tape  cartridges from your LTFS library.\nThis section describes how to add tape cartridges in IBM Spectrum Archive EE. An  unformatted tape cartridge cannot be added to the IBM Spectrum Archive EE library.  However, you can format a tape when you add it to a tape cartridge pool. The process of  formatting a tape in LTFS creates the required LTFS partitions on the tape. \nAfter tape cartridges are added through the I/O station, or after they are inserted directly into  the tape library, you might have to run an  ltfsee retrieve  command. First, run the  ltfsee  info tapes  command. If the tape cartridges are missing, run the  ltfsee retrieve  command,  which synchronizes the data for these changes between the IBM Spectrum Archive EE  system and the tape library. \nThis process occurs automatically. However, if the tape does not appear within the  ltfsee  info tapes  command output, you can force a rebuild of the inventory (synchronization of IBM  Spectrum Archive EE inventory with the tape library’s inventory).\nChapter 7. Operations  147\n7.7.1 Adding tape cartridges\n7.7 Tape library management\n[root@ltfsml1 ~]# ltfsee info nodes Node ID Status Node IP Drives Ctrl Node Library Node Group Host Name 2 Error 9.11.120.224 2 Yes lib_ltfsml2 G0 ltfsml1 1 Available 9.11.120.207 2 Yes(Active) lib_ltfsml1 G0 ltfsml1 Problem Detected: Node ID Error Modules 2 rpcbind;\nExample 7-32 The ltfsee failover command\n[root@ltfsml ~]# ltfsee failover -l lib_ltfsml GLESL659I(00168): failover on library lib_ltfsml is requested."}]}
+{"image": "doclay/doclay_14474.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Carlsberg’s Supervisory Board has 14  members; five members are attached to  the Carlsberg Foundation, the Company’s  principal shareholder, five members have an  international business background and four  members are elected by the employees.\nChairman Born 1952. Professor, D.Sc., h.c.  mult., FRSC. Elected 2005 and 2013.  Election period expires 2014. Chair- man of the Supervisory Board and  the Nomination Committee since  March 2012. Member of the Audit  and Remuneration Committees  2012-2013. Member of the Board of  Directors of the Carlsberg Founda- tion (Chairman as of 1 January 2012)  and of the Supervisory Boards of  property companies affiliated to the  Carlsberg Foundation. Chairman of  the Board of Trustees of the Carls- berg Laboratory and member of the  Boards of the Tuborg Foundation,  MedTech Innovation Center, LevOss  and the Danish management de- velopment organisation CfL. He was  director of the Interdisciplinary Nano- science Center (iNANO), Aarhus  University, from 2002 to 2012. He has  extensive experience of managing  large knowledge-based organisations  and has strong competences relating  to innovation, research, CSR and sus- tainable development. He is Professor  Honoris Causa at 10 international  universities and has received many  international awards, including the  Friendship Award and The Chinese  Government Highest International  Scientific and Technological Cooper- ation Award of the People’s Republic  of China. Most recently appointed as  Foreign Academician of the Chinese  Academy of Sciences, which advises  the Chinese government on major  scientific decisions. \nDeputy Chairman Born 1944. Elected 2008 and 2013.  Election period expires 2014. Chair- man of the Audit Committee and  member of the Nomination and  Remuneration Committees. Former  CEO of the A.P. Møller - Mærsk  Group (1993-2007) and before that  CFO of the same company from 1981.  Member of the Supervisory Board  and the Finance and Audit Com- mittees of The Chubb Corporation,  advisor to Permira and member  of Danske Bank’s Advisory Board.  Managing Director of J.S. Invest ApS  and one subsidiary. Mr Søderberg  has broad international experience  and extensive experience of financial  management and financial reporting  processes, performance manage- ment, and stakeholder and investor  relations management as a result of many years in the senior manage- ment of A.P. Møller - Mærsk. He has  wide experience of growth markets  and the identification and manage- ment of business risks.\nRICHARD BURROWS Born 1946. Elected 2009 and 2013.  Election period expires 2014. Chair- man of the Remuneration Commit- tee and member of the Audit Com- mittee. Mr Burrows has spent most  of his career in the drinks business.  He was joint CEO of Pernod Ricard  from 2000 to 2005. He is Chairman  of British American Tobacco and  VoiceSage Ltd. and a non-executive  director of the board of Rentokil  Initial plc. Mr Burrows has exten- sive experience of the branded  consumer goods sector and wide  international business experience  gained through his career with Irish  Distillers Group plc and Pernod  Ricard. He has extensive experience  of shareholder and investor rela- tions and a broad understanding  of the assessment and mitigation  of business risks. Mr Burrows has  worked extensively with developing  markets and product innovation,  and has substantial experience of  financial management and report- ing processes.\nDONNA CORDNER Born 1956. Elected 2012 and 2013.  Election period expires 2014. Mem- ber of the Audit Committee from 1  January 2013. Ms Cordner is a mem- ber of the Advisory Board of Vosges  Haut Chocolat, managing partner of  OKM Capital, a venture fund invest- ing in disruptive medical technology,  and CEO of HelpAge USA, the US  affiliate of HelpAge International,  an international NGO working to  address issues that affect older  people worldwide. Non-executive  director of Millicom International  Cellular SA 2004-2013, where she  was a member of the Audit Commit- tee and CSR Committee. Formerly  Managing Director and Global Head  of Telecommunications and Media  Structured Finance at Citigroup. She  has also held senior positions at So- ciété Générale and ABN Amro Bank  N.V. in the USA and Europe. She has  been CEO of HOFKAM Limited, the  largest rural microfinance company  in Uganda, and held the positions of  Executive Vice President of Corpor- ate Finance and Treasury, Market  Area Director and CEO for Russia  at Tele2 AB. Ms Cordner has ex- tensive international management  experience, including experience of  growth markets. She has substantial  experience of financial management  and financial reporting processes,  stakeholder and investor relations  management, and the assessment  and mitigation of business risks. She  has also worked extensively with  performance management and CSR  and sustainable development.\n162 Management review SUPERVISORY BOARD\n1  Independent board member.\nCarlsberg Group Annual Report 2013\nDONNA CORDNER 1 Born 1956. Elected 2012 and 2013. \nRICHARD BURROWS 1 Born 1946. Elected 2009 and 2013. \nJESS SØDERBERG 1 Deputy Chairman Born 1944. Elected 2008 and 2013. \nFLEMMING BESENBACHER Chairman Born 1952. Professor, D.Sc., h.c. "}]}
+{"image": "doclay/doclay_29742.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "\nFIG. 16: On the left: Thermopower [95] in K-doped FeAs2 indicating a possible T ln T electronic en trop y near the doping for highest T$_{c}$ , indicating possible quan tum-criticality; On the right: Re- sistivity [90] in Co-doped FeAs2 for various concentration, showing a possible linear in T resistivity near the doping of highest T$_{c}$ , indicating scattering from a singular fluctuations sp ectra consis- tent with that which gives T ln T for the electronic entropy. Both are charaterisitic of Marginal Fermi-liquids.\nthe hole-doped compound. The thermopower measurements are consistent with an entropy ∝ T ln( T ) down to T$_{c}$ from an upper cut-off of about the room temperature in a region close to the highest T$_{c}$ . Similarly, the resistivity is linear in temperature down to T$_{c}$ in a similar region. Neither of these properties are characteristic of fluctuations around a Gaussian quantum critical point, especially in 3d systems [31].\nMore experiments are needed to investigate whether the Fe-Pnictides have the same class of quantum-criticality as the Cuprates and the heavy-fermions. Experiments which would be helpful are measurements of the Raman and inelastic neutron scattering spectra, measurements of single-particle scattering rates by ARPES measurements and of transport scattering rate through optical conductivity measurements. Also analysis of ARPES spectra in the superconducting and normal state following such experiments to decipher the spec-\n51"}]}
+{"image": "doclay/doclay_69991.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "possible for these tests to be disputed, because there is no individual source of truth for what  the implementation should be doing to meet business needs.\nIn this section, we explore how different test stages in the API Test Pyramid apply to an IBM  API Connect solution.\n8.6.3 Test types\nUnit tests\nThe primary question when discussing Unit Testing is what makes up the smallest, testable,  self-contained component, as derived from the requirements. A unit test for an API should  not  call a back-end service. It should  not  rely on making requests from outside the API Connect  domain and should be executable in any simple IBM API Connect environment.\nThe smallest testable unit for API Connect APIs consist of the four components that make an  API:\nAn API has a primary data representation that is called a resource, which is the conceptual  mapping to a set of entities. The  address  of the resource is displayed as a  Uniform Resource  Identifier (URI)  which is crucial to making an API call. \nAddresses  will have tests such as; \nAn  operation  is the method of a REST API that determines what action to perform on the  resource. The four main HTTP verbs that define the operation are; GET (read), PUT (update),  POST (create), and DELETE (delete). \nOperation Unit Tests make requests to valid addresses to ensure that the API exposes only  the verbs that are outlined in the requirement. This test is simply about operation exposure.\nSimple security tests might also be applicable here like the absence of tokens, client IDs, or  certificates for secure endpoints. But they are unlikely to include more advanced tests such  as OAuth, which would be more applicable in integration tests as multiple calls are needed.\nRequest data  normally refers to a list of headers and the body of data that is passed with an  operation to an address. Tests at this level focus on whether the correct data is provided, the  correct headers are used, and that incorrect headers or malformed data are handled  correctly.\nResponse data  normally refers to how the resource call will respond to the request. The data  usually includes a status code, headers, and a body. Tests at this level aim to ensure that  valid and expected output is received when certain requests are passed into the system. \nAdditional tests will be used for the handling of both successful and failure scenarios. \nThe simplest unit test topology is shown in Figure 8-20 on page 565.\n564  Accelerating Modernization with Agile Integration\nGLYPH<SM590000> Its address\nGLYPH<SM590000> Its operation\nGLYPH<SM590000> Request data\nGLYPH<SM590000> Response data\nGLYPH<SM590000> Does an exposed address return a correct result? \nGLYPH<SM590000> Are unspecified addresses correctly handled? \nGLYPH<SM590000> Are misspelled addresses correctly handled?"}]}
+{"image": "doclay/doclay_74613.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "MORGAN STANLEY 1585 BROADWAY NEW YORK, NY 10036-8293 212-761-4000\nmorganstanley.com"}]}
+{"image": "doclay/doclay_31721.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "(a) p = 0 . 85 (b) p = 1 . 5\nFIG. 5: (color online). Typical configurations of MRJ packings of superballs with different values of the deformation parameter p .\n9\nsuperdisks. We do not use monodispersed superdisk systems here because they are easily crystallized into ordered packings [25]. For p = 1, one obtains the binary circular-disk sys- tem which has been intensively studied as a prototypical glass former [41]. Typical jammed packing configurations are shown in Fig. 3. The density φ and the average contact number per particle Z as a function of p are shown in Fig. 4, which reveals that the initial rapid in- creases of φ and Z are linear in | p − 1 | [42]. The density φ increases monotonically as p moves away from unity and shows no signs of a plateau, even for relatively large p . In addition, φ quickly surpasses the density of the optimal binary circular-disk packing associated with the size and molar ratios employed here, which contains phase-separate regions of triangular lattice packings of different sized circular disks [41]. The quantity Z quickly reaches its plateau value Z ∗ ≈ 4 . 7 at p ≈ 1 . 3, which is smaller than 2 f = 6, indicating the packings are hypostatic. The cubatic order parameter P$_{4}$ is defined as P$_{4}$ = 〈 (35 cos 4 θ − 30 cos 2 θ +3) / 8 〉 , where θ is the angle between the particle axis and the director, along which the principle axes of the particles have maximum mutual alignment [37]. The measured cubatic order parameter is P$_{4}$ ≈ 0 . 06 to 0 . 32 with the tendency to increase as | p − 1 | grows."}]}
+{"image": "doclay/doclay_223.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Consolidated Statements of Changes in Stockholders’ (Deficit)/Equity\nSee accompanying notes to consolidated financial statements.\nE m p l o y e e A d d i t i o n a l No. of C o m m o n Loans for Paid in Tre a s u ry S h a re s S t o s k S t o c k C a p i t a l S t o c k (in thousands, except share data) Balance December 31, 1997 1 5 , 1 3 3 , 3 2 1 $ 3 0 4. $ —. $ 6 3 , 3 58. $ ( 4 ) Wa rrants issue (note 11) — — . —. 1 , 7 25. — . Stock options exercised (note 18) 8 0 , 1 3 2 3. —. 1 75. — . Stock options granted in Euronet USA acquisition  (note 4) — — . —. 96. — . Subscription paid — — . —. — . — . Translation adjustment — — . —. — . — . Tax benefit from exercise of stock options (note 16) — —. —. 9 51 . — . S h a re compensation expense (note 18) — — . —. 1 08. — . Net loss for 1998 — — . —. — . — . Balance December 31, 1998 1 5 , 2 1 3 , 4 5 3 $ 3 0 7. $ —. $ 6 6 , 4 13. $ ( 4 ) S h a re compensation expense (note 18) — — . —. 1 27 . — . Stock options exercised (note 18) 2 2 8 , 5 0 3 4. —. 3 31 . — . Sale of tre a s u ry stock 1 0 0 , 0 0 0 — . —. 2 74 . 1 . Wa rrants re p u rchase (note 11) — — . —. ( 1 7 6 ) — . Employee loans for stock (note 25) — — . ( 7 9 4 ) — . — . Translation adjustment — — . —. — . — . Net loss for 1999 — — . —. — . — . Balance December 31, 1997 1 5 , 5 4 1 , 9 5 6 $ 3 1 1. $ ( 7 9 4 ). $ 6 6 , 9 6 9. $ ( 3 ) Stock options exercised (note 18) 3 9 0 , 2 3 1 8. —. 9 41 . — . Sale of common stock (note 12) 1 , 8 8 2 , 7 2 3 3 7. — . 1 3 , 0 4 5. — . Wa rrants issue (notes 12 and 13) — — . —. 3 7 2. — . S u b s c r i p t i o n s — — . —. — . — . Employee loans for stock (note 25) — — . 2 3 3. — . ( 1 3 7 ) Translation adjustment — — . —. — . — . Net loss for 2000 — — . —. — . — . Balance December 31, 2000 1 7 , 8 1 4 , 9 1 0 $ 3 5 6. $ ( 5 6 1 ) $ 8 1 , 3 2 7. $ ( 1 4 0 )\nSix bridges dominate the Tyne between Newcastle and Gateshead, enabling innovative railway and roadway advances over the past two centuries. At the time of its completion in 1929, the Tyne Bridge was the world’s longest single span bridge.\nRIVER TYNE BRIDGES, Newcastle\n2 6EU R O N E T SE RV I C E S IN C. A N D SU B S I D I A R I E S"}]}
+{"image": "doclay/doclay_43874.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "12-26"}]}
+{"image": "doclay/doclay_10946.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Partnering to Capture Growth"}]}
+{"image": "doclay/doclay_5332.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "The increase in general, administrative and support costs in 2001 reflects the increased activity in TransCanada’s Power business, as well as the company’s focus on future growth in this segment.\nMANAGEMENT ’ SDISCUSSIONANDANAL YSIS\nNORTHEASTERN U.S. OPERATIONS\nCALSTOCK\nCASTLETON\nTRANSCANADA 28\nT ransCanada com- pleted construction  of an enhanced wood waste-fired power plant at Calstock, Ontario in mid-2000 and trans- ferred it to Power LP in October 2000.\nIn July 1999, Power LP acquired a combined- cycle plant located at Castleton-on-Hudson, New York.\n1 Currently under construction. 2\nCurrently under construction. 2 At December 31, 2001, TransCanada held a 35.6 per cent ownership interest in Power LP. 3\nAt December 31, 2001, TransCanada held a 35.6 per cent ownership interest in Power LP. 3 TransCanada buys 560 MW of the Sundance A and 353 MW of the Sundance B power plant output through long-term PPAs.\nNortheastern U.S. Operations includes the 560 MW gas-fired OSP plant, the output from the 64 MW gas-fired Castleton power plant, the 60 MW Curtis Palmer hydroelectric power plant and the Westborough, Massachusetts power marketing office (TCPM). TCPM markets elec- tricity to a variety of customers throughout the northeastern U.S., both directly and through distribution re-sellers.\nincreased its earnings in 2001 by successfully providing electricity supply services to a variety of direct industrial\nThe Northeastern U.S. Operations’ operating income in 2001 increased $91 million or 134 per cent compared to 2000. This was primarily due to the ability to capitalize on unprece- dented price volatility throughout 2001 and significantly increased commercial activity of TCPM in 2001. Through prudent use of physical plant to backstop its marketing activities, supplemented with additional contract supplies and markets, TCPM was able to optimize its assets and capture market opportunities through this volatile period. TCPM sells the majority of the output from the northeastern plants under long-term arrangements, although contin- ued supply flexibility is fundamental to Power’s growth and success in the deregulated New England and New York markets. In addition, TCPM expanded its marketing efforts and\nPower’s net earnings of $105 million in 2000 increased by $65 million compared to 1999. This increase included a $23 million after-tax gain on the sale of TransCanada’s interest in the Hermiston Power Partnership in 2000, and reflected higher marketing and trading earnings; the acquisition of the remaining 29.9 per cent ownership interest in Ocean State in October 2000; and increased ownership interest and strong plant performance in the Power LP.\nHigher revenues and operating expenses in the Power segment reflect higher power prices, the addition of new facilities, and increased commercial activity in 2001 when compared to 2000 and 1999.\nNOMINAL GENERATING CAPACITY OF POWER PLANTS (MW)\nTransCanada Power Ocean State 560 MacKay River 1 165 Carseland 80 Bear Creek 1 80 Curtis Palmer 60 Redwater  40 Cancarb 27 Power LP 2 Williams Lake 66 Castleton 64 Tunis 43 Kapuskasing 40 Nipigon 40 North Bay 40 Calstock 35 Other 3 Sundance A 560 Sundance B 353 2,253"}]}
+{"image": "doclay/doclay_69819.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "12.3.1 I/O station and magazine\nFigure 12-5 shows the right side I/O station and magazine door.\nI/O stations are on the right side of the front panel of the library to enable the inserting and  removing of cartridges without interrupting normal library operations. An expansion module’s  I/O station has a capacity of up to five cartridges, depending on where it is located. If it is the  lowest module in the rack for the library, it has only four I/O slots available. \nIndividual I/O station elements cannot be shared between logical libraries. Importing or  exporting cartridges in a logical library without an assigned I/O station requires magazine  access, which takes the whole library offline.\nWhen an operator places cartridges in the I/O station and closes it, the library scans the slots  to update the library inventory. Cartridges should then be moved to storage slot locations by  using the Web User Interface (Web UI) or your backup application. Using the Web UI,  cartridges can be moved from one logical library’s  I/O station slot to a storage slot in another  logical library. However, a warning alert box is shown and the action must be confirmed.\nTo unlock the I/O station, click  Library →  Modules and Magazines →  Actions →  Unlock  I/O Station  from the management interface. The station can then be opened by pulling on the  magazine access handle. The magazine I/O button LED will indicate status of the I/O and  magazine, as shown in Table 12-2. \nChapter 12. IBM TS4300 tape library  317\nTable 12-2 Magazine state\nFigure 12-5 I/O door and MagazineMagazine state LED state Description Closed Steady ON I/O station is enabled Closed Slow Flash Magazine open is in process Closed Fast Flash Magazine is opened Closed OFF I/O station is not enabled Opened OFF Magazine is opened"}]}
+{"image": "doclay/doclay_72198.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Table of Contents\nCITIZENS, INC.\nReal Estate and Equipment Leases.  The Company entered into a long-term lease agreement with an unrelated party for its new home office in Austin, Texas and moved into its new home office in the first week of November 2020. Payments under this new long-term lease agreement average approximately $112,340 per month.\nTotal Purchase Obligations.  Total purchase obligations in the table above reflect primarily the $8.8 million held in the Rabbi Trust at December 31, 2020 for the severance payment made to Mr. Kolander in February 2021.\nThe Company does not have off-balance sheet arrangements at December 31, 2020 and does not expect any future effects on the Company's financial condition related to any such arrangements. We do not utilize special purpose entities as investment vehicles, nor are there any such entities in which we have an investment that engages in speculative activities of any nature, and we do not use such investments to hedge our investment positions.\nThe preparation of consolidated financial statements in accordance with U.S. GAAP requires management to make estimates and assumptions that affect reported amounts and related disclosures. Management considers an accounting estimate to be critical if: (1) it requires assumptions to be made that were uncertain at the time the estimate was made; and (2) changes in the estimate, or different estimates that could have been selected, could have a material effect on our consolidated results of operations or financial condition. While we believe that our estimates, assumptions and judgments are reasonable, they are based on information presently available. Changes in our assumptions, estimates or assessments as a result of unforeseen events or otherwise could have a material impact on our financial position or results of operations.\nManagement has discussed the development and selection of its critical accounting estimates with the Audit Committee of the Board of Directors, and the Audit Committee has reviewed the disclosure presented below relating to them. See  Note 1. Summary of Significant Accounting Policies  in the notes to our consolidated financial statements for further information on our critical accounting policies.\nBased upon current accounting guidance, investment securities must be classified as held-to-maturity, available-for-sale (\"AFS\") or trading. Management determines the appropriate classification at the time of purchase. The classification of securities is significant since it directly impacts the accounting for unrealized gains and losses on securities. Fixed maturity securities are classified as held-to-maturity and carried at amortized cost when management has the positive intent and the Company has the ability to hold the securities to maturity. Securities not classified as held-to-maturity are classified as AFS and are carried at fair value, with the unrealized holding gains and losses, net of tax, reported in other comprehensive income and do not affect earnings until realized. The Company currently does not hold any fixed maturity securities classified as held- to-maturity.\nThe Company monitors all fixed maturity securities on an on-going basis relative to changes in credit ratings, market prices, earnings trends and financial performance, in addition to specific region or industry reviews. The Company evaluates whether a credit impairment exists for fixed maturity securities by considering primarily the following factors: (a) changes in the financial condition of the security's underlying collateral; (b) whether the issuer is current on contractually obligated interest and principal payments; (c) changes in the financial condition, credit rating and near- term prospects of the issuer; and (d) the payment structure of the security. The Company's best estimate of expected future cash flows used to determine the credit loss amount is a quantitative and qualitative process. Quantitative review includes information received from third-party sources such as financial statements, pricing and rating changes, liquidity and other statistical information. Qualitative factors include judgments related to business strategies, economic impacts on the issuer, overall judgment related to estimates and industry factors as well as the Company's intent to sell the security, or if it is more likely than not that the Company would be required to sell a security before recovery of its amortized cost.\nThe Company's best estimate of future cash flows involves assumptions including, but not limited to, various performance indicators, such as historical and projected default and recovery rates, credit ratings, and current delinquency rates. These assumptions require the use of significant management judgment and include the\nDecember 31, 2020 | 10-K 61\nCRITICAL ACCOUNTING POLICIES\nVALUATION OF INVESTMENTS IN FIXED MATURITY SECURITIES"}]}
+{"image": "doclay/doclay_56908.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Resource Group Management Statements\n[THREAD_PRIORITY [=]  N ] [ENABLE|DISABLE] vcpu_spec : { N  |  M  -  N }\nCREATE RESOURCE GROUP  is used for resource group management (see Section 5.1.16, “Resource Groups” ). This statement creates a new resource group and assigns its initial attribute values. It requires the  RESOURCE_GROUP_ADMIN  privilege.\ngroup_name  identifies which resource group to create. If the group already exists, an error occurs.\nThe  TYPE  attribute is required. It should be  SYSTEM  for a system resource group,  USER  for a user resource group. The group type affects permitted  THREAD_PRIORITY  values, as described later.\nThe  VCPU  attribute indicates the CPU affinity; that is, the set of virtual CPUs the group can use:\n•If  VCPU  is not given, the resource group has no CPU affinity and can use all available CPUs.\n•If  VCPU  is given, the attribute value is a list of comma-separated CPU numbers or ranges:\n• Each number must be an integer in the range from 0 to the number of CPUs  − 1. For example, on a system with 64 CPUs, the number can range from 0 to 63.\n• A range is given in the form  M − N , where  M  is less than or equal to  N  and both numbers are in the CPU range.\n•If a CPU number is an integer outside the permitted range or is not an integer, an error occurs.\nVCPU = 0,1,2,3,9,10 VCPU = 0-3,9-10 VCPU = 9,10,0-3 VCPU = 0,10,1,9,3,2\nThe  THREAD_PRIORITY  attribute indicates the priority for threads assigned to the group:\n•If  THREAD_PRIORITY  is not given, the default priority is 0.\n•If  THREAD_PRIORITY  is given, the attribute value must be in the range from -20 (highest priority) to 19 (lowest priority). The priority for system resource groups must be in the range from -20 to 0. The priority for user resource groups must be in the range from 0 to 19. Use of different ranges for system and user groups ensures that user threads never have a higher priority than system threads.\n•Create an enabled user group that has a single CPU and the lowest priority:\n•Create a disabled system group that has no CPU affinity (can use all CPUs) and the highest priority:\nENABLE  and  DISABLE  specify that the resource group is initially enabled or disabled. If neither is specified, the group is enabled by default. A disabled group cannot have threads assigned to it.\nExamples:\nCREATE RESOURCE GROUP rg1 TYPE = USER VCPU = 0 THREAD_PRIORITY = 19;\nCREATE RESOURCE GROUP rg2 TYPE = SYSTEM\n2884\nExample  VCPU  specifiers (these are all equivalent):"}]}
+{"image": "doclay/doclay_36851.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Checkliste  –  Nachweise und Unterlagen \nVon den beauftragten Firmen sind folgende Nachweise vor Arbeitsbeginn vorzulegen. Die Check- liste dient dabei als Inhaltsverzeichnis der bereitgestellten Ordner. In ihr sind die wichtigsten auf  der Baustelle vorzulegenden Nachweise aufgeführt, sie erhebt aber keinen Anspruch auf Voll- ständigkeit. Sowohl der SiGePlan, als auch die Vorgaben Bauleitung, Auftraggeber und Fachpla- ner können die Vorlage weiterer Nachweise erforderlich machen. \n Gefährdungsanalyse für das jeweilige Gewerk \nPrüfprotokolle Kräne \nNachweis der Bestellung und Qualifikation des/der Kranführer/s \nNachweis sicherheitstechnische Unterweisung der Mitarbeiter \nPrüfprotokolle Baustrom \nPrüfprotokolle Bauaufzüge mit Personenbeförderung (überwachungsbedürftige Anlage nach Be- trSichV) \nEinweisungsnachweise der Firmen für Bauaufzüge mit Personenbeförderung \nPrüfprotokolle Anstellaufzüge (Arbeitsmittel nach BetrSichV) (z.B. Fassadenaufzug) \nEinweisungsnachweise der Firmen für die Anstellaufzüge \nPrüfprotokolle Anlegeaufzüge (z.B. Dachdeckeraufzug) \nDokumentation der Abnahme der Freischaltung von Strom- und Medienleitungen\nDokumentation der Abnahme Absperren/Entleeren der Wasser- und Abwasserleitungen im Abbruchbe- reich \nDokumentation der Abnahme Absperren/Kontrolle der Gasleitungen im Abbruchbereich \nDokumentation Freimessen von Gasleitungen bei Abbau von Containern und Gastanks \nDokumentation Freimessen von Schächten und Tanks \nPrüfprotokolle Gerüste (nach BGI 663) \nÜbergabeprotokolle Gerüste (nach BGI 663) \nPrüfprotokoll Hubarbeitsbühnen \nErste Hilfe \nMerkblatt zur Meldung der Projektbeteiligten \nAbbruchanweisung \nAbbruchanzeige \nMontageanweisungen \nPrüfnachweis Feuerlöscher (kann auch an den Geräten angebracht sein) \nPrüfnachweise elektrische Handgeräte \nErste Hilfe: Meldung der Ersthelfer auf der Baustelle mit Hilfe des Merkblatts \"Meldung der Projektbe- teiligten\" \nVon den Firmen vorzulegende Nachweise \nNachweise für gemeinsam genutzte Maschinen und Einrichtungen "}]}
+{"image": "doclay/doclay_49743.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "AAATHE\nspecified at very low levels so even small amounts of use could be  above the specified limits. The limits for certain medicines have  been specified at higher levels, above the levels generally found in  the blood of patients who have taken normal therapeutic doses. If you are found to have a concentration of a drug above its specified  limit in your blood because you have been prescribed or  legitimately supplied a particularly high dose of medicine, then you  can raise a statutory medical defence, provided your driving was  not impaired by the medicine you are taking. \nLaw RTA 1988 sects 4 & 5 \n4.Before setting off \n97. Before setting off.   You should ensure that \n● you have planned your route and allowed sufficient time \n● clothing and footwear do not prevent you using the controls  in the correct manner \n● you know where all the controls are and how to use them  before you need them. Not all vehicles are the same; do not  wait until it is too late to find out \n● your mirrors and seat are adjusted correctly to ensure  comfort, full control and maximum vision \n● head restraints are properly adjusted to reduce the risk of neck and spine injuries in the event of a collision \n● you have sufficient fuel before commencing your journey,  especially if it includes motorway driving. It can be  dangerous to lose power when driving in traffic \n● ensure your vehicle is legal and roadworthy \nhighwaycodeuk.co.uk 46 "}]}
+{"image": "doclay/doclay_8274.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "CONSOLIDATED STATEMENT OF STOCKHOLDER’S EQUITY\nAspen Technology, Inc. and Subsidiaries Consolidated Statements Stockholder’s Equity\nAdditional Number of Carrying Number of $0.10 Par Paid-in  Shares Value Shares Value Capital (In thousands, except share data) Balance, July 1, 2000 — $—  29,060,428 $2,906 $173,591 Issuance of stock in the purchase of businesses and equity investment — — 1,255,782 126 37,151 Issuance of common stock under employee stock purchase plans — — 174,463 17 4,693 Exercise of stock options and warrants — — 991,751 99 11,802 Translation adjustment, not tax effected — — — — — Unrealized market gain on investments, net of tax effect — — — — — Issuance of restricted common stock — — 94,500 9 1,739 Amortization of deferred compensation — — — — — Net Loss — — — — — Comprehensive net loss for the year ended June 30, 2001 Balance, June 30, 2001 — — 31,576,924 3,157 228,976 Issuance of common stock under employee stock purchase plans — — 313,337 31 5,275 Exercise of stock options and warrants — — 185,625 19 1,600 Issuance of Series B convertible preferred stock and common stock warrants, net of issuance costs 60,000 48,544 — — 8,044 Beneficial conversion feature embedded in Series B convertible preferred stock — (3,232) — — 3,232 Issuance of common stock and common stock warrants, net of issuance costs — — 4,166,665 417 47,539 Issuance of common stock in settlement of obligation subject to common stock settlement — — 1,641,672 164 18,336 Return of escrowed shares issued to Optimum Logistics Ltd — — (58,540) (6) (2,084) Reversal of unvested and forfeited restricted common stock — — (94,500) (9) (1,739) Accretion of discount on Series B convertible preferred stock — 5,441 — — — Accrual of Series B convertible preferred stock dividend — — — — 860 Translation adjustment, not tax effected — — — — — Unrealized market gain on investments, net of tax effect — — — — — Amortization of deferred compensation — — — — — Net Loss — — — — — Comprehensive net loss for the year ended June 30, 2002 Balance, June 30, 2002 60,000 50,753 37,731,183 3,773 310,039 Issuance of common stock under employee stock purchase plans — — 759,771 76 3,217 Exercise of stock options — — 56,934 6 144 Issuance of common stock in settlement of Series B convertible preferred stock dividend — — 731,380 74 (74) Accrual of Series B convertible preferred stock dividend — — — — 2,400 Accretion of discount on Series B convertible preferred stock — 6,784 — — — Modification of Series B convertible preferred stock (60,000) (57,537) — — — Reacquisition of common shares issued to CPU — — — — — Translation adjustment, not tax effected — — — — — Unrealized market gain on investments, net of tax effect — — — — — Net Loss — — — — — Comprehensive net loss for the year ended June 30, 2003 Balance, June 30, 2003 — $— 39,279,268 $3,929 $315,726 Series B Convertible Preferred Stock Common Stock\n34"}]}
+{"image": "doclay/doclay_67467.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Examples\n' Copyright IBM Corp. 2 020. All rights reserved.\nxi\n1-1 Checking the AIX environment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1-2 Authentication between the AIX server and HMC. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1-3 Authentication between the AIX server and IBM PowerVC . . . . . . . . . . . . . . . . . . . . . . 6 1-4 Editing /var/adm/ras/liveupdate/lvupdate.data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1-5 Running geninstall -k to perform Live Update. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1-6 CPU_Reduc stanza in the liveupdate.cf file . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 1-7 CPU_Usage stanza in the liveupdate.cf file . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 1-8 Creating a cache pool and cache partition in a dedicated flash logical unit number. . . 20 1-9 Assigning a cache partition to a target device that must be cached . . . . . . . . . . . . . . . 20 1-10 Starting caching on the hdisk2 target and monitoring the status . . . . . . . . . . . . . . . . 20 1-11 Creating a cache pool and cache partition in a VIOS . . . . . . . . . . . . . . . . . . . . . . . . . 21 1-12 Assigning the cache partition to a vhost in a VIOS . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 1-13 Assigning a cache partition to a target hdisk2 device in the AIX LPAR . . . . . . . . . . . 21 1-14 Starting caching on the hdisk2 target and monitoring the status . . . . . . . . . . . . . . . . 21 1-15 Creating a cache pool and cache partition in an NPIV flash logical unit number . . . . 22 1-16 Assigning a cache partition to a target device that must be cached . . . . . . . . . . . . . . 22 1-17 Starting caching on a hdisk2 target and monitoring the status . . . . . . . . . . . . . . . . . . 22 1-18 Using lsmpio to check the path status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 1-19 Displaying parent adapters and remote ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 1-20 Sample output of MPIO detailed statistics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 1-21 Dynamic queue_depth update for device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 1-22 Changing the default reserve_policy to no_reserve for AIXPCM FC disk. . . . . . . . . . 27 1-23 Changing the default algorithm to shortest_queue for the AIXPCM iSCSI disk . . . . . 28 1-24 Disabling paths by using chpath . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 1-25 File-based iSCSI discovery. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 1-26 ODM-based iSCSI discovery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 1-27 Add an iSCSI Target Protocol Device smitty menu. . . . . . . . . . . . . . . . . . . . . . . . . . . 32 1-28 Enabling the nimhttp subsystem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 1-29 Using nimhttp without using cryptographic authentication . . . . . . . . . . . . . . . . . . . . . 35 1-30 Creating an HMC resource . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 1-31 Using nimquery to define the CEC object . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 1-32 Manually defining a CEC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 1-33 Registering the NIM client by using niminit on the client partition . . . . . . . . . . . . . . . . 38 1-34 Adding a management source and LPAR ID to an AIX machine . . . . . . . . . . . . . . . . 38 1-35 Creating a Live Update data resource . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 1-36 Live Update initiated from the NIM master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 1-37 The defragfs command . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 1-38 Checking the file system space reclamation support . . . . . . . . . . . . . . . . . . . . . . . . . 46 1-39 Checking the system physical volumes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 1-40 Initiating the cloning process to hdisk1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 1-41 Checking the new volume group that is created after the clone . . . . . . . . . . . . . . . . . 48 1-42 Waking up the clone and putting it to sleep . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 1-43 Changing the root directory to access altinst_rootvg clone . . . . . . . . . . . . . . . . . . . . 49 1-44 Putting altinst_rootvg to sleep . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 1-45 Attempting to create another clone from the mksysb image and receiving an error . . 50 1-46 Renaming the first altinst_rootvg clone . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51 1-47 Creating a second clone and renaming it . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51 1-48 The nmon command to collect processor frequency metrics . . . . . . . . . . . . . . . . . . . 55"}]}
+{"image": "doclay/doclay_15712.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "5. Term deposits\n6. Financial Instruments\nOperating Loan Facility \nContracts measured at fair value\nForward exchange contracts \nThe term deposits are classified as short term as they can be redeemed prior to maturity without penalty.\nDuring the fourth quarter of 2013 the Company increased its operating loan facility to $100,000,000 and  extended its term for an additional year until 2018. During 2011, the Company established an operating  loan facility totaling $50,000,000 with an initial five year term with its principal banker and during the fourth  quarter of 2012 the Company increased its operating loan facility to $75,000,000 and extended its term for an  additional year until 2017. The interest rate on the facility varies based upon the actual amounts borrowed, but  ranges from 0.45% to 1.45% over prime interest rates or 1.45% to 2.45% over guaranteed notes, depending  on the preference of the Company. Security for this facility includes a General Security Agreement covering all  current and future assets. \n In accordance with its loan facility, the Company is required to ensure that the following covenants are met:\nEBITDA is not a recognized measure under IFRS. EBITDA is defined as net income from continuing operations  before interest expense, current tax expense, depreciation and amortization. Tangible Assets, as per the  loan agreement, consists of all accounts receivable, inventory, unrestricted cash, term deposits and cash  equivalents and the net book value of fixed assets. \nThe Company did not access the loan facility in 2013. The Company accessed the loan facility during the  second quarter of 2012 on a short-term basis, having repaid the amount borrowed prior to June 30, 2012. \nDuring the third quarter of 2013 the Company entered into a forward exchange contract as a risk management  strategy. Forward exchange contracts are included in current assets/liabilities except for those with maturities  greater than 12 months after the end of the reporting period, which are classified as non-current assets/ liabilities. The Company has not designated any of its forward exchange contracts as effective accounting  hedges and, accordingly, fair values its forward exchange contracts with the resulting gains and losses recorded  in the Consolidated Statement of Net Income and Comprehensive Income. \n47\nAKITA DRILLING LTD.  ANNUAL REPORT\nNOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS\n$Thousands  December 31 2013 December 31 2012 Term deposits  $ 5,000  $ -  Effective interest rate (%) on term deposits 1.5 N/A Average number of days from year-end to maturity for term deposits 20 N/A\n•  the ratio of Funded Debt to EBITDA shall not exceed 3.00:1.00 calculated on a trailing 12 month  basis;\n•  the ratio of EBITDA to Interest Expense shall not be less than 3.00:1.00 calculated on a trailing  12 month basis;\n•  the ratio of Tangible Assets to Funded Debt shall not be less than 2.25:1.00."}]}
+{"image": "doclay/doclay_35973.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "16\n1963) 14 , 99. 15 W.P. Osmond, Proc. Phys. Soc. 87 , 335 (1966).\nJ. Kanamori, J. Phys. Chem. Solid 10 , 87 (1959). 14 P.W. Anderson, Solid State Physics , edited by F. Seiz and D. Turnbull (Academic Press, New York and London, 1963) 14 , 99. 15\n(John-Wiley & Sons, New York, 1963). 13 J. Kanamori, J. Phys. Chem. Solid 10 , 87 (1959). 14\nJ.B. Goodenough, Phys. Rev. 117 , 1142 (1960). 12 J.B. Goodenough, Magnetism and the Chemical Bond (John-Wiley & Sons, New York, 1963). 13\nReports on Progr. in Phys. 17 , 201 (1954). 11 J.B. Goodenough, Phys. Rev. 117 , 1142 (1960). 12\nNew York,1967). 10 H. Bizette and B. Tsai, Colloque sur la polarization de la matere cited by Lidiard (Paris, C.N.R.S., 1949) 164, Reports on Progr. in Phys. 17 , 201 (1954). 11\n61 , 3563 (2000). 9 T. Nagamiya, Solid State Physics , edited by F. Seiz, D. Turnbull, and H. Ehrenreich, 20 , 305 (Academic Press, New York,1967). 10\n333 , 757 (2003). 8 H. Sato, T. Enoki, M. Isobe, and Y. Ueda, Phys. Rev. B\n70 , 37 (2001). 7 H. Sato, Y. Kawamura, T. Ogawa, Y. Murakami, H. Ohsumi, M. Mizumaki, and N. Ikeda, Physica B 329 – 333 , 757 (2003). 8\nmann, J. Phys. Soc. Jpn. 73 , 3444 (2004). 6 H. Sato, K. Wakiya, T. Enoki, T. Kiyama, Y. Wak- abayashi, H. Nakano, and Y. Murakami, J. Phys. Soc. Jpn. 70 , 37 (2001). 7\nmann, Phys. Rev. B 68 , 172401 (2003). 5 M. Regulski, R.Przenioslo, I. Sosnowska, and J.-U. Hoff- mann, J. Phys. Soc. Jpn. 73 , 3444 (2004). 6\n(1971). 4 M. Regulski, R.Przenioslo, I. Sosnowska, and J.-U. Hoff- mann, Phys. Rev. B 68 , 172401 (2003). 5\nA. Yoshimori, J. Phys. Soc. Jpn. 14 , 807 (1959). 3 N. Ohama and Y. Hamaguchi, J. Phys. Soc. Jpn. 30 , 1311 (1971). 4\nR.A. Erickson, Phys. Rev. 90 , 779 (1953). 2 A. Yoshimori, J. Phys. Soc. Jpn. 14 , 807 (1959). 3\nitsuko@binghamton.edu 1 R.A. Erickson, Phys. Rev. 90 , 779 (1953). 2\nsuzuki@binghamton.edu † itsuko@binghamton.edu 1\n∗ suzuki@binghamton.edu †\n61 , 3563 (2000)."}]}
+{"image": "doclay/doclay_64067.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "9 \nUS 6,537,456 B2 \n10 \nI have found that by reliable hardness and non-hydroxide  alkalinity removal, to levels which effectively avoid forma› tion of scale at a selected pH for RO operation, the concen› tration of SiO$_{2 }$ in the RO reject stream can be safely  increased to 450 ppm or more. This is accomplished by  increasing the pH of the feedwater to the RO system, and  without use of scale-inhibition chemicals. Moreover, even  with this increase of silica in the RO reject, the level of silica \nThe first step is to adjust the hardness-to-alkalinity ratio of  the feedwater, if needed. Optimizing this ratio, which is 60  typically done by alkali addition, makes complete hardness  removal feasible in the next process step. \nThe second step in the RO process train involves the  utilization of a weak acid cation (WAC) resin (e.g. DOWEX  (R) MAC-3, or Lewatit CNP-80, Amberlite(R) IRC-86).  Operated in hydrogen form, the WAC resin removes hard› ness quantitatively, given the proper hardness-to-alkalinity \nThe selection of specific operations and control points to  fulfill the above process condition requirements is influ› enced by the characteristics of each specific feedwater. The  percent recovery needed ( or desired for a specific  application) also affects the operations and control point  criteria as well. FIG. 2 represents a highly cost effective RO  unit process sequence. \nScaling due to various scale forming compounds, such as  calcium sulfate, calcium carbonate, and the like, can be  predicted by those of ordinary skill in the art and to whom  this specification is directed, by use of the Langlier Satura- tion Index, as discussed above, or other available solubility  data. Operating parameters, including temperature, pH, per› meate and reject flow rates, must be properly accounted for,  as well as the various species of ions in the raw feedwater,  and those species added during pretreatment. \nFeedwaters utilized for production of high purity water, as  well as those encountered in wastewater treatment, include  the presence of silicon dioxide ( also known as silica or  Si0$_{2}$ )  in one form or another, depending upon  pH  and the other  species present in the water. For membrane separation  systems, and in particular for RO type membrane separation  systems, scaling of the membrane due to silica is to be  religiously avoided. This is because (a) silica forms rela› tively hard scale that reduces productivity of the membrane,  (b) is usually rather difficult to remove, (c) the scale removal  process produces undesirable quantities of spent cleaning  chemicals, and (d) cleaning cycles result in undesirable and  unproductive off-line periods for the equipment. Therefore,  regardless of the level of silica in the incoming raw  feedwater, operation of conventional membrane separation  processes generally involves concentration of  Si0$_{2 }$ in the  high total dissolved solids  (\"TDS\")  stream to a level not  appreciably in excess of 150 ppm of SiO$_{2 }$ (as SiO$_{2}$ ).  Typically, RO systems are operated at lowered recovery  rates, where necessary, to prevent silica concentration in the  reject stream from exceeding roughly 150 ppm. \nIn order to operate an  RO  system with reject up to near  pH  11, or at about  pH  11, or above, several process conditions  must be met in order to effectively eliminate the potential for  scale formation on the  RO  membrane. Some of those  process conditions are also necessary for operating an  RO  system at very high recovery rate. Such process conditions  are as follows: \nThe next step consists of operating the RO system in such  a manner that the pH of the reject is approximately, but  preferably not appreciably higher than, 11.0. Note that this  pH 11 limitation is applicable simply with respect to cur› rently available RO membranes.  An exemplary membrane,  with the highest pH tolerance capability, is a FILMTEC type  FT30 membrane.  If RO membranes with a higher pH  tolerance capability become available in the future, then the  maximum allowable RO reject pH can be raised accordingly,  with concomitant benefits from the higher pH, in excess of  11.0. \nBecause of the very high concentration factors (i.e. per- cent recovery) allowed by my HERO brand RO process, the  RO feed pH is correspondingly lower. For example, in a  system operating at ninety percent (90%) recovery, a feed  pH of 10.0 will produce a reject stream at an approximate pH  of 11, provided that the RO feed is only slightly buffered by  the presence of carbonate, phosphate, etc. Unlike conven› tional RO systems, typically operated at about seventy five  percent (75%) recovery, a HERO brand RO system can be  routinely operated at ninety percent (90%) or greater  recovery, limited only by osmotic pressure of the RO reject.  The pH increase from RO feed to reject is magnified at very  high recoveries. Thus, the maximum allowable pH is spe› cifically applicable for the  RO  reject conditions. \nThe HERO brand RO system is highly site-specific.  Individual process steps are customized to fit the specific  feedwater at a specific site. Regardless of the difference in  pretreatment process for different sites, one process param› eter is common for all applications, namely that the RO  system is operated at the highest feasible reject pH. Con› sistent with the highest allowable  pH  limit for currently  available  RO  membranes (for example,  pH  11.0 for  FILMTEC(R)  brand  RO  elements), a typical  HERO  brand  RO  system is designed to operate at  pH  of up to approxi› mately 11, as measured in the  RO  reject stream. \nIn a fourth step, the acidified effluent, containing virtually  zero hardness and alkalinity, is then treated for carbon  dioxide removal. This removal can be accomplished in a  forced/induced draft decarbonator or in an existing vacuum  degasifier of either packed bed or gas permeable membrane  barrier design. The decarbonated, essentially zero hardness,  essentially zero alkalinity water, is then injected with a  soluble alkali, preferably for adjusting pH to 10.0 or higher,  and most preferably to the pH as needed to achieve pH up  to at or near 11.0 in the RO reject. \nThe third step involves adding acid to the WAC effluent  to destroy the remaining alkalinity, if any such alkalinity is  present. Total alkalinity removal at this step is important in  order to achieve very high recovery across the RO system. \nratio of the influent. The hydrogen ions liberated in the  cation exchange process react with the alkalinity and pro› duce carbonic acid (H$_{2}$ CO$_{3}$ ) 2 ,  which is dissolved in the  WAC effluent. \n(8) Substantially higher flux is achieved. \n(9) Reduced overall capital cost, compared to conven› tional RO systems. \n(10) Reduced overall operating cost, compared to con- ventional RO systems. \n(11) The complexity of an ultrapure water system is  significantly reduced. \n(1) Calcium, magnesium, strontium, and barium concen› tration in the RO feed must be substantially eliminated,  preferably to near zero, and most preferably, to essen› tially zero. \n(2) Aluminum, iron, and manganese content including  organically bound species, as well as the presence of  colloidal particles containing such materials, should be  substantially eliminated, and preferably to near zero. \n(3) Buffering anions (specifically bicarbonate, or  carbonate, and/or phosphate species) should be reduced  to as low of a level as can be practically achieved. "}]}
+{"image": "doclay/doclay_38607.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Evidence of technical and  professional capacity T5 (see Section 3.2.3)  The documents must be provided  only by the  involved entities   who contribute to reaching the minimum capacity level for criterion T5 Submit the list of reports  with  the  tender  in  e- Submission  Further details only upon  request by  the Contracting  authority at any time during  the procedure  “Reference_  List_T5”  With the Group leader or  the  sole  tenderer  under  'Parties'   'Identification  tenderer'   'Attachments'  'Tech- nical  and  professional  capacity'.  Evidence of technical and  professional capacity T6 (see Section 3.2.3)  The documents must be provided  only by the  involved entities   who contribute to reaching the minimum capacity level for criterion T6 Submit the list of projects  with  the  tender  in  e- Submission  Further details only upon  request by  the Contracting  authority at any time during  the procedure  “Reference_  List_T6”  With the Group leader or  the  sole  tenderer  under  'Parties'   'Identification  tenderer'   'Attachments'  'Tech- nical  and  professional  capacity'.  Evidence of technical and  professional capacity T7 (see Section 3.2.3)  The documents must be provided  only by the  involved entities   who contribute to reaching the minimum capacity level for criterion T7 Submit the CV and reference  list of the project manager  with  the  tender  in  e- Submission  Further details only upon  request by  the Contracting  authority at any time during  the procedure  “CVs_T7”  With the Group leader or  the  sole  tenderer  under  'Parties'   'Identification  tenderer'   'Attachments'  'Tech- nical  and  professional  capacity'.  Evidence of technical and  professional capacity T8 (see Section 3.2.3)  The documents must be provided  only by the  involved entities   who contribute to reaching the minimum capacity level for criterion T8 Submit the CV and reference  list of the lead editor with the  tender in e-Submission  Further details only upon  request by  the Contracting  authority at any time during  the procedure  “CVs_T8”  With the Group leader or  the  sole  tenderer  under  'Parties'   'Identification  tenderer'   'Attachments'  'Tech- nical  and  professional  capacity'.  Evidence of technical and  professional capacity T9 The documents must be provided  only by the  involved entities  Submit the CVs of the core  technical  team  with  the  tender in e-Submission  “CVs_T9”  With the Group leader or  the  sole  tenderer  under  'Parties'   'Identification  tenderer'   'Attachments'  'Tech-\n47"}]}
+{"image": "doclay/doclay_47113.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "or other heavy abuse still stains and/or damages the rig  materials. Scotchgard $^{®}$ is not harmful to today’s container  fabrics, such as para-pak and Cordura$^{®}$. There are currently  several Scotchgard ® formulas. The standard fabric and  upholstery formula is in the red can.  [Figure A]  Do not use  the rug and carpet formula in the blue can. After the rig is  completely dry, hang it in a well ventilated location.\nFollowing the directions on the can, apply the protector to  the entire outer surface of the rig. For those areas, such as  the inside of the leg pads, backpad, and bottom of the main  container, and light colored panels, such as white, etc., apply  a second coat after the first has dried. Do not intentionally  spray the hardware, housings, and clear vinyl CYPRES ®  window. After the rig has dried, it may then be reassembled  and placed back into service.\nIt is very important that any repairs or maintenance of the  parachute and its related systems are done correctly so that the  parachute is always airworthy. This chapter provides detailed  step-by-step procedures for many repairs and alterations that  can be done by both senior and master riggers. All riggers  must learn to identify conditions that may be unsafe and learn  how to undertake the necessary repairs to return the parachute  to its original, airworthy configuration. \nChapter Summary\n7-90\n"}]}
+{"image": "doclay/doclay_13867.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Joseph Dell Jr. SENIOR VICE PRESIDENT FOR CORPORATE LENDING , Indiana Office\nchildhood. His parents, says Joe, “raised  me to help people. Volunteerism is just an  extension of my upbringing.” The young  Cub Scout who once sold brooms and  cushions for the Lions Club and helped his  church is now president of the Center for \nFamily Life, a prevention arm of the child  welfare system. He also coaches his  daughter’s softball team and serves on  several boards and committees. “Service  is a First Commonwealth tradition,” Joe  says. “We take seriously our responsibility  to keep communities strong.”\nSuccessful Strategies were implemented in large part  through the unified branding program that began in late 2002.  Every First Commonwealth affiliate became part of a new  single First Commonwealth identity with a common name, logo,  colors, signage, and marketing strategy. Though the look of \ninto a continuous process with an  eighteen month forecast completed  every month. \nS uccessful Strategies come from a  disciplined planning process that carefully  evaluates the current economic climate,  understands past and present trends, and  analyzes future possibilities. This process  identifi es the services our clients desire and  defi nes how First Commonwealth can meet  those needs. At First Commonwealth, we have  transformed annual planning and budgeting \nFirst Commonwealth\n4\nJOE DELL TRACES HIS COMMITMENT  TO COMMUNITY SERVICE BACK TO HIS"}]}
+{"image": "doclay/doclay_957.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Notes to the Consolidated Financial Statements Dollar amounts are in thousands of Canadian dollars (except share and per share amounts)\nNotes to the Consolidated Financial Statements Dollar amounts are in thousands of Canadian dollars (except share and per share amounts)\n5.  Investment Properties (continued)\nSensitivity Analysis\nThe investment property segment defined as Other consists of one commercial property of which the Company has a 50% ownership. The  property has a fair value of $2.2 million (December 31, 2012 ‑ $2.1 million).\nIPUC includes land held for future development, which is recorded at a fair value of $2.8 million (December 31, 2012 ‑ $5.2 million) and  properties under construction of $21.6 million (December 31, 2012 ‑ $52.7 million). Fair value cannot be reliably determined for properties  under construction as the projects are in the early stages of development and therefore IPUC is recorded at cost.\nThe significant unobservable inputs used in the fair value measurements categorized within Level 3 of the fair value hierarchy include  cap‑rates, vacancy rates and management fee rates. Investment property valuations are most sensitive to changes in the cap‑rate. The  cap‑rate assumptions for the investment properties are included in the following table:\nThe quantitative sensitivity analysis shown below illustrates the value increase or decrease in the Company’s portfolio of properties given  the change in the noted input.\nDecember 31, 2013 December 31, 2012 Low High Effective  Weighted  Average low High Effective  Weighted  average Apartments 5.88% 6.02% Halifax 5.15% 7.00% 5.87% 5.30% 7.00% 5.85% moncton 5.56% 8.00% 5.94% 6.00% 8.00% 6.30% Fredericton 5.15% 6.25% 5.93% 5.75% 6.50% 6.30% saint John 6.25% 6.75% 6.63% 6.00% 6.75% 6.45% st. John’s  5.15% 6.25% 5.94% 6.25% 7.00% 6.36% Charlottetown 5.65% 6.00% 5.88% 5.75% 6.50% 6.15% ontario 4.50% 5.25% 5.26% 4.50% 5.25% 5.25% Other Atlantic 6.00% 7.00% 6.76% 6.25% 7.00% 7.31% MHCs 6.86% 7.04% ontario 7.00% 8.00% 7.09% 7.00% 8.50% 7.34% Nova Scotia 6.00% 7.50% 6.61% 6.50% 7.50% 6.96% new Brunswick 8.25% 8.25% 8.25% 6.50% 8.50% 6.87% newfoundland and labrador 7.25% 7.25% 7.25% 7.50% 7.50% 7.50%\n80 Killam ProPerties inc | 2013\nClass of property Capitalization rate Vacancy rate Management fee  rate 10 basis  points increase 10 basis  points decrease 1% increase/  decrease in  vacancy 1% increase/  decrease in  management fees apartments  $(22,408) $22,947 $21,055 $22,206 mHcs  $(1,659) $1,708 $1,483 $1,932"}]}
+{"image": "doclay/doclay_39082.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Document code:  Security level:  Effective date:  ICT Governance \nPRO-0027.06  Internal  15/01/2019 Term or abbreviation  Definition  Technical Service  Description  Part of the Service Definition Package. Provides a  description of how the service implementation  (organisation, resourcing, workflows as relevant, …). Withdrawn Services  Contains the decommissioned / retired services. \nRecord name  Security level  Comments  IT Master Plan  Internal  IT Enterprise Architecture  Internal  IT DPB Meeting Minutes  Internal  Service Steering Committee Meeting  Minutes  Internal  IT Service Portfolio  Internal  IT Service Catalogue  Internal  Withdrawn IT Services  Internal  IT Service Pipeline  Internal  Service Cards  Internal  Service Technical Descriptions  Internal  Service Requirements  Internal  Service Request records  Internal  Incident records  Internal  Investment Visions  Internal  Programme Plans  Internal  Programme Board Meeting Minutes  Internal  High-Level Maintenance Plans  Internal  Project Initiation Documents  Internal  Project Closure Documents  Internal  Project Board Meeting Minutes  Internal  CAB records, including RFCs, CIAs  and SCPs  Internal  iCAB records  Internal  Category C Incident Reports  Internal \n7. Annexes \nTEM-0129.01  Uncontrolled copy once printed. Ensure that the right version is in use. \nPage  92  of  92\n6. Records \nN/A "}]}
+{"image": "doclay/doclay_62710.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "449 \nUS 9,323,150 B2 \n450 \nTABLE 4-continued \nResist com12osition  Evaluation result  Surfac- Solvent  Photoacid  Basic  tant  Sensi- Resin (Aa) Resin (Ab)  (mass  generator  compound  (0.01  tivity  Pattern  LER  (5 mass%) (58 mass%)  ratio)  (35 mass%)  (2 mass%) mass%)  (mJ/cm) 2  shape  (nm)  Ex.58  Aa-32  Ab-120  S-1/S-3  Y-5  N-8  W-3  11  Rectangle  3.6  (70/30)  Ex.59  Aa-37  Ab-14  S-1/S-2  B-119  N-10  W-4  11  Rectangle  3.5  (80/20)  * $^{1}$Ex. 60  Aa-37  Ab-14  S-1/S-2  B-119  N-10  W-4  14  Rectangle  4.1  (80/20)  * $^{2}$Ex. 61  Aa-37  Ab-14  S-1/S-2  B-119  N-10  W-4  18  Rectangle  4.6  (80/20)  * $^{5}$Ex. 62  Aa-40  Ab-232  S-2/S-4  N-4  W-2  17  Rectangle  4.5  (70/30)  * $^{5}$Ex. 63  Aa-40  Ab-233  S-2/S-4  N-4  W-2  13  Rectangle  4. 1  (70/30)  * $^{5}$Ex. 64  Aa-40  Ab-234  S-2/S-4  N-4  W-2  10  Rectangle  3.5  (70/30)  * $^{5}$Ex. 65  Aa-5  Ab-245  S-2/S-1  N-7  W-1  21  Rectangle  5.0  (90/10)  * $^{5}$Ex. 66  Aa-12  Ab-245  S-2/S-1  N-7  W-1  19  Rectangle  4.7  (90/10)  * $^{5}$Ex. 67  Aa-22  Ab-245  S-2/S-1  N-7  W-1  13  Rectangle  3.9  (90/10)  Ex. 68  Aa-20  Ab-143  S-4/S-1  B-118  N-9  W-3  26  Rectangle  5.7  (90/10)  Ex. 69  Aa-26  Ab-143  S-4/S-1  B-118  N-9  W-3  24  Rectangle  5.5  (90/10)  Ex. 70  Aa-38  Ab-73  S-1  B-131  N-3  W-1  17  Rectangle  4.5  Ex. 71  Aa-38  Ab-41  S-1  B-131  N-3  W-1  12  Rectangle  3.7  Ex. 72  Aa-15  Ab-37  S-3/S-2  Y-70  N-10  W-2  22  Rectangle  5.3  (90/10)  Ex. 73  Aa-15  Ab-21  S-3/S-2  Y-70  N-10  W-2  19  Rectangle  4.8  (90/10)  Ex. 74  Aa-13  Ab-97  S-1/S-2  B-149  N-5  W-4  18  Rectangle  4.6  (90/10)  Ex. 75  Aa-39  Ab-97  S-1/S-2  B-149  N-5  W-4  16  Rectangle  4.3  (90/10)  Ex. 76  Aa-28  Ab-97  S-1/S-2  B-149  N-5  W-4  13  Rectangle  3.9  (90/10)  Ex. 77  Aa-42  Ab-96  S-1/S-2  B-45  N-8  W-4  11  Rectangle  3.6  (50/50)  Ex. 78  Aa-44  Ab-167  S-1/S-4  Y-61  N-10  W-3  25  Rectangle  5.6  (80/20)  * $^{5}$Ex. 79  Aa-46  Ab-253  S-2/S-4  N-7  W-4  23  Rectangle  5.4  (90/10)  * $^{5}$Ex. 80  Aa-47  Ab-238  S-3/S-4  N-3  W-3  20  Rectangle  4.9  (80/20)  Ex. 81  Aa-65  Ab-120  S-1/S-3  Y-5  N-8  W-3  10  Rectangle  3.4  (70/30)  Ex. 82  Aa-66  Ab-120  S-1/S-3  Y-5  N-8  W-3  10  Rectangle  3.1  (70/30)  * $^{1}$Ex. 83  Aa-50  Ab-275  S-1/S-2  B-182  N-10  W-3  13  Rectangle  3.5  (80/20)  * $^{1}$Ex. 84  Aa-51  Ab-276  S-1/S-2  B-182  N-9  W-1  12  Rectangle  4.0  (70/30)  Ex. 85  Aa-52  Ab-276  S-1/S-2  B-181  N-7  W-2  16  Rectangle  3.8  (60/40)  Ex. 86  Aa-53  Ab-270  S-1/S-2  B-121  N-8  W-2  15  Rectangle  3.6  (90/10)  Ex. 87  Aa-54  Ab-273  S-1/S-2  B-179  N-4  W-4  14  Rectangle  4.1  (70/30)  Ex. 88  Aa-60  Ab-277  S-1/S-2  B-180  N-3  W-2  17  Rectangle  4.2  (50/50)  * $^{1}$Ex. 89  Aa-62  Ab-275  S-1/S-2  B-124  N-5  W-3  12  Rectangle  3.6  (80/20)  * $^{1}$Ex. 90  Aa-63  Ab-274  S-1/S-2  B-183  N-10  W-1  13  Rectangle  3.9  (90/10)  * $^{1}$Ex. 91  Aa-67  Ab-280  S-1/S-2  B-122  N-8  W-1  15  Rectangle  3.3  (70/30)  * $^{1}$Ex. 92  Aa-68  Ab-275  S-1/S-2  B-182  N-10  W-4  16  Rectangle  3.8  (80/20)  * $^{1}$Ex. 93  Aa-69  Ab-282  S-1/S-2  B-119  N-3  W-4  15  Rectangle  3.5  (60/40)  Ex.94  Aa-70  Ab-281  S-1/S-2  B-121  N-10  W-3  13  Rectangle  3.2  (80/20) "}]}
+{"image": "doclay/doclay_61042.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "200510079024. 1\nWTS PAY 12/98 a\n167\ni $F G8 9° \" HEUTE ENTER FALSCHE G fl m"}]}
+{"image": "doclay/doclay_41919.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "2 MIN TURN DC ELEC L R TURN COORDINATOR 2 MIN. D.C. ELEC. L R NO PITCH INFORMATION 2 MIN TURN DC ELEC L R TURN COORDINATOR 2 MIN. D.C. ELEC. L R NO PITCH INFORMATION 2 MIN TURN DC ELEC L R TURN COORDINATOR 2 MIN. D.C. ELEC. L R NO PITCH INFORMATION Skidding Turn Skidding Turn Slipping Turn Slipping Turn Coordinated Turn rudder into turn Coordinated Turn Note the slight differences in rudder placement.\nFigure 4-16.  Adverse yaw.\ncentrifugal force over the horizontal lift component, pulling  the aircraft toward the outside of the turn. The rate of turn  is too great for the angle of bank, so the horizontal lift  component is less than the centrifugal force.\nAn inclinometer, located in the turn coordinator, or turn and  bank indicator indicates the quality of the turn, and should  be centered when the wings are banked. If the ball is off of  center on the side toward the turn, the aircraft is slipping and  rudder pressure should be added on that side to increase the  rate of turn or the bank angle should be reduced. If the ball  is off of center on the side away from the turn, the aircraft  is skidding and rudder pressure toward the turn should be  relaxed or the bank angle should be increased. If the aircraft  is properly rigged, the ball should be in the center when the  wings are level; use rudder and/or aileron trim if available.\nThe increase in induced drag (caused by the increase in  AOA necessary to maintain altitude) results in a minor loss  of airspeed if the power setting is not changed.\nAny force applied to an aircraft to deflect its flight from a  straight line produces a stress on its structure; the amount of  this force is termed load factor. A load factor is the ratio of  the aerodynamic force on the aircraft to the gross weight of  the aircraft (e.g., lift/weight). For example, a load factor of 3  means the total load on an aircraft’s structure is three times  its gross weight. When designing an aircraft, it is necessary  to determine the highest load factors that can be expected in  normal operation under various operational situations. These  “highest” load factors are called “limit load factors.”\nAircraft are placed in various categories (i.e., normal, utility,  and acrobatic) depending upon the load factors they are  designed to take. For reasons of safety, the aircraft must be  designed to withstand certain maximum load factors without  any structural damage.\nLoad Factor\n4-12"}]}
+{"image": "doclay/doclay_73385.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Table of Contents\nAVNET, INC. AND SUBSIDIARIES\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS — (Continued)\nThe following is a summary of the changes in outstanding options for fiscal 2019:\n(1) The above table excludes the Performance Based Stock Options (“PBSOs”). Since the performance metrics for the PBSOs were not achieved by the end of calendar year 2018, as stated in the PBSO Terms and Conditions, although the shares have not yet been canceled, the Company has excluded from the outstanding stock options above.\nThe weighted-average grant-date fair values of stock options granted during fiscal 2019, 2018 and 2017 were $10.74, $8.33 and $9.46, respectively.\nAt June 29, 2019, the aggregate intrinsic value of all outstanding stock option awards was $6.6 million and all exercisable stock option awards was $4.4 million. \nThe following is a summary of the changes in non-vested stock options for the fiscal year 2019:\nWeighted Weighted Average Average Remaining  Shares Exercise Price Contractual Life Outstanding at June 30, 2018 2,321,787 $ 40.93 79 Months Granted 301,148 48.50 110 Months Exercised (559,796) 36.14 49 Months Forfeited or expired  (826,500)  46.98 91 Months Outstanding at June 29, 2019  1,236,639 $ 40.90 78 Months Exercisable at June 29, 2019 545,166 $ 37.41 60 Months (1) (1)\nWeighted Average Grant-Date Shares Fair Value Non-vested stock options at June 30, 2018 1,455,234 $ 11.05 Granted 301,148 10.74 Vested (238,409) 10.23 Forfeited  (826,500)  12.05 Non-vested stock options at June 29, 2019 691,473 $ 10.00 (1)\n(1) Included in forfeitures above are the PBSOs, as noted above in the changes in outstanding stock options table\nAs of June 29, 2019, there was $3.2 million of total unrecognized compensation cost related to stock options, which is expected to be recognized over a weighted-average period of 2.3 years. The total fair value of stock options vested, as of the vesting dates, during fiscal 2019, 2018 and 2017 were $5.7 million, $3.6 million and $3.3 million, respectively.\nCash received from stock option exercises during fiscal 2019, 2018, and 2017 totaled $20.2 million, $9.2 million, and $25.2 million, respectively. The impact of these cash receipts is included in “Other, net” within financing activities in the accompanying consolidated statements of cash flows.\n72"}]}
+{"image": "doclay/doclay_56523.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "H\nHANDLER, 2626 Handlers, 2807 Handler_commit status variable, 954 Handler_delete status variable, 954 Handler_discover status variable, 4197 Handler_external_lock status variable, 954 Handler_mrr_init status variable, 954 Handler_prepare status variable, 955 Handler_read_first status variable, 955 Handler_read_key status variable, 955 Handler_read_last status variable, 955 Handler_read_next status variable, 955 Handler_read_prev status variable, 955 Handler_read_rnd status variable, 955 Handler_read_rnd_next status variable, 955 Handler_rollback status variable, 955 Handler_savepoint status variable, 955 Handler_savepoint_rollback status variable, 955 Handler_update status variable, 955 Handler_write status variable, 956 hash index, 6155 hash indexes, 1722 hash join new features, 31 hash partitioning, 4675 hash partitions managing, 4693 splitting and merging, 4693 HashiCorp Vault configuring, 1422 HashiCorp Vault certificate and key files configuring, 1419 have_compress system variable, 804 have_crypt removed features, 45 HAVE_CRYPT removed features, 45 have_dynamic_loading system variable, 804 have_geometry system variable, 804 have_openssl system variable, 804 have_profiling system variable, 804 HAVE_PSI_MEMORY_INTERFACE option CMake, 233 have_query_cache system variable, 805 have_rtree_keys system variable, 805 have_ssl system variable, 805 have_statement_timeout system variable, 805 have_symlink system variable, 806 HAVING clause, 2664 HDD, 6155 header file keyword_list.h, 4801\n5395"}]}
+{"image": "doclay/doclay_39143.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "CLARIFICATION No: 2\nublication Ref: NEAR/ANK/2020/EA-OP/0056 \nSubject: Supply of Equipment for Final Stop Before Climbing the Ladder: Mantar Cultivation and Technology Commercialization  Center\nSayfa  11  /  21\nCenter - Is balanced to G2.5 at 25000 rpm or U ”  In conjunction with our request related with item 1.2.24, we kindly request you to  allow us to offer HSK63 tool holders while other parameters remain unaffected. Q34  Item 1.3 DMLS MACHINE Powder bed fusion (PBF) is one of Additive Manufacturing techniques, in which  either laser, heat or electron beam is used to melt and fuse the material together to  form a three-dimensional object. The Laser Fused technique can be subdivided into  Selective Laser Sintering (SLS) where only plastic parts can be printed and Direct  Metal Laser Sintering (DMLS) or it is sometimes called Selective Laser Melting  (SLM) where, as the name suggests print metal. The DMLS and SLM processes are  functionally the same used the same Additive Manufacturing Technique PBF.  Powdered metals are used, lasers fuse the metal particles, and all their other internal  processes follow the same script. Observe the part under an SEM you can see both  the parts will have same surface characteristics. The difference between both  processes is in the names DMLS and SLM, where the DMLS is patented name for  EOS GmbH Company. It means that stated requirements can be fully matched by only one 3D printing  machine manufacturer – EOS GmbH. This  leads to limited competition, because  other 3D metal printing machine manufacturers can’t have the same name of  manufacturing machines, as patented DMLS ones. In order to make the  competition fair and meet the needs of the beneficiary, could you please amend the  technical specification parameter as follows: “Metal 3D printer” Please refer to Changes to Tender Dossier No. 2.  Q35  Item 1.3.3.  specification required; “ The build chamber shall be at least 200mm  in radius by 200mm in height ”.  Could you please specify may it mistake occurred the specified requirement and the  build chamber size shall be diameter 200 mm x 200 mm height?  Please refer to Changes to Tender Dossier No. 2. "}]}
+{"image": "doclay/doclay_50519.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "The INFORMATION_SCHEMA PARTITIONS Table\nFor  NDB  tables, you can also obtain this information using the  ndb_desc  utility.\nThe length of the index file for this partition or subpartition, in bytes.\nFor partitions of  NDB  tables, whether the tables use implicit or explicit partitioning, the  INDEX_LENGTH column value is always 0. However, you can obtain equivalent information using the  ndb_desc  utility.\nThe number of bytes allocated to the partition or subpartition but not used.\nFor  NDB  tables, you can also obtain this information using the  ndb_desc  utility.\nThe time that the partition or subpartition was created.\nThe time that the partition or subpartition was last modified.\nThe last time that the table to which this partition or subpartition belongs was checked.\nFor partitioned  InnoDB  tables, the value is always  NULL .\nThe checksum value, if any; otherwise  NULL .\nThe text of the comment, if the partition has one. If not, this value is empty.\nThe maximum length for a partition comment is defined as 1024 characters, and the display width of the PARTITION_COMMENT  column is also 1024, characters to match this limit.\nThis is the nodegroup to which the partition belongs. This is relevant only to NDB Cluster tables; otherwise, the value is always  0 .\nThe name of the tablespace to which the partition belongs. The value is always  DEFAULT , unless the table uses the  NDB  storage engine (see the  Notes  at the end of this section).\n• INDEX_LENGTH\n• DATA_FREE\n• CREATE_TIME\n• UPDATE_TIME\n• CHECK_TIME\n• CHECKSUM\n• PARTITION_COMMENT\n• NODEGROUP\n• TABLESPACE_NAME\nNotes\n• PARTITIONS  is a nonstandard  INFORMATION_SCHEMA  table.\n•A table using any storage engine other than  NDB  and which is not partitioned has one row in the  PARTITIONS  table. However, the values of the  PARTITION_NAME ,  SUBPARTITION_NAME , PARTITION_ORDINAL_POSITION ,  SUBPARTITION_ORDINAL_POSITION ,  PARTITION_METHOD , SUBPARTITION_METHOD ,  PARTITION_EXPRESSION ,  SUBPARTITION_EXPRESSION , and\n4807"}]}
+{"image": "doclay/doclay_78630.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "CHAPTER 12. PERLSTYLE\n12.1. DESCRIPTION\n• For portability, when using features that may not be implemented on every machine, test the construct in an eval to see if it fails. If you know what version or patchlevel a particular feature was implemented, you can test $] ( $PERL_VERSION in English ) to see if it will be there. The Config module will also let you interrogate values determined by the Configure program when Perl was installed.\n• Choose mnemonic identifiers. If you can’t remember what mnemonic means, you’ve got a problem.\n• While short identifiers like $gotit are probably ok, use underscores to separate words. It is generally easier to read $var_names_like_this than $VarNamesLikeThis, especially for non-native speakers of English. It’s also a simple rule that works consistently with VAR_NAMES_LIKE_THIS.\n• You may find it helpful to use letter case to indicate the scope or nature of a variable. For example:\n• If you have a really hairy regular expression, use the /x modifier and put in some whitespace to make it look a little less like line noise. Don’t use slash as a delimiter when your regexp has slashes or backslashes.\n• Use the new \"and\" and \"or\" operators to avoid having to parenthesize list operators so much, and to reduce the incidence of punctuation operators like && and || . Call your subroutines as if they were functions or list operators to avoid excessive ampersands and parentheses.\n• Use here documents instead of repeated print() statements.\n• Line up corresponding things vertically, especially if it’d be too long to fit on one line anyway.\n• Always check the return codes of system calls. Good error messages should go to STDERR, include which program caused the problem, what the failed system call and arguments were, and (VERY IMPORTANT) should contain the standard system error message for what went wrong. Here’s a simple but su ffi cient example:\n• Line up your transliterations when it makes sense:\n159\ntr [abc] [xyz];\nopendir(D, $dir) or die \"can’t opendir $dir: $!\";\nFunction and method names seem to work best as all lowercase. E.g., $obj- > as_string().\nYou can use a leading underscore to indicate that a variable or function should not be used outside the package that defined it.\nPackage names are sometimes an exception to this rule. Perl informally reserves lowercase module names for \"pragma\" modules like integer and strict . Other modules should begin with a capital letter and use mixed case, but probably without underscores due to limitations in primitive file systems’ representations of module names as files that must fit into a few sparse bytes.\n$ALL_CAPS_HERE constants only (beware clashes with perl vars!) $Some_Caps_Here package-wide global/static $no_caps_here function scope my() or local() variables\n$IDX = $ST_MTIME; $IDX = $ST_ATIME if $opt_u; $IDX = $ST_CTIME if $opt_c; $IDX = $ST_SIZE if $opt_s; mkdir $tmpdir, 0700 or die \"can’t mkdir $tmpdir: $!\"; chdir($tmpdir) or die \"can’t chdir $tmpdir: $!\"; mkdir ’tmp’, 0777 or die \"can’t mkdir $tmpdir/tmp: $!\";"}]}
+{"image": "doclay/doclay_42450.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "more the lead). Generally, the lead is 10 percent of the climb rate. For example, if your climb rate is 500 feet per minute, you should lead the level-off by 50 feet. \nTo begin the level-off, apply forward cyclic to adjust and maintain a level flight attitude, which is slightly nose low. You should maintain climb power until the airspeed approaches the desired cruising airspeed, then lower the collective to obtain cruising power and adjust the throttle to obtain and maintain cruising r.p.m. Throughout the level-off, maintain longitudinal trim and heading with the antitorque pedals.\nGround reference maneuvers are training exercises flown to help you develop a division of attention between the flight path and ground references, while controlling the helicopter and watching for other air- craft in the vicinity. Prior to each maneuver, a clearing turn should be accomplished to ensure the practice area is free of conflicting traffic.\nThe rectangular course is a training maneuver in which the ground track of the helicopter is equidistant from all sides of a selected rectangular area on the ground. While performing the maneuver, the altitude and air- speed should be held constant. The rectangular course helps you to develop a recognition of a drift toward or away from a line parallel to the intended ground track. This is helpful in recognizing drift toward or from an airport runway during the various legs of the airport traffic pattern.\nA normal descent is a maneuver in which the helicop- ter loses altitude at a controlled rate in a controlled attitude.\nTo establish a normal descent from straight-and-level flight at cruising airspeed, lower the collective to obtain proper power, adjust the throttle to maintain r.p.m., and increase right antitorque pedal pressure to maintain heading in a counterclockwise rotor system, or left pedal pressure in a clockwise system. If cruising  airspeed is the same as, or slightly above descending air- speed, simultaneously apply the necessary cyclic  pressure to obtain the approximate descending attitude. If cruising speed is well above descending airspeed, you can maintain a level flight attitude until the airspeed approaches the descending airspeed, then lower the nose to the descending attitude. Throughout the maneu- ver, maintain descending attitude and airspeed with the cyclic; descending power and r.p.m. with the collective and throttle; and heading with the antitorque pedals.\nFor this maneuver, pick a square or rectangular field, or an area bounded on four sides by section lines or roads, where the sides are approximately a mile in length. The area selected should be well away from other air traffic. Fly the maneuver approximately 600 to 1,000 feet above the ground, which is the altitude usually required for an airport traffic pattern. You should fly the helicopter parallel to and at a uniform distance, about one-fourth to one-half mile, from the field boundaries, not above the boundaries. For best results, position your flight path outside the field boundaries just far enough away that they may be easily observed from either pilot seat by looking out the side of the helicopter. If an attempt is made to fly directly above the edges of the field, you will have no usable reference points to start and complete the turns. In addition, the closer the track of the helicop- ter is to the field boundaries, the steeper the bank necessary at the turning points. Also, you should be able to see the edges of the selected field while seated in a normal position and looking out the side of the helicopter during either a left-hand or right-hand course. The distance of the ground track from the edges of the field should be the same regardless of whether the course is flown to the left or right. All turns should be started when your helicopter is abeam the corners of the field boundaries. The bank nor- mally should not exceed 30°.\nTo level off from the descent, lead the desired altitude by approximately 10 percent of the rate of descent. For exam- ple, a 500 feet per minute rate of descent would require a 50 foot lead. At this point, increase the collective to obtain cruising power, adjust the throttle to maintain r.p.m., and increase left antitorque pedal pressure to maintain heading (right pedal pressure in a clockwise rotor system). Adjust the cyclic to obtain cruising airspeed and a level flight atti- tude as the desired altitude is reached.\nAlthough the rectangular course may be entered from any direction, this discussion assumes entry on a \n9-14\n1. Failure to maintain constant angle of decent dur- ing training.\nCOMMON ERRORS\nTECHNIQUE\nNORMAL DESCENT\nRECTANGULAR COURSE\nCOMMON ERRORS\nGROUND REFERENCE MANEUVERS\n2. Failure to lead the level-off sufficiently, which results in recovery below the desired altitude.\n3. Failure to adjust antitorque pedal pressures for changes in power.\n1. Failure to maintain proper power and airspeed.\n2. Holding too much or too little antitorque pedal.\n3. In the level-off, decreasing power before lower- ing the nose to cruising attitude."}]}
+{"image": "doclay/doclay_74658.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "NOTES TO AND FORMING PART OF THE FINANCIAL STATEMENTS\nFor the year ended 30 June 2002 Stockland Trust Group comprising Stockland Trust and Stockland Corporation Limited\n27 Distributions/dividends\nDistributions/dividends recognised in the current year by the Trust and Corporation are:\nThe above available amounts are based on the balance of the dividend franking account at year end  adjusted for:\n(a) franking credits that will arise from the payment of the amount of the provision for income tax;\n(b) franking debits that will arise from the payment of dividends recognised as a liability at the year end;\n(c) franking credits that will arise from the receipt of dividends recognised as receivables at the year end; and\n(d) franking credits that the entity may be prevented from distributing in subsequent years.\nThe ability to utilise the franking credits is dependent on there being sufficient available profits  to declare dividends.\nFrom 1 July 2002 the New Business Tax System (Imputation) Act 2002 requires measurement of franking credits  based on the amount of income tax paid, rather than on after-tax profits. As a result the “franking credits available” were converted from $40,308,033 to $17,274,871 as at 1 July 2002. This change in the basis of measurement  does not change the value of franking credits to shareholders who may be entitled to franking credit benefits.\n69\n2002 Interim dividend 1.9¢ 15,150 28 Feb 2002 30 100 Final dividend 2.2¢ 18,185 30 Aug 2002 30 100 Total dividends 33,335 Tax deferred 1 % Interim distribution 12.6¢ 100,463 28 Feb 2002 Final distribution 13.0¢ 107,455 31 Aug 2002 Total distribution 207,918 26% Tax rate for Percentage franking credit franked % 2001 Interim dividend 1.8¢ 11,355 28 Feb 2001 34 100 Final dividend 1.8¢ 13,095 31 Aug 2001 30 100 Total dividends 24,450 Tax deferred 1 Tax free 1 % % Interim distribution 12.1¢ 76,327 28 Feb 2001 Final distribution 12.6¢ 91,667 31 Aug 2001 Total distribution 167,994 18.5% 9.7% 24.0 30 27.8 14.6 9.1 21.7 10.3 Cents per Total Date of Tax rate for Percentage unit/share amount payment franking credit franked $’000 %\n1 Due to recent amendments to the income tax legislation, building allowances claimed by Stockland Trust no longer give rise to “tax free” distributions. Accordingly, Due to amendments to the income tax legislation, building allowances claimed by Stockland Trust ceased to give rise to “tax free” distributions from 1 July 2001.\nthe entire amount of the distribution not considered to be taxable is categorised as “tax deferred”. The entire amount of the 2002 distribution not considered to be taxable is categorised as “tax deferred”.\nNo unfranked dividends have been declared or paid during the year.\nDividend franking account 30% franking credits available to shareholders  of the Corporation for subsequent financial years 40,308 30,979 Corporation 2002 2001 $’000 $’000"}]}
+{"image": "doclay/doclay_3403.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "follows as of the date specified in the corresponding item: \n(i) the provisions revising row 27 of Appended Table 2: April 1, 1995; \n(ii) the provisions revising row 21-2 of Appended Table 2: April 4, 1995; \n(iv) the provisions revising row 35 of Appended Table 2: June 14, 1995. \n(iii) the provisions revising Article 2, paragraph (1), item (iii), row 24 of  Appended Table 2, and row 4 of Appended Table 7: May 1, 1995; \n(2) With regard to the application of penal provision to acts committed prior to  the enforcement of the provisions listed in item (i) or item (iii) of the preceding  paragraph, the provisions then in force remain applicable. \nArticle 1 This Cabinet Order comes into effect as of the date of enforcement of  the Act for Partial Revision of the Act on Conservation of Endangered Species  of Wild Fauna and Flora (June 28, 1995). \n(1) This Cabinet Order comes into effect as of August 23, 1995. \n(2) With regard to the application of penal provision to acts committed prior to  the enforcement of this Cabinet Order, the provisions then in force remain  applicable. \n(1) This Cabinet Order comes into effect as of October 1, 1996; provided, however,  that the provisions listed as follows come into effect as of the date specified in  the corresponding item: \n(ii) the part of the provisions of Article 2 that revises row 2 of Appended Table  1 of the Export Trade Control Order (limited to the part related to (xv) of the  same row), and the provisions revising row 3-2 and row 6 of the same table:  January 3, 1996. \n(2) With regard to a service transaction conducted, as permitted, by a person who  has obtained, prior to the enforcement of this Cabinet Order, permission under  Article 17-2, paragraph (1) of the Foreign Exchange Control Order prior to the \n30 \nSupplementary Provisions [Cabinet Order No. 420 of December 20, 1995] [Extract] \nSupplementary Provisions [Cabinet Order No. 311 of August 9, 1995] \nSupplementary Provisions [Cabinet Order No. 240 of June 14, 1995] [Extract] \n(Effective Date) \n(Effective Date) \n(Transitional Measures) "}]}
+{"image": "doclay/doclay_49034.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "類\n（法人が事業活動を支配する法人等）\n（参加法人の構成）\n（社員総会の決議に不当な影響を及ぼすおそれがある者）\n（地域医療連携推進法人の役員と特殊の関係がある者）\n126 \n三 前二号に掲げる者の親族でこれらの者と生計を一にしているもの\n二 役員の使用人及び使用人以外の者で当該役員から受ける金銭その他の財産によつ て生計を維持しているもの\n一 役員と婚姻の届出をしていないが事実上婚姻関係と同様の事情にある者\n第三十九条の九 法第七十条の三第一項第十三号ロに規定する役員と厚生労働省令で定 める特殊の関係がある者は、次���掲げる者とする。\n五 前各号に掲げる者に類するもの\n四 当該一般社団法人の参加法人と利害関係を有する営利事業を営む個人\n三 当該一般社団法人の参加法人と利害関係を有する営利を目的とする団体の役員又 は職員\n二 当該一般社団法人と利害関係を有する営利事業を営む個人又は当該個人の配偶者 若しくは三親等以内の親族\n一 当該一般社団法人と利害関係を有する営利を目的とする団体の役員又は職員若し くは当該役員の配偶者若しくは三親等以内の親族\n第三十九条の八 法第七十条の三第一項第十二号に規定する厚生労働省令で定める者は、 次に掲げる者とする。\n二 病院等を開設する参加法人の有する議決権の合計が、介護事業等に係る施設又は 事業所を開設し、又は管理する参加法人の有する議決権の合計を超えるものである こと。\n一 病院等を開設する参加法人の数が二以上であるものであること。\n第三十九条の七 法第七十条の三第一項第八号に規定する厚生労働省令で定める要件は、 次の各号のいずれにも該当するものであることとする。\n３ 前二項に規定する財務及び営業又は事業の方針の決定を支配している場合とは、一 の者又はその一若しくは二以上の子法人が社員総会その他の団体の財務及び営業又は 事業の方針を決定する機関における議決権の過半数を有する場合をいう。\n２ 令第五条の十五の二第六号に規定する法人の事業活動を支配する者として厚生労働 省令で定めるものは、一の者が当該法人の財務及び営業又は事業の方針の決定を支配 している場合における当該一の者とする。\n第三十九条の六 令第五条の十五の二第六号に規定する法人が事業活動を支配する法人 として厚生労働省令で定めるものは、同条第二号に掲げる者であつて法人であるもの が他の法人の財務及び営業又は事業の方針の決定を支配している場合における当該他 の法人（第三項において「子法人」という。）とする。"}]}
+{"image": "doclay/doclay_28516.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "rates of all processes are equal, gives\nwhere x ∗ is the equilibrium value of x , etc. Given a value for the concentration in the bulk solution, these relations determine the equilibrium values of all of the other quantities as well as imposing the consistency relation\nSupersaturation at the surface is defined as log ( x/x ∗ ). To illustrate the general behavior of this model, we have solved for the time-dependence of the various quantities for the case that a = a ′ = 0 . 04 k$_{0}$ , k$_{1}$ = 0 . 02 k$_{0}$ , k ′ 1 = k ′ 2 = 0 . 004 k$_{0}$ , k ′ 0 = 0 . 5 k$_{0}$ , k$_{2}$ = 0 . 01 k$_{0}$ , N = 2 with initial conditions x$_{0}$ (0) = 1, and x (0) = y (0) = c (0) = 0. Here the original time t is normalized to k$_{0}$t . The value of k ′ 0 reflects the idea that once adsorbed, a molecule spends on average a long time on the surface before being desorbed back to the bulk. The choice k$_{2}$ < k$_{1}$ amounts to assuming that the activation barrier for aggregation alone is larger than that for adsorption and aggregation. Aside from these assumptions and the physical requirements that the rates at which molecules join a cluster, k$_{1}$ and k$_{2}$ , are greater than the rates for the reverse processes and the detailed balance condition, Eq.8, these values are somewhat flexible. Given an initially flat surface, c$_{N}$ (0) = 0, islands will form causing the mass of the surface to increase until, at long times, equilibrium is reached. At intermediate times, a more-or-less steady growth regime is reached, see Fig. 1, corresponding to a plateau in the growth velocity, dc$_{N}$ dt , which defines a quasi-steady state growth velocity as shown in Fig. 2. Taking the maximum growth velocity as a measure of the typical velocity at intermediate times, one again finds a crossover between small x and large x regimes as illustrated in Figure 3.\n7\nax$_{0}$ = a $^{′}$x∗ (7) k$_{0}$x ∗ = k ′ $_{0}$y ∗ k ′ $_{1}$c ∗ N = k$_{1}$x $^{∗}$y ∗ N − 1 k$_{2}$y ∗ N = k ′ $_{2}$c ∗ N\nk ′ $_{0}$k$_{1}$ k ′ 2 = k$_{0}$k ′ $_{1}$k$_{2}$ . (8)"}]}
+{"image": "doclay/doclay_11260.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Loans\nTable 12 Loans\nTable 13 Loan Maturity and Interest Rate Sensitivity at December 31, 2001 (in Thousands)\nResidential mortgage loans included $296 million of home equity loans, $253 million of mortgage loans held for business relationship purposes, and $154 million of adjustable rate mortgage loans. Consumer loans included $177 million of indirect automobile loans at December 31, 2001, an increase of $62 million since the previous year-end. Substantially all of these loans were purchased from dealers in Oklahoma. Approximately 26% :of the indirect automobile loan portfolio were considered sub-prime.\napproximately 25% of these loans. Commercial real estate loans totaled $1.3 billion or 21% of the loan portfolio at December 31, 2001. This represented a 6% increase from the previous year-end. Construction and land development loans included $265 million for single- family residential lots and premises. The major components of other commercial real estate loans were office buildings — $256 million and retail facilities - $220 million.\nBOK Financial participates in shared national credits when appropriate to obtain or maintain business relationships with local customers. At December 31, 2001, the outstanding principal balance of these loans totaled $659 million, including $637 million to borrowers with local market relationships. BOK Financial is the agent lender in approximately 25% of these loans. Commercial real estate loans totaled $1.3 billion or 21%\nOutstanding Joans to energy customers totaled $988 million or 16% of total loans at December 31, 2001. This represents an increase of 18% over last year. Small- and medium-size customers in the Houston, Texas; Denver, Colorado and West Texas markets were the primary source of this loan growth. Approximately $768 million of the energy loan portfolio was to oil and gas producers. The amount of credit available to these customers generally depends on the value of their proven energy reserves based on current prices. The energy category also included loans to borrowers involved in the transportation and sale of oil and gas and loans to borrowers that manufacture equipment and provide other services to the energy industry. Outstanding loans to the services industry totaled $1.1 billion, an increase of 13%. Services included loans that totaled $162 million to nursing homes, $115 million to the healthcare industry and $69 million to the hotel industry. Loans to the wholesale/retai] industry increased 20% to $600 million. Approximately $40 million of this increase resulted from increased efforts in New Mexico. Agriculture included $150 million of loans to the cattle industry. Other notable loan concentrations by the primary industry of the borrowers are presented in Table 12.\n(in Thousands) Remaining Maturities of Selected Loans Total Within | Year 1-5 Years — After 5 Years Loan maturity: Commercial $3.674,750 $1,371,647 © $1,775,114 $527,989 Commercial real estate 1,341.775 553,363 622,007 166,405 Total $5,016,525 $1,925.010 $2,397,121 $694,394 Interest rate sensitivity for selected loans with: Predetermined interest rates $1,174,615 190.371 ~$ 687,061 $297,183 Floating or adjustable interest rates 3,841,910 1,734,639 1,710,060 397,211 Total $5,016,525 $1,925,010 . $2,397,121 $694,394\nTable 13 Loan Maturity and Interest Rate Sensitivity at December 31, 2001 (in Thousands)\n(in Thousands) December 31, 2001 2000 1999 1998 1997 Commercial: Energy $ 987,556 $ 837,223 - $ 606.561. $ 468,700 © $ 333,988 Manufacturing 467,260 .. 421.046 344,175 245,268 205,836 Wholesale/retail 600,470 499,017 407,785 279,265 264,029 Agriculture 170,861 185,407 173,653 160,241 155,868 Services 1,084,480 963,17] 807,184 635,585 482,476 Other commercial and industrial 364,123 342,169 325,343 200,214 107,260 Commercial real estate: Construction and land development 327,455 311.700 249,160 174,059 104,322 Multifamily 291,687 271,459 257,187 181,525 103,218 Other real estate loans 722,633 687,335 588.195 404,985 284,220 Residential mortgage: Secured by 1-4 family residential properties 703,080 638,044 531,058 500,690 435,753 Residential mortgages held for sale 166,093 48.901 57.057 100,269 79,779 Consumer 409,680 312.390 296,131 296,298 299,272 Total $6,295,378 $5,517,862 $4.643,489 $3,647,099 $2,856,021\n(in Thousands)\nloans increased $427 million during the year. This increase was primarily in the energy, services and wholesale/retail sectors of the loan portfolio. Additionally,-the consumer loan portfolio increased $97 million since December 31, 2000.\nThe aggregate loan portfolio at December 31, 2001 totaled $6.3 billion, an increase of $778 million since December 31, 2000. Growth in the loan portfolio included $184 million from the CNBT acquisition and $117 million of residential mortgage loans held for sale. Excluding these items, total loans increased 9% during 2001: Commercial"}]}
+{"image": "doclay/doclay_15746.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "\n* For more information see our board of directors on page 18.\nPersonal details Role at Sasol Expertise and experience Pat Davies* BSc Eng (Mech) 1995: Appointed to GEC Chief executive and executive director. Director of several Sasol companies. 1975: Joined Sasol Has been responsible for various portfolios, including  the internationalisation of Sasol’s GTL technology,  and the group’s oil and gas businesses, as well as  Sasol Synfuels, Sasol Petroleum International, Sasol  Synfuels International and Sasol Technology. Christine Ramon* CA(SA) 2006: Appointed to GEC  Chief fi nancial officer and executive director.  Director of several Sasol companies. 2006: Joined Sasol Past CEO and financial director of Johnnic Holdings  and past director of Johnnic Communications Limited. Nolitha Fakude* BA (Hons) 2005: Appointed to GEC Executive director responsible for sustainability  and transformation; group human resources; corporate  and government affairs.  Chairman of Sasol Mining Holdings and director  of several other Sasol companies. 2005: Joined Sasol Past member of group executive committee of  Nedbank Limited, responsible for group strategy,  marketing, corporate affairs and transformation. Bram de Klerk BSc Eng (Mech), MBA 2003: Appointed to GEC Group executive, Sasol Group Services, responsible  for Sasol’s Operations Excellence, Project Mafutha  and safety, health and environment. Director of several Sasol companies. 1973: Joined Sasol Past managing director of Natref and Sasol Synfuels  and previously responsible for Sasol Technology. André de Ruyter MBA, LLB, BLC, BA 2009: Appointed to GEC Senior group executive, operations, responsible for  Sasol Oil, Sasol Gas, Sasol Synfuels, Sasol Polymers,  Sasol Solvents, Sasol Olefins & Surfactants, Sasol Nitro,  Sasol Wax and Sasol Infrachem. 1993: Joined Sasol Held various management positions, including  manager group strategy; head of China CTL project  in Beijing and managing director of Sasol Olefi ns &  Surfactants in Germany.  Nereus Joubert B Iuris, LLB, LLD, AMP 1996: Appointed to GEC Group executive and company secretary, responsible  for group company secretarial, legal, intellectual  property, insurance, risk management and  internal audit. 1994: Joined Sasol Former professor of law and vice dean of the  faculty of law at Rand Afrikaans University (now  UJ). Alexander von Humboldt Scholar. Attended  Advanced Management Programme at Harvard  Business School. Bernard Klingenberg MSc Eng (Mech) 2009: Appointed to GEC  Group executive, responsible for human resources. Director of several Sasol companies. 1986: Joined Sasol Held various management positions, including  managing director of Sasol Polymers, Sasol Nitro,  Sasol Solvents and Sasol Olefins & Surfactants SA.  Riaan Rademan B Eng (Mech), MBL 2009: Appointed to GEC Group executive, responsible for Sasol Shared Services,  supply chain management, information management  and Sasol’s Functional Excellence programme. Director of several Sasol companies. 1981: Joined Sasol Held various management positions, including  managing director of Sasol Mining and of Sasol  Nitro. Attended Advanced Management Programme,  Wharton, University of Pennsylvania. Lean Strauss B Com (Hons), M Com 2005: Appointed to GEC Senior group executive responsible for Sasol’s  international energy cluster, Sasol Technology,  Sasol New Energy and new business development. 1982: Joined Sasol  Held various management positions in Sasol Oil and  Sasol Gas and was managing director of Sasol Nitro.\nannual review 2010  •  our business  •  our group executive committee 21"}]}
+{"image": "doclay/doclay_24301.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "63\nAGL Energy Limited Annual Report 2012\nAs the focus of the Board is the governance of and long-term  strategic direction of AGL, there is no direct link between non- executive Director remuneration and AGL’s short-term results.\nNon-executive Directors may choose to receive fees as a  combination of one or more of:\nNon-executive Directors are permitted to vary the components  of their fee entitlements at any time.\nNo options have been granted to non-executive Directors over  any securities or interests of AGL or the consolidated entity.\nThe Board conducted a review of its own performance, the  performance of individual Directors, and the performance  of the Board Committees during the last year.\nThe fee structure for non-executive Directors, effective 1 January  2012, is as follows:\nThis Directors’ Report is made in accordance with a resolution of  the Board of Directors and is signed for and on behalf of the Board  this 22nd day of August 2012.\n> Directed superannuation contributions.  Subject to minimum  contributions as required under SGC legislation, and maximum  tax deductible contributions under the Income Tax Assessment  Act, non-executive Directors may direct that some or all of their  fees be paid as contributions to a complying superannuation fund  of their choice.\n> AGL shares acquired under the AGL Share Purchase Plan. The Plan Trustee acquires AGL shares on-market at market  price during permitted trading periods. Details of the trading  periods are included in the AGL Securities Dealing Policy which  is available on AGL’s website.\n> Cash.  The balance of fee entitlements is paid in cash to the non- executive Directors in equal monthly amounts over the year.\nFive year financial performance The following table shows AGL’s annual performance over the last  five years.\nFive year financial performance The following table shows AGL’s annual performance over the last \nYear ended 30 June 2008 2009 2010 2011 2012 Statutory Profit ($m) 229.0 1,596.1 356.1 558.7 114.9 Statutory EPS in cents 1 50.9 346.6 76.8 118.5 23.8 Underlying Profit ($m) 341.0 378.8 428.9 431.1 482.0 Underlying EPS in cents 1 75.8 82.3 92.5 91.4 100.0 Dividends in cents 53.0 54.0 59.0 60.0 61.0 Increase/(decrease) in  share price (%) 1 (5.7) (5.9) 9.3 (0.3) 4.2 EBIT/Funds Employed  (%) 10.6 9.7 9.4 8.9 9.2 Adjusted EBIT/Funds  Employed (%) 2 n/a 10.8 11.3 10.5 11.6 TSR(%) 2 & 3 (5.9) 1.9 10.2 1.6 13.9\nApproval of Directors’ Report\nNotes:\n1. Restated for the bonus element of the one-for-six share rights issue completed in  June 2012.\n2. Used since FY2010 to calculate Executives’ long-term incentives. See page 53 for details  for calculation.\n3. Based on June VWAP in each financial year.\nBase Fee  $ Audit and Risk  Management  Committee  Fees  $ Other  Committee  Fees  $ Chairman of Board 440,000 – – Chairman of Committee 166,500 48,000 32,000 Director 166,500 24,000 16,000\nJeremy Maycock  Chairman\n"}]}
+{"image": "doclay/doclay_240.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "25\nManagement’s Discussion and Analysis of Financial Condition and Results of Operations\npreviously laid off or terminated employees, management determined in 2002 that a portion of the remaining accrual was no longer necessary. This resulted in a restructuring credit of $10 million in 2002.\nProperty transactions, net consisted of the following:\nIn 2002, Tropical Storm Isidore caused property damage at Beau Rivage totaling  $8 million, including clean-up costs. The amount of the write-down for damaged assets was determined based on the net book value of the assets and engineering estimates. In connection with the revised development agreement in Detroit, we wrote off $5 million, which was the net book value of previously incurred development costs associated with the riverfront permanent casino site ($9 million), offset by previously accrued obliga- tions no longer required under the revised development agreement ($4 million).\nThe following table summarizes information related to interest on our long-term debt:\nNon-operating Results\nInterest cost was higher in 2004 as we had a higher average borrowing rate due to increases in variable interest rates and the issuance of significant fixed rate debt in the second half of 2004 in anticipation of the Mandalay merger.\nCapitalized interest increased in 2004 due to the ongoing Bellagio expansion and KÀ theatre projects. Capitalized interest in 2005 will include interest capitalized on Project CityCenter. Capitalized interest decreased in 2003 due to the suspension of development in Atlantic City in late 2002 and the mid-2003 cessation of interest cap- italization on the Company’s investment in Borgata, which opened on July 3, 2003.\nIn 2004, there were no material unusual property transactions. In 2003, we sold 315 acres of land in North Las Vegas, Nevada near Shadow Creek for approximately  $55 million, resulting in the $37 million gain reflected above. Prior to 2003, we  classified gains and losses on routine assets sales or disposals as a non-operating item at some resorts and as an operating item at other resorts. We believe the preferable pres- entation of these items is as an element of operating income. Prior period statements have not been reclassified as such transactions were not material in periods prior to 2003. Until 2003, demolition costs were typically capitalized as part of new construc- tion. We began expensing demolition costs on major construction projects as incurred on January 1, 2003, and are accounting for this change in policy prospectively. Demolition costs were not material in periods prior to 2003. Demolition costs in 2004 and 2003 related primarily to preparation for the Bellagio standard room remodel, Bellagio expansion and new theatre at MGM Grand Las Vegas. Impairments of assets to be disposed of in 2003 consisted primarily of assets related to the former EFX! show and restaurants closed during 2003 at MGM Grand Las Vegas.\nNon-operating items from unconsolidated affiliates, primarily our share of Borgata’s interest expense and state income taxes, increased from $10 million in 2003 to \nY ear Ended December 31 (In thousands) 2004 2003 2002 Interest cost . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . $ 401,391 $ 352,820 $ 345,448 Less: Capitalized interest . . . . . . . . . . . . . . . . . . . . . . (23,005) (15,234) (61,712) Interest expense, net . . . . . . . . . . . . . . . . . . . . . . . . . $ 378,386 $ 337,586 $ 283,736 Cash paid for interest, net of amounts capitalized . . . $ 321,008 $ 308,198 $ 266,071 Average total debt balance . . . . . . . . . . . . . . . . . . . . $ 5.5 billion $ 5.2 billion $ 5.2 billion Weighted average interest rate . . . . . . . . . . . . . . . . . 7.2% 6.9% 6.8%\nY ear Ended December 31 (In thousands) 2004 2003 2002 Gain on sale of North Las Vegas land . . . . . . . . . . . $ — $ (36,776) $ — Siegfried & Roy theatre write-down – The Mirage . . . — 1,408 — Storm damage – Beau Rivage . . . . . . . . . . . . . . . . . — — 7,824 Write-off of Detroit development costs . . . . . . . . . . . — — 4,754 Impairment of assets to be disposed of . . . . . . . . . . 473 5,764 2,134 Demolition costs . . . . . . . . . . . . . . . . . . . . . . . . . . . 7,057 6,614 — Other net losses on asset sales or disposals . . . . . . . 1,135 4,049 — $ 8,665 $ (18,941) $ 14,712"}]}
+{"image": "doclay/doclay_59153.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Performance Schema Miscellaneous Tables\nThe  performance_timers  table shows which event timers are available:\nmysql>  SELECT * FROM performance_schema.performance_timers; +-------------+-----------------+------------------+----------------+ | TIMER_NAME | TIMER_FREQUENCY | TIMER_RESOLUTION | TIMER_OVERHEAD | +-------------+-----------------+------------------+----------------+ | CYCLE | 2389029850 | 1 | 72 | | NANOSECOND | 1000000000 | 1 | 112 | | MICROSECOND | 1000000 | 1 | 136 | | MILLISECOND | 1036 | 1 | 168 | +-------------+-----------------+------------------+----------------+\nIf the values associated with a given timer name are  NULL , that timer is not supported on your platform. For an explanation of how event timing occurs, see Section 27.4.1, “Performance Schema Event Timing” .\nThe  performance_timers  table has these columns:\nThe timer name.\nThe number of timer units per second. For a cycle timer, the frequency is generally related to the CPU speed. For example, on a system with a 2.4GHz processor, the  CYCLE  may be close to 2400000000.\nIndicates the number of timer units by which timer values increase. If a timer has a resolution of 10, its value increases by 10 each time.\nThe minimal number of cycles of overhead to obtain one timing with the given timer. The Performance Schema determines this value by invoking the timer 20 times during initialization and picking the smallest value. The total overhead really is twice this amount because the instrumentation invokes the timer at the start and end of each event. The timer code is called only for timed events, so this overhead does not apply for nontimed events.\nThe  performance_timers  table has no indexes.\nTRUNCATE TABLE  is not permitted for the  performance_timers  table.\n• TIMER_NAME\n• TIMER_FREQUENCY\n• TIMER_RESOLUTION\n• TIMER_OVERHEAD\n27.12.21.5 The processlist Table\nThe MySQL process list indicates the operations currently being performed by the set of threads executing within the server. The  processlist  table is one source of process information. For a comparison of this table with other sources, see Sources of Process Information.\nThe  processlist  table can be queried directly. If you have the  PROCESS  privilege, you can see all threads, even those belonging to other users. Otherwise (without the  PROCESS  privilege), nonanonymous users have access to information about their own threads but not threads for other users, and anonymous users have no access to thread information.\nIf the  performance_schema_show_processlist  system variable is enabled, the  processlist  table also serves as the basis for an alternative implementation underlying the  SHOW PROCESSLIST  statement. For details, see later in this section.Note\n5085"}]}
+{"image": "doclay/doclay_54517.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "MongoDB Documentation, Release 3.0.4\nAnother option, again depending on your use case, might be to use separate collections, one for each status.\nConsider an index { a : 1 } (i.e. an index on the key a sorted in ascending order) on a collection where a has three values evenly distributed across the collection:\nExample\n{ _id: ObjectId(), a: 1, b: \"ab\" } { _id: ObjectId(), a: 1, b: \"cd\" } { _id: ObjectId(), a: 1, b: \"ef\" } { _id: ObjectId(), a: 2, b: \"jk\" } { _id: ObjectId(), a: 2, b: \"lm\" } { _id: ObjectId(), a: 2, b: \"no\" } { _id: ObjectId(), a: 3, b: \"pq\" } { _id: ObjectId(), a: 3, b: \"rs\" } { _id: ObjectId(), a: 3, b: \"tv\" }\n{ _id: ObjectId(), a: 1, b: \"ab\" } { _id: ObjectId(), a: 2, b: \"cd\" } { _id: ObjectId(), a: 3, b: \"ef\" } { _id: ObjectId(), a: 4, b: \"jk\" } { _id: ObjectId(), a: 5, b: \"lm\" } { _id: ObjectId(), a: 6, b: \"no\" } { _id: ObjectId(), a: 7, b: \"pq\" } { _id: ObjectId(), a: 8, b: \"rs\" } { _id: ObjectId(), a: 9, b: \"tv\" }\nIf you query for { a: 2, b: \"no\" } MongoDB must scan 3 documents in the collection to return the one matching result. Similarly, a query for { a: { $gt: 1}, b: \"tv\" } must scan 6 documents, also to return one result.\nConsider the same index on a collection where a has nine values evenly distributed across the collection:\nIf you query for { a: 2, b: \"cd\" } , MongoDB must scan only one document to fulfill the query. The index and query are more selective because the values of a are evenly distributed and the query can select a specific document using the index.\nHowever, although the index on a is more selective, a query such as { a: { $gt: 5 }, b: \"tv\" } would still need to scan 4 documents.\nIf overall selectivity is low, and if MongoDB must read a number of documents to return results, then some queries may perform faster without indexes. To determine performance, see Measure Index Use (page 528).\nFor a conceptual introduction to indexes in MongoDB see Index Concepts (page 486).\n551\n8.3. Indexing Tutorials"}]}
+{"image": "doclay/doclay_78731.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "CHAPTER 2. PERLINTRO – A BRIEF INTRODUCTION AND OVERVIEW OF PERL\n2.1. DESCRIPTION\nThis is called an \"array slice\".\nYou can do various useful things to lists:\nmy @sorted = sort @animals; my @backwards = reverse @numbers;\nThere are a couple of special arrays too, such as @ARGV (the command line arguments to your script) and @_ (the arguments passed to a subroutine). These are documented in perlvar .\nmy %fruit_color = (\"apple\", \"red\", \"banana\", \"yellow\");\nA hash represents a set of key / value pairs:\nYou can use whitespace and the = > operator to lay them out more nicely:\nTo get at hash elements:\n$fruit_color{\"apple\"}; # gives \"red\"\nYou can get at lists of keys and values with keys() and values() .\nmy @fruits = keys %fruit_colors; my @colors = values %fruit_colors;\nHashes have no particular internal order, though you can sort the keys and loop through them.\nJust like special scalars and arrays, there are also special hashes. The most well known of these is %ENV which contains environment variables. Read all about it (and other special variables) in perlvar .\nScalars, arrays and hashes are documented more fully in perldata .\nMore complex data types can be constructed using references, which allow you to build lists and hashes within lists and hashes.\nA reference is a scalar value and can refer to any other Perl data type. So by storing a reference as the value of an array or hash element, you can easily create lists and hashes within lists and hashes. The following example shows a 2 level hash of hash structure using anonymous hash references.\nExhaustive information on the topic of references can be found in perlreftut , perllol , perlref and perldsc .\n13\nmy $variables = { scalar => { description => \"single item\", sigil => ’$’, }, array => { description => \"ordered list of items\", sigil => ’@’, }, hash => { description => \"key/value pairs\", sigil => ’%’, }, }; print \"Scalars begin with a $variables->{’scalar’}->{’sigil’}\n\";\nmy %fruit_color = ( apple => \"red\", banana => \"yellow\", );\nHashes"}]}
+{"image": "doclay/doclay_55764.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "\n135"}]}
+{"image": "doclay/doclay_9720.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "DEEPENING OUR RELATIONSHIPS\nOUR  CRM process. This growth links directly to our successful utilization of the CRM product. At December 31, 2002, average deposits per branch were $96.4 million, up from $88.6 million one year previous. Excluding the two de novo branches established during 2002, our average branch size exceeded $100 million at December 31, 2002. Over half of our branches possessed over $90 million in deposits at December 31, 2002. Also, at December 31, 2002, core (non-CD) deposits comprised 57% of total deposits. This percentage is up from 49% at December 31, 2000.\nBoth the six-month and twelve-month periods ended December 31, 2002 saw record levels of loan origination activity. Loan originations totaled $717.0 million during the twelve months ended December 31, 2002, 38% above the levels for the twelve months ended December 31, 2001. With interest rates at historic lows, property owners took advantage of the opportunity to refinance their mortgages. This was certainly true in our niche loan product, multi-family residential buildings.\nWhile origination levels were robust, the current market conditions certainly presented challenges. Average interest rates on new multi-family residential loans have been at historic lows. In addition, loan prepayments have run at historically high levels, putting even more pressure upon the  average yield of our loan portfolio. However, as a committed multi-family lender, we feel it is essential to continue to meet the demands of our loan market, and to seek ways to keep the newly originated loan assets as nimble as possible in the event that interest rates rise.\nIn December 2002, our subsidiary, The Dime Savings Bank of Williamsburgh (“Dime Savings”) entered into a multi-family seller/servicing pact with the Federal National Mortgage Association  (“Fannie Mae”). The agreement envisions that Dime Savings will sell at least $200 million of loans to Fannie Mae over the 18-month period ending in May 2004. In December 2002, Dime Savings sold approximately $73.4 million of recently originated loans with an original term of over seven years, completing almost 37% of the initial target. Dime Savings has retained all  loan servicing rights, and recorded a pre-tax gain of $2.0 million on this loan sale,\nOUR  adding approximately $0.04 to our diluted earnings per share \nduring both the six-month and twelve-month  periods ended December 31, 2002.\nWe are very excited to partner with Fannie Mae in the New York City multi-family  market. This partnership should benefit us with an increase in fee income and less reliance on spread income. This partnership should also provide us additional lending\n3\nVincent F. Palagiano addressing shareholders at the Company’s most recent Annual Meeting.\nFannie Mae Seller / Servicer Agreement\nLending For the Way New Yorkers Live\nadding approximately $0.04 to our diluted earnings per share "}]}
+{"image": "doclay/doclay_61989.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "US  2020/0050104  Al \n108 \nFeb. 13, 2020 \n-continued  0 \n-continued  0  0  0  0  RA  RA  )yo  )yo  0  0  CCL  O  O  0  0 "}]}
+{"image": "doclay/doclay_18412.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "87\nAGL Energy Limited Annual Report 2012\n2012  $m 2011  $m Deferred tax balances Deferred tax assets/(liabilities) arise from the following: Unbilled revenue (254.2) (208.4) Allowance for doubtful debts 22.6  19.4  Other receivables (0.3) (9.8) Jointly controlled entities 8.3  (7.2) Exploration and evaluation assets (158.4) (154.2) Oil and gas assets (16.3) (34.2) Property, plant and equipment (301.9) (109.2) Intangible assets (10.1) –  Defined benefit superannuation plans 67.1  12.2  Payables and accruals 5.2  40.7  Borrowings (3.0) –  Provisions 107.0  71.0  Derivative financial instruments 10.8  57.0  Deferred revenue 74.7  6.5  Share issue transaction costs 5.2  –  Tax losses 654.8  11.5  Other (2.8) 2.0  Net deferred tax assets/(liabilities) relating to income tax 208.7  (302.7) Deferred tax assets relating to resource rent tax 53.4  –  Net deferred tax assets/(liabilities)  262.1  (302.7) Recognised in the statement of financial position as follows: Deferred tax assets 611.1  –  Deferred tax liabilities  (349.0) (302.7) Net deferred tax assets/(liabilities)  262.1  (302.7) Unrecognised deferred tax assets Deductible temporary differences –  55.0 \nTax consolidation The Parent Entity and its wholly-owned Australian resident subsidiaries formed a tax-consolidated group under Australian taxation law \nRevenue authority matters During the year ended 30 June 2012, AGL received an unfavourable response from the Australian Taxation Office (ATO) to a request for \nExtension of Petroleum Resource Rent Tax to onshore projects Changes to the Petroleum Resource Rent Tax (PRRT) Assessment Act 1987 extend the operation of the PRRT to onshore oil and gas \nTax consolidation The Parent Entity and its wholly-owned Australian resident subsidiaries formed a tax-consolidated group under Australian taxation law  with effect from 25 October 2006 and are therefore taxed as a single entity from that date. AGL Energy Limited is the head entity in the  tax-consolidated group. \nThe members of the tax-consolidated group have entered into a tax sharing and tax funding agreement. The tax funding agreement  requires payments to/from the head entity equal to the current tax liability (asset) assumed by the head entity and any tax-loss deferred  tax asset assumed by the head entity. The payments are recorded as intercompany receivables/payables. \nOn 29 June 2012, AGL Generation Proprietary Limited, a subsidiary of AGL Energy Limited (AGL), acquired the remaining 67.46% of the  shares in, and loan notes issued by, Great Energy Alliance Corporation Pty Limited (GEAC) and 100% of the shares in Loy Yang Marketing  Holdings Pty Limited (LYMH) which it did not already own. GEAC, LYMH and their subsidiaries are not eligible to be members of the  existing AGL tax-consolidated group. On 23 July 2012, the LYMH entities joined a new tax-consolidated group which was formed by  AGL Generation Holdco Pty Ltd, a subsidiary of AGL. On 27 July 2012, the GEAC entities joined the new tax-consolidated group.  AGL Generation Holdco Pty Ltd is the head entity in the new tax-consolidated group. \nRevenue authority matters During the year ended 30 June 2012, AGL received an unfavourable response from the Australian Taxation Office (ATO) to a request for  a private binding ruling relating to the tax treatment of the supply of unbilled energy to AGL’s mass market customers. AGL’s current tax  treatment is to pay income tax on energy when it is billed to customers. If the ATO view is correct, AGL would be required to pay income  tax on energy when it is supplied to customers rather than when it is billed and AGL would be required to recognise the tax as a current  tax liability rather than a deferred tax liability. AGL believes its current tax treatment is correct and has therefore lodged an objection to  the private binding ruling.\nExtension of Petroleum Resource Rent Tax to onshore projects Changes to the Petroleum Resource Rent Tax (PRRT) Assessment Act 1987 extend the operation of the PRRT to onshore oil and gas  projects from 1 July 2012. As the PRRT falls within the scope of AASB 112  Income Taxes , AGL is required to account for any associated  deferred tax assets or deferred tax liabilities as at 30 June 2012. AGL has recognised a deferred tax asset of $53.4 million representing  the difference between the PRRT starting base amount and the carrying value of the production permits to which the PRRT will apply."}]}
+{"image": "doclay/doclay_64429.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "1111111111111111 IIIIII IIIII 1111111111 11111 lllll lllll lllll 111111111111111 1111111111 11111111 \n1111111111111111 IIIIII IIIII 1111111111 11111 lllll lllll lllll 111111111111111 1111111111 11111111  US 20200246423Al \nc19)  United States  c12)  Patent Application Publication \nLiu et al. \n(54)  STABLE AQUEOUS FORMULATIONS OF  AFLIBERCEPT \nc10) Pub. No.: US 2020/0246423 Al \n(43) Pub. Date:  Aug. 6, 2020 \n(71)  Applicant:  Coherus BioSciences Inc.,  Redwood  City, CA (US) \n(72)  Inventors:  Jun Liu,  Redwood City, CA (US);  Mark Manning,  Redwood City, CA  (US);  Sekhar R. Kanapuram,  Thousand Oaks, CA (US) \n(21)  Appl. No.:  16/566,847 \n(22)  Filed:  Sep. 10, 2019 \nRelated U.S. Application Data \n(63)  Continuation-in-part of application No. 16/297,387,  filed on Mar. 8, 2019, which is a continuation of  application No. 62/640,411, filed on Mar. 8, 2018. \nPublication Classification \n(51)  Int. Cl.  A61K 38/17  (2006.01)  A61K  47122  (2006.01)  A61K  47118  (2006.01)  A61K  47126  (2006.01)  A61K 9/00  (2006.01) \n(52)  U.S. Cl.  CPC ............  A61K 38/179  (2013.01);  A61K  47122  (2013.01);  A61K 9/08  (2013.01);  A61K  47126  (2013.01);  A61K 9/0048  (2013.01);  A61K  471183  (2013.01) \n(57)  ABSTRACT \nA stable aqueous pharmaceutical formulation comprising a  therapeutically effective amount of aflibercept, wherein the  formulation is free of organic co-solvent and/or free of  buffer; methods for making such a formulation; and methods  of using such a formulation. \n96.296  96.634  96.972  97.310  97.648  97.986  ======:::::i::::::::::::::::::::::::::::::::::::::::•r::::::::::::::::::::::::e  -_-_-_-_-_-_-_-_-_-_-- :r ~:::::::::::::::::::::. :,  Response Surface  8.0 "}]}
+{"image": "doclay/doclay_4310.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "19 \nUS 2002/0111024 Al \nAug. 15,2002 \n[0213]  Ammonium Persulfate with Malonamide \n[0214]  Ammonium persulfate combined with malonamide  (H$_{2}$NCOCH$_{2}$ CONH$_{2}$ )  shows W removal rates comparable  with those of Ammonium persulfate+malonic acid using the  Logitech PMS polisher (33 rpm, 12 inch IC 1000 pad, 2 psi)  on 3 inch wafers (10,000 A sputtered  W),  with 5% alumina  slurry (50 parts of 10% alumina +90% water slurry), chem› istry flow rate of 90 ml/min, and slurry flow rate of 20  ml/min, as shown below. \n[0215]  Malonamide enhances the  W  removal rate when  combined with Ammonium persulfate in an aqueous system  over the  W  removal rate of Ammonium persulfate alone.  Removal rates increase with pH, and is particularly fast  between pH 7.9 and pH 9. \n[0216]  As  with previous examples, the slurry pH may be  adjusted to any suitable value in order to give the desired  polishing performance. For example, the slurry  pH  may be  adjusted to a value of between about 1 to 10, and more  preferably to between about 6 to 9. \n[0217]  Experiments with blanket  W  metal (10,000 A)  wafer showed that a 10 wt% ammonium persulfate solution  with a 5% alumina slurry removed 162  Nmm  of the metal  (pH  8), yet a 10 wt % ammonium persulfate mixed with a  2%  K.10$_{4 }$ with only a 5 wt% alumina slurry at a  pH  of 6.9  removed 637  Nmm.  When a 2 wt % potassium iodate  (K.1O$_{3}$ )  was substituted into the ammonium persulfate solu› tion, the polishing rate decreased to 246  Nmm.  Polishing  was done with a Logitech SM polisher with a Politex felt  cloth at 33 rpm and 2 psi pressure on the 3 inch wafer. \n[0218]  The concentration of the ammonium persulfate  solution is preferably between about 2 to 20% by weight,  more preferably between about 5 to 15%, and most prefer› ably about 10 wt%. This relationship seems to hold for cases  where additional oxidizers are added also. The alumina  slurry is preferably between about 2 to 20% solids, more  preferably between about 2 to 10%, and most preferably  about 5%. \n[0219]  Ammonium Persulfate with Periodic Acid \n[0220]  In another aspect of the invention, a similar chem› istry to that of the previous aspect uses a synergism between  ammonium persulfate (Ammonium persulfate) and periodic  acid (rather than potassium periodate) for polishing tung› sten. There is a synergistic effect that enhances W removal  rate when Ammonium persulfate and periodic acid are used  together. The tungsten process appears to operate via the  tungstate (WO4-) anion. \n[0221]  Periodic acid in water added to Ammonium per› sulfate increases the removal rate of W over Ammonium  persulfate alone at a pH of 1; increasing the amount of \n[0222]  Periodic acid clearly improves the polishing rate of  Ammonium persulfate formulations when used on a tung› sten substrate. The Ammonium persulfate concentration is  preferably between about 2 to 20%, more preferably  between about 5 to 15%, and most preferably about 10%.  The concentration of the periodic acid solution is preferably  between about 0 to 10% by weight, more preferably between  about 0.2 to 5%, and most preferably about 2 wt %. \n[0223]  The periodic acid can also be the primary oxidizer.  However, a 10% periodic acid and 2% Ammonium persul› fate formulation at the high  pH  of 8.2, added at 20 ml per  minute with 5%  LOGITECH  abrasive added at 20%, using  an  POLITEX  pad at 2 psi and 33 rpm on a 3\"  IWS  substrate  the disappointing polishing rate of 56 Angstroms per minute.  A  similar test with 10% Ammonium persulfate and 3%  periodic acid at  pH  1.3 gave the surprisingly high etch rate  of 174 Angstroms per minute. \n[0224]  Ammonium Persulfate with Lithium Periodate \n[0225]  Ammonium persulfate can also be admixed with  lithium periodate. Lithium periodate in water added to  Ammonium persulfate increases the removal rate of  W  over  Ammonium persulfate alone. In tests using the Logitech  PMS polisher (33 rpm, 12 inch IClO00 pad, 2 psi), 3 inch  wafers (10,000 A sputtered  W),  5%  MOYCO  alumina (10  parts of 10% alumina+90% water slurry), and chemistry/  slurry addition rate of 100 ml/min, the lithium periodate  provided modest increases in the etching rate as shown  below. \nperiodic acid used with 10 parts Ammonium persulfate also  increases the W removal rate using the Logitech PMS  polisher (33 rpm, 12 inch IClO00 pad, 2 psi), 3 inch wafers  (10,000 A sputtered  W),  0-3 parts  NH$_{4}$0H  to adjust  pH,  1 %  alumina (10 parts of 10% alumina+90% water slurry), and  chemistry/slurry addition rate of 100 ml/min, as shown  below. \nCMP with Ammonium persulfate - Malonamide Slurries  Ammonium  persulfate (wt.  %)  Malonamide (wt. %) pH  Removal Rate (A/mm)  10  0  8.0  162  10  2.0  7.9  210  10  1.0  9.0  429  10  2.5  8.9  385  10  2.0  7.9  250  10  0  7.9  198 \nCMP with Ammonium persulfate/Periodic acid Slurries  Ammonium  persulfate (wt.  %)  Periodic Acid (wt. %)  pH Removal Rate (A/mm)  0  2.0  1.5  130  10  2.0  1.1  386  10  0.5  3.5  118  10  2.0  5.2  388  10  0  6  112 \nCMP with Ammonium persulfate/Lithium Periodate Slurries  Ammonium  Removal Rate  persulfate (wt.  % )  Lithium Periodate (wt.  % )  pH  (A/mm)  0  0.4  7.4  38  8  0.3  6.4  112  10  0.3  2.7  202  10  0.4  5  196  10  0.4  5.5  298  10  0.4  8.5  473  10  0.1  7  177  10  0.3  7.5  237  10  0.3  7.7  301 "}]}
+{"image": "doclay/doclay_40097.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Q14  Item 2.2 Double Sided Parallel Polishing Machine  Definition: This device shall be used to obtain surface smoothness without stress  and heat-related distortion on sensitive surfaces such as glass and ceramic.  In order to be able to configure the machine according to the needs of the  beneficiary, we kindly request the Contracting Authority to clarify following points;  What is the end use of the workpiece (or the end product to which the part will be  connected)? (automotive, aerospace, laboratory bench etc.)  Could you please share a technical drawing or a draft of the workpiece? If possible  the raw and the polished workpiece with tolerance values. For the raw material, could you please share following values ? - Thickness  - Thickness tolerance  - Process before polishing  - The sawdust amoun  For the finished material;  Thickness  The equipment will be mostly used to grind transparent spinel.  The end pieces will be used as for example, watch screens and  observation windows for lab. equipment. No value can be given  for the sawdust amount.  Please refer to Changes No:1 to the Tender Dossier, article  2.2.10.  Q15  Item 2.2.3  Machine shall be suitable for working pieces of materials with hardness up to  Please refer to Changes No:1 to the Tender Dossier, article 2.2.3. \nCLARIFICATION No: 1\nPublication Ref: EuropeAid/140639/IH/SUP/TR  Subject: Supply of Equipment for Advanced Prototype Station (APS)\nSayfa  7  /  23"}]}
+{"image": "doclay/doclay_76381.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "TABLE IV: Numerical results for Δ M$_{Gij}$ of muon g − 2 from diagrams Gij in set II(e) in each of which tau-lepton induces light-by-light scattering. Full symmetry factors are included in the individual values. The number of sampling points for each iteration is 10 8 for all diagrams with the second-order self-energy subdiagrams and 2 × 10 8 for all others.\nGij Δ M$_{Gij}$ (uncertainty) χ 2 iterations A 44 0 . 422 177 (18) 1 . 09 1600 A 55 0 . 215 057 (18) 1 . 19 480 A 77 0 . 219 086 (19) 1 . 18 320 A 47 0 . 112 235 (14) 0 . 96 240 A 45 − 0 . 008 963 (17) 1 . 07 160 A 46 0 . 119 699 (16) 1 . 37 160 A 57 0 . 138 883 (10) 1 . 63 160 B 44 − 0 . 239 377 (18) 1 . 02 1400 B 55 − 0 . 298 375 (18) 0 . 99 1280 B 47 − 0 . 017 671 (16) 1 . 11 160 B 45 0 . 053 945 (16) 1 . 16 160 B 46 − 0 . 014 195 (13) 0 . 96 160 B 57 − 0 . 140 250 5 (80) 1 . 43 240 C 44 − 0 . 288 614 (18) 1 . 04 1280 C 55 − 0 . 125 456 (18) 1 . 14 400 C 77 − 0 . 120 731 (18) 1 . 18 320 C 47 0 . 019 880 (15) 1 . 13 160 C 45 0 . 011 773 (16) 0 . 89 160 C 46 − 0 . 129 852 (14) 1 . 09 240 C 57 − 0 . 014 913 9 (86) 1 . 17 160 sum − 0 . 085 66 (7)\n14"}]}
+{"image": "doclay/doclay_44714.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "When installed in the aircraft, there is sometimes only one  thermocouple lead and indicator for each engine installed  in an aircraft.\nCylinder head temperatures are indicated by a gauge  connected to a thermocouple attached to the cylinder, that  tests show to be the hottest on an engine in a particular  installation. The thermocouple may be placed in a special  gasket located under a rear spark plug, or in a special well  in the top or rear of the cylinder head.\nThe temperature recorded at either of these points is merely  a reference or control temperature; but as long as it is  kept within the prescribed limits, the temperatures inside  the cylinder dome, exhaust valve, and piston is within a  satisfactory range. Since the thermocouple is attached to only  one cylinder, it can do no more than give evidence of general  engine temperature. While normally it can be assumed that  the remaining cylinder temperatures are lower, conditions  such as detonation are not indicated unless they occur in the  cylinder that has the thermocouple attached.\nThe cylinder head temperature gauge range marking is  similar to that of the manifold pressure and tachometer  indicator. The cylinder head temperature gauge is a dual  gauge that incorporates two separate temperature scales.  [Figure 10-39]  The scales are calibrated in increments of 10°,  with numerals at the 0°, 100°, 200°, and 300° graduations. The  space between any two graduation marks represents 10 °C.\nMost torque systems use an oil pressure output from a torque  valve to indicate actual engine power output at various power  settings. The torquemeter indicates the amount of torque being  produced at the propeller shaft. A helical gear moves back  and forth as the torque on the propeller shaft varies. This gear,  acting on a piston, positions a valve that meters the oil pressure  proportionally to the torque being produced. A change in \nTurbine engines use percent rpm indicators due to the  high rpm that the engines generally operate. Each rotating  assembly in an engine has its own percent rpm indicator.  The 100 percent position on the indicator is the highest rpm  the engine can operate. Red lines and green arcs operate the  same as with reciprocating engines.\nDuring the engine test procedures, the cylinder head  temperatures of various cylinders on the reciprocating  engine are normally tested. Thermocouples are connected  to several cylinders and, by a selector switch, any cylinder  head temperature can be indicated on the indicators. \n10-24\nFigure 10-39.  Cylinder head temperature gauge. \nFigure 10-38.  Tachometer. \nCylinder Head Temperature Indicator\n65 Figure 10-37.  Manifold pressure gauge. \nBlue Green Red 300 200 0 100 300 200 0 100 CYL. TEMP. HEAD C° 300 200 0 100 300 200 0 100Torquemeter\nGreen Red MAN. IN. HG. ABS. 10 15 20 25 30 35 40 45 50 55 60 65 70 75 15 20 25 30 35 40 45 50 55 60 65 75"}]}
+{"image": "doclay/doclay_18964.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "MANAGEMENT’S DISCUSSION AND ANALYSIS\nThe Company remains well positioned in terms of drilling potential for shallow and deep natural gas and  heavy and conventional crude oil. AKITA has the experience, personnel and financial resources to increase its  presence in Western Canada. Further, AKITA has successfully demonstrated its ability to convert conventional  rigs into pad configurations and is also currently constructing its first slant-capable rig. AKITA’s strategy over  the past years has been to develop equipment and key relationships to effectively target specific market  opportunities.\nAs at December 31, 2013, management evaluated, under the supervision of and with the participation of the  President and Chief Executive Officer (the “CEO”) and the Vice President, Finance and Chief Financial Officer  (the “CFO”), the effectiveness of the Company’s disclosure controls and procedures (“DC&P”) as defined under  National Instrument 52-109. Based on that evaluation, the CEO and CFO concluded that the Company’s DC&P  was effective as at December 31, 2013.\nFrom time to time AKITA makes forward-looking statements. These statements include but are not limited  to comments with respect to AKITA’s objectives and strategies, financial condition, results of operations, the  outlook for industry and risk management discussions.\nBy their nature, these forward-looking statements involve numerous assumptions, inherent risks and  uncertainties, both general and specific, and therefore carry the risk that the predictions and other forward- looking statements will not be realized. Readers of this MD&A are cautioned not to place undue reliance on  these statements as a number of important factors could cause actual future results to differ materially from  the plans, objectives, estimates and intentions expressed in such forward-looking statements.\nForward-looking statements may be influenced by factors such as the level of exploration and development  activity carried on by AKITA’s customers; world crude oil prices and North American natural gas prices;  weather; access to capital markets; and government policies. We caution that the foregoing list of factors is  not exhaustive and that while relying on forward-looking statements to make decisions with respect to AKITA,  investors and others should carefully consider the foregoing factors as well as other uncertainties and events  prior to making a decision to invest in AKITA. Except where required by law, the Company does not undertake  to update any forward-looking statement, whether written or oral, that may be made from time to time by it or  on its behalf.\nAdditional information is provided by the Company in its Annual Information Form, Notice of Annual Meeting  and Information Circular all dated March 5, 2014. Copies of these documents including additional copies  of the Annual Report for the year ended December 31, 2013 may be obtained upon request from the Vice  President, Finance and Chief Financial Officer of the Company at 900, 311 – 6th Avenue S.W., Calgary, Alberta,  T2P 3H2 or at www.sedar.com.\nThere are no announced upcoming accounting standards (IFRS) changes that will affect AKITA in the near term.\nUpcoming Accounting Standard Changes\nOther Information\nDisclosure Controls and Internal Controls Over Financial Reporting\nForward-Looking Statements\n28 AKITA DRILLING LTD.  ANNUAL REPORT"}]}
+{"image": "doclay/doclay_40070.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "II – S ITUATIONS D ' EXCLUSION CONCERNANT LES PERSONNES PHYSIQUES OU MORALES AYANT  LE POUVOIR DE REPRESENTATION ,  DE DECISION OU DE CONTROLE A L ' EGARD DE LA PERSONNE MORALE  ET LES BENEFICIAIRES EFFECTIFS\nNe s'applique pas aux personnes physiques, aux États membres et aux autorités locales \nIII – S ITUATIONS D ' EXCLUSION CONCERNANT LES PERSONNES PHYSIQUES OU MORALES QUI  REPONDENT INDEFINIMENT DES DETTES DE LA PERSONNE MORALE\n4 \n2) déclare qu'une personne physique ou morale qui est membre de  l'organe d'administration, de direction ou de surveillance de la personne morale susmentionnée ou qui possède des pouvoirs  de représentation, de décision ou de contrôle à l'égard de ladite  personne morale (à savoir, par exemple, les chefs d'entreprise, les membres des organes de direction ou de surveillance et les personnes physiques ou morales détenant, à titre individuel, la majorité des parts), ou un bénéficiaire effectif de la personne [au sens de l’article 3, point 6), de la directive (UE) 2015/849]  se trouve dans l'une des situations suivantes: OUI  NON  Sans  objet  Situation visée au point c) ci-dessus (faute professionnelle grave)  Situation visée au point d) ci-dessus (fraude, corruption ou autre  infraction pénale)  Situation visée au point e) ci-dessus (manquements graves dans  l'exécution d'un marché)  Situation visée au point f) ci-dessus (irrégularité)  Situation visée au point g) ci-dessus (création d’une entité dans  l’intention de se soustraire à des obligations légales)  Situation visée au point h) ci-dessus (personne créée dans  l’intention de se soustraire à des obligations légales)  Situation visée au point i) ci-dessus \n3) déclare qu'une personne physique ou morale qui répond  indéfiniment des dettes de la personne morale susmentionnée se  trouve dans l'une des situations suivantes: OUI  NON  Sans  objet  Situation visée au point a) ci-dessus (faillite)  Situation visée au point b) ci-dessus (non-respect des obligations  de paiement des impôts ou des cotisations de sécurité sociale) "}]}
+{"image": "doclay/doclay_76340.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "[hep-ph]].\n[20] T. Aoyama, M. Hayakawa, T. Kinoshita, and M. Nio, Tenth-Order Lepton Anomalous Mag- netic Moment – Second-Order Vertex Containing Two Vacuum Polarization Subdiagrams, One Within the Other , Phys. Rev. D 78 , 113006 (2008) [arXiv:0810.5208 [hep-ph]].\n[21] C. Amsler et al. [Particle Data Group], Review of particle physics , Phys. Lett. B 667 , 1 (2008).\n[22] P. Cvitanovic and T. Kinoshita, Feynman-Dyson rules in parametric space , Phys. Rev. D 10 , 3978 (1974).\n[23] P. Cvitanovic and T. Kinoshita, New Approach To The Separation Of Ultraviolet And Infrared Divergences Of Feynman - Parametric Integrals , Phys. Rev. D 10 , 3991 (1974).\n[24] P. Cvitanovic and T. Kinoshita, Sixth-order magnetic moment of the electron , Phys. Rev. D 10 , 4007 (1974).\n[25] T. Kinoshita and M. Nio, Revised α 4 term of lepton g − 2 from the Feynman diagrams con- taining an internal light-by-light scattering subdiagram , Phys. Rev. Lett. 90 , 021803 (2003) [arXiv:hep-ph/0210322].\n[26] G. P. Lepage, A new algorithm for adaptive multi-dimensinonal integration , J. Com- put. Phys. 27 , 192 (1978).\n[27] T. Kinoshita and W. B. Lindquist, Eighth-order magnetic moment of the electron. IV. Vertex diagrams containing photon-photon scattering subdiagrams , Phys. Rev. D 39 , 2407 (1989).\n18"}]}
+{"image": "doclay/doclay_74295.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "133 STAT. 966 \nPUBLIC LAW 116–23—JUNE 25, 2019 \nPublic Law 116–23  116th Congress \nAn Act \nSECTION 1. SHORT TITLE. \nSEC. 2. CLARIFICATION OF PRESUMPTIONS OF EXPOSURE FOR VET- ERANS WHO SERVED IN VICINITY OF REPUBLIC OF VIETNAM. \n‘‘§ 1116A. Presumptions of service connection for veterans  who served offshore of the Republic of Vietnam \nDetermination. \nDetermination. \nduring that service.  ‘‘(c) EFFECTIVE DATE OF AWARD.—(1) Except as provided by  paragraph (2), the effective date of an award under this section  shall be determined in accordance with section 5110 of this title.  ‘‘(2)(A) Notwithstanding subsection (g) of section 5110 of this \nshall be determined in accordance with section 5110 of this title.  ‘‘(2)(A) Notwithstanding subsection (g) of section 5110 of this  title, the Secretary shall determine the effective date of an award  based on a claim under this section for an individual described  in subparagraph (B) by treating the date on which the individual  filed the prior claim specified in clause (i) of such subparagraph  as the date on which the individual filed the claim so awarded  under this section. \nof such disease during the period of such service.  ‘‘(b) EXPOSURE.—A veteran who, during active military, naval,  or air service, served offshore of the Republic of Vietnam during  the period beginning on January 9, 1962, and ending on May  7, 1975, shall be presumed to have been exposed during such  service to an herbicide agent unless there is affirmative evidence  to establish that the veteran was not exposed to any such agent  during that service.  ‘‘(c) EFFECTIVE DATE OF AWARD.—(1) Except as provided by \nTime period. \n‘‘(a) SERVICE CONNECTION.—For the purposes of section 1110  of this title, and subject to section 1113 of this title, a disease  covered by section 1116 of this title becoming manifest as specified  in that section in a veteran who, during active military, naval,  or air service, served offshore of the Republic of Vietnam during  the period beginning on January 9, 1962, and ending on May  7, 1975, shall be considered to have been incurred in or aggravated  by such service, notwithstanding that there is no record of evidence  of such disease during the period of such service.  ‘‘(b) EXPOSURE.—A veteran who, during active military, naval, \nTime period. \n38 USC 1116A. \n(a) IN GENERAL.—Chapter 11 of title 38, United States Code,  is amended by inserting after section 1116 the following new section: \nThis Act may be cited as the ‘‘Blue Water Navy Vietnam  Veterans Act of 2019’’. \nBlue Water Navy  Vietnam  Veterans Act  of 2019.  38 USC 101 note. \nBe it enacted by the Senate and House of Representatives of  the United States of America in Congress assembled, \nTo amend title 38, United States Code, to clarify presumptions relating to the  exposure of certain veterans who served in the vicinity of the Republic of Vietnam,  and for other purposes. \nJune 25, 2019 \n[H.R. 299] "}]}
+{"image": "doclay/doclay_60213.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "UCI CYCLING REGULATIONS \nChapter X UCI RANKINGS  (chapter replaced on 1.01.09 ; modified on 1.01.16). \n§ 1 Elite and Under 23 Men’s UCI World Ranking \nUCI RANKINGS  (chapter replaced on 1.01.09 ; modified on 1.01.16). \n2.10.001 The UCI publishes the world rankings on account of results in men elite and under 23  men UCI events on the international calendar. This ranking is the exclusive property of  the UCI. \nIndividual UCI World Ranking  2.10.002 The individual UCI World Ranking is a 52-week rolling ranking and shall be drawn up at  least once a week.\nIndividual UCI World Ranking  The individual UCI World Ranking is a 52-week rolling ranking and shall be drawn up at \nIndividual UCI World Ranking  –  one-day races  The individual UCI World Ranking – one-day races is a 52-week rolling ranking that is\nIndividual UCI World Ranking - stage races  The individual UCI World Ranking – stage races is a 52-week rolling ranking that is\nRiders score points on the individual ranking in accordance with the scale in article  2.10.008 only taking into account stage races. \nThe new ranking comes into force on the day of publication and stands until the  publication of the subsequent ranking. \n(article introduced on 1.01.19; abrogated on 23.10.19; reintroduced on 11.02.20). \nRiders score points on the individual ranking in accordance with the scale in article  2.10.008 only taking into account one-day races. \nIf necessary, the ranking for the preceding weeks shall be corrected. The new ranking  comes into force on its day of publication and remains valid until the publication of the  subsequent ranking. \n(article introduced on 1.01.16; text modified on 23.10.19). \nPoints awarded for stages are included in the ranking drawn up following the final day of  a stage race. \nRiders score points on the individual ranking in accordance with the scale in article  2.10.008. \nThe new ranking comes into force on the day of publication and stands until the  publication of the subsequent ranking. \n(article introduced on 1.01.16; text modified on 23.10.19). \nElite and under 23 men shall be listed in the same ranking. \nIndividual UCI World Ranking  –  one-day races  2.10.002 The individual UCI World Ranking – one-day races is a 52-week rolling ranking that is bis updated once a week. \nIndividual UCI World Ranking - stage races  2.10.002 The individual UCI World Ranking – stage races is a 52-week rolling ranking that is ter updated once a week. \nE170421 \nROAD RACES \n73 "}]}
+{"image": "doclay/doclay_25193.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Δ 1 ,  1 Δ 2 ,  1 Δ 1 ,  2 Δ 2 ,  2 Δ 1 ,  3 Δ 2 ,  3 Δ 1 ,  4 Δ 2 ,  4 γ 1 γ 2 γ 3 chol ( V$_{1}$ ,  1 ) chol ( V$_{2}$ ,  1 ) chol ( V$_{2}$ ,  2 ) mean (β 1 ) mean (β 2 ) 0.95 1.00 1.05 1.10 0.1 0.2 0.3 0.4 0.5 1.2 1.3 1.4 1.5 0.5 0.6 0.7 −0.01 0.00 0.01 0.02 0.03 −0.050 −0.025 0.000 0.025 0.050 0.075 −0.05 0.00 0.05 0.00 0.02 0.04 0.0 0.1 0.2 0.3 −0.2 −0.1 0.0 33.80 33.85 33.90 0.80 0.84 0.88 −0.01 0.00 0.01 0.02 0.03 0.19 0.20 0.21 0.22 1.01 1.02 1.03 0.005 0.010 0.015 500 550 600 650 700 500 550 600 650 700 500 550 600 650 700 500 550 600 650 700 Iteration (x 1000) value\nFigure 5: HMC trace plot for value of population-level parameters in hierarchical model example, starting at Iteration 500,000. Every 500th iteration is plotted.\nabout 8.7 seconds. The time to sample 1,000 proposals from an MVN distribution, and compute the MVN densities for each, is about .89 seconds. Therefore, to collect and evaluate 16.5 million proposal samples (to get 300 posterior draws) would take about 44 hours. But this is for a single processing core. Using all 12 cores on our Mac Pro, the sampling time is reduced to 220 minutes. We discuss the scalability of the component steps of the algorithm in Section 4.\nAccess to more processing nodes could reduce this time even further. It is the ability to collect posterior samples in parallel that gives our method its greatest advantage over MCMC methods. One could run multiple MCMC chains in parallel, but this involves waiting until all of the chains, individually, converge to the target posterior, before we could begin collecting samples for infer- ence. Even then, there is no way to confirm that the chain has, in fact, converged.\nWe can draw inferences about the accuracy of our method by comparing the estimated marginal densities to those that we get from HMC. Note that the HMC estimates are accurate only if all of the chains converge to the target density, and we have a large-enough effective sample size. This condition clearly does not hold, but it is sufficiently close for the majority of the population-level parameters for us to use HMC samples as a baseline standard. Figure 6 is a comparison of the\n18"}]}
+{"image": "doclay/doclay_35524.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "AuAu collisions (Fig. 1) we expect that central collisions of AuAu and CuCu show a similar v$_{2}$/ϵ$_{part}$ despite of the large difference of N$_{part}$ . In peripheral CuCu and AuAu collision v$_{2}$/ϵ$_{part}$ should be very similar for the same N$_{part}$ . In order to compare our model with exper- iment we have to determine ( v$_{2}$/ϵ$_{part}$ ) $^{hydro}$, i.e. v$_{2}$/ϵ$_{part}$ for f$_{core}$ = 1. We take ( v$_{2}$/ϵ$_{part}$ ) hydro as 24%, 19.7% and 12.6% for reactions at √$_{s}$ of 200 AGeV, 62 AGeV and 17.2 AGeV, respectively. In fig.5 we display the ex- perimental results from PHOBOS (full symbols), from STAR (open symbols) and from NA49 (open squares) in comparison with our predictions, presented as lines. We see a quite nice agreement. As in our model, for a given number of N$_{part}$ the experimental values of v$_{2}$/ϵ$_{part}$ for CuCu are higher than those for AuAu. Hydrody- namical calculations predict the opposite. This allows to conclude on the underlying mechanism once the error bars of the present preliminary data are further reduced. The situation becomes much more clear when we divide v$_{2}$/ϵ$_{part}$ by f$_{core}$ . Our model predicts a constant. Fig. 6 presents the PHOBOS data for the 4 different systems, AuAu and CuCu at 200 and 64 AGeV . The experimen- tal v$_{2}$/ ( ϵ$_{part}$f$_{core}$ ) is indeed independent of N$_{part}$ which means that the centrality dependence of v$_{2}$/ ( ϵ$_{part}$ ) agrees with that of f$_{core}$ . This does not exclude, of course, that in hydrodynamical calculations a viscosity can be obtained by fitting the centrality dependence of the ex- perimental data. In our approach we do, however, not need such a fit parameter. It is astonishing that even for the most peripheral reactions, where the number of core particles is of the order of 10 and therefore the assump- tion of a hydrodynamical elliptical flow is questionable, the predictions of core - corona model still hold.\nIn our approach v$_{2}$/ϵ$_{part}$ is a property of the plasma particles and therefore one may expect the same central- ity dependence of v$_{2}$/ϵ$_{part}$ for all hadrons (although we cannot exclude that the hadronization itself creates dif- ferences for different types of hadrons). This is, how- ever, not true. The fraction of particles which come from the core depends, according to eq. 1, on the par- ticle species. For all charged particles and π , for which M$_{core}$ ≈ M$_{corona}$ , this dependence is weak [12] (and there- fore we have divided v$_{2}$ by f$_{core}$ ) but for multi-strange hadrons, for which M$_{core}$ >> M$_{corona}$ , this is an impor- tant effect. We expect\ndoes not show a scaling with the number of entrained quarks n$_{q}$ which has been observed in the differential spectra for ( m$_{T}$ − m$_{0}$ ) /n$_{q}$ < 1 GeV , with m$_{T}$ ( m$_{0}$ ) being the transverse (rest) mass. The relative ratio of v i 2 ϵ$_{part}$ between baryons and mesons depend on centrality and on the particle species and is not 3/2 corresponding to the ratio of entrained constituent quarks. However, before firm conclusions can be drawn more data have to\nFig.7 shows the centrality dependence of v i 2 $_{ϵ$_{part}$}$( N$_{part}$ ) / v charged hadrons 2 ϵ$_{part}$ ( N$_{part}$ ) for the prelimi- nary p$_{T}$ integrated K$_{0}$, Λ , Ξ data as measured by the STAR collaboration [17]. These data are compared with the model, eq. 4. Model and experiment agree within error bars and the trend of the data is well reproduced. We note that the p$_{T}$ integrated value of v$_{2}$\nv i 2 ϵ$_{part}$ ( N$_{part}$ ) (4) = f$_{core}$ · M i core f$_{core}$ · M i core + (1 − f$_{core}$ $^{)}$· M i corona · ( v$_{2}$ $_{ϵ$_{part}$}$) $^{hydro}$.\nFIG. 5: Top: N part dependence of v 2 /ϵ part for charged hadrons in AuAu and CuCu at 200 AGeV and 62 AGeV as measured by PHOBOS[14] and STAR [15, 17] as well as at 17.2 AGeV [16] as measured by NA49 in comparison with theory. Bottom: Zoom of the region of small N part .\n0 50 100 150 200 250 300 350 400 0 5 10 15 20 25 30 35 40 45 0 20 40 60 80 100 120 0 5 10 15 20 25 30\n4"}]}
+{"image": "doclay/doclay_59676.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "NDB Cluster Status Variables\nNDB Cluster Status Variables\nSection 23.1.4, “What is New in NDB Cluster”\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nNdb_api_bytes_received_count_replica\nNdb_api_bytes_received_count_session\nNdb_api_bytes_received_count_slave\nNdb_api_bytes_sent_count\nNdb_api_bytes_sent_count_replica\nNdb_api_bytes_sent_count_session\nNdb_api_bytes_sent_count_slave\nNdb_api_event_bytes_count\nNdb_api_event_bytes_count_injector\nNdb_api_event_data_count\nNdb_api_event_data_count_injector\nNdb_api_event_nondata_count\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nSection 23.1.4, “What is New in NDB Cluster”\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nNDB Cluster Status Variables\nSection 23.1.4, “What is New in NDB Cluster”\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nSection 23.1.4, “What is New in NDB Cluster”\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nSection 23.5.13, “NDB API Statistics Counters and Variables”\nNDB Cluster Status Variables\nSection 23.5.13, “NDB API Statistics Counters and Variables”\n6007"}]}
+{"image": "doclay/doclay_65128.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "U.S. Patent \nJun.25,2019 \nSheet 21 of 35 \nUS 10,332,688 B2 \nFigure 21 \n.  ~  ro  ’7  .._  >,  - •m  C:  ID  +,,#  C:  2.5  2.0  ’+  •+•+•+•-++•••+•++•+•••+  1.5  1.0  0.5  0.0  Energy w. r.  t.  EF  I  eV "}]}
+{"image": "doclay/doclay_29583.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "true, GWs from infinite strings can give dominant contribution to the GW background at those low frequencies, as we will show in this paper. Second, infinite strings can emit GWs with wavelength of horizon scale because the characteristic scale of infinite strings is as long as the size of the horizon. This may be detected by future and on-going CMB surveys. Loops cannot emit GWs with such long wavelength. $^{2}$Thus, we are lead to consider GWs from infinite strings.\nA structure on infinite strings which is responsible for GW emission is a kink. $^{3}$Kinks are produced when infinite strings reconnect and kinks on the infinite strings can produce GW bursts. The kinks are sharp when they first appear, but are gradually smoothened as the Universe expands. Moreover, when an infinite string self-intercommutes and produces a loop, some kinks immigrate from the infinite string to the loop, and hence the number of kinks on the infinite string decreases. Recently, Copeland and Kibble derived the distribution function of kinks on an infinite string taking into account these effects [13]. However, they did not study the GWs from kinks.\nTherefore, in this paper, we investigate GWs from kinks using the kink distribution obtained in [13] and discuss the detectability of them by future GW experiments, especially by pulsar timing, such as Square Kilometer Array (SKA) and space-based detectors such as DECIGO and BBO.\nThis paper is organized as follows. In section 2, we briefly review a part of the basis of cosmic strings. In section 3, we derive the distribution function of kinks on infinite strings according to [13]. In section 4, we derive the formula of the energy radiated from kinks per unit time. In section 5, we calculate the spectrum of stochastic GW background originating from kinks, using formula derived in section 4. Section 6 is devoted to summary and discussion.\n2 Other recent simulations imply α ∼ 0 . 1, which is much bigger than Gµ . In this case loops can emit GWs whose wavelength is comparable to or somewhat shorter than the horizon scale [12].\n3 Generically, infinite strings do not have any cusp since its existence depends on the boundary condition of the string, i.e., the periodic condition.\n3"}]}
+{"image": "doclay/doclay_7754.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\nA curtailment is a significant reduction in plan benefits that can result when a DB pension plan is amended  or restructured. Types of  curtailments include:\n• a reduction in the expected number of years of future service of active employees\n• the elimination of the right to earn defined benefits for some or all of the future service of employees.\nA company makes a settle- ment when it substantially settles all or part of an accrued benefit obligation. An example is a lump-sum cash payment to employees in exchange for their rights to receive future benefits.\nWe amortize past service costs from plan amend- ments on a straight-line basis over the average remain- ing service period of employees who were active on  the day of the amendment. This represents the period that we expect to realize economic benefits from the amendments.\nTransitional assets and obligations that arose upon implementation of new accounting standards for employee future benefits are amortized on a straight- line basis over the average remaining service period of employees expected to receive benefits under the plans.\nWe use the corridor approach to recognize actuarial gains and losses into earnings. First we deduct 10% of the benefit obligation or the market-related value of plan assets, whichever is greater, from the unamortized net actuarial gains or losses based on a market-related value basis. Then we amortize the excess over the aver- age remaining service period of active employees. At the end of 2004, this ranges from approximately 10 to 17 years, with a weighted average period of 14 years.\nWhen the restructuring of a benefit plan results  in both a curtailment and a settlement of obligations, we account for the curtailment before we account for the settlement.\nDecember 31 is the measurement date for most of our employee benefit plans. Our actuaries perform a valua- tion at least every three years to determine the actuarial present value of the accrued pension and other retire- ment benefits. The last actuarial valuation of most of our pension plans was performed on January 1, 2003.\nSome of our subsidiaries offer defined contribution (DC) plans that provide certain employees with pen- sion benefits.\nIn January 2005, BCE Inc. and Bell Canada intro- duced a DC pension plan for its employees. Current employees had the option of retaining their DB cover- age or switching to the new DC coverage.\nGoing forward, most new employees will partici- pate in the DC pension arrangements.\nWe recognize a pension cost for DC plans when the employee provides service to the company, essentially coinciding with the cash contributions to the plan.\n90 Bell Canada Enterprises  2004 Annual Report\nWe credit to share capital any amount employees pay when they exercise their stock options or buy shares. We recognize the contributions BCE Inc. makes under ESPs as compensation expense. We also recognize compensation expense or recovery relating to SCPs.\n• setting specific performance targets that must be met before the option can be exercised.\n• the value of the long-term incentive plans where stock options are granted was reduced to account for the introduction of a new mid-term incentive plan that uses RSUs\nStarting in 2004, we made a number of prospective changes to the key features in our stock-based com- pensation plans, including:\nBCE Inc.’s stock-based compensation plans include employee savings plans (ESPs), restricted share units (RSUs) and long-term incentive plans. Before 2000, the long-term incentive plans often included SCPs.\nWe expense all subscriber acquisition costs when  services are activated. \nWe calculate future income taxes using the rates enacted by tax law and those substantively enacted. A tax law is substantively enacted when it has been tabled in the legislature but may not have been passed into law. The effect of a change in tax rates on future income tax assets and liabilities is included in earnings in the period when the change is substantively enacted.\n• the benefit of losses and non-refundable tax credits that will more likely than not be realized and carried forward to future years to reduce income taxes.\n• the temporary differences between the carrying amounts of assets and liabilities for accounting purposes and the amounts used for tax purposes, on an after- tax basis\nCurrent income tax expense is the estimated income taxes payable for the current year before any refunds or the use of losses incurred in previous years. We use the asset and liability method to account for future income taxes. Future income taxes reflect:\nIncome Taxes\nCurtailment\nSettlement\n(ii) Defined Contribution Plans\nSubscriber Acquisition Costs\nStock-Based Compensation Plans"}]}
+{"image": "doclay/doclay_56766.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "sys Schema Stored Functions\n*************************** 1. row *************************** thread_stack: {\"rankdir\": \"LR\",\"nodesep\": \"0.10\", \"stack_created\": \"2014-02-19 13:39:03\", \"mysql_version\": \"8.0.2-dmr-debug-log\", \"mysql_user\": \"root@localhost\",\"events\": [{\"nesting_event_id\": \"0\", \"event_id\": \"10\", \"timer_wait\": 256.35, \"event_info\": \"sql/select\", \"wait_info\": \"select @@version_comment limit 1\nerrors: 0\nwarnings: 0\nlock time: ...\n{ \"error\": \"Trx info truncated: Row 6 was cut by GROUP_CONCAT()\" }\nmysql>  SELECT sys.ps_thread_trx_info(48)\\G *************************** 1. row *************************** sys.ps_thread_trx_info(48): [ { \"time\": \"790.70 us\", \"state\": \"COMMITTED\", \"mode\": \"READ WRITE\", \"autocommitted\": \"NO\", \"gtid\": \"AUTOMATIC\", \"isolation\": \"REPEATABLE READ\", \"statements_executed\": [ { \"sql_text\": \"INSERT INTO info VALUES (1, \\’foo\\’)\", \"time\": \"471.02 us\", \"schema\": \"trx\", \"rows_examined\": 0, \"rows_affected\": 1, \"rows_sent\": 0, \"tmp_tables\": 0, \"tmp_disk_tables\": 0, \"sort_rows\": 0,\n5210\nExample\nReturn Value\nConfiguration Options\nParameters\n28.4.5.17 The ps_thread_trx_info() Function\nReturns a JSON object containing information about a given thread. The information includes the current transaction, and the statements it has already executed, derived from the Performance Schema events_transactions_current  and  events_statements_history  tables. (The consumers for those tables must be enabled to obtain full data in the JSON object.)\nIf the output exceeds the truncation length (65535 by default), a JSON error object is returned, such as:\nSimilar error objects are returned for other warnings and exceptions raised during function execution.\n• in_thread_id BIGINT UNSIGNED : The thread ID for which to return transaction information. The value should match the  THREAD_ID  column from some Performance Schema  threads  table row.\n• ps_thread_trx_info.max_length ,  @sys.ps_thread_trx_info.max_length\nps_thread_trx_info()  operation can be modified using the following configuration options or their corresponding user-defined variables (see Section 28.4.2.1, “The sys_config Table” ):\nThe maximum length of the output. The default is 65535.\nA  LONGTEXT  value."}]}
+{"image": "doclay/doclay_41261.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "\nFigure 3. Angle of attack. \nPage 8 of 8\nChange 1 (December 2015)\n A-10"}]}
+{"image": "doclay/doclay_70302.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "8464ch02_Architecture.fm\nDraft Document for Review February 7, 2020 3:15 pm\nCall Home events send data that is related to the problem to the IBM product support group.  This data includes the following information:\nGLYPH<SM590000> Overall system information, such as system serial number and Licensed Internal Code  level \nGLYPH<SM590000> Details of the error\nGLYPH<SM590000> Error logs that can help to resolve the problem\nAfter the Call Home is received by the assigned IBM support group, the associated  information is examined. Following analysis, an appropriate course of action is defined to  resolve the problem. For example, an IBM SSR might be sent to the site location to take the  corrective actions. Alternatively, the problem might be repaired or resolved remotely by IBM  support personnel through a broadband (if available) or telephone (if necessary) connection.\nThe TS3000 Total Storage System Console (TSSC) is the subsystem component responsible  for placing the service call or Call Home when necessary. Since model 93p and release  TSSC V4.7, only broadband connection is supported.\n2.2 Stand-alone cluster: Components, functions, and features\nIn general, any cluster can be used as a stand-alone cluster. The TS7700 features several  internal characteristics for High Availability (DDP RAID 6 protection, dual power supplies, and  so forth). However, a grid configuration can be configured for both more high availability (HA)  and Disaster Recovery (DR) functions with different levels of business continuance. For more  information, see Chapter 3, “IBM TS77 00 usage considerations” on page 109.\nIn this section, general information is provided about the components, functions, and features  that are used in a TS7700 environment. The general concepts and information are also  available in 2.2, “Stand-alone cluster: Components, functions, and features” on page 28. \nFor more information about deviations and the multi-cluster grid, see 2.4, “Multi-cluster grid  configurations: Components, functions, and features” on page 59.\n2.2.1 Views from the Host: Library IDs\nComposite library\nAll host interaction with tape data in a TS7700 is through virtual volumes and virtual tape  drives. \nYou must be able to identify the logical entity that represents the virtual drives and volumes,  but also address the single entity of a physical cluster. Therefore, two types of libraries are  available: a composite library and a distributed library. Each type is associated with a library  name and a Library ID.\nThe  composite library  is the logical image of the stand-alone cluster or grid that is presented  to the host. All logical volumes and virtual drives are associated with the composite library. In  a stand-alone TS7700, the host sees a logical tape library with up to 31 3490E tape CUs.  These CUs each have 16 IBM 3490E tape drives and are connected through 1 - 8 FICON  channels. The composite library is defined through the Interactive Storage Management  Facility (ISMF). A composite library is made up of one or more distributed libraries.\n28  IBM TS7700 Release 5.0 Guide"}]}
+{"image": "doclay/doclay_61108.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "200510079024. 1\na MH RB 3836/1527\n39\nLPM, AZALI, RHMH 200 BMBF RA P/AKH HRW, PNAS AA ALRET HAF AARER RA P/MARBE EZRAEEHAWRS. THEIR. mHLB, THMH00LTY Witt RRERREDHAR, RR-TREANHA. REWLT, EAA 700 TURAZREARRHEPHE-ASA, GC “MR” LE KPA RR. HMA 700 KPA FH PSAHAGRRY BT Hl, HABFFAMZLBAAE,\nBisa 7 RRA RAMA 700 2H KF 95 EBM A oe (te ER) WINE. EIN FAHETEHFZRAEUHTFAF (SAFR $l, HRA), HRA IS TRABRS 108 AFAAHSE ER. BMAP MIE HERYHRARRME. EELPREADSB wh, 100 LS 154 TERBSITS 702, KIT HR READ “OPW” 2a) HT PRR 704. TAARSSS 152 ¥ KSLITE 702.\nELLY FAP, RAMA 700 TH FORD 8) HARTE RU CLBARARKRIMART SHER SE OAR. Bite:\n@ Kalk Fi 702 G, TPMKRABN 704 TUARAMAH 700 KA Fh de 706. ZI 700 HHA Fh de 706 HT HARA NE R” 708.\n@ AFZAZH, RAM 700 THEARA TBR 708, RER FREE] 704 Ao TT HMR AEAM.\n@ HR “BR” 708, 7 BURA 704 HAF BN 712 RTF 710 4) BF Fe/RBH (RHE) WA.\no° ZH 70 TAEFFHNIA-TEFER TA DREHTE HERA PER,\n@ ZAM 700 LY MRM 718 RACER 716. blo, KAM #] 700 TERRA 718 Hew, wR, RAP BN 712 FARA SAM RAH.\noe SHAH 718 CARET AHERN, CHTUAKM 720, 38 40 KX FH LA 700.\noo S24 FR 12KATAERE, CHARAMH 700 R—-+Ai 722, HFK AMA 700."}]}
+{"image": "doclay/doclay_52389.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "MongoDB Documentation, Release 3.0.4\n11.2.7 Does MongoDB run on Amazon EBS?\n11.2.8 Why are MongoDB’s data files so large?\n11.2.9 How do I optimize storage use for small documents?\nSee also:\n$^{7}$https://docs.mongodb.org/ecosystem/platforms/amazon-ec2\nChapter 11. Frequently Asked Questions\n748\nShortening field names reduces expressiveness and does not provide considerable benefit for larger documents and where document overhead is not of significant concern. Shorter field names do not reduce the size of indexes, because indexes have a predefined structure.\n{ lname : \"Smith\", score : 3.9 }\nIn general it is not necessary to use short field names.\nIf you shorten the field named last_name to lname and the field named best_score to score , as follows, you could save 9 bytes per document.\n{ last_name : \"Smith\", best_score: 3.9 }\nMongoDB stores all field names in every document. For most documents, this represents a small fraction of the space used by a document; however, for small documents the field names may represent a proportionally large amount of space. Consider a collection of documents that resemble the following:\nYou can store any value in the _id field, but because this value serves as a primary key for documents in the collection, it must uniquely identify them. If the field’s value is not unique, then it cannot serve as a primary key as there would be collisions in the collection.\nTo optimize storage use, users can specify a value for the _id field explicitly when inserting documents into the collection. This strategy allows applications to store a value in the _id field that would have occupied space in another portion of the document.\nMongoDB clients automatically add an _id field to each document and generate a unique 12-byte ObjectId for the _id field. Furthermore, MongoDB always indexes the _id field. For smaller documents this may account for a significant amount of space.\nConsider the following suggestions and strategies for optimizing storage utilization for these collections:\nEach MongoDB document contains a certain amount of overhead. This overhead is normally insignificant but becomes significant if all documents are just a few bytes, as might be the case if the documents in your collection only have one or two fields.\nWhy are the files in my data directory larger than the data in my database? (page 774)\n• Use the _id field explicitly.\n• Use shorter field names.\nSee also:\nYes.\nMongoDB users of all sizes have had a great deal of success using MongoDB on the EC2 platform using EBS disks.\nAmazon EC2 7\nMongoDB aggressively preallocates data files to reserve space and avoid file system fragmentation. You can use the storage.smallFiles setting to modify the file preallocation strategy."}]}
+{"image": "doclay/doclay_23172.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "The Chairman of the Annual General Meeting will allow a reasonable opportunity for shareholders to ask questions about the  Company’s performance and operations and also ask questions of the external auditor concerning the conduct of the audit,  preparation and content of the Independent Auditor’s Report.\nRecommendation 7.1 of the revised Corporate Governance Council Principles provides that companies should establish policies  for the oversight and management of material business risks and disclose a summary of those policies. The Board of Directors  has overall responsibility for monitoring compliance and oversight of these policies along with ensuring that they are efficient and effective.\nCurrently, as part of the Group’s strategy to implement an integrated framework of control, the Board of Directors continually  identifies and monitors the key business and financial risks that could jeopardise the Group achieving its objectives. The Board of  Directors has and continues to develop appropriate controls to effectively manage those risks. A summary of the Company’s  policies for the oversight and management of material business risks follows:\nIn compliance with Recommendation 7.3, the Board of Directors encourages senior management level accountability for the  Company’s Annual Report by requiring the Executive Chairman and Chief Financial Officer to state in writing to the Board of  Directors that:\nRecommendation 7.2 of the revised Corporate Governance Council Principles provides that the Board of Directors should require  management to design and implement the risk management and internal control system to manage the Company’s material  business risks and report to it on whether those risks are being managed effectively. Throughout the financial year, the Company  has reviewed and where required improved risk management and internal compliance and control systems following reports from  senior management. The Company will continue to review and improve its risk management systems in conjunction with senior  management over the coming financial period.\nKaroon Gas Australia Ltd  Annual Report 2011\n91\n• the Annual Report is compiled in accordance with best practice and is properly monitored using the Audit Committee and the  external auditors to ensure a sound system of risk management and control.\n• the Company’s Annual Report presents a true and fair view, in all material respects, of the Company’s financial condition and  operational results and is in accordance with relevant Australian Accounting Standards; and\n• operational reporting is submitted to the Board of Directors at every Board meeting to ensure decisions are made in an efficient  and effective manner. Reports include reviews of current assets, potential acquisitions and general operational issues and/or  opportunities.\n• the Company protects its employees through the adoption of a Health, Safety and Environment Policy and travel insurance for  periods where employees are travelling on business, along with membership to emergency assistance and management for  an employee overseas; and\n• the Company offsets the risk of operational failures using appropriate insurance, with covers for third party liability, well control,  day-to-day office and business insurance and operator’s extra expense;\n• financial controls are set in place by the use of an authority matrix, general purchasing principles and approvals procedures. All  expenditure is closely monitored by the Audit Committee on behalf of the Board of Directors and reported on a quarterly basis.  The Chairman of the Audit Committee also works closely with the Company’s finance personnel prior to Board meetings in  order to understand financial risks and report such risks to the Board of Directors. Management accounts are prepared regularly  for the Board of Directors to ensure information congruence between management and the Board of Directors;\nRisk Assessment and Management\nManagement Accountability"}]}
+{"image": "doclay/doclay_52727.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Funeral Processions  Motorists, bicyclists, and pedestrians, \nEmergency Vehicles Motorists, bicyclists, and pedestrians \nFlorida’s Move Over Law  The Move Over Law protects law \nPublic Transit  All drivers shall yield the right-of-way \nMove Over Law \nOn a Multi-Lane Roadway \nCommercial Motor  Vehicles  Sharing the road with commercial motor \nRules for Motorists  1. Stay out of the “No Zone.” CMVs \nOn a Two-Lane Roadway \nEmergency Vehicles Motorists, bicyclists, and pedestrians  must yield the right-of-way to law  enforcement vehicles, fire engines, and  other emergency vehicles using sirens  or flashing lights. Pull over to the closest  edge of the roadway immediately and  stop until the emergency vehicle has  passed. Do not block intersections. \nFuneral Processions  Motorists, bicyclists, and pedestrians,  must yield the right-of-way to funeral  processions. When the funeral lead  vehicle enters an intersection, the  remaining vehicles in the funeral  procession may follow through the  intersection regardless of any traffic  control devices. All vehicles in the  procession should have their headlights  on (and may also use flashing hazard  lights) as a signal to other drivers not  to drive between or interfere with the  funeral procession. \nFlorida’s Move Over Law  The Move Over Law protects law  enforcement officers, emergency  workers, tow truck drivers, sanitation  workers, and utility workers stopped  along roadways while performing their  jobs. \nPublic Transit  All drivers shall yield the right-of-way  to public transit buses traveling in the  same direction that have signaled and  are reentering the traffic flow from a  specifically designated pullout bay. \nYou must vacate the lane closest to the  stationary law enforcement, emergency  vehicle, tow truck, sanitation, or utility  vehicle. (Signal your intention to  change lanes.) \nIf you cannot move over safely, you  must slow down to a speed of 20 MPH  below the posted speed limit. \nDrivers who are not in the lane closest  to the stationary vehicle should be  prepared to allow those who are about  to move over into their lane. \nVehicles  Sharing the road with commercial motor  vehicles (CMVs) such as semi trucks or  travel buses means abiding by different  rules and safety strategies. \nYou must slow down to a speed of 20  MPH below the posted speed limit. \nIf the speed limit is 20 MPH or less, you  must travel at 5 MPH. \nRules for Motorists  1. Stay out of the “No Zone.” CMVs  have large blind spots in front,  behind, and on both sides of the  vehicle. Even though large vehicles  have several rear-view mirrors,  other vehicles will be hidden from  view if within the “No Zone”/blind  spot.  2. Don’t tailgate; you’ll be in the rear \nspot.  2. Don’t tailgate; you’ll be in the rear  blind spot and may collide with the  CMV if it stops unexpectedly. \n44  ©2020 Florida Department of Highway Safety and Motor Vehicles "}]}
+{"image": "doclay/doclay_37100.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Performance Audit Report on the Control of F MD\nCHAPTER 4 \n4.0 FINDINGS \n4.1 PLANNING IN FMD CONTROL \n4.1.1 STRATEGIC PLANNING \nThe Performance Management System (PMS) in the Public Service requires that  Ministries and their Departments develop strategic plans which articulate what  they would deliver to the public during the six-year planning period. 27\nIt was observed during the audit that the DVS had not developed a  comprehensive long-term departmental strategic plan. Such a plan could provide  a clear direction for the department’s FMD control efforts, identifying objectives  and strategies to accomplish those objectives as well as outlining measurable  goals supported with realistic, quantifiable benchmarks for monitoring and  evaluating the department’s overall performance in the long term. Instead, the  DVS developed several strategy documents such as the Fence Strategy, Fence  Maintenance Strategy, the 2014/2015 Annual Performance Plan, the 2013  Surveillance Plan as well as the Annual Disease Surveillance Plan October 2014- March 2016. Such strategies lacked clear and measurable time bound objectives.  While such documents were adequately relevant to FMD control, it was  important to integrate them into a comprehensive Departmental plan in the form  of a strategic plan, which could serve as a blue print of the DVS commitment to  delivering on its mandate. Absence of a Departmental Strategic Plan was  attributed to an oversight of management on the need for it (strategic plan). This  oversight emanated from consideration that there was already a Ministerial  Strategic Plan in place. However, it should be noted that such a plan was to a  considerable extent generic and lacking clear focus on critical aspects of the  mandate of the DVS such as disease control.\n$^{27}$ PERFORMANCE MANAGEMENT IN THE BOTSWANA PUBLIC SERVICE- PUBLIC SERVICE REFORMS-BOTSWANA\n23 |  P a g e"}]}
+{"image": "doclay/doclay_26846.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "4.4 “End of Inflation” Mechanism\n78\nRearranging this for m$_{0}$ gives\nIf φ is light during primordial inflation, i.e. | m$_{φ,}$$_{inf}$ | ≪ $^{H}$∗ , our potential, Eq. (4.2), can receive an appreciable SUGRA correction during primordial inflation of [52–54]\nwhere $^{c}$∗ is a coupling constant. The SUGRA correction is appreciable only from the time of primordial inflation up until primordial inflation reheating, as it is suppressed at all times after this [54]. As the scale factor a grows (almost) exponentially during inflation, φ is driven rapidly to 0 , i.e. we have $^{φ}$∗ = 0 . Therefore the effective mass of φ during primordial inflation is\nIn order to keep this light we therefore need\nand\nCase C\nm$_{0}$ ≪ 100 √ M$_{P}$   $^{H}$$^{3}$$^{α}$$^{−}$$^{2}$ ∗$_{h}$ ( √$_{λ}$ M n $_{P}$H 2 ∗ ) 2 α$_{−}$ 1 n +2    1 2 α$_{−}$ 2 (4.130)\nΔ V ∼ $^{c}$∗H 2 ∗ φ 2 (4.131)\nm 2 φ, inf ∼ − m 2 0 + $^{c}$∗H 2 ∗ (4.132)\nm$_{0}$ ≪ $^{H}$∗ (4.133)\n$^{c}$∗ < 1 (4.134)"}]}
+{"image": "doclay/doclay_54005.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Securing Group Communication Connections with Secure Socket Layer (SSL)\nseparate. If you need to configure different allowlists to meet your security requirements, ensure that there is sufficient overlap between the allowlists in the replication group to maximize the possibility of servers being able to reconnect in the absence of their original seed member.\nFor host names, name resolution takes place only when a connection request is made by another server. A host name that cannot be resolved is not considered for allowlist validation, and a warning message is written to the error log. Forward-confirmed reverse DNS (FCrDNS) verification is carried out for resolved host names.\nHost names are inherently less secure than IP addresses in an allowlist. FCrDNS verification provides a good level of protection, but can be compromised by certain types of attack. Specify host names in your allowlist only when strictly necessary, and ensure that all components used for name resolution, such as DNS servers, are maintained under your control. You can also implement name resolution locally using the hosts file, to avoid the use of external components.\nSecure sockets can be used for group communication connections between members of a group. The Group Replication system variable  group_replication_ssl_mode  is used to activate the use of SSL for group communication connections and specify the security mode for the connections. The default setting means that SSL is not used. The option has the following possible values:\nThe remainder of the configuration for Group Replication’s group communication connections is taken from the server’s SSL configuration. For more information on the options for configuring the server SSL, see Command Options for Encrypted Connections. The server SSL options that are applied to Group Replication’s group communication connections are as follows:\nTable 18.3 SSL Options\nTable 18.2 group_replication_ssl_mode configuration values\nServer Configuration Description ssl_key The path name of the SSL private key file in PEM format. On the client side, this is the client private key. On the server side, this is the server private key.\nValue Description DISABLED Establish an unencrypted connection (the default). REQUIRED Establish a secure connection if the server supports secure connections. VERIFY_CA Like REQUIRED, but additionally verify the server TLS certificate against the configured Certificate Authority (CA) certificates. VERIFY_IDENTITY Like VERIFY_CA, but additionally verify that the server certificate matches the host to which the connection is attempted.\n3767\n18.6.2 Securing Group Communication Connections with Secure Socket Layer (SSL)\nWarning\n"}]}
+{"image": "doclay/doclay_1165.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "The table below shows our net pension expense for the years ended December 31, 2013 and 2012. Net interest cost is included in finance costs and other pension expenses are included in the salaries and benefits expense in the consolidated statements of income.\nWe also provide supplemental unfunded pension benefits to certain executives. The table below includes our accrued benefit obligations, pension expense included in employee salaries and benefits, net interest cost and other comprehensive income.\nCertain subsidiaries have defined contribution plans with total pension expense of $2 million in 2013 (2012 – $2 million), which is included in employee salaries and benefits expense.\nThere are significant assumptions that are used in the calculations provided by our actuaries, and it is the responsibility of management to determine which assumptions could result in a significant impact when determining the accrued benefit obligations and pension expense.\nWe estimate our 2014 employer contributions to be $96 million. The average duration of the defined benefit obligation at December 31, 2013 is 19 years.\nActual return on plan assets was $102 million in 2013 (2012 – $75 million).\nWe have recognized a cumulative loss in other comprehensive income and retained earnings of $201 million at December 31, 2013 (December 31, 2012 – $299 million).\nThe table below shows the actual contributions to the plans for the years ended December 31:\nWe make contributions to the plans to secure the benefits of plan members and invest in permitted investments using the target ranges established by our Pension Committee, which reviews actuarial assumptions on an annual basis.\nPlan assets consist primarily of pooled funds that invest in common stocks and bonds. The pooled Canadian equity funds has investments in our equity securities. As a result, approximately $3 million (2012 – $2 million) of the plans’ assets are indirectly invested in our own equity securities.\nIn the sensitivity analysis shown below, we determine the defined benefit obligation using the same method used to calculate the defined benefit obligation we recognize in the consolidated statements of financial position. We calculate sensitivity by changing one assumption while holding the others constant. The actual change in defined benefit obligation will likely be different from that shown in the table, since it is likely that more than one assumption will change at a time, and that some assumptions are correlated.\nSensitivity of Key Assumptions\nAllocation of Plan Assets\nAssumptions\nPrincipal Actuarial Assumptions\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS\n2013 2012 Plan cost: Service cost $ 71 $ 46 Net interest cost 12 5 Net pension expense 83 51 Administrative expense 2 2 Total pension cost recognized in net income $ 85 $ 53 Net interest cost, a component of the plan cost above is included in finance costs and is outlined as follows. 2013 2012 Net interest cost: Interest income on plan assets $ (40) $ (40) Interest cost on plan obligation 52 45 Net interest cost recognized in finance costs $1 2 $ 5\n2013 2012 Return on plan assets (excluding interest income) $ 65 $ 37 Change in financial assumptions 140 (220) Change in demographic assumptions (43) – Effect of experience adjustments (16) (49) Change in asset ceiling (9) – Remeasurement recognized in other comprehensive income (loss) and equity $ 137 $ (232)\ncost and other comprehensive income. 2013 2012 Accrued benefit obligation $4 9 $4 5 Pension expense included in employee salaries and benefits expense 2 2 Net interest cost recognized in finance costs 2 2 Remeasurement recognized in other comprehensive income 3 5\n2013 2012 Weighted average of significant assumptions: Defined benefit obligation Discount rate 5.1% 4.5% Rate of compensation increase 3.0% 3.0% Mortality rate CPM-RPP2014 Priv UP94 Generational Pension expense Discount rate 4.5% 5.5% Rate of compensation increase 3.0% 3.0% Mortality rate UP94 Generational UP94 Generational\nEmployer Employee Total 2013 $ 101 $ 26 $ 127 2012 85 23 108\nPercentage of plan assets Target asset allocation percentage Asset category December 31, 2013 December 31, 2012 Equity securities: Domestic 20.1% 19.3% 10% to 29% International 40.7% 38.3% 29% to 48% Debt securities 38.9% 41.8% 38% to 47% Other – cash 0.3% 0.6% 0% to 2% 100.0% 100.0%\n2013 ANNUAL REPORT ROGERS COMMUNICATIONS INC. 119\nThe remeasurement recognized in other comprehensive income, is determined as follows.\nIncrease/(decrease) in accrued benefit obligation Increase/(decrease) in pension expense 2013 2012 2013 2012 Discount rate Impact of: 0.5% increase $ (105) $ (99) $ (11) $ (11) 0.5% decrease 120 110 13 9 Rate of future compensation increase Impact of: 0.25% increase $ 14 $ 15 $ 3 $ 1 0.25% decrease (14) (15) (2) (3) Mortality rate Impact of: 1 year increase $ 26 $ 28 $ 4 $ 1 1 year decrease (27) (28) (3) (4)"}]}
+{"image": "doclay/doclay_19770.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "California Bank of Commerce\nNOTES TO FINANCIAL STATEMENTS\n1.  SUMMARY OF SIGNIFICANT ACCOUNTING POLICIES  (Continued)\nLoans (Continued)\nAllowance for Loan Losses\nGenerally, loans are restored to accrual status when the obligation is brought current and has  performed in accordance with the contractual terms for a reasonable period of time and the ultimate  collectability of the total contractual principal and interest is no longer in doubt. The policy for placing  loans on nonaccrual status, recording payments received on nonaccrual loans, resuming the accrual  of interest and determining past due or delinquency status, does not differ by portfolio segment or  class of financing receivable.\nAn impaired loan is measured based on the present value of expected future cash flows discounted  at the loan’s effective rate or, as a practical matter, at the loan’s observable market price or the fair  value of collateral less estimated costs to sell if the loan is collateral dependent. A loan is collateral  dependent if the repayment of the loan is expected to be provided solely by the underlying collateral. All loans are evaluated and considered impaired when, based on current information and events,  it is probable that the Bank will be unable to collect all amounts due (including both principal and  interest) in accordance with the contractual terms of the loan agreement. The policy for accounting  for impaired loans, recognizing interest on impaired loans and recording payments on impaired loans  is generally the same as that described above for nonaccrual loans, and does not differ by portfolio  segment or class of financing receivable.\nSubstantially all loan origination fees, commitment fees, direct loan origination costs and purchase  premiums and discounts on loans are deferred and recognized as an adjustment of yield, to be  amortized to interest income over the contractual term of the loan. The unamortized balance of  deferred fees and costs is reported as a component of net loans.\nThe Bank services loans that have been participated with other financial institutions totaling  approximately $6,879,000 and $3,856,000, respectively, as of December 31, 2011 and 2010. The  participated balances of these loans were sold without recourse and are not included on the Bank’s  balance sheet.\nThe allowance for loan losses is an estimate of credit losses inherent in the Bank’s loan portfolio that  have been incurred as of the balance-sheet date. The allowance is established through a provision  for loan losses which is charged to expense. Additions to the allowance are expected to maintain the  adequacy of the total allowance after credit losses and loan growth. Credit exposures determined to  be uncollectible are charged against the allowance. Cash received on previously charged off amounts  is recorded as a recovery to the allowance. The policy for charging off loans and recording recoveries  does not differ by portfolio segment or class of financing receivable. The overall allowance consists  of two primary components, specific reserves related to individually identified impaired loans and  general reserves for inherent losses related to loans that are collectively evaluated for impairment.\n18"}]}
+{"image": "doclay/doclay_39732.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "TENDER SPECIFICATIONS \nReference:  OC/EFSA/DATA/2021/01  Subject:  Provision of support to EFSA in the remit of scientific data management activities \nand processes Procurement procedure:  Open call (Article 164(1) (a) of the Financial Regulation)  Project/Process code:  E04.01.01 Data Collection and Management\nProcurement procedure:  Open call (Article 164(1) (a) of the Financial Regulation)  Project/Process code:  E04.01.01 Data Collection and Management\nAdditional guidance:  Please read the  EFSA Guidance for tenderers\nProvide EFSA with feedback: If you considered applying to this call for tenders but finally decided not to, please provide \nAdditional guidance:  Please read the  EFSA Guidance for tenderers  available on the EFSA website, designed  to assist potential tenderers in their understanding of EFSA procurement procedures. \nProvide EFSA with feedback: If you considered applying to this call for tenders but finally decided not to, please provide  EFSAProcurement@efsa.europa.eu  with your feedback on the call and reasons for not  applying. Feedback will be treated confidentially and will only be used for improving future  EFSA procurement calls. \n1 \nTender specifications purpose : 1. specify what EFSA will buy under the contract resulting from this procurement  procedure;  2. announce the criteria which EFSA will use to identify the successful contractor;\nprocedure;  2. announce the criteria which EFSA will use to identify the successful contractor; 3. guide tenderers in the preparation and sending of their offer; \n2. announce the criteria which EFSA will use to identify the successful contractor; 3. guide tenderers in the preparation and sending of their offer;  4. form annex 1 of the contract resulting from this procurement procedure and be \n3. guide tenderers in the preparation and sending of their offer;  4. form annex 1 of the contract resulting from this procurement procedure and be  binding for contract implementation.\nTender specifications purpose : 1. specify what EFSA will buy under the contract resulting from this procurement \nReference:  OC/EFSA/DATA/2021/01  Subject:  Provision of support to EFSA in the remit of scientific data management activities  and processes Procurement procedure:  Open call (Article 164(1) (a) of the Financial Regulation) "}]}
+{"image": "doclay/doclay_3572.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Basic English Language Skills\n•  Each paragraph should contain one main thought or idea, and there  should be a logical link between each paragraph and the next. Make sure that you focus on answering the question – only include \nshould be a logical link between each paragraph and the next. •  Make sure that you focus on answering the question – only include  relevant information, and remember to present logical arguments in  support of your answer.\nIn your assignments, you will often be asked to write short paragraphs or  longer essays in which you have to “explain” a particular concept, “iden- tify” certain features, or “prove” a certain point.\nIt’s sometimes difficult to figure out exactly what these questions mean  -- which is why we are providing you with the following explanations:\n8.  Proofread your assignment before handing it in.  Tip: read your  answers out loud to make sure that they sound logical.\n9.  Always keep a copy or electronic backup of your assignment. This way, you won’t have to start over if your computer crashes, or  redo the whole assignment if the original goes missing.\n10.  When you get your assignment back from your tutor: Read through the feedback, and learn from your mistakes.  This will  help you to prepare for your exams (if you have to write them), as well  as to help you achieve better marks in future assignments.\nTYPES OF QUESTIONS THAT YOU WILL FREQUENTLY COME  ACROSS IN ASSIGNMENTS"}]}
+{"image": "doclay/doclay_829.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "30 | EMPLOYEES\nFROM PENNSYLVANIA TO NEW MEXICO, WE THANK EVERY MEMBER OF TEAM CHESAPEAKE  »\nWe would like to thank each of Chesapeake’s 10,021 employees who brought a unique combination of experience, talent and positive attitude to the company in 2010. Last year the company was honored for the fourth consecutive year with inclusion  in the FORTUNE 100 Best Companies to Work For ®  list at #32, the highest-ranking company in the energy production industry.\n1989 (3)\n1990 (3)\n1991 (4)\n1996 (29)\n1998 (62)\n1992 (2)\n1993 (5)\n1994 (16)\n2001 (98)\n1999 (22)\n2000 (41)\n1997 (32)\n1995 (26)\n2002 (132)\n2003 (211)\nRonald Aaron Pat Abla Corky Baker StaciBarentine-Bogle Charlie Bateman Mike Bechtel John Biggs Tammi Bradford\nShawn Marsh Andrew McCalmont Mitch McNeill Richard Mieser Steve Mills Sidney Mitchell Claudia Molina de Wolford Nathan Morrison Todd Murphy Cindy Murray Jeff Newby Rick Nunley John Ortiz David Parker Robert Pennel Ryan Phillips Sharon Pool Bob Portman Eric Powell Mike L. Reddick Ronald Reidle Martin Robertson II A.D. Robison Randy Rodrigue Vern Roe Jr. Danny Schmidt Kary Schneberger Stacy Settles Dewayne Shaw Michael Sherwood Will Shisler Greg Skiles Chad Smith Robin Smith Maria Strain Josh Swift Chris Townsend Michelle Townsend Ryan Turner Rodney Vaeth Fred Vasquez Ruben Vega Jr. Al Warner James Warner Michael Weese Hazel Welch Leslie Wertz Eddie Whitehead John Wilken Gary Willeford Mark Willson Jerry Wilson Robert A. Wilson Roy Wilson\nLeonard Blackwill Paul Bowyer Troy Bradford Robert Bradley Don Bredy Jim Brock Cindy Brown Kathy Brown Lynn Broyles Jason Budde Greg Burchett Aaron Bush Ernest Byrd Chris Carter Paul Childers Jackie Cooper Jr. Lori Crabtree Cary Crusinbery Jr. James Davis Trent Delano Cheryl Delzer Cathy DeGiusti Larry Dill Sherry Dixon Eldon Eagan Eric S. Edwards Michael Falen Mark Falk Shawn Fields Tom Flesher Viel Flores Justin Foust Adam Gaskill Tamara Gathers Fred Gipson Lisa Glover Cornelio Gomez David Gouker Steve Hall Melvin Harper John Henry John Hornsby John Hurst Todd Ice Bud Jackson Jay Jarvis Danny Jech Jim Jinkins Gary D. Johnson William D. Johnson Chris Jones Joe Jones Mike Kee Dax Kimble Nancy Knox Greg Kochenower Jeremie Koehn Spencer Land Steve Larman Ricky Laster Casidy Lee Ken Leedy Stephen Lobaugh Billy Long\nPaula Abla Nicole Adams Jenny Adkins Roger Aldrich Jimmy Alexander Brian Babb Charlie Bagley Bob Baker Lynard Barrera Cindy Barrios Shane Barron Dennis Bass James Beavers Randy Bergen\nDaniel Koehn Kennetta Lee Jeff Lenocker Julia Lillard Darwin Lindenmuth Travis Long Rita Marple JimMcHenry Debbie McKee Don Messerly J. C. Morris MelindaNeher Lee Nelson Kevin Newberry Tim Newville Deborah O’Neal Ricky Petty Dianne Pickard Catherine Ratliff Lynn Regouby Gina Romano John Romine Larry Ross Mike Rossiter Larry Settle Dee Smith Jr. Patrick Smith Chris Sorrells Dennis Splan Jason Stamper Cindy Stevens Bill Stillwell Gary Stoner Howard Stout Tim N. Taylor Jason Thaxton Alvin Thomas Rudy Thomas Robbie Thrash Larry Watters Paige Whitehead Connie Williams Freda Williams Dawn Wilson Brandon Winsett Marvin Winter Jr. Larry Woodruff Amanda Young\nBrent Scruggs Vance Shires Stuart Skelton David W. Smith Catherine Stairs Jerry Townley Nick Wavers Brenda Wheeler Bob Whitman David Whitten Brent Williams Bob Woodside\nJerry Aebi Karen Albornoz Cranford Jeremy Allison Terry Ashton Betsy Ball Gloria Bates Michelle Bender Bruce Boeckman Boyce Boelen Sharon Bradford Von Brinkley Deanne Brooks Marty Byrd Carlos Caraveo Biff Carter John Carter Keith Case Marika Chambers Kristi Clemmens John Cook TimCook Juanita Cooper Jim Corsoro Leigh Ann Crain Brian Cunningham Garry Curry Shawn Downey Jeff Eager Richard Easterly Tommy Edler Amanda Elam Brian Exline Alex Gallardo Jr. Matt Gambill Roy Gentry Suzie Goolsby Randy Grayson Rick Green Kajsa Greenhoward Jackie Gross Johnny Harris Jeremiah Jackson Krista Jacobson Justin Johnson Keith Johnson Rob Jones John Kapchinske Ginni Kennedy Edward Killen Julie Knox\nShellie Ashworth Pollard Johnnie Bartlett Doug Bellis Jan Benton Bobby Bolton Jeff Brooks Becky Cassel Rachel Clapp Debbie Curtis Jennifer Dees Tammy Fields Robin Gonzalez Annie Hamilton Twila Hines Eric Hoffman Ronnie Howell Jim Kuhlman Don Lee Debbie Lloyd Jay May Jr. Andrea McCall Cindy McClintock Collin McElrath Courtney Moad Georgia Moller Chantelle Porter Edward Puffinbarger Mike Sawatzky Cindy Schwieger\nLinda Allen Karla Allford Sara Caldwell Steve Cody Kristine Conway Randy Cornelsen Michelle Cullen Bruce Dixon Greg Drwenski Mark B. Evans Joy Franklin Rob Gilkes Shane Hamilton Michael Horn Eric Hughes David B. Jones Mike Ludlow Sarah Lumen Lauren Matlock Sam McCaskill Bob Neely Bob Pope Erick Porter\nRichey Albright Paula Asher Eric Ashmore Randy Borlaug Shelli Butler Melissa Chambers Dale Cook Ted Davis Mandy Duane Steve Gaskins Jennifer Grigsby Gayle Harris HenryHood Lorrie Jacobs Barry Langham Cindy LeBlanc Leland Murray Fred Portillo\nStephen Adams Crae Barr Francy Beesley JoelBennett Leonard Berry Jr. Susan Bradford Mark Brown Randy Brown Lori Budde Terry Caldwell Bob Campbell Ted Campbell Sherri Childers Tana Clark Jennifer Copeland David Craycraft Iris Drake Mac Drake Gary Egger Steve Emick Dan Estes Dennis Frick Stacy Gilbert Jim Gowens Kelsey Hammit Tresa Hammond Jeff L. Harris Debbie Hulett Julie Ingram Tammy Kelln Rose Kim Steve King Mike Lancaster Chris H. Lee Carrie Lewis-Crawford Craig Madsen John Marshall Kim Massey Allen May DennisMcGee Allen A. Miller Bill Miller Carey Milligan David Mobley Wesley Myers Bud Neff Jr. Kathy Nowlin Don Pannell Michael Park Mandy Pena Matt Rockers Kelly Ruminer Greg Small\nJonathan Ball Mel Barker Sue Black DoryDouglas Mark Edge Jenny Ferguson Jeanie Fuller Susan Green YameiHou Doug Jacobson Jim Kelley Lynn Looper Dea Mengers Michael Miller Tammy Nguyen LaCosta Rawls Larry Shipley Michelle Smith Connie Turner Courtney Tyson Tonya Vallerand Tobin Yocham\nBill Snyder George Soto Dan Sparks Linda Steen Becky Thomas Jennifer Van Meir Rusty Walker Lynn Whipple Mandy Whipple\nJolene Schur Carolyn Simmons April Smith Wilma Smith Frank Unsicker Ivajean Wallace Craig White Dori Williams Curtis Williford\nJohn Qualls Pat Rolla Hank Scheel Charles W. Scholz Stan Stinnett Brenda Stremble Greg Weinschenk Brian Winter\nKinney Louthan Aubrey McClendon Patsy Watters\nKevin Decker David Higgins Cindi Williams\nSteve Dixon Marilyn Pollard Patti Schlegel Julie Washam\nHeather Anderson Jamie Carter Jasen Davis George Denny TimDenny Gary Dunlap Laurie Eck Jan Fair Barbara Frailey Linda Gardner Charlene Glover Randy Goben Jim Gomez Melissa Gruenewald Doug W. Johnson Jim Johnson Taylor Kemp Mike Lebsack Steve Lepretre Larry Lunardi John Marks Sandi Michalicka Liz Muskrat Angela Ports Tommy Putz Bryan Sagebiel Kurt Schrantz Phyllis Trammell Allan Waldroup\nBarbara Bale Martha Burger Michael Coles Traci Cook Ron Goff Greg Knight Dan LeDonne Rich McClanahan Steve W. Miller Tommy Morphew Pat Pope Danny Rutledge Stephanie Shedden Ronnie Ward Shelly White Gerald Zgabay\nRalph Ball David Desalvo Mike Johnson Randy Pierce Dave Wittman\nTom Price Melanie Weaver"}]}
+{"image": "doclay/doclay_65509.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "22. The method of claim 17, wherein the first plurality of signals and the second plurality of signals correspond to forces applied by corresponding portions of a user’s body.\n21. The method of claim 19, wherein identifying commands based at least partly on the second plurality of signals and the defined codes includes:\ndetermining a distance between the second plurality of signals to a command code based at least in part on the projection matrix; and\ncomparing the determined distance to a predetermined distance threshold."}]}
+{"image": "doclay/doclay_45327.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "A-2"}]}
+{"image": "doclay/doclay_23239.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "ADTRAN, INC. Consolidated Statements of Changes in Stockholders’ Equity  Years ended December 31, 2013, 2012 and 2011\n (In thousands) Common  Shares Common  Stock Additional  Paid-In  Capital Retained Earnings Treasury Stock Accumulated Other Comprehensive Income Total Stockholders’ Equity Balance, December 31, 2010 79,652 $797 $193,866 $731,962 $(381,251) $26,948 $572,322 Net income 138,577 138,577 Other comprehensive loss, net of tax (13,846) (13,846) Dividend payments (23,124) (23,124) Dividends accrued for unvested restricted stock units (52) (52) Stock options exercised (6,345) 40,470 34,125 Restricted stock units vested (812) 812 — Purchase of treasury stock: 1,112 shares (35,565) (35,565) Income tax benefit from exercise of stock options 10,525 10,525 Stock-based compensation expense 9,169 9,169 Balance, December 31, 2011 79,652 $797 $213,560 $840,206 $(375,534) $13,102 $692,131 Net income 47,263 47,263 Other comprehensive loss, net of tax (1,834) (1,834) Dividend payments (22,813) (22,813) Dividends accrued for unvested restricted stock units 15 15 Stock options exercised (2,659) 8,708 6,049 Restricted stock units vested (212) (547) 547 (212) Purchase of treasury stock: 1,786 shares (39,362) (39,362) Income tax benefit from exercise of stock options 1,905 1,905 Stock-based compensation expense 9,264 9,264 Balance, December 31, 2012 79,652 $797 $224,517 $861,465 $(405,641) $11,268 $692,406 Net income 45,794 45,794 Other comprehensive loss, net of tax (515) (515) Dividend payments (21,412) (21,412) Dividends accrued for unvested restricted stock units (23) (23) Stock options exercised (762) 4,391 3,629 Restricted stock units vested (248) (611) 611 (248) Purchase of treasury stock: 5,608 shares (124,267) (124,267) Income tax benefit from exercise of stock options 169 169 Stock-based compensation expense 9,073 9,073 Balance, December 31, 2013 79,652 $797 $233,511 $884,451 $(524,906) $10,753 $604,606\nWe issued 217 shares, 393 shares and 1,813 shares of treasury stock to accommodate employee stock option exercises, vesting of restricted stock, and vesting of restricted stock units during 2013, 2012 and 2011, respectively. During 2011, we  received 7 shares, previously held by employees for at least six months as payment of the exercise price for employee stock options. None of the transactions with respect to these shares were made in the open market. The average price paid per share with respect to these transactions was based on the closing price of the common stock on the NASDAQ Global Select Market on the date of the transaction. There were no such transactions during 2012 and 2013.\nSee notes to consolidated financial statements. \nADTRAN 2013 Annual Report 38"}]}
+{"image": "doclay/doclay_20491.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "44\nannual report 2012  kAThMANdu\n5  INCOME TAX EXPENSE\nGroup pArent 2012 nZ$’000 2011 nZ$’000 2012 nZ$’000 2011 nZ$’000 Income statement Current income tax charge 17,053 17,237 (154) (339) Deferred income tax charge (refer note 15) (779) 914 - 445 Income tax charge / (credit) reported in income statement 16,274 18,151 (154) 106 reconciliation of effective tax charge Profit before income tax 51,126 57,217 18,127 18,522 Income tax calculated at 28% (2011: 30%) 14,315 17,165 5,075 5,557 Adjustments to taxation: Adjustments due to different rate in different jurisdictions 654 51 - - Non-taxable income - - (5,600) (6,000) Expenses not deductible for tax purposes 946 967 31 189 Effect of change in corporate tax rate - 13 - (5) Utilisation of tax losses by group companies - - - 365 Tax expense transferred to foreign currency translation reserve 464 202 - - Adjustments in respect of prior years (105) (247) 340 - Income tax charge / (credit) reported in income statement 16,274 18,151 (154) 106\nunrecognised tax losses\nthe group has estimated tax losses to carry forward from Kathmandu (u.K.) limited of £7,290,184 (nZ$14,350,756) (2011:  £5,743,723 (nZ$12,016,157)) which can be carried forward to be offset against future profits generated within the uK.\nthe above amounts represent the balance of the imputation account as at the end of July 2012, adjusted for:\nthe balance of australian franking credits able to be used by the Group as at 31 July 2012 is a$3,369,445 (2011: a$836,783).\nImputAtIon CreDItS Group pArent 2012 nZ$’000 2011 nZ$’000 2012 nZ$’000 2011 nZ$’000 Imputation credits available for use in subsequent reporting periods 3,554 4,479 (1) -\nImputation credits that will arise from the payment of the amount of the provision for income tax;\nImputation debits that will arise from the payment of dividends recognised as a liability at the reporting date; and\nImputation credits that will arise from the receipt of dividends recognised as receivables at the reporting date. \n"}]}
+{"image": "doclay/doclay_1940.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "FIG. 10: (Color online) ISGDR strength distributions obtained for the Sn isotopes in the present experiment. Error bars represent the uncertainties from fitting the angular distributions in the MDA procedure. The solid lines show Lorentzian fits to the data.\nFig. 9; the corresponding fitting parameters are presented in Table III and compared with results from TAMU [19, 21]. In this and subsequent comparisons and discussion, we refer only to the recent TAMU results because those are from comparable data and analysis—all other previous results on the Sn isotopes were from peak-fitting analyses of data taken at significantly lower energies.\nIn order to compare with the available theoretical results, various moment ratios for the experimental ISGMR strength distributions have been calculated over the excitation-energy range, E$_{x}$ = 10.5–20.5 MeV, encompassing the ISGMR peak. The results are listed in Table IV. The reasons for the difference between the present results and those from TAMU for $^{112}$Sn and $^{124}$Sn are not readily apparent but might be attributable to the fact that in their analysis the multipole decomposition is carried out after subtracting a “background” from the excitation-energy spectrum, whereas, as pointed out earlier, no such subtraction is required in the present analysis since the Sn( α, α $^{′}$) spectra obtained in our work have been rendered free of all instrumental background events.\n14\n"}]}
+{"image": "doclay/doclay_23920.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Annual Report 2013 67\nWe record revenue, expenses and assets net of the amount of Goods and Services Tax (GST) except:\nThe net amount of GST recoverable from, or payable to, the taxation authority is included as part of receivables or payables in the statement of  financial position� \nCash flows are included in the statement of cash flows on a gross basis and the GST component of cash flows arising from investing and financing  activities, which is recoverable from, or payable to, the taxation authority is classified as part of operating cash flows� \nCommitments and contingencies are disclosed net of the amount of GST recoverable from, or payable to, the taxation authority�\nBasic earnings per share is calculated as net profit attributable to ordinary shareholders, adjusted to exclude any costs of servicing equity (other  than dividends), divided by the weighted average number of ordinary shares outstanding during the period� \nDiluted earnings per share adjusts the figures used in the determination of basic earnings per share to take into account: \n„ the after tax effect of interest and other financing costs associated with dilutive potential ordinary shares that have been recognised as  expenses, and \n„ the weighted average number of additional ordinary shares that would have been outstanding assuming the conversion of all dilutive potential  ordinary shares�\n„ When the GST incurred on a purchase of goods and services is not recoverable from the taxation authority, in which case the GST is  recognised as part of the cost of acquisition of the asset or as part of the expense item as applicable�\n„ Receivables and payables, which are stated with the amount of GST included�\n3. SUMMARY OF SIGNIFICANT ACCOUNTING POLICIES (CONTINUED)\n(t) Income tax and other taxes (continued)\n(u) Earnings per share\n(ii) Other taxes\n(i) Basic earnings per share\n(ii) Diluted earnings per share\nNOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS CONT"}]}
+{"image": "doclay/doclay_67719.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "8860ch03.fm\nDraft Document for Review September 23, 2019 1:17 am\n11.On the following panel select channel path type  CIB as show in Figure 3-8\nFigure 3-8 Filter Channel Path type: Type CIB for channel path type\nChapter 3. Preparing for a new z15  39\nGoto Filter Backup Query Help ----- +-------------------------------------+ ------------------------------ | 1 1. Set Filter | t Row 1 of 86 More: Comma | 2. Clear Filter | ______________ Scroll ===> CSR | 3. Count rows on (filtered) list | Selec +-------------------------------------+ nter. To add use F11. Processor ID . . . . : ARIES Cetus Configuration mode . : LPAR Channel Subsystem ID : 0 CHID+ Dyn Entry + / CHPID AID/P Type+ Mode+ Sw+ Sw Port Con Mng Description _ 10 1B0 FC SPAN 01 01 1C No Z15B-LG16-D1 TS7700 _ 11 120 FC SPAN 01 01 26 No Z22B-LG11-D1 TS7700 _ 12 1B1 FC SPAN 02 02 1C No Z15B-LG16-D2 TS7700 _ 13 121 FC SPAN 02 02 26 No Z22B-LG11-D2 TS7700 _ 22 100 FCP SHR __ __ __ No Z22B-LG01-D1 SAN64-K-p44 _ 23 180 FCP SHR __ __ __ No Z15B-LG01-D1 SAN64-L-p44 _ 24 101 FCP SHR __ __ __ No Z22B-LG01-D2 SAN64-K-p45 _ 25 181 FCP SHR __ __ __ No Z15B-LG01-D2 SAN64-L-p45 _ 26 12C FCP SHR __ __ __ No Z22B-LG14-D1 SAN64-K-p46 _ 27 19C FCP SHR __ __ __ No Z15B-LG09-D1 SAN64-L-p46 \n+----------------------- Filter Channel Path List ------------------------+ | | | | | Specify or revise the following filter criteria. | | | | Channel path type .  CIB | | Operation mode . . . ____ + | | Managed . . . . . . _ (Y = Yes; N = No) I/O Cluster ________ + | | Dynamic entry switch __ + | | Entry switch . . . . __ + | | CF connected . . . . _ (Y = Connected; N = Not connected) | | CHID AID/P PCHID/P _____ | | | | Description . . . . ________________________________ | | | | Partition . . . . . ________ + | | Connected to CUs . . _ (Y = Connected; N = Not connected) | | | | | | | | | +-------------------------------------------------------------------------+\nFigure 3-7 Channel Path List: Set Filter"}]}
+{"image": "doclay/doclay_72232.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS OF AMERICAN AIRLINES, INC.\nBenefit Obligations, Fair Value of Plan Assets and Funded Status\nThe following tables provide a reconciliation of the changes in the pension and retiree medical and other postretirement benefits obligations, fair value of plan assets and a statement of funded status as of December 31, 2019 and 2018:\n$^{(1)}$  The 2019 and 2018 pension actuarial (gain) loss primarily relates to changes in American’s weighted average discount rate and mortality assumption and, in 2018, changes to American’s retirement rate assumptions.\n$^{(2)}$  The 2019 retiree medical and other postretirement benefits actuarial loss primarily relates to changes in American’s weighted average discount rate assumption and plan experience adjustments.\nThe 2018 retiree medical and other postretirement benefits actuarial gain primarily relates to changes in American’s weighted average discount rate, medical trend and per capita claims assumptions.\n$^{(3)}$  During 2019, American contributed $1.2 billion to its defined benefit pension plans, including supplemental contributions of $444 million and a $780 million minimum required contribution. During 2018, American contributed $472 million to its defined benefit pension plans, including supplemental contributions of $433 million and a $39 million minimum required contribution.\n142\nPension Benefits Retiree Medical and Other Postretirement Benefits 2019 2018 2019 2018 (In millions) Benefit obligation at beginning of period $ 16,282 $ 18,175 $ 837 $ 1,010 Service cost 2 2 3 5 Interest cost 699 670 33 35 Actuarial (gain) loss  (1), (2) 1,951 (1,905) 20 (132) Settlements (2 ) (4 ) — — Benefit payments (686) (659) (74) (81) Other — 3 5 — Benefit obligation at end of period $ 18,246 $ 16,282 $ 824 $ 837\nPension Benefits Retiree Medical and Other Postretirement Benefits 2019 2018 2019 2018 (In millions) Fair value of plan assets at beginning of period $ 10,001 $ 11,340 $ 225 $ 295 Actual return (loss) on plan assets 2,292 (1,148) 41 (24) Employer contributions  (3) 1,224 472 12 35 Settlements (2) (4) — — Benefit payments (686 ) (659 ) (74 ) (81 ) Fair value of plan assets at end of period $ 12,829 $ 10,001 $ 204 $ 225 Funded status at end of period $ (5,417 ) $ (6,281 ) $ (620 ) $ (612 )"}]}
+{"image": "doclay/doclay_70810.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "77\nб) дополнить новыми строками следующего содержания:\n»;\n2) в пункте 3.3:\n«\n»\nзаменить строкой\n«\n».\n60. В федеральном государственном образовательном стандарте высшего образования – бакалавриат по направлению подготовки 12.03.03 Фотоника и оптоинформатика, утвержденном приказом Министерства образования и науки Российской Федерации от 19 сентября 2017 г. № 949 (зарегистрирован Министерством юстиции Российской Федерации 9 октября 2017 г., регистрационный № 48479), с изменениями, внесенными приказом Министерства науки и высшего образования Российской Федерации от 8 февраля 2021 г № 83 (зарегистрирован Министерством юстиции Российской Федерации 12 марта 2021 г., регистрационный № 62739):\n« | Экономическая культура, в том числе финансовая рамотность УК-9. Способен принимать обоснованные экономические решения в различных областях жизнедеятельности УК-10. Способен формировать нетерпимое отношение к коррупционному поведению Гражданская ПОЗИЦИЯ\nстроку ОПК-4. Способен использовать современные информационные технологии и программное обеспечение при решении задач профессиональной деятельности, соблюдая требования информационной безопасности Использование информационных технологий\nстроку\nОПК-4. Способен понимать принципы работы современных информационных технологий и использовать их для решения задач профессиональной деятельности Использование информационных технологий"}]}
+{"image": "doclay/doclay_47271.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "S T A T U T O R Y I N S T R U M E N T S\n2020 No. 463 \nAGRICULTURE \nThe Direct Payments to Farmers (Legislative Continuity) Act  2020 (Consequential Amendments) Regulations 2020 \nThe Secretary of State, in exercise of the powers conferred by section 6(1) of the Direct Payments  to Farmers (Legislative Continuity) Act 2020( a ), makes the following Regulations. \nIn accordance with section 6(5) of the Direct Payments to Farmers (Legislative Continuity) Act  2020, the Secretary of State has obtained consent from the Scottish Ministers, Welsh Ministers  and the Department of Agriculture, Environment and Rural Affairs in Northern Ireland. \n1. —(1) These Regulations may be cited as the Direct Payments to Farmers (Legislative  Continuity) Act 2020 (Consequential Amendments) Regulations 2020 and come into force on 30th  April 2020. \n(2) Any provision of these Regulations which amends an enactment has the same extent as the  enactment amended. \nMade - - - - 27th April 2020  Laid before Parliament 28th April 2020  Coming into force - - 30th April 2020 \nCitation, commencement and extent \nAmendment of the Interpretation Act 1978 \n2. —(1) The Interpretation Act 1978( b ) is amended as follows. \n(2) In section 21(1), after “any Act” (but before the words to be inserted at the same place by  paragraph 19 of Schedule 8 to the European Union (Withdrawal) Act 2018)( c ) insert “or made or  to be made on or after exit day under retained direct EU CAP legislation as defined in section 2 of  the Direct Payments to Farmers (Legislative Continuity) Act 2020”. \n(3) In section 23ZA(4)(a)— \n(a) in sub-paragraph (i), omit “or”; \n(b) after that sub-paragraph insert— \n( a ) 2020 c. 2. \n( b ) 1978 c. 30. Section 21(1) is amended by paragraph 19 of Schedule 8 to the European Union (Withdrawal) Act 2018 and  paragraph 10 of Schedule 5 to the European Union (Withdrawal Agreement) Act 2020 (c. 1). Section 23ZA was inserted by  paragraph 20 of Schedule 8 to the European Union (Withdrawal) Act 2018 and amended by paragraph 11 of Schedule 5 to  the European Union (Withdrawal Agreement) Act 2020. \n( c ) 2018 c. 16. "}]}
+{"image": "doclay/doclay_74258.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "PUBLIC LAW 116–22—JUNE 24, 2019 \n133 STAT. 951 \nvendor within 90 days of a determination by the Secretary to  renew, extend, or terminate such contract.’’. \nSection 565(f) of the Federal Food, Drug, and Cosmetic Act  (21 U.S.C. 360bbb–4(f)) is amended—  (1) by redesignating paragraphs (3) through (6) as para-\n(21 U.S.C. 360bbb–4(f)) is amended—  (1) by redesignating paragraphs (3) through (6) as para- graphs (4) through (7), respectively;  (2) by inserting after paragraph (2) the following: \nSEC. 503. AVAILABILITY OF REGULATORY MANAGEMENT PLANS. \nWeb posting. \ngraphs (4) through (7), respectively;  (2) by inserting after paragraph (2) the following:  ‘‘(3) PUBLICATION.—The Secretary shall make available on \n(2) by inserting after paragraph (2) the following:  ‘‘(3) PUBLICATION.—The Secretary shall make available on  the internet website of the Food and Drug Administration  information regarding regulatory management plans, including—  ‘‘(A) the process by which an applicant may submit \nincluding—  ‘‘(A) the process by which an applicant may submit  a request for a regulatory management plan;  ‘‘(B) the timeframe by which the Secretary is required \na request for a regulatory management plan;  ‘‘(B) the timeframe by which the Secretary is required  to respond to such request;  ‘‘(C) the information required for the submission of \nto respond to such request;  ‘‘(C) the information required for the submission of  such request;  ‘‘(D) a description of the types of development mile-\nsuch request;  ‘‘(D) a description of the types of development mile- stones and performance targets that could be discussed  and included in such plans; and  ‘‘(E) contact information for beginning the regulatory \nand included in such plans; and  ‘‘(E) contact information for beginning the regulatory  management plan process.’’;  (3) in paragraph (6), as so redesignated, in the matter \nmanagement plan process.’’;  (3) in paragraph (6), as so redesignated, in the matter  preceding subparagraph (A)—  (A) by striking ‘‘paragraph (4)(A)’’ and inserting ‘‘para-\npreceding subparagraph (A)—  (A) by striking ‘‘paragraph (4)(A)’’ and inserting ‘‘para- graph (5)(A)’’; and  (B) by striking ‘‘paragraph (4)(B)’’ and inserting ‘‘para-\ngraph (5)(A)’’; and  (B) by striking ‘‘paragraph (4)(B)’’ and inserting ‘‘para- graph (5)(B)’’; and  (4) in paragraph (7)(A), as so redesignated, by striking \ngraph (5)(B)’’; and  (4) in paragraph (7)(A), as so redesignated, by striking  ‘‘paragraph (3)(A)’’ and inserting ‘‘paragraph (4)(A)’’. \nSEC. 505. ADDITIONAL STRATEGIES FOR COMBATING ANTIBIOTIC  RESISTANCE. \nSEC. 504. THE BIOMEDICAL ADVANCED RESEARCH AND DEVELOP- MENT AUTHORITY AND THE BIOSHIELD SPECIAL RESERVE  FUND. \n(a) BIOSHIELD SPECIAL RESERVE FUND.—Section 319F–2(g)(1)  (42 U.S.C. 247d–6b(g)(1)) is amended—  (1) by striking ‘‘$2,800,000,000 for the period of fiscal years \n(42 U.S.C. 247d–6b(g)(1)) is amended—  (1) by striking ‘‘$2,800,000,000 for the period of fiscal years  2014 through 2018’’ and inserting ‘‘$7,100,000,000 for the period  of fiscal years 2019 through 2028, to remain available until  expended’’; and  (2) by striking the second sentence. \nexpended’’; and  (2) by striking the second sentence.  THE BIOMEDICAL ADVANCED RESEARCH AND DEVELOPMENT \n(2) by striking the second sentence.  (b) THE BIOMEDICAL ADVANCED RESEARCH AND DEVELOPMENT  AUTHORITY.—Section 319L(d)(2) (42 U.S.C. 247d–7e(d)(2)) is  amended by striking ‘‘$415,000,000 for each of fiscal years 2014  through 2018’’ and inserting ‘‘$611,700,000 for each of fiscal years  2019 through 2023’’. \n(a) ADVISORY COUNCIL.—The Secretary of Health and Human  Services (referred to in this section as the ‘‘Secretary’’) may continue  the Presidential Advisory Council on Combating Antibiotic-Resist- ant Bacteria, referred to in this section as the ‘‘Advisory Council’’.  (b) DUTIES.—The Advisory Council shall advise and provide \nant Bacteria, referred to in this section as the ‘‘Advisory Council’’.  (b) DUTIES.—The Advisory Council shall advise and provide  information and recommendations to the Secretary regarding pro- grams and policies intended to reduce or combat antibiotic-resistant \nRecommenda-  tions. \nContinuation. \n42 USC 247d–5  note. "}]}
+{"image": "doclay/doclay_56609.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "lock ranges of index records and  gaps , with each transaction acquiring some locks but not others due to a timing issue.\n A mechanism that automatically detects when a  deadlock  occurs, and automatically  rolls back  one of the transactions  involved (the  victim ). Deadlock detection can be disabled using the  innodb_deadlock_detect configuration option.\nSee Also deadlock, rollback, transaction, victim.\n When  InnoDB  processes a  DELETE  statement, the rows are immediately marked for deletion and no longer are returned by queries. The storage is reclaimed sometime later, during the periodic garbage collection known as the  purge  operation. For removing large quantities of data, related operations with their own performance characteristics are  TRUNCATE  and  DROP .\nSee Also drop, purge, truncate.\n The technique of storing changes to secondary index pages, resulting from  DELETE  operations, in the  change buffer  rather than writing the changes immediately, so that the physical writes can be performed to minimize random I/O. (Because delete operations are a two-step process, this operation buffers the write that normally marks an index record for deletion.) It is one of the types of  change buffering ; the others are  insert buffering and  purge buffering .\nSee Also change buffer, change buffering, insert buffer, insert buffering, purge buffering.\n A data storage strategy that duplicates data across different tables, rather than linking the tables with  foreign keys  and  join  queries. Typically used in  data warehouse  applications, where the data is not updated after loading. In such applications, query performance is more important than making it simple to maintain consistent data during updates. Contrast with  normalized .\nSee Also data warehouse, foreign key, join, normalized.\n A type of  index  where index storage is optimized to process  ORDER BY  column  DESC  clauses. See Also index.\n The dictionary object cache stores previously accessed  data dictionary  objects in memory to enable object reuse and minimize disk I/O. An  LRU -based eviction strategy is used to evict least recently used objects from memory. The cache is comprised of several partitions that store different object types.\nFor more information, see Section 14.4, “Dictionary Object Cache” . See Also data dictionary, LRU.\n A  page  in the  InnoDB buffer pool  that has been updated in memory, where the changes are not yet written ( flushed ) to the  data files . The opposite of a  clean page . See Also buffer pool, clean page, data files, flush, page.\n An operation that retrieves unreliable data, data that was updated by another transaction but not yet  committed . It is only possible with the  isolation level  known as  read uncommitted .\nFor background information on how deadlocks are automatically detected and handled, see Section 15.7.5.2, “Deadlock Detection” . For tips on avoiding and recovering from deadlock conditions, see Section 15.7.5.3, “How to Minimize and Handle Deadlocks” .\nSee Also gap, lock, transaction.\n6147\ndeadlock detection\ndelete\ndelete buffering\ndenormalized\ndescending index\ndictionary object cache\ndirty page\ndirty read"}]}
+{"image": "doclay/doclay_20983.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "For purposes of this discussion, “MetLife,” the “Company,” “we,” “our” and “us” refer to MetLife, Inc., a Delaware corporation incorporated in 1999, its subsidiaries and affiliates. Following this summary is a discussion addressing the consolidated results of operations and financial condition of the Company for the periods indicated. This discussion should be read in conjunction with “Note Regarding Forward-Looking Statements,” “Selected Financial Data” and the Company’s consolidated financial statements included elsewhere herein, and “Risk Factors” included in MetLife’s Annual Report for the year ended December 31, 2012 (the “2012 Form 10-K”).\nThis Management’s Discussion and Analysis of Financial Condition and Results of Operations may contain or incorporate by reference information that includes or is based upon forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. Forward-looking statements give expectations or forecasts of future events. These statements can be identified by the fact that they do not relate strictly to historical or current facts. They use words such as “anticipate,” “estimate,” “expect,” “project,” “intend,” “plan,” “believe” and other words and terms of similar meaning in connection with a discussion of future operating or financial performance. In particular, these include statements relating to future actions, prospective services or products, future performance or results of current and anticipated services or products, sales efforts, expenses, the outcome of contingencies such as legal proceedings, trends in operations and financial results. Any or all forward-looking statements may turn out to be wrong. Actual results could differ materially from those expressed or implied in the forward-looking statements. See “Note Regarding Forward-Looking Statements.”\nThis Management’s Discussion and Analysis of Financial Condition and Results of Operations includes references to our performance measures, operating earnings and operating earnings available to common shareholders, that are not based on accounting principles generally accepted in the United States of America (“GAAP”). Operating earnings is the measure of segment profit or loss we use to evaluate segment performance and allocate resources. Consistent with GAAP accounting guidance for segment reporting, operating earnings is our measure of segment performance. Operating earnings is also a measure by which senior management’s and many other employees’ performance is evaluated for the purposes of determining their compensation under applicable compensation plans. See “— Non-GAAP and Other Financial Disclosures” for definitions of such measures.\nForward-Looking Statements and Other Financial Information\nExecutive Summary\nMetLife is a leading global provider of insurance, annuities and employee benefit programs throughout the United States, Japan, Latin America, Asia, Europe and the Middle East. Through its subsidiaries and affiliates, MetLife offers life insurance, annuities, property & casualty insurance, and other financial services to individuals, as well as group insurance and retirement & savings products and services to corporations and other institutions.\nMetLife is organized into six segments, reflecting three broad geographic regions: Retail; Group, Voluntary & Worksite Benefits; Corporate Benefit Funding; and Latin America (collectively, the “Americas”); Asia; and Europe, the Middle East and Africa (“EMEA”). In addition, the Company reports certain of its results of operations in Corporate & Other, which includes MetLife Bank, National Association (“MetLife Bank”) (see Note 3 of the Notes to the Consolidated Financial Statements for information regarding MetLife Bank’s exit from certain of its businesses (the “MetLife Bank Divestiture”)) and other business activities. Management continues to evaluate the Company’s segment performance and allocated resources and may adjust related measurements in the future to better reflect segment profitability.\nOn November 1, 2010 (the “ALICO Acquisition Date”), MetLife, Inc. completed the acquisition of American Life Insurance Company (“American Life”) from AM Holdings LLC (formerly known as ALICO Holdings LLC) (“AM Holdings”), a subsidiary of American International Group, Inc. (“AIG”), and Delaware American Life Insurance Company (“DelAm”) from AIG (American Life, together with DelAm, collectively, “ALICO”) (the “ALICO Acquisition”). The assets, liabilities and operating results relating to the ALICO Acquisition are included in the Latin America, Asia and EMEA segments. See Note 3 of the Notes to the Consolidated Financial Statements.\nCertain international subsidiaries have a fiscal year-end of November 30. Accordingly, the Company’s consolidated financial statements reflect the assets and liabilities of such subsidiaries as of November 30, 2012 and 2011 and the operating results of such subsidiaries for the years ended November 30, 2012, 2011 and 2010.\nWe continue to experience an increase in sales in several of our businesses; however, global economic conditions continue to negatively impact the demand for some of our products. Portfolio growth, resulting from strong sales in the majority of our businesses, drove positive investment results and higher asset-based fee revenue. Changes in interest rates and the impact of the nonperformance risk adjustment on variable annuity embedded derivatives resulted in significant derivative losses. In addition, a goodwill impairment charge was recorded in the current year, as well as a charge associated with the global review of assumptions related to deferred policy acquisition costs (“DAC”), reserves and certain intangibles.\nYears Ended December 31, 2012 2011 2010 (In millions) Income (loss) from continuing operations, net of income tax ............................. $1,314 $ 6,391 $ 2,619 Less: Net investment gains (losses) ................................................ (352) (867) (408) Less: Net derivative gains (losses) ................................................. (1,919) 4,824 (265) Less: Goodwill impairment ....................................................... (1,868) — — Less: Other adjustments to continuing operations (1) .................................. (2,550) (1,451) (708) Less: Provision for income tax (expense) benefit ...................................... 2,195 (914) 304 Operating earnings ............................................................. 5,808 4,799 3,696 Less: Preferred stock dividends ................................................... 122 122 122 Operating earnings available to common shareholders ................................. $5,686 $ 4,677 $ 3,574\n(1) See definitions of operating revenues and operating expenses for the components of such adjustments.\nYear Ended December 31, 2012 Compared with the Year Ended December 31, 2011\nDuring the year ended December 31, 2012, income (loss) from continuing operations, net of income tax, decreased $5.1 billion from the prior year. The change was predominantly due to a $6.7 billion ($4.4 billion, net of income tax), unfavorable change in net derivative gains (losses) primarily driven by changes in interest rates, the weakening of the U.S. dollar and Japanese yen, equity market movements, decreased volatility and the impact of a\nMetLife, Inc.\n6"}]}
+{"image": "doclay/doclay_61416.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "EP 3 800 011 A1\nFIG. 1\n11\n"}]}
+{"image": "doclay/doclay_43236.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "8/15/19 1/30/20 \nPilot/Controller Glossary Pilot/Controller Glossary \ntraffic rules, unless otherwise authorized by air traffic  control. Not all areas listed in 14 CFR Part 93 are  designated SFRA, but special air traffic rules apply to  all areas described in 14 CFR Part 93. \nSPECIAL USE AIRSPACE- Airspace of defined  dimensions identified by an area on the surface of the  earth wherein activities must be confined because of  their nature and/or wherein limitations may be  imposed upon aircraft operations that are not a part of  those activities. Types of special use airspace are: \n(See INSTRUMENT APPROACH PROCEDURE.) \na.  Alert Area- Airspace which may contain a high  volume of pilot training activities or an unusual type  of aerial activity, neither of which is hazardous to  aircraft. Alert Areas are depicted on aeronautical  charts for the information of nonparticipating pilots.  All activities within an Alert Area are conducted in  accordance with Federal Aviation Regulations, and  pilots of participating aircraft as well as pilots  transiting the area are equally responsible for  collision avoidance. \nb.  Controlled Firing Area- Airspace wherein  activities are conducted under conditions so  controlled as to eliminate hazards to nonparticipating  aircraft and to ensure the safety of persons and  property on the ground. \nc.  Military Operations Area (MOA)- Permanent  and temporary MOAs are airspace established  outside of Class A airspace area to separate or  segregate certain nonhazardous military activities  from IFR traffic and to identify for VFR traffic where  these activities are conducted. Permanent MOAs are  depicted on Sectional Aeronautical, VFR Terminal  Area, and applicable En Route Low Altitude Charts. \nNote: Temporary MOAs are not charted. \n(Refer to AIM.) \nd.  Prohibited Area- Airspace designated under  14 CFR Part 73 within which no person may operate  an aircraft without the permission of the using  agency. \n(Refer to AIM.) \n(Refer to En Route Charts.) \ne.  Restricted Area- Permanent and temporary  restricted areas are airspace designated under 14 CFR  Part 73, within which the flight of aircraft, while not  wholly prohibited, is subject to restriction. Most \nrestricted areas are designated joint use and IFR/VFR  operations in the area may be authorized by the  controlling ATC facility when it is not being utilized  by the using agency. Permanent restricted areas are  depicted on Sectional Aeronautical, VFR Terminal  Area, and applicable En Route charts. Where joint  use is authorized, the name of the ATC controlling  facility is also shown. \nNote: Temporary restricted areas are not charted. \n(Refer to 14 CFR Part 73.) \n(Refer to AIM.) \nf.  Warning Area- A warning area is airspace of  defined dimensions extending from 3 nautical miles  outward from the coast of the United States, that  contains activity that may be hazardous to  nonparticipating aircraft. The purpose of such  warning area is to warn nonparticipating pilots of the  potential danger. A warning area may be located over  domestic or international waters or both. \nSPECIAL VFR CONDITIONS- Meteorological  conditions that are less than those required for basic  VFR flight in Class B, C, D, or E surface areas and  in which some aircraft are permitted flight under  visual flight rules. \n(See SPECIAL VFR OPERATIONS.) \n(Refer to 14 CFR Part 91.) \nSPECIAL VFR FLIGHT [ICAO]- A VFR flight  cleared by air traffic control to operate within Class  B, C, D, and E surface areas in metrological  conditions below VMC. \nSPECIAL VFR OPERATIONS- Aircraft operating  in accordance with clearances within Class B, C, D,  and E surface areas in weather conditions less than the  basic VFR weather minima. Such operations must be  requested by the pilot and approved by ATC. \n(See SPECIAL VFR CONDITIONS.) \n(See ICAO term SPECIAL VFR FLIGHT.) \nSPEED-\n(See AIRSPEED.) \n(See GROUND SPEED.) \nSPEED ADJUSTMENT- An ATC procedure used to  request pilots to adjust aircraft speed to a specific  value for the purpose of providing desired spacing.  Pilots are expected to maintain a speed of plus or  minus 10 knots or 0.02 Mach number of the specified  speed. Examples of speed adjustments are: \na.  “Increase/reduce speed to Mach point  (number).” \nPCG S-6 \nSPECIAL INSTRUMENT APPROACH PROCE- DURE-"}]}
+{"image": "doclay/doclay_20152.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "3.3 CORE COMPETENCIES\nbRAnD EquITy\nCuSTOMER RELATIOnSHIPS\nDIFFEREnTIATED InnOVATIVE PRODuCTS\nPROCuREMEnT ExPERTISE\nLOW bREAk-EVEn POInT, SCALAbLE OPERATIOnS\n28 HIGH LINER FOODS INCORPORATED\n3 The Best New Product Awards is an annual awards program focusing on everyday consumer packaged goods products in the food, personal care and household care  categories Winners are selected based on voting by over 25,000 Canadian consumers from coast-to-coast who participate in the annual independent market research survey  conducted by BrandSpark International \nbased on changing consumer tastes. We can be flexible, and  now we more quickly respond to trends and tastes as they  emerge. Our joint venture in China and the addition of a  primary processing plant in China strengthen our control  over seafood supplies.\nOur core operational competencies are: \nHigh Liner  is the leading Canadian seafood brand, with a  leading retail market share. The retail market share that  we are using to measure ourselves against includes mass  merchandisers, general merchandisers, club stores and  distributors, in addition to the grocery channel. We are the  preferred seafood brand, and the value of our leadership  position is not recorded in our financial statements. The  strength of our brand reputation can be leveraged into growth  with new species, in new channels, and to new customers.  The brand also has a positive impact on our food service  business where we are well known for our innovative, quality  products and superior service.\nWe have been supplying food products to major grocery  retailers and food service distributors for decades. We have  developed strong relationships with our customers through  excellent customer service and brand recognition. We reach  our consumers through these exceptionally strong customer  relationships. We sell to most of the retail chains and to the  major club stores in North America and most food service  distributors in Canada and the U.S. We have ensured that our  infrastructure is capable of meeting the exacting demands of these customers, for both excellent products and delivery service. \nHigh Liner  is currently building brand awareness in the U.S.  Well known in U.S. club stores for the launch of premium  products under the  High Liner  brand and the umbrella  branding of  Fisher Boy  and  Sea Cuisine  brands further  strengthen our market position in traditional grocery outlets.  Fisher Boy  already has strong brand recognition in certain  regions of the U.S. and  Sea Cuisine  is expanding its ACV.\nInnovation is one of our core values and we exhibit this  especially in our product line. We strive to develop and  launch new products that are differentiated from others in  the market. For example, in late 2010 we launched a new  innovative product line in the U.S. food service channel  called  FireRoasters . Due to the success of  FireRoasters  we  are expanding its distribution to U.S. retail, and Canadian  retail and food service channels. It is a line of value-added,  flame-seared seafood product that is unlike anything in the  market today. During 2011, we created more than 125 stock  keeping units for new products. High Liner’s  Market Cuts ,  which were launched in 2011 in Canadian retail, won the  “Best New Product Award 3 ” in the frozen fish category in  January 2012. Our premium products in the U.S. and Canada  have been an excellent example of our innovation in seafood  products. Increasing the depth of our product line by adding  new species from aquaculture has allowed us to develop even  more innovative products. \nIn the U.S. food service market, the  FPI  brand is also well  known for its product innovation and quality products. It is  one of the most recognizable brands in the U.S. food service  market. The  Viking  brand increases our share of the market  for broad line value-added seafood products in the U.S. food  service industry, making us one of the largest suppliers of  value-added seafood products to that market. In addition, the  Icelandic USA Acquisition makes us the largest supplier of  value-added seafood to the U.S. food service market.\nWe are seafood experts, and procure seafood on world  markets from a position of strength. We have no harvesting  or farming operations, we procure many species from around  the world, accessing product from various fisheries in  different parts of the globe. This provides us with a continuity  of supply, without the investment in capital necessary for  fishing or farming operations, and allows us to focus on  what the customer wants rather than trying to sell what is  caught. Our procurement group’s proprietary Internet-based  procurement and inventory management system enables  the purchase of approximately 30 species of seafood from  geographically diverse suppliers in approximately 30 different nations. The results are lower raw material costs,  better predictability of raw material supply and pricing, high  quality, reduced risk and better inventory management. Our  expertise has also allowed us to competitively outsource low  value-added, labour-intensive products to other processors,  freeing capacity in our own plants for more specialized,  and higher value-added products. Lastly, our procurement  knowledge has provided the freedom to develop products \nOur business model has a low break-even point. We are  no longer in the capital-intensive fishing operations, but  instead rely on our procurement expertise. Our business  has relatively low fixed costs and proportionately more  variable costs, which means that the break-even point for the  Company is low. Our sales more than doubled since 2007, and  they are expected 1  to increase significantly in 2012 as a result  of the Icelandic USA Acquisition; however, our selling, general  and administrative costs that are primarily fixed costs increased  at a much slower pace. Specifically, our selling, general and  administrative costs, excluding stock options, as a percentage  of sales in 2007 were 14.3%, but this has now dropped to  10.7% in 2011 and is expected 1  to decrease even further in  2012. We are 1  well positioned to continue to increase sales  and profitability without significant increases in fixed cost."}]}
+{"image": "doclay/doclay_75121.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "mine site where more than 400 employees work. Sodexo  also was recognized for achieving four million hours with  no lost time accidents at both the  BHP Billiton  “Villa  Cerros Alegres Minera Escondida” and the  Antofagasta  Minerals  “Los Pelambres” sites. The recognitions refl ect  the progress in creating a culture of prevention throughout  the organization through the systematic improvement of  safe behaviors.\nBetter quality of life by improving the attractiveness  of their employees’ offshore living environments is  crucial to clients’ ability to recruit, retain and engage a  skilled workforce. To respond to employees’ increasingly  demanding expectations for comfort and privacy on-board  offshore work sites, Sodexo introduced the “efficiency@ sea” solution, which optimizes limited space on-board  while improving amenities by providing soundproof cabins,  comfortable recreational and relaxing facilities, functional  kitchens and pleasant restaurant environments.\nFor the 14th consecutive year, the expertise in health  and safety management systems of Sodexo teams  working on North Sea remote sites earned the prestigious  “International British Safety Council Award”.  In addition,  Sodexo teams in India also received this award for the  first time after scoring 57 out of a possible 60 points.  The awards reflect the HSE performance at Remote Sites  operations around the world.\nEffi ciency@sea complies with the latest safety standards  while improving social interaction among crew, providing  smoking and non-smoking TV lounges and quiet/reading  rooms and improving laundry rooms and corridors.  Refurbishment includes consulting, design and project  management and is carried out offshore to avoid  interruption to drilling operations.\nCertifications earned by Sodexo in  Chile  include  ISO  9001 (quality management), 14001 (environmental  management), and 18001 (health/safety management)  at the  Antofagasta Minerals  “Pelambres Division” site  and NCh2861 –  HACCP (1)  for the  Yamana Gold Inc.  Minera  “El Peñon Project” and  BHP Billiton ’s Minera Escondida –  “Villa Cerros Alegres Division”.\nIn the  United Arab Emirates,  Sodexo earned  ISO 14001  environmental certification  for its entire foodservices  business, reflecting progress made in reducing the  generation of food and material wastes and lowering  consumption of electricity, water and vehicle fuel.\nSodexo was honored by  “Mutual de Seguridad”  for  five million hours worked with no lost time accidents on  the  AngloAmerica  “Los Bronces Escondida Villa Hills” \nSalym Petroleum Development NV  presented Sodexo  with a diploma for high Health, Safety and Environment standards, reflecting the strong performance and zero  lost time incidents since the beginning of the contract  in March 2010.\nExxonMobil  recognized the excellent safety record achieved  by Sodexo since starting its facilities management services  contract in Qatar in June 2011: 265,000 hours worked  with no lost time incidents. Among the major challenges  met by the 63-member on-site team: deployment of a  particularly diffi cult service of exterior window cleaning at  the client’s 16-floor headquarters and the implementation  and management of a common safety culture integrating  subcontractor staff. Services provided at the headquarters  and research center include managing the technical  hotline, equipment maintenance, janitorial services,  pest control, landscaping, visitor reception, vehicle fl eet  management, mail delivery and management of fi le/copy  rooms and conference space.\n41 Sodexo  - Registration Document Fiscal 2013\nRUSSIA – HSE PERFORMANCE\nCHILE – SAFETY CULTURE REFLECTED IN RESULTS\nCertifi cations\nQATAR – FACILITIES MANAGEMENT SERVICES  IMPROVE SAFETY PERFORMANCE\nNORTH SEA AND INDIA – NEW RECOGNITION BY THE  BRITISH SAFETY COUNCIL\nINTERNATIONAL\nHighlights…\n“Effi ciency@sea” breathes new life into off shore  units\n1\n1 GROUP PRESENTATION Our Group and Our Quality of Life Services"}]}
+{"image": "doclay/doclay_38843.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "C) THE BEST PRICE-QUALITY RATIO \n30 \nTenders for which financial offers were made within the maximum budget and satisfied  the formal requirements indicated in the tender specification will be retained for the  identification of the tender with the best price-quality ratio based on the following formula:\nQUALITY SCORE (max 420 points) + PRICE SCORE (max 200 points) "}]}
+{"image": "doclay/doclay_15997.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Algonquin Power & Utilities Corp. – Consolidated Financial Statements\nALGONQUIN POWER & UTILITIES CORP.  Notes to the Consolidated Financial Statements \n21.  Commitments and contingencies \nALGONQUIN POWER & UTILITIES CORP.  Notes to the Consolidated Financial Statements  December 31, 2012 and 2011 \nNotes to the Consolidated Financial Statements  December 31, 2012 and 2011   (in thousands of Canadian dollars except as noted and amounts per share) \nDecember 31, 2012 and 2011   (in thousands of Canadian dollars except as noted and amounts per share) \nb) Commitments (continued) \nIn addition to the commitments related to the proposed acquisitions disclosed in note 3 the  following significant commitments exist at December 31, 2012. \nAs a result of the dam safety legislation passed in Quebec (Bill C93), APUC has completed  technical assessments on its hydroelectric facility dams owned or leased within the Province  of Quebec. The assessments have identified a number of remedial measures required to  meet the new safety standards. APUC currently estimates further capital expenditures of  approximately $16,900 over a period of five years related to compliance with the legislation.\nAPUC has outstanding purchase commitments for power purchases, gas delivery, service and  supply, service agreements, capital project commitments and operating leases. Detailed below  are estimates of future commitments under these arrangements: \nCalpeco has entered into a five year all-purpose power purchase agreement with NV Energy to provide its full electric requirements at NV Energy’s “system average cost”  rates. The PPA has an effective starting date of January 1, 2011 with a five year renewal option. The commitment amounts included in the table above are based on market  prices as of December 31, 2012. However, the effects of purchased power unit cost  adjustments are mitigated through a purchased power rate-adjustment mechanism. Granite  State has several types of contracts for the purchase of electric power. Substantially all of  these contracts require power to be delivered before the Company is obligated to make  payment.\n2012 Annual Report 126\nYear 1  Year 2  Year 3  Year 4  Year 5  Thereafter Total  Purchased power  $56,276 $42,999 $41,316 $ - $ -  $ - $140,591 Gas delivery, service and  supply agreements  25,165 16,792 14,977 5,777 5,207 52,461 120,379 Service agreements  27,147 18,610 17,827 22,253 23,023  566,903 675,763 Capital projects  3,110 500 - - -  - 3,610 Operating leases  4,405 4,099 3,792 3,284 3,202  69,562 88,344 Total $116,103 $83,000 $77,912 $31,314 $31,432 $688,926 $1,028,687"}]}
+{"image": "doclay/doclay_64513.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "U.S. Patent \nJan.10,2017 \nUS 9,541,834 B2 \nc::::::::::::::\"i~i~IIIIIIIII  ~  mimm:..............  ~  ........  ~  ::::::::::::::::::IH:~:~:  ::::’.:’.:’.:’.:’.:’.  --~  -~~ "}]}
+{"image": "doclay/doclay_4056.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "US  2020/0050106  Al \n48 \nFeb. 13, 2020 \nF  LUMO:-1. 46  Tg:284  -continued  F  M-27 \no):Jo  F*I  F  ~  F  F  F  LUMO:-1. 59  Tg: 168  M-28 \nLUMO:-1.02  Tg: 162  M-29 \nLUMO: -0.53  Tg: 104  M-30 \nLUMO:-2.00  Tg: 364  M-31 \n-continued  F3C  LUMO: -0.30  Tg:385  M-32 \nLUMO:-0.22  Tg: 133  M-33 \nLUMO:-0.15  Tg: 138  M-34 \nHO  LUMO: -0.22  Tg:412  0  M-35 \nLUMO:-0.20  Tg: 377  M-36 "}]}
+{"image": "doclay/doclay_52992.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Numeric Literals\nTo insert binary data into a string column (such as a  BLOB  column), you should represent certain characters by escape sequences. Backslash ( \\ ) and the quote character used to quote the string must be escaped. In certain client environments, it may also be necessary to escape  NUL  or Control+Z. The  mysql client truncates quoted strings containing  NUL  characters if they are not escaped, and Control+Z may be taken for END-OF-FILE on Windows if not escaped. For the escape sequences that represent each of these characters, see Table 9.1, “Special Character Escape Sequences” .\nWhen writing application programs, any string that might contain any of these special characters must be properly escaped before the string is used as a data value in an SQL statement that is sent to the MySQL server. You can do this in two ways:\n•Process the string with a function that escapes the special characters. In a C program, you can use the  mysql_real_escape_string_quote() C API function to escape characters. See mysql_real_escape_string_quote(). Within SQL statements that construct other SQL statements, you can use the  QUOTE()  function. The Perl DBI interface provides a  quote  method to convert special characters to the proper escape sequences. See Section 29.9, “MySQL Perl API” . Other language interfaces may provide a similar capability.\n•As an alternative to explicitly escaping special characters, many MySQL APIs provide a placeholder capability that enables you to insert special markers into a statement string, and then bind data values to them when you issue the statement. In this case, the API takes care of escaping special characters in the values for you.\nNumber literals include exact-value (integer and  DECIMAL ) literals and approximate-value (floating-point) literals.\nIntegers are represented as a sequence of digits. Numbers may include  .  as a decimal separator. Numbers may be preceded by  -  or  +  to indicate a negative or positive value, respectively. Numbers represented in scientific notation with a mantissa and exponent are approximate-value numbers.\nExact-value numeric literals have an integer part or fractional part, or both. They may be signed. Examples: 1 ,  .2 ,  3.4 ,  -5 ,  -6.78 ,  +9.10 .\nApproximate-value numeric literals are represented in scientific notation with a mantissa and exponent. Either or both parts may be signed. Examples:  1.2E3 ,  1.2E-3 ,  -1.2E3 ,  -1.2E-3 .\nTwo numbers that look similar may be treated differently. For example,  2.34  is an exact-value (fixed-point) number, whereas  2.34E0  is an approximate-value (floating-point) number.\nThe  DECIMAL  data type is a fixed-point type and calculations are exact. In MySQL, the  DECIMAL  type has several synonyms:  NUMERIC ,  DEC ,  FIXED . The integer types also are exact-value types. For more information about exact-value calculations, see Section 12.25, “Precision Math” .\nThe  FLOAT  and  DOUBLE  data types are floating-point types and calculations are approximate. In MySQL, types that are synonymous with  FLOAT  or  DOUBLE  are  DOUBLE PRECISION  and  REAL .\nAn integer may be used in floating-point context; it is interpreted as the equivalent floating-point number.\nDate and time values can be represented in several formats, such as quoted strings or as numbers, depending on the exact type of the value and other factors. For example, in contexts where MySQL expects a date, it interprets any of  ’2015-07-21’ ,  ’20150721’ , and  20150721  as a date.\n9.1.2 Numeric Literals\n9.1.3 Date and Time Literals\n1862"}]}
+{"image": "doclay/doclay_46411.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Appendix 2:  Registration and Marking Requirements for Small Unmanned Aircraft \nApplicants must be familiar with all of the information in  14 CFR part 48, Registration and Marking  Requirements for Small Unmanned Aircraft, especially the sections listed in the following table: \nSection  Title  48.15 Requirement to register  48.20 Eligibility for registration  48.25 Applicants  48.100 Application  48.205 Display and location of unique identifier \nRemote Pilot – Small Unmanned Aircraft Systems Study Guide \n76 "}]}
+{"image": "doclay/doclay_49027.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "五 当該金融機関等が合併、事業譲渡その他これらに準ずるものにより他の金融機関 等の事業を承継する場合において、当該他の金融機関等が顧客等について既に本人 確認を行つており、かつ、当該金融機関等に対して、当該本人確認について作成し た本人確認記録を引き継ぎ、当該金融機関等が当該本人確認記録を保存している場 合\n(v) where the financial institutions, etc. succeed the business of other financial  institutions, etc. due to merger, transfer of business or other reasons  equivalent thereto, when the other financial institutions, etc. have already  conducted identity confirmation of customers, etc. and have handed over a  record of identity confirmation prepared in regard to the identity  confirmation to the financial institutions, etc., and the financial institutions,  etc. preserve the record of the identity confirmation; \n六 当該金融機関等が合併、事業譲渡その他これらに準ずるものにより他の金融機関 等の事業を承継する場合において、当該他の金融機関等が第七条の三に掲げるもの と既に行為を行つたことがあり、その際に法第二十二条の二第二項の規定により準 用される法第十八条第三項の規定により顧客等とみなされる自然人について本人確 認を行つており、かつ、当該金融機関等に対して、当該本人確認について作成した 本人確認記録を引き継ぎ、当該金融機関等が当該本人確認記録を保存している場合\n(vi) where the financial institutions, etc. succeed the business of other financial  institutions, etc. due to merger, transfer of business or other reasons  equivalent thereto, the other financial institutions, etc. have already  committed the acts with those listed in Article 7-3 and have, in committing  the acts, conducted identity confirmation of natural persons who are deemed  to be customers, etc. pursuant to the provisions of Article 18, paragraph (3)  of the Act, as applied mutatis mutandis pursuant to Article 22-2, paragraph  (2) of the Act, and have handed over the record of identity confirmation  prepared in regard to the identity confirmation to the financial institutions,  etc., and the financial institutions, etc. preserve the record of identity  confirmation. \n３ 金融機関等が第一項第二号又は第三号に掲げる行為を行う場合において、信託契約 の受益者が特定されていないとき若しくは存在しないとき、信託契約の受益者が受益 の意思表示をしていないとき又は信託契約の受益者の信託契約の利益を受ける権利に 停止条件若しくは期限が付されているときは、金融機関等が当該受益者の特定若しく は存在、当該受益の意思表示又は当該停止条件の成就若しくは当該期限の到来を知つ た時に、当該受益者について同号に掲げる信託契約の受益者の指定がなされたものと みなして同号の規定を適用する。\n(3) Where financial institutions, etc. commit the acts listed in paragraph (1),  item (ii) or (iii), when the beneficiary of a trust contract has yet to be specified  or does not exist, when the beneficiary of a trust contract has yet to manifest  the intention to receive benefits, or when conditions precedent or time limit are  set on the beneficiary's beneficial interest in a trust contract, the provisions of \n36 "}]}
+{"image": "doclay/doclay_48442.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de- Seite 106 von 120 -"}]}
+{"image": "doclay/doclay_26684.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Note that the formulation of the continuity assumption in Kalai’s paper already assumes anonymity. In this paper continuity is captured by the Lipschitz constant of the game, and is therefore not tied to anonymity. Kalai’s argument is based on self-purification : the realized profile of a mixed Nash equilibrium is, with high probability, a pure ϵ -equilibrium, and it has been a folk knowledge that the argument is based on continuity alone. This paper pinpoints the limit behavior of the Lipschitz constant required for the self-purification argument to hold and for pure equilibrium to exist.\nA common situation where the continuity assumption holds without the anonimity is network games [11, Sections 9.2-9.3]. In these games players are identified with nodes of a graph, and the payoff of each player depends in a Lipschitz continuous way on the empirical distribution of strategies of her neighbors. These games are not anonymous, but it follows from our result that if the set of neighbors of each player is sufficiently large relative to the total number of players, then a pure approximate equilibrium exists.\nSection 2 contains the necessary definitions and the main results. The proofs of the existence result and of its tightness are in Sections 3 and 4. In Section 5 we show that if the number of strategies of each player is unbounded, then it is not possible to improve the trivial bound of o (1 /n ) to guarantee pure ϵ -equilibrium existence. In Section 6 we consider the special case of anonymous games and show that for such games the required Lipschitz constant is o (1), that is independent of the number of players in the game, even though the self-purification argument fails. Appendix A shows that existence of pure approximate equilibria in Lipschitz games implies Nash’s theorem on existence of mixed equilibrium.\n2. Main results\nAn n –player game in normal form G is given by finite sets { A$_{i}$ } n i =1 of strategies and by payoff functions { f$_{i}$ : A → R } n i $_{=1}$, where A = ∏ n i $_{=1}$A$_{i}$ is the set of strategy profiles . A mixed strategy for player i is a probability distribution over A$_{i}$ . Nash equilibrium and ϵ –Nash equilibrium (in pure or mixed strategies) are defined as usual.\n3"}]}
+{"image": "doclay/doclay_26032.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "60\nChapter 2: Motivation\nby changing coordinates to U = r/α ′ the α ′ dependence drops out of S$_{D}$$_{3}$ . The controlling parameter for Eq. (2.42) then turns out to be g$_{s}$N ( ∂U ) $^{2}$/U 4 [322]. The lowest order term from the action yields N = 4 SU ( N ) super-Yang-Mills from the F$_{αβ}$ term. The quadratic term has no quantum corrections and the quartic term has only a one-loop correction, consistent with N = 4 SYM [326, 327]. This loop correction has been calculated from the gauge theory and string theory, and the two agree [328]. Moreover, it can be argued that all higher order terms in Eq. (2.42) are determined from the fourth-order term [312]. In order for this series to make sense g$_{s}$N ( ∂U ) $^{2}$/U 4 ≪ 1. In particular in the supergravity regime of the AdS/CFT duality g$_{s}$N ≫ 1, and the higher order terms beyond SU ( N ) may become important.\nIn this section we will follow [322] closely for a schematic motivation of the AdS/CFT conjecture (see the same for a very good review of the correspon- dence as well as an extensive bibliography). Consider from a field theoretic standpoint Type IIB string theory in a 10 dimensional spacetime with a stack of N coincident extremal ( r$_{+}$ = r$_{−}$ ≡ R ) D 3 branes at the origin. At ener- gies small compared to the string scale 1 /l$_{s}$ = 1 / √ α ′ only the massless string modes can be excited. The full low energy effective action is then\n2.3.3 Motivation for the AdS/CFT Correspondence\nS = S$_{bulk}$ + S$_{branes}$ + S$_{int}$. (2.44)"}]}
+{"image": "doclay/doclay_64902.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "U.S.  Patent \nNov. 4,  1997 \nSheet  2 of 4 \n5,684,180 \nt--------~z  ,___  ___  .......  N  ll.. "}]}
+{"image": "doclay/doclay_14671.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "A United Airlines Airbus A320 approaches the  runway powered by IAE V2500 engines and  equipped with nacelles and more than a dozen  systems from UTC Aerospace Systems, including  flight controls, electric power, lighting, air data  systems, ice detection, cockpit controls, and  wheels and brakes. Our acquisition of Goodrich  Corp. and our majority ownership in the IAE  International Aero Engines AG collaboration  reshaped our portfolio and strengthened our position in the fast-growing commercial  aerospace market. \nUnited Technologies Corporation (UTC)  is  a diversified company that provides a broad  range of high-technology products and services  to the global aerospace and building systems  industries. Our commercial businesses are Otis elevators and escalators, and UTC Climate,  Controls & Security, which includes Carrier  heating, air-conditioning and refrigeration  systems, as well as fire and security solutions  from brands such as Kidde and Chubb.\nOur aerospace businesses are Sikorsky  helicopters, Pratt & Whitney aircraft engines  and UTC Aerospace Systems. The company  also operates a central research organization  that pursues technologies for improving the  performance, energy efficiency and cost of UTC products and processes. \nTo learn more, visit  www.utc.com ."}]}
+{"image": "doclay/doclay_21469.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "\nTO OUR SHAREHOLDERS\nPACCAR had an excellent year in 2011, as our primary markets improved due to stronger economies and customers updating their fleets. The company has earned  an impressive 73 consecutive years of net income. This remarkable achievement was due to our 23,400 employees who delivered industry-leading product quality,  innovation and outstanding operating efficiency. PACCAR benefited from its global  diversification, superior financial strength and strong growth from aftermarket business  and financial services. PACCAR’s $823 million of capital investments and research  and development in 2011 enhanced its manufacturing capability and accelerated new  product introductions. PACCAR delivered 138,000 trucks to its customers and sold $2.6 billion of aftermarket parts and services. PACCAR’s excellent S&P credit rating of A+ results from consistent profitability, a strong balance sheet and good cash flow.\nLooking ahead to 2012, the North American truck market is expected to continue to  improve. The European truck market could be lower due to the Eurozone economic  challenges. It is anticipated that there will be continued growth in the aftermarket  business due to the aging of the truck parc. PACCAR Financial Services’ revenues  should increase due to a growing portfolio.\nPACCAR’s net income of $1.04 billion on revenues of $16.4 billion was the fourth  best in company history. PACCAR declared regular dividends of $.60 per share and a  special dividend of $.70 per share. Regular quarterly cash dividends have tripled in  the last 10 years. Shareholder equity is a robust $5.4 billion. \nClass 8 industry truck sales in North America, including  Mexico, rose to 216,000 vehicles in 2011 compared to  141,000 units the prior year. The European 15+ tonne  market in 2011 improved to 244,000 vehicles, compared  to 183,000 in 2010. Our customers are generating better  profits due to increased freight and higher rates, which \nis translating into more industry truck orders.\nPACCAR’s excellent financial performance in 2011  resulted from higher truck and parts sales and margins.\nThe company’s 2011 after-tax return on revenues was  6.4%. After-tax return on beginning shareholder equity  (ROE) was 19.4% in 2011, compared to 9.0% in 2010."}]}
+{"image": "doclay/doclay_4897.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Table of Contents\nDamage to our reputation or brand image or loss of customer confidence in our services could adversely affect our business and financial results, as well as require additional resources to rebuild our reputation.\nMoreover, the outbreak and spread of COVID-19 have adversely impacted consumer perceptions of the health and safety of travel, and in particular airline travel, and these negative perceptions could continue even after the pandemic subsides. Actual or perceived risk of infection on our flights has had, and may continue to have, a material adverse effect on the public's perception of us, which has harmed, and may continue to harm, our reputation and business. We have taken various measures to reassure our team members and the traveling public of the safety of air travel, including requirements that passengers wear face coverings, the provision of protective equipment for team members and enhanced cleaning procedures onboard aircraft and in airports. We expect that we will continue to incur COVID-19 related costs as we sanitize aircraft, implement additional hygiene-related protocols and take other actions to limit the threat of infection among our employees and passengers. However, we cannot assure that these or any other actions we might take in response to the COVID-19 pandemic will be sufficient to restore the confidence of consumers in the safety of air travel.\nIn a modern world where news can be captured and travel rapidly, we are at risk of adverse publicity stemming from any public incident involving our company, our people or our brand. Such an incident could involve the actual or alleged behavior of any of our employees. Further, if our personnel, one of our aircraft, a type of aircraft in our fleet, or personnel of, or an aircraft that is operated under our brand by, one of our regional operators or an airline with which we have a marketing alliance, joint business or codeshare relationship, were to be involved in a public incident, accident, catastrophe or regulatory enforcement action, we could be exposed to significant reputational harm and potential legal liability. The insurance we carry may be inapplicable or inadequate to cover any such incident, accident, catastrophe or action. In the event that our insurance is inapplicable or inadequate, we may be forced to bear substantial losses from an incident or accident. In addition, any such incident, accident, catastrophe or action involving our personnel, one of our aircraft (or personnel and aircraft of our regional operators and our codeshare partners), or a type of aircraft fleet could create an adverse public perception, which could harm our reputation, result in air travelers being reluctant to fly on our aircraft or those of our regional operators or codeshare partners, and adversely impact our business, results of operations and financial condition.\nWhile we have to date successfully integrated many of our computer, communication and other technology systems in connection with the merger of US Airways and American, including our customer reservations system and our pilot, flight attendant and fleet scheduling system, we still have to complete several additional important system integration or replacement projects. In a number of prior airline mergers, the integration of these systems or deployment of replacement systems has taken longer, been more disruptive and cost more than originally forecasted. The implementation process to integrate or replace these various systems will involve a number of risks that could adversely impact our business, results of operations and financial condition. New systems will replace multiple legacy systems and the related implementations will be a complex and time- consuming project involving substantial expenditures for implementation consultants, system hardware, software and implementation activities, as well as the transformation of business and financial processes.\nWe cannot assure that our security measures, change control procedures or disaster recovery plans will be adequate to prevent disruptions or delays in connection with systems integration or replacement. Disruptions in or changes to these systems could result in a disruption to our business and the loss of important data. Any of the foregoing could result in a material adverse effect on our business, results of operations and financial condition.\nWe have recently instituted, and intend to institute in the future, changes to our business model designed to increase revenues and offset costs. These measures include further segmentation of the classes of services we offer, such as Premium Economy service and Basic Economy service, enhancements to our AAdvantage loyalty program, charging separately for services that had previously been included within the price of a ticket, changing (whether it be increasing, decreasing or eliminating) other pre-existing fees, reconfiguration of our aircraft cabins, and efforts to optimize our network including by focusing growth on a limited number of large hubs. For example, in 2020, we eliminated change fees for most\n35\nChanges to our business model that are designed to increase revenues may not be successful and may cause operational difficulties or decreased demand.\nWe face challenges in integrating our computer, communications and other technology systems.\nWe are at risk of losses and adverse publicity stemming from any public incident involving our company, our people or our brand, including any accident or other public incident involving our personnel or aircraft, or the personnel or aircraft of our regional, codeshare or joint business operators."}]}
+{"image": "doclay/doclay_31803.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "where p is the longitudinal load and q is the transverse load. Via the Hamilton’s principle, we have the equations of motion\nu$_{xx}$ ( c$_{11}$ − d 2 31 a$_{33}$ ) + u$_{zz}$ ( c$_{55}$ − d 2 15 a$_{11}$ ) + w$_{xz}$ ( c$_{13}$ + c$_{55}$ − d 2 15 a$_{11}$ ) − ϕ$_{xz}$ ( d$_{31}$ a$_{33}$ + d$_{15}$ a$_{11}$ ) + w$_{xxx}$ ( d$_{15}$ a$_{11}$ f$_{1111}$ − d$_{31}$ a$_{33}$ f$_{1313}$ ) + f$_{1331}$ a$_{11}$ d$_{15}$u$_{zzz}$ − w$_{xzz}$ ( d$_{31}$ a$_{33}$ f$_{3333}$ + d$_{15}$ a$_{11}$ f$_{1331}$ ) f$_{1111}$ a$_{11}$ [ ϕ$_{xxx}$ + f$_{1111}$u$_{xxxx}$ + f$_{1331}$ ( u$_{xxzz}$ + w$_{xxzz}$ ) + f$_{3311}$w$_{xxxz}$ ] f$_{1331}$ a$_{11}$ [ ϕ$_{xzz}$ + f$_{1111}$u$_{xxzz}$ + f$_{1331}$ ( u$_{zzzz}$ + w$_{xzzz}$ ) + f$_{3311}$w$_{xzzz}$ ] f$_{1133}$ + f$_{1313}$ a$_{33}$ [ ϕ$_{xzz}$ + f$_{1133}$u$_{xxzz}$ + f$_{1313}$ ( u$_{xxzz}$ + w$_{xxxz}$ ) + f$_{3333}$w$_{xzzz}$ ] − p = ϱ ¨ u, w$_{xx}$ ( c$_{55}$ − d 2 15 a$_{11}$ ) + w$_{zz}$c$_{33}$ + u$_{xz}$ ( c$_{13}$ + c$_{55}$ − d 2 15 a$_{11}$ ) (23) − d$_{15}$ a$_{11}$ ϕ$_{xx}$ − d$_{15}$ a$_{11}$ f$_{3311}$w$_{xxz}$ + u$_{xxx}$ ( d$_{31}$ a$_{33}$ f$_{1313}$ − d$_{15}$ a$_{11}$ f$_{1111}$ ) − f$_{1313}$ a$_{33}$ [ ϕ$_{xxz}$ + f$_{1133}$u$_{xxxz}$ + f$_{1313}$ ( u$_{xxxz}$ + w$_{xxxx}$ ) + f$_{3333}$w$_{xxzz}$ ] + f$_{1331}$ a$_{11}$ [ ϕ$_{xxz}$ + f$_{1111}$u$_{xxxz}$ + f$_{1331}$ ( u$_{xzzz}$ + w$_{xxzz}$ ) + f$_{3311}$w$_{xxzz}$ ] f$_{3333}$ a$_{33}$ [ ϕ$_{zzz}$ + f$_{1133}$u$_{xzzz}$ + f$_{1313}$ ( u$_{xzzz}$ + w$_{xxzz}$ ) + f$_{3333}$w$_{zzzz}$ ] − q = ϱ ¨ w, ϕ$_{xx}$ ( 3 a$_{11}$ − ε$_{0}$ ) + ϕ$_{zz}$ ( 3 a$_{33}$ − ε$_{0}$ ) − u$_{xz}$ ( d$_{15}$ a$_{11}$ + d$_{31}$ a$_{33}$ ) − d$_{15}$ a$_{11}$ w$_{xx}$ − f$_{1111}$ a$_{11}$ u$_{xxx}$ − f$_{3333}$ a$_{33}$ w$_{zzz}$ − u$_{xzz}$ ( f$_{1331}$ a$_{11}$ + f$_{1313}$ a$_{33}$ ) + w$_{xxz}$ ( f$_{1331}$ a$_{11}$ + f$_{3311}$ a$_{11}$ + f$_{1313}$ a$_{33}$ ) = 0\nu = u ′ x = w = w ′ x = ϕ = 0 , (24)\n∂H ∂u$_{x}$ − ∂ ∂x ( ∂H ∂u$_{xx}$ ) − 1 2 ∂ ∂z ∂H ∂u$_{xz}$ = P$_{∗}$, ∂H ∂u$_{xx}$ = 0 , ∂H ∂w$_{x}$ − ∂ ∂x ( ∂H ∂w$_{xx}$ ) − 1 2 ∂ ∂z ∂H ∂w$_{xz}$ = 0 , (25) ∂H ∂w$_{xx}$ = 0 , ∂H ∂ϕ$_{x}$ = 0 ,\nwith the boundary conditions presented for the brevity sake in the form of partial derivatives of the electric enthalpy function as: at x = 0\nat x = l\n13"}]}
+{"image": "doclay/doclay_80473.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "13.6 Expected failures during a DR test\n814  IBM TS7700 Release 4.2 Guide\nIEF233A M 2507,A10088,,DENEKA8,STEP2,DENEKA.HG.TEST1.DUMP1 IEC518I SOFTWARE ERRSTAT: WRITPROT 2507,A10088,SL,DENEKA8,STEP2 IEC502E RK 2507,A10088,SL,DENEKA8,STEP2 IEC147I 613-24,IFG0194F,DENEKA8,STEP2,AUS1,2507,,DENEKA.HG.TEST1.DUMP1 \nIEF116I DENEKY6 STEP1 - MOUNT OF VOLUME PRIVAT ON DEVICE 2580 FAILED IEE763I NAME= CBRLLACS CODE= 14017E CBR4000I LACS MOUNT permanent error for drive 2580. CBR4126I Library HYDRAG drive is in read only mode. IEF272I DENEKY6 STEP1 - STEP WAS NOT run\nIEF233A M 2500,A08759,,DENEKA1,STEP1,DENEKA.HG.TEST1.DUMP1 CBR4195I LACS retry possible for job DENEKA1: 399 IEE763I NAME= CBRLLACS CODE= 140394 CBR4000I LACS WAIT permanent error for drive 2500. CBR4171I Mount failed. LVOL=A08759, LIB=HYDRAG,  PVOL=??????,RSN=22\nSeveral expected failures that can occur during a DR test are described in this section. \nThe messages that are shown in Example 13-10 might appear if you try to read a logical  volume that was not present at time zero in the DR Family.\nThe message that is shown in Example 13-11 might also appear if you want to modify a  volume that is in a write protect media category. \nThe message that is shown in Example 13-12 might occur if a job was running on the cluster  while the FlashCopy was enabled.\nExample 13-12 Message for job running on the cluster while FlashCopy was enabled\nExample 13-11 Error message for volume in a write media category\nExample 13-10 Expected failures during the disaster recovery test"}]}
+{"image": "doclay/doclay_33442.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "4\ninduced by the interaction with the probe. The target ground and final states, | 0 〉 and | n 〉 , are eigenstates of the nuclear Hamiltonian H belonging to the eigenvalues E$_{0}$ and E$_{n}$ , respectively. Note that scattering cross sec- tion of a scalar probe (e.g. thermal neutrons scattering off liquid helium) can be written in the simple form\nwhere ( dσ/d Ω)$_{0}$ is the elementary cross section describ- ing scattering off individual target constituents, while the response defined in Eq. (10) is an intrinsic property, fully determined by internal target dynamics.\nIn the case of electron- or neutrino-nucleus scattering, Eq. (10) can be readily generalized, replacing the density fluctuation operator with the operators describing the electromagnetic and weak nuclear currents. The resulting response tensor reads\ndσ/dQ 2 shrinks, we observe an increase of the allowed range of Q 2 $_{rec}$; the behavior in the two variables is thus completely different. 2\nwhere the hole and particle spectral functions, P$_{h}$ and P$_{p}$ , describe the energy and momentum distributions of the struck particle in the initial and final states, respectively. The simplest implementation of the IA (usually referred to as plane wave impulse approximation, or PWIA) is based on the further assumption that final state inter- actions (FSI) between the knocked out nucleon and the spectator particles can be neglected. As a consequence, the nuclear matter particle spectral function reduces to\ncompletely different. In Fig. 4 we compare the lines of constant Q 2 = 0 . 607 GeV 2 and Q 2 rec = 0 . 306 GeV 2 corresponding to E$_{ν}$ = 0.8 GeV. The results clearly show that the two variables, in spite of leading to very similar distributions of events, are quite different. It clearly appears that the Q 2 and Q 2 rec distributions are determined by the nuclear response in different regions of the ( ω, | q | ) plane, the latter being sensitive to significantly lower values of the momentum transfer. This feature implies that the Q 2 rec distribu- tion receives contributions from the kinematical region in which the validity of the IA may become questionable.\nwhere n ( p + q ) is the occupation probability of the single particle state of momentum p + q and E$_{p}$ denotes the en- ergy of a free nucleon carrying momentum p . Note that, in the above definition, Pauli blocking of the phase space available to the struck nucleon is treated in a consistent fashion, using the momentum distribution obtained from the hole spectral function through\nIn order to pin down the boundary of the kinemati- cal region in which the IA is applicable, we have studied the response of nuclear matter (a translationally invari- ant system consisting of equal number of protons and neutrons subject to strong interactions only) to a scalar probe delivering momentum q and energy ω :\nIn most calculations of electron- and neutrino-nucleus scattering cross sections, 4 πp 3 $_{F}$n ( p ) / 3 is replaced with the RFG result θ ( p$_{F}$ − | p | ), yielding\nIn the above equation, the operator ρ$_{q}$ = ∑ $_{p}$a † p + $_{q}$a$_{p}$ , a † p and a$_{p}$ being nucleon creation and annihilation op- erators, describes the fluctuations of the target density\nTABLE I. Position of the knees or bumps of the distributions shown in Fig. 2.\nE$_{ν}$ (GeV) ω (GeV) | q | (GeV) Q 2 (GeV $^{2}$) Q 2 rec (GeV $^{2}$) 0.4 0.2536 0.5013 0.187 0.107 0.8 0.5923 0.9788 0.607 0.306 1.2 0.9576 1.4181 1.094 0.494\nFIG. 4. (color online). Comparison of curves of fixed Q 2 and Q 2 rec corresponding to the knee (bump) of the differential cross section dσ/dQ 2 ( dσ/Q 2 rec ).\nQ 2 rec = 0 . 306 GeV 2 Q 2 = 0 . 607 GeV 2 hadronic leptonic Conditions: 12 $_{6}$C( ν$_{µ}$, µ $^{−}$), RFG, E$_{ν}$ = 0 . 8 GeV ω (GeV) | q | (GeV) 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 1.8 1.6 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0\ndσ d Ω = ( dσ d Ω )$_{0}$ S ( q , ω ) , (11)\nW$_{νµ}$ = ∑ n 〈 0 | J † $_{ν}$| n 〉〈 n | J$_{µ}$ | 0 〉 δ $^{4}$( q + p$_{0}$ − p$_{n}$ ) . (12)\nS ( q , ω ) = ∫ d $^{3}$p dE P$_{h}$ ( p , E ) P$_{p}$ ( p + q , ω − E ) , (13)\nIn the IA regime, Eq. (10) can be rewritten in the form\nP$_{p}$ ( p + q , ω − E ) = [1 − 4 3 πp 3 F n ( p + q )] × δ ( ω − E + M − E$_{p}$$_{+}$$_{q}$ ) , (14)\nIII. BREAKDOWN OF THE IMPULSE APPROXIMATION\nn ( p ) = ∫ dE P$_{h}$ ( p , E ) . (15)\nS ( q , ω ) = ∑ n 〈 0 | ρ † $_{q}$| n 〉〈 n | ρ$_{q}$ | 0 〉 δ ( ω + E$_{0}$ − E$_{n}$ ) . (10)\nP$_{p}$ ( p $^{′}$, E ) = [ 1 − θ ( p$_{F}$ − | p $^{′}$| ) ] δ ( E + M − E$_{p}$ ′ ) = θ ( | p $^{′}$|  − p$_{F}$ ) δ ( E + M − E$_{p}$ ′ ) . (16)"}]}
+{"image": "doclay/doclay_74777.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Quarterly Data\nReconciliation of Net Subscriptions*\nThis table is presented to facilitate comparisons of FactSet’s net subscriptions presented in this annual report to historical amounts  previously reported on a gross basis. The amounts in columns A are the amounts previously reported. Net subscriptions represent gross subscription amounts less estimated clearing fee recoveries for the periods presented.\n* See Note 3 to the Consolidated Financial Statements\nStock Information\nCommon Stock\nQuarterly Stock Prices\nThe principal stock exchange, on which the Company’s common stock (par value $0.01 per share) is listed, is the New York Stock Exchange. At October 28, 2003, there were approximately 9,900 shareholders of the Company’s common stock.\nQuarterly stock prices reflect the high and low prices for the Company’s common stock on the New York Stock Exchange  composite tape for the last two fiscal years.\nA ugust 31, 2003, 2002, 2001 | FactSet Research Systems Inc.\nA B A-B Estimated Clearing Fee R ecoveries Gross Included in  Net Thousands Subscriptions Subscriptions Subscriptions August 31, 2002  218,970  7,514 211,456 November 30, 2002  221,212  7,252  213,960 February 28, 2003 230,320  7,423  222,897 May 31, 2003  235,898  7,876  228,022 August 31, 2003  242,716  7,734  234,982\nFirst Second Third Fourth 2003 High $31.25 $33.79 $38.56 $49.49 Low 22.02 24.28 24.35 36.40 2002 High $31.55 $39.20 $41.45 $32.73 Low 17.80 29.45 29.56 21.15\n42"}]}
+{"image": "doclay/doclay_76846.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "- 38 -\n13040.19\nMassive Trennwandkonstruktionen 6.2.2\nUmschließungswände von Technikzentralen 6.2.2.1\nTreppenhauswände 6.2.2.2\nAusführungshinweise 6.2.3\n- Die gegebenenfalls vorgesehenen schwimmenden Estriche in den Nasszellen sind raumweise einzubauen. Im Bereich von Türen müssen die Fußbodenauf- bauten durch eine Trennfuge - Estrich abstellen - vollständig unterbrochen wer- den. Die Trennfuge ist auch im Oberbelag vorzusehen.\n- Für die Herstellung der Gipskarton-Ständerwände dürfen nur Systemwände, das heißt, Komplettwandsysteme eines Herstellers (z. B. Firma Rigips, Firma Knauf oder gleichwertig) verwendet werden. Die Ausführung der Wände erfolgt geschosshoch bis an die Rohdecke.\n- Die Aufstellung der Trennwände erfolgt beim gegebenenfalls ausgeführten schwimmenden Estrich (auf Dämmschicht) auf der Rohdecke. Die leichten Trennwände im Bereich des Estrichs auf Trennlage können auf die bestehende Estrichkonstruktion gestellt werden. Unterdecken sind raumweise auszuführen.\nMassivtrennwände mit einer flächenbezogenen Masse von e„ + 430 kg/m² + 200 mm Stahlbetonwand bzw. + 240 mm massive Mauerwerkswand (Annahme Rohdichte Š } 1800 kg/m³), beidseitig verputzt\nMassivtrennwände mit einer flächenbezogenen Masse von e„ + 430 kg/m² + 200 mm Stahlbetonwand bzw. + 240 mm massive Mauerwerkswand (Annahme Rohdichte Š } 1800 kg/m³), beidseitig verputzt bewertetes Bau-Schalldämm-Maß Oƒ$_{w}$ + 47 dB"}]}
+{"image": "doclay/doclay_36567.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "arXiv:1001.2741v2 [physics.chem-ph] 16 Apr 2010\nThe $^{1}$S + $^{1}$S asymptote of Sr$_{2}$ studied by Fourier-transform spectroscopy\nAlexander Stein, 1 Horst Kn¨ ockel, 1 and Eberhard Tiemann 1\n$^{1}$Institut f¨ ur Quantenoptik, Leibniz Universit¨ at Hannover, Welfengarten 1, D-30167 Hannover, Germany\n(Dated: October 29, 2018)\nAn experimental study of the long range behavior of the ground state X $^{1}$Σ+ g of Sr 2 is performed by high resolution spectroscopy of asymptotic vibrational levels and the use of available photoassoci- ation data. Ground state levels as high as v ′′ = 60 (outer turning point at 23 ˚ A and 0.1 cm − 1 below the asymptote) could be observed by Fourier-transform spectroscopy of fluorescence progressions induced by single frequency laser excitation of the v ′ = 4, J ′ = 9 rovibrational level of the state 2 $^{1}$Σ+ $_{u}$. A precise value of the scattering length for the isotopologue $^{88}$Sr 2 is derived and transferred to all other isotopic combinations by mass scaling with the given potential. The derived potential together with already published information about the state 2 $^{1}$Σ+ u directs to promising optical paths for producing cold molecules in the electronic ground state from an ultracold ensemble of Sr atoms.\nPACS numbers: 34.20.Cf, 31.50.Bc, 33.20.Kf, 33.20.Vq\nthe asymptote with which we extend the precisely known potential region significantly into the long range regime. With these data the experimental knowledge about the long range coefficients C$_{6}$, C$_{8}$ and C$_{10}$ and the precision in the scattering lengths will be improved.\nThe paper is organized as follows: Section II describes the experimental methods, Sec. III shows the obtained data set and discusses the measurement uncertainties, Sec. IV presents the resulting ground state potential and scattering lengths. Sec. V gives conclusions and a short outlook.\nII. EXPERIMENT\nI. INTRODUCTION\nOur spectroscopic work on this molecule is motivated by the current high interest in ultracold ensembles of Strontium atoms [1–4], which could be a candidate for an optical frequency standard [5–7], and also by inter- est in ultracold Sr$_{2}$ molecules [8, 9]. Though for all these experiments reliable knowledge of collision prop- erties for Sr atoms like scattering lengths would be of advantage, there was no sufficiently precise ground state potential available from ab initio calculations or exper- imental work, from which these quantities could be de- rived by directly solving the radial Schr¨ odinger equation.\nIn [10] we reported on the optical spectrum of the sys- tem 2 $^{1}$Σ+ u — X $^{1}$Σ+ g with more than 10300 transitions which involve the term energies of nearly 60% of the ex- isting rovibrational levels of the ground state for the main isotopologue $^{88}$Sr$_{2}$ and additionally many levels for the isotopologues $^{86}$Sr$^{88}$Sr and $^{87}$Sr$^{88}$Sr. We reached vibra- tional levels up to v ′′ = 49 and rotational levels up to J ′′ = 224. Using this data set we had to correct the ro- tational assignment given by [11] by four units and were able to construct a potential energy curve (PEC) which is reliable in the range from 4 to 11 ˚ A, covering an energy region from the bottom up to 9 cm − 1 below the dissocia- tion asymptote. With the help of theoretically calculated long range coefficients C$_{6}$ and C$_{8}$ [12, 13] and at that time available node positions of the scattering wave function at large internuclear separation for a kinetic energy of a few microkelvins [14] and 2 mK [1] from photoassociation, we estimated a complete set of scattering lengths for all com- binations of naturally abundant Sr isotopes. Using our derived potentials to calculate Franck-Condon factors we proposed spectroscopic schemes to measure the highest existing vibrational levels of the ground state. Meanwhile new work on photoassociation [15] was performed and the binding energy of the last vibrational level v ′′ = 62 for $^{88}$Sr$_{2}$ was determined and for $^{84}$Sr two groups reached Bose-Einstein condensation [16, 17].\nIn this work we report on successful experiments in the proposed direction and derive ground state levels close to\nTo measure the highest vibrational levels of the ground state, the vibrational band of the excited state with v ′ = 4 and the rotational levels with J ′ = 25, J ′ = 21, J ′ = 17, J ′ = 13, and J ′ = 9 were selected. Low J are very important for observing asymptotic levels because high J are not existing for these v. For measuring the progres-\nregion. The molecules are excited to the v ′ = 4 level of the state 2 $^{1}$Σ+ u by light from a Coherent CR 699 ring dye laser operated with Rhodamine 6G at frequencies close to 17635 cm − 1 (depending on the rotational quantum number J). The power of the dye laser was about 70 mW in front of the heatpipe. The fluorescence light emitted antiparallel to the beam direction of the laser is imaged into a Bruker IFS 120 HR Fourier-transform spectrome- ter.\nThe apparatus is the same as in [10], the experimental procedure is an extension of the earlier one. Strontium is filled into a stainless steel heatpipe, which is heated to a temperature of about 1220 K under 20 mbar of argon as a buffer gas. To keep the optical path free from con- densing strontium crystals growing at both ends of the heatpipe, the oven has to be moved every two hours to bring this Sr back to the heated zone. This means, that the heated cell is not working perfectly as a heatpipe where the condensed substance flows back to the heated region. ′"}]}
+{"image": "doclay/doclay_15843.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "by borrowings, requiring us to incur debt, or by the issuance of our common stock. These transactions involve numerous risks, and we cannot ensure that:\nOur operations and our customers’ operations are subject to a variety of governmental laws and regulations that may increase our costs, limit the demand for our products and services or restrict our operations.\nOur business and our customers’ businesses may be significantly affected by:\nIn addition, we depend on the demand for our products and services from the oil and gas industry. This demand is affected by changing taxes, price controls and other laws and regulations relating to the oil and gas industry in general, including those specifically directed to offshore operations. For example, the adoption of laws and regulations curtailing exploration and development drilling for oil and gas for economic or other policy reasons could adversely affect our operations by limiting demand for our products. We cannot determine the extent to which our future operations and earnings may be affected by new legislation, new regulations or changes in existing regulations and enforcement thereof.\nVarious new regulations intended to improve offshore safety systems and environmental protection have been issued since 2010 that have increased the complexity of the drilling permit process and may limit the opportunity for some operators to continue deepwater drilling in the U.S. Gulf of Mexico, which could adversely affect the Company’s financial operations. Third party challenges to industry operations in the U.S. Gulf of Mexico may also serve to further delay or restrict activities. If the new regulations, policies, operating procedures and possibility of increased legal liability are viewed by our current or future customers as a significant impairment to expected profitability on projects, they could discontinue or curtail their offshore operations, thereby adversely affecting our financial operations by decreasing demand for our products.\nBecause of our foreign operations and sales, we are also subject to changes in foreign laws and regulations that may encourage or require hiring of local contractors or require foreign contractors to employ citizens of, or purchase supplies from, a particular jurisdiction. If we fail to comply with any applicable law or regulation, our business, results of operations, financial position and cash flows may be adversely affected.\n22\n• federal, state, local and foreign laws and other regulations relating to the oilfield operations, worker safety and the protection of the environment;\n• changes in these laws and regulations; and\n• the level of enforcement of these laws and regulations.\n• any acquisition would be successfully integrated into our operations and internal controls;\n• the due diligence conducted prior to an acquisition would uncover situations that could result in financial or legal exposure;\n• the use of cash for acquisitions would not adversely affect our cash available for capital expenditures and other uses;\n• any disposition, investment, acquisition or integration would not divert management resources from the operation of our business; or\n• any disposition, investment, acquisition or integration would not have a material adverse effect on our financial condition, results of operations or cash flows."}]}
+{"image": "doclay/doclay_28638.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "For values of doping close to the Cooperon band edge ( | µ − Δ / 2 | ≫ Δ) spectral curvature is important and the action given in Eqn. 2.5 is inadequate. A better description of the Cooperon dynamics is given by the sine-Gordon model\nwhere M 2 = Δ 2 − 4 µ $^{2}$. The mass term here can be thought to arise as follows in a mean field way from the SO(8) Gross-Neveu model. The SO(8) Gross-Neveu model can be written in terms of fundamental fermions (which are non-local with respect to the original fermions in the problem) with an interaction term of the form\nHere a = 1 , 4 and ψ$_{a}$ = ( ψ R a , ψ L $_{a}$) and τ y is a Pauli matrix acting in R − L space. The four fundamental fermions correspond to the different degrees of freedom in SO(8): charge, spin, orbital, parity. The Cooperon (charge) we take to be given by ψ$_{1}$ . With a finite chemical potential lowering the Cooperon gap, the fluctuations of the Cooperon will be strongest. Invoking mean field theory, we thus replace ψ † $_{a}$τ$^{y}$ψ$_{a}$ for a = 2 , 3 , 4 by its expectation value. The resulting bosonization of the remaining degree of freedom ψ$_{a}$ results in the sine-Gordon model.\nHaving elucidated the properties of individual 4-leg ladders, we now consider an array of such ladders. We assume initially that the electron-electron interaction acts only inside individual ladders and is much smaller than the bandwidth W ∼ 2 t$_{0}$ . It is also assumed that W ≫ t$_{⊥}$ (the inter-ladder tunneling). We imagine two scenarios. In the first we assume t$_{⊥}$ is on the same order as Δ$_{A}$, the gap on the inner bands of the four leg ladder, but much smaller than Δ$_{B}$, the gap on the outer bands. In this case coupling the ladders together lead to small Fermi pockets, very much like in Ref.(10). However in this case the pockets are found near ± π/ 2 , ± π/ 2. The residual coupling between these Fermi pockets and the A-cooperons then leads to superconductivity in the A-bands. And because of a proximity effect, the superconductivity of the A-bands induces superconductivity in the B-bands.\n6\nIII. SUPERCONDUCTIVITY OF ARRAYS OF FOUR-LEG LADDERS: TWO SCENARIOS\nH SO (8) int = 2 g ( ∑ a ψ † $_{a}$τ$^{y}$ψ$_{a}$ ) 2 (2.7)\nL = 1 8 π [ v − 1 F ( ∂$_{τ}$ θ ) 2 + v$_{F}$ ( ∂$_{x}$θ − 4 µ ) $^{2}$] − M 2 cos( θ ) . (2.6)"}]}
+{"image": "doclay/doclay_68463.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Draft Document for Review February 7, 2020 3:15 pm\n8464ch09_Oper.fm\nTokens are internal data structures that are used to track changes to the ownership, data, or  properties of each one of the existing logical volumes in the grid. Hot tokens occur when a  cluster attempts to merge its own token information with the other clusters, but the clusters  are not available for the merge operation (tokens that cannot merge became “hot”).\nStolen volume  describes a volume whose ownership was taken over during a period in which  the owner cluster was in service mode or offline, if an unexpected cluster outage occurs when  the volume ownership is taken over under an operator’s direction, or by using AOTM. \nFor more information about copy mode and other concepts referred to in this section, see  Chapter 2, “Architecture, components, and functional characteristics” on page 13. \nFor more information about this MI function, see IBM Knowledge Center.\nTasks window\nThis window is used to monitor the status of tasks that are submitted to the TS7700. The  information in this window refers to the entire grid operation if the accessing cluster is part of  a grid, or only for this individual cluster if it is a stand-alone configuration. The table can be  formatted by using filters, or the format can be reset to its default by using reset table  preferences. Information is available in the task table for 30 days after the operation stops or  the event or action becomes inactive. \nTasks are listed by starting date and time. Tasks that are still running are shown at the top of  the table; the completed tasks are listed at the bottom. Figure 9-35 shows an example of the  Tasks window. Notice that the information on this page and the task status pods are of grid  scope.Figure 9-35 Tasks window: displaying the properties of one specific task \nChapter 9. Configuring and operating the IBM TS7700  387"}]}
+{"image": "doclay/doclay_27709.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "would not be identifiable.\nExample 3.2. To illustrate the abstract concept of a set of matrices that is re- constructible from rows, we borrow an example from (Chang 1996). We say that a square matrix P is diagonal largest in column (DLC) if P ( j, j ) > P ( i, j ) for all i ̸ = j . The set of DLC matrices is reconstructible from rows.\nWhile DLC serves as a good means for conceptualising a set of matrices that is reconstructible from rows, it has also been shown to be useful as an empirical test for model identifiability (Kaehler et al. 2015). As remarked in Chang (1996), it is not the only set of matrices that is reconstructible from rows but might be a reasonable assumption. Unfortunately, as branch lengths increase, the assumption of DLC becomes less reasonable.\nExample 3.3. Under very weak assumptions, as branch length increases the transi- tion probability matrix on that branch must tend towards its stationary limit. That is, all its rows must tend towards equality. Rows that are closer to equality are in some sense less likely to satisfy DLC. To illustrate the point,\nis DLC .\nis not DLC .\nP =   $^{0}$$^{.}$$^{5}$ 0 . 3 0 . 2 0 . 1 0 . 4 0 . 5 0 . 1 0 . 1 0 . 8    \n$^{0}$$^{.}$$^{5}$  P 2 =    0 . 3 0 . 29 0 . 41 0 . 14 0 . 24 0 . 62 0 . 14 0 . 15 0 . 71   \nHowever, it is an important observation that there is no way of permuting the rows of the second matrix in the above example so that it is DLC. We are therefore motivated to coin the following term.\nDefinition 3.4. A set of matrices S ( M ) is sympathetic to a set of matrices M if\n15"}]}
+{"image": "doclay/doclay_1820.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "10 100 M/m 10 −3 10 −2 α=0.99 α=0.95 α=0.91 α=0.85\nFIG. 9: (Color online) Dimensionless compressibility − mL − $^{1}$( ∂L/∂M )$_{v}$$_{W}$ (filled symbols) and scaled position fluctuations of the piston σ 2 $_{Z}$mg 0 /Lb ( α, α$_{P}$ ) T$_{P}$ ( empty symbols) as a function of the mass ratio, M/m . The different symbols correspond to different values of the coefficient of restitution for the collision between particles, α , as indicated in the insert. The straight line has a slope − 3 / 4, and it is a guide for the eye.\nNevertheless, the analysis carried out in ref. [19] indicates that the range of hydrodynamic gradients considered here exceeds the limit of validity of the Navier-Stokes approximation.\nSome of the main results can be summarized as follows: i) for large mass of the movable piston compared with the mass of the gas particles, the volume fluctuations are Gaussian with very good accuracy, ii) the square root of the second moment of their distribution scales with the square of the velocity of the vibrating wall at the bottom, i.e. in the same way as the amplitudes of the hydrodynamic fields in the gas, iii) by requiring the same relation between volume fluctuations and compressibility as in equilibrium systems to be verified, an “effective temperature” can be defined, iv) the effective temperature turns out to be proportional to the second moment of the velocity fluctuations of the piston, with a proportionality parameter that depends on the inelasticity of both the particle-particle\n18"}]}
+{"image": "doclay/doclay_55921.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Performance Schema Setup Tables\nThe initial  setup_objects  contents look like this:\nmysql>  SELECT * FROM performance_schema.setup_objects;\n+-------------+--------------------+-------------+---------+-------+ | OBJECT_TYPE | OBJECT_SCHEMA | OBJECT_NAME | ENABLED | TIMED | +-------------+--------------------+-------------+---------+-------+ | EVENT | mysql | % | NO | NO | | EVENT | performance_schema | % | NO | NO | | EVENT | information_schema | % | NO | NO | | EVENT | % | % | YES | YES | | FUNCTION | mysql | % | NO | NO | | FUNCTION | performance_schema | % | NO | NO | | FUNCTION | information_schema | % | NO | NO | | FUNCTION | % | % | YES | YES | | PROCEDURE | mysql | % | NO | NO | | PROCEDURE | performance_schema | % | NO | NO | | PROCEDURE | information_schema | % | NO | NO | | PROCEDURE | % | % | YES | YES | | TABLE | mysql | % | NO | NO | | TABLE | performance_schema | % | NO | NO | | TABLE | information_schema | % | NO | NO | | TABLE | % | % | YES | YES | | TRIGGER | mysql | % | NO | NO | | TRIGGER | performance_schema | % | NO | NO | | TRIGGER | information_schema | % | NO | NO | | TRIGGER | % | % | YES | YES | +-------------+--------------------+-------------+---------+-------+\nModifications to the  setup_objects  table affect object monitoring immediately.\nFor object types listed in  setup_objects , the Performance Schema uses the table to how to monitor them. Object matching is based on the  OBJECT_SCHEMA  and  OBJECT_NAME  columns. Objects for which there is no match are not monitored.\nThe effect of the default object configuration is to instrument all tables except those in the  mysql , INFORMATION_SCHEMA , and  performance_schema  databases. (Tables in the  INFORMATION_SCHEMA database are not instrumented regardless of the contents of  setup_objects ; the row for information_schema.%  simply makes this default explicit.)\nWhen the Performance Schema checks for a match in  setup_objects , it tries to find more specific matches first. For example, with a table  db1.t1 , it looks for a match for  ’db1’  and  ’t1’ , then for  ’db1’ and  ’%’ , then for  ’%’  and  ’%’ . The order in which matching occurs matters because different matching setup_objects  rows can have different  ENABLED  and  TIMED  values.\nRows can be inserted into or deleted from  setup_objects  by users with the  INSERT  or  DELETE  privilege on the table. For existing rows, only the  ENABLED  and  TIMED  columns can be modified, by users with the UPDATE  privilege on the table.\nFor more information about the role of the  setup_objects  table in event filtering, see Section 27.4.3, “Event Pre-Filtering” .\nThe  setup_objects  table has these columns:\nThe type of object to instrument. The value is one of  ’EVENT’  (Event Scheduler event),  ’FUNCTION’ (stored function),  ’PROCEDURE’  (stored procedure),  ’TABLE’  (base table), or  ’TRIGGER’  (trigger).\nTABLE  filtering affects table I/O events ( wait/io/table/sql/handler  instrument) and table lock events ( wait/lock/table/sql/handler  instrument).\n• OBJECT_TYPE\n4950"}]}
+{"image": "doclay/doclay_36551.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Using the notation c$_{m}$ = 〈 m | ψ 〉 we obtain the following equation for the time evolution of the coefficients c$_{m}$ :\nUsing this result in Eq. (A2) we obtain\nThus, for m ′ ̸ = m we get\nwrite the Schr¨ odinger equation for the state vector | ψ 〉 as\nTaking the derivative of ˆ H$_{1}$ = ∑ m ′′ ϵ$_{m}$ ′′ | m $^{′′}$〉〈 m $^{′′}$| with respect to time we get\n(A7) Finally, writing c$_{m}$ = a$_{m}$e − iϵ$_{m}$$^{t/$_{ℏ}$}$, and ϵ$_{m}$ − ϵ$_{m}$ ′ = $_{ℏ}$ω$_{mm}$ ′ , we arrive at\nThis way of expressing the time evolution of the state vector makes it clear what operator is responsible for in- ducing transitions between the instantaneous eigenstates, which of the eigenstates are coupled by the time-varying Hamiltonian, and what condition must hold for the evo- lution to be adiabatic.\nThe last term in this equation can be put into a more convenient form by noting that\nIt follows that for m ′ ̸ = m\n12\n〈 m $^{′}$| ∂ ˆ H$_{1}$ ∂t | m 〉 = ( ϵ$_{m}$ − ϵ$_{m}$ ′ ) 〈 m $^{′}$| ∂ ∂t | m 〉 . (A6)\n∑ m 〈 m $^{′}$| ˆ H$_{1}$ + ˆ H$_{2}$ | m 〉〈 m | ψ 〉 = i$_{ℏ}$ ∑ m 〈 m $^{′}$| ∂ ∂t ( | m 〉〈 m | ψ 〉 ) = i$_{ℏ}$ ∑ m ( 〈 m $^{′}$| ∂ ∂t | m 〉〈 m | ψ 〉 + 〈 m $^{′}$| m 〉 d dt 〈 m | ψ 〉$^{)}$ . (A1)\nϵ$_{m}$ ′ c$_{m}$ ′ + ∑ m 〈 m ′ ∣ ∣ ∣ ˆ H$_{2}$ − i$_{ℏ}$ ( ϵ$_{m}$ − ϵ$_{m}$ ′ ) ∂ ˆ H$_{1}$ ∂t ∣ ∣ ∣ m$^{〉}$ c$_{m}$ = i$_{ℏ}$ dc$_{m}$ ′ dt . (A7) −\n∑ m 〈 m $^{′}$| ˆ H$_{1}$ + ˆ H$_{2}$ − i$_{ℏ}$ ∂ ∂t | m 〉 c$_{m}$ = i$_{ℏ}$ dc$_{m}$ ′ dt . (A2)\n∂ ˆ H$_{1}$ ∂t = ∑ m ′′ $^{[(}$dϵ$_{m}$ ′′ dt ) | m $^{′′}$〉〈 m $^{′′}$| + ϵ$_{m}$ ′′ $^{(}$∂ | m $^{′′}$〉 ∂t ) 〈 m $^{′′}$| + ϵ$_{m}$ ′′ | m $^{′′}$〉 $^{(}$∂ 〈 m $^{′′}$| ∂t )] . (A3)\n∑ m 〈 m ′ ∣ ∣ ∣ ˆ H$_{2}$ − i ω$_{mm}$ ′ ∂ ˆ H$_{1}$ ∂t ∣ ∣ ∣ m$^{〉}$ a$_{m}$e − iω$_{mm}$ ′ t = i$_{ℏ}$ da$_{m}$ ′ dt . (A8)\n〈 m $^{′}$| ∂ ˆ H$_{1}$ ∂t | m 〉 = ϵ$_{m}$ 〈 m $^{′}$| ∂ ∂t | m 〉 + ϵ$_{m}$ ′ $^{(}$∂ 〈 m $^{′}$| ∂t ) | m 〉 . (A4)\n∂ ∂t ( 〈 m $^{′}$| m 〉 ) = 0 = $^{(}$∂ 〈 m $^{′}$| ∂t ) | m 〉 + 〈 m $^{′}$| ∂ ∂t | m 〉 . (A5)\n[18] T. E. Wall, J. F. Kanem, J. J. Hudson, B. E. Sauer, D. Cho, M. G. Boshier, E. A. Hinds and M. R. Tarbutt, Phys. Rev. A 78 , 062509 (2008).\n[17] S. K. Tokunaga, J. O. Stack, J. J. Hudson, B. E. Sauer, E. A. Hinds and M. R. Tarbutt, J. Chem. Phys. 126 , 124314 (2007).\n[16] W. J. Childs and L. S. Goodman, Phys. Rev. A 21 , 1216 (1980).\n[15] J. J. Sakurai, Modern quantum mechanics , (Addison- Wesley, Reading, 1994).\n[14] H. L. Bethlem, G. Berden, A. J. A. van Roij, F. M. H. Crompvoets and G. Meijer, Phys. Rev. Lett. 84 , 5744 (2000).\n[13] M. Kajita, Eur. Phys. J. D 38 , 315 (2006).\n[12] M. Kajita, T. Suzuki, H. Odashima, Y. Moriwaki and M. Tachikawa, Jpn. J. Appl. Phys. 40 , L1260 (2001).\n[11] M. Kirste, B. G. Sartakov, M. Schnell and G. Meijer, Phys. Rev. A 79 , 051401(R) (2009).\n[10] S. A. Meek, H. Conrad and G. Meijer, Science 324 , 1699 (2009).\n[1] S. Y. T. van de Meerakker, H. L. Bethlem and G. Meijer, in Cold Molecules , edited by R. V. Krems, W. C. Stwalley and B. Friedrich (CRC Press, Boca Raton 2009), chap. 14.\n[2] H. L. Bethlem, G. Berden and G. Meijer, Phys. Rev. Lett. 83 , 1558 (1999).\n[3] S. Y. T. van de Meerakker, N. Vanhaecke and G. Meijer, Annu. Rev. Phys. Chem. 57 , 159 (2006).\n[4] S. Hoekstra, M. Mets¨ al¨ a, P. C. Zieger, L. Scharfenberg, J. J. Gilijamse, G. Meijer and S. Y. T. van de Meerakker, Phys. Rev. A 76 , 063408 (2007).\n[5] M. Lara, B. L. Lev and J. L. Bohn, Phys. Rev. A 78 , 033433 (2008).\n[6] S. K. Tokunaga, J. M. Dyne, E. A. Hinds and M. R. Tarbutt, New J. Phys. 11 , 055038 (2009).\n[7] K. Wohlfart, F. Filsinger, F. Gr¨ atz, J. K¨ upper and G. Meijer, Phys. Rev. A 78 , 033421 (2008).\n[8] O. Bucicov, M. Nowak, S. Jung, G. Meijer, E. Tiemann and C. Lisdat, Eur. Phys. J. D 46 , 463 (2008).\n[9] A. Schwettmann, J. Franklin, R. Overstreet and J. P. Shaffer, J. Chem. Phys. 123 , 194305 (2005)."}]}
+{"image": "doclay/doclay_75145.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "OUR FINANCIAL RESULTS  ARE A REFLECTION OF  HOW OUR CUSTOMERS  FEEL ABOUT US AND THE  TALENT AND EFFORTS OF  OUR EMPLOYEES.\n—  Robert Sarver01"}]}
+{"image": "doclay/doclay_66618.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "[2380-6 ( i ).]\nSECTION  1888 . Inspection of Premises of Grading Establishment . — The fiber inspector or other person acting under his authority shall have free access to the grading and baling sheds; and also to the warehouses where the bales are stored, of any grading es tablishment within his jurisdiction, during working hours, to make an inspection, for the purpose of satisfying himself as to the propriety of the methods used therein. He shall also see that the approved set of official standards is always carefully prese rved and renewed within the specified period.\n[2380-6  (j) .]\nS ECTION  1889 . Certification of Inspected Fibers . — Every shipment of graded and baled abacá, maguey, or sisal, which has been inspected and approved, shall be accompanied by a certificate or certificates of inspection attached to the bill of lading and dul y signed by the fiber inspector who made the inspection. All certificates of grading shall be prepared in quadruplicate, the original and one copy to be given the owner, one copy to be forwarded to the Director of Agriculture, and one copy to be filed in t he inspector's office.\n[2380-6 ( k ).]\nS ECTION  1890 . Transfer of Certificate to New Owner — Issuance of Secondary Certificate . — When a lot of fiber, which has been graded, baled, and duly inspected and approved, is transferred by sale or otherwise from one owner to another, the certificate of  inspection shall accompany the lot and the transfer of ownership noted thereon by the fiber inspector in the locality where the transfer has taken place. If, however, a new certificate is desired by the purchaser, the same shall be issued to him by the loc al fiber inspector. Such certificate, however, shall be known as \"secondary certificate of inspection\".\n[2380-6 ( l ).]\nS ECTION  1891 . Second Inspection of Fiber Shipped from Port to Port. — Fiber which has been duly inspected, graded, baled, and shipped from one port to another in the Philippine Islands shall not be subject to further inspection at the port of destination,  except upon written complaint received by the chief fiber inspector, providing that during transit the bales shall not have been exposed to moisture or any other agency which is likely to impair their quality.\n[2380-6 ( m ).]\nSECTION  1892 . Inspection Fee . — Ten centavos shall be charged and\nCopyright 2012 CD Technologies Asia, Inc. and Accesslaw, Inc. Philippine Law Encyclopedia 2011\n562"}]}
+{"image": "doclay/doclay_65160.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "I  1111111111111111 11111 111111111111111 11111 111111111111111 111111111111111111  US005925690A \n1111111111111111 11111 111111111111111 11111 111111111111111 111111111111111111  US005925690A \nUnited States Patent  [19J \nFuchigami et al. \n[11]  Patent Number:  5,925,690 \n[45]  Date of Patent:  Jul. 20, 1999 \n[54]  DENTAL PRIMER COMPOSITION AND KIT \n[75]  Inventors:  Satoru Fuchigami,  Tsukuba;  Hideki  Ohno,  Moriya-cho, both of Japan \n[73]  Assignee:  Tokuyama Corproation,  Japan \n[21]  Appl. No.:  08/977,237 \n[22]  Filed:  Nov. 24, 1997 \n[63]  Continuation of application No. 08/560,979, Nov. 20, 1995,  abandoned. \n[51]  Int. Cl. 6  .......................................................  A61K 6/08 \n[52]  U.S. Cl.  ..........................  523/118;  524/547; 524/559;  526/277; 526/318.2 \n[58]  Field of Search  ............................. 523/118; 526/277,  526/318.2; 524/547, 559 \n[56]  References Cited \nU.S. PATENT DOCUMENTS \n4,806,381  4,810,195  4,952,613  5,089,051  5,145,902  5,204,383  5,258,067  5,264,513  5,338,773  5,401,783  2/1989 Engelbrecht et al. .  3/1989 Asmussen et al. .  8/1990 Hosoda.  2/1992 Eppinger et al. .  9/1992 Ravel et al. ............................ 524/547  4/1993 Manabe et al. ......................... 523/118  11/1993 Podszun et al. .  11/1993 Ikemura et al. ........................ 523/118  8/1994 Lu et al. ................................. 523/118  3/1995 Bowen .................................... 523/118 \n0 155 812  0 661 034 Al  3427220  62-33109  62-231652  63-279851  1-279815  6-9327  6-24928  93/12758  9/1985  7/1995  1/1986  2/1987  10/1987  11/1988  11/1989  1/1994  2/1994  7/1993  European Pat. Off ..  European Pat. Off ..  Germany ............................... 524/547  Japan.  Japan.  Japan.  Japan.  Japan.  Japan.  WIPO. \nFOREIGN PATENT DOCUMENTS \nOTHER PUBLICATIONS \nDerwent Publications Ltd., London, GB; AN 94-260386 &  JP-A-06 192 030 (Tokuyama Soda KK), Jul. 12, 1994  (abstract). \nPrimary Examiner-Andrew  E. C. Merriam \nAttorney, Agent, or  Firm-Wenderoth, Lind & Ponack,  L.L.P. \nA dental composition which comprises  (A)  a phosphoric  acid group-containing monomer,  (B)  a carboxylic acid  groups-containing monomer and (C) water as main compo› nents in amounts of 0.5 to 50% by weight, 1 to 50% by  weight and 5 to 90% by weight, based on the composition,  respectively; and a dental adhesive kit comprising a dental  primer composition containing the monomer  (A)  and water  and an adhesive containing a carboxylic acid-containing  polyfunctional monomer and a polymerizable initiator. \n[57]  ABSTRACT \n13 Claims, No Drawings \nRelated U.S. Application Data "}]}
+{"image": "doclay/doclay_20234.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "NON AUDIT SERVICES\nThe following non-audit services were provided by the entity’s auditor, Ernst & Young. The Directors are satisfied that the provision of non-audit  services is compatible with the general standard of independence for auditors imposed by the Corporations Act. The nature and scope of each type  of non-audit service provided means that auditor independence was not compromised. Ernst & Young received or are due to receive the following  amounts for the provision of non-audit services:\nSigned in accordance with a resolution of the Directors\nDonald McGauchie  Chairman\nBrisbane  24 May 201331 Mar 2013 31 Dec 2012 31 Mar 2012 $ $ $ Advisory services - 12,251 - Tax related advice - - - - 12,251 -\nAnnual Report 2013 37"}]}
+{"image": "doclay/doclay_15749.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "The changes in value of the aluminum derivative contracts are recorded on the statement of financial position in accumulated other comprehensive income. Any ineffective portion is recorded in selling, general and administrative expenses. For 2011 and 2010, no ineffectiveness was recognized. Payments made or proceeds received upon the settlement of these contracts are recorded in cost of goods sold.\nPrices for aluminum fluctuate in response to changes in supply and demand, market uncertainty and a variety of other factors beyond the Company’s control. A US$100/MT increase (decrease) in the price of aluminum would have resulted in a $0.7 million (2010 – $0.5 million) decrease (increase) in other comprehensive income and no impact on the earnings from operations (2010 – nil) of the Company. This analysis assumes that all other variables, in particular foreign currency rates, remain constant.\nDuring 2006, the Company entered into cross-currency interest rate swap agreements (hedging items) that converted fixed rate unsecured U.S. dollar-denominated senior notes (hedged items) into Canadian dollar floating rate debt in order to reduce the Company’s exposure to the U.S. dollar debt and create a better balance between fixed and floating interest rate exposures. The fair values of the swaps are recorded in current and non-current liabilities when negative in value and current and non-current assets when positive in value. Change in fair value of the debt is accounted for in current and non-current liabilities and offsets the swap fair values on the income statement. No ineffectiveness has been recognized in the income statement as these are fully effective hedges. One of these swaps matured in July 2010.\nDuring 2003, the Company entered into an interest rate swap agreement (“IRSA”), the hedging item, in order to redistribute the Company’s exposure to fixed and floating interest rates with a view to reducing interest costs over the long term. The hedged item is 50% of a fixed rate unsecured U.S. dollar-denominated senior note. Fair value of this IRSA is recorded in current and non-current liabilities when negative in value and current and non-current assets when positive in value. Change in fair value of the debt is accounted for in current and non-current liabilities and offsets the IRSA’s fair values on the income statement. No ineffectiveness has been recognized in the income statement as this is a fully effective hedge.\n* There is an annual principal payment on this swap. Remaining principal amounts are US$4.7 million and C$5.4 million.\n* There is an annual principal payment on this swap. Remaining principal amount is US$4.7 million.\nDuring 2006, the Company entered into cross-currency interest rate swap agreement (“CCIRSAs”) the hedging items that converted Canadian dollar fixed rate and Canadian dollar floating rate debt into euro fixed rate debt and euro floating rate debt in order to hedge the Company’s exposure to its net investment in self-sustaining euro-denominated operations, with a view to reducing foreign exchange fluctuations and interest expense. Fair value of these CCIRSAs is recorded in current and non-current liabilities when negative in value and current and non-current assets when positive in value. The offset is recorded in other comprehensive income. These have been and continue to be 100% fully effective hedges as the notional amounts of the hedging items equal the portion of the net investment balance being hedged. No ineffectiveness has been recognized in the income statement. One of the swaps matured in July 2010. A second swap matured in March 2011.\nCCL Industries Inc. 2011 Annual Report 77\n(c) Hedges of net investment in self-sustaining operations\n(b) Fair value hedges\nNotional principal amount Interest rate Fair value December 31 Fixed rate Floating rate Paid (CAD) Received (USD) 2011 (CAD) 2010 (CAD) Maturity Effective date US$31.0 million C$36.0 million 3-month BA + 1.67% 6.67% — — July 8, 2010 December 29, 2006 US$28.1 million* C$32.6 million 3-month BA + 2.01% 6.97% (539.5) (1,088.5) September 16, 2012 December 29, 2006\nInterest rate Fair value December 31 Notional principal amount Currency Paid (USD) Received (USD) 2011 (CAD) 2010 (CAD) Maturity Effective date $42.1 million* US$ 3-month LIBOR + 2.97% 6.97% 110.9 376.9 September 16, 2012 December 16, 2003"}]}
+{"image": "doclay/doclay_52270.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "db.inventory.find( { ratings: { $gt: 5, $lt: 9 } } )\nThe operation returns the following documents:\nMongoDB Documentation, Release 3.0.4\n{ \"_id\" : 5, \"type\" : \"food\", \"item\" : \"aaa\", \"ratings\" : [ 5, 8, 9 ] } { \"_id\" : 6, \"type\" : \"food\", \"item\" : \"bbb\", \"ratings\" : [ 5, 9 ] } { \"_id\" : 7, \"type\" : \"food\", \"item\" : \"ccc\", \"ratings\" : [ 9, 5, 8 ] }\nThe document with the \"ratings\" : [ 5, 9 ] matches the query since the element 9 is greater than 5 (the first condition) and the element 5 is less than 9 (the second condition).\nArray of Embedded Documents\nConsider that the inventory collection includes the following documents:\n{ _id: 100, type: \"food\", item: \"xyz\", qty: 25, price: 2.5, ratings: [ 5, 8, 9 ], memos: [ { memo: \"on time\", by: \"shipping\" }, { memo: \"approved\", by: \"billing\" } ] } { _id: 101, type: \"fruit\", item: \"jkl\", qty: 10, price: 4.25, ratings: [ 5, 9 ], memos: [ { memo: \"on time\", by: \"payment\" }, { memo: \"delayed\", by: \"shipping\" } ] }\nMatch a Field in the Embedded Document Using the Array Index If you know the array index of the embedded document, you can specify the document using the embedded document’s position using the dot notation .\nThe following example selects all documents where the memos contains an array whose first element (i.e. index is 0 ) is a document that contains the field by whose value is ’shipping’ :\ndb.inventory.find( { 'memos.0.by': 'shipping' } )\nThe operation returns the following document:\n{ _id: 100, type: \"food\", item: \"xyz\", qty: 25, price: 2.5, ratings: [ 5, 8, 9 ], memos: [ { memo: \"on time\", by: \"shipping\" }, { memo: \"approved\", by: \"billing\" } ] }\nChapter 3. MongoDB CRUD Operations\n100"}]}
+{"image": "doclay/doclay_51864.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "chapter 4 — rules of the road\n49These illustrations show lane tracking when you’re making a  right turn.\nBefore you make a turn, you need to get your vehicle into the  correct lane. Then you need to end up in the correct lane when  you complete your turn. This is sometimes called lane tracking. \nWhen you are on a freeway with more than two lanes in each  direction, you should drive in the centre lane or a right‑hand  lane. This leaves the left lane for higher‑speed traffic and  passing vehicles. \nJust because you are driving at the speed limit does not mean  you should continually drive in the left lane. This may cause  other drivers to try to pass on the right, which may not be as  safe as passing on the left. \nChoose the lane that gives you the best vision and allows you  to go where you want to go. On a multi‑lane highway, you  should travel in one of the right‑hand lanes. This is especially  important if you are driving more slowly than other vehicles or if signs direct you to keep out of the left lane. \nIn the last chapter, you learned about the signs, signals and  pavement markings that identify which lanes you can drive in.  This section tells you more about which lanes to use and how to  use them. \nUsing lanes correctly \nWhich lane should you use? \nLane tracking \nRight turns \nTo turn right, move your  car to the right lane and  turn into the right lane  of the cross street. In  some intersections, road  markings allow you to turn  right from a centre lane."}]}
+{"image": "doclay/doclay_29855.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "PyMol [23] was used for visualization of the protein conformation. The accessible surface area (ASA) of all the amino acid residues in uncomplexed lysozyme are estimated using NACCESS [24].\nAll biomolecules do not interact with metal colloids in the same way. Some of them result in agglomeration of the colloidal particles, others do not cause aggregation but modify the surface charge of the particle [7]. To understand the effect of added lysozyme molecules on Ag colloids, we study the plasmon band of Ag particles in the sol on adsorption of the protein molecules. Plasmon band of Ag colloids is shown by black dotted line in Fig. 1 (a). Ag sols absorb light at 398 nm, due to the dipolar surface plasmon of small spherical particles of Ag. The average particle size of Ag has been estimated to be ∼ 100 ˚ A.\nTime-dependance of the plasmon band of Ag colloids in the sols is shown in Fig. 1 (a). Spectra, recorded just after the addition of protein molecules in the metal sols, are shown by black solid line. Subsequent changes in the spectra with time (after 15 mins., 30 mins, 1 hr, 2 hrs and 3 hrs.) are shown by colored solid lines in the Fig. 1 (a). Addition of lysozyme to the sol results in (i) decrease in intensity and (ii) broadening with a (iii) red shift of the plasmon resonance band of Ag particles in the sol. The decrease in relative intensity of the plasmon absorption band in solutions (ratio of maximum intensity of the plasmon band of Ag colloids after addition of protein to that of the Ag colloids), is shown in Fig. 1(b). We observe that the intensity of the plasmon band decays exponentially. The decay time constant of intensity is estimated to be 60 min in the sol. The observed broadening and the red shift of the plasmon band indicate formation of bigger particles in the sol by added lysozyme molecules. Furthermore, the decrease in the intensity of the peak can be explained by precipitation of metal particles from the sol followed by immediate aggregation.\nAnalysis of SERS Spectra\nIV. EFFECT OF METAL COLLOIDS ON ADDED LYSOZYME MOLECULES\nA. Analysis of Plasmon Band of Silver Colloids\nIII. EFFECT OF ADDED LYSOZYME MOLECULES ON METAL COLLOIDS\n5"}]}
+{"image": "doclay/doclay_22522.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Financial information  continued\nFree cash flow\nConstant exchange rates (CER)\nEBITDA\nNet debt reconciliation\nRestructuring and impairment before taxes\nCash flow return on investment\n52 Syngenta Annual Review 2011\nThe incidence of these business changes may be periodic and the  effect on reported performance of initiating them will vary from  period to period. Because each such business change is different  in nature and scope, there will be little continuity in the detailed  composition and size of the reported amounts which affect  performance in successive periods. Separate disclosure of these  amounts facilitates the understanding of performance including  and excluding items affecting comparability. Syngenta’s definition  of restructuring and impairment may not be comparable to similarly  titled line items in financial statements of other companies.\nImpairment includes impairment losses associated with major  restructuring as well as impairment losses and reversals of  impairment losses resulting from major changes in the markets  in which a reported segment operates. \nCash flow return on investment is a measure used by Syngenta  to compare cash returns to average invested capital. Gross cash  flow used in the calculation comprises cash flow before change in  net working capital, excluding interest and other financial receipts  and payments. In 2011 and 2010, accelerated contributions to the  defined benefit pension plans were also excluded. Invested capital  comprises: total current assets, excluding cash and derivative and  other financial assets; total non-current assets, excluding non- current derivative and other financial assets and defined benefit  pension assets, and adjusted to reflect the gross book values of  property, plant and equipment and intangible assets; total current  liabilities, excluding derivative financial liabilities and current  financial debt; and deferred tax liabilities.\nRestructuring represents the effect on reported performance of  initiating and enabling business changes that are considered major  and that, in the opinion of management, will have a material effect  on the nature and focus of Syngenta’s operations, and therefore  require separate disclosure to provide a more thorough  understanding of business performance. Restructuring includes  the incremental costs of closing, restructuring or relocating existing  operations, and gains or losses from related asset disposals.  Restructuring also includes the effects of completing and  integrating significant business combinations and divestments,  including related transaction costs, gains and losses. Recurring  costs of normal business operations and routine asset disposal  gains and losses are excluded.\nNet debt comprises total debt net of related hedging derivatives, cash  and cash equivalents and marketable securities. Net debt is not a  measure of financial position under generally accepted accounting  principles and the net debt measure used by Syngenta may not be  comparable to the similarly titled measure of other companies. Net  debt has been included as it is used by many investors as a useful  measure of financial position and risk. The following table presents  the derivation of the debt/equity gearing ratio:\nFree cash flow is not a measure of financial performance under  generally accepted accounting principles and the free cash flow  measure used by Syngenta may not be identical to similarly titled  measures of other companies. Free cash flow has been included  as it is used by many investors as a useful supplementary measure  of cash generation.\nFree cash flow comprises cash flow from operating and investing  activities: excluding investments in and proceeds from marketable  securities, which are included in investing activities; excluding cash  flows from and used for foreign exchange movements and  settlement of related hedges on inter-company loans, which are  included in operating activities; and including cash flows from  acquisitions of non-controlling interests, which are included in  financing activities. \nResults in this report from one period to another period are, where  appropriate, compared using constant exchange rates (CER).  To present that information, current period results for entities  reporting in currencies other than US dollars are converted into  US dollars at the prior period’s exchange rates, rather than at  the exchange rates for the current year. CER margin percentages  for gross profit and EBITDA are calculated by the ratio of these  measures to sales after restating the measures and sales at prior  period exchange rates. The CER presentation indicates the  underlying business performance before taking into account  currency exchange fluctuations.\nEBITDA is defined as earnings before interest, tax, non-controlling  interests, depreciation, amortization, restructuring and impairment.  Information concerning EBITDA has been included as it is used by  management and by investors as a supplementary measure of  operating performance. Management excludes restructuring from  EBITDA in order to focus on results excluding items affecting  comparability from one period to the next. EBITDA is not a  measure of cash liquidity or financial performance under generally  accepted accounting principles and the EBITDA measures used  by Syngenta may not be comparable to other similarly titled  measures of other companies. EBITDA should not be construed  as an alternative to operating income or cash flow as determined  in accordance with generally accepted accounting principles.\n(US$m) 2011 2010 Net debt 1,135 1,473 Shareholders’ equity 7,494 7,439 Debt/equity gearing ratio (%) 15% 20%"}]}
+{"image": "doclay/doclay_1363.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "13 13"}]}
+{"image": "doclay/doclay_70131.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "128 704, 832, 960 256 1216, 1472, 1728, 1984, 2240 … 4032 512 4544, 5056 … 8128 Memory increment (GB) Offered memory sizes (GB)\n2.5.1 Memory subsystem topology\nFigure 2-16 CPC drawer memory topology\nThe z14 ZR1 memory subsystem uses high-speed, differential-ended communications  memory channels. An overview of the CPC drawer memory topology of a z14 ZR1 server is  shown in Figure 2-16.\nThe CPC drawer includes 5, 10, 15, or 20 DIMMs (up to four populated memory banks).  DIMMs are connected to the memory control unit (MCU) on each PU SCM. Each PU SCM  has one MCU, which uses five channels: one DIMM per channel, which implements a RAIM  protection scheme (4 +1 design). Each CPC drawer can have one, two, or four populated  memory banks.\nDIMMs are used in 32, 64, 128, 256, and 512 GB sizes with five DIMMs of the same size  included in a memory feature (160, 320, 640, 1280, and 2560 GB RAIM array size).\nThe z14 ZR1 server uses the RAIM protection scheme against hardware memory failures.  The RAIM design detects and recovers from failures of dynamic random access memory  (DRAM), sockets, memory channels, or DIMMs.\n2.5.2 Redundant array of independent memory\nFigure 2-16 CPC drawer memory topology\nChapter 2. Central processor complex hardware components  39"}]}
+{"image": "doclay/doclay_67208.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "delinquent tax or delinquent revenue to pay the same, at the time required, the Collector of Internal Revenue or his  deputy may seize and distrain any personal property belonging to such person or any property subject to the tax lien, in sufficient quantity to satisfy the tax, or charge, together with any increment thereto incident to delinquency, and the expenses of the  distraint.\n[2339-151.]\nS ECTION  1733 . Mode of Procedure and Disposition of Proceeds . — The officer levying the distraint shall make or cause to be made an account of the goods or effects distrained, a copy of which signed by himself shall be left either with the owner or person f rom whose possession such goods or effects were taken, or at the dwelling or place of business of such person and with some one of suitable age and discretion, to which list shall be added a statement of the sum demanded and note of the time and place of s ale; and the said officer shall forthwith cause a notification to be exhibited in not less than two public places in the municipality where the distraint is made, specifying the time and place of sale and the articles distrained. The time of sale shall not  be less than twenty days after notice to the owner or possessor of the property as above specified and the publication or posting of such notice. One place for the posting of such notice shall be at the office of the president of the municipality in which  the property is distrained. At the time and place fixed in such notice the said officer shall sell the goods, chattels, credits, or effects, so distrained, at public auction, to the highest bidder for cash. IDaEHS\nAny residue over and above what is required to pay the entire claim, including expenses, shall be returned to the owner of the property sold. The expenses chargeable upon such seizure and sale shall embrace only the actual expense of seizure and preservati on of the property pending the sale, and no charge shall be imposed for the services of the local internal-revenue officer or his deputy.\n[2339-152.]\nS ECTION  1734 . Release of Distrained Property Upon Payment Prior to Sale . — If at any time prior to the consummation of the sale all proper charges are paid to the officer conducting the sale, the goods or effects distrained shall be restored to the owner. IDaEHS\n[2339-153.]\nS ECTION  1735 . Report of Sale to Bureau of Internal Revenue.  — Within two days after the sale the officer making the same shall make a report of his proceedings in writing to the Collector of Internal Revenue and shall himself\nCopyright 2012 CD Technologies Asia, Inc. and Accesslaw, Inc.\nPhilippine Law Encyclopedia 2011\n520"}]}
+{"image": "doclay/doclay_45007.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Figure 7-38.  Positions of two-bladed propeller during a balance check. \nFigure 7-39.  Positions of three-bladed propeller during balance check.\nDuring a propeller static balance check, all blades must be at  the same blade angle. Before conducting the balance check,  inspect to see that each blade has been set at the same blade  angle.\nUnless otherwise specified by the manufacturer, an  acceptable balance check requires that the propeller assembly  have no tendency to rotate in any of the positions previously  described. If the propeller balances perfectly in all described  positions, it should also balance perfectly in all intermediate  positions. When necessary, check for balance in intermediate  positions to verify the check in the originally described  positions.  [Figure 7-40]\nWhen a propeller assembly is checked for static balance and  there is a definite tendency of the assembly to rotate, certain  corrections to remove the unbalance are allowed.\nThe location for removal or addition of weight for propeller  unbalance correction has been determined by the propeller \n1.  The addition of permanent fixed weights at acceptable  locations when the total weight of the propeller  assembly or parts is under the allowable limit.\n2.  The removal of weight at acceptable locations when  the total weight of the propeller assembly or parts is  equal to the allowable limit.\n7-25\nA. Vertical balance check B. Horizontal balance check\n1 3 2 3 2 1 2 1 3"}]}
+{"image": "doclay/doclay_22124.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "\n8 China\n10 Papua New Guinea\n12 USA\n11 Australia\n9 Indonesia\n5 2 1 3 4 6 10 9 11 7 8 12\n Advanced plans to develop Sasol’s  first CTL plant outside SA . Following  the completion of a feasibility study,  we await the Chinese government’s  approval for the CTL plant to go  ahead.  Together with a joint- venture partner, Sasol O&S has  started basic engineering work  to  expand our oleochemical alcohols  capacity in Lianyungang. Studies have  been conducted to explore further  business opportunities for Sasol O&S’  Nanjing-based surfactant business.\n SSI has signed a MOU with  the Indonesian government to investigate the viability of  developing a CTL plant in the region.\n Sasol’s main activities in Australia are aimed at growing our upstream  gas resources  and investigating  options to develop GTL projects.  In 2010, SPI entered into a new  exploration permit, AC/P-52 through a  45% farm-in with Finder Exploration.\n With our entry into four petroleum  prospecting licences in Papua New  Guinea  in 2008, Sasol Petroleum  International (SPI) established itself as  a 51% equity operator in this area.  Together with our new partner,  Talisman, we are active in the  maturation of prospects, which are  planned to be drilled in 2011.\n Sasol Solvents has started basic  engineering to develop technology  to manufacture octene  by  tetramerising ethylene for use  as a comonomer in the manufacture  of linear low-density polyethylene at  Lake Charles.\nannual review 2010 • our business •  our growth opportunities 15\nexploration and downstream hydrocarbon beneficiation and chemical production."}]}
+{"image": "doclay/doclay_42102.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "smaller area than would normally be considered. On landing, use short or soft field technique, as appropri- ate, for the site selected. A slightly higher-than-normal approach airspeed may be required to maintain ade- quate airflow over the rudder for proper yaw control.\nneeded. In addition, you should always maintain an awareness of your surroundings and be constantly on the alert for suitable emergency landing sites.\nWhen an engine failure occurs at altitude, the first course of action is to adjust the gyroplane’s pitch atti- tude to achieve the best glide speed. This yields the most distance available for a given altitude, which in turn, allows for more possible landing sites. A common mistake when learning emergency procedures is attempting to stretch the glide by raising the nose, which instead results in a steep approach path at a slow airspeed and a high rate of descent. [Figure 21-3] Once you have attained best glide speed, scan the area within gliding distance for a suitable landing site. Remember to look behind the aircraft, as well as in front, making gentle turns, if necessary, to see around the airframe. When selecting a landing site, you must consider the wind direction and speed, the size of the landing site, obstructions to the approach, and the condition of the surface. A site that allows a landing into the wind and has a firm, smooth surface with no obstructions is the most desirable. When considering landing on a road, be alert for powerlines, signs, and automobile traffic. In many cases, an ideal site will not be available, and it will be necessary for you to evaluate your options and choose the best alternative. For example, if a steady wind will allow a touchdown with no ground roll, it may be acceptable to land in a softer field or in a\nOn any flight not in the vicinity of an airport, it is highly advisable to prepare a survival kit with items that would be necessary in the event of an emergency. A properly equipped survival kit should be able to  provide you with sustenance, shelter, medical care, and a means to summon help without a great deal of effort on your part. An efficient way to organize your survival kit is to prepare a basic core of supplies that would be necessary for any emergency, and allow additional space for supplementary items appropriate for the  terrain and weather you expect for a particular flight. The basic items to form the basis of your survival kit would typically include: a first-aid kit and field  medical guide, a flashlight, water, a knife, matches, some type of shelter, and a signaling device. Additional items that may be added to meet the conditions, for example, would be a lifevest for a flight over water, or heavy clothing for a flight into cold weather. Another consideration is carrying a cellular phone. Several pilots have been rescued after calling someone to  indicate there had been an accident. \nEMERGENCY EQUIPMENT AND SURVIVAL GEAR\nFigure 21-3. Any deviation from best glide speed will reduce the distance you can glide and may cause you to land short of a safe touchdown point.\n21-4\nB e s t G l i d e S p e e d T o o F a s t T o S l $_{o}$w"}]}
+{"image": "doclay/doclay_57240.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Buffer Pool\nBy default, the algorithm operates as follows:\n•3/8 of the buffer pool is devoted to the old sublist.\n•The midpoint of the list is the boundary where the tail of the new sublist meets the head of the old sublist.\n•When  InnoDB  reads a page into the buffer pool, it initially inserts it at the midpoint (the head of the old sublist). A page can be read because it is required for a user-initiated operation such as an SQL query, or as part of a read-ahead operation performed automatically by  InnoDB .\n•Accessing a page in the old sublist makes it “young” , moving it to the head of the new sublist. If the page was read because it was required by a user-initiated operation, the first access occurs immediately and the page is made young. If the page was read due to a read-ahead operation, the first access does not occur immediately and might not occur at all before the page is evicted.\n•As the database operates, pages in the buffer pool that are not accessed “age”  by moving toward the tail of the list. Pages in both the new and old sublists age as other pages are made new. Pages in the old sublist also age as pages are inserted at the midpoint. Eventually, a page that remains unused reaches the tail of the old sublist and is evicted.\n•Ideally, you set the size of the buffer pool to as large a value as practical, leaving enough memory for other processes on the server to run without excessive paging. The larger the buffer pool, the more InnoDB  acts like an in-memory database, reading data from disk once and then accessing the data from memory during subsequent reads. See Section 15.8.3.1, “Configuring InnoDB Buffer Pool Size” .\n•On 64-bit systems with sufficient memory, you can split the buffer pool into multiple parts to minimize contention for memory structures among concurrent operations. For details, see Section 15.8.3.2, “Configuring Multiple Buffer Pool Instances” .\n•You can keep frequently accessed data in memory regardless of sudden spikes of activity from operations that would bring large amounts of infrequently accessed data into the buffer pool. For details, see Section 15.8.3.3, “Making the Buffer Pool Scan Resistant” .\n•You can control how and when to perform read-ahead requests to prefetch pages into the buffer pool asynchronously in anticipation of impending need for them. For details, see Section 15.8.3.4, “Configuring InnoDB Buffer Pool Prefetching (Read-Ahead)” .\n•You can control when background flushing occurs and whether or not the rate of flushing is dynamically adjusted based on workload. For details, see Section 15.8.3.5, “Configuring Buffer Pool Flushing” .\nYou can configure the various aspects of the buffer pool to improve performance.\nBy default, pages read by queries are immediately moved into the new sublist, meaning they stay in the buffer pool longer. A table scan, performed for a  mysqldump  operation or a  SELECT  statement with no WHERE  clause, for example, can bring a large amount of data into the buffer pool and evict an equivalent amount of older data, even if the new data is never used again. Similarly, pages that are loaded by the read-ahead background thread and accessed only once are moved to the head of the new list. These situations can push frequently used pages to the old sublist where they become subject to eviction. For information about optimizing this behavior, see Section 15.8.3.3, “Making the Buffer Pool Scan Resistant” , and Section 15.8.3.4, “Configuring InnoDB Buffer Pool Prefetching (Read-Ahead)” .\nInnoDB  Standard Monitor output contains several fields in the  BUFFER POOL AND MEMORY  section regarding operation of the buffer pool LRU algorithm. For details, see Monitoring the Buffer Pool Using the InnoDB Standard Monitor.\nBuffer Pool Configuration\n3008"}]}
+{"image": "doclay/doclay_654.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "\nRobert S. Patterson First National Bank  of Abilene\nDavid Byrd San Angelo  National Bank\nPerry Elliott Stephenville Bank  & Trust Co.\nJanis McDowell First National Bank,  Sweetwater\nTRUST FEES  in millions\nTRUST ASSETS  in millions\n98 99 00 01 02 $0 $500 $600 $700 $800 $900 $1000 $100 $200 $300 $400 $845 $911 $959 $986 $774\n98 99 00 01 02 $0 $4 $3 $5 $6 $1 $2 $5.10 $5.50 $5.89 $5.83 $4.75\n13\nJ. Bruce Hildebrand Executive Vice President\nTo further enhance our risk management assessments in 2003, we will be introducing an Operational Peer Review Team similar to the successful peer review teams used in the Personal Trust areas of our four locations.\nDuring 2002, we saw a successful conversion of Stephenville Bank & Trust to the SEI Corporation account- ing system. In March 2003, we will be converting First National Bank, Sweetwater, to this system as well. This will provide all First Financial Bankshares trust clients with the strength and advantages of a uniform accounting system. Other operational systems have been examined and con- sistent practices and procedures have been implemented. \nThe performance of the stock market the past three years has been a challenge that our trust investment profes- sionals have managed well. Not since 1939-1941 have we seen the S&P 500 drop 35% in a three-year period. Our portfolio managers outperformed their indices in Large Cap stocks by 83 basis points and Fixed Income securi- ties by 168 basis points. This performance bodes well for the present and future of our client accounts.\nWith skilled trust professionals offering a complete range of financial products and services, the future of our trust departments look bright. Through dedication to individu- alized portfolio design and personalized service, our trust departments stand ready to meet the needs of our pres- ent and future clients.\nPlans for the formation of a First Financial Bankshares trust company are moving forward with regulatory approval anticipated in late Spring or early Summer. This will permit your Company to provide quality, locally delivered trust services to additional markets.\nAssets managed by the Trust Departments at First National Bank of Abilene, San Angelo National Bank, Stephenville Bank & Trust Co. and First National Bank, Sweetwater, increased $27.3 million during the past year to a  December 31, 2002 book value of $986.2 million. However, due to depressed stock market values and volumes, trust department revenue declined in 2002. Trust combined revenues for the year were down slightly from $5.89 mil- lion in 2001 to $5.83 million for 2002. In 2003, we anticipate a return to improved income growth. \nRobert S. Patterson Senior Vice President, Trust Services"}]}
+{"image": "doclay/doclay_41147.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "$_{Figure 4-31.}$  Radar summary chart.\n•  Type of precipitation—the type of precipitation is  marked on the chart using specific symbols.\n•  Echo configuration—echoes are shown as areas, cells,  or lines.\n•  Weather watches—severe weather watch areas for  tornadoes and severe thunderstorms are depicted by  boxes outlined with heavy dashed lines.\nStability/Lifted Index Chart\nComposite Moisture Stability Chart\nA valuable tool for preflight planning, the SD chart has  several limitations. Since it depicts only areas of current  precipitation, it will not show areas of clouds and fog with no  appreciable precipitation, or the height of the tops and bases  of the clouds. SD charts should be used in conjunction with  current METAR and weather forecasts.\nThe composite moisture stability chart is a chart composed  of four panels depicting stability, precipitable water,  freezing level, and average relative humidity conditions.  This computer-generated chart contains data obtained from  upper-air observations, is updated twice a day, and shows  the relative stability of the air mass and the potential for  thunderstorms or thermal activity. \nThe LI (numerator of the fraction) is a common measure of  atmospheric stability. It is calculated by hypothetically lifting  a parcel of air to the 500 mb level, approximately 18,000 feet  MSL, and analyzing its stability at that level. A positive LI  indicates that a particular parcel of air is stable and resists  further upward motion. Large positive values (+8 or greater)  would indicate very stable air. Conversely, a negative LI  means that a lifted surface parcel of air is unstable, and more  likely to rise. Large negative values (–6 or more) indicate  very unstable air. \nA subdisplay of the composition moisture stability chart is  the stability or lifted index (LI) chart, a valuable tool for  determining the stability of the atmosphere. The stability  or LI chart is the upper left hand panel of the composite  moisture stability chart. Two indexes represent the moisture  and stability of the air: the K index (KI) and the LI, with  these numbers composing a fraction. KI (denominator of the  fraction) provides moisture and stability information. Values  range from high positive values to low negative values. A  high positive KI indicates moist, unstable air. KI values are  considered high when at or above +20, and low when less  than +20.  [Figure 4-32]\n4-32\n"}]}
+{"image": "doclay/doclay_38082.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Service contract conditions of December 2018 \nContract number: [ complete ] \nnon-disclosure of information in violation of a specific obligation, with the same effect or iii)  the misapplication of such funds or assets for purposes other than those for which they were  originally granted, which damages the Union's financial interests;\n'Grave professional misconduct':  a violation of applicable laws or regulations or ethical  standards of the profession to which a contractor or a related person belongs, including any  conduct leading to sexual or other exploitation or abuse, or any wrongful conduct of the  contractor or a related person which has an impact on its professional credibility where such  conduct denotes wrongful intent or gross negligence. \n‘Interface control document’ : the guideline document which lays down the technical  specifications, message standards, security standards, checks of syntax and semantics, etc. to  facilitate machine-to-machine connection. This document is updated on a regular basis;\n‘Irregularity’ : any infringement of a provision of Union law resulting from an act or  omission by an economic operator, which has, or would have, the effect of prejudicing the  Union’s budget. \n‘Notification’  (or ‘notify’): form of communication between the parties made in writing  including by electronic means;\n‘Performance of the contract’ : the execution of tasks and delivery of the purchased services  by the contractor to the contracting authority;\n‘Personnel’ : persons employed directly or indirectly or contracted by the contractor to  perform the contract; \n‘Pre-existing material’ : any material, document, technology or know-how which exists prior  to the contractor using it for the production of a  result  in the  performance of the contract ;\n‘Pre-existing right’ : any industrial and intellectual property right on  pre-existing material ; it  may consist in a right of ownership, a licence right and/or right of use belonging to the  contractor, the  creator , the contracting authority as well as to any other third parties; \n‘Professional conflicting interest’ : a situation in which the contractor’s previous or ongoing  professional activities affect its capacity to perform the contract to an appropriate quality  standard.\n‘Related person’ : any natural or legal person who is a member of the administrative,  management or supervisory body of the contractor, or who has powers of representation,  decision or control with regard to the contractor;\n‘Result’ : any intended outcome of the  performance of the contract , whatever its form or  nature. A  result may be further defined in this contract as a deliverable. A  result may, in  addition to newly created materials produced specifically for the contracting authority by the  contractor or at its request, also include  pre-existing materials ;\n‘Supplier portal’ : the  e-PRIOR portal, which allows the contractor to exchange electronic  business documents, such as invoices, through a graphical user interface.\n14 "}]}
+{"image": "doclay/doclay_31423.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "the spin, and [ ] < represents the lesser components, and 〈 〉 i represents the averaging over the random spin-orbit impurities. Taking the lesser component, we obtain\nThe retarded and advanced electron Green’s functions at zero frequency are represented by g r and g $^{a}$, respectively.\nThe leading contribution for small 1 / ( ϵ$_{F}$ τ ) is given by\nExpanding q in the Green’s function, we obtain the leading contribution as\nUsing the rotational symmetry, i.e., 〈 k$_{i}$k$_{j}$ 〉 = k 2 3 δ$_{ij}$ and 〈 k$_{i}$k$_{j}$k$_{l}$k$_{k}$ 〉 = k 4 $_{15}$( δ$_{ij}$δ$_{kl}$ + δ$_{ik}$δ$_{jl}$ + δ$_{il}$δ$_{jk}$ ) (the average here denotes the angular average), we obtain\nWe carry out the average over the impurity spin-orbit interaction as Eq. (10) to obtain\nThe asymmetric part of the trace is calculated by use of ( A ( ≡ 1 $_{2}$( A$_{+}$ + A$_{−}$ + σ$_{z}$ ( A$_{+}$ − A$_{−}$ ))) and B ( ≡ 1 $_{2}$( B$_{+}$ + B$_{−}$ + σ$_{z}$ ( B$_{+}$ − B$_{−}$ ))) are any diagonal 2 × 2 matrices)\ntr[( σ$_{β}$Aσ$_{γ}$ − σ$_{γ}$Aσ$_{β}$ ) B ] = − 2 iϵ$_{βγz}$ ∑ σ σA$_{σ}$B$_{−}$$_{σ}$. (B7)\nT z so = 4 i 45 π n$_{so}$λ$_{so}$ 2 e m 2 ∫ d Ω 2 π ∑ kk ′ ∑ q ∑ βγ ϵ$_{zβγ}$e − i q · $^{x}$e i Ω $^{t}$Ω( q · A − q$_{γ}$A$_{γ}$/ 2) k $^{2}$( k $^{′}$) $^{4}$tr[ σ$_{β}$g r $_{k}$σ$_{γ}$ g r k ′ ( g a k ′ ) $^{2}$] + c . c . (B6)\nT z so = − i π e m 2 ∫ d Ω 2 π ∑ kk ′ ∑ q ∑ klβγ ϵ$_{zβk}$e − i q · $^{x}$e i Ω t 〈 v ( k ) so ( k − k $^{′}$) v ( γ ) so ( k ′ − k ) 〉 i × 1 45 A$_{l}$ Ω k $^{2}$( k $^{′}$) $^{4}$( − 4 δ$_{kγ}$q$_{l}$ + δ$_{lγ}$q$_{k}$ + δ$_{kl}$q$_{γ}$ )tr[ σ$_{β}$g r $_{k}$σ$_{γ}$ g r k ′ ( g a k ′ ) $^{2}$] + c . c . (B5)\nT z so = − i π e m 2 ∫ d Ω 2 π ∑ kk ′ ∑ q ∑ ijklo ∑ mnβγ ϵ$_{ijk}$ϵ$_{zβk}$ϵ$_{mnγ}$e − i q · $^{x}$e i Ω t 〈 v ( k ) so ( k − k $^{′}$) v ( γ ) so ( k ′ − k ) 〉 i × A$_{l}$ Ω k$_{i}$k ′ $_{j}$k ′ $_{m}$k$_{n}$ k ′ $_{l}$k ′ $_{o}$q$_{o}$ tr[ σ$_{β}$g r $_{k}$σ$_{γ}$ g r k ′ ( g a k ′ ) $^{2}$] + c . c . (B4)\nT z so = − i π e m ∫ d Ω 2 π ∑ kk ′ ∑ q ∑ ijkl ∑ mnβγ ϵ$_{ijk}$ϵ$_{zβk}$ϵ$_{mnγ}$e − i q · $^{x}$e i Ω t 〈 v ( k ) so ( k − k $^{′}$) v ( γ ) so ( k ′ − k ) 〉 i × A$_{l}$ Ω k$_{i}$k ′ $_{j}$k ′ $_{m}$k$_{n}$ k ′ $_{l}$tr[ σ$_{β}$g r $_{k}$σ$_{γ}$ g r k ′ g a k $^{′}$+ $_{q}$] + c . c . (B3)\nT z so = − i 2 π e m ∫ d Ω 2 π ∑ kk ′ ∑ q ∑ ijkl ∑ mnβγ ϵ$_{ijk}$ϵ$_{zβk}$ϵ$_{mnγ}$e − i q · $^{x}$e i Ω t 〈 v ( k ) so ( k − k $^{′}$) v ( γ ) so ( k ′ − k ) 〉 i × A$_{l}$ Ω( k − k $^{′}$)$_{i}$ ( k + k ′ + q )$_{j}$ k ′ $_{m}$k$_{n}$ ( k ′ + q 2 ) $_{l}$tr[ σ$_{β}$g r $_{k}$σ$_{γ}$ g r k ′ g a k $^{′}$+ $_{q}$] + c . c . (B2)\n17"}]}
+{"image": "doclay/doclay_55807.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "STANDARDS SECTION XVIII - TOURNAMENT STANDARDS OF PERFORMANCE\nexceed the greater of the industry-standard adequate power supply  or an amount of power equivalent to the power supplied to the  Host Broadcaster. The WTA (and its designees) must not be charged  more than the Tournament’s cost for all such production facilities  (including power) and production space. The following outlines the  standard production facilities and production space requirements:\n(a) Transmission Office: Office space within the TV compound,  which is at least 10 feet x 15 feet and contains two (2) long work  tables (approximately 6 feet x 3 feet), seven (7) chairs, access to  four (4) power outlets, Host Broadcaster cabling of the Clean  Feed (including back-up feed), a configurable 31” multi-view  HD, two (2) cabled high-speed internet line connections, and  access to a minimum 4 Mbps wireless internet connection via a  router in the Transmission Office. The office space must be able  to be securely locked. Where a fiber rack is the chosen method  of delivery, WTA shall designate the location for the fiber rack,  and two (2) 16 amp diverse single phase c-form connector  power sources must also be available in the same location.  Except for lighting, power (including the aforementioned  c-form connector power sources), telephone, internet, and  other utilities (each of which must be operational 24 hours per  day), WTA (or its designees) is responsible for all costs of the  Transmission Office. \n(b)  Newsfeed Production Office: An office space located within the  TV compound in close proximity to the Host Broadcaster truck to  be used for recording match highlights, producing the newsfeed,  and managing the distribution of the newsfeed globally. The  office space should be at least 12 feet x 22 feet, contain at least  three (3) long work tables (approximately 6 feet x 3 feet), two  (2) desks, seven (7) chairs, two (2) cabled high speed internet  lines, an international telephone line, four (4) power outlets, a  TV monitor with multi-view, a “Matches in Progress” feed, and  access to a minimum 4 Mbps wireless internet connection via  a router in the Newsfeed Production Office. The office space  must be able to be securely locked. Except for lighting, power,  telephone, internet, and other utilities (each of which must  be operational 24 hours per day), WTA (or its designees) is  responsible for all costs of the Newsfeed Production Office.\nIn addition to the foregoing, the following internet connection  must be provided to the following specifications for the  Newsfeed Production Office:\n395"}]}
+{"image": "doclay/doclay_23075.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "MINERALS TECHNOLOGIES INC. AND SUBSIDIARY COMPANIES  NOTES TO CONSOLIDATED FINANCIAL STATEMENTS \nRevenue Recognition\nForeign Currency \nIncome Taxes\nResearch and Development Expenses\nAccounting for Stock-Based Compensation \nPension and Post-retirement Benefits\nEnvironmental\nF-9 \nExpenditures that relate to current operations are expensed or capitalized as appropriate. Expenditures that relate to an  existing condition caused by past operations and which do not contribute to current or future revenue generation are  expensed. Liabilities are recorded when it is probable the Company will be obligated to pay amounts for environmental site  evaluation, remediation or related costs, and such amounts can be reasonably estimated. \nThe Company also provides post-retirement healthcare benefits for the majority of its retirees and employees in the United  States. The Company measures the costs of its obligation based on its best estimate. The net periodic costs are recognized as  employees render the services necessary to earn the post-retirement benefits. \nThe Company has defined benefit pension plans covering the majority of its employees. The benefits are generally based  on years of service and an employee's modified career earnings. \nThe Company recognizes compensation expense for share-based awards based upon the grant date fair value over the  vesting period. \nResearch and development expenses are expensed as incurred.\nThe accompanying financial statements generally do not include a provision for U.S. income taxes on international  subsidiaries' unremitted earnings, which are expected to be permanently reinvested overseas. \nThe application of income tax law is inherently complex. Laws and regulations in this area are voluminous and are often  ambiguous. As such, we are required to make many subjective assumptions and judgments regarding our income tax  exposures. Interpretations of and guidance surrounding income tax laws and regulations change over time. As such, changes  in our subjective assumptions and judgments can materially affect amounts recognized in the consolidated balance sheets and  statements of operations. The Company's accounting policy is to recognize interest and penalties as part of its provision for  income taxes. See Note 5, \"Income Taxes,\" for additional detail on our uncertain tax positions. \nThe Company operates in multiple taxing jurisdictions, both within the U.S. and outside the U.S. In certain situations, a  taxing authority may challenge positions that the Company has adopted in its income tax filings. The Company regularly  assesses its tax position for such transactions and includes reserves for those differences in position. The reserves are utilized  or reversed once the statute of limitations has expired or the matter is otherwise resolved. \nDeferred tax assets and liabilities are recognized for the estimated future tax consequences attributable to differences  between the financial statement carrying amounts of existing assets and liabilities and their respective tax bases. Deferred tax  assets and liabilities are measured using enacted tax rates in effect for the year in which those temporary differences are  expected to be recovered or settled. The effect on deferred tax assets and liabilities of a change in tax rates is recognized in  income in the period that includes the enactment date. \nThe assets and liabilities of the Company's international subsidiaries are translated into U.S. dollars using exchange rates  at the respective balance sheet date. The resulting translation adjustments are recorded in accumulated other comprehensive  income (loss) in shareholders' equity. Income statement items are generally translated at monthly average exchange rates  prevailing during the period. International subsidiaries operating in highly inflationary economies translate non-monetary  assets at historical rates, while net monetary assets are translated at current rates, with the resulting translation adjustments  included in net income. At December 31, 2013, the Company had no international subsidiaries operating in highly  inflationary economies. \nRevenue from sale of products is recognized at the time the goods are shipped and title passes to the customer. In most of  the Company's PCC contracts, the price per ton is based upon the total number of tons sold to the customer during the year.  Under those contracts the price billed to the customer for shipments during the year is based on periodic estimates of the total  annual volume that will be sold to such customer. Revenues are adjusted at the end of each year to reflect the actual volume  sold. The Company also has consignment arrangements with certain customers in our Refractories segment. Revenues for  these transactions are recorded when the consigned products are consumed by the customer. \nRevenues from sales of equipment are recorded upon completion of installation and receipt of customer acceptance.  Revenues from services are recorded when the services have been performed. "}]}
+{"image": "doclay/doclay_77613.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "It is also possible to secure some idea of the temperature of  a piece of carbon or low alloy steel, in the low temperature  range used for tempering, from the color of the thin oxide film  that forms on the cleaned surface of the steel when heated in  this range. The approximate temperature/color relationship  is indicated on the lower portion of the scale in  Figure 7-5 . \nabove) and by the furnace atmosphere. Iron-constantan  is more suited for use in reducing and chromel-alumel in  oxidizing atmospheres. Thermocouples are usually encased  in metallic or ceramic tubes closed at the hot end to protect  them from the furnace gases. A necessary attachment is  an instrument, such as a millivoltmeter or potentiometer,  for measuring the electromotive force generated by the  thermocouple. In the interest of accurate control, place the  hot junction of the thermocouple as close to the work as  possible. The use of an automatic controller is valuable in  controlling the temperature at the desired value. \nIt is often necessary or desirable to protect steel or cast iron  from surface oxidation (scaling) and loss of carbon from  the surface layers (decarburization). Commercial furnaces,  therefore, are generally equipped with some means of  atmosphere control. This usually is in the form of a burner for  burning controlled amounts of gas and air and directing the  products of combustion into the furnace muffle. Water vapor,  a product of this combustion, is detrimental and many furnaces  are equipped with a means for eliminating it. For furnaces  not equipped with atmosphere control, a variety of external  atmosphere generators are available. The gas so generated is  piped into the furnace and one generator may supply several  furnaces. If no method of atmosphere control is available,  some degree of protection may be secured by covering the  work with cast iron borings or chips. Since the liquid heating  medium surrounds the work in salt or lead baths, the problem  of preventing scaling or decarburization is simplified. Vacuum  furnaces also are used for annealing steels, especially when a  bright non-oxidized surface is a prime consideration. \nPyrometers may have meters either of the indicating type  or recording type. Indicating pyrometers give direct reading  of the furnace temperature. The recording type produces a  permanent record of the temperature range throughout the  heating operation by means of an inked stylus attached to  an arm, which traces a line on a sheet of calibrated paper or  temperature chart. \nPyrometer installations on all modern furnaces provide  automatic regulation of the temperature at any desired setting.  Instruments of this type are called controlling potentiometer  pyrometers. They include a current regulator and an operating  mechanism, such as a relay. \nThe object in heating is to transform pearlite (a mixture of  alternate strips of ferrite and iron carbide in a single grain) to  austenite as the steel is heated through the critical range. Since  this transition takes time, a relatively slow rate of heating  must be used. Ordinarily, the cold steel is inserted when the  temperature in the furnace is from 300 °F to 500 °F below  the hardening temperature. In this way, too rapid heating  through the critical range is prevented. \nThe temperature of the furnace must be held constant  during the soaking period, since it is during this period that  rearrangement of the internal structure of the steel takes place.  Soaking temperatures for various types of steel are specified  in ranges varying as much as 100 °F. [Figure 7-6]  Small parts  are soaked in the lower part of the specified range and heavy  parts in the upper part of the specified range. The length of  the soaking period depends upon the type of steel and the size  of the part. Naturally, heavier parts require longer soaking to  ensure equal heating throughout. As a general rule, a soaking  period of 30 minutes to 1 hour is sufficient for the average  heat-treating operation. \nIf temperature-measuring equipment is not available, it  becomes necessary to estimate temperatures by some other  means. An inexpensive, yet accurate method involves the  use of commercial crayons, pellets, or paints that melt at  various temperatures within the range of 125 °F to 1,600 °F.  The least accurate method of temperature estimation is by  observation of the color of the hot hearth of the furnace or  of the work. The heat colors observed are affected by many  factors, such as the conditions of artificial or natural light, the  character of the scale on the work, and so forth. Steel begins  to appear dull red at about 1,000 °F, and as the temperature  increases, the color changes gradually through various shades  of red to orange, to yellow, and finally to white. A rough  approximation of the correspondence between color and  temperature is indicated in  Figure 7-5 . \nThe rate of cooling through the critical range determines the  form that the steel retains. Various rates of cooling are used to  produce the desired results. Still air is a slow cooling medium  but is much faster than furnace cooling. Liquids are the fastest  cooling media and are therefore used in hardening steels. \nThere are three commonly used quenching liquids: brine,  water, and oil. Brine is the strongest quenching medium,  water is next, and oil is the least. Generally, an oil quench  is used for alloy steels and brine or water for carbon steels. \n7-16 \nCooling \nSoaking \nHeating "}]}
+{"image": "doclay/doclay_68938.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "GLYPH<SM590000> Always cross-check the host LUN ID information with the vdisk_UID of the SAN Volume  Controller. Do not assume that the operating system recognizes, creates, and numbers  the disk devices in the same sequence or with the same numbers as you created them in  the SAN Volume Controller/Storwize.\nGLYPH<SM590000> Ensure that you delete any volume or LUN definition in the server  before  you unmap it in  IBM Spectrum Virtualize. For example, in AIX, remove the hdisk from the volume group  ( reducevg ) and delete the associated hdisk device ( rmdev ).\nGLYPH<SM590000> From version 7.4 onwards, consider enabling volume protection by using  chsystem  -vdiskprotectionenabled yes -vdiskprotectiontime <value_in_minutes> . Volume  protection ensures that some CLI actions (most of those that either explicitly or implicitly  remove host-volume mappings or delete volumes) are policed to prevent the removal of  mappings to volumes or deletion of volumes that are considered  active  (the system has  detected I/O activity within the specified time in minutes to the volume from any host).\nGLYPH<SM590000> Ensure that you explicitly remove a volume from any volume-to-host mappings and any  copy services relationship to which it belongs  before  you delete it. \nGLYPH<SM590000> When you are deallocating volumes, plan for an interval between unmapping them to  hosts ( rmvdiskhostmap ) and deleting them ( rmvdisk ). The IBM internal Storage Technical  Quality Review Process (STQRP) asks for a minimum of a 48-hour period, and having at  least a one business day interval so that you can perform a quick backout if you later  realize you still need some data on that volume.\nGLYPH<SM590000> Before you map new servers to IBM Spectrum Virtualize, verify that they are all error free.  Fix any errors that you find in your server and IBM Spectrum Virtualize before you  proceed. In IBM Spectrum Virtualize, pay special attention to anything inactive in the  svcinfo lsfabric  command.\nGLYPH<SM590000> Plan for an interval between updating the zoning in each of your redundant SAN fabrics,  such as at least 30 minutes. This interval allows for failover to occur and stabilize, and for  you to be notified if unexpected errors occur.\nGLYPH<SM590000> After you perform the SAN zoning from one server’s HBA to IBM Spectrum Virtualize, you  should list its WWPN by using the  svcinfo lshbaportcandidate  command. Use the  svcinfo lsfabric  command to certify that it was detected by the IBM Spectrum Virtualize  nodes and ports that you expected. When you create the host definition in IBM Spectrum  Virtualize ( svctask mkhost ), try to avoid the  -force  parameter. If you do not see the host’s  WWPNs, it might be necessary to scan fabric from the host. For example, use the  cfgmgr command in AIX.\n406  IBM System Storage SAN Volume Controller, IBM Storwize V7000, and IBM FlashSystem 7200 Best \nWhen you add and remove a host (or hosts) in IBM Spectrum Virtualize, consider the  following guidelines:\nIf you issue the  svctask rmvdisk  command and it still has pending mappings, IBM  Spectrum Virtualize prompts you to confirm and is a hint that you might have done  something incorrectly.\nAttention:  You must avoid the use of the  -force  parameter in  rmvdisk .\nNote:  Volume protection cannot be overridden by the use of the  -force  flag in the  affected CLI commands. Volume protection must be disabled to carry on an activity that  is currently blocked.\n9.3.2 Adding and removing hosts"}]}
+{"image": "doclay/doclay_79374.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "CHAPTER 20. PERLFAQ4\n20.4. DATA: STRINGS\n20.4.3 How do I remove consecutive pairs of characters?\n20.4.4 How do I expand function calls in a string?\n20.4.5 How do I find matching / nesting anything?\n20.4.6 How do I reverse a string?\n246\nUse reverse() in scalar context, as documented in reverse in perlfunc .\n$reversed = reverse $string;\nA more complicated and sneaky approach is to make Perl’s regular expression engine do it for you. This is courtesy Dean Inada, and rather has the nature of an Obfuscated Perl Contest entry, but it really does work:\nOne simple destructive, inside-out approach that you might try is to pull out the smallest nesting parts one at a time:\nIf you are serious about writing a parser, there are a number of modules or oddities that will make your life a lot easier. There are the CPAN modules Parse::RecDescent, Parse::Yapp, and Text::Balanced; and the byacc program. Starting from perl 5.8 the Text::Balanced is part of the standard distribution.\nThis isn’t something that can be done in one regular expression, no matter how complicated. To find something between two single characters, a pattern like /x([ˆx]*)x/ will get the intervening bits in $1. For multiple ones, then something more like /alpha(.*?)omega/ would be needed. But none of these deals with nested patterns. For balanced expressions using ( , { , [ or < as delimiters, use the CPAN module Regexp::Common, or see (??{ code }) in perlre . For other cases, you’ll have to write a parser.\nSee also “How can I expand variables in text strings?” in this section of the FAQ.\nprint \"My sub returned @{[mysub(1,2,3)]} that time.\n\";\nThis is documented in perlref . In general, this is fraught with quoting and readability problems, but it is possible. To interpolate a subroutine call (in list context) into a string:\ny///cs; # y == tr, but shorter :-)\nHere’s a solution that turns \"abbcccd\" to \"abcd\":\ns/(.)\\1/$1/g; # add /s to include newlines\nTo turn \"abbcccd\" into \"abccd\" :\nwhile (s/BEGIN((?:(?!BEGIN)(?!END).)*)END//gs) { # do something with $1 }\n# $_ contains the string to parse # BEGIN and END are the opening and closing markers for the # nested text. @( = (’(’,’’); @) = (’)’,’’); ($re=$_)=~s/((BEGIN)|(END)|.)/$)[!$3]\\Q$1\\E$([!$2]/gs; @$ = (eval{/$re/},$@!~/unmatched/i); print join(\"\n\",@$[0..$#$]) if( $$[-1] );"}]}
+{"image": "doclay/doclay_14443.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "General corporate expense for the fourth quarter and year  was $7.5 million and $26.7 million, respectively, compared  to $3.4 million and $21.4 million for the comparable periods  of fiscal 2012. An increase in the Company’s lower of cost or  market inventory reserve caused a notable expense increase  for the fourth quarter and fiscal year compared to fiscal 2012.  The higher expense for both the fourth quarter and fiscal year  also reflects an increase in employee-related expenses com- pared to fiscal 2012.\nNet earnings attributable to the Company’s noncontrolling  interests were $1.1 million and $3.9 million for the 2013  fourth quarter and fiscal year, respectively, compared to $1.7  million and $4.9 million for the comparable periods of fiscal  2012. The Company’s Precept Foods business generated lower  results for both the fourth quarter and full year compared to  fiscal 2012. However, these declines were partially offset by  continued improvement from the Company’s China operations,  which were up for both the fourth quarter and fiscal year com- pared to fiscal 2012 results.\nThe Company was not party to any material related party  transactions during fiscal years 2014, 2013, or 2012.\nCash and cash equivalents were $334.2 million at the end of  fiscal year 2014 compared to $434.0 million at the end of fiscal  year 2013 and $682.4 million at the end of fiscal year 2012.\nDuring fiscal 2014, cash provided by operating activities was $746.9 million compared to $637.8 million in 2013 and  $517.8 million in 2012. Continued higher earnings and net  positive working capital changes largely generated the  increase in 2014.\nCash used in investing activities decreased to $616.8 million  in fiscal year 2014 from $691.1 million in fiscal year 2013  and increased from $106.8 million in fiscal year 2012. The  fourth quarter of fiscal 2014 included $424.3 million used  to purchase CytoSport Holdings, Inc. and the fiscal year  also included $41.9 million used to purchase the China  based  SKIPPY ®  peanut butter business in Weifang, China  from Unilever United States Inc. The larger use of cash in  fiscal 2013 included $665.4 million used to acquire the U.S.  based  SKIPPY ®  peanut butter business. In anticipation of  that purchase in the prior year, the Company liquidated its  marketable securities portfolio at the end of the first quarter  of fiscal 2013, which generated $77.6 million in cash. Capital  expenditures in fiscal 2014 increased to $159.1 million, from \nMaximizing the value returned to shareholders through div- idend payments remains a priority for use of the Company’s  strong cash position going forward. The Company remains  focused on growing the business, utilizing innovation to drive  organic growth, and is also well positioned to take advantage  of strategic acquisition opportunities. Capital spending to  enhance and expand current operations will also be a signifi- cant cash outflow in fiscal 2015.\nCash flows from operating activities continue to provide the  Company with its principal source of liquidity. The Company  does not anticipate a significant risk to cash flows from  this source in the foreseeable future because the Company  operates in a relatively stable industry and has strong brands  across many product lines.\nCash dividends paid to the Company’s shareholders also  continue to be an ongoing financing activity for the Company,  with $203.2 million in dividends paid in fiscal 2014, compared  to $174.3 million in the fiscal 2013 and $152.2 million in fiscal  2012. The dividend rate was $0.80 per share in 2014, which  reflected a 17.6 percent increase over the fiscal 2013 rate. The  Company has paid dividends for 345 consecutive quarters and  expects to continue doing so in the future. The annual dividend  rate for fiscal 2015 was increased 25.0 percent to $1.00 per  share, representing the 49th consecutive annual dividend  increase.\nThe Company used $58.9 million for common stock repur- chases during fiscal 2014, compared to $70.8 million in fiscal  2013 and $61.4 million in fiscal 2012. During fiscal 2014,  the Company repurchased 1.3 million shares of its common  stock at an average price per share of $46.87. On January 31,  2013, the Company announced that its Board of Directors had  authorized the repurchase of 10.0 million shares of its com- mon stock with no expiration date. At of the end of fiscal 2014,  there were 8.2 million shares remaining for repurchase under  that authorization.\nCash used in financing activities was $229.4 million in fiscal  2014 compared to $195.5 million in fiscal 2013 and $192.7  million in fiscal 2012.\n$106.8 million in 2013 and $132.3 million in 2012. Capital  expenditures for fiscal 2015 are estimated to be approximately  $180.0 million to $200.0 million.\nRELATED PARTY TRANSACTIONS\nLiquidity and Capital Resources\n25"}]}
+{"image": "doclay/doclay_47145.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "(12) Nothing in this article overrides the requirement to obtain scheduled monument consent  under the Ancient Monuments and Archaeological Areas Act 1979( a ). \n24. —(1) The authorised tramway must be operated by electricity or, in an emergency or for the  purposes of maintenance, by diesel power or other means. \n(2) The authorised tramway must be constructed on a nominal gauge of 1,435 millimetres. \n(3) Where the authorised tramway is constructed along a street or in any place to which the  public has access (including any place to which the public has access only on making a payment),  the Authority must take such care as in all the circumstances is reasonable to ensure that the  authorised tramway is constructed and maintained so that the street or other place is safe for other  users. \n(4) When considering what measures are required under paragraph (3) the Authority must have  particular regard to the character and usage of the street or other place and to those who could  reasonably be expected to use it. \n(5) Where the authorised street tramway has been constructed in a street, works by any person  which affect or are likely to affect the Authority’s obligations under paragraph (3), including  works to any street surfaces and works affecting any equipment or apparatus placed in the street  under article 11 (power to keep apparatus in streets) must not be carried out without the consent of  the Authority, which may be given subject to such reasonable terms and conditions as the  Authority may require but must not be unreasonably withheld. \n25.  Any person who, without reasonable excuse— \nis guilty of an offence and liable on summary conviction to a fine not exceeding level 3 on the  standard scale. \n26. —(1) The Authority may, if it considers it necessary or expedient in consequence of any  street works executed or proposed to be executed in a street along which an authorised street  tramway is constructed— \n(2) The powers conferred by this article may only be exercised with the consent of the street  authority but such consent may not be unreasonably withheld. \n(3) The provisions of articles 10(2) (power to alter layout, etc., of streets), 11 (power to keep  apparatus in streets), 12 (power to execute street works) and 43 (traffic signs) apply in relation to  temporary tramways laid under the powers conferred by this article as they apply in relation to  authorised street tramways. \nMode of construction and operation of tramway \nObstruction of construction of authorised works \n(a) obstructs another person acting under the authority of the Authority in setting out the  lines of the scheduled works, or in constructing any of the authorised works; or \n(b) interferes with, moves or removes any apparatus belonging to any person acting under the  authority of the Authority, \n(a) remove or discontinue the operation of the authorised street tramway; and \n(b) lay, maintain and operate in that street or in a street near to that street a temporary  tramway in place of the authorised street tramway. \nPower to construct temporary tramways \n( a ) 1979 c. 46. \n20"}]}
+{"image": "doclay/doclay_13890.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "FINANCIAL HIGHLIGHTS\nThe following selected financial data should be read in conjunction with “Management’s Discussion and Analysis of Financial Condition and Results of Operations” and the historical Consolidated Financial Statements and Notes thereto included herein:\nYears Ended December 31, (In thousands, except per share amounts) 2003 2002 2001 2000 1999 Operating Data: Net sales $353,116 $325,431 $254,770 $253,129 $268,951 Operating profit $ 34,277 $ 29,213 $ 20,345 $ 17,067 $ 33,269 Income from continuing operations  before income taxes and cumulative  effect of change in accounting principle $ 31,243 $ 25,647 $ 16,194 $ 13,646 $ 30,595 Provision for income taxes $ 11,868 $ 9,883 $ 6,364 $ 5,652 $ 12,105 Income from continuing operations  before cumulative effect of change  in accounting principle $ 19,375 $ 15,764 $ 9,830 $ 7,994 $ 18,490 Discontinued operations 1 (net of taxes) $ 48 $ (200) $ (896) $ (6,447) 2 $ (1,299) Cumulative effect of change in accounting  principle for goodwill (net of taxes) $ (30,162) Net income (loss) $ 19,423 $ (14,598) $ 8,934 $ 1,547 $ 17,191 Income (loss) per common share: Income from continuing operations: Basic $ 1.92 $ 1.61 $ 1.02 $ .77 $ 1.62 Diluted $ 1.88 $ 1.57 $ 1.02 $ .77 $ 1.62 Discontinued operations: Basic $ (.02) $ (.10) $ (.62) $ (.11) Diluted $ (.02) $ (.10) $ (.62) $ (.11) Cumulative effect of change in accounting  principle for goodwill: Basic $ (3.08) Diluted $ (3.01) Net income (loss): Basic $ 1.92 $ (1.49) $ .92 $ .15 $ 1.51 Diluted $ 1.88 $ (1.46) $ .92 $ .15 $ 1.51 Financial Data: Working capital $ 29,700 $ 24,067 $ 12,816 $ 23,400 $ 42,669 Total assets $160,104 $145,396 $156,975 $159,298 $156,044 Long-term obligations $ 27,737 $ 39,102 $ 43,936 $ 58,275 $ 46,451 Stockholders’ equity $ 93,653 $ 70,104 $ 81,210 $ 72,164 3 $ 84,089\n1 Refers to the operations of the Company’s discontinued axle and tire refurbishing operation.\n2 After a non-cash charge of $6.9 million in 2000 to reflect an impairment related to the Company’s axle and tire refurbishing operation.\n3 In 2000, the Company purchased treasury stock for $13.5 million.\nThe closing price per share for the common stock on March 17, 2004 was $36.10.\nYear-End Stock Prices\nYear End Debt to Equity Ratio\nEquity Per Common Share\n$ 16.05 $ 10.75 $ 9.00 $ 5.75 1999 2000 2001 2002 2003 $ 27.80\n0.7 0.7 0.6 0.9 1999 2000 2001 2002 2003 0.4\n$ 7.06 $ 8.40 $ 7.44 $ 7.47 1999 2000 2001 2002 2003 $ 9.18\nDREW INDUSTRIES INCORPORATED 2003 ANNUAL REPORT 1"}]}
+{"image": "doclay/doclay_50832.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "(continued from previous page)\n(continues on next page)\n4\n3 Static SystemTap markers\nThe low-level way to use the SystemTap integration is to use the static markers directly. This requires you to explicitly state the binary file containing them.\nFor example, this SystemTap script can be used to show the call/return hierarchy of a Python script:\nprobe process(\"python\").mark(\"function__entry\") { filename = user_string($arg1); funcname = user_string($arg2); lineno = $arg3; printf(\"%s => %s in %s:%d\\\n\", thread_indent(1), funcname, filename, lineno); } probe process(\"python\").mark(\"function__return\") { filename = user_string($arg1); funcname = user_string($arg2); lineno = $arg3;\n156641360502280 function-entry:call_stack.py:start:23 156641360518804 function-entry: call_stack.py:function_1:1 156641360532797 function-entry: call_stack.py:function_3:9 156641360546807 function-return: call_stack.py:function_3:10 156641360563367 function-return: call_stack.py:function_1:2 156641360578365 function-entry: call_stack.py:function_2:5 156641360591757 function-entry: call_stack.py:function_1:1 156641360605556 function-entry: call_stack.py:function_3:9 156641360617482 function-return: call_stack.py:function_3:10 156641360629814 function-return: call_stack.py:function_1:2 156641360642285 function-return: call_stack.py:function_2:6 156641360656770 function-entry: call_stack.py:function_3:9 156641360669707 function-return: call_stack.py:function_3:10 156641360687853 function-entry: call_stack.py:function_4:13 156641360700719 function-return: call_stack.py:function_4:14 156641360719640 function-entry: call_stack.py:function_5:18 156641360732567 function-return: call_stack.py:function_5:21 156641360747370 function-return:call_stack.py:start:28\n/self->trace/ { self->indent--; printf(\"%d\t%*s:\", timestamp, 15, probename); printf(\"%*s\", self->indent, \"\"); printf(\"%s:%s:%d\n\", basename(copyinstr(arg0)), copyinstr(arg1), } python$target:::function-return /copyinstr(arg1) == \"start\"/ { self->trace = 0; }\n$ sudo dtrace -q -s call_stack.d -c \"python3.6 script.py\"\nThe output looks like this:\nIt can be invoked like this:"}]}
+{"image": "doclay/doclay_57242.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "IDENTIFIED WITH mysql_no_login; GRANT ALL PRIVILEGES ON mydevdb.* TO ’developer’@’localhost’; GRANT ALL PRIVILEGES ON mydb.* TO ’data_entry’@’localhost’;\nGRANT PROXY ON ’developer’@’localhost’ TO ’’@’’; GRANT PROXY ON ’data_entry’@’localhost’ TO ’’@’’;\nshell>  mysql --user=antonio --password --enable-cleartext-plugin Enter password:  antonio_password\nmysql>  SELECT USER(), CURRENT_USER(), @@proxy_user; +-------------------+---------------------+--------------+ | USER() | CURRENT_USER() | @@proxy_user | +-------------------+---------------------+--------------+ | antonio@localhost | developer@localhost | ’’@’’ | +-------------------+---------------------+--------------+\nmysql>  SELECT USER(), CURRENT_USER(), @@proxy_user; +-------------------+----------------------+--------------+ | USER() | CURRENT_USER() | @@proxy_user | +-------------------+----------------------+--------------+ | antonio@localhost | data_entry@localhost | ’’@’’ | +-------------------+----------------------+--------------+\nThis demonstrates that the  antonio  operating system user is authenticated to have the privileges of the  data_entry  MySQL user, and that proxying occurs through the default proxy account.\nIf  antonio  is not a member of the  root  PAM group but is a member of the  users  PAM group, a similar process occurs, but the plugin maps  user  PAM group membership to the  data_entry  MySQL user name and returns that name to the server:\nThis demonstrates that the  antonio  operating system user is authenticated to have the privileges granted to the  developer  MySQL user, and that proxying occurs through the default proxy account.\nThe server authenticates the connection using the default  ’’@’’  proxy account. The resulting privileges for  antonio  depend on which PAM groups  antonio  is a member of. If  antonio  is a member of the  root  PAM group, the PAM plugin maps  root  to the  developer  MySQL user name and returns that name to the server. The server verifies that  ’’@’’  has the  PROXY  privilege for developer  and permits the connection. The following query returns output as shown:\n1326\nThe proxied accounts use the  mysql_no_login  authentication plugin to prevent clients from using the accounts to log in directly to the MySQL server. Instead, users who authenticate using PAM are expected to use the  developer  or  data_entry  account by proxy based on their PAM group. (This assumes that the plugin is installed. For instructions, see Section 6.4.1.8, “No-Login Pluggable Authentication” .) For alternative methods of protecting proxied accounts against direct use, see Preventing Direct Login to Proxied Accounts.\n7. Use the  mysql  command-line client to connect to the MySQL server as  antonio .\n6. Grant to the proxy account the  PROXY  privilege for each proxied account:\nAuthentication Plugins"}]}
+{"image": "doclay/doclay_71150.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Table of Contents\nThe following tables present the estimated effects on the fair value of our financial instruments as of December 31, 2018 and 2017 due to an increase in yield rates of 100 basis points, a 10% decline in foreign currency exchange rates and a 10% decline in the S&P 500, with all other variables held constant.\nMarket Risk Scenario 1\nMarket Risk Scenario 1\nDecember 31, 2018 Increase (Decrease) (In millions) Estimated Fair Value Interest Rate Risk Foreign Currency Risk Equity Price Risk Assets: Fixed maturity securities $ 39,546 $ (2,440) $ (203) $ — Equity securities 780 (29 ) (2 ) (18 ) Limited partnership investments 1,982 — — (79) Other invested assets 53 — (4 ) — Mortgage loans  (1) 827 (36) — — Short term investments 1,286 (1 ) (12 ) — Total assets 44,474 (2,506) (221) (97) Derivative financial instruments, included in Other liabilities 4 15 — — Total securities $ 44,478 $ (2,491) $ (221) $ (97) Long term debt  (1) $ 2,731 $ (120 ) $ — $ —\nDecember 31, 2017 Increase (Decrease) (In millions) Estimated Fair Value Interest Rate Risk Foreign Currency Risk Equity Price Risk Assets: Fixed maturity securities $ 41,487 $ (2,559) $ (215) $ — Equity securities 695 (26 ) (2 ) (6 ) Limited partnership investments 2,369 — — (95) Other invested assets 44 — (3 ) — Mortgage loans  (1) 844 (40) — — Short term investments 1,436 (1 ) (10 ) — Total assets 46,875 (2,626) (230) (101) Derivative financial instruments, included in Other liabilities (3 ) 17 — — Total securities $ 46,872 $ (2,609) $ (230) $ (101) Long term debt  (1) $ 2,896 $ (148 ) $ — $ —\n(1) Reported at amortized value in the Consolidated Balance Sheets included under Item 8 and not adjusted for fair value changes.\n(1) Reported at amortized value in the Consolidated Balance Sheets included under Item 8 and not adjusted for fair value changes.\n52"}]}
+{"image": "doclay/doclay_22041.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Segment Results\n($000) 2010 2009  2008  2010 Change 2009 Change Revenue Investment Information  $ 444,957 $ 386,642  $ 390,693  15.1% (1.0)% Investment Management  110,394 92,354  111,764  19.5% (17.4)% Consolidated revenue  $ 555,351 $ 478,996  $ 502,457  15.9% (4.7)% Operating income Investment Information  $ 127,740 $ 138,429  $ 138,659  (7.7)% (0.2)% Investment Management  56,816 52,889  60,396  7.4% (12.4)% Intangible amortization and corporate depreciation expense  (32,094) (26,349)  (20,550)  21.8% 28.2% Corporate unallocated  (31,403) (40,296)  (39,629)  (22.1)% 1.7% Consolidated operating income  $ 121,059 $ 124,673  $ 138,876  (2.9)% (10.2)% Operating margin Investment Information  28.7% 35.8%  35.5%  (7.1)pp 0.3pp Investment Management  51.5% 57.3%  54.0%  (5.8)pp 3.3pp Consolidated operating margin  21.8% 26.0%  27.6%  (4.2)pp (1.6)pp\nInvestment Information Segment\nThe Investment Information segment includes all of our data, soft- ware, and research products and services, which are typically sold  through subscriptions or license agreements.\nThe largest products in this segment based on revenue are  Morningstar Licensed Data, Morningstar Advisor Workstation,  Morningstar.com, Morningstar Direct, Morningstar Site Builder and  Licensed Tools, and Morningstar Principia. Licensed Data is a set  of investment data spanning all of our investment databases and  available through electronic data feeds. Advisor Workstation is a  web-based investment planning system for advisors. Advisor  Workstation is available in two editions: Morningstar Office for  independent financial advisors and an enterprise edition for financial  advisors affiliated with larger firms. Morningstar.com includes both  Premium Memberships and Internet advertising sales. Morningstar  Direct is a web-based institutional research platform. Site Builder  and Licensed Tools are services that help institutional clients build  customized websites or enhance their existing sites with  Morningstar’s online tools and components. Principia is our CD-ROM- based investment research and planning software for advisors.\nThe Investment Information segment also includes Morningstar  Equity Research, which we distribute through several channels. From  June 2004 through July 2009, our equity research was distributed  through six major investment banks to meet the requirements for  independent research under the Global Analyst Research Settlement  (GARS). The period covered by GARS ended in July 2009. Although  the banks covered by GARS are no longer required to provide inde- pendent research to their clients, we entered into equity research  contracts with two of the banks that were clients under GARS. We  also sell equity research to several other companies that purchase  our research for their own use or provide our research to their  affiliated financial advisors or to individual investors. In addition,  we’re continuing to provide broad equity coverage to individual  investors, financial advisors, and institutions through a variety of  other channels. In 2010, we replaced approximately one-third of the  lost annual GARS revenue with other equity research business.\nMorningstar, Inc. 2010 Annual Report 81"}]}
+{"image": "doclay/doclay_26869.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "a GLYPH<RParen1> 775 780 785 790 795 0 50 100 150 200 250 Λ GLYPH<LParen1> nm GLYPH<RParen1> t D GLYPH<LParen1> ps GLYPH<RParen1> Λ c b GLYPH<RParen1> 785 787 789 791 0 5 10 15 Λ GLYPH<LParen1> nm GLYPH<RParen1> t D GLYPH<LParen1> ps GLYPH<RParen1>\nFig. 2. (Color online) Experimental (points) and theoretical (solid lines) values of the wavelength-dependent slow light delay measured a) across the entire region around the D1 and D2 resonances and b) in the region of uniform group index between the resonances. The grey horizontal bar indicates the 6 nm region of minimal group index variation centered on λ$_{c}$ . The data correspond to a probe beam passing three times through a 7 cm vapor cell at a temperature of 280 ◦ C. The error is the same for all points and is due to uncertainties in the vapor temperature measurement.\npeak at a time t = 0. We find excellent agreement between the model and experimental data for 650 and 250-fs-long pulses centered at 787.5 and 788.4 nm after they have traveled through the cell heated to 326 and 263 ◦ C (see Fig. 3 a) and b), respectively). After propagation through the vapor, the pulses become broader and develop trailing intensity oscillations (we quantify this distortion below). Because we are working so far from the atomic resonances, we find that the main contribution to pulse distortion stems from dispersive effects ( i.e. , absorption-induced distortion is negligible), as described in Appendix. A. We also note that our system is nearly lossless; the decrease in pulse amplitude is a direct result of power redistribution rather than loss due to absorption (we calculate the absorption to be < 1%).\nWe find that our model also describes accurately pulse propagation for a broad range of temperatures. Figure 4 a) shows the output pulse shapes for identical incident 650-fs- long pulses traveling through the vapor at various temperatures. The group delay depends strongly (nearly exponentially) on the temperature, as shown in Figure 4 b), which allows\n8"}]}
+{"image": "doclay/doclay_36294.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "\nFigure 1: Illustration of the level structure of an excitonic system. The excited states | e$_{n}$ 〉 of N monomers with tran- sition frequency Ω (left part of the figure) split due to the resonance interaction into N one exciton states | ¯ u$_{n}$ 〉 (right). Absorption spectra of ensembles of non-interacting (left) and interaction (right) monomers. The system also exhibits higher excitons states (two-exciton states | ¯ U$_{n}$ 〉 are depicted here), with Ω being the mean transition frequency from the one- to two-exciton bands. A pictorial 2D spectrum with peaks re- sulting from transitions between the ground- and one-exciton states (red arrows) and one- and two-exciton states (blue ar- rows) is presented in the upper left corner of the figure. The transitions between the ground- and one-excitons states lead to positive contributions to the 2D spectrum (absorption and ground state bleach), while the transitions between the one- and two-exciton states result in a negative contribution (ex- cited state absorption).\nA. Projection operator technique and Nakajima-Zwanzig identity\nB. Convolutionless equation of motion\nWe start with the density operator W , which describes the state of the system composed of the aggregate and its surroundings. This operator fulfills Liouville-von Neu- mann equation\nHere, [ A, B ]$_{−}$ ≡ AB − BA , and we introduced Liouville superoperator L by its action on an arbitrary operator A as L A = 1 $_{ℏ}$[ H, A ]$_{−}$ . Liouville superoperators L$_{S}$ , L$_{B}$ and L$_{S}$$_{−}$$_{B}$ that correspond to Hamiltonian operators of\nThis superoperator is of course unknown, but it allows us to turn a time non-local differential equation (14) for- mally into a time-local one. We can write\nBefore we introduce approximations into Eq. (14), we can make one more formal step, which enables us to over- come its time non-local character. Let us assume an evo- lution superoperator U $^{′}$( t ) , which satisfies\nwhere the subscript I denotes interaction picture with re- spect to the bath Hamiltonian H$_{B}$ . Eq. (14) is known as Nakajima-Zwanzig identity [27, 36]. Although one can- not practically solve Eq. (14), because it is as difficult as the original complete problem, one can use it as a starting point for approximations that will follow.\nwhere w is a pure bath operator satisfying the condition tr$_{B}$ { w } = 1 . For convenience we also define a comple- mentary projection operator Q ≡ 1 − P . For the pro- jected density matrix P W ( t ) one can write a formally exact equation of motion as\nwhere tr$_{B}$ represents trace over all bath DOF, is the quantity carrying just the relevant information [27]. To derive equation of motion for ρ ( t ) we can use projection operator approach as following. We define a projection operator P by its action on an arbitrary operator A as\nWe are often not interested in the complete information carried by W ( t ) , but only in the information related to the electronic states of the aggregate. The reduced den- sity matrix (RDM) defined as\nthe system, the bath and their interaction will be used later in this paper. A formal solution of Eq. (10) can be written using evolution superoperators such that\n4\nW ( t ) = U ( t − t$_{0}$ ) W ( t$_{0}$ ) . (11)\nρ ( t ) = tr$_{B}$ { W ( t ) } , (12)\nP A = tr$_{B}$ { A } w, (13)\n∂ ∂t P W ( t ) = − i PL$_{I}$ ( t ) P W ( t ) −PL$_{I}$ ( t ) exp { − i ˆ t t 0 dτ QL$_{I}$ ( τ ) Q } Q W ( t$_{0}$ ) − t − t 0 ˆ 0 dτ $^{′}$PL$_{I}$ ( t ) exp { − i ˆ τ ′ t 0 dτ $^{′′}$QL$_{I}$ ( τ $^{′′}$) Q } × QL$_{I}$ ( t − τ $^{′}$) P W ( t − τ $^{′}$) , (14)\nP W ( t ) = U $^{′}$( t − t$_{0}$ ) P W ( t$_{0}$ ) . (15)\n∂ ∂t P W ( t ) = − i PL$_{I}$ ( t ) P W ( t )\n∂ ∂t W ( t ) = − i $_{ℏ}$[ H, W ( t )]$_{−}$ = − i L W ( t ) . (10)"}]}
+{"image": "doclay/doclay_78064.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "CHAPTER 17. PERLFAQ1\n17.1. DESCRIPTION\n17.1.3 Which version of Perl should I use?\n17.1.4 What are perl4 and perl5?\n17.1.5 What is Ponie?\n17.1.6 What is perl6?\n17.1.7 How stable is Perl?\n211\nLarry and the Perl development team occasionally make changes to the internal core of the language, but all possible e ff orts are made toward backward compatibility. While not quite all perl4 scripts run flawlessly under perl5, an update to perl should nearly never invalidate a program written for an earlier version of perl (barring accidental bug fixes and the rare new keyword).\nProduction releases, which incorporate bug fixes and new functionality, are widely tested before release. Since the 5.000 release, we have averaged only about one production release per year.\n\"We’re really serious about reinventing everything that needs reinventing.\" –Larry Wall\nPerl6 is not scheduled for release yet, and Perl5 will still be supported for quite awhile after its release. Do not wait for Perl6 to do whatever you need to do.\nIf you want to learn more about Perl6, or have a desire to help in the crusade to make Perl a better place then peruse the Perl6 developers page at http: // dev.perl.org / perl6 / and get involved.\nAt The Second O’Reilly Open Source Software Convention, Larry Wall announced Perl6 development would begin in earnest. Perl6 was an oft used term for Chip Salzenberg’s project to rewrite Perl in C ++ named Topaz. However, Topaz provided valuable insights to the next version of Perl and its implementation, but was ultimately abandoned.\nFor more details, see http: // www.poniecode.org /\nAt The O’Reilly Open Source Software Convention in 2003, Artur Bergman, Fotango, and The Perl Foundation announced a project to run perl5 on the Parrot virtual machine named Ponie. Ponie stands for Perl On New Internal Engine. The Perl 5.10 language implementation will be used for Ponie, and there will be no language level di ff erences between perl5 and ponie. Ponie is not a complete rewrite of perl5.\nSee perlhist for a history of Perl revisions.\nTo avoid the \"what language is perl5?\" confusion, some people prefer to simply use \"perl\" to refer to the latest version of perl and avoid using \"perl5\" altogether. It’s not really that big a deal, though.\nThe 5.0 release is, essentially, a ground-up rewrite of the original perl source code from releases 1 through 4. It has been modularized, object-oriented, tweaked, trimmed, and optimized until it almost doesn’t look like the old code. However, the interface is mostly the same, and compatibility with previous releases is very high. See Perl4 to Perl5 Traps in perltrap .\nPerl4 and perl5 are informal names for di ff erent versions of the Perl programming language. It’s easier to say \"perl5\" than it is to say \"the 5(.004) release of Perl\", but some people have interpreted this to mean there’s a language called \"perl5\", which isn’t the case. Perl5 is merely the popular name for the fifth major release (October 1994), while perl4 was the fourth major release (March 1991). There was also a perl1 (in January 1988), a perl2 (June 1988), and a perl3 (October 1989).\nYou should definitely use version 5. Version 4 is old, limited, and no longer maintained; its last patch (4.036) was in 1992, long ago and far away. Sure, it’s stable, but so is anything that’s dead; in fact, perl4 had been called a dead, flea-bitten camel carcass. The most recent production release is 5.8.2 (although 5.005_03 and 5.6.2 are still supported). The most cutting-edge development release is 5.9. Further references to the Perl language in this document refer to the production release unless otherwise specified. There may be one or more o ffi cial bug fixes by the time you read this, and also perhaps some experimental versions on the way to the next release. All releases prior to 5.004 were subject to bu ff er overruns, a grave security issue."}]}
+{"image": "doclay/doclay_69385.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "The process that is used to deploy an appliance includes the following steps (see Figure A-3):\nThe SSC framework provides following appliance management controls for appliance  administrators:\nAt the time of this writing, the SSC software framework provides support for the following  components:\n1. Purchasing the software appliance. \n2. Downloading the appliance image.\n3. Creating and activating the SSC LPAR.\n4. Deploying the appliance by using the appliance installer.\n5. Configuring and using the appliance through REST API or a web UI.\nGLYPH<SM590000> View messages and events\nGLYPH<SM590000> Manage network, users and disks\nGLYPH<SM590000> Export and import data\nGLYPH<SM590000> View appliance status\nGLYPH<SM590000> Apply services and updates\nGLYPH<SM590000> Support for software license\nGLYPH<SM590000> FCP and ECKD storage\nGLYPH<SM590000> Dynamic Partition Manager\nGLYPH<SM590000> User management within appliance with LDAP\nGLYPH<SM590000> Enhanced network and storage management user interface (UI)\nGLYPH<SM590000> File system with embedded CRC checking \nGLYPH<SM590000> Include KVM, qemu, virsh packages\nGLYPH<SM590000> Embedded OS upgrades\nGLYPH<SM590000> Support smart card machine unique key handling\nFigure A-3 SSC deployment in five steps\nAppendix A. IBM Secure Service Container framework  463\n"}]}
+{"image": "doclay/doclay_34080.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "3\nFigure 3: (Color) Complex bandstructure of bulk bcc Cr in the commensurate AFM (c-afm) phase along [001] for k$_{|}$$_{|}$ = 0. The real part of k$_{⊥}$ and the exponential decay rate κ (imag- inary part of k$_{⊥}$ ) are shown in panels (b) and (a, c), respec- tively. The color code of the bands indicates the irreducible representations of the point group 4 mm of the associated Bloch states. The green circles at the Fermi energy mark the complex Δ$_{1}$-band of second kind, to k$_{⊥}$ = (0 . 922 , 0 . 503) π / a , which governs the transmission of majority electrons at ¯ Γ (cf. Fig. 1a).\nFigure 2: (Color online) Fermi surface cross sections in the (100) plane of commensurate AFM Cr (c-afm). The nesting vectors along [001] (arrows) are shown in an extended zone scheme and are listed in Table I.\nTable I: Nesting vectors of commensurate AFM (c-afm) Cr along [001], as given in Fig. 2, are characterized by their os- cillation periods (in ML).\nc-afm L’ L” S A B C D’ D” λ [ML] 11.03 9.21 2.12 2.82 3.62 7.21 13.26 6.96\ndate the underlying mechanism of these oscillations. To strengthen the discussion we focus in the following on the transmissions at ¯ Γ.\nThe oscillation period can be estimated by fitting co- sine functions to the deviation of T P $_{maj}$( k$_{|}$$_{|}$ = 0) from the averaged exponential decay (black diamonds in Fig. 1b). The fit with a period of 2 ML (blue) reproduces only the peak positions but deviates significantly in amplitude. A second fit, with 2 . 17 ML period (red), hits the data best.\nThe 2 ML oscillation can be explained by the local magnetic structure of the layer-wise antiferromagnetic (LAFM) Cr interlayers (Fig. 1c). The magnetic mo- ments of the Cr layers at the Cr/MgO interface is siz- ably enhanced due to the nonmagnetic MgO film. As a consequence of these partially uncompensated magnetic moments, the Cr interface layers act as spin filters for the tunnel currents. Hence, the latter are increased (de- creased) if the magnetic moments within the Cr interface layers are parallel (anti-parallel) to the magnetization of the opposite Fe electrode. Due to the LAFM growth of the Cr interlayer the tunnel current characteristics should exhibit signatures of 2 ML oscillations. The maxima of these oscillations should arise for P (AP) magnetic config- urations of the Fe leads at even (odd) multiples of the Cr interlayer thickness x . This behaviour was already found for LAFM Mn interlayers in Fe(001)/ x (Mn)/Vac/Fe(001) MTJs $^{36}$. However, the mismatch in Fig. 1b appears like an undersampling which cannot be satisfactorily ex- plained by means of the spin filter effect. The better match of the other oscillation period with 2 . 17 ML points to another effect which additionally influences the elec- tronic transport.\nother wavelengths than the 2 ML. Firstly, one could think of spin-density waves within the Cr interlayers. Spin-density waves are found for Cr bulk systems 37 and are related to nesting vectors of the Fermi surface. Nest- ing vectors that come into question are shown in Fig. 2 for a cross section of the Fermi surface in the (100) plane. The corresponding wavelengths of these vectors along the [001] direction (i. e. in transport and growth direction) are given in Table I. The only vector that exhibits a wavelength which is comparable to that of the transmis- sion (2 . 17 ML) is S, with an oscillation period of 2 . 12 ML. However, since we are interested in the oscillatory onset at k$_{|}$$_{|}$ = 0, the vector S cannot explain our findings be- cause it is offset from ¯ Γ.\nThe oscillatory exponential decay of T P $_{maj}$( k$_{|}$$_{|}$ = 0) is explained most promisingly in terms of the complex bandstructure 38 of the Cr interlayers. Since a (continu- ous) dispersion relation is not defined for thin films, due to lack of translational invariance, we refer to the com- plex bandstructure of bulk Cr along [001]. The latter is decomposed with respect to the irreducible representa-\nThere are two possible mechanisms that may explain"}]}
+{"image": "doclay/doclay_57609.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "MongoDB Documentation, Release 3.0.4\nStep 7: Restore the config server data. For each config server, use mongorestore to restore the data dump to each config server’s data directory. Include the --drop option to drop the collections before restoring and, be- cause the backup procedure (page 258) included the --oplog option, include the --oplogReplay option for mongorestore .\nmongorestore --drop --oplogReplay /data/dump/configData\nStep 8: Start one mongos instance. Start one mongos instance. For the --configdb , specify the hostnames (and port numbers) of the config servers started in the step Deploy three new config servers. (page ?? )\nStep 9: If shard hostnames have changed, update the config database. If shard hostnames have changed , update the shards (page 742) collection in the Config Database (page 737) to reflect the new hostnames.\nStep 10: Restart all the shard mongod instances.\nStep 11: Restart the other mongos instances. Restart the remaining two mongos instances. For the --configdb , specify the hostnames (and port numbers) of the config servers started in the step Deploy three new config servers. (page ?? )\nStep 12: Verify that the cluster is operational. Connect to a mongos instance from a mongo shell and use the db.printShardingStatus() method to ensure that the cluster is operational, as follows:\ndb.printShardingStatus()\nshow collections\nMongoDB Backup Methods (page 184), Backup and Restore Sharded Clusters (page 254)\nSee also:\nRecover Data after an Unexpected Shutdown\nIf MongoDB does not shutdown cleanly 105 the on-disk representation of the data files will likely reflect an inconsistent state which could lead to data corruption. 106\nTo prevent data inconsistency and corruption, always shut down the database cleanly and use the durability journaling . MongoDB writes data to the journal, by default, every 100 milliseconds, such that MongoDB can always recover to a consistent state even in the case of an unclean shutdown due to power loss or other system failure.\nIf you are not running as part of a replica set and do not have journaling enabled, use the following procedure to recover data that may be in an inconsistent state. If you are running as part of a replica set, you should always restore from a backup or restart the mongod instance with an empty dbPath and allow MongoDB to perform an initial sync to restore the data.\nThe Administration (page 183) documents, including Replica Set Syncing (page 593), and the documentation on the --repair repairPath and storage.journal.enabled settings.\nSee also:\n105 To ensure a clean shut down, use the db.shutdownServer() from the mongo shell, your control script, the mongod --shutdown option on Linux systems, “Control-C” when running mongod in interactive mode, or kill $(pidof mongod) or kill -2 $(pidof mongod) .\n106 You can also use the db.collection.validate() method to test the integrity of a single collection. However, this process is time consuming, and without journaling you can safely assume that the data is in an invalid state and you should either run the repair operation or resync from an intact member of the replica set.\n263\n5.2. Administration Tutorials"}]}
+{"image": "doclay/doclay_19506.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "AMDOCS LIMITED\nNOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS (dollar and share amounts in thousands, except per share data)\nNote 1 — Nature of Entity\nNote 2 — Summary of Significant Accounting Policies\nBasis of Presentation\nConsolidation\nUse of Estimates\nReclassifications\nFunctional Currency\nCash and Cash Equivalents\nF-10\nCash and cash equivalents consist of cash and interest-bearing investments with insignificant interest rate risk and maturities from acquisition date of 90 days or less.\nThe Company manages its foreign subsidiaries as integral direct components of its operations. The operations of the Company’s foreign subsidiaries provide the same type of services with the same type of expenditures throughout the Amdocs group. The Company has determined that its functional currency is the U.S. dollar. The Company periodically assesses the applicability of the U.S. dollar as the Company’s functional currency by reviewing the salient indicators as indicated in the authoritative guidance for foreign currency matters.\nFrom time to time, certain immaterial amounts in prior years’ financial statements may be reclassified to conform to the current year’s presentation.\nThe preparation of financial statements in conformity with U.S. GAAP requires management to make estimates and assumptions that affect the reported amounts of assets and liabilities and disclosure of contingent assets and liabilities at the dates of the financial statements, and the reported amounts of revenue and expenses during the reporting period. Actual results could differ from those estimates.\nThe consolidated financial statements are prepared in accordance with U.S. generally accepted accounting principles, or U.S. GAAP.\nThe Company is a Guernsey corporation, which directly or indirectly holds numerous wholly-owned subsidiaries around the world. The majority of the Company’s customers are in North America, Europe, Latin America and the Asia-Pacific region. The Company’s main development facilities are located in Brazil, Canada, Cyprus, India, Ireland, Israel and the United States.\nAmdocs Limited (the “Company”) is a leading provider of software and services for communications, media and entertainment industry service providers. The Company and its subsidiaries operate in one segment, providing integrated products and services. The Company designs, develops, markets, supports, implements and operates customer experience systems primarily for leading wireless, wireline, cable and satellite service providers throughout the world. Amdocs also offers a full range of advertising and media solutions for local marketing service providers and search and directory publishers.\nThe consolidated financial statements include the accounts of the Company and its wholly-owned subsidiaries. All intercompany transactions and balances have been eliminated in consolidation."}]}
+{"image": "doclay/doclay_41177.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Table B-4. Example THC Estimate \nTable B-5. Conversion Factors \nSource: EPA and FAA,  Recommended Best Practice for Quantifying Speciated Organic Emissions from Aircraft Equipped with Turbofan,  Turbojet, and Turboprop Engines , May 27, 2009, http://www.epa.gov/otaq/regs/nonroad/aviation/420r09901.pdf  Note: \n2009, http://www.epa.gov/otaq/regs/nonroad/aviation/420r09901.pdf  Note:  $^{1 }$For the purpose of reporting, application, and comparison, the units for the compounds in this  table are referenced as follows: THC measured as methane equivalent (following Procedures in the  Emissions Certification of Aircraft Engines, Annex 16, Volume II, International Civil Aviation  Organization, TOG as TOG, VOC as VOC, and NMOG as NMOG. \nThis conversion from THC to TOG emissions i s shown in  Equation B-3  ( Conversion to TOG  Emissions ). \nEquation B-3. Conversion to TOG Emissions \nTOG Emissions (kg)  = THC Emissions (kg) x THC to TOG Conversion Factor \nTHC to  TOG  VOC to  TOG  THC to  NMHC  THC to  VOC  NMOG to  TOG  TOG to  VOC  TOG to  NMHC  1.16  1.01  1.16  1.15  1.00  0.99  1.00  Source: EPA and FAA,  Recommended Best Practice for Quantifying Speciated Organic Gas \nFuel Flow Rate (per Engine)  Time  in  Mode  (min)  Fuel  Consumption  (kg)  THC  Emission  Indices  (g/kg of  Fuel)  Number of  THC  (kg)  Mode  Rate (kg/sec)  Engines  Operations  Takeoff  1.051  1.51  95.221  0.23  2  500  21.90  Climbout  0.862  0.53  27.412  0.23  2  500  6.30  Total  278 \nSource: EPA and FAA,  Recommended Best Practice for Quantifying Speciated Organic Gas Emissions from Aircraft  Equipped with Turbofan, Turbojet, and Turboprop Engines , May 27, 2009,  http://www.epa.gov/otaq/regs/nonroad/aviation/420r09901.pdf. \nUnlike emissions from other transportation sources, international certification standards require  that HAP emissions from newly certified aircraft engines  be reported in units of methane  equivalency. Thus, for HAP emissions , the methane equivalency 57  is converted to TOG  according to the average molecular weight of the specific profile.  The factors for converting  THC to TOG, VOC to TOG and factors to/from the other groups of organic compounds (such as  Non-Methane Organic Gases - NMOG and Non-Methane Hydrocarbons - NMHC) are provided  in  Table B-5  ( Conversion Factors ). \nAPPENDIX B$_{ }$\n57  ICAO,  Procedures in the Emissions Certification of Aircraft Engines , Annex 16, Volume II,  www.icao.int. \n55$_{ }$"}]}
+{"image": "doclay/doclay_21805.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "2012 Annual Report\nCardiovascular Disease\nIn late 2012, Bristol-Myers Squibb  received regulatory approvals for  Eliquis  (apixaban) in the U.S., EU,  Japan and Canada. Tested in one of  the largest clinical trial programs ever  undertaken, it was approved to reduce  the risk of stroke and systemic embo- lism in patients with nonvalvular atrial  fibrillation, the most common cardiac  arrhythmia. Without lifelong treat- ments, these patients are at serious  risk of developing strokes. \nClinical studies comparing  Eliquis (a Factor Xa inhibitor) to warfarin, the  standard of care for almost 60 years,  found that  Eliquis  was superior in  reducing stroke and systemic embo- lism, major bleeding and mortality. In  a trial comparing  Eliquis  to aspirin in  patients who could not take warfarin,  Eliquis  showed a substantial reduc- tion in stroke risk, without a significant  increase in major bleeding compared  to aspirin.\n“While it took more than a decade to  bring  Eliquis  to patients, it remains the only drug in its class that shows  superiority against warfarin in patients  with atrial fibrillation in all three mea- sures: stroke and systemic embolism,  major bleeding and mortality,” says  Jack Lawrence, M.D.,  Eliquis  full devel- opment lead. Scientists at DuPont  Pharmaceuticals, which we acquired  in 2001, provided the first clinical  proof that direct Factor Xa inhibition  with a small molecule was an effective  approach to preventing clots.\nIn addition to recent approvals for  stroke risk reduction in atrial fibrillation,  in 2011  Eliquis  received clearance in  the EU to prevent venous thromboem- bolic events (VTEs) following elective \nNew approaches are in earlier devel-\nhip and knee replacement surgeries. \nBeyond VTE prevention in the ortho- pedic setting, the company is studying  Eliquis  for VTE treatment, with the first  of two large studies finding that  Eliquis was superior to placebo in preventing  recurrent VTEs in patients who had  completed a standard anticoagula- tion course of therapy. Treatment with  Eliquis  for an additional year reduced  the risk of the combined endpoint of  recurrent VTEs and total mortality.  Although patients on  Eliquis  are at risk  for bleeding, in this study  Eliquis  did not  show an increase in major bleeding. A  second trial is studying whether  Eliquis can replace the current standard of  care as an initial course of treatment. \nopment. For example, along with Pfizer,  our development and commercializa- tion partner for  Eliquis , Bristol-Myers  Squibb is collaborating with Portola  Pharmaceuticals to develop a novel  reversal agent for urgent clinical situa- tions where reversing the anticoagula- tion effects of certain blood thinners,  including  Eliquis , is needed. \nOther R&D efforts are focused on  heart failure, for which there are  few new effective treatments, with  a long-acting version of relaxin, a  naturally occurring peptide that has the  potential to improve cardiac function  and patient survival. Also being studied  is a next-generation anticoagulant to  treat strokes as well as a compound  that may be able to normalize the  rhythms of atrial fibrillation. Therapeutic  approaches for atherosclerosis include  a novel therapy to remove cholesterol  from plaque and a robust approach to  lowering LDL (bad) cholesterol that, \nwhen combined with statins, poten- tially would allow patients to achieve  their cholesterol-lowering goals.\nease remains the leading cause of  death worldwide. That’s why we are  developing both our cardiovascular  and metabolic disease portfolios to  focus on cardiovascular event reduc- tion. Several of our novel diabetes  agents –  Byetta  (exenatide),  Bydureon  (exenatide extended-release for  injectable suspension) and  Forxiga (dapagliflozin) – have demonstrated  reductions in weight and blood pres- sure, two major risk factors for heart  disease, while helping to control  glucose levels, a third major risk factor.  Onglyza  (saxagliptin),  Bydureon  and  Forxiga  are being studied for their  potential to be cardio-protective (also see pages 16-17).\nLawrence believes the attributes that  helped bring  Eliquis  to market will also  aid in developing a robust cardiovascu- lar pipeline. “Our success with  Eliquis speaks to the successful efforts of our  global clinical development program  that tested  Eliquis  at 4,000 sites,  exploring five potential indications con- currently in nine large Phase III studies  involving more than 60,000 patients,”  he says. “And it speaks to the talent  and dedication of biologists, chemists  and clinicians, who were involved in this  pioneering Factor Xa program starting  in 1994 and those who have stayed  with this effort to this day.” r\n12 Bristol-Myers Squibb \nEliquis  joins other company efforts  to reduce potentially debilitating and  sometimes deadly cardiovascular  events. After all, even with multiple  interventions available, heart dis-\n"}]}
+{"image": "doclay/doclay_57340.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Textfile Input and Output  131 \np  1  Q  0  R  0  S  0  T  3  U  0  V  0  W  0  X  0  Y  0  Z  0  a  5  b  2  c  5  d  3  e  13  f  2  g  4  h  6  i  10  j  2  k  2  1  3  m  7  n  4  0  10  p  2  q  2  r  6  s  5  t  7  u  5  v  2  w  2  x  2  y  2  z  2 "}]}
+{"image": "doclay/doclay_15641.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\n[in thousands of Canadian dollars, except per share amounts]\nDecember 31, 2012 and 2011\nCritical accounting estimates and judgements\n(i) Impairment of intangible assets \n(ii) Deferred tax assets\n(iii) Provisions for other liabilities\n(iv) Share-based payments\nIn the process of applying CI’s accounting policies, management has made signifi cant judgements involving estimates and  assumptions which are summarized as follows:\nIndefinite life intangible assets, including goodwill, are tested for impairment annually or more frequently if changes in  circumstances indicate that the carrying amount may be impaired. The values associated with intangibles involve estimates  and assumptions, including those with respect to future cash infl ows and outfl ows, discount rates and asset lives. These  estimates require significant judgement regarding market growth rates, fund flow assumptions, expected margins and  costs which could affect CI’s future results if the current estimates of future performance and fair values change. These  determinations also affect the amount of amortization expense on fund contracts with finite lives recognized in future  periods.\nDeferred tax assets are recognized for unused tax losses to the extent that it is probable that taxable profits will be  available against which the losses can be utilized. Significant management judgement is required to determine the amount  of deferred tax assets that can be recognized, based upon the likely timing and level of future taxable profi ts together  with future tax planning strategies. \nDue to the nature of provisions, a considerable part of their determination is based on estimates and judgements,  including assumptions concerning the future. The actual outcome of these uncertain factors may be materially different  from the estimates, causing differences with the estimated provisions. Further details are provided in Note 6. \nThe cost of employee services received (compensation expense) in exchange for awards of equity instruments recognized  is estimated using a Black-Scholes option valuation model which requires the use of assumptions. Further details regarding  the assumptions used in the option pricing model are provided in Note 7 [b].\n59"}]}
+{"image": "doclay/doclay_56595.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "APPENDIX K ITF RULES OF TENNIS\nCase 6: A player throws the racket at the ball in play. Both the racket and the ball  land in the court on the opponent’s side of the net and the opponent(s) is unable  to reach the ball. Which player wins the point?\nDecision: The player who threw the racket at the ball loses the point.\nCase 7: A ball that has just been served hits the receiver or in doubles the receiver’s  partner before it touches the ground. Which player wins the point?\nDecision: The server wins the point, unless it is a service let.\nCase 8: A player standing outside the court hits the ball or catches it before it  bounces and claims the point because the ball was definitely going out of the  correct court.\nDecision: The player loses the point, unless it is a good return, in which case the  point continues.\nIt is a good return if:\n25. A GOOD RETURN\na.  The ball touches the net, net posts/singles sticks, cord or metal cable,  strap or band, provided that it passes over any of them and hits the  ground within the correct court; except as provided in Rule 2 and 24 (d);  or\nb.  After the ball in play has hit the ground within the correct court and has  spun or been blown back over the net, the player reaches over the net  and plays the ball into the correct court, provided that the player does  not break Rule 24; or\nc.  The ball is returned outside the net posts, either above or below the level  of the top of the net, even though it touches the net posts, provided that  it hits the ground in the correct court; except as provided in Rules 2 and  24 (d); or\nd. The ball passes under the net cord between the singles stick and the  adjacent net post without touching either net, net cord or net post and  hits the ground in the correct court, or\ne. The player’s racket passes over the net after hitting the ball on the  player’s own side of the net and the ball hits the ground in the correct  court; or\n456 f.  The player hits the ball in play, which hits another ball lying in the correct  court.\n456"}]}
+{"image": "doclay/doclay_8371.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "ASTEC INDUSTRIES, INC.\n4101 Jerome Avenue Post Office Box 72787 Chattanooga, TN 37407\ntel.  423.867.4210 fax.  423.867.4127\nwww.astecindustries.com\n"}]}
+{"image": "doclay/doclay_28840.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "FIG. 2: Carbon nanotube transistor characteristics including the DC current (inset) and the RF transconductance g RF m measured in the 0 − 0 . 8 GHz band (main panel) as function of gate voltage V$_{g}$ for a representative set of (color encoded) bias voltages increasing according to the arrow. The transconductance maximum for V$_{g}$ ≃ +0 . 5 V saturates at a large value ≳ 30 µ S. Low bias data, for V$_{d}$ = − (100 , 200 , 300) mV, are fitted with Eq.(2) (solid lines) within a prefactor ≃ 0 . 6 added to account for non ideal ballistic transport above the barrier. The fitting parameter, V$_{Te}$ = k$_{B}$T$_{e}$/eβ ≃ (120 , 140 , 170) ± 0 . 01 mV, gives (with β = 0 . 2) the thermal energies k$_{B}$T$_{e}$ = (24 , 28 , 34) meV.\n9\n"}]}
+{"image": "doclay/doclay_38009.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "$_{1.b.7.}$  Oracle Server \n$_{1.b.8.}$  SAS Studio \n$_{1.b.9.}$  SAS Data Integration \n$_{1.b.10.}$ SAS Enterprise guide. \n$_{1.b.11.}$ Spark. \nc. Other programming, development, and Query languages \n$_{1.c.1.}$  Java \n$_{1.c.2.}$  Julia \n$_{1.c.3.}$  Python \n$_{1.c.4.}$  R \n$_{1.c.5.}$  Scala \n$_{1.c.6.}$  SQL \n$_{1.c.7.}$  Software Development Life Cycle \nd. Training skills \n$_{1.d.1.}$  Online and physical trainings \ne. Project management skills \n$_{1.e.1.}$  Project management skills including Agile/Scaled Agile Framework \nf. Service creation support skills \n$_{1.f.1.}$  Knowledge of ITIL practices (or equivalent) to be implemented also with the  use of professional ticketing and knowledge management tools \n2. Scientific Skills \n$_{2.a.1}$  Pesticides residues including: knowledge in interpreting and analysing  pesticide residues data and o European legislation \n$_{2.b.1}$  Chemical contaminants including: knowledge in interpreting and analysing  chemical contaminants and/or food additives data and European legislation\n18 "}]}
+{"image": "doclay/doclay_79103.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "CONTENTS\nCONTENTS\n89.4 Core Enhancements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1352 89.4.1 AUTOLOAD Is Now Lvaluable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1352 89.4.2 PerlIO is Now The Default . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1352 89.4.3 Signals Are Now Safe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1353 89.5 Modules and Pragmata . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1353 89.5.1 New Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1353 89.5.2 Updated And Improved Modules and Pragmata . . . . . . . . . . . . . . . . . . . . . . . . 1356 89.6 Performance Enhancements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.7 Utility Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8 New Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8.1 perlclib . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8.2 perliol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8.3 README.aix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8.4 README.bs2000 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8.5 README.macos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8.6 README.mpeix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1357 89.8.7 README.solaris . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1358 89.8.8 README.vos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1358 89.8.9 Porting / repository.pod . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1358 89.9 Installation and Configuration Improvements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1358 89.9.1 New Or Improved Platforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1358 89.9.2 Generic Improvements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1359 89.10 Selected Bug Fixes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1360 89.10.1 Platform Specific Changes and Fixes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1360 89.11 New or Changed Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1360 89.12 Changed Internals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1361 89.13 New Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1361 89.14 Known Problems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1361 89.14.1 AIX vac 5.0.0.0 May Produce Buggy Code For Perl . . . . . . . . . . . . . . . . . . . . . 1361 89.14.2 lib / ftmp-security tests warn ’system possibly insecure’ . . . . . . . . . . . . . . . . . . . . 1361 89.14.3 lib / io_multihomed Fails In LP64-Configured HP-UX. . . . . . . . . . . . . . . . . . . . . 1361 89.14.4 Test lib / posix Subtest 9 Fails In LP64-Configured HP-UX . . . . . . . . . . . . . . . . . . 1361 89.14.5 lib / b test 19 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1361 89.14.6 Linux With Sfio Fails op / misc Test 48 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1361 89.14.7 sigaction test 13 in VMS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1362 89.14.8 sprintf tests 129 and 130 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1362 89.14.9 Failure of Thread tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1362 89.14.10 Localising a Tied Variable Leaks Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . 1362 89.14.11 Self-tying of Arrays and Hashes Is Forbidden . . . . . . . . . . . . . . . . . . . . . . . . . 1362 89.14.12 Building Extensions Can Fail Because Of Largefiles . . . . . . . . . . . . . . . . . . . . . 1362 89.14.13 The Compiler Suite Is Still Experimental . . . . . . . . . . . . . . . . . . . . . . . . . . . 1362 89.15 Reporting Bugs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1363 89.16 SEE ALSO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1363 89.17 HISTORY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1363 90 perl570delta 1364 90.1 DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1364 90.2 Security Vulnerability Closed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1364 90.3 Incompatible Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1364 90.4 Core Enhancements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1365 90.5 Modules and Pragmata . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1365 90.5.1 New Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1365 90.5.2 Updated And Improved Modules and Pragmata . . . . . . . . . . . . . . . . . . . . . . . . 1365 90.6 Utility Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1366 90.7 New Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1366 90.8 Performance Enhancements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1366\n1696"}]}
+{"image": "doclay/doclay_43975.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Box I Double I C Plain rectangular Routed\nA 6A recommended 5A minimum 2A 6A recommended 5A minimum 15A minimum No fittings within these limits Direction of grain if spruce or outer  face grain if  plywood 1 /4 A A\nFigure 6-21.  Typical splice repair of solid rectangular spar. \nFigure 6-22.  Typical splice repair of solid rectangular spar.\nLocal damage to the top or bottom edge of a solid spar may  be repaired by removing the damaged portion and fabricating  a replacement filler block of the same material as the spar.  Full width doublers are fabricated as shown and then all three  pieces are glued and clamped to the spar. Nails or screws \nThere are numerous tools made by individuals, and there are  commercial plans for sale with instructions for building scarf-  cutting tools. Most of them work, but some are better than  others. The most important requirement for the tool is that it  produces a smooth, repeatable cut at the appropriate angle.\n6-17"}]}
+{"image": "doclay/doclay_44309.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": " iv"}]}
+{"image": "doclay/doclay_50523.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Server Option, System Variable, and Status Variable Reference\nName Cmd-Line Option File System Var Status Var Var Scope Dynamic have_profiling Yes Global No have_query_cache Yes Global No have_rtree_keys Yes Global No have_ssl Yes Global No have_statement_timeout Yes Global No have_symlink Yes Global No help Yes Yes histogram_generation_max_mem_size Yes Yes Yes Both Yes host_cache_size Yes Yes Yes Global Yes hostname Yes Global No identity Yes Session Yes immediate_server_version Yes Session Yes information_schema_stats_expiry Yes Yes Yes Both Yes init_connect Yes Yes Yes Global Yes init_file Yes Yes Yes Global No init_slave Yes Yes Yes Global Yes initialize Yes Yes initialize- insecure Yes Yes innodb Yes Yes innodb_adaptive_flushing Yes Yes Yes Global Yes innodb_adaptive_flushing_lwm Yes Yes Yes Global Yes innodb_adaptive_hash_index Yes Yes Yes Global Yes innodb_adaptive_hash_index_parts Yes Yes Yes Global No innodb_adaptive_max_sleep_delay Yes Yes Yes Global Yes innodb_api_bk_commit_interval Yes Yes Yes Global Yes innodb_api_disable_rowlock Yes Yes Yes Global No innodb_api_enable_binlog Yes Yes Yes Global No innodb_api_enable_mdl Yes Yes Yes Global No innodb_api_trx_level Yes Yes Yes Global Yes innodb_autoextend_increment Yes Yes Yes Global Yes innodb_autoinc_lock_mode Yes Yes Yes Global No innodb_background_drop_list_empty Yes Yes Yes Global Yes Innodb_buffer_pool_bytes_data Yes Global No Innodb_buffer_pool_bytes_dirty Yes Global No innodb_buffer_pool_chunk_size Yes Yes Yes Global No innodb_buffer_pool_debug Yes Yes Yes Global No innodb_buffer_pool_dump_at_shutdown Yes Yes Yes Global Yes\n656"}]}
+{"image": "doclay/doclay_73413.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Accumulated Other Comprehensive Income (Loss)\nAmounts recognized in AOCI not yet recognized as components of net periodic pension and OPEB cost, pretax, were as follows:\nAs of December 31, 2020 As of December 31, 2019 Pension OPEB Total Pension OPEB Total (In millions) Net actuarial loss (gain) $ 684.6  $ (108.6) $ 576.0  $ 685.7  $ (167.5) $ 518.2  Net prior service cost (benefit) 10.5  (4.0) 6.5  7.1  (4.9) 2.2  Total not yet recognized $ 695.1  $ (112.6) $ 582.5  $ 692.8  $ (172.4) $ 520.4 \nChanges in plan assets and benefit obligations recognized in OCI, pretax, were as follows:\nPension OPEB Total (In millions) Accumulated other comprehensive loss (income) as of December 31, 2018 $ 698.0  $ (197.3) $ 500.7  Amortization of prior service (costs) benefit (1.1) 0.7  (0.4) Amortization of net actuarial (loss) gain (10.4) 14.1  3.7  Net prior service cost (2.0) —  (2.0) Settlement and curtailment (29.8) (0.2) (30.0) Current year actuarial loss (gain) 38.5  7.4  45.9  Foreign currency exchange rate change (0.4) 2.9  2.5  Accumulated other comprehensive loss (income) as of December 31, 2019 $ 692.8  $ (172.4) $ 520.4  Amortization of prior service (costs) benefit (0.3) 0.7  0.4  Amortization of net actuarial (loss) gain (7.3) 14.5  7.2  Net prior service cost 0.8  —  0.8  Current year actuarial loss (gain) 8.1  44.0  52.1  Foreign currency exchange rate change 1.0  0.6  1.6  Accumulated other comprehensive loss (income) as of December 31, 2020 $ 695.1  $ (112.6) $ 582.5 \n120"}]}
+{"image": "doclay/doclay_59451.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Caching of Prepared Statements and Stored Programs\n| test.t1 | preload_keys | status | OK | | test.t2 | preload_keys | status | OK | +---------+--------------+----------+----------+\nThe  IGNORE LEAVES  modifier causes only blocks for the nonleaf nodes of the index to be preloaded. Thus, the statement shown preloads all index blocks from  t1 , but only blocks for the nonleaf nodes from t2 .\nIf an index has been assigned to a key cache using a  CACHE INDEX  statement, preloading places index blocks into that cache. Otherwise, the index is loaded into the default key cache.\nIt is possible to specify the size of the block buffers for an individual key cache using the key_cache_block_size  variable. This permits tuning of the performance of I/O operations for index files.\nThe best performance for I/O operations is achieved when the size of read buffers is equal to the size of the native operating system I/O buffers. But setting the size of key nodes equal to the size of the I/O buffer does not always ensure the best overall performance. When reading the big leaf nodes, the server pulls in a lot of unnecessary data, effectively preventing reading other leaf nodes.\nTo control the size of blocks in the  .MYI  index file of  MyISAM  tables, use the  --myisam-block-size option at server startup.\nA key cache can be restructured at any time by updating its parameter values. For example:\nIf you assign to either the  key_buffer_size  or  key_cache_block_size  key cache component a value that differs from the component’s current value, the server destroys the cache’s old structure and creates a new one based on the new values. If the cache contains any dirty blocks, the server saves them to disk before destroying and re-creating the cache. Restructuring does not occur if you change other key cache parameters.\nWhen restructuring a key cache, the server first flushes the contents of any dirty buffers to disk. After that, the cache contents become unavailable. However, restructuring does not block queries that need to use indexes assigned to the cache. Instead, the server directly accesses the table indexes using native file system caching. File system caching is not as efficient as using a key cache, so although queries execute, a slowdown can be anticipated. After the cache has been restructured, it becomes available again for caching indexes assigned to it, and the use of file system caching for the indexes ceases.\nFor certain statements that a client might execute multiple times during a session, the server converts the statement to an internal structure and caches that structure to be used during execution. Caching enables the server to perform more efficiently because it avoids the overhead of reconverting the statement should it be needed again during the session. Conversion and caching occurs for these statements:\n•Prepared statements, both those processed at the SQL level (using the  PREPARE  statement) and those processed using the binary client/server protocol (using the  mysql_stmt_prepare() C API function). The  max_prepared_stmt_count  system variable controls the total number of statements the server caches. (The sum of the number of prepared statements across all sessions.)\n1820\n8.10.3 Caching of Prepared Statements and Stored Programs\nmysql>  SET GLOBAL cold_cache.key_buffer_size=4*1024*1024;\n8.10.2.6 Restructuring a Key Cache\n8.10.2.5 Key Cache Block Size"}]}
+{"image": "doclay/doclay_47703.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "S T A T U T O R Y I N S T R U M E N T S\n2020 No. 494 \nHIGHWAYS, ENGLAND \nThe A6055 (A1(M) Junction 56, Barton Interchange) (Trunking)  Order 2020 \nMade - - - - 5th May 2020  Coming into force - - 19th May 2020 \nThe Secretary of State for Transport makes this Order in exercise of powers conferred by section  10(2) of the Highways Act 1980( a ) and now vested in the Secretary of State( b ):- \nIn accordance with section 10(2) of that Act, the Secretary of State has taken into consideration  the requirements of local and national planning, including the requirements of agriculture, as is  satisfied as to the expediency. \nThis Order is made in compliance with the provisions of Parts I and III of Schedule 1 of that Act. \n1.  This Order may be cited as the A6055 (A1(M) Junction 56, Barton Interchange) (Trunking)  Order 2020 and shall come into force on 19th May 2020. \n2.  In this Order “the plan” means the plan numbered HE/10/OD/005, marked “The A6055  (A1(M) Junction 56, Barton Interchange) (Trunking) Order 2020”, signed by the authority of the  Secretary of State for Transport and deposited at Communities and Local Government, Deposited  Document Services, Room F13, Ashdown House, St Leonards on Sea, Hastings, East Sussex,  TN37 7GA; \n3.  The length of highway described in the Schedule to this Order shall become trunk road from  the date when the Order comes into force. \nSigned by authority of the Secretary of State for Transport \n5th May 2020 \n( a ) 1980 c.66. Section 10 is amended by the New Roads and Street Works Act 1991 (c.22), section 22(2)(a), and the  Infrastructure Act 2015 (c.7), paragraph 10(2) of Schedule 1. There are further amendments to section 10 which are not  relevant to this Order. \n( b ) S.I. 1981/238. \nSimon Connick A Senior Civil Servant in the Department for Transport "}]}
+{"image": "doclay/doclay_12874.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "The following assets as of March 31, 2003 and 2002 were pledged as collateral for certain loans:\nAnnual maturities of long-term debts at March 31, 2003 were as follows:\nThe unexecuted balance of commitments for borrowings by the Company and consolidated subsidiaries (Subaru of America, Inc. and Subaru Europe N.V./S.A.) at March 31, 2003 were as follows:\nThe unexecuted balance of overdraft facilities and lending commitments at a consolidated subsidiary (Subaru Finance Co., Ltd.) at March 31, 2003 was as follows:\nThe Company and consolidated domestic subsidiaries have non-contributory funded defined benefit pen- sion plans. The plan of the Company covers 80% of retirement and severance benefits for employees who terminate employment at age 50 or over. Foreign subsidiaries primarily have defined contribution plans.\nportion of the overdraft facilities and lending commitments above is subject to credit considerations as documented in the customer contracts. Therefore, the total balance above is not always executable.\n12. Pension and Severance Plans\n11. Unexecuted Balance of Overdraft Facilities and Lending Commitments\nMillions Thousands of of yen U.S. dollars 2004 ¥ 57,660 $ 479,701 2005 43,373 360,840 2006 38,674 321,747 2007 25,440 211,647 2008 10,459 87,013 2009 and thereafter 31,416 261,365 ¥207,022 $1,722,313\nMillions Millions Thousands of of yen of yen U.S. dollars 2003 2002 2003 Notes and accounts receivable, trade ¥ 34,843 ¥ 22,934 $ 289,875 Other current assets 1,079 784 8,977 Property, plant and equipment 105,815 116,311 880,324 Investment securities  — 206 — Other assets — 376 — ¥141,737 ¥140,611 $1,179,176\nMillions Thousands of of yen U.S. dollars Total commitments ¥109,337 $909,626 Less amounts currently executed  19,369 161,140 Unexecuted balance ¥ 89,968 $748,486\nMillions Thousands of of yen U.S. dollars Total overdraft facilities and lending commitments ¥6,215 $51,706 Less amounts currently executed  1,980 16,473 Unexecuted balance ¥4,235 $35,233\nAnnual Report 2003 43"}]}
+{"image": "doclay/doclay_78175.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "CHAPTER 10. PERLTOOC\n10.2. CLASS DATA IN A CAN\n10.2 Class Data in a Can\n10.3 Class Data as Package Variables\nAs with any other global variable, some programmers prefer to start their package variables with capital letters. This helps clarity somewhat, but by no longer fully qualifying the package variables, their significance can be lost when reading the code. You can fix this easily enough by choosing better names than were used here.\n129\nIn the accessor methods below, we’ll for now just ignore the first argument–that part to the left of the arrow on method invocation, which is either a class name or an object reference.\nBecause a class in Perl is really just a package, using package variables to hold class attributes is the most natural choice. This makes it simple for each class to have its own class attributes. Let’s say you have a class called Some_Class that needs a couple of di ff erent attributes that you’d like to be global to the entire class. The simplest thing to do is to use package variables like $Some_Class::CData1 and $Some_Class::CData2 to hold these attributes. But we certainly don’t want to encourage outsiders to touch those data directly, so we provide methods to mediate access.\nOne of the easiest ways to solve a hard problem is to let someone else do it for you! In this case, Class::Data::Inheritable (available on a CPAN near you) o ff ers a canned solution to the class data problem using closures. So before you wade into this document, consider having a look at that module.\nThis technique is highly legible and should be completely straightforward to even the novice Perl programmer. By fully qualifying the package variables, they stand out clearly when reading the code. Unfortunately, if you misspell one of these, you’ve introduced an error that’s hard to catch. It’s also somewhat disconcerting to see the class name itself hard-coded in so many places.\nBoth these problems can be easily fixed. Just add the use strict pragma, then pre-declare your package variables. (The our operator will be new in 5.6, and will work for package globals just like my works for scoped lexicals.)\npackage Some_Class; use strict; our($CData1, $CData2); # our() is new to perl5.6 sub CData1 { shift; # XXX: ignore calling class/object $CData1 = shift if @_; return $CData1; } sub CData2 { shift; # XXX: ignore calling class/object $CData2 = shift if @_; return $CData2; }\npackage Some_Class; sub CData1 { shift; # XXX: ignore calling class/object $Some_Class::CData1 = shift if @_; return $Some_Class::CData1; } sub CData2 { shift; # XXX: ignore calling class/object $Some_Class::CData2 = shift if @_; return $Some_Class::CData2; }"}]}
+{"image": "doclay/doclay_19249.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "309\nDevelopment of shareholding in Aegon N.V.\nOther major shareholders\nThe simplified capital structure also included an amendment to the Amended 1983 Merger Agreement between Aegon N.V. and  Vereniging Aegon. Following this 2013 amendment, Vereniging Aegon’s call option relates to common shares B. Vereniging Aegon may  exercise its call option to keep or restore its total stake at 32.6%, irrespective of the circumstances which cause the total shareholding  to be or become lower than 32.6%. \nIn the years 2003 through 2010, 69,030,000 class B preferred shares were issued under these option rights. In March 2011,  Vereniging Aegon exercised its option rights to purchase in aggregate 41,042,000 class B preferred shares at par value. It did this to  correct dilution caused by Aegon’s issuance of shares conducted under Aegon’s US Shelf Registration, which comprised the sale of  173,604,912 common shares of Aegon N.V. at a price of EUR 5.20 per share in March 2011. In August 2012 and October 2012,  Vereniging Aegon exercised its option rights to purchase in aggregate 8,021,000 class B Preferred Shares at par value. It did this to  correct dilution caused by Aegon’s issuance of shares on June 15, 2012, being the final dividend 2011 in the form of stock dividend,  and its issuance of shares on September 15, 2012, being the interim dividend 2012 in the form of stock dividend. In July 2013,  Vereniging Aegon exercised its option rights to purchase in aggregate 12,691,745 Common Shares B at market value. It did this to  correct dilution caused by Aegon’s issuance of shares on May 1, 2013 and May 16, 2013 in connection with the Long Term Incentive  Plans for senior management, the issuance of shares on June 14, 2013, being the final dividend 2012 in the form of stock-dividend.\nAccordingly, at December 31, 2013, the voting power of Vereniging Aegon under normal circumstances amounts to approximately  14.58%, based on the number of outstanding and voting shares (excluding issued common shares held in treasury by Aegon N.V.). In  the event of a Special Cause, Vereniging Aegon’s voting rights will increase, currently to 32.6%, for up to six months.\nAt December 31, 2013, the General Meeting of Members of Vereniging Aegon consisted of 17 members. The majority of the voting  rights is with the 15 members who are not employees or former employees of Aegon N.V. or one of the Aegon Group companies, nor  current or former members of the Supervisory Board or the Executive Board of Aegon N.V. The two other members are elected by the  General Meeting of Members of Vereniging Aegon from the Executive Board of Aegon N.V.\nVereniging Aegon has an Executive Committee consisting of 7 members, 5 of whom are not, nor have ever been, related to Aegon,  including the chairman and the vice chairman. The other two members are also members of the Executive Board of Aegon N.V.  Resolutions of the Executive Committee, other than regarding the amendment of the Articles of Association of Vereniging Aegon, are  made with an absolute majority of the votes. When a vote in the Executive Committee results in a tie, the General Meeting of Members  has the deciding vote. Regarding the amendment of the Articles of Association of Vereniging Aegon, a special procedure requires a  unanimous proposal from the Executive Committee, thereby including the consent of the representatives of Aegon N.V. at the Executive  Committee. Following the amendment of the Articles of Association put into effect on September 13, 2005, this requirement does not  apply in the event of a hostile change of control at the General Meeting of Shareholders of Aegon N.V., in which event Vereniging  Aegon may amend its Articles of Association without the cooperation of Aegon N.V. Furthermore, the two members of the Executive  Board of Aegon N.V. who are also members of the Executive Committee have no voting rights on several decisions that relate to Aegon  N.V., as set out in the Articles of Association of Vereniging Aegon.\nTo Aegon’s knowledge based on the filings made with the Netherlands Authority for Financial Markets, the AFM, the US-based  investment management firm Dodge & Cox and the US-based investment management firm FMR LLC each hold a capital and voting  interest in Aegon N.V in excess of 3%.\nNumber of shares Common Common B Preferred A Preferred B At January 1, 2013 171,974,055 - 211,680,000 118,093,000 Exchange of Preferred A and B shares 120,713,389 566,313,695 (211,680,000) (118,093,000) Exercise option right common shares B - 12,691,745 - - At December 31, 2013 292,687,444 579,005,440 - -"}]}
+{"image": "doclay/doclay_24362.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "94 Fifth Third Bancorp \nThe following table reflects the notional amounts and fair values for all derivative instruments included in the Consolidated Balance Sheets as  of December 31:\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS \n2010 2009 Fair value Fair value  ($ in millions)  Notional  Amount  Derivative  Assets  Derivative  Liabilities  Notional  Amount  Derivative  Assets  Derivative  Liabilities  Qualifying hedging instruments :  Fair value hedges:  Interest rate swaps related to long-term debt  $4,355 $442 $ - $5,155  $275 $ - Interest rate swaps related to time deposits  - - - 771  - 6 Total fair value hedges  442 - 275 6 Cash flow hedges:  Interest rate floors related to C&I loans  1,500 153 - 1,500  162 - Interest rate swaps related to C&I loans  3,000 8 - 3,500  33 - Interest rate caps related to long-term debt  1,500 4 - 2,750  44 - Interest rate swaps related to long-term debt  1,190 - 31 -  - - Total cash flow hedges  165 31 239 - Total derivatives designated as qualifying hedging instruments  607 31 514 6 Derivatives not designated as qualifying hedging instruments  Free-standing derivatives – risk management and other  business purposes:   Interest rate contracts related to MSRs  12,477  141 81 8,592  114 24 Forward contracts related to held for sale mortgage loans 6,389 90 14 3,633 33 2 Interest rate swaps related to long-term debt  173 3 1 410 4 2 Foreign exchange contracts for trading purposes  2,494 4 4 - - - Put options associated with Processing Business Sale  769 - 8 667 - 9 Stock warrants associated with Processing Business Sale  175 79 - 152 75 - Swap associated with the sale of Visa, Inc. Class B shares  363 - 18 522 - 55 Total free-standing derivatives – risk management and other  business purposes  317 126 226 92 Free-standing derivatives - customer accommodation:  Interest rate contracts for customers  26,817  701 735 28,628  719 753 Interest rate lock commitments  1,772  9 9 1,489  3 8 Commodity contracts 1,878  99 92 805  63 58 Foreign exchange contracts  17,998  339 319 10,997  206 169 Derivative instruments related to equity linked CDs  70  2 2 113  2 2 Total free-standing derivatives – customer accommodation  1,150 1,157 993 990 Total derivatives not designated as qualifying hedging  instruments  1,467 1,283 1,219 1,082 Total $2,074 $1,314 $1,733 $1,088\nFair Value Hedges  The Bancorp may enter into interest rate swaps to convert its \nwere accounted for using the “long-haul” method. The long-haul  method requires a quarterly assessment of hedge effectiveness and  measurement of ineffectiveness. For interest rate swaps accounted  for as a fair value hedge using the long-haul method, ineffectiveness is the difference between the changes in the fair  value of the interest rate swap and changes in fair value of the  long-term debt attributable to the risk being hedged. The  ineffectiveness on interest rate swaps hedging long-term debt or  time deposits is reported within interest expense in the Consolidated Statements of Income. \nFair Value Hedges  The Bancorp may enter into interest rate swaps to convert its  fixed-rate, long-term debt or time deposits to floating-rate.  Decisions to convert fixed-rate debt or time deposits to floating are  made primarily through consideration of the asset/liability mix of  the Bancorp, the desired asset/liability sensitivity and interest rate  levels. For the years ended December 31, 2010 and 2009, certain  interest rate swaps met the criteria required to qualify for the  shortcut method of accounting. Based on this shortcut method of  accounting treatment, no ineffectiveness is assumed. For interest  rate swaps that do not meet the shortcut requirements, an  assessment of hedge effectiveness was performed and such swaps "}]}
+{"image": "doclay/doclay_80288.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "This capability is used to disallow JCL-specified LDG names. If LDG names are permitted in  the JCL, the associated data sets must be in a DFSMS tape environment. Otherwise, the  allocation fails because an LDG name restricts allocation to TS3500 tape library drives that  can be used only for system-managed volumes.\nConsideration:  An LDG name that is specified as a  UNITNAME  in JCL can be used only to  filter requests within the ACS routine. Because DFSMS replaces the externally specified  UNITNAME , it cannot be used to direct allocation to a specific library or library device type  unless  SMSHONOR  is specified on the unit parameter. For a description of  SMSHONOR  and  changes that are needed for JES3 see  z/OS JES3 Initialization and Tuning Guide ,  SA32-1003,  and z/OS MVS JCL Reference,  SA32-1005.\nAll components within z/OS and DFSMS request tape mounting and unmounting inside a  tape library. They call a Data Facility Product (DFP) service, Library Automation  Communication Services (LACS), rather than sending a write to operator (WTO), which is  done by z/OS allocation, so all mounts are deferred until job run time. The LACS support is  called at that time.\nMDS allocates an available drive from the available unit addresses for LDGW3495. It passes  that device address to z/OS allocation through the JES3 allocation SSI. At data set OPEN  time, LACS is used to mount and verify a scratch tape. When the job finishes with the tape,  either CLOSE or deallocation issues an unmount request through LACS, which removes the  tape from the drive. MDS does normal breakdown processing and does not need to  communicate with the tape library.\nIn a multi-cluster grid configuration, careful planning of the Copy Consistency Points and the  Copy Override settings can help avoid unnecessary copies in the grid and unnecessary traffic  on the grid links.\nConsider the following aspects, especially if you are using a multi-cluster grid with more than  two clusters and not all clusters contain copies of all logical volumes:\nIf you do not copy logical volumes to all of the clusters in the grid, JES3 might, for a  specific mount, select a drive that does not have a copy of the logical volume. If Retain  Copy mode is not enabled on the mounting cluster, an unnecessary copy might be forced  according to the Copy Consistency Points that are defined for this cluster in the  Management Class (MC). \nCopy Consistency Point has one of the largest influences on which cluster’s cache is used  for a mount. The Copy Consistency Point of Rewind Unload (R) takes precedence over a  Copy Consistency Point of Deferred (D). For example, assuming that each cluster has a  consistent copy of the data, if a virtual device on Cluster 0 is selected for a mount and the  Copy Consistency Point is [R,D], the CL0 cache is selected for the mount. However, if the  Copy Consistency Point is [D,R], CL1’s cache is selected.\nFor workload balancing, consider specifying [D,D] rather than [R,D]. This more evenly  distributes the workload to both clusters in the grid.\n856  IBM TS7700 Release 4.2 Guide\nGLYPH<SM590000> Copy Consistency Point\nGLYPH<SM590000> Retain Copy mode setting\nMulti-cluster grid considerations "}]}
+{"image": "doclay/doclay_22675.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "91\nAGL Energy Limited Annual Report 2011\nSignificant terms and conditions\nEnvironmental restoration\nRestructuring\nOnerous contracts\nNote 30 – Provisions (non-current)\nIn September 2010, the consolidated entity issued US$300.0 million of fixed rate unsecured senior notes in the US private placement  market, comprising two tranches of 12 year and 15 year maturities for US$165.0 million and US$135.0 million, respectively. To manage the  foreign exchange risk arising from the future principal and interest payments required on the US$300.0 million, the notes were converted  back to A$337.8 million through cross currency interest rate swaps. The weighted average interest rate at the end of the reporting period  was 7.67%.\nFinance lease liabilities are secured over the assets leased.\nMovements in each class of provision, except employee benefits are set out below:\nA provision for environmental restoration is recognised when there is a present obligation as a result of exploration, development and  production activities having been undertaken, and it is probable that an outflow of economic benefits will be required to settle the  obligation. The estimated future obligations include the costs of removing facilities and restoring the affected areas.\nA restructuring provision is recognised when the consolidated entity has developed a detailed formal plan for the restructuring and has  raised a valid expectation in those affected that it will carry out the restructuring by starting to implement the plan or announcing its main  features to those affected by it. The measurement of a restructuring provision includes only the direct expenditures arising from the  restructuring, which are those amounts that are both necessarily entailed by the restructuring and not associated with the ongoing  activities of the entity.\nA provision for onerous contracts is recognised where the consolidated entity has a contract under which the unavoidable costs of meeting  the obligations under the contract exceed the economic benefits expected to be received under it.\n2011 2010 $m $m Note 29 – Borrowings (non-current) At amortised cost USD senior notes – unsecured  274.4 – Bank loans – unsecured  – 886.7 Finance lease liabilities – secured (Note 38)  11.9 10.6 Other loans – unsecured  – 3.5 Deferred borrowing costs  (1.8) – 284.5 900.8\nEmployee benefits  7.4 5.9 Environmental restoration  49.6 39.2 Onerous contracts  104.6 117.3 Other  – 0.1 161.6 162.5\nEnvironmental Onerous restoration Restructuring contracts Other Total $m $m $m $m $m Year ended 30 June 2011 Balance at beginning of financial year  39.2 – 138.2 2.5 179.9 Additional provisions recognised  10.8 12.9 – 0.5 24.2 Acquisitions through business combinations  5.5 – 2.3 – 7.8 Provisions utilised  (0.1) – (23.1) (0.1) (23.3) Provisions reversed  – – (0.9) (1.7) (2.6) Unwinding of discount  2.4 – 9.0 – 11.4 Balance at end of financial year  57.8 12.9 125.5 1.2 197.4 Current  8.2 12.9 20.9 1.2 43.2 Non-current  49.6 – 104.6 – 154.2 57.8 12.9 125.5 1.2 197.4"}]}
+{"image": "doclay/doclay_61846.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "US 2020/0192222 Al \n14 \nJun.  18,2020 \n-continued  v-<-Q)-{  I  /  O=S  I\\  I  I  y-<-0--{  I  /  O=S  I\\  I  I  y-<:  I  I  y-<:-qo~/o  I  /  -N  0  I  I  y-<:-qo~/o  I  /  -N  0  I  I  y-<:-qo~/o  I  /  -N  0 \n-continued  I  I  y-<:-OJ;:o  o~/ o  I  /  -N  0  I  I  y-<~o  0 ~/ 0  I  /  -N  0  Iyil  O  o~/  I  HN~- ✓S=O  0 "}]}
+{"image": "doclay/doclay_56415.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "100  Pascal User  Manual \nWarning:  if a record variable pi i' created by the second form of New,  then this variable must not change  Iii\"  variant during program execution.  Assignment to the entire variable i  I  an error; however one can assign to  the components of  pi. \nThe first step in programmin  I~  a solution to our problem posed  above, is to introduce a pointer var lable. Let it be called  NewP. Then the  statement \nNew(NewP) \nallocates a new variable of type  PI  [son. \nNext the new variable, referenced by the pointer NewP, is to be  inserted after the person referenced by  Pt. See Figure 1O.d. \nFigure lO.d  Linked List Before Insertion \nInsertion is a simple matter of changing the pointers: \nNewpi.Next  := Pti.Next;  Pti.Next  := NewP \nFigure 10.e illustrates the result. \nFigure lO.c  Linked List After Insertion \nNewp~  Insert  •• \nPerson  /  New  ,  ~.  NewP  ~  .. "}]}
+{"image": "doclay/doclay_21689.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "PART II\nITEM 5  Market for the Registrant’s Common Equity,  Related Stockholder Matters and Issuer Purchases  of Equity Securities\nFMC common stock of $0.10 par value is traded on the New York Stock Exchange and the Chicago Stock Exchange (Symbol: FMC). Th  ere  were 4,041 registered common stockholders as of December 31, 2010. Presented below are the 2010 and 2009 quarterly summaries of the high  and low prices of the company’s common stock.\nCommon stock prices: 2010 2009 First Quarter Second  Quarter Th  ird  Quarter Fourth  Quarter First Quarter Second  Quarter Th  ird  Quarter Fourth Quarter High $62.24 $65.80 $69.38 $82.03 $52.00 $56.25 $58.13 $57.75 Low $50.75 $56.69 $55.64 $66.84 $34.90 $41.50 $40.69 $49.53\nOur Board of Directors has declared regular quarterly dividends since  2006; however, any future payment of dividends will depend on our  fi nancial condition, results of operations, conditions in the fi nancial  markets and such other factors as are deemed relevant by our Board  of Directors. Total cash dividends of $36.4 million, $36.3 million  and $34.4 million were paid in 2010, 2009 and 2008, respectively.\nOn February 18, 2011, our Board of Directors approved a regular  quarterly dividend of 15 cents per share to shareholders of record as \nTransfer Agent and Registrar of Stock:\nof March 31, 2011. This represents an increase of 20 percent over the  dividend of 12.5 cents per share declared on December 17, 2010 to  shareholders of record as of December 31, 2010.\nFMC’s annual meeting of stockholders will be held at 2:00 p.m. on  Tuesday, April 26, 2011, at Top of the Tower, 1717 Arch Street, 50$^{th}$  Floor, Philadelphia, PA 19103. Notice of the meeting, together with  proxy materials, will be mailed approximately 30 days prior to the  meeting to stockholders of record as of March 1, 2011.\nWells Fargo Shareowner Services Attn: Manager of Account Administration 161 North Concord Exchange South St. Paul, Minnesota 55075-1139\nStockholder Return Performance Presentation\nThe graph that follows shall not be deemed to be incorporated by  reference into any filing made by FMC under the Securities Act of  1933 or the Securities Exchange Act of 1934.\nThe following Stockholder Performance Graph compares the fi ve-year  cumulative total return on FMC’s Common Stock for the period from  January 1, 2006 to December 31, 2010 with the S&P 500 Index and  the S&P 500 Chemicals Index. The comparison assumes $100 was  invested on December 31, 2005, in FMC’s Common Stock and in  both of the indices, and the reinvestment of all dividends.\n2005 2006 2007 2008 2009 2010 FMC Corporation $50 $100 $150 $200 $250 $300 $350 S&P 500 Index S&P 500 Chemical Index\n16 FMC CORPORATION    2010 Form 10K"}]}
+{"image": "doclay/doclay_47602.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "145\n( a ) Section 102(4) was amended by section 96(1) of the Water Act 2003 (c. 37) and paragraphs 2 and 90 of Schedule 7 to the  Water Act 2014 (c. 21). \n( b ) Section 104 was amended by section 96(1) of, and Part 3 of Schedule 9 to, the Water Act 2003, section 42(3) of the Flood  and Water Management Act 2010 (c. 29) and section 11(1) and (2) of the Water Act 2014. \n( c )  S.I. 2016/1154. \n(a) any requirement for any permits under the Environmental Permitting (England and  Wales) Regulations 2016( c ) or other legislation and any other associated consents are  obtained by the undertaker, and any approval or agreement required from Anglian Water  on alternative outfall locations as a result of such re-location are approved, such  approvals from Anglian Water not to be unreasonably withheld or delayed; and \n(b) the undertaker has made the appropriate application required under the Water Industry  Act 1991 together with a plan and section of the works proposed and Anglian Water has  agreed all of the contractual documentation required under the Water Industry Act 1991,  such agreement not to be unreasonably withheld or delayed; and such works to be carried  out only in accordance with the plan and description submitted and in accordance with  such reasonable requirements as may be made by Anglian Water for the alteration or  otherwise for the protection of the apparatus, or for securing access to it. \n(a) 2.25 metres where the diameter of the pipe is less than 150 millimetres; \n(b) 3 metres where the diameter of the pipe is between 150 and 450 millimetres; \n(c) 4.5 metres where the diameter of the pipe is between 450 and 750 millimetres; and \n(d) 6 metres where the diameter of the pipe exceeds 750 millimetres, \n(a) any works, mains, pipes or other apparatus belonging to or maintained by Anglian Water  for the purposes of water supply and sewerage; \n(b) any drain or works vested in Anglian Water under the Water Industry Act 1991; and \n(c) any sewer which is so vested or is the subject of a notice of intention to adopt given under  section 102(4)( a ) (adoption of sewers and disposal works) of the Water Industry Act 1991  or an agreement to adopt made under section 104( b ) (agreements to adopt sewer, drain or  sewage disposal works, at future date) of that Act, \n“alternative apparatus” means alternative apparatus adequate to enable Anglian Water to fulfil  its statutory functions in not less efficient a manner than previously; \n“apparatus” means— \nand includes a sludge main, disposal main or sewer outfall and any manholes, ventilating  shafts, pumps or other accessories forming part of any sewer, drain, or works (within the  meaning of section 219 (general interpretation) of that Act) and any structure in which  apparatus is or is to be lodged or which gives or will give access to apparatus; \n“functions” includes powers and duties; \n“in” in a context referring to apparatus or alternative apparatus in land includes a reference to  apparatus or alternative apparatus under, over or upon land; and \n“plan” includes sections, drawings, specifications and method statements. \n71.  The undertaker must not interfere with, build over or near to any apparatus within the Order  land or carry out the placing, installation, bedding, packing, removal, connection or disconnection  of any apparatus, or carry out any filling around the apparatus (where the apparatus is laid in a  trench) within the standard protection strips which are the strips of land falling the following  distances to either side of the medial line of any relevant pipe or apparatus— \nunless otherwise agreed in writing with Anglian Water, such agreement not to be unreasonably  withheld or delayed, and such provision being brought to the attention of any agent or contractor  responsible for carrying out any work on behalf of the undertaker. \n72.  The alteration, extension, removal or re-location of any apparatus must not be implemented  until— "}]}
+{"image": "doclay/doclay_76224.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "6\nΔ ≡ t R c ( p $^{′}$, p, x ) − V R c ( p $^{′}$, p, x ) V R c ( p ′ , p, x )\nof the t-matrix. For the real part they are clearly visible at small momenta. For the imaginary part at bigger scattering angles they are relatively large, when compared to the absolute minimum of Im ( t ) and decrease with decreasing angles.\nThe t-matrices obtained using the localized screening of Eq. (5) are shown in Fig. 6 ( R = 9 fm) and Fig. 7 ( R = 55 fm). These values of the localized screening range parameter R = 9 (55) fm correspond roughly to the values of the screening radius R = 20 (120) fm for the exponential screening. The resulting t-matrices are very similar to those obtained with the exponential screening at the same angles.\nFor the exponential screening we investigated the dependence of the screened Coulomb t-matrix on the value of the screening parameter n . We found only weak dependence, as exemplified in Fig. 8 where t-matrices at θ = 10 ◦ are shown for n = 2 and n = 3. This picture can be further supplemented by parts of Fig. 2 ( n = 4) and Fig. 4 (sharp cut-off, what corresponds to infinite value of n ) at the same angle. It is seen that there is only small decreasing of the height of the diagonal ridge for the real part of the t-matrix at the smallest momenta. The minimum of the imaginary part becomes narrower and deeper with increasing n .\nFinally, we checked, how good is the approximation of the three-dimensional screened Coulomb t-matrix by the screened Coulomb potential alone. To that aim we looked at the ratio\nIn Fig. 9 we show Δ at different scattering angles, obtained for the exponential screening with R =120 fm and n =4 at E = 13 MeV. At all angles the real part of Δ does not exceed 12%. The imaginary part of Δ is below 3% for all p and p ′ values what emphasizes the smallness of the imaginary part and would indicate on validity of approximation t R c by pure screened Coulomb potential V R c . The differences between the values of t R c and V R c are biggest for p, p ′ < p$_{0}$ and around p = p$_{0}$ or p ′ = p$_{0}$ . It means that in those regions of momenta the approximation of the screened Coulomb t-matrix by the corresponding screened Coulomb potential is rather poor.\nFor the on-shell screened Coulomb t-matrix elements < p$_{0}$ ˆ p ′ | t R c ( p 2 0 $_{m}$) | p$_{0}$ ˆ p > obtained with expo- nential screening we show quality of the Born approximation in Figs. 10 and 11. There the screened Coulomb potential V R c ( p$_{0}$, p$_{0}$, x ) together with t-matrix elements are shown as a function of cosine of scattering angle θ . The screening parameters are n = 4 and R = 20 fm for Fig. 10 and n = 4 and R = 120 fm for Fig. 11\nThe real part of the screened Coulomb t-matrix (solid line) and the screened Coulomb potential (dotted line) are close to each other, and their ratio does not exceed 4% of V R c for the screening"}]}
+{"image": "doclay/doclay_43240.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "This is your first trip to today's destination. You are looking forward to the flight so that you can check out your new IFR  GPS. The only approach to your destination is a GPS stand-alone, and although you've never flown one, you have spent  about an hour of GPS practice on a PCATD. Your client just called to tell you that it is critical that you make the meeting— he is leaving town that night.\nYou are an 845-hour private pilot with an instrument rating. You are planning a 475-mile winter trip with your wife and  teenage son to visit relatives for the 3-day holiday weekend. You have recently purchased a 180 HP Cessna 172 that sports  a service ceiling of 14,000 feet.\nYou have flown over the mountains once several years ago. The most direct route to your destination requires 13,500 feet  to clear the mountain range by at least 1,000 ft. and the nearest airway Minimum Enroute Altitude is 14,000 feet. In spite  of the fact that you really want to justify the utility of your airplane to your wife, you begin to doubt that your 172 is the  right airplane for the trip.\nWhich choice from the list below reflects the best preflight risk management for this situation?\nScenario 2\nWhich of the options from the list below would make the aircraft risk factor acceptable for this trip?\nScenario 3\na. You take off as scheduled, having made arrangements at the alternate to have a rental car ready should you need to  land there and hope the weather holds.\nb. You rush your plans, leave early, and try to beat the worsening weather by arriving earlier.\nc. You decide that today is not the day to fly yourself to this destination. You move the meeting to later in the afternoon  and catch an airline flight.\na. C-172. Fly the 172, but revise your schedule to allow more travel time and change your route to one with a 10,000- foot maximum airway MEA.\nb. PA-32. Schedule the FBO’s Turbo Saratoga that you flew a couple of years ago, and get refresher checkout.\nc. C-172. Fly the 172 on the original route, but plan a stop at a 7,000-foot airport on this side of the highest ridges to  check out conditions and get local advice. Take portable oxygen.\nYou are an instrument-rated private pilot and have logged 942 hours since you started flying 5 years ago. You regularly fly  your own, well-equipped Bonanza to see your company’s customers within a 700-mile radius.\nYou are planning a 365-mile trip with Jim, your chief engineer, to visit a long-time client. You need to figure out what is  going wrong with the newly installed framis plate—your company’s newly upgraded flagship product. The client has just  landed a significant government contract, but their new framis plate is holding up production. The client is so upset, that  he is threatening to go to your competitor. You and Jim were at the office until 2:30 AM going over the calculations, and  think you have a solution. You will only need a few hours to install the changes.\nYou have logged over 6 approaches and 12 hours actual instrument time during the last 2 months including three approaches  with weather right at minimums. You also completed a Bonanza type refresher course less than a year ago.\nThe forecast for the destination airport is ¾-mile visibility in rain and 300-foot overcast, with temporary conditions of ¼  mile in rain and fog and 100-foot overcast. The ILS approach decision height is 200 feet and the visibility minimum is ½  mile. There are no thunderstorms observed or forecast and the freezing level is 2,000 feet above your filed altitude. These  conditions are widespread and the best alternate is another 100 miles beyond the destination. The weather at the alternate  just makes the legal minimums of a 600-foot ceiling and 2 miles visibility to qualify it as an alternate.\nB-3"}]}
+{"image": "doclay/doclay_80794.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Investments\nAs part of its investment strategy, the Company establishes a level of cash and highly liquid short-term and intermediate-term securities that, combined with expected cash flow, it believes is adequate to meet its payment obligations. Due to the low fixed maturity investment returns, the Company invests in equity securities, merger arbitrage securities, investment funds, private equity, loans and real estate related assets. The Company's investments in investment funds and its other alternative investments have experienced, and the Company expects to continue to experience, greater fluctuations in investment income.\nThe Company also attempts to maintain an appropriate relationship between the effective duration of the investment portfolio and the approximate duration of its liabilities (i.e., policy claims and debt obligations). The effective duration of the investment portfolio was 2.8 years at December 31, 2019 and 2018. The Company’s investment portfolio and investment-related assets as of December 31, 2019 were as follows:\n______________ (1) Pre-refunded securities are securities for which an escrow account has been established to fund the remaining payments of principal and interest through maturity. Such escrow accounts are funded almost exclusively with U.S. Treasury and U.S. government agency securities.\nFixed Maturity Securities. The Company’s investment policy with respect to fixed maturity securities is generally to purchase instruments with the expectation of holding them to their maturity. However, management of the available for sale\n($ in thousands) Carrying Value Percent of Total Fixed maturity securities: U.S. government and government agencies $ 786,931 4.0% State and municipal: Special revenue 2,422,700 12.4 Local general obligation 469,855 2.4 State general obligation 421,704 2.2 Pre-refunded (1) 390,126 2.0 Corporate backed 261,559 1.3 Total state and municipal 3,965,944 20.3 Mortgage-backed securities: Agency 859,043 4.4 Residential-Prime 432,418 2.2 Commercial 309,374 1.6 Residential-Alt A 33,130 0.2 Total mortgage-backed securities 1,633,965 8.3 Asset-backed securities 2,790,630 14.3 Corporate: Industrial 2,329,173 12.0 Financial 1,481,152 7.6 Utilities 340,641 1.7 Other 5,449 — Total corporate 4,156,415 21.3 Foreign government 847,076 4.3 Total fixed maturity securities 14,180,961 72.6 Equity securities available for sale: Preferred stocks 313,815 1.6 Common stocks 166,805 0.9 Total equity securities available for sale 480,620 2.5 Real estate 2,105,950 10.8 Investment funds 1,213,535 6.2 Cash and cash equivalents 1,023,710 5.3 Arbitrage trading account 400,809 2.1 Loans receivable 91,799 0.5 Total investments $ 19,497,384 100.0% ______________\n51"}]}
+{"image": "doclay/doclay_28295.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Equipped with (17), we are now in a position to explore the secondary stability of weakly nonlinear spatially periodic solutions of the dispersive Nikolaevskiy equation. Such solutions correspond to plane-wave solutions of (17), which exist in the form A = Pe i( ωT + qξ $^{)}$, with P = (1 − q $^{2}$)1 / 2 and ω = q $^{2}$( b − a ) − b . To study the stability of the plane-wave solution, we write A = (1 + p ( ξ, T )) Pe i( ωT + qξ $^{)}$, which, after substitution in (17) and linearization in the perturbation p , yields\nThen upon setting p ( ξ, T ) = R ( T )e i Lξ + S $^{∗}$( T )e − i Lξ and equating the coefficients of e i Lξ and e − i $^{Lξ}$, we have\nFinally, with R ( T ) and S ( T ) proportional to e $^{µT}$, and expanding the growth rate in powers of the perturbation wavenumber L , we have the dispersion relation\n$^{2}$( $^{2}$[ ]) If we suppose (as is generally the case) that a ̸ = b + d then it is apparent from (18) that the solution has a long-wavelength oscillatory instability whenever\n$^{2}$( ) Since 1 + a ( b + d ) < 3 + a ( b + d ) + 2( b + d ) $^{2}$, we see that stability is determined by the following. If 1 + a ( b + d ) > 0 then 3 + a ( b + d ) + 2( b + d ) 2 > 0, and the plane-wave solutions are stable provided\nIf instead 1 + a ( b + d ) < 0, then all plane waves are unstable. We note that setting a = b = d = 0 reduces (17) to a real Ginzburg–Landau equation for A , and our results reduce to the usual Eckhaus instability (with stability for q 2 < 1 / 3) [15, 16].\nTo apply this result to (2) it is necessary to indicate the regions in α , β parameter space in which the quantity 1 + a ( b + d ) is positive or negative. In Fig. 5, regions denoted by “s” indicate where 1 + a ( b + d ) > 0, so that there are some stable plane waves, as in (19); those\n11\n0 ≤ q 2 < q 2 c ≡ 1 + a ( b + d ) 3 + 2( b + d ) 2 + a ( b + d ) < 1 . (19)\nq $^{2}$( 3 + 2( b + d ) 2 + a ( b + d ) ) > 1 + a ( b + d ) . + a ( b + d ) + 2( b + d ) $^{2}$, we see that stability is determined by the\nµ = − 2i q ( a − b − d ) L + L $^{2}$P − $^{2}$( − 1 − a ( b + d ) + q $^{2}$[ 3 + 2( b + d ) 2 + a ( b + d ) ]) + O ( L $^{3}$) . (18) If we suppose (as is generally the case) that a ̸ = b + d then it is apparent from (18) that\nd R d T = − (1 + i a ) L ( LR + 2 qR ) − (1 + i b ) Q $^{2}$( R + S ) − i dQ $^{2}$( R + S ) , d S d T = − (1 − i a ) L ( LS − 2 qS ) − (1 − i b ) Q $^{2}$( R + S ) + i dQ $^{2}$( R + S ) .\n∂p ∂T = (1 + i a ) ( ∂ $^{2}$p ∂ξ 2 + 2i q ∂p ∂ξ ) − (1 + i b ) P $^{2}$( p ∗ + p ) + i dP $^{2}$( 〈 p + p $^{∗}$〉 − ( p + p $^{∗}$)) ."}]}
+{"image": "doclay/doclay_7758.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Personnel\nGrainCorp Foundation\nPolicies and Procedures\nTrading of GrainCorp Shares\nEthical Standards\nHealth and Safety\nRelated Party\nGrainCorp sponsors a number of rural-based community activities throughout its operating area on an ad hoc  basis. In August 2000, the Board resolved to establish  the GrainCorp Foundation which is now operating independently of the Company. GrainCorp will allocate  1 per cent of after tax profits annually to sponsorship activities. The primary objective is to provide financial support, in an objective and programmed fashion, to the rural communities in which GrainCorp is based. A review of Foundation activities is provided in this Report.\nThe Company has established a traineeship program for both graduates and grain handlers and places emphasis on training, graduate recruitment and development and is constantly reviewing career development for its employees.\nAll Directors and employees are expected to act with the utmost integrity and objectivity, striving at all times to enhance the reputation and performance of the Company. The Company has implemented a Code of Conduct and Diversity and Equity Policy for all employees. Membership of appropriate professional bodies is encouraged.\nThe following policy applies for the trading of GrainCorp shares by Directors and employees. \nThat buying or selling of GrainCorp Limited shares by Directors, officers, all staff agreement employees, contractors located at any of the Company’s offices, users of the general ledger financial systems and related parties, who are aware of price sensitive information not available to the market, be restricted to the following time periods:\nGrainCorp is committed to ensuring compliance with relevant health, safety and environmental legislation. The Board requires a best practice approach in these areas and has implemented appropriate management objectives and structures and a regular reporting process to ensure that this objective is achieved. GrainCorp’s health, safety and environmental policies are under continuous review and are updated when required. In general terms, GrainCorp’s policies are designed to eliminate injury to people and to minimise loss or damage to product stored and handled on behalf of customers. \nTransactions by Directors for storage, handling, testing, seed, sales and purchases of grain or fertiliser are undertaken on terms no more favourable than available  to other customers and apart from standard business transactions are reviewed and approved by the Chairman of the Audit Committee in accordance with the corporate governance policy of the Company.\nIt is also noted that the GrainCorp Foundation donated funds to a charitable foundation chaired by Mr Burton Taylor in compliance with the Foundation Charter.\nThese trading windows are open subject to an individual not being in possession of market-sensitive information.\n(ii) Six weeks commencing from the date of lodgement  of the half yearly accounts of GrainCorp Limited with ASIC and the ASX.\n(ii) Six weeks commencing from the date of lodgement of the preliminary final report of GrainCorp Limited with the ASX.\n(iii) Four weeks commencing from the date of the Annual General Meeting of the Company.\n34 GrainCorp 2001 Annual Report"}]}
+{"image": "doclay/doclay_52470.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "mysqlpump — A Database Backup Program\n• --include-tables  and  --exclude-tables  apply to tables. These options also affect triggers associated with tables unless the trigger-specific options are given.\n• --include-triggers  and  --exclude-triggers  apply to triggers.\n• --include-routines  and  --exclude-routines  apply to stored procedures and functions. If a routine option matches a stored procedure name, it also matches a stored function of the same name.\n• --include-events  and  --exclude-events  apply to Event Scheduler events.\n• --include-users  and  --exclude-users  apply to user accounts.\n• %  matches any sequence of zero or more characters.\n• _  matches any single character.\n•By default, with no inclusion or exclusion options,  mysqlpump  dumps all databases (with certain exceptions noted in mysqlpump Restrictions).\n•If inclusion options are given in the absence of exclusion options, only the objects named as included are dumped.\n•If exclusion options are given in the absence of inclusion options, all objects are dumped except those named as excluded.\n•If inclusion and exclusion options are given, all objects named as excluded and not named as included are not dumped. All other objects are dumped.\n•The  --all-databases  option dumps all databases (with certain exceptions noted in mysqlpump Restrictions). It is equivalent to specifying no object options at all (the default  mysqlpump  action is to dump everything).\nAny inclusion or exclusion option may be given multiple times. The effect is additive. Order of these options does not matter.\nThe value of each inclusion and exclusion option is a list of comma-separated names of the appropriate object type. For example:\nWildcard characters are permitted in the object names:\nFor example,  --include-tables=t%,__tmp  matches all table names that begin with  t  and all five- character table names that end with  tmp .\nFor users, a name specified without a host part is interpreted with an implied host of  % . For example,  u1 and  u1@%  are equivalent. This is the same equivalence that applies in MySQL generally (see Section 6.2.4, “Specifying Account Names” ).\nInclusion and exclusion options interact as follows:\nIf multiple databases are being dumped, it is possible to name tables, triggers, and routines in a specific database by qualifying the object names with the database name. The following command dumps databases  db1  and  db2 , but excludes tables  db1.t1  and  db2.t2 :\nThe following options provide alternative ways to specify which databases to dump:\n529\n--exclude-databases=test,world --include-tables=customer,invoice\nmysqlpump --include-databases=db1,db2 --exclude-tables=db1.t1,db2.t2"}]}
+{"image": "doclay/doclay_68601.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Internet Small Computer System Interface qualified name\nInternet storage name service\nInter-switch link hop\nInput/output group\nI/O throttling rate\niSCSI initiator\niSCSI session\niSCSI target\nLatency\nLeast recently used\nLicensed capacity\nInternet Small Computer System Interface (iSCSI) qualified name (IQN) refers to special  names that identify both iSCSI initiators and targets. IQN is one of the three name formats  that is provided by iSCSI. The IQN format is  iqn.< yyyy - mm> .< reversed domain name > . For  example, the default for an SVC node can be in the following format:\niqn.1986-03.com.ibm:2145.< clustername >.< nodename >\nThe Internet Storage Name Service (iSNS) protocol that is used by a host system to manage  iSCSI targets and the automated iSCSI discovery, management, and configuration of iSCSI  and FC devices. It was defined in Request for Comments (RFC) 4171.\nAn inter-switch link (ISL) is a connection between two switches and counted as one ISL hop.  The number of hops is always counted on the shortest route between two N-ports (device  connections). In an SVC environment, the number of ISL hops is counted on the shortest  route between the pair of nodes that are farthest apart. The SVC supports a maximum of  three ISL hops.\nA collection of volumes and node relationships that present a common interface to host  systems. Each pair of nodes is known as an I/O group.\nThe maximum rate at which an I/O transaction is accepted for a volume.\nAn initiator functions as an iSCSI client. An initiator typically serves the same purpose to a  computer as a SCSI bus adapter would, except that, instead of physically cabling SCSI  devices (like hard drives and tape changers), an iSCSI initiator sends SCSI commands over  an IP network. \nThe interaction (conversation) between an iSCSI Initiator and an iSCSI Target. \nAn iSCSI target is a storage resource located on an iSCSI server.\nThe time interval between the initiation of a send operation by a source task and the  completion of the matching receive operation by the target task. More generally, latency is the  time between a task initiating data transfer and the time that transfer is recognized as  complete at the data destination.\nLeast recently used (LRU) pertains to an algorithm used to identify and make available the  cache space that contains the data that was least recently used.\nThe amount of capacity on a storage system that a user is entitled to configure.\nAppendix C. Terminology  805"}]}
+{"image": "doclay/doclay_42735.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Safety Management System Overview \nSection 1 \n2 \n1.1_SMSM_201509 Originally published September 2015 Uncontrolled copy when downloaded\n• Provide a common framework to proactively and reactively identify and address safety hazards and risks associated with NAS equipment, operations, and procedures;\n• Encourage intra-agency stakeholders to participate in solving the safety challenges of an increasingly complex NAS;\n• Reduce isolated analysis and decision-making using integrated safety management principles;\n• Improve accountability for safety through defined managerial roles and responsibilities and S afety  R isk  M anagement  processes;\n• Integrate Safety Assurance processes that enable the ATO to effectively measure safety performance;\n• Promote a continuous cycle of assessing, correcting/mitigating, and monitoring the safety of air navigation services;\n• Foster a positive safety culture that can help improve system safety; and\n• Measure the performance and support the improvement of the SMS.\n1.1.4  SMS Benefits  ATO processes and tools that support the SMS help: \n1.1.4  SMS Benefits  ATO processes and tools that support the SMS help: \ninitiatives on significant causes, events, and hazards that necessitate remedial action, thus,  advancing risk-based decision-making initiatives. "}]}
+{"image": "doclay/doclay_68575.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Guide for Hybrid Cloud , REDP5319  ( http://www.redbooks.ibm.com/abstracts/redp5319.html?Open ).\nWhen we make a statement that IBM API Connect is  deployed  into a particular 3rd party  cloud, we might actually mean a few different things. For example, the topology might be  customer managed (in the same way that it would be, if it were on-premises), or it might be  managed by IBM. It might be a public managed platform where it is shared with other  customers, or it might be dedicated/reserved for the customer. In this section, we walk  through the various possibilities of what deploying to cloud can mean, and their relative  benefits. \nIBM API Connect installations are provided in Container/Kubernetes and OVA VMware form  factors to run virtually anywhere. Keep in mind that OVA installations are based on  Kubernetes internally, giving customers some of the benefits of a cloud-native solution  without having to install their own Kubernetes environment.\nTherefore, IBM API Connect can be deployed with Kubernetes, IBM Cloud Pak for  Integration, and OVA (VMWare) and Red Hat OpenShift for maximum flexibility to enable a  true hybrid or multicloud adoption.\nIBM API Connect is available in three different deployment options described in this list: \n5.3.4 Product deployment options\n1. IBM Managed API Connect on IBM Cloud IBM API Connect is available on IBM Cloud in three different options, which gives you  different flexibility and isolation options:\na. IBM Cloud Public:  This format leverages the advantages of hosting the services on  the public IBM Cloud architecture. The Public cloud includes the following key features:\nGLYPH<129> No additional hardware requirements.\nGLYPH<129> No special firewall requirements.\nGLYPH<129> Easy to pair with other IBM Cloud services.\nb. IBM Cloud Dedicated:  Cloud Dedicated is a Cloud environment that is set up  specifically for your organization and is managed by the IBM operations team. The  Cloud dedicated deployment includes the following key features:\nGLYPH<129> No additional hardware requirements.\nGLYPH<129> More security because you are removed from the public cloud.\nGLYPH<129> A single-tenant environm ent that enables a higher level of stability.\nc. IBM API Connect Reserved Instance:  This option offers an individual API Connect  instance that runs on IBM-managed infrastructure. Reserved Instance provides value  by balancing the flexibility of a shared in Reserved Instance infrastructure with the  isolation of a single-tenant deployment based on the topology and functionality of API  Connect. Reserved Instance offers the following key features:\nGLYPH<129> Common log-in with other IBM services that use IBMid.\nGLYPH<129> Isolation from other users of the IBM Cloud public service.\nGLYPH<129> Managed, monitored, and operated by the API Connect operations team.\nGLYPH<129> Deployed across multiple pods within the datacenter-zone for resilience.\nGLYPH<129> Optionally deployed as a Hig h Availability (HA) deployment with a 99.95% SLA, for  an additional cost.\nChapter 5. IBM Cloud Pak for Integration  151"}]}
+{"image": "doclay/doclay_43977.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "8/15/19\nAIM \nFIG 6 − 3 − 5 Wind − Swell − Ditch Heading\nGOOD GOOD !! BACK SIDE POOR!!! FACE GOOD FAIR BEST DIRECTION OF SWELL MOVEMENT Landing parallel to the major swell Landing on the face and back of swell\na. A successful aircraft ditching is dependent on three primary factors. In order of importance they are:\n1. Sea conditions and wind.\n2. Type of aircraft.\n3. Skill and technique of pilot.\nb. Common oceanographic terminology.\n1. Sea. The condition of the surface that is the result of both waves and swells.\n2. Wave  (or Chop). The condition of the surface caused by the local winds.\n3. Swell. The condition of the surface which has been caused by a distance disturbance.\n4. Swell Face. The side of the swell toward the observer. The backside is the side away from the observer. These definitions apply regardless of the direction of swell movement.\n5. Primary Swell. The swell system having the greatest height from trough to crest.\n6. Secondary Swells. Those swell systems of less height than the primary swell.\n7. Fetch. The distance the waves have been driven by a wind blowing in a constant direction, without obstruction.\n8. Swell Period. The time interval between the passage of two successive crests at the same spot in the water, measured in seconds.\n9. Swell Velocity. The speed and direction of the swell with relation to a fixed reference point, measured in knots. There is little movement of water in the horizontal direction. Swells move primarily in a vertical motion, similar to the motion observed when shaking out a carpet.\n10. Swell Direction. The direction  from  which a swell is moving. This direction is not necessarily the result of the wind present at the scene. The swell may be moving into or across the local wind. Swells, once set in motion, tend to maintain their original direction for as long as they continue in deep water, regardless of changes in wind direction.\nDistress and Urgency Procedures\n6 − 3 − 4"}]}
+{"image": "doclay/doclay_39432.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "- Regelverhalten: EIN-/AUS Regler, PID Regler (2 - Punkt und stetig)  Schalttafeleinbau  Fabrikat/Typ: PMA/Digital 280 -1  Oder gleichwertig  Fabrikat : ..........................  Typ: ..................................  Summe Pos. 10.4 (Liefern + Montieren) ………………  ………………  Summe Pos. 10 (liefern + montieren): ……………… "}]}
+{"image": "doclay/doclay_80388.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "The Network Diagnostics window can be used to initiate ping or trace route commands to any  IP address or host name from this TS7700 cluster. The user can use these commands to test  the efficiency of grid links and the network system. \nFigure 9-81 shows the navigation to the Network Diagnostics window and a ping test  example.\nThe following information is shown on this window:\nImportant:  The  Traceroute  command is intended for network testing,  measurement, and management. It imposes a heavy load on the network and  should not be used during normal operations.\n516  IBM TS7700 Release 4.2 Guide\n– IP Address/Hostname: The target IP address or host name for the selected network  test. The value in this field can be an IP address in IPv4 or IPv6 format or a fully  qualified host name. \n– Traceroute: Select this option to initiate a trace route test against the IP address or host  name that is entered in the IP Address/Hostname field. This option traces the path that  a packet follows from the accessing cluster to a target address and displays the  number of times packets are rebroadcasted by other servers before reaching their  destination.\n– Ping: Select this option to initiate a ping test against the IP address or host name  entered in the IP Address/Hostname field. This option tests the length of time that is  required for a packet of data to travel from the computer to a specified host, and back  again. This option can test whether a connection to the target IP address or host name  is enabled, the speed of the connection, and the distance to the target.\nGLYPH<SM590000> Network Test: The type of test to be run from the accessing cluster. The following values  are available:\nNetwork Diagnostics window\nFigure 9-81 Network Diagnostics window\n"}]}
+{"image": "doclay/doclay_65205.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "US 9,063,416 B2 \n73 \n74 \n-continued \n-continued \n(a2-0-12b) \nIn the formulas, R andA’ are the same as defined above; and  each of c to e independently represents an integer of  1  to 3.  -Structural Unit (a2L): \nExamples of the structural unit (a2L) include structural  units represented by the aforementioned general formula ( a2- 0) in which the R$^{28 }$group has been substituted with a lactone- containing cyclic group. Specific examples include structural  units represented by general formulas ( a2-1) to ( a2-5) shown  below. \n[Chemical Formula 32] \n(a2-1) \n(a2-2) \nR  ~o  $^{0 }$\\  R’-.:...Tir  -1- R’  A\"  0  0  -continued  (a2-3) \n(a2-4) \nR  (a2-5)  ~o  0  \\  0  (D1Do \nIn the formulas, R represents a hydrogen atom, an alkyl  group of  1  to 5 carbon atoms or a halogenated alkyl group of  1  to 5 carbon atoms; each R’ independently represents a  hydrogen atom, an alkyl group, an alkoxy group, a haloge- nated alkyl group, a hydroxy group, -COOR\", -OC(=O)  R\", a hydroxyalkyl group, or a cyano group, wherein R\"  represents a hydrogen atom or an alkyl group; R$^{29 }$represents  a single bond or a divalent linking group; s\" represents an  integer of0 to 2;A\" represents an oxygen atom, a sulfur atom  or an alkylene group of  1  to 5 carbon atoms which may  contain an oxygen atom or a sulfur atom; and m represents  0  or  1. \nIn general formulas (a2-1) to (a2-5), R is the same as  defined above. \nAs the alkyl group, alkoxy group, halogenated alkyl group,  ----COOR\",---OC(=O)R\" andhydroxyalkylgroup forR’, the  same alkyl groups, alkoxy groups, halogenated alkyl groups,  --COOR\", ---OC(=O)R\" and hydroxyalkyl groups as those  described above as the substituent which a -SO$_{2}$ - contain- ing cyclic group may have, can be mentioned. \nIn terms of industrial availability, R’ is preferably a hydro› gen atom. \nThe alkyl group for R\" may be any of linear, branched or  cyclic. \nWhen R\" is a linear or branched alkyl group, it preferably  has  1  to  10  carbon atoms, more preferably  1  to 5 carbon  atoms. "}]}
+{"image": "doclay/doclay_24213.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "\nFront row:  Dudley S. Taft, Jewell D. Hoover, John J. Schiff Jr., Kevin T. Kabat, William M. Isaac Second row:  Dr. Mitchel D. Livingston, James P. Hackett, Darryl F. Allen, Marsha C. Williams Third row:  Emerson L. Brumback, Hendrik G. Meijer, Gary R. Heminger, Ulysses L. Bridgeman Jr. \nFifth Third Bancorp is committed to maintaining  strong corporate governance practices. As  measured by RiskMetrics Group, Fifth Third’s  Governance Risk Indicators (GRId) classify Audit,  Board Structure, Compensation and Shareholder  Rights as Low Concern, the best possible rating.\nthe board. Mr. Isaac brings a wealth of experience  to the board, having spent his career in the banking  industry and serving as Chairman of the FDIC  from 1981 to 1985. The addition of a non-executive  chairman to the board of directors improves our  already strong corporate governance practices and  provides support to the executive leadership team. \nFor more on Fifth Third’s corporate governance,  visit  www.53.com. \nFifth Third’s board is controlled by a majority of  independent outsiders. In May of 2010, Fifth Third  appointed William Isaac to the role of chairman of \n2010  ANNUAL REPORT\n7\nCorporate  Governance"}]}
+{"image": "doclay/doclay_58220.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Server SQL Modes\nstatement to skip to the next row instead of aborting. (For nonignorable errors, an error occurs regardless of the  IGNORE  keyword.)\nExample: If the table  t  has a primary key column  i  containing unique values, attempting to insert the same value of  i  into multiple rows normally produces a duplicate-key error:\nWith  IGNORE , the row containing the duplicate key still is not inserted, but a warning occurs instead of an error:\nExample: If the table  t2  has a  NOT NULL  column  id , attempting to insert  NULL  produces an error in strict SQL mode:\nIf the SQL mode is not strict,  IGNORE  causes the  NULL  to be inserted as the column implicit default (0 in this case), which enables the row to be handled without skipping it:\nThese statements support the  IGNORE  keyword:\n For partitioned tables where no partition matching a given value is found,  IGNORE  causes the insert operation to fail silently for rows containing the unmatched value.\n980\n• LOAD DATA ,  LOAD XML : With  IGNORE , rows that duplicate an existing row on a unique key value are discarded.\n• INSERT : With  IGNORE , rows that duplicate an existing row on a unique key value are discarded. Rows set to values that would cause data conversion errors are set to the closest valid values instead.\n• DELETE :  IGNORE  causes MySQL to ignore errors during the process of deleting rows.\n• CREATE TABLE ... SELECT :  IGNORE  does not apply to the  CREATE TABLE  or  SELECT  parts of the statement but to inserts into the table of rows produced by the  SELECT . Rows that duplicate an existing row on a unique key value are discarded.\nmysql>  CREATE TABLE t (i INT NOT NULL PRIMARY KEY); mysql>  INSERT INTO t (i) VALUES(1),(1); ERROR 1062 (23000): Duplicate entry ’1’ for key ’t.PRIMARY’\nmysql>  INSERT IGNORE INTO t (i) VALUES(1),(1); Query OK, 1 row affected, 1 warning (0.01 sec) Records: 2 Duplicates: 1 Warnings: 1 mysql>  SHOW WARNINGS; +---------+------+-----------------------------------------+ | Level | Code | Message | +---------+------+-----------------------------------------+ | Warning | 1062 | Duplicate entry ’1’ for key ’t.PRIMARY’ | +---------+------+-----------------------------------------+ 1 row in set (0.00 sec)\nmysql>  CREATE TABLE t2 (id INT NOT NULL); mysql>  INSERT INTO t2 (id) VALUES(1),(NULL),(3); ERROR 1048 (23000): Column ’id’ cannot be null mysql>  SELECT * FROM t2; Empty set (0.00 sec)\nmysql>  INSERT INTO t2 (id) VALUES(1),(NULL),(3); mysql>  SELECT * FROM t2; +----+ | id | +----+ | 1 | | 0 | | 3 | +----+"}]}
+{"image": "doclay/doclay_48313.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\nUnterabschnitt 2\nBesondere Wertvorschriften\nUnterabschnitt 3\nWertfestsetzung\nAbschnitt 8\nErinnerung und Beschwerde\nAbschnitt 9\nSchluss- und Übergangsvorschriften\n§ 38 Stufenantrag\n§ 39 Antrag und Widerantrag, Hilfsanspruch, wechselseitige Rechtsmittel, Aufrechnung\n§ 40 Rechtsmittelverfahren\n§ 41 Einstweilige Anordnung\n§ 42 Auffangwert\n§ 43 Ehesachen\n§ 44 Verbund\n§ 45 Bestimmte Kindschaftssachen\n§ 46 Übrige Kindschaftssachen\n§ 47 Abstammungssachen\n§ 48 Ehewohnungs- und Haushaltssachen\n§ 49 Gewaltschutzsachen\n§ 50 Versorgungsausgleichssachen\n§ 51 Unterhaltssachen und sonstige den Unterhalt betreffende Familiensachen\n§ 52 Güterrechtssachen\n§ 53 Angabe des Werts\n§ 54 Wertfestsetzung für die Zulässigkeit der Beschwerde\n§ 55 Wertfestsetzung für die Gerichtsgebühren\n§ 56 Schätzung des Werts\n§ 57 Erinnerung gegen den Kostenansatz, Beschwerde\n§ 58 Beschwerde gegen die Anordnung einer Vorauszahlung\n§ 59 Beschwerde gegen die Festsetzung des Verfahrenswerts\n§ 60 Beschwerde gegen die Auferlegung einer Verzögerungsgebühr\n§ 61 Abhilfe bei Verletzung des Anspruchs auf rechtliches Gehör\n§ 61a Verordnungsermächtigung\n§ 62 (weggefallen)\n§ 62a Bekanntmachung von Neufassungen\n§ 63 Übergangsvorschrift\n- Seite 3 von 35 -"}]}
+{"image": "doclay/doclay_75298.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "3\nCONSOLIDATED INFORMATION\nSodexo Consolidated Financial Statements as of August 31, 2013\n3\n› (in millions of euro) Notes Fiscal 2013 Fiscal 2012 Profit for the year 462 550 Components of other comprehensive income to be  reclassified subsequently to profit or loss Change in fair value of available for sale financial assets 4.11.3 and 4.14 1 1 Change in fair value of available for sale financial assets  reclassified to profit or loss 4.11.3 and 4.14 Change in fair value of c ash f low h edges 4.16 and 4.14 0 (21) Change in fair value of c ash f low h edges reclassified  to profit or loss 4.16 and 4.14 12 13 Currency translation differences (342) 287 Tax on components of other comprehensive income  to be reclassified subsequently to profit or loss 4.14 (4) 3 Share of other components of comprehensive income  of companies consolidated by the equity method, net of tax 4.14 7 (9) Components of other comprehensive income that  will not be reclassified subsequently to profit or loss Actuarial gain (loss) on defined benefit pension plans 4.17.1 and 4.14 (11) (98) Tax on components of other comprehensive income  that will not be reclassified subsequently to profit or loss 4.14 5 23 Total other comprehensive income (loss), after tax (332) 199 COMPREHENSIVE INCOME 130 749 Of which: Equity holders of the parent 109 720 Non-controlling interests 21 29\n3.2.2 CONSOLIDATED STATEMENT OF COMPREHENSIVE INCOME\n›\n143 Sodexo  - Registration Document Fiscal 2013"}]}
+{"image": "doclay/doclay_6435.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "FIRST COMMONWEALTH FINANCIAL CORPORATION AND SUBSIDIARIES\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS (Dollar Amounts in Thousands, except per share data)\nThe following table identifies the related tax effects allocated to each component of other comprehensive income in the Statements of Changes in Shareholders’ Equity:\nexpense by $920 in 2002. Goodwill amortization expense was $920 and $865 for 2001 and 2000, respectively. Goodwill represented basic and diluted earnings per share of $0.016 and $0.015 for 2001 and 2000, respectively. Upon implementation of the standard, the Corporation determined no impairment of its outstanding goodwill existed.\nEffective March 1, 2002, the Corporation acquired all of the outstanding shares of Strategic Capital Concepts, Inc. (“SCC”) and Strategic Financial Advisors, Inc. (“SFA”), each a Pennsylvania corporation headquartered in Allison Park, Pennsylvania. As a registered investment adviser, Strategic Capital Concepts provides financial planning, asset management and consulting services to individuals, businesses, retirement plans, trusts, and estates. Strategic Financial Advisors offers investment and insurance products as well as employee benefit services. Each of the outstanding shares of Strategic Capital Concepts, Inc. and Strategic Financial Advisors, Inc. were exchanged for shares of the Corporation’s common stock. In addition, the shareholders of SCC and SFA are entitled to receive additional shares of the Corporation’s common stock for each of the years 2002 through 2005 based on a formula defined in the merger agreement which takes into consideration the financial performance of SCC and SFA after the merger date. The merger was accounted for as a purchase transaction whereby the identifiable tangible and intangible assets and liabilities of SCC and SFA have been recorded at their fair values at the acquisition date. Goodwill in the amount of $1,656 was recorded as a result of the transaction. As prescribed under the purchase method of accounting, the results of operations of SCC and SFA from the date of acquisition are included in the Corporation’s financial statements for 2002.\nIn October 2002, SFA was merged into SCC and the name was changed to First Commonwealth Financial Advisors, Inc. This acquisition should expand the Corporation’s product offerings and positively impact fee based revenue, which is a continuing priority.\nAs of January 1, 2002, the Corporation discontinued the amortization of goodwill which reduced other operating\n24\nOn January 1, 2002, the Corporation adopted FASB Statement No. 142, “Goodwill and Other Intangible Assets” (“FAS No. 142”), which addresses the accounting and reporting for acquired goodwill and other intangible assets which supersedes APB Opinion No. 17, “Intangible Assets.” FAS No. 142 includes requirements to test goodwill and indefinite-lived intangible assets for impairment rather than amortize them. As of January 1, 2002, the Corporation had goodwill, net of accumulated amortization, of approximately $5,800 subject to the transitional testing provisions of FAS No. 142. Also, management reclassified an intangible asset previously recorded by an insurance subsidiary when acquiring the expiring list of policy holders from their joint-venture partner to goodwill with a net carrying amount of $718.\nNOTE 4— Goodwill and Other Intangible Assets\nNOTE 5— Business Combination\nNOTE 3— Supplemental Cash Flow Disclosures\nNOTE 2— Supplemental Comprehensive Income Disclosures\nDecember 31, 2002 December 31, 2001 December 31, 2000 Tax Net of Tax Net of Tax Net of Pre-tax (Expense) Tax Pre-tax (Expense) Tax Pre-tax (Expense) Tax Amount Benefit Amount Amount Benefit Amount Amount Benefit Amount Unrealized gains (losses) on securities: Unrealized holding gains (losses) arising during the period $ 26,987 $ (9,445) $ 17,542 $ 28,676 $(10,037) $ 18,639 $ 51,739 $(18,109) $ 33,630 Less: reclassification adjustment for gains realized in net income (606) 212 (394) (3,274) 1,146 (2,128) (1,745) 611 (1,134) Net unrealized gains (losses)  26,381 (9,233) 17,148 25,402 (8,891) 16,511 49,994 (17,498) 32,496 Other comprehensive income $ 26,381 $ (9,233) $ 17,148 $ 25,402 $ (8,891) $ 16,511 $ 49,994 $(17,498) $ 32,496\n2002 2001 2000 Cash paid during the year for: Interest $ 124,953 $ 186,558 $ 166,919 Income taxes $ 12,010 $ 11,890 $ 12,842 Noncash investing and financing activities: ESOP loan reductions $ 1,071 $ 1,161 $ 906 Loans transferred to other real estate owned and repossessed assets $ 5,029 $ 5,246 $ 6,405 Gross increase in market value adjustment to securities available for sale $ 26,381 $ 25,402 $ 49,994 Treasury stock reissued for insurance agency interest acquired $ -0- $ -0- $ 852 Treasury stock reissued for business combination $ 830 $ -0- $ -0-"}]}
+{"image": "doclay/doclay_18996.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "PART I ITEM 1B Unresolved Staff Comments\nUnresolved Staff Comments ITEM 1B\nProperties ITEM 2\nNone.\nServices, Core Medical and Service Operations and the domestic office of Cigna’s Global Supplemental Benefits business are the Wilde Building located at 900 Cottage Grove Road in Bloomfield, Connecticut (Cigna’s corporate headquarters) and Two Liberty Place located at 1601 Chestnut Street in Philadelphia, Pennsylvania. The Wilde Building measures approximately 833,000 square feet and is owned, while Two Liberty Place measures approximately 462,000 square feet and is leased office space.\nCigna’s global real estate portfolio consists of approximately 8.1 million square feet of owned and leased properties. Our domestic portfolio has approximately 6.7 million square feet in 40 states, the District of Columbia, and Puerto Rico. Our International properties contain approximately 1.4 million square feet located throughout the following countries: Belgium, Canada, China, France, Germany, Hong Kong, India, Indonesia, Ireland, Italy, Malaysia, Netherlands, New Zealand, Singapore, South Korea, Spain, Sweden, Switzerland, Taiwan, Thailand, Turkey, United Arab Emirates, and the United Kingdom.\nCigna believes its properties are adequate and suitable for its business as presently conducted. The foregoing does not include information on investment properties.\nOur principal, domestic office locations, including various support operations, along with Group Disability and Life Insurance, Health\nThe information contained under ‘‘Litigation and Other Legal Matters’’ in Note 24 to Cigna’s Financial Statements beginning on page 122 of this Form 10-K, is incorporated herein by reference.\nNot applicable.\nMine Safety Disclosures ITEM 4\nLegal Proceedings ITEM 3\n28 CIGNA CORPORATION -  2012 Form  10-K"}]}
+{"image": "doclay/doclay_61878.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "US 2019/0064665 Al \n12 \nFeb.28,2019 \n(a) \n(b) \n0  0 [0101]  In,.  iormulae ( )  methyl or t  .fl  a and (b)  RA  .  h  n uorometh I  zA  . ’  is  ydroge  fl  .  group, naphthyl  y .  is a sing!  b  n,  uonne  z•  eneg  eondh  ’  -, wherein Z’ i  rou~ or (backbone) C(’ p enylene  alkyl  s a straight b  - =0) o  ene group wh• h  ’ ranched  - - bond, ester bond ic  may contain ah  dr  or cycl)c C1 -C10  naphthylene grou o~la~tone ring, o/ph~:y~ mmety, ether  gen or a polar  p.  is an acid labile  y ene group or  from mnon  hgroup having at least  group.  yA  is hydro- b  g  ydroxyl  one structu  ond, ester b  , cyano  carb  re selected  lactone ring,  ~~f;  sulf~nic acid,ester  ~~:~  carboxyl, ether  [0102]  E  one =s and c,ri,oxylic ;;::y’:~date bond, \nxmnples of h  I e.  wherein  zA  •  .  t e structur  h  .  h  1s a vari  t  e  avmg £  t ereto. Notabl  RA  an are shown be!  b  ormula (a)  y,  and  XA  are as defi owd,  ut not limited  ne  above. "}]}
+{"image": "doclay/doclay_10017.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "A summary of changes in the status of stock options awarded to of ficers and employees of the Companies as of December 31, 2003, 2002 and 2001 is as follows:\nThe following table summarizes stock options outstanding at December 31, 2003 for each plan year for the Companies:\nCon Edison Con Edison of New York O&R We ighted Weighted Weighted Average Average Average Exercise Exercise Exercise Shares Price Shares Price Shares Price Outstanding at 12/31/00 4,790,913 $37.749 4,485,113 $37.682 73,000 $32.500 Granted 1,487,050 37.758 1,287,550 37.760 101,000 37.750 Exercised (363,013) 29.740 (363,013) 29.740 - - Forfeited (160,300) 41.333 (63,200) 41.414 - - Outstanding at 12/31/01 5,754,650 38.157 5,346,450 38.215 174,000 35.547 Granted 1,584,350 42.510 1,349,850 42.510 113,000 42.510 Exercised (413,899) 30.813 (413,199) 30.793 - - Forfeited (127,450) 44.103 (116,950) 44.491 (2,000) 35.125 Outstanding at 12/31/02 6,797,651 39.506 6,166,151 39.532 285,000 38.311 Granted 1,621,700 39.639 1,346,700 39.704 113,000 39.505 Exercised (692,175) 32.728 (660,425) 32.705 (9,500) 32.500 Forfeited (110,000) 45.365 (99,000) 45.764 - - Outstanding at 12/31/03 7,617,176 $40.065 6,753,426 $40.142 388,500 $38.800\nCon Edison Con Edison of New York O&R Weighted Weighted Weighted Remaining Average Average Average Plan Contractual Options Exercise Options Options Exercise Options Options Exercise Options Year Life Outstanding Price Exercisable Outstanding Price Exercisable Outstanding Price Exercisable 2003 9 1,619,700 $39.640 - 1,346,700 $39.704 - 113,000 $39.505 - 2002 8 1,573,850 42.510 - 1,340,350 42.510 - 113,000 42.510 - 2001 7 1,465,350 37.758 - 1,272,850 37.760 - 100,000 37.750 - 2000 6 909,200 32.499 909,200 798,700 32.499 798,700 62,500 32.500 62,500 1999 5 1,076,600 47.868 1,076,600 1,028,900 47.865 1,028,900 - - - 1998 4 667,200 42.563 667,200 660,650 42.563 660,650 - - - 1997 3 208,676 31.500 208,676 208,676 31.500 208,676 - - - 1996 2 96,600 27.875 96,600 96,600 27.875 96,600 - - - Total 7,617,176 2,958,276 6,753,426 2,793,526 388,500 62,500\nCon Edison Annual Report 2003 81"}]}
+{"image": "doclay/doclay_27111.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "32\n$^{!$_{\"#$}$}$$_{ }$  $^{!%$_{\"#$}$}$  $^{&}$  $^{’}$  Interfering Cell $ BS of Interest  !$_{\"#$}$ ( { ! $_{1}$, ! $_{2}$, GLYPH<133> !$_{)}$ , GLYPH<133> !$_{*}$ } ( { $_{1}$, $_{2}$, GLYPH<133> ,  $_{+}$ , GLYPH<133> ,  $_{,}$ } !%$_{\"#$}$ ( { !% $_{1}$, !% $_{2}$, , GLYPH<133> !%$_{-}$ , GLYPH<133> , $^{!%$_{.}$}$} \nFig. 1. Geometrical illustration of dividing the cellular network into multiple rings of non-uniform width Δ$_{k}$ ."}]}
+{"image": "doclay/doclay_69256.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Figure 5-26 shows the orders of magnitude of difference between the link bandwidths. It is  easy to see how  1920  errors can arise when your bandwidth is insufficient. Never use a  TCP/IP ping to measure RTT for FCIP traffic.\nIn Figure 5-26, the amount of time in microseconds that is required to transmit a packet  across network links of varying bandwidth capacity is compared. The following packet sizes  are used:\nFinally, your path maximum transmission unit (MTU) affects the delay that is incurred to get a  packet from one location to another location. An MTU might cause fragmentation, or be too  large and cause too many retransmits when a packet is lost.\nAfter a 1920 error occurs, the Global Mirror auxiliary volumes are no longer in a  Consistent  Synchronized  state. You must establish the cause of the problem and fix it before you restart  the relationship. \nWhen the relationship is restarted, you must resynchronize it. During this period, the data on  the Metro Mirror or Global Mirror auxiliary volumes on the secondary system is inconsistent,  and your applications cannot use the volumes as backup disks. To address this data  consistency exposure on the secondary system, a FlashCopy of the auxiliary volumes can be  created to maintain a consistent image until the Global Mirror (or the Metro Mirror)  relationships are synchronized again and back in a consistent state. \nIBM Spectrum Virtualize provides the Remote Copy  Consistency Protection  feature that  automates this process. When Consistency Protection is configured, the relationship between  the primary and secondary volumes does not go in to the  Inconsistent copying  status once  restarted. Instead, the system uses a secondary  change volume  to automatically copy the  previous consistent state of the secondary volume. \n250  IBM System Storage SAN Volume Controller, IBM Storwize V7000, and IBM FlashSystem 7200 Best \nRecovery after 1920 errors\nGLYPH<SM590000> 64 bytes: The size of the common ping packet\nGLYPH<SM590000> 1500 bytes: The size of the standard TCP/IP packet\nGLYPH<SM590000> 2148 bytes: The size of an FC frame\nFigure 5-26 Effect of packet size (in bytes) versus the link size\n"}]}
+{"image": "doclay/doclay_25304.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "ating any of the possible tags from the i th category of mRNA is\nWhen ambiguous tagging sites occur within a gene’s mRNA transcript, say sites l and m , these sites are simply excluded from the summation over j in eq. (1). The reduction in φ$_{i}$ due to tag ambiguity is greatest when an ambiguous tag is formed at the 3’ most AE site (site 1 in Figure 1) and is least when such a tag occurs in the 5’ most AE site (site k$_{i}$ ). But note that it is possible for transcripts to have multiple ambiguous AE tag formation sites. For purposes of our analysis, we will assume that the value of φ$_{i}$ has been estimated for all genes and treat these as known constants (see Gilchrist et al. (2007) for a more details on these calculations). The variation in the tag formation probability between genes stems from the two basic facts. First, genes vary in the number of AE sites they contain. Second, genes also vary in the number and location of AE sites which are ambiguous. As a result the tag pool represents a biased sample of the mRNA population of interest. The degree of bias exhibited is a function of both the distribution of tag formation probabilities across the genome, and the distribution of these genes within the mRNA population itself, as we will now demonstrate.\nAs discussed earlier, an obvious model for the observed tag data is the multinomial distri- bution. Let T$_{tot}$ = ∑ k i =1 t$_{i}$ be the total count of all observed tags. Then\n3.2 Maximum Likelihood and the Joint Posterior Distribution\nP ( T | θ ) = ( T$_{tot}$ t$_{1}$, t$_{2}$, . . . , t$_{k}$$^{)}$$^{∏}$ i θ t$_{i}$ i\n10\nφ$_{i}$ = k$_{i}$ ∑ j =1 (1 − p ) j − $^{1}$p = 1 − (1 − p ) $^{k$_{i}$}$. (1)"}]}
+{"image": "doclay/doclay_73311.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "to secure natural gas feedstock for the Liquefaction Projects, (2) income tax provision, (3) losses on modification or extinguishment of debt, (4) operating and maintenance expense, (5) depreciation and amortization expense, (6) interest rate derivative losses and (7) interest expense, net of capitalized interest. This loss was partially offset by increased gross margins primarily due to additional LNG volume available to be sold from additional Trains that have reached substantial completion between the periods, a portion of which the customers elected not to take delivery but were required to pay a fixed fee with respect to the contracted volumes.\nOur consolidated net income attributable to common stockholders was $471 million, or $1.92 per share—basic and $1.90 per share—diluted, in the year ended December 31, 2018. This $177 million increase in net income in 2019 compared to 2018 was primarily attributable to (1) increased gross margins due to increased volume of LNG sold partially offset by decreased pricing on LNG, (2) increased tax benefit from the release of a significant portion of the valuation allowance previously recorded against our deferred tax assets, (3) increased LNG revenues as a result of derivative gains on commodity derivatives and (4) decreased net income attributable to non-controlling interest, which were partially offset by an increase in (1) interest expense, net of amounts capitalized, (2) operating and maintenance expense, (3) derivative losses, net, associated with our interest rate derivatives, (4) depreciation and amortization expense and (5) losses on equity method investments.\nWe enter into derivative instruments to manage our exposure to (1) changing interest rates, (2) commodity-related marketing and price risks and (3) foreign exchange volatility. Derivative instruments are reported at fair value on our Consolidated Financial Statements. In some cases, the underlying transactions economically hedged receive accrual accounting treatment, whereby revenues and expenses are recognized only upon delivery, receipt or realization of the underlying transaction. Because the recognition of derivative instruments at fair value has the effect of recognizing gains or losses relating to future period exposure, use of derivative instruments may increase the volatility of our results of operations based on changes in market pricing, counterparty credit risk and other relevant factors.\nTotal revenues decreased during the year ended December 31, 2020 from the comparable period in 2019, primarily as a result of decreased revenues recognized by our integrated marketing function due to the recent downturn in the energy market and the absence of variable fees for cargoes in which customers notified us they would not take delivery. During the year ended December 31, 2020, we recognized $969 million in revenues associated with LNG cargoes for which customers notified us that they would not take delivery, of which $38 million would have been recognized subsequent to December 31, 2020, if the cargoes were lifted pursuant to the delivery schedules with the customers. The increase in revenue attributable to LNG volume sold during the year ended December 31, 2019 from the comparable period in 2018 was due to increased volume of LNG sold following the achievement of substantial completion of Trains between the years, partially offset by decreased LNG revenues per MMBtu, which was primarily affected by market prices realized for volumes sold by our integrated marketing function. We expect our LNG revenues to increase in the future upon Train 3 of the CCL Project and Train 6 of the SPL Project becoming operational.\nPrior to substantial completion of a Train, amounts received from the sale of commissioning cargoes from that Train are offset against LNG terminal construction-in-process, because these amounts are earned or loaded during the testing phase for the construction of that Train. During the years ended years ended December 31, 2020, 2019 and 2018, we realized offsets to LNG terminal costs of $19 million, $301 million and $140 million, corresponding to 3 TBtu, 51 TBtu and 17 TBtu, respectively, that were related to the sale of commissioning cargoes from the Liquefaction Projects.\nAlso included in LNG revenues are sale of unutilized natural gas procured for the liquefaction process, gains and losses from derivative instruments, which include the realized value associated with a portion of derivative instruments that settle through physical delivery, and revenues from arrangements in which we financially settled previously-scheduled LNG cargo\n48\nYear Ended December 31, (in millions) 2020 2019 Change 2018 Change LNG revenues $ 8,924  $ 9,246  $ (322) $ 7,572  $ 1,674  Regasification revenues 269  266  3  261  5  Other revenues 165  218  (53) 154  64  Total revenues $ 9,358  $ 9,730  $ (372) $ 7,987  $ 1,743 \nRevenues\n2020 vs. 2019 and 2019 vs. 2018"}]}
+{"image": "doclay/doclay_21048.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "NOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS (CONT’D)\nNOTE 21 Related party transactions\nThe ultimate parent\nHigh Liner Foods Incorporated is the ultimate parent entity.\nIn addition to their salaries, the Company also provides benefits to the Chief Executive Officer (“CEO”), Named Executive Officers (“NEOs”)  and Directors in the form of contributions to post-employment benefit plans on their behalf, non-cash plans and various other short- and  long-term incentive and benefit plans as described below.\nKey management personnel compensation\nFuture employee benefits\nTermination and change of control benefits\nPlease refer to  note 14  for details of each plan as applicable to the Company’s CEO and NEOs.\nThe Company has entered into Change of Control Agreements (the “Agreements”) between the Company and the CEO and NEOs. The  Agreements are automatically extended annually by one additional year unless the Company provides 90 days notice of its unwillingness to  extend the agreements.\nThe change of control agreements provide that, in the event of a termination by the Company following a change of control, other than for  cause, or by the executive for good reason, the CEO and NEOs are entitled to: (a) cash compensation equal to the final annual compensation  (including base salary and short-term incentives) multiplied by 3 for the CEO and 2 for all other NEOs; (b) the automatic vesting of any  options or other entitlements for the purchase or acquisition of shares in the capital of the Company which are not then exercisable, which  shall be exercisable following termination for 3 years for the CEO and 2 years for all other NEOs; and (c) continue to participate in certain  benefit programs for 3 years for the CEO and 2 years for all other NEOs.\nThe short-term incentive (“Bonus”) plan for the CEO and other NEOs is based on two components: (1) goals relating to financial  performance of the Company and/or an operating unit of the Company and (2) individual goals related specifically to the individual’s  responsibilities and areas of influence. The Bonus is paid as a percentage of eligible annual earnings, as reported for income taxes not  including taxable benefits, miscellaneous earnings or incentive payments.\nShort-term incentive plans\nLong-term incentive plans\nThe Company has two long-term incentive plans available for the CEO and NEOs which are the Company’s Option Plan and the Company’s  PSU Plan. Details regarding the Share Option and PSU Plans are detailed in  note 18 .\nKey management personnel compensation is comprised of:\nDirectors of the Company control 3.8% of the common shares of the Company. A number of Directors, or their related parties, hold positions  in other entities that result in them having control or significant influence over the financial or operating policies of these entities.\nThe Company has transacted with a number of these entities in the reporting period. The terms and conditions of the transactions with key  management personnel and their related parties were no more favourable than those available, or which might reasonably be expected to  be available, on similar transactions to non-key management personnel related entities on an arm’s length basis. From time to time  directors of the Company, or their related entities, may purchase goods from the Company. These purchases are on the same terms and  conditions as those entered into by other Company employees or customers.\nKey management personnel and director transactions\nDecember 28,  December 29, (Amounts in $000s) 2013 2012 Salaries $ 2,017 $ 1,958 Short-term incentive plans 318 1,087 Future employee benefits 382 496 Share-based awards 1,381 1,659 $ 4,098 $ 5,200\n92\nHIGH LINER FOODS INCORPORATED"}]}
+{"image": "doclay/doclay_2604.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "3.6 Award (ranking of tenders) \n3.7 Award of Specific Contracts in Lot 1 reopening of competition\n1. Request for offer\n2. Acceptance of the request for offer by the FWC contractors/Availability\n3. Offer by the FWC contractor\nThe tenders in each lot shall be ranked according to the highest scoring in accordance with  the formula below. \nThis formula will be applied only for offers meeting the minimum quality thresholds as set  above.  Tenders reaching the minimum quality thresholds will be scored 0 . For any  additional quality point, the scoring will be as follows: \nScore tender X = \n{[((SUM of ALL Quality Award Criteria points)-60)/40] x 60 quality points} + [(Lowest  Total Price/ Total Price of tender X) x (40 price points)]\nNOTE: where the Total Price of tender X is higher than 3 times the Lowest Total Price,  tender X will be given 0 price points. \n The Contract shall be awarded to the first three ranked tenderers in each lot, which  comply with the Tender Specifications, have access to this procurement, are not in an  exclusion situation and fulfil with the selection criteria. \nThe ranking will determine the sequence in which the contractors will be offered  specific contracts during the implementation of the FWC in each lot . \nThe procedure to sign a specific contract will include the following steps:\nExcept in the case of a conflict of interests (see section 3.2.4), each request for offer must  be sent to all FWC contractors simultaneously. The request will include tender specifications  that set out the specific tasks to be performed, an outline of the specific timetable for the  individual assignment, volumes and the duration of the tasks. The request will also include  information on the contract award criteria to be applied to the offers, as mentioned in point  4 below.\nUnless specified differently, within  5 working days  from the date of the request for offer,  the FWC contractors shall inform the  Contracting Authority  in written form (e.g. by e-mail)  whether or not they have the capacity to carry out the services required and whether or  not they will submit an offer. \nWithin the time limit specified in the request for offer (in general not less than 15 working  days) the FWC contractors shall submit an offer for the required tasks by e-mail only. \nUp to  5 working days before the offer submission deadline, the FWC contractors are  entitled to send questions before the deadline exclusively to [ FWC666 ]@echa.europa.eu.  The answer to any questions will be simultaneously sent by the  Contracting Authority  to \n38\n"}]}
+{"image": "doclay/doclay_2067.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "where their PP contributions are\nFrom this, we see that the renormalization constant ˜ Z$_{1}$ must be\nso that ˜ Z$_{1}$ = Z$_{5}$ and thus we obtain the relations\nTherefore, the sum of all PP contributions of the right-hand side of Eq. (103) becomes\nwhich is the same result as for the left-hand side, Eq. (120).\nBesides these ultraviolet divergent parts, arising from the planar parts of the diagrams, we have also infrared singular parts (SP) coming from the nonplanar parts of the same diagrams, at p, q, k = 0. Explicit calculations, combining denominators with Feynman parameters and using nonplanar integrals, give us the SP for the diagrams Λ µνλ on the left-hand side of Eq. (103):\nwhere we are not taking into account the logarithmic singularities. Contracting q$_{µ}$ in the above expression, we obtain\nwhich is exactly the same SP for the photon self-energy diagrams on the right-hand side of Eq. (103),\nThe other diagrams of the ST identity (103) contribute only with logarithmic SP. These singularities are not problematic as they are integrable.\n= i ( − i ) $^{2}$(2 e ) 3 ∫ d $^{4}$l (2 π ) 4 ( − l )$_{α}$ γ αν λ ′ ( p + l, q, − p − q − l ) l $^{2}$( p + l ) $^{2}$( p + q + l ) 2 × sin( l ∧ p ) sin( − l ∧ p − l ∧ q ) sin( l ∧ q + p ∧ q ) ,\nPP[ B λ ν ′ ( p, q, k )( q $^{2}$g νν ′ − q $^{ν}$qν $^{′}$) + B ν λ ′ ( p, k, q )( k $^{2}$g λλ ′ − k $^{λ}$kλ $^{′}$)] = − e 2 16 π 2 1 ϵ [( k $^{2}$g λν − k $^{λ}$k$^{ν}$) − ( q $^{2}$g νλ − q $^{ν}$q$^{λ}$)] . (129)\n˜ Z$_{1}$ = 1 − e 2 16 π 2 1 ϵ , (130)\nZ$_{2}$/Z$_{1}$$_{F}$ = ˜ Z$_{3}$/ ˜ Z$_{1}$ = Z$_{3}$/Z$_{1}$. (131)\nP P [Π νλ $_{b,c,d}$( q ) − Π λν $_{b,c,d}$( k ) + B λ ν ′ ( p, q, k )( q $^{2}$g νν ′ − q $^{ν}$qν $^{′}$) + B ν λ ′ ( p, q, k )( k $^{2}$g λλ ′ − q $^{λ}$qλ $^{′}$)] = 7 e 2 48 π 2 1 ϵ [( k $^{2}$g λν − k $^{λ}$k$^{ν}$) − ( q $^{2}$g νλ − q $^{ν}$q$^{λ}$)] , (132)\nSP[2 e sin( p ∧ q )Λ µνλ b 1 ,b 2 ,c,d 1 ,d 2 ,d $_{3}$( p, q, k )] = 4 e 3 π 2 sin( p ∧ q ) p ∧ q ( ˜ p $^{µ}$˜ p $^{ν}$˜ p λ ξ ˜ p 4 + ˜ q $^{µ}$˜ q $^{ν}$˜ q λ ξ ˜ q 4 + ˜ k µ ˜ k ν ˜ k λ ξ ˜ k 4 ) , (133)\nSP[ q$_{µ}$ Λ µνλ b 1 ,b 2 ,c,d 1 ,d 2 ,d $_{3}$( p, q, k )] = 2 e 2 π 2 ( ˜ q $^{ν}$˜ q λ ξ $^{2}$˜ q 4 − ˜ k ν ˜ k λ ξ 2 ˜ k 4 ) , (134)\nSP[Π νλ $_{b,c,d}$( q ) − Π λν $_{b,c,d}$( k )] = 2 e 2 π 2 ( ˜ q $^{ν}$˜ q λ ξ $^{2}$˜ q 4 − ˜ k ν ˜ k λ ξ 2 ˜ k 4 ) . (135)\n22"}]}
+{"image": "doclay/doclay_21967.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "IFRS. The amendments in this update are effective for annual reporting periods beginning on or after January 1, 2013. The  adoption of the standard did not have a significant impact on NNN's financial position or results of operations.\nIn February 2013, the FASB issued ASU 2013-02. The objective of this update is to improve the reporting of reclassifications  out of accumulated other comprehensive income. The update requires reporting significant reclassifications out of accumulated other comprehensive income on the respective line items in net income if the amount being reclassified is required under  GAAP to be reclassified in its entirety to net income or cross-reference other required disclosures that provide additional detail  about amounts that are not. The amendments in this update are effective prospectively for reporting periods beginning after  December 15, 2012. The adoption of the standard in the quarter ended March 31, 2013, did not have a significant impact on  NNN's financial position or results of operations.\nIn February 2013, the FASB issued ASU 2013-04. The objective of this update is to provide guidance for the recognition,  measurement, and disclosure of obligations resulting from joint and several liability arrangements for which the total amount of  the obligation within the scope of this guidance is fixed at the reporting date. The amendments in this update are effective for  fiscal years, and interim periods within those years, beginning after December 15, 2013. The adoption of the standard is not  expected to have a significant impact on NNN's financial position or results of operations.\nIn July 2013, the FASB issued ASU 2013-10. The amendments in this update permit the Fed Funds Effective Swap Rate (also  referred to as Overnight Index Swap Rate) to be used as a United States benchmark interest rate for hedge accounting purposes  under Topic 815, in addition to treasury obligations of the United States Government and the London Interbank Offered Rate.  The amendments are effective prospectively for qualifying new or redesignated hedging relationships entered into on or after  July 17, 2013. The adoption of the standard did not have a significant impact on NNN's financial position or results of  operations.\nIn July 2013, the FASB issued ASU 2013-11. The objective of the amendments in this update is to eliminate the diversity in  practice of financial statement presentation of an unrecognized tax benefit when a net operating loss carryforward, a similar tax  loss, or a tax credit carryforward exists. The provisions of the update are that an unrecognized tax benefit, or a portion of an  unrecognized tax benefit, should be presented, with certain exceptions, in the financial statements as a reduction to a deferred  tax asset for a net operating loss carryforward, a similar tax loss, or a tax credit carryforward. The amendments in this update  are effective for fiscal years, and interim periods within those years, beginning after December 15, 2013. NNN is currently  evaluating ASU 2013-11 to determine the potential impact, if any, its adoption will have on NNN's financial position and  results of operations.\nUse of Estimates – Additional critical accounting policies of NNN include management’s estimates and assumptions relating to  the reporting of assets and liabilities, revenues and expenses and the disclosure of contingent assets and liabilities to prepare the  consolidated financial statements in conformity with accounting principles generally accepted in the United States of America.  Additional critical accounting policies include management’s estimates of the useful lives used in calculating depreciation  expense relating to real estate assets, the recoverability of the carrying value of long-lived assets, including the commercial  mortgage residual interests, the recoverability of the deferred income taxes, and the collectibility of receivables from tenants,  including accrued rental income. Actual results could differ from those estimates.\nCorrection of Immaterial Errors – During the year ended December 31, 2012, NNN identified certain immaterial errors related  to deferred tax assets and the related valuation allowance. In 2009, NNN incurred a loss on foreclosure and impairment charges  associated with acquiring the operations of one of its lessees. The properties and operations were transferred to taxable REIT  subsidiaries upon foreclosure. Certain charges associated with the acquisition and impaired properties should have been  recorded in NNN’s qualified REIT subsidiaries prior to the properties’ transfer to the taxable REIT subsidiary group. Deferred  tax assets associated with the book charges of $10,350,000 in 2009 were inappropriately recorded in the taxable REIT  subsidiary group. A valuation allowance for the full amount of the deferred tax assets was also recorded in 2009. In the year  ended December 31, 2012, NNN decreased deferred tax assets and the related valuation allowance by $10,350,000 each to  correct the error. \nNNN further reviewed its conclusions in previous periods, commencing in 2009, with respect to the realizability of the  remaining deferred tax assets. Upon further review, NNN determined that its available sources of income supported  realizability of all but $3,104,000 of its gross deferred tax assets as of December 31, 2009, 2010 and 2011. As a result, NNN  determined that it had previously understated its deferred income tax benefit in the years ended December 31, 2010 and 2009  by $3,121,000 and $3,372,000, respectively, and understated its net deferred tax assets by $6,493,000 as of December 31, 2011  and 2010, in its financial statements. NNN corrected this in the year ended December 31, 2012 by reversing the valuation  allowance and recording an income tax benefit of $6,493,000. NNN reviewed the impact of correcting the prior period errors in  2012 as well as its impact on prior periods in accordance with SAB Topics 1.M and 1.N and determined that the misstatements  did not have a material effect on the Company’s financial position, results of operations, trends in earnings, or cash flows for  any of the periods presented. \n 55"}]}
+{"image": "doclay/doclay_71602.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Table of Contents\nNotes to Consolidated Financial Statements — (Continued) Becton, Dickinson and Company\nNotes to Consolidated Financial Statements — (Continued) Becton, Dickinson and Company\nThe fair value of share-based payments is recognized as compensation expense in net income. The amounts and location of compensation cost relating to share-based payments included in the consolidated statements of income is as follows:\nUpon the Company's acquisition of Bard in 2018, certain pre-acquisition equity awards of Bard were converted into either BD SARs or BD restricted stock awards, as applicable. These awards have substantially the same terms and conditions as the converted Bard awards immediately prior to the acquisition date. Compensation expense of $16 million, $40 million and $126 million associated with these replacement awards was recorded in  Acquisitions and other restructurings  in 2020, 2019 and 2018, respectively.\n(Millions of dollars) 2020 2019 2018 Cost of products sold $ 40  $ 37  $ 36  Selling and administrative expense 150  145  136  Research and development expense 34  32  29  Acquisitions and other restructurings 20  50  130  $ 245  $ 265  $ 332  Tax benefit associated with share-based compensation costs recognized $ 57  $ 62  $ 79 \nSARs represent the right to receive, upon exercise, shares of common stock having a value equal to the difference between the market price of common stock on the date of exercise and the exercise price on the date of grant. SARs vest over a period of four years and have a term of ten years. The fair value was estimated on the date of grant using a lattice-based binomial option valuation model that uses the following weighted- average assumptions:\nStock Appreciation Rights\nExpected volatility is based upon historical volatility for the Company’s common stock and other factors. The expected life of SARs granted is derived from the output of the lattice-based model, using assumed exercise rates based on historical exercise and termination patterns, and represents the period of time that SARs granted are expected to be outstanding. The risk-free interest rate used is based upon the published U.S. Treasury yield curve in effect at the time of grant for instruments with a similar life. The dividend yield is based upon the most recently declared quarterly dividend as of the grant date. The Company issued 0.8 million shares during 2020 to satisfy the SARs exercised.\n2020 2019 2018 Risk-free interest rate 1.69% 3.05% 2.32% Expected volatility 19.0% 18.0% 19.0% Expected dividend yield 1.24% 1.27% 1.33% Expected life 7.4 years 7.2 years 7.4 years Fair value derived $48.82 $51.86 $46.10\n75"}]}
+{"image": "doclay/doclay_1301.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Nordstrom, Inc. Consolidated Statements of Cash Flows In millions\nConsolidated Statements of Cash Flows In millions\nThe accompanying Notes to Consolidated Financial Statements are an integral part of these financial statements.\n40\nFiscal year 2014 2013 2012 Operating Activities Net earnings $720 $734 $735 Adjustments to reconcile net earnings to net cash provided by operating activities: Depreciation and amortization expenses 508 454 429 Amortization of deferred property incentives and other, net (76) (58) (63) Deferred income taxes, net 7 12 22 Stock-based compensation expense 68 58 53 Tax benefit from stock-based compensation 20 21 23 Excess tax benefit from stock-based compensation (22) (23) (24) Bad debt expense 41 52 42 Change in operating assets and liabilities: Accounts receivable (161) (93) (99) Merchandise inventories (176) (157) (170) Prepaid expenses and other assets (4) (6) 5 Accounts payable 15 167 48 Accrued salaries, wages and related benefits 18 (12) 13 Other current liabilities 155 60 36 Deferred property incentives 110 89 58 Other liabilities (3) 22 2 Net cash provided by operating activities 1,220 1,320 1,110 Investing Activities Capital expenditures (861) (803) (513) Change in restricted cash — — 200 Change in credit card receivables originated at third parties (8) (6) (42) Other, net (20) (13) (14) Net cash used in investing activities (889) (822) (369) Financing Activities Proceeds from long-term borrowings, net of discounts 34 399 — Principal payments on long-term borrowings (7) (407) (506) (Decrease) increase in cash book overdrafts (4) 47 5 Cash dividends paid (251) (234) (220) Payments for repurchase of common stock (610) (515) (725) Proceeds from issuances under stock compensation plans 141 103 91 Excess tax benefit from stock-based compensation 22 23 24 Other, net (23) (5) (2) Net cash used in financing activities (698) (589) (1,333) Net decrease in cash and cash equivalents (367) (91) (592) Cash and cash equivalents at beginning of year 1,194 1,285 1,877 Cash and cash equivalents at end of year $827 $1,194 $1,285 Supplemental Cash Flow Information Cash paid during the year for: Income taxes, net of refunds $391 $445 $429 Interest, net of capitalized interest 152 170 169 Non-cash investing and financing activities: Issuance of common stock for Trunk Club acquisition 280 — — Debt exchange — 201 —"}]}
+{"image": "doclay/doclay_64880.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Jun.29,2006 \n15 \nUS 2006/0141632 Al \n-continued \nWhat is claimed is: \nwith one or more acidic moieties having pKas of less  than about 2 when coupled with the polypeptide or  peptides, to provide one or more derivatized analytes; \n2.  A method according to claim 1 wherein the fragmen› tation pattern is substantially free of a-ions and b-ions. \n(a) converting the epsilon amino group of lysine on the  lysine containing peptides to a guanine or another very  basic group, a fixed cationic-charged group or an  isotopically labeled group; \n(b) derivatizing the N-terminus of the polypeptide or the  N-termini of one or more peptides of the polypeptide \n( c) analyzing one or more derivatized analytes using a  mass spectrometric technique to provide a fragmenta› tion pattern; and \n( d) interpreting the fragmentation pattern. \n1.  A method of determining the amino acid sequence of a  polypeptide wherein one or more peptides of the polypeptide  contain lysine, said method comprising: \n<210> SEQ ID NO 6  <211> LENGTH: 16  <212> TYPE: PRT  <213> ORGANISM: rat  <400> SEQUENCE: 6  Ile Leu Ile Arg Pro Leu Tyr Ser Asn Pro Pro Leu Asn Gly Ala Arg  1  5  10  15 \n<210> SEQ ID NO 7  <2 11 > LENGTH : 7  <212> TYPE: PRT  <213> ORGANISM: rat  <400> SEQUENCE: 7  Val Val Leu His Pro Glu Arg  1  5 \n<210> SEQ ID NO 8  <211> LENGTH: 5  <212> TYPE: PRT  <213> ORGANISM: rat  <400> SEQUENCE: 8  Asn Val Asn Phe Arg  5 \n<210> SEQ ID NO 9  <211> LENGTH: 21  <212> TYPE: PRT  <213> ORGANISM: Artificial Sequence  <220> FEATURE:  <223> OTHER INFORMATION: OTHER INFORMATION:  Modified subtilisin from B.  lentus  <400> SEQUENCE: 9  Gly Val Leu Val Val Ala Ala Ser Gly Asn Ser Gly Ala Gly Ser Ile  1  5  10  15  Ser Tyr Pro Ala Arg  20 \n<210> SEQ ID NO 10  <2 11 > LENGTH : 9  <212> TYPE: PRT  <213> ORGANISM: Artificial Sequence  <220> FEATURE:  <223> OTHER INFORMATION: commercially available from Sigma Chemical Co.  <400> SEQUENCE: 10  Val Gly Gly Tyr Gly Tyr Gly Ala Lys  1  5 "}]}
+{"image": "doclay/doclay_29941.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Note also the attribution of isospin I=1/2 to the three lightest structure masses.\nWe conclude that the growing number of coherent indications reinforces the evidence for the genuine existence of these structures. These structures are clearly exotic since there is no room for them in the qqq configurations [1], since their width is smaller than the widths of ”classical” PDG [2] baryonic resonances, and also since some masses lie below the pion threshold mass. They are naturally associated with precursor quark deconfinement and may show that the quark and gluon degrees of freedom are effective even at very low energy and must be taken into account.\n[1] S. Capstick and W.Roberts, Prog. Part. Nucl. Phys. 45 , 08241 (2000).\n[2] Particle Data Group, Phys. Lett. B 592 , 1 (2004).\n[3] B. Tatischeff et al. , Phys. Rev. Lett. 79 , 601 (1997).\n[4] B. Tatischeff et al. , Eur. Phys. A 17 , 245 (2003).\n[5] B. Tatischeff et al. , Phy. Rev. C 72 , 034004 (2005).\n[6] B. Tatischeff et al. , Surveys in High Energy Physics, 19 , 55 (2004).\n[7] B. Tatischeff, Proceedings of the 16th International Baldin Seminar on High Energy Physics Problems, Dubna 2002; arXiv nucl-ex/0207004.\n[8] J. Banaigs et al. , Phys. Lett. B 45 , 535 (1973).\n[9] R. Baldini-Celio, F.L. Fabbri, G. La Rosa, and P. Picozza, Journal of Nuclear Physics B 107, 321 (1976); R. Baldini et al. , Nucl. Phys. A 379 , 477 (1982)\n[10] S. Hirenzaki, E. Oset, C. Djalali, and M. Morlet, Phys. Rev. C 61 , 044605 (2000).\n[11] H.P. Morsch et al. Phys. Rev. Lett. 69 , 1336 (1992).\n[12] B. Tatischeff and E. Tomasi-Gustafsson, Proceedings of the 17th International Baldin Seminar on High Energy Problems, Dubna 2004; arXiv nucl-ex/0411044.\n[13] H.P. Morsch, Proceedings of the Dixi` eme Journee Th` ematique de l’IPN d’Orsay (1995).\n[14] H.P. Morsch, private communication.\n[15] B. Tatischeff and E. Tomasi-Gustafsson, Proceedings of the 12th International Conference on Nuclear Reaction Mechanisms, Varenna 2009.\n[16] V. Dimitriev, O. Sushkov, and C. Gaarde, Nucl. Phys. A459 , 503 (1986).\n[17] D.V. Bugg et al. , Phys. Rev. B133 , 1017 (1967).\n20"}]}
+{"image": "doclay/doclay_73687.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Table of Contents\nActuarial assumptions used for the CNA Retirement Plan and CNA Health and Group Benefits Program to determine benefit obligations are presented in the following table. The interest crediting rate is the weighted average interest rate applied to the individual pension balances for employees who elected to cease accruals effective December 31, 1999.\nTo determine the discount rate assumption as of the year-end measurement date for the CNA Retirement Plan and CNA Health and Group Benefits Program, the Company considered the estimated timing of plan benefit payments and available yields on high quality fixed income debt securities. For this purpose, high quality is considered a rating of Aa or better by Moody's or a rating of AA or better from S&P. The Company reviewed several yield curves constructed using the cash flow characteristics of the plans as well as bond indices as of the measurement date. The trend of those data points was also considered.\nIn determining the expected long term rate of return on plan assets assumption for the CNA Retirement Plan, CNA considered the historical performance of the benefit plan investment portfolio as well as long term market return expectations based on the investment mix of the portfolio and the expected investment horizon.\nThe CNA Health and Group Benefits Program has limited its share of the health care trend rate to a cost-of-living adjustment of 4% per year. For all participants, the employer subsidy on health care costs will not increase by more than 4% per year. As a result, the assumed health care cost trend rate used in measuring the accumulated postretirement benefit obligation for the CNA Health and Group Benefits Program was 4% per year in 2018, 2017 and 2016.\nCNA employs a total return approach whereby a mix of equity, limited partnerships and fixed maturity securities are used to maximize the long term return of retirement plan assets for a prudent level of risk and to manage cash flows according to plan requirements. The target allocation of plan assets is 40% to 60% invested in equity securities and limited partnerships, with the remainder primarily invested in fixed maturity securities. Alternative investments, including limited partnerships, are used to enhance risk adjusted long term returns while improving portfolio diversification. The intent of this strategy is to minimize the Company's expense related to funding the plan by generating investment returns that exceed the growth of the plan liabilities over the long run. Risk tolerance is established after careful consideration of the plan liabilities, plan funded status and corporate financial conditions.\nAs of December 31, 2018, the Plan had committed approximately $93 million to future capital calls from various third-party limited partnership investments in exchange for an ownership interest in the related partnerships. Derivatives may be used to gain market exposure in an efficient and timely manner. Investment risk is measured and monitored on an ongoing basis through annual liability measurements, periodic asset/liability studies and quarterly investment portfolio reviews.\nActuarial assumptions used for the CNA Retirement Plan and CNA Health and Group Benefits Program to determine net cost or benefit are presented in the following table.\nDecember 31 2018 2017 Pension benefits Discount rate 4.250% 3.550% Expected long term rate of return 7.500 7.500 Interest crediting rate 5.000 5.000 Postretirement benefits Discount rate 3.550% 2.750%\nYears ended December 31 2018 2017 2016 Pension benefits Discount rate 3.550% 3.950% 4.150% Expected long term rate of return 7.500 7.500 7.500 Interest crediting rate 5.000 5.000 5.000 Postretirement benefits Discount rate 2.750% 2.750% 2.750%\n116"}]}
+{"image": "doclay/doclay_70123.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "GLYPH<SM590000> Two Flexible Support Processor (FSP) cards that are used to control the drawer.\nGLYPH<SM590000> Two Power Supply Units (PSUs) in a redundant configuration. \nGLYPH<SM590000> Six hot-swappable cooling fan modules at the front of the drawer.\nfront view rear view cooling fans X 6 2 vertical I/O Domains each 8 I/O slots PCIe switch Cards x 2 FSP Cards x 2 power  supplies x 2\nFigure 2-4 PCIe+ I/O drawer front and rear view\nPCIe I/O infrastructure\nTerminology:  Throughout this chapter, the terms  adapter  and  card  are interchangeable  and refer to a feature that is installed in a PCIe+ I/O drawer.\nThe PCIe I/O infrastructure uses the PCIe fanouts that are installed in the processor (CPC)  drawer to connect to the PCIe+ I/O drawer. The PCIe adapters include the following features:\nGLYPH<SM590000> FICON Expresss16S+ (two port card), long wavelength (LX) or short wavelength (SX),  which contains two physical channel IDs (PCHIDs)\nGLYPH<SM590000> FICON Express16S (two port card), long wavelength (LX) or short wavelength (SX), which  contain two PCHIDs (only for carry-forward MES)\nGLYPH<SM590000> FICON Express8S (two port card), long wavelength (LX) or short wavelength (SX), which  contain two PCHIDs (only for carry-forward MES)\nGLYPH<SM590000> Open Systems Adapter (OSA)-Express7S 25GbE Short Reach (SR) - New feature\nGLYPH<SM590000> Open System Adapter (OSA)-Express6S:\n– OSA-Express6S 10 Gb Ethernet (single port card, Long Reach (LR) or Short Reach  (SR), one PCHID)\n– OSA-Express6S Gb Ethernet (two port card, LX or SX, one PCHID)\n– OSA-Express6S 1000BASE-T Ethernet (two port card, RJ-45, one PCHID)\nGLYPH<SM590000> Open System Adapter (OSA)-Express5S and 4S features (for carry-forward MES only):\n– OSA-Express5S and 4S 10 Gb Ethernet (one port card, LR or SR, and one PCHID)\n– OSA-Express5S and 4S Gb Ethernet (two port card, LX or SX, and one PCHID)\n– OSA-Express5S 1000BASE-T Ethernet (two port card, RJ-45, and one CHPID)\nGLYPH<SM590000> Crypto Express6S (new build) and Crypto Express5s (only for carry-forward MES). Each  feature holds one PCIe cryptographic adapter. Each adapter can be configured as:\n– Secure IBM Common Cryptographic  Architecture (CCA) coprocessor\n– Secure IBM Enterprise Public Key Cryptography Standards (PKCS) #11 (EP11)  coprocessor\n– Accelerator\nChapter 2. Central processor complex hardware components  25"}]}
+{"image": "doclay/doclay_7592.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "SKIN CARE\nQUALITY PRODUCTS THAT DELIVER VISIBLE RESULTS\nSkin care sales continued to grow at The Estée Lauder Companies. Net sales increased 11% on a reported basis and rose 7% before foreign currency translation. Holding true to our heritage of developing highly innovative, quality products that deliver visible results helps drive our success in this area.\nAs the art of cosmetic science becomes more advanced, research and development plays a larger role in creating products that deliver more clinically proven benefits to the skin. More than 400 Estée Lauder Companies scientists work in seven labs around the world to stay on the cutting edge of skin science. From this research, we introduced several dazzling 25"}]}
+{"image": "doclay/doclay_37136.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "XII CONCLUSION\n180. I would like to express my gratitude to all officers, notably the Accountant  General and her staff, the Accounting Officers of all Ministries and Extra- Ministerial Departments and their staff and Heads of Parastatals and their staff  who have contributed in the production of this report in the discharge of my  statutory functions under the Constitution.\nI would also like to extend my gratitude to the Government Printer who,  as always, has assisted with speedy printing of the report. \n1 March 2019 \n201 \nPulane D. Letebele \nPulane D. Letebele  AUDITOR GENERAL "}]}
+{"image": "doclay/doclay_54956.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "MAKING APPLICATIONS / 159\nThe names, addresses and status of your referees can be included on a separate sheet. It is not essential to include them when first applying for a job although it is sometimes useful for a prospective employer to have an immediate contact.\nRemember to check with your referees before submitting their names.\nCHECKING FOR ERRORS\n◆ Sell yourself.\n◆ Prepare a striking profile.\n◆ Use only relevant material in your CV.\n◆ List education, qualifications and jobs in reverse order – most recent first.\n◆ Remember to include your skills and achievements but don’t overdo them.\n◆ Always write legibly.\n◆ Remember to ask before offering a referee’s name.\n1. Write two personal profiles – one for a specific job and one general one.\n2. Plan your CV.\n3. Write a covering letter to accompany your CV. Identify the post for which you are applying.\nPRACTISING WHAT YOU’VE LEARNT"}]}
+{"image": "doclay/doclay_65105.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Jan. 13,  2011 \n89 \nUS 2011/0008728 Al \n[Chemical Formula 109] \nCompound (VI) \n0 ~:  WW  0  Ha  Ha  Ha  H  O’SD \nAcid generator (B13) \n[Chemical Formula 111] \n[Chemical Formula 11 OJ \nCompound (VI) \nCompound (IV) \n[1161]  The obtained acid generator (B13) was analyzed by  NMR. \n[1162]  $^{1}$H-NMR (DMSO-d6, 400 MHz):  Ii  (ppm)=7.76-7.  88 (m, !OH, Phenyl), 7.62 (s, 2H, Phenyl), 4.64 (s, 2H, H 6 ),  4.43-4.44 (t, 2H, ff), 4.22-4.23 (t, 2H,  Hd),  1.51-2.36 (m,  38H, Adamantane+Ha+Hc) \n[1163]  $^{19}$F-NMR (DMSO-d6, 376 MHz):  Ii  (ppm)=-106.7 \n[1164]  From the results shown above, it was confirmed that  the acid generator (B13) had a structure shown below. \n[1159]  (iv) Synthesis of Acid Generator (B13) \n[1160]  4.77 g of the compound (VI) was dissolved in 23.83  g of dichloromethane and 23.83 g of pure water, and 3.22 g of  the compound (IV) was then added to the resulting solution.  The resultant was stirred for 1 hour, followed by liquid sepa› ration to collect the organic phase. The organic phase was  washed with 3.84 g of water three times. Thereafter, the  resulting organic layer was concentrated and solidified,  thereby obtaining 4.98 g ofa compound (B13) (yield: 87%). \nAcid-Generator Synthesis Example 5 \nSynthesis of Acid Generator (B14) \n[1165]  (i) Synthesis of Compound (5) \n[1166]  4.74 gofxylenol and 16.1 gofanhydrouspotassium  carbonate were mixed in 94.8 g of acetone. Then, 32.9 g of  1-iodohexane was gradually added thereto in dropwise man› ner, and a reaction was effected for 19 hours under reflux.  After the reaction, the reaction mixture was cooled and sub› jected to filtration. Acetone was removed from the obtained  filtrate, thereby obtaining 25.5 g of a viscous liquid. Then,  25.4 g of t-butylmethylether and 25.4 g of a 1 % aqueous  solution of sodium hydroxide were added to the obtained  liquid, and the organic phase was collected, followed by  washing the organic phase with 25 .4 g of a 1 % aqueous  solution of sodium hydroxide. The organic phase was col› lected again, and washing was conducted four times with 25 .4  g of a 1 % aqueous solution of sodium hydroxide. Thereafter,  t-butylmethylether was removed to obtain 23.5 g of a crude  product. "}]}
+{"image": "doclay/doclay_70774.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "ПРИЛОЖЕНИЕ № 3 к Правилам предоставления в 2021 году из федерального бюджета  субсидий на государственную поддержку  туроператоров для обеспечения прироста  внутренних туристических потоков \n(форма) \nВ Федеральное агентство по туризму \nО Т Ч Е Т  программ внутренних коммерческих чартерных воздушных перевозок пассажиров,\nО Т Ч Е Т  об организации программ внутренних коммерческих чартерных воздушных перевозок пассажиров, выполненных по заказу туроператора (туроператоров) с 1 июня 2020 г. \n__________________________________________________________________ \n(полное наименование туроператора)  __________________________________________________________________ \n(полное наименование туроператора)  __________________________________________________________________ \n(адрес, место нахождения, адрес электронной почты туроператора) \nИдентификационный номер налогоплательщика ____________ \nРеестровый номер в едином федеральном реестре туроператоров (ЕФРТ) ________________________ \nДля организации программ внутренних коммерческих чартерных воздушных перевозок пассажиров, выполненных по заказу  туроператора (туроператоров) с 1 июня 2020 г., по Российской Федерации были понесены расходы в рамках договора  фрахтования воздушного судна или части воздушного судна либо иного договора в целях организации перевозки туристов в размере _____________________ рублей. "}]}
+{"image": "doclay/doclay_419.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "SHENANDOAH TELECOMMUNICATIONS COMPANY AND SUBSIDIARIES NOTES TO CONSOLIDATED FINANCIAL STATEMENTS\nNote 1. Summary of Significant Accounting Policies\nDescription of business:  Shenandoah Telecommunications Company and subsidiaries (the Company) provides telephone service, wireless personal communications service (PCS) under the Sprint brand name, cable television, unregulated communications equipment sales and services, Internet access, and paging services. In addition, the Company leases towers and operates and maintains an interstate fiber optic network. The Company’s operations are located in the four state region surrounding the Northern Shenandoah Valley of Virginia. Pursuant to a management agreement with Sprint Communications Company and its related parties (collectively, “Sprint”), the Company is the exclusive PCS Affiliate of Sprint providing wireless mobility communications network products and services in the geographic area extending from Altoona, Harrisburg and York, Pennsylvania, south through Western Maryland, and the panhandle of West Virginia, to Harrisonburg, Virginia. The Company is licensed to use the Sprint brand name in this territory, and operates its network under the Sprint radio spectrum license (Note 7). A summary of the Company’s significant accounting policies follows:\nStock split:  All share and per share information reflect the two for one stock split announced in October 2003, to shareholders of record as of the close of business on January 30, 2004. The additional shares were distributed on February 20, 2004. The effective date of the split is February 23, 2004. All previously reported share and per share data included herein are retroactively adjusted to reflect the split.\nPrinciples of consolidation: The consolidated financial statements include the accounts of all wholly owned subsidiaries and other entities where effective control is exercised. All significant intercompany balances and transactions have been eliminated in consolidation.\nUse of estimates: Management of the Company has made a number of estimates and assumptions related to the reporting of assets and liabilities, the disclosure of contingent assets and liabilities at the date of the consolidated financial statements and the reported amounts of revenues and expenses during the reporting periods. Management reviews its estimates, including those related to recoverability and useful lives of assets as well as liabilities for income taxes and pension benefits. Changes in facts and circumstances may result in revised estimates and actual results could differ from those reported estimates.\nCash and cash equivalents: The Company considers all temporary cash investments purchased with a maturity of three months or less to be cash equivalents. The Company places its temporary cash investments with high credit quality financial institutions. At times, these investments may be in excess of FDIC insurance limits. Cash and cash equivalents were $28.7million, $2.2 million, and $2.0 million at December 31, 2003, 2002 and 2001, respectively.\nAccounts receivable:   Accounts receivable are recorded at the invoiced amount and do not bear interest. The allowance for doubtful accounts is the Company’s best estimate of the amount of probable credit losses in the Company’s existing accounts receivable. The Company determines the allowance based on historical write-off experience and by industry and national economic data. The Company reviews its allowance for doubtful accounts monthly. Past due balances meeting specific criteria are reviewed individually for collectibility. All other balances are reviewed on a pooled basis. Account balances are charged off against the allowance after all means of collection have been exhausted and the potential for recovery is considered remote. Accounts receivable are concentrated among customers within the Company’s geographic service area and large telecommunications companies. The Company’s allowance for uncollectable receivables related to continuing operations was $477 thousand, $914 thousand and $650 thousand at December 31, 2003, 2002 and 2001, respectively.\nSecurities and investments:  The classifications of debt and equity securities are determined by management at the date individual investments are acquired. The appropriateness of such classification is continually reassessed. The Company monitors the fair value of all investments, and based on factors such as market conditions, financial information and industry conditions, the Company will reflect impairments in values as is warranted. The classification of those securities and the related accounting policies are as follows:\nSHENANDOAH TELECOMMUNICATIONS COMPANY ■  18\nAvailable-for-Sale Securities:  Debt and equity securities classified as available-for-sale consist of securiti es which the Com pany intends to hold for an indefinite period of time, but not necessarily to maturity. Any decision to sell a secu rity classified as available-for-sale would be based on various factors, including changes in market c ondition s, liqui dity needs and similar criteria. Available-for-sale securities are recorded at fair value as determined by quot e d  Debt and equity securities classified as available-for-sale consist of  securities which the Company intends to hold for an indefinite period of time, but not necessarily to maturity. Any decision to s e ll a security classified as available-for-sale would be based on various factors, including changes in mark et c ondi tions, liquidity needs and similar criteria. Available-for-sale are recorded at fair value as determined by quoted Available-for-Sale Securities:  Debt and equity securities classified as available-for-sale consist of securities which the Company intends to hold for an indefinite period of time, but not necessarily to maturity. Any decision to sell a security classified as available-for-sale would be based on various factors, including changes in market conditions, liquidity needs and similar criteria. Available-for-sale securities are recorded at fair value as determined by quoted market prices. Unrealized holding gains and losses, net of the related tax effect, are excluded from earnings and are reported as a separate component of other comprehensive"}]}
+{"image": "doclay/doclay_73989.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "APPALACHIAN POWER COMPANY AND SUBSIDIARIES CONSOLIDATED STATEMENTS OF COMPREHENSIVE INCOME (LOSS)\nAPPALACHIAN POWER COMPANY AND SUBSIDIARIES CONSOLIDATED STATEMENTS OF COMPREHENSIVE INCOME (LOSS) For the Years Ended December 31, 2020, 2019 and 2018\nYears Ended December 31, 2020 2019 2018 Net Income $ 369.7  $ 306.3  $ 367.8  OTHER COMPREHENSIVE INCOME (LOSS), NET OF TAXES Cash Flow Hedges, Net of Tax of $(0.5), $(0.2) and $(0.2) in 2020, 2019 and 2018, Respectively (1.7) (0.9) (0.9) Amortization of Pension and OPEB Deferred Costs, Net of Tax of $(1.0), $(0.7) and $(0.8) in 2020, 2019 and 2018, Respectively (3.8) (2.5) (3.1) Pension and OPEB Funded Status, Net of Tax of $2.0, $3.6 and $(0.7) in 2020, 2019 and 2018, Respectively 7.7 13.4 (2.6) TOTAL OTHER COMPREHENSIVE INCOME (LOSS) 2.2  10.0  (6.6) TOTAL COMPREHENSIVE INCOME $ 371.9  $ 316.3  $ 361.2 \nSee Notes to Financial Statements of Registrants beginning on page 229.\n167\nCONSOLIDATED STATEMENTS OF COMPREHENSIVE INCOME (LOSS) For the Years Ended December 31, 2020, 2019 and 2018  (in millions)\nFor the Years Ended December 31, 2020, 2019 and 2018  (in millions)"}]}
+{"image": "doclay/doclay_65459.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "the influence of humidity and force on I D sensor 12 can be ignored. As shown in Figure 25, there is no significant change of ratios of opposite electrodes after testing under 5000 cycles, which indicates a stable and durable electrical property of the sensor 12.\nAs discussed above, the I D sensor 12 and 2D sensor 10 can enable trajectory, displacement and velocity detection. Therefore, the combination of the two patches can achieve 3D signal detection and control. The concept can be applied to the applications of robotics, electronic skins, and automatic control, etc. To evaluate 3D control enabled by the sensors 10 and 12, a robotics control system 30 was developed as shown in Figure 3. Through the control connection between the patches 10, 12 and the robotic manipulator (34, 36), experiments with different sliding speeds were conducted to control the robotic manipulator with different moving speeds. The trajectory tracking ability of the sensors 10, 12 were utilised to control the robotic manipulator to write different letters. Three letters \"C\",\"X\" and \"Q\" were selected and written by the robot manipulator on a whiteboard. Figure 20(c) illustrates the voltage curves of four electrodes corresponding to the letter trajectories induced by a fingertip.\nExample 2\nThe energy harvesting performance of a four-direction device 200 from hand tapping (~3 Hz, illustrated in Fig. 26(a)) is shown in Figure 26. When the resistance of the external load varies, a maximum output power of 4.8 mW can be achieved (Figure 26(b)). Figure 26(c) and Figure 26(d) illustrate the output voltage of the device under 100 ΜΩ load (~355 V) and short circuit current (~12 µΑ ), respectively.\nEight-direction control can, for example, be realised through a device 400 with a single electrode grid 401 (Figure 27(a)) according to an example embodiment, shown in Figure 27. The electrode grid has different interconnected grating structures e.g. 402 along the different respective directions 1 to 8 with grating element width of 8 mm (e.g. grating element 404) and 4 mm (e.g. grating element 406), and spacing of 6 mm (e.g. 408). Grating elements with larger"}]}
+{"image": "doclay/doclay_67961.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "8464ch11_Monitoring.fm\nDraft Document for Review February 7, 2020 3:15 pm\n11.3.2 TS7700 Management Interface: Other pages\nIn this section, we describe the other pages that are available in the TS7700 MI.\nVirtual Tape Drives page\nTo view the information about volumes that are mounted by virtual devices, select the  Virtual →  Virtual Tape Drives  page. In the MI, the synchronous mode mounts are visible  only in the Virtual Tape Device view of the Host I/O cluster. The selected second synchronous  target cluster does not show any mount that an internal device is used because for the  synchronous mount, which is not shown in the Virtual Tape drive window (see Figure 11-16).\nTo view the active pools, select the  Physical →  Physical Volumes →  Active Data  Distribution  window. Figure 11-17 shows the active pools and correspondent data  distribution (number of cartridges by occupancy percentage range).\nActive Data Distribution window\nFigure 11-16 Virtual Tape Drive view for synchronous mode copy \nFigure 11-17 Pool Active Data Distribution\n640  IBM TS7700 Release 5.0 Guide"}]}
+{"image": "doclay/doclay_347.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "\n400 Pine Street, Abilene, Texas 79601 www.ffin.com"}]}
+{"image": "doclay/doclay_36674.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "124  (Eigenerklärung zur Eignung) \n3 von 3 \n© VHB Bayern – Stand 2019 \n$^{4}$ nur erforderlich, wenn diese Eigenerklärung nicht Bestandteil eines unterschriebenen Angebotes ist \nAngabe zur Mitgliedschaft bei der Berufsgenossenschaft \nIch bin/Wir sind Mitglied der Berufsgenossenschaft. \nFalls mein/unser Angebot/Teilnahmeantrag in die engere Wahl kommt, werde ich/werden wir eine qualifizierte  Unbedenklichkeitsbescheinigung der Berufsgenossenschaft des für mich zuständigen Versicherungsträgers  mit Angabe der Lohnsummen vorlegen.\nMir/Uns ist bekannt, dass die jeweils genannten Bestätigungen/Nachweise zu den Eigenerklärungen auf ge- sondertes Verlangen der Vergabestelle innerhalb der gesetzten angemessenen Frist vorgelegt werden müs- sen und mein/unser Angebot / Teilnahmeantrag ausgeschlossen wird, wenn die Unterlagen nicht vollständig  innerhalb dieser Frist vorgelegt werden. \n(Ort, Datum, Unterschrift) 4"}]}
+{"image": "doclay/doclay_61431.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "EP 3 800 013 A1\nEUROPEAN SEARCH REPORT\nApplication Number\nEP 20 16 6067\nEuropäisches Patentamt\nEuropean p‘ a DE des brevets’\n5\n10\n15\n20\n25\n30\n35\n40\n45\n50\n55\nKe EPO FORM 1503 03.82 (PO4C01)\n15\nDOCUMENTS CONSIDERED TO BE RELEVANT EP 2 952 306 Al (MAKITA CORP [JP]) INV. 9 December 2015 (2015-12-09) B25F5/00 * the whole document * B23D57/02 B25F5/02 DE 20 2013 103656 U1 (HITACHI KOKI KK 1-3,5-8 | B27B17/00 [JP]} 12 September 2013 (2013-09-12) * the whole document * DE 11 2015 003376 T5 (MAKITA CORP [JP]) 30 March 2017 (2017-03-30) * the whole document * TECHNICAL FIELDS SEARCHED (IPC) B25H B25F Place of search Date of completion of the search Examiner The Hague 1 March 2021 Dewaele, Karl CATEGORY OF CITED DOCUMENTS T : theory or principle underlying the invention E: earlier patent document, but published on, or X: particularly relevant if taken alone after the filing date Y : particularly relevant if combined with another D : document cited in the application document of the same category L : document cited for other reasons A: technological background ©: non-written disclosure & : member of the same patent family, corresponding P : intermediate document document\n"}]}
+{"image": "doclay/doclay_4277.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "I  Ill  lllll  Ill lllll lllll 111111111111111111111111111111111111111111111111 \nIll lllll lllll 111111111111111111111111111111111111111111111111  US005648520A \nUnited States Patent  [19] \nKnof el et al. \n[111  Patent Number:  5,648,520 \n[45]  Date  of  Patent:  Jul.  15, 1997 \n[54]  FRACTIONATION AND PURIFICATION OF  AROMATIC POLYAMINE AND THE USE  THEREOF \n[75]  Inventors:  Hartmut Knofel,  Odenthal;  Michael  Brockelt,  Leverkusen, both of Germany \n[73]  Assignee:  Bayer Aktiengesellschaft,  Leverkusen,  Germany \n[21]  Appl. No.:  623,286 \n[22]  Filed:  Mar. 28, 1996 \n[51]  Int. CI. 6  ...................................................  C07C 209/86 \n[52]  U.S. CI . ..........................  560/347;  564/315; 564/331;  564/332; 564/333; 564/334; 564/437; 564/450;  564/451 \n[58]  Field of Search  ..................................... 564/315, 331,  564/332. 333, 334, 437, 450, 451; 560/347 \n[30]  Foreign Application Priority Data \n[56]  References Cited \nU.S. PATENT DOCUMENTS \n10 Claims, 4 Drawing Sheets \n[57]  ABSTRACT \nOTHER PUBLICATIONS \nFOREIGN PATENT DOCUMENTS \n4,914,236  4/1990 Knofel et al ............................ 564/334  4,924,028  5/1990 Knofel et al ............................ 564/331  5,1%,591  3/1993 Knofel et al ............................ 564/331  5,359,141  10/1994 Knofel et al ............................ 564/331 \nApr. 7, 1995  [DE]  Germany ........................... 19513163.0 \n4,087,459  5/1978 Knofel et al ............................ 564/331 \n2238319  2/1973  Germany . \n1170619  11/1969  United Kingdom. \nH. Becker et al \"Organikum\" 1976, Veb Destscher Verlag  der Wissenschaften, Berlin XP002005624, pp. 74-82. \nPrimary Examiner-Richard  L. Raymond \nAttorney, Agent, or Firm-Joseph  C.  Gil \nThe invention relates to a process for the fractionation and  purification of aromatic polyarnine mixtures and the use  thereof. "}]}
+{"image": "doclay/doclay_47534.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Removal of human remains \n21\n(10) If the Authority is satisfied that any person giving notice under paragraph (5) is the  personal representative or relative as that person claims to be and that the remains in question can  be identified, but that person does not remove the remains, the Authority must comply with any \nsubject to paragraph (10), the Authority must remove the remains and cause them to be re-interred  in such burial ground or cemetery in which burials may legally take place as the Authority thinks  suitable for the purpose; and, so far as possible, remains from individual graves must be re- interred in individual containers which must be identifiable by a record prepared with reference to  the original position of burial of the remains that they contain. \n(8) The Authority must pay the reasonable expenses of removing and re-interring or cremating  the remains of any deceased person under this article. \n(9) If— \n(7) If the Authority is not satisfied that any person giving notice under paragraph (5) is the  personal representative or relative as that person claims to be, or that the remains in question can  be identified, the question must be determined on the application of either party in a summary  manner by the county court, and the court may make an order specifying who must remove the  remains and as to the payment of the costs of the application. \nand that person must, as soon as reasonably practicable after such re-interment or cremation,  provide to the Authority a certificate for the purpose of enabling compliance with paragraph (11). \n(6) Where a person has given notice under paragraph (5), and the remains in question can be  identified, that person may cause such remains to be— \n(5) At any time within 56 days after the first publication of a notice under paragraph (3), any  person who is a personal representative or relative of any deceased person whose remains are  interred in the specified land may give notice in writing to the Authority of that person’s intention  to undertake the removal of the remains. \n(4) As soon as reasonably practicable after the first publication of a notice under paragraph (3),  the Authority must send a copy of the notice to Birmingham City Council. \n(3) Before any such remains are removed from the specified land, the Authority must give  notice of the intended removal, describing the specified land and stating the general effect of the  following provisions of this article, by— \n(2) Before the Authority carries out any development or works that will or may disturb any  human remains in the specified land, it must remove those human remains from the specified land,  or cause them to be removed, in accordance with the following provisions of this article. \n27. —(1) In this article, “the specified land” means the land within the Order limits or the limits  of deviation. \n(a) publishing a notice once in each of 2 successive weeks in a newspaper circulating in the  area of the authorised works; and \n(b) displaying a notice in a conspicuous place on or near to the specified land. \n(a) removed and re-interred in any burial ground or cemetery in which burials may legally  take place; or \n(b) removed to, and cremated in, any crematorium, \n(a) within the period of 56 days referred to in paragraph (5) no notice under that paragraph is  given to the Authority in respect of any remains in the specified land; \n(b) notice under paragraph (5) is given within the period of 56 days and no application is  made under paragraph (7) within 56 days after the giving of the notice, but the person  who gave the notice fails to remove the remains within a further period of 56 days; \n(c) within 56 days after any order is made by the county court under paragraph (7) any  person, other than the Authority, specified in the order fails to remove the remains; or \n(d) it is determined that the remains to which a notice under paragraph (5) relates cannot be  identified, "}]}
+{"image": "doclay/doclay_57861.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "BIT_COUNT() Operations\n| 0F0F0F0F | +-------------+\nThe  BIT_COUNT()  function always returns an unsigned 64-bit integer, or  NULL  if the argument is  NULL .\nFor the  BIT_AND() ,  BIT_OR() , and  BIT_XOR()  bit functions, the result type depends on whether the function argument values are evaluated as binary strings or numbers:\nNULL  values do not affect the result unless all values are  NULL . In that case, the result is a neutral value having the same length as the length of the argument values (all bits 1 for  BIT_AND() , all bits 0 for BIT_OR() , and  BIT_XOR() ).\nExample:\nFor backward compatibility, MySQL 8.0 evaluates bit operations in numeric context when all bit arguments are hexadecimal literals, bit literals, or  NULL  literals. That is, bit operations on binary-string bit arguments\n2266\nSpecial Handling of Hexadecimal Literals, Bit Literals, and NULL Literals\nBIT_AND(), BIT_OR(), and BIT_XOR() Operations\nBIT_COUNT() Operations\n•Binary-string evaluation occurs when the argument values have a binary string type, and the argument is not a hexadecimal literal, bit literal, or  NULL  literal. Numeric evaluation occurs otherwise, with argument value conversion to unsigned 64-bit integers as necessary.\n•Binary-string evaluation produces a binary string of the same length as the argument values. If argument values have unequal lengths, an  ER_INVALID_BITWISE_OPERANDS_SIZE  error occurs. If the argument size exceeds 511 bytes, an  ER_INVALID_BITWISE_AGGREGATE_OPERANDS_SIZE  error occurs. Numeric evaluation produces an unsigned 64-bit integer.\nmysql>  CREATE TABLE t (group_id INT, a VARBINARY(6)); mysql>  INSERT INTO t VALUES (1, NULL); mysql>  INSERT INTO t VALUES (1, NULL); mysql>  INSERT INTO t VALUES (2, NULL); mysql>  INSERT INTO t VALUES (2, X’1234’); mysql>  INSERT INTO t VALUES (2, X’FF34’); mysql>  SELECT HEX(BIT_AND(a)), HEX(BIT_OR(a)), HEX(BIT_XOR(a)) FROM t GROUP BY group_id; +-----------------+----------------+-----------------+ | HEX(BIT_AND(a)) | HEX(BIT_OR(a)) | HEX(BIT_XOR(a)) | +-----------------+----------------+-----------------+ | FFFFFFFFFFFF | 000000000000 | 000000000000 | | 1234 | FF34 | ED00 | +-----------------+----------------+-----------------+\nmysql>  SELECT BIT_COUNT(127); +----------------+ | BIT_COUNT(127) | +----------------+ | 7 | +----------------+ mysql>  SELECT BIT_COUNT(b’010101’), BIT_COUNT(_binary b’010101’); +----------------------+------------------------------+ | BIT_COUNT(b’010101’) | BIT_COUNT(_binary b’010101’) | +----------------------+------------------------------+ | 3 | 3 | +----------------------+------------------------------+"}]}
+{"image": "doclay/doclay_13460.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "partnering for the future\n5. other current assets\n6. property, plant and equipment, net\nProperty, plant and equipment consist of the following:\nOther current assets consist of the following:\nprepaid commodity purchase contracts Prepaid commodity purchase contracts represent payments to producers in advance of delivery of the underlying commodities. Prepaid commodity purchase contracts are recorded at market.\nsecured advances to suppliers Bunge provides cash advances to suppliers, which primarily include farmers of soy- beans and other agricultural commodities, to finance a portion  of the suppliers’ production cost. The advances are generally collateralized by physical assets of the supplier, carry a market interest rate and are repaid through the delivery of soybeans and other agricultural commodities. Secured advances to suppliers are stated at the original value of the advance plus accrued interest, less allowances for uncollectible advances. In addition to the current secured advances, Bunge has long-term secured advances to suppliers, primarily farmers, in the amount of  $198 million and $84 million at December 31, 2004 and 2003, respectively. The allowances for uncollectible advances totaled $43 million and $31 million at December 31, 2004 and 2003, respectively.\nmarketable securities These securities are classified as trading securities and recorded at fair value based on quoted market prices. The related gains or losses are recognized in other income and (expense)—net in the consolidated statements of income.\nBunge capitalized interest on construction in progress in the amount of $6 million, $8 million and $6 million in 2004, 2003 and 2002, respectively. Depreciation and depletion expense was $208 million, $182 million and $166 million in 2004, 2003 and 2002, respectively.\n7. change in accounting principles\nEffective January 1, 2002, Bunge adopted SFAS No.142. SFAS No.142 supersedes APB Opinion No.17,  Intangible Assets, and changes the accounting for goodwill and other intangible assets with indefinite lives acquired individually or with a group of other assets, and those acquired in a business combination, by elimi- nating prospectively the amortization of all existing and newly acquired goodwill and other intangible assets with indefinite lives. SFAS No.142 requires goodwill and other intangible assets to be tested at least annually for impairment. Separable other intangible assets that are not deemed to have an indefinite life will continue to be amortized over their useful lives. The amorti- zation provisions of SFAS No.142 apply immediately to goodwill and intangible assets acquired after June 30, 2001. SFAS No.142 also requires that companies complete a transitional goodwill impairment test within six months from the date of adoption.\nIn accordance with the transitional guidance and the adoption of SFAS No.142, Bunge completed a transitional impairment test computed based on a discounted cash flow and recorded a charge of $14 million, net of tax of $1 million as of January 1, 2002 for goodwill impairment losses. This impairment was related mainly to goodwill in the bakery mixes business line of its former wheat milling and bakery products segment. The goodwill impairment\nDecember 31, (US$ in millions) 2004 2003 Prepaid commodity purchase contracts $ 3 37 7 $ 247 Secured advances to suppliers 6 69 97 7 280 Unrealized gains on derivative contracts 3 31 10 0 418 Margin deposits 4 43 3 95 Recoverable taxes 1 13 38 8 70 Marketable securities 1 14 4 13 Other 3 33 38 8 351 Total $ $1 1,,5 57 77 7 $1,474\nDecember 31, (US$ in millions) 2004 2003 Land $ 1 14 40 0 $ 114 Mining properties 2 20 06 6 136 Buildings 9 91 17 7 936 Machinery and equipment 2 2,,4 48 82 2 2,078 Furniture, fixtures and other 2 22 24 4 158 3 3,,9 96 69 9 3,422 Less: accumulated depreciation and depletion ((1 1,,8 81 10 0)) (1,556) Plus: construction in process 3 37 77 7 224 Total $ $ 2 2,,5 53 36 6 $ 2,090\n63"}]}
+{"image": "doclay/doclay_37369.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Receipt of each delivery of  Products  shall be recorded in a  Consignment note  signed by the  contracting authority as stated in Article I.1. of the General Conditions (including the balance  to be delivered for each  Product ). \nFor each  Product  listed in the Annexes of the framework contract, the contractor shall  specify by a  Means of communication  the technical installation requirements and any  refurbishment necessary for the premises intended to house the  Product s. \nThe contracting authority shall ensure that from then onwards the premises where the  Products  are installed satisfy the conditions set out by the contractor regarding access, air– conditioning and electric power supplies and are equipped with the necessary data  transmission lines. \nThe contracting authority shall grant the contractor access to its premises for the assembly  of  Complex hardware products  on the  Installation date , which must be duly notified by the  contractor with a  Means of registered communication  within five (5)  Normal working days  upon the contracting authority’s notification referred to in the last paragraph of Article  IV.3.2.2. \nA pre-installation meeting may be organised. A technical representative of the contractor  will be available for each specific contract for a pre-installation meeting organised on the  contracting authority’s premises. The purpose of this meeting is to review practical issues  related to installation of the  Products  covered in the relevant specific contract. The  minutes of each pre-installation meeting should be drafted after the pre-installation meeting  by the contractor, unless otherwise agreed in this meeting. \nInstallation will be done in conformity with the relative specific contract and/or  Service Level  agreement  and with the minutes of the pre-installation meeting and in accordance the  methodology agreed in the pre-installation meeting if appropriate. \nIf the place of delivery is not the place of installation, the contracting authority shall arrange  for  Products  to be moved at its own risk from the place of delivery to the place of installation  within fifteen (15)  Normal working days  from the day of signature of the  Consignment note  and undertakes to notify the contractor of the place of the move by a  Means of  communication  within five (5)  Normal working days  upon successful move of the  Products  to  the installation site. \nThe assembly of  Complex hardware products  and the bringing into service of a  System  shall  be executed by the contractor at its own expense, unless otherwise agreed in the framework  contract. \nPage 18 of 40 \nIV.3.3.1.  The  Commissioning date\nIV.3.3.  Acceptance \nIV.3.2.2.  Procedure \nIV.3.2.  Product installation \nIV.3.2.1.  Installation requirements \n–  Pre-installation meeting \n–  Installation "}]}
+{"image": "doclay/doclay_45864.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "and airspeed. Speed should be allowed to dissipate before the  pitch attitude is decreased. This point is particularly important  for fast airplanes as they do not readily lose their airspeed— any slight deviation of the airplane’s nose downwards results  in an immediate increase in airspeed. Once the airspeed has  dissipated to best glide speed, the pitch attitude should be set  to maintain that airspeed. This should be done with reference  to the natural horizon and with a quick reference to the flight  instruments. When the airspeed has stabilized, the airplane  should be trimmed to eliminate any flight control pressures  held by the pilot. Precision is required in maintaining the best  glide airspeed if the benefits are to be realized. \nat slow speeds.  With the absent propeller effects and the  subsequent  compensation for these effects, which is designed  into many airplanes, it is likely that, during glides, slight left  rudder pressure is required to maintain coordinated flight.  In addition, the deflection of the flight controls to effect  change is greater due to the relatively slow airflow over the  control surfaces.\nMinimum sink  speed is used to maximize the time that the  airplane remains in flight. It results in the airplane losing  altitude at the  lowest rate. Minimum sink speed occurs at an  airspeed less than the best glide speed. It is important that  pilots realize that flight at the minimum sink airspeed results  in less distance traveled. Minimum sink speed is useful in  flight situations where time in flight is more important than  distance flown. An example is ditching an airplane at sea.  Minimum sink speed is not an often published airspeed but  generally is a few knots less than best glide speed.\nIn an emergency, such as an engine failure, attempting to  apply elevator back pressure to stretch a glide back to the  runway is likely to lead the airplane landing short and may  even lead to loss of control if the airplane stalls. This leads  to a cardinal rule of airplane flying that a student pilot must  understand and appreciate: The pilot must never attempt to  “stretch” a  glide by applying back-elevator pressure and  reducing the air speed below the airplane’s recommended best  glide speed. The purpose of pitch control during the glide is  to maintain the maximum L/D, which may require fore or  aft flight control pressure to maintain best glide airspeed.  must remain alert to any variation in attitude, feel, or sound. After a solid comprehension of the normal glide is attained,  the beginning pilot should be instructed in the differences  between normal and abnormal glides. Abnormal glides are  those glides conducted at speeds other than the best glide  speed. Glide airspeeds that are too slow or too fast may result  in the airplane not being able to make the intended landing  spot, flat approaches, hard touchdowns, floating, overruns,  and possibly stalls and an accident.  Gliding Turns\nTo enter a glide, the pilot should close the throttle and,  if equipped, advance the propeller lever forward. With  back pressure on the elevator flight control, the pilot  should maintai n altitude until the airspeed decreases to  the recommended best glide speed. In most airplanes, as  power is reduced, propeller slipstream decreases over the  horizontal  stabil izer, which decreases the tail-down force,  and the airplane’s nose tends to lower immediately. To keep  pitch attitude  constant after a power change, the pilot must  counteract the  pitch down with a simultaneous increase in  elevator back pressure. If the pitch attitude is allowed to  decrease during glide entry, excess airspeed is carried into  the glide and retards the attainment of the correct glide angle \nThe absence of the propeller slipstream, loss of effectiveness  of the various flight control surfaces at lower airspeeds, and  designed-in aerodynamic corrections complicates the task of  flight control coordination in comparison to powered flight for  the inexperienced pilot. These principles should be thoroughly  explained by the flight instructor so that the beginner pilot  may be aware of the necessary differences in coordination. \nThree elements in gliding turns that tend to force the nose  down and increase glide speed are:\nglide by applying back-elevator pressure and  After a solid comprehension of the normal glide is attained,  the beginning pilot should be instructed in the differences  between normal and abnormal glides. Abnormal glides are  those glides conducted at speeds other than the best glide  speed. Glide airspeeds that are too slow or too fast may result  in the airplane not being able to make the intended landing  spot, flat approaches, hard touchdowns, floating, overruns,  and possibly stalls and an accident. \n3-21\nA stabilized, power-off descent at the best glide speed is  often referred to as normal glide. The beginning pilot should  memorize the airplane’s attitude and speed with reference  to the natural horizon and noting the sounds made by the  air passing over the airplane’s structure, forces on the flight  controls, and the feel of the airplane. Initially, the beginner  pilot may be unable to recognize slight variations in airspeed  and angle of bank by vision or by the pressure required on  the flight controls. The instructor should point out that an  increase in sound levels denotes increasing speed, while a  decrease in sound levels indicates decreasing speed. When  a sound level change is perceived, a beginning pilot should  cross-check the visual and pressure references. The beginning  pilot must use all three airspeed references (sound, visual,  and pressure) consciously until experience is gained, and then  must remain alert to any variation in attitude, feel, or sound.\nFigure 3-24.  Best glide speed provides the greatest forward distance  for a given loss of altitude.\nGliding Turns\n• Decrease in lift due to the direction of the lifting force\n• Excessive rudder inputs as a result of reduced flight  control pressures\n14 Too slow Too fast Best glide spee d"}]}
+{"image": "doclay/doclay_56542.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "UCI CYCLING REGULATIONS \nClassifier, as well as any other disciplinary measure provided in Part XII of the UCI  Regulations.\n(text introduced on 23.10.19) \nPart Three: Athlete Evaluation \n16.4.007  General Provisions \n16.4.008  Eligible Impairment  Any Athlete wishing to compete in para-cycling must have an Eligible Impairment which \nAthlete Evaluation is the process by which an Athlete is assessed in accordance with  these Classification Rules in order to be allocated a Sport Class and designated a Sport  Class Status. \nAthlete Evaluation encompasses a number of steps and these Classification Rules  therefore include provisions regarding: \na)  An assessment to determine whether the Athlete has an Eligible Impairment for  para-cycling; \nb)  An assessment to determine whether the Athlete complies with the Minimum  Impairment Criteria (MIC) for para-cycling; and\nc)  the allocation of a Sport Class (and designation of a Sport Class Status)  depending on the extent to which the Athlete is able to execute the specific tasks  and activities fundamental to para-cycling (with the exception for athletes with  Vision Impairment where the current assessment criteria is not yet sport specific  and does not include a requirement that the athletes are assessed in respect of  the ‘extent to which the Athlete is able to execute the specific tasks and activities  fundamental to the sport’). \n(text modified on 01.02.18)\nEligible Impairment  Any Athlete wishing to compete in para-cycling must have an Eligible Impairment which  must be Permanent.\nArticle 16.5.001 of the UCI Cycling Regulations specifies the Eligible Impairment(s) an  Athlete must have in order to compete in para-cycling.\nAny Impairment that is not listed as an Eligible Impairment in article 16.5.001, is referred  to as a Non-Eligible Impairment. Article 16.5.009 includes examples of Non-Eligible  Impairments. \nAssessment of Eligible Impairment  The UCI must determine if an Athlete has an Eligible Impairment.\nAssessment of Eligible Impairment  The UCI must determine if an Athlete has an Eligible Impairment.\nIn order to be satisfied that an Athlete has an Eligible Impairment, the UCI requires all  Athletes to demonstrate that he or she has an Underlying Health Condition. Article  16.5.010 lists examples of Health Conditions that are not Underlying Health Conditions. \nThe means by which the UCI determines whether an Athlete has an Eligible Impairment  is at the sole discretion of the UCI. The UCI may consider that an Athlete’s Eligible  Impairment is sufficiently obvious and therefore not require evidence that demonstrates  the Athlete’s Eligible Impairment. \nE0121 \nPARA-CYCLING \n14 "}]}
+{"image": "doclay/doclay_57415.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Optimizing SELECT Statements\nPrior to MySQL 8.0.20, a hash join could not be used if any pair of joined tables did not have at least one equi-join condition, and the slower block nested loop algorithm was employed. In MySQL 8.0.20 and later, the hash join is used in such cases, as shown here:\nmysql>  EXPLAIN FORMAT=TREE ->  SELECT * FROM t1 -> JOIN t2 ON (t1.c1 = t2.c1) -> JOIN t3 ON (t2.c1 < t3.c1)\\G *************************** 1. row *************************** EXPLAIN: -> Filter: (t1.c1 < t3.c1) (cost=1.05 rows=1) -> Inner hash join (no condition) (cost=1.05 rows=1) -> Table scan on t3 (cost=0.35 rows=1) -> Hash -> Inner hash join (t2.c1 = t1.c1) (cost=0.70 rows=1) -> Table scan on t2 (cost=0.35 rows=1) -> Hash -> Table scan on t1 (cost=0.35 rows=1)\n(Additional examples are provided later in this section.)\nA hash join is also applied for a Cartesian product—that is, when no join condition is specified, as shown here:\nmysql>  EXPLAIN FORMAT=TREE ->  SELECT * -> FROM t1 -> JOIN t2 -> WHERE t1.c2 > 50\\G *************************** 1. row *************************** EXPLAIN: -> Inner hash join (cost=0.70 rows=1) -> Table scan on t2 (cost=0.35 rows=1) -> Hash -> Filter: (t1.c2 > 50) (cost=0.35 rows=1) -> Table scan on t1 (cost=0.35 rows=1)\nIn MySQL 8.0.20 and later, it is no longer necessary for the join to contain at least one equi-join condition in order for a hash join to be used. This means that the types of queries which can be optimized using hash joins include those in the following list (with examples):\n• Inner non-equi-join :\nmysql>  EXPLAIN FORMAT=TREE SELECT * FROM t1 JOIN t2 ON t1.c1 < t2.c1\\G *************************** 1. row *************************** EXPLAIN: -> Filter: (t1.c1 < t2.c1) (cost=4.70 rows=12) -> Inner hash join (no condition) (cost=4.70 rows=12) -> Table scan on t2 (cost=0.08 rows=6) -> Hash -> Table scan on t1 (cost=0.85 rows=6)\n• Semijoin :\nmysql>  EXPLAIN FORMAT=TREE SELECT * FROM t1  -> WHERE t1.c1 IN (SELECT t2.c2 FROM t2)\\G *************************** 1. row *************************** EXPLAIN: -> Nested loop inner join -> Filter: (t1.c1 is not null) (cost=0.85 rows=6) -> Table scan on t1 (cost=0.85 rows=6) -> Single-row index lookup on <subquery2> using <auto_distinct_key> (c2=t1.c1) -> Materialize with deduplication -> Filter: (t2.c2 is not null) (cost=0.85 rows=6) -> Table scan on t2 (cost=0.85 rows=6)\n• Antijoin :\nmysql>  EXPLAIN FORMAT=TREE SELECT * FROM t2 \n1655"}]}
+{"image": "doclay/doclay_14920.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "|  21  2012 AnnUAL REPORT\nOtis elevators, escalators and moving walk- ways are the innovative systems of choice  for some of the largest and most ambitious  building projects around the globe. \nDuring the year, its United Kingdom business  was awarded the largest contract in its history   —a 30-year contract to install, maintain and  modernize 107 escalator units for the London  Crossrail, a new high-frequency railway sys- tem and Europe’s largest construction project.  Work is scheduled to begin in early 2013. \ntem and Europe’s largest construction project.  Work is scheduled to begin in early 2013. \nOtis businesses will supply 208 energy-  efficient Gen2 and Sky series elevators to the  Castle Jiujun project, a more than 7.5-million- square-foot ecological and livable community  in southern Harbin, China. Also in China, Otis  companies will provide 299 escalators and 50  elevators to the Hangzhou Metro Line 2, one of  the country’s new, high-speed rail systems. \nOtis continues to be a part of some of the  world’s most iconic buildings. Its company in  Brazil will install 21 elevators and escalators  in Rio de Janeiro’s famous Maracanã Stadium,  site of the 2014 FIFA World Cup final champi- onship match and the 2016 Summer Olympics  opening and closing ceremonies. The com- pany also is assisting with the modernization  of the Sydney Opera House in Australia, one of  the world’s most distinctive buildings. \nOtis companies are building a number of factories to meet growing demand. During  the year, Otis companies opened the seventh  factory in China and began expansion on a  factory in Bengaluru, India. In 2013, the com- pany will open a 423,000-square-foot facility in  Florence, S.C., which will be its main manufac- turing center for U.S. and Canadian operations.  Another factory is under construction in Brazil. \nturing center for U.S. and Canadian operations.  Another factory is under construction in Brazil. \nOtis Elite service is a key differentiator for the company. Using innovative, Web-based  technology, it offers customers an unprece- dented level of support and benefits that help  ensure maximum equipment reliability and efficient repairs of their elevator systems. Otis Elite service subscriptions were up\nefficient repairs of their elevator systems. Otis Elite service subscriptions were up 25 percent from 2011. \nThe Otis regenerative drive continues to set  the standard for innovation and performance.  When used on elevators, it captures energy \nthe standard for innovation and performance.  When used on elevators, it captures energy  once lost during braking and returns it to the  electrical grid, providing up to 75 percent  more energy efficiency.\nUTC Climate, Controls & Security delivers  solutions to customers worldwide from leading  brands such as Carrier, Automated Logic,  Lenel, Chubb, Det-Tronics, Edwards, Fenwal,  Interlogix, Kidde, Marioff and Supra. \nDuring the year, the company sustained  momentum from the completed Carrier trans- formation, which began in 2008 to simplify  the business and concentrate on core growth  platforms. The company also focused on  improving and transforming its fire and security operations. \nNumerous product innovations were  introduced in 2012, including Kidde’s new  Worry-Free line of smoke alarms. Equipped  with a 10-year, sealed-in battery, the alarms  address customer complaints of low-battery  chirps and fire industry concerns about  missing or dead batteries in alarm units. \nCarrier Transicold introduced ecoFORWARD  technologies in advance of U.S. Environmental  Protection Agency diesel emission standards,  which went into effect January 1, 2013. Trailer  refrigeration systems with ecoFORWARD  technologies consume significantly less fuel,  operate more quietly and deliver improved  performance, all while running cleaner than the  models they are replacing. \nfrom OnGuard’s strong integration capabil- ity and increased functionality. Deployed in  transit vehicles around the world, Interlogix’s  Mobileview is the first and only mobile sur- veillance solution to be designated Qualified  Anti-Terrorism Technology by the U.S.  Department of Homeland Security. \n2012 marked the 500 th  installation of Carrier’s  CO$_{2}$OLtec refrigeration system, this one in a  new Famila market in Friesoythe, Germany.  Carrier’s CO$_{2}$OLtec installations across Europe \nnew Famila market in Friesoythe, Germany.  Carrier’s CO$_{2}$OLtec installations across Europe  reduce carbon dioxide equivalent emissions  by 137,100 tons, equal to taking 37,200 cars off the road. Carrier also won its largest order  in Saudi Arabia during the year with a contract  to supply and install large chillers to cool King Saud University. \nAutomated Logic will provide the building auto- mation system for The Tower at PNC Plaza, a 32-story office building under construction  in Pittsburgh, Pa., that is expected to exceed  LEED Platinum standards and become the  world’s greenest skyscraper. The system will  provide a comfortable environment for the  building’s occupants through control and monitoring of heating, cooling and many third-party systems. \nUTC Climate, Controls & Security reached  a number of milestones in 2012. Several  Carrier products achieved breakthrough  energy efficiency: Among them were the new  WeatherExpert packaged rooftop unit, the new Infinity 98 gas furnace with Greenspeed  intelligence and the Evergreen 23xRv chiller  with Foxfire compression, which set a new record for chiller efficiency. Carrier  Transicold’s NaturaLINE and PrimeLINE container refrigeration units were validated by UL Environment as having 95 percent and  93 percent recyclability rates, respectively, the only container refrigeration units in the  industry to achieve recyclability validation. \nLenel introduced OnGuard 2012, the latest  release of its industry-leading security  management platform. Customers benefit \nSupra won six contract renewals to supply  iBox products to real estate associations  throughout the United States. Five of the contracts were for the new iBox BT, a real  estate key box that can interact with Bluetooth smartphones. \n01 Carrier’s AquaForce 30XA chiller is designed  to meet the efficiency demands of today and  the future. \n02 UT Electronic Controls, which designs,  sources and manufactures microproces- sor-based controls, is the first electronics  manufacturing facility to receive LEED Gold  certification for existing buildings.\n03 Customers no longer have to worry about  replacing smoke alarm batteries. Kidde’s  new Worry-Free line of smoke alarms comes  with a  10 -year, sealed-in battery. "}]}
+{"image": "doclay/doclay_9664.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Segment Information (continued)  Primary Segment – 30 June 2002 Comparative (continued) \nSegment Information (continued)  Primary Segment – 30 June 2002 Comparative (continued) \nFranchising  and  Corporate  Retail –  New  Zealand  Retail –  Rebel Sport Asia  Non- Franchised Retail  Property  Investments Property  Under  Construction  for  Investment  Property  Development  for Resale  Financial  Services  Share  Trading  Eliminations Consolidated  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000  2002  $000 \nAssets \nLiabilities \nOther Segment  Information \nSegment Assets 3,385,974 47,480 110,796 100,645 53,904 582,747 93,622 11,375 216,523 8,982 (2,943,546) 1,668,502 Less: Eliminations (2,734,847)  -  -  -  (1,851)  (21,798)  (6,012)  (7)  (179,031)  -  2,943,546  -   A ssets After Eliminations  651,127  47,480  110,796  100,645  52,053  560,949  87,610  11,368  37,492  8,982  -  1,668,502 \nSegment Liabilities 2,788,244 32,536 58,838 36,812 56,081 477,532 83,931 15,186 185,219 1,775 (2,943,546) 792,608 Less: Eliminations (2,734,847)  -  -  -  (1,851)  (21,798)  (6,012)  (7)  (179,031)  -  2,943,546  -   Lia bilities After Eliminations  53,397  32,536  58,838  36,812  54,230  455,734  77,919  15,179  6,188  1,775  -  792,608   T otal Liabilities  792,608 \nEquity accounted  investments included in  segment assets  -  -  -  -  1,538  26,612  6,237  8,000  -  -  -  42,387  Depreciation 34,432 1,838 4,013 3,990 859 7,100 61 - 81 - - 52,374 Amortisation -  -  4,859  -  199  -  -  -  -  -  -  5,058  Non-cash expenses other  than depreciation and  amortisation  795  -  767  -  2,652  1  -  -  698  -  -  4,913  Acquisition of property, plant  and equipment, intangible  assets and other non- current assets  43,212  3,458  17,544  1,344  5,130  90,738  14,198  1,815  52,551  6,478  -  236,468 \nHARVEY NORMAN HOLDINGS LIMITED AND ITS CONTROLLED ENTITIES – ANNUAL REPORT 2003\n25 "}]}
+{"image": "doclay/doclay_37807.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "54 of 124 \nConstruction of Giresun Wastewater Treatment Plant  Tender Dossier Volume 3 Employer’s Requirements  Section 08: Electrical Works \nGeneral junction boxes are to be constructed of aluminium complete with lid and captive gasket to a degree of  IP 65. The necessary number and size of entries together with terminals are to be designed according to circuit  requirements. General junction boxes shall be suitable for direct mounting with external fixing holes, and are to  be labelled with reference number. \nPower connection will be made between MCC boards and local boards. Signal cable will be connected directly.  Terminal box will be IP65 and aluminum in submersible pumps and pump power and signal cables will be  connected in same terminal box. \n8.12 Junction Boxes \n8.13 Cable Entries \n8.15 Cables \n8.14 Cable Glands \n8.15.1 Power cables \n8_Vol3_d4 3_Section 8 electrical works_en_GIR rev6.doc \n• PVC for internal building. \n• Cross-linked-polyethylene (XLPE) for all other locations. \nPower cables shall generally consist of two types: \nPower cables shall be selected such that the voltage drop does not exceed the maximum value defined in IEC  60364 at any point in the installation. \nCable sizes, types and construction must be chosen with due regard to the connected equipment requirements,  ambient conditions, installation method, and fault and overcurrents. Generally, the cable manufacturer's  published data are to be used in determining cable adequacy. \nAll cables used in the plant shall be of stranded type and shall have necessary protection against rodents.\nPower cables are cables having operating range U  50 V. Signal cables are cables having operating range U<50  V \nAll cable glands are to be of the compression type acting upon the cable sheath and where necessary provided  with stockings, which grip the cable. All cable glands are to be of corrosion resistant metal or plastic cable  glands will be accepted if it is not original accessory of provided equipment. Cable glands are to be of a type,  which will not reduce the degree of tightness of an enclosure, and are to be correctly sized to the cable they  seal. \nEach mounting frame shall be embedded in walls. \nThe cable penetration system shall comprise a steel-mounting frame packed with insert blocks to accommodate  the cables and to fill out surplus room. After cable installation the insert blocks shall be compressed to complete  the sealing. \nCable entries from one room to another or from outside to inside shall be performed by watertight and fireproof  multi cable penetration seals to provide an efficient barrier against fire, smoke, flooding and vermin.\nTerminals are to be arranged at different heights for different services and a barrier is to be provided to shield  instrument circuits from power circuits at different voltages. Terminals are to be of the necessary number and  size (20 % spare) and determined according to respective circuit requirements. "}]}
+{"image": "doclay/doclay_17874.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "RESEARch\nEthical Considerations in Research on  Human Subjects and Specimens Derived  from Humans\nBiosafety Control\nEthical Considerations in Animal Testing\nHandling of Intellectual Property\nclInIcAl DEVEloPmEnT\nProtection of Human Rights, Privacy and Confidentiality of Personal Information of Research Subjects, and Assurance of  Reliability in Clinical Trials\nAstellas conducts research on human subjects and research on  specimens derived from humans, following obtained appropriate  consent in accordance with the laws, regulations and guidelines  of relevant countries. In Japan, Astellas offers training for  researchers in areas such as bioethics, genomic research and  clinical studies, based on a strong commitment to respecting  the human rights of research subjects, protecting privacy and  ensuring the reliability of research. Furthermore, Astellas has an  Astellas Research Ethics Committee, which consists of nine  members of both genders, including 4 outside members. The  Committee deliberates on the scientific propriety and the ethical  acceptability of research. In fiscal 2013, the Committee met 12  times and deliberated on 27 issues.\nAstellas has established the Institutional Animal Care and Use  Committee, in which outside members participate as committee  members, overseeing the Company’s animal testing and breed- ing plans in Japan. In fiscal 2013, the Company established the  Global Policy for the Use and Care of Animals.\nAstellas’ initiatives in animal testing are recognized by AAALAC  International*. As a result, all of Astellas’ animal testing facilities in  Japan and our U.S. subsidiary Agensys have acquired accredita- tion from AAALAC International. In fiscal 2013, the Tsukuba  Research Center and the Yaizu Technology Center received  follow-up audits by AAALAC International to renew their accredi- tations. In March 2014, the accreditations of both facilities were  renewed.\nAstellas regards its intellectual property (patents in particular)  relating to new compounds or other findings as valuable busi- ness assets. Employees receive ongoing training to raise their  awareness on obtaining patents and swiftly making patent appli- cations and acquiring rights. At the same time, we emphasize  respecting the rights of others. We make sure our research does  not infringe on third-party patents, and if necessary, we obtain  approval to use them so as not to infringe on the patent estate  of others.\nIn fiscal 2013, we unified the standards underlying our  approach to intellectual property on a global basis by establishing  the Global Policy on Intellectual Property.\nExperiments using genetically modified organisms, or materials  containing pathogens are performed under the World Health  Organization (WHO) Laboratory Biosafety Manual and the Centers  for Disease Control and Prevention (CDC)/National Institute of  Health (NIH)  Biosafety in Microbiological and Biomedical   Laboratories , as well as the laws of individual countries. In Japan,   Astellas has established biosafety management rules in compli- ance with the Cartagena Protocol on Biosafety* and related  ministerial ordinances, and has set forth detailed handling proce- dures. We have also set up the Biosafety Committee to review  whether the experiments meet the standard required by these  rules. Laboratory personnel receive regular training courses once  a year (1,037 participants in fiscal 2013), in order to rigorously  enforce safe and proper biosafety management and use of these  organisms and suchlike. In the U.S., we conduct such experi- ments based on the rules established by the occupational health  and safety (OHS) authorities.\n* AAALAC International: The Association for Assessment and Accreditation  of Laboratory Animal Care International. An organization that promotes  the humane treatment of animals through voluntary accreditation and  assessment programs. Studies are undertaken both from scientific and  ethical standpoints to verify the quality of animal control and use programs.\n* Law Concerning the Conservation and Sustainable Use of Biological  Diversity through Regulations on the Use of Living Modified Organisms\nof clinical trial subjects. Furthermore, it is crucial to conduct  assessments in clinical trials scientifically and accurately in order  to develop new drug candidates into drugs that can be used  confidently by patients. Accordingly, Astellas has a clinical devel- opment framework in place to ensure compliance with GCP and  relevant laws and regulations. Moreover, our clinical trials are  conducted only at medical institutions complying with the rel- evant laws and regulations.\nIn clinical trials, we investigate new drug candidates developed  through drug discovery research in further detail, and assess their  efficacy and safety in patients. Under the Helsinki Declaration*,  clinical trials must be fully ethically planned and safely conducted  with full consideration to protecting the human rights and privacy \nAstellas Pharma Inc.  _ Annual Report 2014\n54"}]}
+{"image": "doclay/doclay_35497.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Naoz, Perets & Ragozzine\n8\nally interacting satellites, creates a unique brand of tidal evolution. Multiple resonance crossings can excite ec- centricities and inclinations, perhaps leading to instabil- ity (e.g., Canup et al. 1999). In hierarchical systems with significant mutual inclination, the Kozai-Lidov ef- fect may destabilize the system (Perets & Naoz 2009). For all multiple systems, survival to the present epoch can be difficult, and multiples must have been more com- mon in the primordial population. Additional study of these multiple minor planet sys-\nmon in the primordial population. Additional study of these multiple minor planet sys- tems will provide unique insights into the formation and evolution of these systems. See Benecchi et al. (2009b) for an additional review of multiple minor planet sys- tems, including a table of properties.\ncounters formed/perturbed the binaries and strongly af- fected their orbital evolution. We suggest that these en- counters together with secular Kozai evolution and tidal effects, could have erased much of the direct signatures of the initial formation of BMPs, as possibly reflected by their observed orbits (see also Perets & Naoz 2009). More theoretical work, however, is required to under- stand the different parts played by the initial formation and configurations of BMPs vs. their later dynamical evolution. Especially important are better theoretical predictions for the observational signatures of different BMP formation scenarios, which could be compared with the data presented in this paper and additional future data.\nIn this paper we compiled a catalog of BMPS, both binary TNOs and binary asteroids, with full orbital so- lutions. We presented a first analysis of the eccentricity and inclinations distribution of BMPs as well as their semi-major axis-eccentricity distribution. This data and its analysis can be used to study and constrain forma- tion and evolutionary scenario of BMPs. Specifically we find high relative inclinations for the BMPs as well as typically large (but not extremely high) eccentricities for BMPs not affected by tidal evolution. By themselves these results already suggest BMPs evolved in dense en- vironment in which collisions and close gravitational en-\nWe thank Eran Ofek for useful discussion regarding the transformation from the ecliptic plane to the equato- rial frame of reference. SN acknowledge the partial sup- port by Israel Science Foundation grant 629/05 and U.S.- Israel Binational Science Foundation grant 2004386. SN and HBP acknowledge the generous support of the Dan David Fellowship. HBP is a CfA, Rothschild, FIRST and Fullbright fellow. HBP also acknowledges the Israeli commercial and industrial club for their support through the Ilan-Ramon-Fullbright fellowship. DR is grateful for the support by NASA Headquarters under the Earth and Space Sciences Fellowship.\nThe mutual inclination i$_{m}$ represent the angle between the inner and the outer orbit. All of the heliocentric parameters are given with respect to the ecliptic plane, while the inner orbital parameters are given with respect to the equatorial frame of reference. Thus, we first transform the heliocentric inclination and the longitude of ascending node from the ecliptic plane ( i$_{c}$, Ω$_{c}$ ) to the equatorial frame of reference ( i$_{q}$, Ω$_{q}$ ). Let us define the pole vector with respect to the ecliptic (equatorial) frame, P$_{c}$ ( P$_{q}$ ):\n4. SUMMARY\nAPPENDIX\nCALCULATION OF THE MUTUAL INCLINATION\nACKNOWLEDGMENTS\nThe rotation matrix from the ecliptic to the equatorial is rotation with respect to the x axis of the invariable plane, i.e.,\nwhere ϵ is the ecliptic angle. Thus, the resulting equations of the transformation from the ecliptic to the equatorial are:\n$_{P$_{c,q}$}$  x y z   =   sin Ω$_{c,q}$ sin i$_{c,q}$ − cos Ω$_{c,q}$ sin i$_{c,q}$ cos i$_{c,q}$   . (A1)\nR ( x )$_{c}$ $^{→}$q =   1 0 0 0 cos ϵ − sin ϵ 0 sin ϵ cos ϵ   . (A2)\ncos( i$_{q}$ ) = cos( i$_{c}$ ) cos( ϵ ) − sin( i$_{c}$ ) sin( ϵ ) cos(Ω$_{c}$) , (A3) cos(Ω$_{q}$) sin( i$_{q}$ ) = cos( i$_{c}$ ) sin( ϵ ) + sin( i$_{c}$ ) cos( ϵ ) cos(Ω$_{c}$) , sin(Ω$_{q}$) sin( i$_{q}$ ) = sin(Ω$_{c}$) sin( i$_{c}$ ) ,\nP $^{out}$,s =   sin Ω $^{out}$,in sin i $^{out}$,in − cos Ω $^{out}$,in sin i $^{out}$,in cos i $^{out}$,in   , (A4)\nwhere from the last two equations we can find Ω$_{q}$ using the atan 2( x, y ) function. Now we turn to calculate the mutual inclination. We take the longitude of ascending node and inclinations with\nwhere from the last two equations we can find Ω$_{q}$ using the 2( ) function. Now we turn to calculate the mutual inclination. We take the longitude of ascending node and inclinations with respect to equatorial frame (resulting from the above transformation) of the inner and outer orbit, i.e., i out , Ω out , and i$_{s}$, Ω$_{s}$ , and calculate the mutual inclinations. Again let us define the binary outer orbit and inner pole vectors as:"}]}
+{"image": "doclay/doclay_74569.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "About Accenture\nAccenture is the world's leading management and technology services organization. Through its network of businesses approach—in which the company enhances its consulting and outsourcing expertise through alliances, affiliated companies and other capabilities—Accenture delivers innova- tions that help clients across all industries quickly realize their visions.\nWith more than 75,000 people in 47 countries, Accenture can quickly mobilize its broad and deep global resources to accelerate results for clients. The company has extensive experience in 18  industry groups in key business areas, including customer relationship management, supply chain management, business strategy, technology and outsourcing. Accenture also leverages its affiliates, alliances and venture capital activities to help drive innovative solutions. Strong relationships within this network of businesses extend Accenture's knowledge of emerging business models and  products, enabling the company to provide its clients with the best possible tools, technologies and capabilities. Accenture uses these resources to serve as a catalyst, helping clients anticipate and gain value from business and technology change.\nRecognizing the important role of business in society, Accenture supports the active involvement of its people in community volunteer initiatives all around the world. The company also is involved in major projects where it can leverage its capabilities in cooperation with other businesses, governments and organizations to make a positive contribution to the communities in which it oper- ates. For example, Accenture is co-chairing the World Economic Forum task force on the digital divide and is taking a lead role in the G8 Digital Opportunities task force. Both initiatives seek to ensure that far more of the world's people are given the chance to benefit from the combination of entrepreneurship and new technology to create a virtuous circle of economic development.\nAccenture’s home page is www.accenture.com.\n© 2001 Accenture. All rights reserved. Accenture and the Accenture logo are trademarks of Accenture and/or its affiliates in the United States and certain other countries. All other trademarks and registered trademarks mentioned in this document are the property of their respective owners.\nForward-looking Statements and Certain Factors that May Affect Our Business—We have included in this report and in our Annual Report on Form 10-K filed with the SEC, forward-looking statements relating to our operations that are based on our current expectations, estimates and projections. Words such as “expects,” “intends,” “plans,” “projects,” “believes,” “estimates” and similar expressions are used to identify these forward-looking statements. These statements are not guaran- tees of future performance and involve risks, uncertainties and assumptions that are difficult to predict. Forward-looking statements are based upon assumptions as to future events that may not prove to be accurate. Actual outcomes and results may differ materially from what is expressed or forecast in these forward-looking statements.\nAccenture Technology Ventures helps talented entrepreneurs build companies that can transform entire industries, create new markets and ulti- mately generate superior economic returns. Its portfolio includes innovative companies that are building key components of tomorrow's commerce infrastructure. Launched in December 1999, Accenture Technology Ventures is the venture capital unit of Accenture. Its home page is www.accenturetechventures.com.\nAccenture Technology Ventures \nAccenture\n36"}]}
+{"image": "doclay/doclay_75644.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Notes to the Financial Statements  For the year ended 30 September \n38. Superannuation commitments (continued) \nOrica Limited 120\n(c) (ix) Surplus/(deficit) for major defined benefit plans  30 September 2012  Plan  Accrued  Benefits   Fund  Assets  Accrued  (deficit)/ surplus Current contribution recommendation  Discount  rate Expected  return on  plan assets Future  salary  increases  $m $m $m % % % The Flexible Benefits Super Fund  (2a) 347.5 257.4 (90.1) 13.0% of salaries 2.90 7.00 3.75 Pension Plan for Employees of Orica  Canada Inc $^{(2b)}$  115.3 93.0 (22.3) Set in accordance with local annual funding requirements  4.75 5.80 3.25 Post Retirement Benefits (Canada) $^{(2c)}$  18.8 - (18.8) Based on benefit payments  4.75 n/a n/a Orica Pension Scheme (UK) $^{(2b)}$  37.7 31.0 (6.7) 25.0% of pensionable earnings  4.10 5.50 2.70 Dyno Nobel Sweden AB $^{(2d)}$  32.7 - (32.7) Based on benefit payments  3.50 n/a  3.50 Nitro Consult AB (Sweden) $^{(2d)}$  11.3 (11.3) n/a Dyno DNE (Norway) $^{(2e)}$  19.5 17.9 (1.6) Insurance premiums  2.25 4.10 3.50 Dyno Defence (Norway)$^{ (2e)}$  3.4 3.4 - Dynea HK (Norway) $^{(2e)}$  7.0 3.6 (3.4) Insurance premiums  2.25 4.10 3.50 Orica New Zealand Ltd Retirement  Plan $^{(2b)}$  29.4 18.4 (11.0) 15.8% of salaries  2.60 5.40 3.50 Orica USA Inc. Retirement Income  Plan $^{(2b)}$  29.0 18.8 (10.2) Set in accordance with local  annual funding requirements  3.75 7.25 n/a Minova USA Retirement Plans $^{(2b)}$  21.6 14.2 (7.4) Set in accordance with local  annual funding requirements  3.75 7.25 n/a Orica’s Benefit Plan (Brazil) $^{(2b)}$  6.4 5.5 (0.9) Set in accordance with local  annual funding requirements  9.20 9.62 6.59 Other $^{(1)}$  34.7 10.9 (23.8) Various  Various Various Various 714.3 474.1 (240.2) Restriction on assets recognised (0.3) (240.5)  30 September 2011  Plan  Accrued  Benefits   Fund  Assets  Accrued  (deficit)/ surplus Current  contribution recommendation  Discount  rate Expected  return on  plan assets Future  salary  increases  $m $m $m % % % The Flexible Benefits Super Fund  (2a) 302.8 239.2 (63.6) 13.0% of salaries  4.00 7.25 3.75 Pension Plan for Employees of Orica  Canada Inc $^{(2b)}$  97.6 75.9 (21.7) Set in accordance with local annual funding requirements  5.50 6.70 3.75 Post Retirement Benefits (Canada) $^{(2c)}$  17.1 - (17.1) Based on benefit payments  5.50 n/a n/a Orica Pension Scheme (UK) $^{(2b)}$  37.6 30.0 (7.6) 25.0% of pensionable earnings  5.05 7.05 3.55 Dyno Nobel Sweden AB $^{(2d)}$  33.9 - (33.9) Based on benefit payments  3.90 n/a 3.50 Nitro Consult AB (Sweden) $^{(2d)}$  10.9 (10.9) Dyno DNE (Norway) $^{(2e)}$  21.4 19.3 (2.1) Insurance premiums  3.30 5.60 3.75 Dyno Defence (Norway) $^{(2e)}$  3.9 3.6 (0.3) Dynea HK (Norway) $^{(2e)}$  8.6 4.3 (4.3) Insurance premiums  3.30 5.60 3.75 Orica New Zealand Ltd Retirement  Plan $^{(2b)}$  27.3 17.8 (9.5) 15.8% of salaries  3.20 5.90 3.50 Orica USA Inc. Retirement Income  Plan $^{(2b)}$  25.1 16.5 (8.6) Set in accordance with local  annual funding requirements  5.25 8.00 n/a Minova USA Retirement Plans $^{(2b)}$  18.4 12.9 (5.5) Set in accordance with local  annual funding requirements  5.25 7.50 n/a Orica’s Benefit Plan (Brazil) $^{(2b)}$  6.1 7.1 1.0 Set in accordance with local  annual funding requirements  10.88 12.32 6.59 Other $^{(1)}$  31.5 10.7 (20.8) Various  Various Various Various 642.2 437.3 (204.9) Restriction on assets recognised (1.1) (206.0)\n(c) (ix) Surplus/(deficit) for major defined benefit plans  September 2012  Accrued   Fund  Accrued "}]}
+{"image": "doclay/doclay_24597.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "non-Hermitian P ϕ T $_{ϕ}$-symmetrized and/or P θ T $_{θ}$-symmetrized (anticipated to be feasible but yet to be identified) Hamiltonians better be nicknamed as pseudo- PT -symmetric Hamiltonians.\n16"}]}
+{"image": "doclay/doclay_21085.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "PART II  ITEM 7 Management’s Discussion and Analysis of Financial Condition and Results of Operations\nQuarterly Results of Operations\nJETBLUE AIRWAYS CORPORATION  -  2013 Annual Report 31\n(3)  Excludes results of operations and employees of LiveTV, LLC, which are unrelated to our airline operations and are immaterial to our consolidated operating results.\n(2)  During the fourth quarter of 2013 we recorded $3 million in losses related to the early extinguishment of a portion of our long-term debt. \n(1)  During the second quarter of 2013, LiveTV recorded a gain of approximately $7 million relating to the sale of the Airfone business. During the fourth quarter of 2013, we recorded net gains  of approximately $2 million related to the sale of three spare aircraft engines.\nThe following table sets forth selected financial data and operating statistics for the four quarters ended December 31, 2013. The information for each  of these quarters is unaudited and has been prepared on the same basis as the audited consolidated financial statements appearing elsewhere in this  Form 10-K.\nThree Months Ended March 31,  2013 June 30,  2013 September 30,  2013 December 31,  2013 Statements of Operations Data  (dollars in millions) Operating revenues $ 1,299 $ 1,335 $ 1,442 $ 1,365 Operating expenses: Aircraft fuel and related taxes 467 465 501 466 Salaries, wages and benefits 280 279 283 293 Landing fees and other rents 70 80 81 74 Depreciation and amortization 68 71 73 78 Aircraft rent 32 33 32 31 Sales and marketing 50 53 60 60 Maintenance materials and repairs 114 111 109 98 Other operating expenses (1) 159 141 151 150 Total operating expenses 1,240 1,233 1,290 1,250 Operating income 59 102 152 115 Other income (expense) (2) (36) (42) (33) (38) Income before income taxes 23 60 119 77 Income tax expense 9 24 48 30 NET INCOME $ 14 $ 36 $ 71 $ 47 Operating margin 4.5% 7.6% 10.5% 8.4% Pre-tax margin 1.8 % 4.5 % 8.2 % 5.7 % Operating Statistics: Revenue passengers  (thousands) 7,300 7,753 8,059 7,351 Revenue passenger miles  (millions) 8,506 9,115 9,561 8,654 Available seat miles ASM  (millions) 10,140 10,741 11,252 10,691 Load factor 83.9% 84.9% 85.0% 80.9% Aircraft utilization  (hours per day) 11.9 12.2 12.2 11.5 Average fare $ 162.53 $ 157.51 $ 164.02 $ 168.94 Yield per passenger mile  (cents) 13.95 13.40 13.83 14.35 Passenger revenue per ASM  (cents) 11.70 11.37 11.75 11.62 Operating revenue per ASM  (cents) 12.81 12.42 12.82 12.77 Operating expense per ASM  (cents) 12.23 11.48 11.47 11.70 Operating expense per ASM, excluding fuel  (cents) 7.62 7.15 7.02 7.34 Operating expense per ASM, excluding fuel and profit sharing  (cents) 7.62 7.15 6.95 7.30 Airline operating expense per ASM  (cents) (3) 12.06 11.36 11.33 11.52 Departures 66,773 70,722 74,206 70,432 Average stage length  (miles) 1,092 1,088 1,085 1,095 Average number of operating aircraft during period 180.3 183.1 187.1 189.9 Average fuel cost per gallon, including fuel taxes $ 3.29 $ 3.06 $ 3.14 $ 3.10 Fuel gallons consumed  (millions) 142 152 160 150 Full-time equivalent employees at period end (3) 12,385 12,743 12,124 12,647"}]}
+{"image": "doclay/doclay_24145.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "CONSOLIDATED STATEMENTS OF EARNINGS  Years Ended March 31, 2010, 2009, and 2008  (In thousands, except share and per share data)  2010  2009  2008  Revenues: Vessel revenues $ 1,138,162 1,356,322 1,215,134 Other marine revenues 30,472 34,513 55,037 1,168,634 1,390,835 1,270,171 Costs and expenses:  Vessel operating costs  605,259  660,876  584,746  Costs of other marine revenues  27,387  29,282  47,423  Depreciation and amortization 130,184  126,231  120,837  General and administrative 149,932 136,228 126,589 Provision for Venezuelan operations, net  43,720  ---  ---  Gain on asset dispositions, net  (28,178)  (27,251)  (11,449)  928,304 925,366 868,146 Operating income  240,330  465,469  402,025  Other income (expenses):  Foreign exchange gain (loss)  4,094  2,695  (891)  Equity in net earnings of unconsolidated companies  18,107  16,978  14,470  Interest income and other, net  6,882  7,066  16,957  Interest and other debt costs  (1,679)  (693)  (6,992)  27,404 26,046 23,544 Earnings before income taxes  267,734  491,515  425,569  Income tax expense  8,258  84,617  76,806 Net earnings  $  259,476  406,898  348,763  Basic earnings per common share  $  5.04  7.92  6.43  Diluted earnings per common share  $  5.02  7.89  6.39  Weighted average common shares outstanding  51,447,077  51,364,237  54,259,495  Incremental common shares from stock options  241,953  182,620  347,311  Adjusted weighted average common shares  51,689,030  51,546,857  54,606,806  Cash dividends declared per common share  $  1.00  1.00  .60 \nTIDEWATER INC.  CONSOLIDATED STATEMENTS OF EARNINGS \nSee accompanying Notes to Consolidated Financial Statements. \nF-6"}]}
+{"image": "doclay/doclay_38484.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "(c) The  Group leader  shall act as a single contact point with the  Contracting authority  in the  delivery of the services and/or supplies subject to the contract. It shall co-ordinate the  delivery of the services and/or supplies by the  Group  to the  Contracting authority , and  shall see to a proper administration of the contract. \nAny modification to the present Power of attorney shall be subject to the  Contracting authority ’s  express approval. This Power of attorney shall expire when all the contractual obligations of the  Group have ceased to exist. The parties cannot terminate it before that date without the  Contracting authority’s  consent. \nPlace and date: \nName (in capital letters), function, company and signature: \nPage  28  of  32"}]}
+{"image": "doclay/doclay_71544.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Table of Contents\nThe obligations of the Borrowers under the Amended and Restated Credit Agreement are guaranteed by each existing material domestic subsidiary of the Company, certain other domestic subsidiaries of the Company and certain existing material foreign subsidiaries of the Company that are disregarded entities for U.S. income tax purposes (each such foreign subsidiary, a \"Disregarded Foreign Subsidiary\"), and such obligations are required to be guaranteed by each subsequently acquired or formed material domestic subsidiary and Disregarded Foreign Subsidiary (each, a \"Guarantor\"), and the obligations of the Borrowers other than the Company (\"Foreign Borrowers\") for which the Company is not the primary obligor are also guaranteed by the Company. In addition, (i) the Borrowers’ obligations under the Amended and Restated Credit Agreement are secured by a first priority lien (subject to liens permitted by the Amended and Restated Credit Agreement) on substantially all of the personal property of the Company and the Guarantors as set forth in the Amended and Restated Pledge and Security Agreement and (ii) the obligations of the Foreign Borrowers are secured by a first priority lien on 100% of the capital stock of the Foreign Borrowers.\nThe representations, covenants and events of default in the Credit Facility are customary for financing transactions of this nature, including required compliance with a minimum fixed charge coverage ratio and a maximum leverage ratio (each as defined below).\nUnder the Credit Facility as amended, the fixed charge coverage ratio, defined as the ratio of (i)(A) consolidated earnings before interest expense, income taxes, depreciation, amortization, stock-based compensation expense, and certain other charges and expenses (\"EBITDA\") minus (B) aggregate income taxes to the extent paid in cash minus (C) unfinanced capital expenditures to (ii) the sum of: (A) consolidated interest expense to the extent paid (or required to be paid) in cash, plus (B) the aggregate of all scheduled payments of principal on funded debt (including the principal component of payments made in respect of capital lease obligations) required to have been made (whether or not such payments are actually made), plus (C) the aggregate of all restricted payments (as defined) paid, plus (D) the aggregate of all earnouts paid or required to be paid, must not be less than 1.10 to 1.00 for the four-quarter period ending at the end of each fiscal quarter.\nAlso under the Credit Facility as amended, the senior secured leverage ratio, defined as the ratio of (i) consolidated total funded debt (excluding unsecured or subordinated debt) minus unrestricted cash to (ii) consolidated EBITDA, must not be greater 3.25 to 1.00 at the end of each fiscal quarter. In addition, the maximum permitted total leverage ratio allowable, which includes any unsecured or subordinated debt, must not be greater than 4.25 to 1.00.\nAt December 31, 2018, the Company was in compliance with the financial covenants under the Credit Facility. If the Company does not meet the covenant requirements in the future, it would be in default under the Credit Facility. Upon the occurrence of an event of default, the lenders may terminate the loan commitments, accelerate all loans and exercise any of their rights under the Credit Facility and ancillary loan documents.\nShort-term borrowings under the Credit Facility totaled $23,195,000 and $24,641,000 at December 31, 2018 and 2017, respectively. The Company expects, but is not required, to repay all of such short-term borrowings at December 31, 2018 in 2019.\nThe Company's capital leases are primarily comprised of equipment leases with terms ranging from 24 to 60 months.\nInterest expense, including amortization of capitalized loan costs, on the Company's short-term and long-term borrowings was $11,399,000, $9,909,000, and $9,934,000 for the years ended December 31, 2018, 2017, and 2016, respectively. Interest paid on the Company's short-term and long-term borrowings was $10,381,000, $8,394,000, and $8,451,000 for the years ended December 31, 2018, 2017, and 2016, respectively.\nPrincipal repayments of long-term debt, including current portions and capital leases, as of December 31, 2018 are expected to be as follows, assuming no prepayments or extensions beyond the stated maturity:\n79\nLong-term Debt Capital Lease Obligations Total Year Ending December 31, (In thousands) 2019 $ 23,195 $ 89 $ 23,284 2020 — 3 3 2021 — 2 2 2022 167,121 — 167,121 Total $ 190,316 $ 94 $ 190,410"}]}
+{"image": "doclay/doclay_26412.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "we pass to a quantum field theory.\nLet us now consider canonical quantization of Dirac fields. Quantum theory uses the Hamiltonian to determine the time evolution of a system. In the Heisenberg picture of quan- tum theory, time-dependence is carried by operators governed by the Heisenberg equation of motion,\nIn order to quantize the Dirac fields, we must first know what Hamiltonian operator to use in (1.4). Since the Hamiltonian and Lagrangian are related, we may determine a suitable Lagrangian for the Dirac fields and use this to find the corresponding Hamiltonian. The simplest form of the Lagrangian can be written as\nwhere ¯ Q = Q $^{†}$γ $^{0}$. When this Lagrangian is substituted into the Euler-Lagrange equation (1.3) with Q and ¯ Q treated as dynamical fields, the correct equations of motion for Q and ¯ Q result, so this is a suitable Lagrangian for the quark fields. Using the relationship between the Hamiltonian and the Lagrangian along with (1.5), the Hamiltonian for Dirac fields can be shown to be\nWe may now use the Heisenberg equation of motion (1.4) to quantize Dirac fields. Using the Hamiltonian (1.6) and the identity [ A , BC ] = { A , B } C − B { A , C } ,\n12\n[ Q ( x ) , H ] = i$^{∫}$ d $^{3}$y [ Q ( x ) , ¯ Q ( y ) γ 0 ∂ ∂y $_{0}$Q ( y )$^{]}$ = i$^{∫}$ d $^{3}$y ( { Q ( x ) , ¯ Q ( y ) } γ 0 ∂ ∂y $_{0}$Q ( y ) − ¯ Q ( y ) { Q ( x ) , γ 0 ∂ ∂y $_{0}$Q ( y ) }$^{)}$ = i$^{∫}$ d $^{3}$y ( { Q ( x ) , ¯ Q ( y ) } γ 0 ∂ ∂y $_{0}$Q ( y ) − ¯ Q ( y ) γ 0 ∂ ∂y $_{0}${ Q ( x ) , Q ( y ) }$^{)}$ = i ∂ ∂x $_{0}$Q ( x ) . (1.7)\nH = ∫ d $^{3}$x H = ∫ d $^{3}$x$^{[}$ ∂ L ∂ [ ∂$_{0}$ Q ( x )] ∂$_{0}$Q ( x ) − L$^{]}$ = i$^{∫}$ d $^{3}$x ¯ Q ( x ) γ $^{0}$∂$_{0}$ Q ( x ) . (1.6)\nL = ¯ Q $^{[}$i / ∂ − m $^{]}$Q , (1.5)\ni∂$_{0}$Q ( x ) = [ Q ( x ) , H ] . (1.4)"}]}
+{"image": "doclay/doclay_52133.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Using System Variables\nVariable Name Variable Type Variable Scope show_create_table_verbosity Boolean Both show_old_temporals Boolean Both slave_allow_batching Boolean Global slave_checkpoint_group Integer Global slave_checkpoint_period Integer Global slave_compressed_protocol Boolean Global slave_exec_mode Enumeration Global slave_max_allowed_packet Integer Global slave_net_timeout Integer Global slave_parallel_type Enumeration Global slave_parallel_workers Integer Global slave_pending_jobs_size_max Integer Global slave_preserve_commit_order Boolean Global slave_rows_search_algorithms Set Global slave_sql_verify_checksum Boolean Global slave_transaction_retries Integer Global slave_type_conversions Set Global slow_launch_time Integer Global slow_query_log Boolean Global slow_query_log_file File name Global sort_buffer_size Integer Both sql_auto_is_null Boolean Both sql_big_selects Boolean Both sql_buffer_result Boolean Both sql_log_bin Boolean Session sql_log_off Boolean Both sql_mode Set Both sql_notes Boolean Both sql_quote_show_create Boolean Both sql_require_primary_key Boolean Both sql_safe_updates Boolean Both sql_select_limit Integer Both sql_slave_skip_counter Integer Global sql_warnings Boolean Both ssl_ca File name Global ssl_capath Directory name Global ssl_cert File name Global ssl_cipher String Global\n936"}]}
+{"image": "doclay/doclay_12530.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "TECHNICAL PROVISIONS\nThe provision for life insurance represents the present value of future benefits to be paid to or on behalf of policyholders and related expenses less the present value of future net premiums. The provision is calculated using actuarial methods that include assumptions such as estimates of premiums, mortality, investment performance, lapses, surrenders and expenses. These assumptions are initially based on best estimates of future experience at policy inception date, in some instances taking into account a margin for the risk of adverse deviation. The assumptions used are regularly reviewed, compared to actual experience and, if necessary, depending on the type of products, updated.\nFor products that have guaranteed benefits over the lifetime of the policy or at maturity, the premiums also include loadings for the expected cost of the guarantee. The pricing of the guarantee is based on assumptions for future investment performance, including reinvestment assumptions.\nThe provision for life insurance also comprises the provision for unexpired risks as well as the provision for claims outstanding. In case the premium-paying period is shorter than the lifetime of the policy, a provision for future expenses is set up to cover any estimated future expenses after the premium-paying period. Future costs in connection with benefit payments are also provided for.\nIn various countries products are sold that contain minimum guarantees. For these products the regular technical provision is recognized under technical provisions with investments for account of policyholders. The technical provision life insurance includes provisions for guaranteed minimum benefits related to contracts where the policyholder otherwise bears the investment risk.\nIn the United States, a common feature in variable annuities is a guaranteed minimum death benefit (GMDB). This means that when the insured dies, the beneficiaries receive either the account balance or the guaranteed amount, whichever is higher. The latter is calculated using the total deposits made by the contract holder, less any withdrawals and sometimes includes a roll-up or step-up feature thereby increasing the guarantee with interest or with increases in the account value, respectively.\nThe provision for life insurance includes a provision in connection with the guarantees issued. A cap and a floor for this provision is calculated using stochastic prospective methods (probability weighted calculation using multiple future scenarios) and current assumptions. Within the cap and floor corridor, the accrual method based on pricing assumptions with valuation interest less actual claims incurred is followed. Outside the cap and floor corridor, a surplus or shortfall of the provision will cause an extra charge or credit to the income statement.\nIn Canada, the variable annuity products sold are known as segregated funds. The provisions for the minimum guarantees on segregated funds are established consistent with the method described for the minimum guarantees on the variable annuity contracts sold in the United States.\nIn the Netherlands, Fundplan policies have a guaranteed return of 3% or 4% at maturity or upon the death of the insured if premium paid for a consecutive period of ten years is invested in the Mix Fund and/or the Fixed Income Fund. For this guaranteed return a provision is established based on stochastic modelling. The provision is developed applying the accrual method based on pricing assumptions less actual claims incurred. A corridor for the provision is determined regularly based on stochastic modelling methods. If the provisions develop outside the corridor, a charge or credit to the income statement is recorded. Minimum interest guarantees on group pension contracts in the Netherlands are given for nominal benefits, based on the 3% or 4% actuarial interest, after retirement of the employees. Due to the nature of the product, these guarantees have a long-term horizon of about 30 to 60 years. The provision is developed applying the accrual method based on pricing assumptions less actual deductions.\nProvisions for fixed annuities, guaranteed investment contracts (GICs) and funding agreements (FAs) are equal to the accumulated contract balance.\nUnder US GAAP the technical provisions for traditional life insurance contracts are computed using the net level premium method with investment yields, mortality, lapses and expenses based on historical assumptions, and include a provision for adverse deviation. For universal life contracts and investment type contracts (annuities) the technical provisions are equal to the policyholder account balances at the balance sheet date. The technical provision in the United Kingdom is reduced to equal the contract holder balance. The technical provision for fixed annuities, GICs and FAs is the same as under Dutch accounting principles.\nAlso US GAAP technical provisions include the part of the change in value of the debt securities that must be allocated to policyholders based on the effects of the application of SFAS 115. The SFAS 115 effect on US GAAP equity is EUR (300) million  (2002: EUR (348) million).\nIn addition, to the extent that the contract contains an embedded derivative as defined by US GAAP, the contract is unbundled and the derivative is marked to fair value with changes recognized in the income statement. This adjustment is included in the derivative line in the reconciliation.\nAEGON GROUP ANNUAL REPORT 2003 149"}]}
+{"image": "doclay/doclay_6077.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "basis and reflect periods during which the Energizer businesses operated as wholly owned subsidiaries of Ralston. The financial information in these financial statements does not include certain expenses and adjustments that would have been incurred had Energizer been a separate, independent company, and may not  necessarily be indicative of results that would have occurred had Energizer been a separate, independent company during the periods presented or of future results of Energizer.\nOn June 10, 1999, the Board of Directors of Ralston approved in principle a plan to spin off its battery business to the Ralston stock- holders. In September 1999, Energizer Holdings, Inc. (Energizer) was incorporated in Missouri as an indirect subsidiary of Ralston.\nEffective April 1, 2000, Energizer became an independent, publicly owned company as a result of the distribution by Ralston of Energizer’s $.01 par value common stock to the Ralston stockholders at a distribution ratio of one for three (the spin-off). Prior to the  spin-off, Energizer operated as a wholly owned subsidiary of Ralston. Ralston received a ruling from the Internal Revenue Service stating the distribution qualified as a tax-free spin-off. \nEnergizer’s significant accounting policies, which conform to  generally accepted accounting principles in the United States  and are applied on a consistent basis among all years presented, except as indicated, are described below. \nPrinciples of Consolidation – These financial statements include the accounts of Energizer and its majority-owned sub- sidiaries. All significant intercompany transactions are eliminated. Investments in affiliated companies, 20% through 50% owned, are carried at equity. A one-month lag is utilized in reporting all interna- tional subsidiaries in Energizer’s consolidated financial statements.\nEnergizer is the world’s largest publicly traded manufacturer of  primary batteries and flashlights and a global leader in the dynamic business of providing portable power. Energizer manufactures and markets a complete line of primary alkaline and carbon zinc batteries under the brands  Energizer e 2 , Energizer and  Eveready, as well as miniature and rechargeable batteries, and flashlights and other  lighting products. Energizer and its subsidiaries operate 22 manu- facturing facilities in 15 countries on four continents. Its products are marketed and sold in more than 140 countries primarily  through a direct sales force, and also through distributors, to  mass merchandisers, wholesalers and other customers.\nUse of Estimates – The preparation of financial statements in  conformity with generally accepted accounting principles requires management to make estimates and assumptions that affect the  reported amounts of assets and liabilities, the disclosure of contin- gent assets and liabilities at the date of the financial statements, and the reported amounts of revenues and expenses during the reporting  period. Actual results could differ from those estimates.\nThe Balance Sheet as of September 30, 2000 is presented on a  consolidated basis. The Statement of Earnings and Statement of  Cash Flows for the year ended September 30, 2000 include the combined results of operations of the Energizer businesses under Ralston for the six months prior to the spin-off and the consolidated results of operations of Energizer on a stand-alone basis for the  six months ended September 30, 2000. The financial statements  for all periods prior to the spin-off are presented on a combined\nForeign Currency Translation – Financial statements of foreign operations where the local currency is the functional currency are translated using end-of-period exchange rates for assets and liabili- ties and average exchange rates during the period for results of operations. Related translation adjustments are reported as a  component within accumulated other comprehensive income in  the shareholders equity section of the Consolidated Balance Sheet.\n25\n(2) SUMMARY OF ACCOUNTING POLICIES\n(1) BASIS OF PRESENTATION\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS\n(Dollars in millions except per share data)"}]}
+{"image": "doclay/doclay_7255.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS – (continued) (Dollars in millions except per share data)\nThe following tables present the benefit obligation and funded status of the plans for the period subsequent to the spin-off.\nA summary of nonqualified ENR stock options outstanding is as  follows (shares in millions).\nEnergizer has several defined benefit pension plans covering  substantially all of its employees in the United States and certain employees in other countries. The plans provide retirement benefits based on years of service and earnings.\nCertain other foreign pension arrangements, that include various retirement and termination benefit plans, some of which are required by local law or coordinated with government-sponsored plans, are not significant in the aggregate. \nEnergizer currently provides other postretirement benefits,  consisting of health care and life insurance benefits for certain groups of retired employees. Retiree contributions for health care benefits are adjusted periodically, and it is expected that such adjustments will continue into the future.\nPrior to the spin-off, Energizer employees participated in Ralston’s defined benefit plans. In addition, certain groups of retirees and management employees were eligible for certain postretirement  benefits provided by Ralston. See further discussion of pre-spin pension and postretirement benefits below.\nThe following pension and other postretirement benefit information is presented in accordance with SFAS 132, “Employers’ Disclosures about Pensions and Other Postretirement Benefits.”\nFor pension plans with accumulated benefit obligations in  excess of plan assets, the projected benefit obligation was  $9.4 at September 30, 2000. There are no plan assets for  these nonqualified plans as of September 30, 2000.\nENERGIZER 2000 ANNUAL REPOR T 36\n(9) PENSION PLANS AND OTHER POSTRETIREMENT BENEFITS \nSeptember 30, 2000 Pension Postretirement Change in Benefit Obligation: Benefit obligation at April 1, 2000 $ 345.6 $ 77.6 Service cost 7.8 0.1 Interest cost 11.8 2.8 Plan participants’ contributions 0.2 – Actuarial (gain)/ loss (1.3) 4.2 Benefits paid (10.0) (1.0) Foreign currency exchange  rate changes (7.0) – Amendments 4.5 – Benefit obligation at end of year $ 351.6 $ 83.7 Change in Plan Assets: Fair value of plan assets at  April 1, 2000 $ 558.9 $ 1.7 Actual return on plan assets 16.6 0.2 Company contributions 1.2 1.0 Plan participants’ contributions 0.2 1.0 Benefits paid  (10.0) (2.0) Foreign currency exchange  rate changes (9.2) – Fair value of plan assets at  end of year $ 557.7 $ 1.9 Funded Status: Funded status of the plan $ 206.1 $ (81.8) Unrecognized net loss/(gain) (113.0) (2.3) Unrecognized prior service cost 0.4 (3.6) Unrecognized net transition asset 1.1 Prepaid/(accrued) benefit cost $ 94.6 $ (87.7) Amounts Recognized in the Consolidated Balance Sheet: Prepaid benefit cost $ 102.0 $ – Accrued benefit liability (9.4) (87.7) Intangible asset 0.2 – Accumulated other  comprehensive income 1.8 – Net amount recognized $ 94.6 $ (87.7)\n2000 Weighted-Average  Shares Exercise Price Outstanding on October 1 – $ – Granted 7.37 17.41 Exercised – – Cancelled – – Outstanding on September 30 7.37 17.41 Exercisable on September 30 – $ –"}]}
+{"image": "doclay/doclay_6542.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "80 Proposals to Ratify Stock Purchase Plan\nFranklin Covey 2000 Annual Report\nRestrictions on Issuance and Transfer of  Common Stock Issuable Under the Purchase Plan\nThe Company shall not be required to issue any Common Stock under the Purchase Plan unless and until the Committee reasonably determines that such issuance will be in compliance with the Securities Act of 1933, as amended and other governing securities laws. The Committee may impose and enforce any condition required by applicable securities law in connection with the issuance or transfer of any Common Stock issued or issuable under the Purchase Plan. \nUnder governing securities laws, no shares of Common Stock acquired under the Purchase Plan Plan may be offered or sold while the holder thereof is in possession of material nonpublic information. Violation of such prohibition may result in civil or criminal sanctions.\nThe securities laws of the United States subject officers, directors and certain beneficial owners of 10 percent or more of the Common Stock (collectively, “Insiders”) to the reporting and liability provisions of Section 16 of the Securities Exchange Act of 1934, as amended (the “Exchange Act”). \nSection 16(b) Liability Provisions. Section 16(b) of the Exchange Act generally provides that any profit realized by an Insider from any purchase and sale, or any sale and purchase, of any equity security of the Company within six months is recoverable by the Company. Transactions by Insiders of the Company in Common Stock are subject to such short-swing liability provisions under Section 16(b), unless an exemption is available thereunder. Rule 16b-3 provides that a transaction pursuant to an employee stock purchase plan that satisfies certain requirements of Section 423 of the Code is exempt from the short-swing restrictions of Section 16(b). The Purchase Plan satisfies such requirements of Section 423 of the Code and, accordingly, the issuance of Common Stock Pursuant to Purchase Plan will be exempt (i.e., not counted as a purchase transaction) for purposes of the short-swing liability provisions of Section 16(b). \nEven if a Registration Statement on Form S-8 is in effect with respect to shares of Common Stock issued under the Purchase Plan, shares of Common Stock issued to “affiliates” of the Company (a term which includes Insiders and other persons who are deemed to control the Company) pursuant to the Purchase Plan may not be resold unless the re-sale transaction is registered under the Securities Act or such shares are re-sold pursuant to an applicable exemption, including the exemption provided by Rule 144 under the Securities Act (“Rule 144”). Pursuant to Rule 144, an affiliate of the Company is entitled to sell, within any three-month period, a number of Common Shares that does not exceed the greater of one percent (1%) of the outstanding shares of such class or the average weekly trading volume of such shares during the four calendar\nThe preceding summary of certain provisions of the securities laws of the United States is based upon the existing rules and regulations, which are subject to further change and interpretation, and does not purport to be a complete discussion of such securities laws. Participants who are Insiders of the Company are encouraged to consult with legal counsel with respect to the securities laws, rules and regulations applicable to any contemplated transaction under the Purchase Plan.\nSection 16(a) Reporting Requirements and Section 16(c) Derivative Trading Restrictions. The Rules promulgated under the Exchange Act also impose various reporting requirements pursuant to Section 16(a) for Insiders of the Company with respect to transactions under the Purchase Plan. Violations of such requirements could result in penalties, fines and disclosure of such violations in the Company’s Proxy Statement and Annual Report on Form 10-K. Section 16(c) of the Exchange Act continues to prohibit generally sales of an equity security by an Insider if he does not own the security or, if he owns the security, he does not deliver it within 20 days after sale. \nAlthough receipt by an Insider of Common Stock under the Purchase Plan may be exempt from short-swing liability, as discussed above, the sale of such Common Stock by an Insider of the Company will generally not be exempt. Therefore, unless one of the limited number of exceptions applies, the sale to any party other than the Company of Common Stock acquired under the Purchase Plan may be matchable against any non-exempt purchase transaction occurring within six months before or after such sale. Insiders of the Company are advised to take appropriate measures to assure compliance with the provisions of Section 16.\nConditions To Issuance of Common Stock \nRestrictions on Transfer of Shares Held By Affiliates \nProhibitions on Trading While In Possession of Material Non-Public Information \nLimitations on Transfer By Certain Insiders Subject to Section 16 of the Exchange Act"}]}
+{"image": "doclay/doclay_5865.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "In ophthalmology, we launched multiple innovative products: RESTASIS, which is the world’s first and only therapeutic dry eye product that relieves the symptoms of dry eye disease by restoring natural tear production; ZYMAR, the first fourth-generation fluoroquinolone anti-infective; and ACULAR LS, an optimized formulation of the world’s largest topical non-steroidal anti- inflammatory. In the BOTOX area, we launched VISTABEL, the trade name for BOTOX Cosmetic in Europe. BOTOX also received approval for hyperhidrosis, a chronic condition of excessive sweating, in the European Union. Although famous both in the United States and across the world as the wrinkle treatment, 60 percent of BOTOX sales are related to applications for chronic therapeutic conditions. In using BOTOX, the physician seeks to temporarily relax a muscle or reduce the activity of an overactive gland. Today, BOTOX is approved by regulatory agencies in 73 countries around the world and for use in up to 20 different indications, depending on the country. This points to the enormous versatility of BOTOX. With a large number of clinical studies and scientific papers exploring new BOTOX treatments, other uses continue to be reported. These include new therapeutic areas such as migraine and pain related to neuromuscular disorders. \nSTRONG OPERATING PERFORMANCE AND KEY TRANSACTIONS.  Earnings per share in 2003 increased by 23 percent on a recurring basis, adjusting principally for the write-off of in-process R&D relating to two transactions that occurred  during the year: the exercise of our option to purchase Bardeen Sciences Company, LLC and the acquisition of Oculex Pharmaceuticals, Inc. These two transactions further increased the depth and breadth of Allergan’s R&D pipeline. The Bardeen transaction enabled us to secure the sole rights to such important ophthalmology programs such as memantine, LUMIGAN in a fixed combination with timolol, androgen tears and the tazarotene oral program for acne. The Oculex acquisition accelerated our entry into the next key market in ophthalmology, therapeutics to treat diseases of the retina, by several years. Specifically, we obtained POSURDEX, a steroid implant for the treatment of macular edema, as well as the Oculex bioerodable delivery platform. This proprietary bioerodable device is capable of supplying minute amounts of drug to the back of the eye for a period of as long as six months and will serve as the delivery vehicle for Allergan’s early stage proprietary anti-VEGF, tazarotene, Panzem and other compounds. Market leadership in the retinal disease market will be determined by relative efficacy of the competing drugs, as well as the ability to deliver the drugs safely and effectively to the back of the eye in a low number of treatment cycles per year. The acquisition of the Oculex technology places Allergan at the forefront of this opportunity. \nWe also again fulfilled our goal of providing earnings performance in the top quartile of the best specialty pharmaceutical and biotech companies. As evidence of our financial and operational strength, we generated $326 million of operating cash flow prior to dividend payments and share repurchases. This was after investing $110 million into new fixed assets, principally in a new BOTOX facility in Ireland, which addresses our foreseeable expanding demand for BOTOX for the coming decade, and a state-of-the-art, 170,000 square foot R&D facility at our Irvine campus that will address our laboratory space requirements for roughly the next five years. We managed our working capital even tighter than in prior years with inven- tory days on hand (DOH) declining by 14 days to 78 days and receivables holding constant, even as our sales expanded strongly. Days of Sales outstanding finished the year at a record low of 42 days. At year end we held a cash position of $508 million, granting us flexibility for future strategic transactions.\nReinvestment into the two key drivers of growth in the pharmaceutical industry, R&D and Sales and Marketing, remained at very high levels and at the top of the benchmarks for the best companies in our peer group of specialty pharmaceutical and large biotech companies. Our selling, general and administrative (SG&A) expenditures increased 17 percent over 2002, as adjusted for one-time items, given the investments in launches of multiple new products and were 41.5 percent of pharmaceutical-only sales. Expenditures on R&D, adjusted for the in-process R&D charges referenced above, increased 34 percent to $306 million, or 18.3 percent of pharmaceutical-only sales.\nHIGH MARKET SHARES AND STRONG GROWTH IN EVERY BUSINESS. In 2003, with both the cosmetic and therapeutic franchises growing at approximately the same rate, BOTOX sales increased by 28 percent to $564 million. As a result, the therapeutic share of total sales remained at approximately 60 percent of the total, consistent with the 2002 mix. The unique versatility of BOTOX is the key strategic driver for the long-term growth sustainability of this product. The BOTOX therapeutic franchise is made up of a great diversity of indications ranging from mature ophthalmic movement disorders such as blepharospasm, to cervical dystonia, to emerging use in hyperhidrosis, migraine headaches, pain associated with movement disorders and overactive bladder. With 15 years of history in the United States, approval in 73 countries around the world and over 1 million patients treated with BOTOX in 2002 alone, BOTOX has a virtually unparalleled record in the pharmaceutical industry of use for many serious medical conditions. Allergan continues to invest heavily in BOTOX R&D – over $200 million in the past three years – to investigate and secure regulatory approval for new indications for BOTOX as well as to further improve the product."}]}
+{"image": "doclay/doclay_18638.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "SECTION 7.3  Share-based payment\nNumber Exercise price Executive  directors Key  management  personnel Other management  personnel Resigned  employees Total Fixed,  weighted  average Share options outstanding at 31 December 2011 302,112 105,893 456,439 295,066 1,159,510 347.08 Granted 131,500 - - - 131,500 444.60 Forfeited/expired - - -4,707 - -4,707 270.91 Exercised -13,008 -11,191 -71,545 -77,167 -172,911 260.10 Transferred - -17,946 -30,578 48,524 - 406.72 Share options outstanding at 31 December 2012 420,604 76,756 349,609 266,423 1,113,392 413.37 Granted 91,000 - - - 91,000 573.50 Forfeited/expired - - -2,550 - -2,550 305.22 Exercised -12,388 -19,648 -145,129 -89,063 -266,228 363.20 Transferred - - -7,417 7,417 - 342.73 Share options outstanding at 31 December 2013 499,216 57,108 194,513 184,777 935,614 443.93 Exercisable at 31 December 2012 199,104 68,369 193,902 340,030 801,405 395.94 Exercised options as % of share capital 0.01% 0.01% 0.05% 0.05% 0.12% Exercisable at 31 December 2013 216,716 55,908 185,280 194,010 651,914 414.17 Exercised options as % of share capital 0.01% 0.01% 0.10% 0.06% 0.18%\n2013 2012 Grant date Expiry date Programme Exercise  price Expected  volatility Risk-free interest rate Expected  dividend  yield Expected life  of options,  years Fair value at  measure ment  date Options  outstanding Options  outstanding 01.03.2005 01.03.2013 Grant 2005 232.71 27% 3.1% 1.7% 5.5 74.27 - 40,739 01.03.2006 01.03.2014 Grant 2006 306.89 19% 3.3% 1.3% 5.5 89.37 31,589 89,670 01.03.2007 01.03.2015 Grant 2007 472.11 19% 3.9% 1.0% 5.5 136.67 104,493 151,257 01.03.2008 01.03.2016 Grant 2008 457.82 22% 3.6% 1.1% 5.5 141.72 117,303 159,138 01.06.2008 01.06.2016 Special grant 531.80 23% 4.3% 0.9% 5.5 181.08 142,462 161,044 01.09.2008 01.09.2016 Special grant 448.18 27% 4.3% 1.3% 5.5 128.83 40,000 40,000 01.03.2009 01.03.2017 Grant 2009 203.50 52% 3.0% 1.7% 5.5 88.41 124,328 159,555 01.03.2010 01.03.2018 Grant 2010 417.34 30% 3.1% 0.8% 8.0 174.52 91,739 119,289 01.03.2011 01.03.2019 Grant 2011 566.78 25% 2.9% 0.9% 8.0 180.50 61,200 61,200 01.03.2012 01.03.2020 Grant 2012 444.60 34% 0.9% 1.2% 8.0 146.67 131,500 131,500 01.05.2013 01.05.2021 Grant 2013 573.50 27% 1.5% 1.0% 8.0 167.98 91,000 - Outstanding share options under the share option programme 935,614 1,113,392 ASSUMPTIONS\nASSUMPTIONS\nThe average share price at the exercise date for share options was DKK 583 (2012: DKK 493). At 31 December 2013, the exercise price for outstanding share options was in the range DKK 203.50 to DKK 573.50 (2012: DKK 203.50 to DKK 566.78). The average remaining contractual life was 3.8 years (2012: 3.8 years).\nConsolidated financial statements SECTION 7: STAFF COSTS AND REMUNERATION 121\nCarlsberg Group Annual Report 2013\n7.3.1  Share option programme\n7.3  SIGNIFICANT ACCOUNTING  ESTIMATES AND JUDGEMENTS\nFor share options and PSUs granted  or measured after 1 January 2010, the  volatility is based on presently observed  data on Bloomberg’s Options Valuation  Function, while prior to 2010 it was based  on the historical volatility in the price of  Carlsberg A/S’s class B shares over the  previous two years.\nThe risk-free interest rate is the interest  rate on Danish government bonds of the  relevant maturity, while the dividend yield  is calculated as the expected dividend  at the grant date of DKK 5.50 per share  (2012: DKK 5.50 per share) divided by the  share price. The fair value at 31 December  is calculated applying an expected dividend  of DKK 8.00 per share.\nFor share options granted or measured  after 1 January 2010, the expected life is  based on exercise at the end of the exercise  period, while prior to 2010 it was based on  exercise in the middle of the exercise period."}]}
+{"image": "doclay/doclay_57468.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Authentication Plugins\nIf your system supports PAM and permits LDAP as a PAM authentication method, another way to use LDAP for MySQL user authentication is to use the server- side  authentication_pam  plugin. See Section 6.4.1.5, “PAM Pluggable Authentication” .\nNotePrerequisites for LDAP Pluggable Authentication\n•An LDAP server must be available for the LDAP authentication plugins to communicate with.\n•LDAP users to be authenticated by MySQL must be present in the directory managed by the LDAP server.\n•An LDAP client library must be available on systems where the server-side authentication_ldap_sasl  or  authentication_ldap_simple  plugin is used. Currently, supported libraries are the Windows native LDAP library, or the OpenLDAP library on non-Windows systems.\n•To use SASL-based LDAP authentication:\n•The LDAP server must be configured to communicate with a SASL server.\n•A SASL client library must be available on systems where the client-side authentication_ldap_sasl_client  plugin is used. Currently, the only supported library is the Cyrus SASL library.\n•To use a particular SASL authentication method, any other services required by that method must be available. For example, to use GSSAPI/Kerberos, a GSSAPI library and Kerberos services must be available.\nTo use LDAP pluggable authentication for MySQL, these prerequisites must be satisfied:\nThis section provides a general overview of how MySQL and LDAP work together to authenticate MySQL users. For examples showing how to set up MySQL accounts to use specific LDAP authentication plugins, see Using LDAP Pluggable Authentication. For information about authentication methods available to the LDAP plugins, see LDAP Authentication Methods.\nThe client connects to the MySQL server, providing the MySQL client user name and a password:\nHow LDAP Authentication of MySQL Users Works\n•For simple LDAP authentication, the client-side and server-side plugins communicate the password as cleartext. A secure connection between the MySQL client and server is recommended to prevent password exposure.\n•For SASL-based LDAP authentication, the client-side and server-side plugins avoid sending the cleartext password between the MySQL client and server. For example, the plugins might use SASL messages for secure transmission of credentials within the LDAP protocol. For the GSSAPI authentication method, the client-side and server-side plugins communicate securely using Kerberos without using LDAP messages directly.\nIf the client user name and host name match no MySQL account, the connection is rejected.\nIf there is a matching MySQL account, authentication against LDAP occurs. The LDAP server looks for an entry matching the user and authenticates the entry against the LDAP password:\n1335"}]}
+{"image": "doclay/doclay_6181.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "B OA R D O F ADV I S O RS\nB OA R D O F D I R ECT O R S\nE X EC U T I V E O FF I CE RS\nGeorge Conrade s Cha i rmanandCh i efExe c ut i veOff i c er\nP aul  S agan P re s i dent\nR obert Cobuzzi  Ch i ef  F i nan c i a l  Off i c er\nMi c hael  R uffolo Exe c ut i veV i c e  P re s i dent ,  G l oba l  Sa l e s, Serv i c e s,  andMarket i ng\nChri s S c hoettle Exe c ut i veV i c e  P re s i dent ,  Te c hno l ogy , Network s,  andSupport\nKathryn Meyer V i c e  P re s i dentandGenera l  Coun s e l\nF .  Thom s on  L eighton  Ch i efS c i ent i s t\nGeorge Conrade s Cha i rman\nMartin Coyne  II GroupExe c ut i ve , P hotog r aphyGroup , andExe c ut i veV i c e  P re s i d e nt , Ea s tmanKodakCompany\nR onald Graham I rw i nand  J oan  J a c ob s  En dowedCha i r  ofComputerand  I nform a t i onS c i en c e , Un i ver s i tyofCa li forn i aa t SanD i ego\nWilliam Halter  F ormerA c t i ngComm i ss i o ner  oftheU . S .  So c i a l  Se c ur i t y  Adm i n i s trat i on\nF .  Thom s on  L eighton  Ch i efS c i ent i s t\nF rederi c S alerno F ormerV i c eCha i rmanan dCh i ef  F i nan c i a l Off i c er ,  Ver i zonCommun i c at i on s, I n c .\nNaomi  S eligman  Sen i or  P artner ,  O s tr i kerv o nS i m s on , I n c .\nTim Berner s - L ee  D i re c toroftheWor l dW i deWeb Con s ort i um ,  Ma ss a c hu s ett s I n s t i tute  ofTe c hno l ogy\nJ ame s  Ca s h , J r . J ame s  E . Rob i n s on  P rofe ss orofBu s i ne ss Adm i n i s trat i on ,  HarvardBu s i ne ss  S c hoo l\nDavid  F ilo Ch i efYahoo!  /  Co-founder ,  Yahoo! , I n c .\nTom  F re s ton Cha i rmanandCEO ,  MTVNetwork s\nGil  F rie s en F ormerEnterta i nmentExe c ut i veand I nve s tor\nS am Ga ss el Te c hno l ogy  F e ll ow ,  CNN  I nternet Te c hno l og i e s\nJ an Hier-King  Sen i orV i c e  P re s i dent ,  Spe c i a l P ro j e c t s, Char l e s  S c hwabCorporat i on\nAmo s  Ho s tetter , J r . Cha i rman , P il otHou s eA ss o c i ate s,  LLC\nJ onathan  S eelig Co-founder ,  Akama i Te c hno l og i e s, I n c .\nDan  S mith  P re s i dentandCEO ,  Sy c amoreNetwork s\nR alph Terkowitz  V i c e  P re s i dentofTe c hno l ogy , Wa s h i ngton  P o s t\n"}]}
+{"image": "doclay/doclay_33719.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "21\nprovided a theoretical context for an Omega parameter for LTB models, which has been defined in the literature as an ansatz [15, 16]. Given the widespread use of LTB dust solutions for dealing with a wide variety of prob- lems and models in General Relativity and Cosmology, the new approach to these solutions presented here has a significant potential for applications.\nIn this article we have mostly introduced, discussed and justified the use of a new scalar representation for studying LTB models. However, the formalism that we have presented is potentially useful in future work using these models, hence we are looking at its direct applica- tion in separate articles, on the make, dealing with new results on important theoretical and practical issues, such as: (i) the asymptotic properties and boundary condi- tions of scalars in the radial direction, (ii) the conditions for constructing LTB models with scalars having radial profiles of “clumps” or “voids”, (iii) the conditions for the existence of a positive “back–reaction” in LTB mod- els, which would allow us to mimmic the effect of an accelerated cosmic expansion in the context of Buchert’s scalar averaging [21, 22]. Together with these articles under elaboration, we are also conducting a comprehen- sive numeric study of the models, based on the evolu- tion equations derived here. Finally, as shown by [45], the extension of the formalism of quasi–local scalars can be suitably modified in order to apply it to the quasi– spherical Szekeres spacetimes. The main justification of the present article is then to motivate and induce researchers to consider the introduced variables in the study and application of LTB models, as well as to serve as the theoretical reference for the use of these variables.\nAppendix A: Regularity issues of the new variables.\n2. The Riemann tensor.\nThe same conditions hold at a second symmetry cen- ter r = r$_{c}$ in closed elliptic models (see Appendix A 3). Notice that a central singularity is now associated with L ( ct, r ) = 0.\nRegardless of which parameters or variables we may use, the regularity at each spacetime point or surface in LTB models can be characterized by the continu- ity and finiteness of the Riemann tensor R (e)(f)(g)(h) = R $_{abcd}$e a $_{(e)}$e b $_{(f)}$e c $_{(g)}$e d $_{(h)}$, in an orthonormal tetrad basis e a (e) [3, 24]. Considering the natural tetrad associated with the LTB metric in its form (39)\nSince E (0) = M (0) = M $^{′}$(0) = E $^{′}$(0) = 0, then m$_{qi}$ (0) = m$_{i}$ (0) and k$_{qi}$ (0) = k$_{i}$ (0) must hold, and thus H $_{qi}$(0) = H $_{i}$(0). For any scalar A and its dual function A$_{q}$ we have\nA ( t, 0) = A$_{q}$ ( t, 0) , A $^{′}$( t, 0) = A ′ $_{q}$( t, 0) = 0 , (A2)\ne a (0) = u $^{a}$, e a (1) = √ 1 − k$_{qi}$R 2 i GLYPH<suppress>L Γ R ′ i δ a $_{r}$, e a (2) = 1 L R$_{i}$ δ a $_{θ}$, e a (3) = 1 L R$_{i}$ sin θ δ a $_{φ}$, (A3)\nR (0)(1)(0)(1) = 3 m − 2 m$_{q}$ = m$_{q}$ (1 + 3 δ ( m $^{)}$) , (1)(2)(1)(2) = 3 m m$_{q}$ = m$_{q}$ (2 + 3 δ ( m $^{)}$) , R (0)(2)(0)(2) = m$_{q}$, R (2)(3)(2)(3) = 2 m$_{q}$. (A4)\nthe nonzero Riemann tensor basis components are given readily in terms of the new variables m$_{q}$ and δ ( m ) by\nThese basis components also involve other scalars like H , H $_{q}$, k, k$_{q}$ and δ ( H $^{)}$, δ( k $^{)}$, which are related to m, m$_{q}$ and δ ( m ) by the constraints (37), (38), (33) and the Hamiltonian constraint (20) for the local covariant scalars\nH 2 = 2 m − k + Σ 2 = 2 m − k + ( H $_{q}$δ ( H $^{)}$)$^{2}$. (A5)\nClearly, it is sufficient for the regularity of LTB models based on (A4) that all the involved scalars (not only m and m$_{q}$ ) are bounded and continuous, but it is not a nec- essary condition, since H and H q could diverge because k and k$_{q}$ diverge, with m and m$_{q}$ remaining bounded. Also, we note that the relative fluctuations δ ( A ) might diverge in some cases when A and A$_{q}$ are bounded.\nWe have only considered in this article LTB models having (at least) one symmetry center, which is a regular timelike worldline corresponding to a fixed point of the rotation group SO(3). This is a sufficient condition for integrals in (24) to be finite in a domain ϑ ( r ) defined by (23). The symmetry center can be marked as r = 0 (and r = r$_{c}$ if there is a second one). The following conditions hold: R ( t, 0) = ˙ R ( t, 0) = 0. Considering (36) and (40) and R ′ → 1 as r → 0, we can mark the symmetry center by a zero of R$_{i}$ ( r ) (distinct from the locus of a curvature singularity: L = 0) [25]. Hence\n3. Topology of the space slices.\n1. Symmetry centers.\nGiven the existence of (at least) one symmetry center, the admissible topologies (homeomorphic classes) of the $^{3}$T [ t ] are\nL ( ct, 0) > 0 , Γ( ct, 0) = 1 . (A1)\nThe regularity of LTB models in the conventional variables has been extensively discussed in the litera- ture [2, 3, 24, 25, 39]. We examine this issue in terms of the quasi–local variables and their fluctuations."}]}
+{"image": "doclay/doclay_6220.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "TUNE IT IN\nWhether you’re a little bit country or a whole lotta rock’n roll, Canadians are tuned in to Corus Entertainment stations Visnja (Edge 102) with Kelly Lemieux (Goldfinger)\nnationwide for over 85 million hours every week. Corus reaches 65% of Canada’s rock listeners through 10 powerful Brian Byrne (I Mother Earth)\nHoward Stern (Q107) Rutherford (CHQR) Ceara K (630 CHED) Brother Jake (CKNW) Over a half-million Canadians tune in to Corus stations Humble Howard (Edge 102) Fred Patterson (Edge 102) Willy Percy (LG73) Rhubarb Jones (630 CHED) like Country 105 in Calgary or Country 96 in Kingston\nlisteners in cyberspace as one of the Top 10 online radio stations in the world. Does this country like country? Great Big Sea\nrock stations, such as Vancouver’s Rock 101, Winnipeg’s Anthony Kiedis (Red Hot Chili Peppers) Power 97 and Toronto’s Edge 102. The Edge also reaches\nevery week. And when your kids tune you out? They’re likely among the 37% of hits listeners plugged in to our The Bare Naked Ladies\nEnergy or Power stations across the country. Corus is Canada’s largest sports radio broadcaster – 2 million Canadians Martina McBride\ntune in to stations like Winnipeg’s CJOB and Calgary’s CHQR for the best in sports, talk radio and news. Leave it on!"}]}
+{"image": "doclay/doclay_68213.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "2. Select a host or a host cluster to which the new volume should be attached, as shown in  Figure 6-38.\nNote:  At this point, you can let the system assign a SCSI ID or choose it to assign it  manually by selecting the  Self Assign  option. In this example, we chose to let system  assign a SCSI ID.\nChapter 6. Volume configuration  343Figure 6-38 Select a host or a host cluster"}]}
+{"image": "doclay/doclay_54623.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "OpenShift Routes\nRed Hat OpenShift is a popular enterprise distribution of Kubernetes. Besides being fully compliant with Kubernetes, OpenShift provides some additional features. One of these features are Routes, which are very similar to Ingress. They are so similar, in fact, the differences might be difficult to spot. First of all, Routes predates the intro‐ duction of the Ingress object in Kubernetes, so Routes can be considered a kind of predecessor of Ingress.\nHowever, some technical differences still exist between Routes and Ingress objects:\nHaving said all that, you can use Ingress on OpenShift, too. So you have the choice when using OpenShift.\nIn this chapter, we covered the favorite  Service Discovery  mechanisms on Kubernetes. Discovery of dynamic Pods from within the cluster is always achieved through the Service resource, though different options can lead to different implementations. The Service abstraction is a high-level cloud-native way of configuring low-level details such as virtual IP addresses, iptables, DNS records, or environment variables.  Service Discovery  from outside the cluster builds on top of the Service abstraction and focu‐ ses on exposing the Services to the outside world. While a  NodePort  provides the basics of exposing Services, a highly available setup requires integration with the plat‐ form infrastructure provider.\nTable 12-1 summarizes the various ways  Service Discovery  is implemented in Kuber‐ netes. This table aims to organize the various   mechanisms in this chapter from more straightforward to more complex. We hope it can help you build a mental model and understand them better.\nDiscussion\n• A Route is picked up automatically by the OpenShift-integrated HAProxy load balancer, so there is no requirement for an extra Ingress controller to be installed. However, you can replace the build in OpenShift load balancer, too.\n• You can use additional TLS termination modes like re-encryption or pass- through for the leg to the Service.\n• Multiple weighted backends for splitting traffic can be used.\n• Wildcard domains are supported.\nDiscussion  |  113"}]}
+{"image": "doclay/doclay_22118.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "CI Financial Corp. is a diversified wealth management firm and Canada’s third-largest investment fund company. Independent  and Canadian-owned, CI provides a comprehensive selection of top-quality investment products and services. CI has two  million clients and manages or administers approximately $105 billion in assets (as at March 31, 2013). CI operates primarily  through subsidiaries CI Investments Inc. and Assante Wealth Management (Canada) Ltd.\nCI Investments offers the industry’s broadest selection of investment funds under the CI, Black Creek, Cambridge, Harbour,  Red Sky, Signature, Synergy, Portfolio Series, Portfolio Select Series and Sun Wise  Essential Series 2 banners.\nAssante Wealth Management provides financial advisory services through a national network of 750 professional fi nancial  advisors. Stonegate Private Counsel, a division of CI Private Counsel LP, provides wealth planning services to high net worth  individuals and families.\nCI’s other businesses include Perimeter Markets Inc., which operates alternative marketplaces for trading Canadian fi xed- income products under the CBID brand. CI also owns interests in Altrinsic Global Advisors, LLC, a global investment manager  based in Greenwich, Connecticut, and in Toronto-based alternative asset managers Red Sky Capital Management Ltd. and  Lawrence Park Capital Partners Ltd.\n1"}]}
+{"image": "doclay/doclay_26675.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "4.4 “End of Inflation” Mechanism\n91\nFig. 4.7: The allowed parameter space for h , with α = 1 , Γ$_{ϕ}$ ≪ H$_{T I}$ and the parameter values of Table 4.2. The Black line is h = 10 − $^{9}$, the Red line is the lower bound given by Eq. (4.93) and the Brown line is the upper bound given by Eq. (4.112). The constraints on m$_{0}$ that are shown are the following: Green: Eq. (4.166) Blue: Eq. (4.94) Purple: Eq. (4.114)\n10 2 10 3 10 $_{4}$m 0 ( GeV ) 10 - 11 10 - 10 10 - ✾ 10 - GLYPH<a0> h\nTable 4.3: Values of quantities in the model for α =1 , Γ$_{ϕ}$ ≪ H$_{TI}$ , m$_{0}$ ∼ 10 3 GeV and the parameter values of Table 4.2.\nm$_{0}$ ∼ 10 3 GeV is ruled-out. However, as we are working within an order of magnitude for each value, we can see that our predicted value, i.e. the Black\nQuantity Order of Magnitude Value $^{ψ}$∗ 10 12 GeV δψ$_{∗}$ ψ$_{∗}$ 10 − 4 H$_{T I}$ 10 − 2 GeV 〈 φ 〉 10 13 GeV V 1 4 0 10 8 GeV T$_{1}$ 10 7 GeV T$_{2}$ 10 3 GeV Γ 10 2 GeV r 10 − 13"}]}
+{"image": "doclay/doclay_71969.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Table of Contents\nNotes to Consolidated Financial Statements — (Continued) Becton, Dickinson and Company\nLong-term debt\nThe carrying value of  Long-Term Debt , net of unamortized debt issuance costs, at September 30 consisted of:\n(Millions of dollars) 2020 2019 3.250% Notes due November 12, 2020 (a) —  699  Floating Rate Notes due December 29, 2020 (a) —  748  0.174% Notes due June 4, 2021 —  651  3.125% Notes due November 8, 2021 1,008  1,004  2.894% Notes due June 6, 2022 1,797  1,795  Floating Rate Notes due June 6, 2022 499  498  1.000% Notes due December 15, 2022 584  542  Revolving Credit Facility due December 29, 2022 —  480  3.300% Notes due March 1, 2023 295  295  1.401% Notes due May 24, 2023 350  325  0.632% Notes due June 4, 2023 933  867  3.875% Notes due May 15, 2024 180  181  3.363% Notes due June 6, 2024 1,742  1,740  3.734% Notes due December 15, 2024 1,370  1,369  3.020% Notes due May 24, 2025 320  306  1.208% Notes due June 4, 2026 699  649  6.700% Notes due December 1, 2026 172  174  1.900% Notes due December 15, 2026 582  541  3.700% Notes due June 6, 2027 1,715  1,714  7.000% Debentures due August 1, 2027 175  175  6.700% Debentures due August 1, 2028 174  175  2.823% Notes due May 20, 2030 (b) 743  —  6.000% Notes due May 15, 2039 246  246  5.000% Notes due November 12, 2040 124  124  4.875% Notes due May 15, 2044 247  248  4.685% Notes due December 15, 2044 1,044  1,045  4.669% Notes due June 6, 2047 1,485  1,485  3.794% Notes due May 20, 2050 (b) 742  —  Other long-term debt —  5  Total Long-Term Debt $ 17,224  $ 18,081 \n(a) All of the aggregate principal amount outstanding was redeemed during 2020, as further discussed below.\n(b) Represents notes issued during 2020, as further discussed below.\nThe aggregate annual maturities of debt including interest during the fiscal years ending September 30, 2021 to 2025 are as follows: 2021 — $1.2 billion; 2022 — $3.8 billion; 2023 — $2.6 billion; 2024 — $2.3 billion; 2025 — $2.0 billion.\nThe Company has a five-year senior unsecured revolving credit facility in place which will expire in December 2022. The facility agreement includes a provision that enabled BD, subject to additional\nOther current credit facilities\n92"}]}
+{"image": "doclay/doclay_50779.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "SQL Statements for Controlling Replica Servers\nstatement applies to the default channel. If a  STOP REPLICA | SLAVE  statement does not name a channel when using multiple channels, this statement stops the specified threads for all channels. This statement cannot be used with the  group_replication_recovery  channel. See Section 17.2.2, “Replication Channels”  for more information.\nWhen the replica is multithreaded ( slave_parallel_workers  is a nonzero value), any gaps in the sequence of transactions executed from the relay log are closed as part of stopping the worker threads. If the replica is stopped unexpectedly (for example due to an error in a worker thread, or another thread issuing  KILL ) while a  STOP REPLICA | SLAVE  statement is executing, the sequence of executed transactions from the relay log may become inconsistent. See Section 17.5.1.34, “Replication and Transaction Inconsistencies” , for more information.\nWhen the source is using the row-based binary logging format, you should execute  STOP REPLICA | SLAVE  or  STOP REPLICA | SLAVE SQL_THREAD  on the replica prior to shutting down the replica server if you are replicating any tables that use a nontransactional storage engine. If the current replication event group has modified one or more nontransactional tables,  STOP REPLICA | SLAVE  waits for up to 60 seconds for the event group to complete, unless you issue a  KILL QUERY  or  KILL CONNECTION statement for the replication SQL thread. If the event group remains incomplete after the timeout, an error message is logged.\nWhen the source is using the statement-based binary logging format, changing the source while it has open temporary tables is potentially unsafe. This is one of the reasons why statement-based replication of temporary tables is not recommended. You can find out whether there are any temporary tables on the replica by checking the value of  Slave_open_temp_tables ; when using statement-based replication, this value should be 0 before executing  CHANGE REPLICATION SOURCE TO  |  CHANGE MASTER TO . If there are any temporary tables open on the replica, issuing a  CHANGE REPLICATION SOURCE TO  |  CHANGE MASTER TO  statement after issuing a  STOP REPLICA | SLAVE  causes an ER_WARN_OPEN_TEMP_TABLES_MUST_BE_ZERO  warning.\nStops the replication threads. From MySQL 8.0.22,  STOP SLAVE  is deprecated and the alias  STOP REPLICA  should be used instead. The statement works in the same way as before, only the terminology used for the statement and its output has changed. Both versions of the statement update the same status variables when used. Please see the documentation for  STOP REPLICA  for a description of the statement.\nThe following functions, which are available from MySQL 8.0.22 for standard source to replica replication and from MySQL 8.0.23 for Group Replication, enable you to add and remove replication source servers from the source list for a replication channel. The asynchronous connection failover mechanism automatically establishes an asynchronous (source to replica) replication connection to a new source from the appropriate list after the existing connection from the replica to its source fails. From MySQL 8.0.23, the connection is also changed if the currently connected source does not have the highest weighted priority in the group. For Group Replication source servers that are defined as part of a managed group, the connection is also failed over to another group member if the currently connected source leaves the group\n2781\n13.4.2.11 Functions which Configure the Source List\n13.4.2.10 STOP SLAVE | REPLICA Statement\nSTOP {SLAVE | REPLICA} [ thread_types ] [ channel_option ] thread_types : [ thread_type  [,  thread_type ] ... ] thread_type : IO_THREAD | SQL_THREAD channel_option : FOR CHANNEL  channel"}]}
+{"image": "doclay/doclay_77050.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Contract number: [ complete ]-0763 \nContract conditions of December 2018 \n(b) require the contractor to take further action within a specified deadline;\n(a) its  personnel ;\n(b) any natural person with the power to represent it or take decisions on its behalf;\n(c) third parties involved in the  performance of the contract , including subcontractors.\nII.8.1  The contracting authority and the contractor must treat with confidentiality any  information or documents, in any format, disclosed in writing or orally relating to the  performance of the contract  and identified in writing as confidential.\nII.8.2  Each party must:\n(a) not use  confidential information or documents  for any purpose other than to perform  its obligations under the contract without the prior written agreement of the other  party;\n(b) ensure the protection of such  confidential information or documents with the same  level of protection as its own confidential information or documents, and in any case  with due diligence;\n(c) not disclose directly or indirectly  confidential information or documents to third  parties without the prior written agreement of the other party. \nII.8.3  The confidentiality obligation set out in this Article are binding on the contracting  authority and the contractor during the performance of the contract and for as long as  the information or documents remain confidential unless:\n(a) the disclosing party agrees to release the receiving party from the confidentiality  obligation earlier;\n(b) the  confidential information or documents  become public through other means than in  breach of the confidentiality obligation\n(c) the applicable law requires the disclosure of the  confidential information or  documents .\nII.8.4 The contractor must obtain from any natural person with the power to represent it or  take decisions on its behalf, as well as from third parties involved in the performance  of the contract, a commitment that they will comply with this Article .At the request of  the contracting authority, the contractor must provide a document providing evidence  of this commitment.\nII.7.3  The contractor must pass on all the relevant obligations in writing to: \nThe contractor must also ensure that the persons referred to above are not placed in a  situation which could give rise to conflicts of interest.\nAny personal data included in or relating to the contract, including its implementation, shall  be processed in accordance with Regulation (EU) 2018/1725. Such data shall be processed \nII.9.1 Processing of personal data by the contracting authority\nII.9. PROCESSING OF PERSONAL DATA \nII.8. CONFIDENTIALITY \n22 "}]}
+{"image": "doclay/doclay_76887.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Moreover, they could also contribute to surface instability and present a fire  risk with the potential for excessive black smoke. 39Figure 10: Tyres at the Gamodubu Landfill \nRecommendation:\nThe OAG recommends that the EHD should; \n Expedite the reclamation project to enable management of the  accumulation of tyres within the landfill, in order to reduce instances of  surface instability that may represent fire risks.\n$^{39}$ Guidelines for the Disposal of Waste by the Landfill, 1997 \n44 | P a g e"}]}
+{"image": "doclay/doclay_9137.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "MANAGEMENT’S DISCUSSION AND ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS\nThe following flow chart diagrams Ford Credit’s typical U.S. retail securitization transaction:\nConsistent with conventional practices in the securitization industry, Ford Credit uses SPEs in securitization transactions to  achieve isolation of the sold receivables for the benefit of securitization investors. Some of the SPEs used in Ford Credit’s  securitization transactions are classified as qualifying special purpose entities consistent with the requirements of SFAS No.  140,  Accounting for Transfers and Servicing of Financial Assets and Extinguishments of Liabilities , because of the nature of the  assets held by these entities and the limited nature of their activities. When these accounting rules are met, the sold receivables  are removed from its balance sheet. The use of SPEs in the typical securitization structure, along with the use of various forms of  credit and payment enhancements to reduce the risk of loss, allows the SPE to issue senior asset-backed securities that generally  receive the highest short-term credit ratings and among the highest long-term credit ratings, thereby providing Ford Credit with  a cost-effective source of funding. \nFord Credit selects receivables at random for securitization transactions using selection criteria designed for the specific  transaction. The selection criteria are generally based on factors such as location of the obligor, contract term, payment  schedule, interest rate, financing program, and the type of financed vehicle. In general, the criteria also require receivables to  be active and in good standing.\nFord Credit retains interests in the securitized receivables. The retained interests may include senior and subordinated securities  issued by the SPE, undivided interests in wholesale receivables, restricted cash held for the benefit of the SPEs (for example, a  reserve fund) and residual interests in securitization transactions. Income from residual interest in securitization transactions  represents the right to receive collections on the sold finance receivables in excess of amounts needed by the SPE to pay interest  and principal to investors, servicing fees and other required payments. Ford Credit retains credit risk in securitizations. Ford  Credit’s retained interests include the most subordinated interests in the SPE, which are the first to absorb credit losses on the  sold receivables. The impact of credit losses in the pool of sold receivables will likely be limited to Ford Credit’s retained interests  because securitizations are structured to protect the holders of the senior asset-backed securities. \nAt December 31, 2004 and 2003, the total outstanding principal amount of receivables sold by Ford Credit in securitizations  was $35.6 billion and $46.9 billion, respectively. This decrease primarily reflected lower funding requirements. At December  31, 2004 and 2003, Ford Credit’s retained interests in such sold receivables were $9.2 billion and $12.6 billion, respectively. \nFord Credit generally has no obligation to repurchase or replace any receivable sold to an SPE that subsequently becomes  delinquent in payment or otherwise is in default. Investors holding securities issued by a SPE have no recourse to Ford Credit or  its other assets for credit losses on the sold receivables and have no right to require it to repurchase the securities. Ford Credit  does not guarantee any asset-backed securities and has no obligation to provide liquidity or make monetary contributions or  contributions of additional receivables to its SPEs either due to the performance of the sold receivables or the credit rating of its  short-term or long-term debt. However, as the seller and servicer of the finance receivables to the SPE, Ford Credit is obligated  to provide certain kinds of support to its securitizations, which are customary in the securitization industry. These obligations  consist of indemnifications, receivable repurchase obligations on receivables that do not meet eligibility criteria or that have  been materially modified, the mandatory sale of additional receivables in revolving transactions, and servicer advances.\nRisks to Future Sales of Receivables. Some of Ford Credit’s securitization programs contain structural features that could prevent  further funding from these sources if:\n• the credit losses or delinquencies in a pool of sold receivables exceed specified levels; \n• the delinquencies on a pool of sold receivables or our overall portfolio of receivables exceeds specified levels; \n• the payment rates on wholesale receivables are lower than specified levels; or\n• the amount of wholesale receivables are lower than specified levels. \n4 8\n"}]}
+{"image": "doclay/doclay_34936.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "13\nVII. SUMMARY AND CONCLUDING REMARKS\n10 -15 10 -10 10 -5 200 150 100 50 0 GaAs Ge InAs N I [A]\nFIG. 8. Persistent current versus the ring length N in the ring made of the real crystalline band insulator (GaAs, Ge, InAs). The persis- tent current is estimated by means of the 1D formula (47), where Γ$_{N}$ is the hopping amplitude of the electron in the light-hole band, cal- culated in the preceding figure. The lattice constants of theGaAs, Ge, and InAs crystals are ∼ 0 . 6 nm, i.e., the maximum ring lengths considered in the figure are L = Na ∼ 120 nm. The rings of such length could be realizable by means of advanced nanotechnology.\nWe have analyzed theoretically persistent currents in rings made of band insulators. We started by formulating a recipe which determines the Bloch states of a one-dimensional (1D) ring from the Bloch states of an infinite 1D crystal created by the periodic repetition of the ring. Using the recipe, we have derived an expression for the persistent current in a 1D ring made of an insulator with an arbitrary valence band ϵ ( k ) .\nTo find an exact result for a specific insulator, we have con- sidered a 1D ring represented by a periodic lattice of N identi- cal sites with a single value of the on-site energy. If the Bloch states in the ring are expanded over a complete set of N on- site Wannier functions, the discrete on-site energy splits into the energy band. At full filling, the band emulates the valenc e band of the band insulator and the ring is insulating.\nWe have found that the ring carries a persistent current equal to the product of N and the derivative of the on-site energy with respect to the magnetic flux. This current is not zero because the on-site Wannier function and consequently the on-site energy of each ring site depend on magnetic flux.\nFurther, we have expanded all N Wannier functions of the ring over the basis of Wannier functions of the constituting infinite 1D crystal. In terms of the crystal Wannier function s, the current at full filling arises because the electron in thering with N lattice sites is allowed to make a single hop from site i to its periodic replicas i ± N . Alternatively, in terms of the ring Wannier functions the same current is due to the flux dependence of the Wannier functions basis, and the longest allowed hop is from i to i ± Int( N/ 2) only. We have eventually derived the crystal Wannier functions in\n± We have eventually derived the crystal Wannier functions in the LCAO approximation, and have expressed the persistent current at full filling by means of an exact formula. The valid - ity of the formula was verified by comparison with the numer- ical LCAO approach. We have presented quantitative results for a 1D ring made of an artificial band insulator, namely for a GaAs ring subjected to a periodic potential emulating the insulating lattice.\nthe increasing ring length exponentially, but a careful choice of the insulating material allows to achieve the persistent cur- rent of measurable value for a technologically realizable ring size. Indeed, the maximum ring lengths considered in the fig- ure 8 are close to the value ∼ 120 nm, in principle achiev- able by modern nanotechnology. Concerning the amplitude of the persistent current, the value ∼ 0 . 0003 nA estimated for the InAs ring of length ∼ 120 nm is very small, but in prin- ciple detectable say by the experimental technique of Refs. [9, 25, 26]. The considered insulators are ordered as GaAs, Ge and InAs for the persistent currents ordered increasingly. This suggests a simple rule: the smaller the light-hole effec- tive mass the larger the persistent current.\nMoreover, we have provided estimates for the rings made of real band insulators (GaAs, Ge, InAs) with a fully filled valence band and empty conduction band. The current at full filling decays with the ring length exponentially due to the exponential decay of the Wannier function tails. In spite of that, it can be of measurable size.\nWe conclude with a few remarks showing that the above 1D estimates hold roughly also for the 3D rings. Similar calcu- lations as in the figure 7 were performed for the k values on the line ( X [ − 2 π/a, 0 , 0] , Γ[0 , 0 , 0] , X [2 π/a, 0 , 0] ). We have found the energies ϵ ( k ) and amplitudes Γ$_{N}$ (not shown) very similar to those in the figure 7, with the resulting persisten t currents being of the same order of magnitude as those in the figure 8. Moreover, we have observed similar results when testing the k values on the lines ( K, Γ , K ) and ( W, Γ , W ). The model of the elastically bent crystal thus provides roughly the same persistent current independently on the fact which crys- talline axis is chosen to be directed along the ring circum- ference. This suggests that anisotropy of the valence band with respect to the ⃗ k direction does affect the resulting persis- tent current dramatically. Therefore, the estimated values of the current should hold reasonably also for the realistic ring- shaped crystals similar to the ring sketched in figure 5.\nWe have ignored the effect of nonzero temperature. We expect the persistent currents in rings made of the band in- sulators to be temperature-independent as long the thermal energy k$_{B}$T is much smaller than the energy gap separating the valence band from the conduction band. For example, the energy gap in the InAs crystal is ∼ 400 meV. Hence, the zero- temperature values of the persistent current, predicted for the insulating InAs ring, could persist even at room temperature.\nWe have also ignored the electron-electron interaction. The many-body studies [30, 31] suggest that in the 1D ring consid- ered in this paper the repulsive electron-electron interaction"}]}
+{"image": "doclay/doclay_30168.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Fig. reaction χ 2 D χ 2 NR Comment 7 pp → nΔ ++ 4.7 2.1 8(a) pp → nΔ ++ 3.6 0.9 8(b) pp → nΔ ++ 6.8 1.3 9(a) d(p,n)X 44.8 2.3 for M$_{X}$ ≥ 1 GeV 9(b) d(p,n)X 58.7 1.6 for M$_{X}$ ≥ 1 GeV 9(c) d(p,n)X 20.6 0.8 for M$_{X}$ ≥ 1 GeV 13 $^{3}$He(p,t)Δ++ 2.5 1.5 17(a) d ( $^{3}$He,t)X 12.1 3.0 17(b) d ( $^{3}$He,t)X 17.2 1.1 18(a) d ( $^{3}$He,t)X 14.7 2.2 18(b) d ( $^{3}$He,t)X 53.0 4.0\nTABLE II: Selection of several statistical significances between data and broad PDG Δ resonance ( χ 2 $_{D}$) on the one hand, and between data and total spectra including the narrow resonances ( χ 2 $_{NR}$) on the other hand.\nFig. 14 shows the cross-sections of the p( $^{3}$He,t)Δ++ reaction [25] measured at Saturne (SPES4 beam line) at T 3 $_{He}$=1.5 GeV, θ = 3 . 5 ◦ in insert (a), T 3 $_{He}$=2 GeV, θ = 5 ◦ in insert (b), and T 3 $_{He}$=2 GeV, θ = 0 ◦ in insert (c).\nThe data are well fitted using the masses of narrow baryonic structures. Special attention has to be brought to the low mass spectra. Below M$_{X}$=1100 MeV, the data in Fig. 14 (empty squares) are rescaled by a factor of five. We observe here negative and positive numberq resulting from the subtraction of quite poor statistics data obtained with a CH 2 and a C targets.\nFIG. 13: (Color online.) Cross-section of the $^{3}$He(p,t)Δ++ reaction, at T$_{p}$=850 MeV, θ$_{lab.}$ =6 ◦ [24] after a ΔM=-9 MeV shift (see text).\n11"}]}
+{"image": "doclay/doclay_52920.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "CHAPTER 22 Controller\nA  Controller  actively monitors and maintains a set of Kubernetes resources in a desired state. The heart of Kubernetes itself consists of a fleet of controllers that regu‐ larly watch and reconcile the current state of applications with the declared target state. In this chapter, we see how to leverage this core concept for extending the plat‐ form for our needs.\nYou already have seen that Kubernetes is a sophisticated and comprehensive platform that provides many features out of the box. However, it is a general-purpose orches‐ tration platform that does not cover all application use cases. Luckily, it provides nat‐ ural extension points where specific use cases can be implemented elegantly on top of proven Kubernetes building blocks.\nThe main question that arises here is about how to extend Kubernetes without chang‐ ing and breaking it, and how to use its capabilities for custom use cases.\nBy design, Kubernetes is based on a declarative resource-centric API. What exactly do we mean by  declarative ? As opposed to an  imperative  approach, a declarative approach does not tell Kubernetes how it should act, but instead describes how the target state should look. For example, when we scale up a Deployment, we do not actively create new Pods by telling Kubernetes to “create a new Pod.” Instead, we change the Deployment resource’s  replicas  property via the Kubernetes API to the desired number.\nSo, how are the new Pods created? This is done internally by the  Controllers . For every change in the resource status (like changing the  replicas  property value of a Deployment), Kubernetes creates an event and broadcasts it to all interested listeners. These listeners then can react by modifying, deleting, or creating new resources,\n175\nProblem"}]}
+{"image": "doclay/doclay_52024.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Character Set and Collation of Function Results\nFor simple functions that take string input and return a string result as output, the output’s character set and collation are the same as those of the principal input value. For example,  UPPER( X )  returns a string with the same character string and collation as  X . The same applies for  INSTR() ,  LCASE() ,  LOWER() , LTRIM() ,  MID() ,  REPEAT() ,  REPLACE() ,  REVERSE() ,  RIGHT() ,  RPAD() ,  RTRIM() ,  SOUNDEX() , SUBSTRING() ,  TRIM() ,  UCASE() , and  UPPER() .\nThe  REPLACE()  function, unlike all other functions, always ignores the collation of the string input and performs a case-sensitive comparison.\nNoteIf a string input or function result is a binary string, the string has the  binary  character set and collation. This can be checked by using the  CHARSET()  and  COLLATION()  functions, both of which return  binary for a binary string argument:\nmysql>  SELECT CHARSET(BINARY ’a’), COLLATION(BINARY ’a’); +---------------------+-----------------------+ | CHARSET(BINARY ’a’) | COLLATION(BINARY ’a’) | +---------------------+-----------------------+ | binary | binary | +---------------------+-----------------------+\nFor operations that combine multiple string inputs and return a single string output, the “aggregation rules” of standard SQL apply for determining the collation of the result:\n•If an explicit  COLLATE  Y  occurs, use  Y .\n•If explicit  COLLATE  Y  and  COLLATE  Z  occur, raise an error.\n•Otherwise, if all collations are  Y , use  Y .\n•Otherwise, the result has no collation.\nFor example, with  CASE ... WHEN a THEN b WHEN b THEN c COLLATE  X  END , the resulting collation is  X . The same applies for  UNION ,  || ,  CONCAT() ,  ELT() ,  GREATEST() ,  IF() , and  LEAST() .\nFor operations that convert to character data, the character set and collation of the strings that result from the operations are defined by the  character_set_connection  and  collation_connection  system variables that determine the default connection character set and collation (see Section 10.4, “Connection Character Sets and Collations” ). This applies only to  BIN_TO_UUID() ,  CAST() ,  CONV() ,  FORMAT() , HEX() , and  SPACE() .\nAn exception to the preceding principle occurs for expressions for virtual generated columns. In such expressions, the table character set is used for  BIN_TO_UUID() ,  CONV() , or  HEX()  results, regardless of connection character set.\nIf there is any question about the character set or collation of the result returned by a string function, use the  CHARSET()  or  COLLATION()  function to find out:\nmysql>  SELECT USER(), CHARSET(USER()), COLLATION(USER()); +----------------+-----------------+-------------------+ | USER() | CHARSET(USER()) | COLLATION(USER()) | +----------------+-----------------+-------------------+ | test@localhost | utf8 | utf8_general_ci | +----------------+-----------------+-------------------+ mysql>  SELECT CHARSET(COMPRESS(’abc’)), COLLATION(COMPRESS(’abc’)); +--------------------------+----------------------------+ | CHARSET(COMPRESS(’abc’)) | COLLATION(COMPRESS(’abc’)) | +--------------------------+----------------------------+ | binary | binary | +--------------------------+----------------------------+\n2201"}]}
+{"image": "doclay/doclay_23445.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Daiwa Securities Group Annual Report 2012\nCorporate Summary\nExecutive Messages\nBusiness Strategy\nManagement Systems & CSR\nFinancial Section\nOther Information\n80\n2. Derivatives to which hedge accounting is applied\nMain hedged items, contract amount and fair value of these derivatives at March 31, 2012 and 2011 are as follows:\nMillions of yen Hedging instrument Hedge accounting treatment Main hedged item Contract amount Fair value Foreign exchange forward contract Allocation method Foreign bond ¥ 54 ¥ 54 Fundamental method Forecasted transaction in foreign currency 735 (11) Interest swap Fundamental method Long-term debt and government bond 623,500 (3,626) Special treatment Long-term debt and government bond 181,550 (335)\nMarch 31, 2012\nMillions of yen\nContract amount, fair value and net unrealized gains (losses) of these derivatives at March 31, 2012 and 2011 are as follows:\n8. Derivatives used for non-trading purposes\n1. Derivatives to which hedge accounting is not applied\nCost and fair value of marketable available-for-sale securities as of March 31, 2012 and 2011 consisted of the following:\nMillions of yen Cost Fair value Difference March 31, 2012: Equities ¥ 88,566 ¥ 118,213 ¥29,647 Government, corporate and other bonds 874,696 880,228 5,532 Other 111,660 115,068 3,408 ¥1,074,922 ¥1,113,509 ¥38,587\nMillions of yen\nMillions of yen\nCost Fair value Difference March 31, 2011: Equities ¥ 99,795 ¥141,499 ¥41,704 Government, corporate and other bonds 9,702 9,705 3 Other 169,310 168,736 (574) ¥278,807 ¥319,940 ¥41,133\nU.S. dollars Cost Fair value Difference March 31, 2012: Equities $ 1,080,073 $ 1,441,622 $361,549 Government, corporate and other bonds 10,667,024 10,734,488 67,463 Other 1,361,708 1,403,268 41,561 $13,108,805 $13,579,378 $470,573\nThousands of  U.S. dollars\nMillions of yen Contract amount Fair value Unrealized  gains (losses) March 31, 2012: Stock index future ¥1,669 ¥(88) ¥(88)\nMillions of yen Contract amount Fair value Unrealized  gains (losses) March 31, 2011: Stock index future ¥– ¥– ¥–\nThousands of U.S. dollars Contract amount Fair value Unrealized  gains (losses) March 31, 2012: Stock index future $20,354 $(1,073) $(1,073)"}]}
+{"image": "doclay/doclay_52169.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": ">>> try : ... print(1/0) ... except : ... raise RuntimeError(\"Something bad happened\") from None ... Traceback (most recent call last): File \"<stdin>\" , line4, in <module> RuntimeError: Something bad happened\nThe Python Language Reference, Release 3.9.5\nAdditional information on exceptions can be found in section Exceptions , and information about handling exceptions is in section The try statement .\nChanged in version 3.3: None is now permitted as Y in raise X from Y .\nNew in version 3.3: The __suppress_context__ attribute to suppress automatic display of the exception context.\n$_{break}$may only occur syntactically nested in a$_{for}$ or$_{while}$ loop, but not nested in a function or class definition within that loop.\nbreak_stmt ::= \"break\"\nIt terminates the nearest enclosing loop, skipping the optional$_{else}$clause if the loop has one.\nIf a$_{for}$ loop is terminated by$_{break}$, the loop control target keeps its current value.\nWhen $_{break}$passes control out of a $_{try}$statement with a finally clause, that$_{finally}$clause is executed before really leaving the loop.\n$_{continue_stmt}$::= \"continue\"\n$_{continue}$may only occur syntactically nested in a for or while loop, but not nested in a function or class definition within that loop. It continues with the next cycle of the nearest enclosing loop.\nWhen$_{continue}$passes control out of a$_{try}$ statement with a$_{finally}$ clause, that$_{finally}$ clause is executed before really starting the next loop cycle.\n7.10 The continue statement\n7.11 The$_{import}$ statement\nimport_stmt ::= \"import\" module [\"as\" identifier ] (\",\" module [\"as\" identifier | \"from\" relative_module \"import\" identifier [\"as\" identifier ] (\",\" identifier [\"as\" identifier ])* | \"from\" relative_module \"import\" \"(\" identifier [\"as\" identifier (\",\" identifier [\"as\" identifier ])* [\",\"] \")\" | \"from\" relative_module \"import\" \"*\" module ::= ( identifier \".\")* identifier $_{relative_module}$::= \".\"* module | \".\"+\nThe basic import statement (no$_{from}$clause) is executed in two steps:\n1. find a module, loading and initializing it if necessary\nChapter 7. Simple statements\n90\n7.9 The break statement"}]}
+{"image": "doclay/doclay_3257.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "FIA World Endurance Championship Prologue and Round 1 Silverstone \nBritish Para Athletics Sprint Meet \nMotorsport UK – HSCC Formula 2 Championship Masters Historic Race Weekend \nMotorsport UK – British Superkart Championship and Support Series \nMotorsport UK – British Truck Racing Championship \nBritish Equestrian – International Dressage Events \nEuropean Tour – Betfred British Masters \nMotorsport UK – GT World Challenge Europe Sprint Cup and Support Series \nMotorsport UK – Donington Historic Festival \nMotorsport UK – British Touring Car Championship and Support Series \nMotorsport UK – Ferrari Challenge UK and Support \nMotorsport UK – British GT Championship and Support Series / Porsche Sprint Challenge GB  and Support Series \nMotorsport UK – Master Historic F1 / Sports Cars and Support Series \nMotorsport UK – FIA Main Event 2021 and Support Series \nEngland Hockey Pro League \nFIM Speedway Grand Prix World Championship - Qualifying Round \nRoyal Windsor Horse Show \nBritish Speedway Premiership, Championship and National Development Leagues \nThe 2020 UEFA European Football Championship \nBritish Superbike Championship and Support Series \nACU – British Motocross Championship and Support races \nEquestrian Eventing – Cirencester \nEuropean Tour – English Championships \nLingfield Derby/Oaks Trials Day horse-racing \nAl Shaqab Lockinge Day horse-racing \nDante Festival horse-racing \nLawn Tennis Association – GB Pro Series Roehampton 1 & 2 \nEquestrian Jumping – Wellington, Heckfield \nCurling – World Mixed Doubles Championship 2021 \nUCI Mountain Bike World Cup \nAJ Bell 2021 World Triathlon Leeds \nEuropean 10,000m Cup (incorporating the British 10,000 Olympic Trial) \nEquestrian Eventing - Belsay International \nW Series Test Event \n52"}]}
+{"image": "doclay/doclay_60851.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "03825019. 5\nwe A 5/7\nMEAS Pm, At 14 RAS HRM —-ECHRNP OBS, + BREAS HRD 12, BRTMSHP OARMRDAA-EKEF AXRHERE 4 HOB. Bi 14 HSS HEAR AR BAMA BME 10 HHA 22, FAB 14 HA-T+MAREAA F Fae 16 FRR TL 20.\nSMB 12 BRAMAN A 14 OP AAW KE As HER, AREER 4 PR\nAF RMA ESOL 2 FIRE 4 RNR 26 PRES HR INARA MARE 4 Aci.\ncH TOM Te ah RA ER RR EB AK 0\n“P TEL Ut BS AR AB CB SS Hr Bl Ba A\nHX, BUBRSAAERME 10 ETRE 2 KOA. Sia, CRE 4 STR HEM. BUM 14 TERN HH A FLIBA BI SCSE 10 FU — aE, MERE 16 RTA 14 AS eR ARES TL 20. RIG, HAR 16 ERB 10 HMB Er 16.\nEHENRET, MUT 26 MARRS 4 HAO PHA Ses 12 SHUR mM 26 3 -RE. AbRAe, AMZ BUFR AC »\nRM 6 EAWREARRA—T THAR ECHS NLA Fl."}]}
+{"image": "doclay/doclay_61781.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Apr. 18,  2019 \n24 \nUS 2019/0113844 Al \n[0069]  In formula (AL-3),  RL 5 ,  RL 6  and  RL $^{7 }$are each  independently a C$_{1 }$-C$_{20 }$ monovalent hydrocarbon group  which may contain a heteroatom such as oxygen, sulfur,  nitrogen or fluorine. The monovalent hydrocarbon groups  may be straight, branched or cyclic, with C$_{1 }$-C$_{20 }$ alkyl  groups being preferred. Any two of  RL 5 ,  RL 6  and  RL $^{7 }$may  bond together to form a ring with the carbon atom to which  they are attached. The ring contains 3 to 20 carbon atoms,  preferably 4 to 16 carbon atoms and is typically alicyclic. \n[0070]  The base polymer may further comprise recurring  units (b) having a phenolic hydroxyl group as an adhesive  group. Examples of suitable monomers from which recur› ring units (b) are derived are given below, but not limited  thereto. Herein  RA  is as defined above. \n[0065]  The acid labile groups represented by R$^{11 }$and R 12  in the recurring units (al) and (a2) may be selected from a  variety of such groups, for example, those groups described  in JP-A 2013-080033 (U.S. Pat. No. 8,574,817) and JP-A  2013-083821 (U.S. Pat. No. 8,846,303). \n[0066]  Typical of the acid labile group are groups of the  following formulae (AL-1) to (AL-3). \n[0067]  In formulae (AL-1) and (AL-2),  RL 1  and  RL 2  are  each independently a C$_{1 }$-C$_{40 }$ monovalent hydrocarbon  group which may contain a heteroatom such as oxygen,  sulfur, nitrogen or fluorine. The monovalent hydrocarbon  groups may be straight, branched or cyclic, with alkyl  groups of 1 to 40 carbon atoms, especially 1 to 20 carbon  atoms being preferred. In formula (AL-1), \"a\" is an integer  of 0 to 10, especially 1 to 5. \n[0068]  In formula (AL-2),  RL 3  and  RL 4  are each indepen› dently hydrogen or a C$_{1 }$-C$_{20 }$monovalent hydrocarbon group  which may contain a heteroatom such as oxygen, sulfur,  nitrogen or fluorine. The monovalent hydrocarbon groups  may be straight, branched or cyclic, with C$_{1 }$-C$_{20 }$ alkyl  groups being preferred. Any two of  RL2, RL 3  and  RL 4  may  bond together to form a ring with the carbon atom or carbon  and oxygen atoms to which they are attached. The ring  contains 3 to 20 carbon atoms, preferably 4 to 16 carbon  atoms, and is typically alicyclic. \nOR12  XR’  XR’  XR’  0  0  0  0  0  0  I~  I~  ¢  Q  & OR12  #  OR12  #  OR12 \n(AL-1) \n(AL-2) \n(AL-3) \nXR’  0  0  6  HO  OH "}]}
+{"image": "doclay/doclay_30532.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "8\nThe quark level transition b → sγ induces the inclusive B → X$_{s}$γ decay. The effective Hamiltonian for b → sγ can be written in the following form 8\n∑ where the form of operators O$_{i}$ ( µ ) and the expressions for calculating the Wilson coefficients C$_{i}$ ( µ ) are given in [55]. The introduction of fourth generation changes the values of Wilson coefficients C$_{7}$ and C$_{8}$ via the virtual exchange of the t ′ -quark and can be written as\nThe values of C t ′ 7 , 8 can be calculated from the expression of C$_{7}$$_{,}$$_{8}$ by replacing the mass of t -quark by m$_{t}$ ′ .\nIn order to reduce the uncertainties arising from b –quark mass, we consider the following ratio\nIn leading logarithmic approximation this ratio can be written as [56]\n| | Here the Wilson coefficient C$_{7}$ is evaluated at the scale µ = m$_{b}$ . The phase space factor f ( ˆ m$_{c}$ ) in Br ( B → X$_{c}$e ¯ ν ) is given by [57]\nκ ( ˆ m$_{c}$ ) is the 1-loop QCD correction factor [57]\nHere ˆ m$_{c}$ = m$_{c}$/m$_{b}$ .\nH eff = 4 G$_{F}$ √$_{2}$ V ∗ $_{ts}$V$_{tb}$ 10 ∑ i =1 C$_{i}$ ( µ ) Q$_{i}$ ( µ ) . (18)\nThe quark level transition b → s l $^{+}$l − is responsible for the inclusive decay B → X$_{s}$ l $^{+}$l − . We apply the same approach introduced for b → sγ . The effective Hamiltonian for the decay b → s l $^{+}$l − is given by 4 G$_{F}$ 10\nD. B → X$_{s}$ l $^{+}$l − decay\nκ ( ˆ m$_{c}$ ) = 1 − 2 α$_{s}$ ( m$_{b}$ ) 3 π [( π 2 − 31 4 ) (1 − ˆ m$_{c}$ ) 2 + 3 2 ] . (17)\nf ( ˆ m$_{c}$ ) = 1 − 8 ˆ m 2 c + 8 ˆ m 6 c − ˆ m 8 c − 24 ˆ m 4 c ln ˆ m$_{c}$ . (16)\nR = | V ∗ $_{ts}$V$_{tb}$ | 2 | V$_{cb}$ | 2 6 α | C tot 7 ( m$_{b}$ ) | 2 πf ( ˆ m$_{c}$ ) κ ( ˆ m$_{c}$ ) . (15) C$_{7}$ is evaluated at the scale µ = m$_{b}$ . The phase space factor\nR = Br ( B → X$_{s}$γ ) Br ( B X$_{c}$e ¯ ν$_{e}$ ) .\nC tot 7 , $_{8}$( µ ) = C$_{7}$$_{,}$$_{8}$ ( µ ) + V ∗ t ′ $_{s}$V$_{t}$ ′ b V ∗ $_{ts}$V$_{tb}$ C t ′ 7 , $_{8}$( µ ) . (14)\nH eff = 4 G$_{F}$ √$_{2}$ V ∗ $_{ts}$V$_{tb}$ 8 ∑ i =1 C$_{i}$ ( µ ) Q$_{i}$ ( µ ) , (13) O$_{i}$ ( µ ) and the expressions for calculating the Wilson coefficients"}]}
+{"image": "doclay/doclay_43145.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "fly along the centerline when on a Federal airway or,  on routes other than Federal airways, along the direct  course between NAVAIDs or fixes defining the route. The  regulation allows maneuvering to pass well clear of other  air traffic or, if in visual meteorogical conditions (VMC),  to clear the flightpath both before and during climb or  descent. \nAirway routing occurs along pre-defined pathways called  airways. [Figure 2-2] Airways can be thought of as three-  dimensional highways for aircraft. In most land areas of  the world, aircraft are required to fly airways between the  departure and destination airports. The rules governing  airway routing, Standard Instrument Departures (SID)  and Standard Terminal Arrival (STAR), are published flight  procedures that cover altitude, airspeed, and requirements  for entering and leaving the airway. Most airways are  eight nautical miles (14 kilometers) wide, and the airway  flight levels keep aircraft separated by at least 500 vertical  feet from aircraft on the flight level above and below  when operating under VFR. When operating under IFR,  between the surface and an altitude of Flight Level (FL)  290, no aircraft should come closer vertically than 1,000  feet. Above FL 290, no aircraft should come closer than  2,000 feet except in airspace where Reduced Vertical  Separation Minima (RVSM) can be applied in which case  the vertical separation is reduced to 1,000 feet. Airways  usually intersect at NAVAIDs that designate the allowed  points for changing from one airway to another. Airways  have names consisting of one or more letters followed by  one or more digits (e.g., V484 or UA419). \nEn route instrument flight rules (IFR) navigation is evolving  from the ground-based navigational aid (NAVAID) airway  system to a sophisticated satellite and computer-based  system that can generate courses to suit the operational  requirements of almost any flight. The FAA Global  Navigation Satellite System (GNSS) provides satellite-based  positioning, navigation, and timing services in the United  States to enable performance-based operations for all  phases of flight, to include en route navigation. \n14 CFR Part 91, § 91.181, is the basis for the course to be  flown. Unless authorized by ATC, to operate an aircraft  within controlled airspace under IFR, pilots must either \nThe en route airspace structure of the National Airspace  System (NAS) consists of three strata. The first stratum low \nFigure 2-1. Code of Federal Regulations, Title 14 Aeronautics and Space. \nFigure 2-2. Airways depicted on an aeronautical chart. \nAirways \nEn Route Navigation \n2-2 "}]}
+{"image": "doclay/doclay_49157.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "認銀行」という。）」を加え、同項第二号を次のように改める。\n（印紙税法施行令の一部改正）\n(Partial Revision of the Order for Enforcement of the Stamp Tax Act) \n第二十三条の見出し中「自由円」を「非居住者円」に改め、同条中「第二十七条か ら第三十条まで（支払及び債権に関する制限及び禁止）の規定に基づく政令で定めら れた非居住者自由円勘定」を「第六条第一項第六号（定義）に規定する非居住者の本 邦にある同法第十一条（業務上の取極）に規定する外国為替公認銀行（以下この条及 び第二十八条において「外国為替公認銀行」という。）に対する本邦通貨をもつて表 示される勘定」に改め、「同法第十一条（業務上の取決め）に規定する」及び「（第 二十八条第一項において「外国為替公認銀行」という。）」を削る。\nThe term \"free-yen\" in the caption of Article 23 is revised to \"non-resident  yen,\" the term \"Non-resident Free-yen Account specified by Cabinet Order  based on the provisions of Articles 27 through 30 (Restriction and prohibition  concerning payment and claims)\" in the same Article is revised to \"account  displayed in Japanese currency against a certified foreign exchange bank in  Japan prescribed in Article 11 of the same Act (Arrangement on Business) for a  non-resident prescribed in Article 6, paragraph (1), item (vi) (Definitions)  (hereinafter such bank is referred to as a 'certified foreign exchange bank' in  this Article and Article 28),\" and the terms \"prescribed in Article 11 of the  same Act (Arrangement on Business)\" and \"(referred to as a 'certified foreign  exchange bank' in Article 28, paragraph (1))\" are deleted. \n第二十八条第一項第二号中「同項第十四号に規定する外貨債権」を「同項第十三号 に規定する債権であつて外国において若しくは外国通貨をもつて支払を受けることが\nArticle 2, paragraph (3), item (ii) is revised as follows, adding the term  \"(referred to as a \"certified foreign exchange bank\" in the following item)\" after  \"a certified foreign exchange bank\" in item (i) of the same paragraph. \n二 非居住者の本邦にある外国為替公認銀行に対する本邦通貨をもつて表示される 勘定に係る預金その他の債務（次条第三号において「非居住者円勘定に係る債 務」という。）\n(ii) A deposit or other debts pertaining to an account displayed in Japanese  currency against a non-resident's certified foreign exchange bank in Japan  (referred to as \"debts pertaining to non-resident free-yen account\" in item  (iii) of the following Article) \n第三条第三号中「自由円勘定に係る債務」を「非居住者円勘定に係る債務」に改め る。\nThe term \"debts pertaining to free-yen account\" in Article 3, item (iii) is  revised to \"debts pertaining to non-resident free-yen account.\" \n第十一条 印紙税法施行令（昭和四十二年政令第百八号）の一部を次のように改正する。\nArticle 11 Part of the Order for Enforcement of the Stamp Tax Act (Cabinet  Order No. 108 of 1967) is revised as follows. \n69 "}]}
+{"image": "doclay/doclay_10463.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "ROYALGOLD, INC\nMh ify\n2001 Smart Growth [annual report]"}]}
+{"image": "doclay/doclay_10736.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "the nature of united technologies /  pratt & whitneyPratt Power The Bombardier JetTrain* locomotive is the first application of Pratt & Whitney’s ST40 gas turbine in a high-speed passenger train. The ST40 is a lightweight alternative for high-speed  rail, at one-tenth the size  and 38,000 pounds lighter than standard diesel train engines of equivalent power.\nMothers of Invention Kathy Spink, Debra Desrocher and Archie Deskus took the initiative to develop the Supplier Direct Ship information system, which tracks inventory and parts at both Pratt & Whitney and Hamilton Sundstrand, saving time, and – best of all – millions of dollars.\nPratt Canada The Pratt & Whitney Canada- powered Cessna Citation Sovereign business jet  successfully completed  its first flight in February. The new jet will enter  service in 2004. \nAtlas V The newest member of the Atlas family, a Lockheed Martin Atlas V successfully  placed a European television satellite into orbit. The first stage was powered by the RD-180 engine produced by RD AMROSS, LLC, a joint venture of Pratt & Whitney and NPO Energomash of Russia. The upper stage was powered by a Pratt RL10A-4-2 engine.\n*Trademark of Bombardier Inc.\n10 united technologies corporation"}]}
+{"image": "doclay/doclay_6320.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "utilities. Therefore, we have adopted the following  objectives:\ni) Our return on equity should continue at a rate commensurate with those of other well-run Canadian utilities.\nii) The financial and business risks of Fortis operations overall should not be substantially greater than those associated with the operation of a Canadian utility. \niii) Our growth in market capitalization should be greater than the average of other Canadian public corporations of similar size.\nThe principal business of Fortis will remain the ownership and operation of electric distribution utilities. We will be proactive and innovative in responding to the challenges and opportunities presented by changes in\nTo continue to enhance value for our shareholders, we believe Fortis should build upon its long history of sound financial performance and continue to grow without significantly disturbing the risk-reward balance traditionally associated with the operation of electricThe corporate headquarters of Fortis Inc. is located in the  Fortis Building in historic St. JohnGLYPH<213>s, Newfoundland and Labrador.\nFortis, through its operating companies, \nhas been a generator and distributor of electricity since 1885. It was structured  as a holding company in 1987 to pursue profitable growth. Our electricity business now consists of investments in three provinces of Canada (Newfoundland and Labrador, Prince Edward Island and Ontario) as well as in Belize, Grand Cayman, and New York. We have grown our non-utility operation, Fortis Properties, into the leading owner and operator of commercial real estate and hotels in Atlantic Canada. While pursuing growth and diversification, we have strengthened Fortis and greatly enhanced earnings. \nVision\nH. Stanley Marshall, President and Chief Executive Officer (left), and Karl W. Smith, Vice President,  Finance and Chief Financial Officer, Fortis Inc. (right)8"}]}
+{"image": "doclay/doclay_50430.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "MySQL Enterprise Encryption Function Reference\n• MYSQL_OPENSSL_UDF_DH_BITS_THRESHOLD : Maximum key length in bits for create_dh_parameters() . The minimum and maximum values for this variable are 1,024 and 10,000.\n•The underlying SSL library takes care of randomness initialization.\n•If the arguments are not suitable to permit a function to perform the requested operation, it returns  NULL or 0 as appropriate. This occurs, for example, if a function does not support a specified algorithm, a key length is too short or long, or a string expected to be a key string in PEM format is not a valid key. (OpenSSL imposes its own key-length limits, and server administrators can impose additional limits on maximum key length by setting environment variables. See Section 6.6.2, “MySQL Enterprise Encryption Usage and Examples” .)\n•For arguments of the wrong type or an incorrect number of arguments, each function returns an error.\nSeveral of the functions take an encryption algorithm argument. The following table summarizes the supported algorithms by function.\nTable 6.40 Supported Algorithms by Function\nFunction Supported Algorithms asymmetric_decrypt() RSA asymmetric_derive() DH asymmetric_encrypt() RSA\n1597\nName Description asymmetric_decrypt() Decrypt ciphertext using private or public key asymmetric_derive() Derive symmetric key from asymmetric keys asymmetric_encrypt() Encrypt cleartext using private or public key asymmetric_sign() Generate signature from digest asymmetric_verify() Verify that signature matches digest create_asymmetric_priv_key() Create private key create_asymmetric_pub_key() Create public key create_dh_parameters() Generate shared DH secret create_digest() Generate digest from string\n6.6.3 MySQL Enterprise Encryption Function Reference\n6.6.4 MySQL Enterprise Encryption Function Descriptions\nMySQL Enterprise Encryption functions have these general characteristics:\nThe example uses Bourne shell syntax. The syntax for other shells may differ.\nTo use any of these environment variables, set them in the environment of the process that starts the server. If set, their values take precedence over the maximum key lengths imposed by OpenSSL. For example, to set a maximum key length of 4,096 bits for DSA and RSA keys for create_asymmetric_priv_key() , set these variables:\nexport MYSQL_OPENSSL_UDF_DSA_BITS_THRESHOLD=4096 export MYSQL_OPENSSL_UDF_RSA_BITS_THRESHOLD=4096\nTable 6.39 MySQL Enterprise Encryption Functions"}]}
+{"image": "doclay/doclay_55532.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "• $annotations  holds all annotations as a JSON object, with annotation names as properties.\n• With  to_entries , we convert a JSON object like  { \"a\": \"b\"}  into a an array with entries like  { \"key\": \"a\", \"value\": \"b\" } . See the  jq  documentation for more details.\n• .[]  selects the array entries individually.\n• From these entries, we pick only the ones with the matching key. There can be only zero or one matches that survive this filter.\n• Finally, we extract the value ( .value ) and convert it with  @uri  so that it can be used as part of an URI.\nThis expression converts a JSON structure like\n{ \"k8spatterns.io/pattern\" : \"Controller\", \"k8spatterns.io/podDeleteSelector\" : \"app=webapp\" }\nto a selector  app%3Dwebapp .\nIf the script can extract a  selector , we can use it now directly to select the Pods to delete. First, we look up all Pods that match the selector, and then we delete them one by one with direct API calls.\nThis shell script-based controller is, of course, not production-grade (e.g., the event loop can stop any time), but it nicely reveals the base concepts without too much boilerplate code for us.\nThe remaining work is about creating resource objects and container images. The controller script itself is stored in a ConfigMap  config-watcher-controller  and can be easily edited later if required.\nWe use a Deployment to create a Pod for our controller with two containers:\n• One Kubernetes API  Ambassador  container that exposes the Kubernetes API on localhost on port 8001. The image  k8spatterns/kubeapi-proxy  is an Alpine Linux with a local  kubectl  installed and  kubectl proxy  started with the proper CA and token mounted. The original version, kubectl-proxy, was written by Marko Lukša, who introduced this proxy in  Kubernetes in Action .\n• The main container that executes the script contained in the just-created Config‐ Map. We use here an Alpine base image with  curl  and  jq  installed.\nYou can find the Dockerfiles for the  k8spatterns/kubeapi-proxy  and  k8spatterns/ curl-jq  images in our example Git repository.\nSolution  |  183"}]}
+{"image": "doclay/doclay_21124.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "DIRECTORS\nEXECUTIVE OFFICERS\nBOARD COMMITTEES\nHerbert Wender Non-executive Chairman Radian Group Inc.\nDavid C. Carney Former Chairman ImageMax, Inc.\nHoward B. Culang Director ioSemantics, LLC Former President Laurel Corporation\nLisa W. Hess President and Managing Partner SkyTop Capital Management LLC\nStephen T. Hopkins President Hopkins and Company LLC\nSanford A. Ibrahim Chief Executive Officer Radian Group Inc.\nBrian D. Montgomery Chairman The Collingwood Group, LLC\nRonald W. Moore Retired Adjunct Professor of Business Administration, Harvard University, Graduate School of Business Administration\nGaetano J. Muzio Co-founder Ocean Gate Capital Management, LP\nJan Nicholson President The Grable Foundation\nGregory V. Serio Partner Park Strategies, LLC\nNoel J. Spiegel Retired Deputy Managing Partner Deloitte & Touche LLP\nSanford A. Ibrahim Chief Executive Officer\nTeresa Bryce Bazemore President Radian Guaranty Inc.\nC. Robert Quint Executive Vice President and Chief Financial Officer\nRichard I. Altman Executive Vice President and Chief Operating Officer Radian Guaranty Inc.\nEdward J. Hoffman Executive Vice President, General Counsel and Corporate Secretary\nH. Scott Theobald Executive Vice President and Chief Risk Officer Radian Guaranty Inc.\nCatherine M. Jackson Senior Vice President and Corporate Controller\nStockholders, interested investors, financial analysts and others may obtain, without charge, a copy of Radian’s Annual Report on Form 10-K for the year ended December 31, 2012, as filed with the Securities and Exchange Commission by sending a written request to:\nEdward J. Hoffman Corporate Secretary Radian Group Inc. 1601 Market Street Philadelphia, Pennsylvania 19103\nor by accessing the Radian website at www.radian.biz\nAudit Committee Mr. Carney, Chairman Ms. Hess, Messrs. Serio and Spiegel\nCompensation and Human Resources Committee Mr. Hopkins, Chairman Messrs. Culang, Montgomery and Moore\nCredit Committee Mr. Culang, Chairman Mr. Carney, Ms. Nicholson and Mr. Spiegel\nGovernance Committee Ms. Nicholson, Chairwoman Messrs. Carney, Culang and Hopkins\nInvestment and Finance Committee Mr. Moore, Chairman Ms. Hess, and Messrs. Hopkins, Muzio and Spiegel\nANNUAL MEETING The annual meeting of stockholders of Radian Group Inc. will be held on Wednesday, May 15, 2013 at 9:00 a.m. at The Sofitel Philadelphia, 120 South 17 th Street, Philadelphia, Pennsylvania 19103\nTRANSFER AGENT AND REGISTRAR Computershare Trust Company, N.A. P.O. Box 43006 Providence, RI 02940-3006 www.computershare.com 866.214.3035\nINDEPENDENT AUDITORS PricewaterhouseCoopers LLP Philadelphia, Pennsylvania\nCORPORATE HEADQUARTERS 1601 Market Street Philadelphia, Pennsylvania 19103 +1 215 231.1000\nINVESTOR RELATIONS Emily Riley 1601 Market Street Philadelphia, Pennsylvania 19103 +1 215 231.1035"}]}
+{"image": "doclay/doclay_69094.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Using the CLI\n9.2.3 Creating the MDisk arrays or discovering unmanaged MDisks\nUsing the GUI\nChapter 9. IBM Storwize Family and SAN Volume Controller  129\nNote:  If you want to determine the drives that will be spare, you can manually select  them before this step and mark them  spare  in the  Use  column. For that, right-click the  drive and select  Mark As  followed by the  spare  option. A good practice is to select one  spare drive for each drawer and type of drive.\nTo accomplish this task in the GUI, complete the following steps:\nNote:  Storwize V3700 allows only internal disks; the SAN Volume Controller allows only  external disks.\nWhen you use the Storwize V5000 or V7000 server, you can use internal or external disks to  create MDisks.\nThese steps can also be done by using the CLI, as shown in Example 9-1. \nExample 9-1 Creating a pool using the CLI\n# svctask mkmdiskgrp -ext 256 -warning 100% -name UD_pool\n1. Hover the cursor over the  Pools  icon. The Pools menu opens (Figure 9-4). \n2. To create an MDisk with internal disks, click  Internal Storage  to display the list of  candidate internal disks. Select the drive class that you want to configure, for example,  SAS disks for metadata and NL_SAS (or Serial Advanced Technology Attachment, also  known as SATA) for user data. Then, click  Configure Storage  (Figure 9-5 on page 130).Figure 9-4 Pools menu"}]}
+{"image": "doclay/doclay_34186.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "6\nJoseph D. Barry et al.\nis that the straight line boundaries at y = 0 and y = 1 naturally occur as a result of this process.\nA semi-periodic monodisperse sample is created using the standard method outlined in the Surface Evolver documentation (which is supplied with the software pack- age). Disordered semi-periodic samples are created by the following process (illustrated in Fig. 3).\nUsing the above methods for foam sample creation, we create one monodisperse foam sample and five foam sam- ples of polydispersity µ$_{2}$ ( A ) = 0 . 13 ± 0 . 002, where the measure of polydispersity is defined as the second mo- ment of the area distribution,\nPoints are placed at random in the unit cell using a uniform distribution to determine the x and y posi- tions; see Fig. 3(a). New points are added to the box if they are more than a predefined minimum distance r$_{min}$ from any other point. The process is continued until the desired number of points have been successfully placed. A lower value of r$_{min}$ results in more polydisperse sam- ples. These points are translated to boxes to the left and right, and reflected (see Fig. 3(a)) through the lines y = 0 and y = 1 to boxes above and below, based on the method of De Fabritiis and Coveney [10] (as indi- cated by the background triangles in Fig. 3(a)). With the software package Qhull [1], the Voronoi Diagram (a particular way of tessellating the plane into regions of convex polygons) of these points is calculated; see Fig. 3(b). This is then passed into the Surface Evolver. The box in the centre is isolated (see Fig. 3(c)) and keeping the areas of each of the cells fixed, the Surface Evolver performs line minimization on the structure. The result- ing structure is our final two-dimensional half-periodic (i.e. periodic in the x-direction only) foam data file; see Fig. 3(d). Of interest here (as a result of the reflection)\nWe proceed to move the top boundary in the posi- tive x-direction with velocity V by incrementally moving vertices at y = 1 a distance V dt per timestep dt . The VF algorithm, as outlined in Sec. 2 is used to determine the dynamics of the foam during each timestep. Typical values for the displacement of the shearing boundary per\nThe foam samples consist of N$_{b}$ = 100 bubbles in a square unit cell of area 1; it is too computationally expensive to run larger samples in a VF simulation. In our dimensionless simulation units, our system size L = 1 and mean bubble area ¯ A = 0 . 01. We define a new length scale ¯ A 1 / $^{2}$, the square root of the mean bubble area. In these new units, L = 10 ¯ A 1 / $^{2}$. The width W$_{l}$ of one layer of bubbles in our square sample is given by\nHere A denotes the area of a bubble, and ¯ A the mean bubble area.\nµ$_{2}$ ( A ) = ( 1 − A ¯ A$^{)}$$^{2}$ . (3)\nW$_{l}$ = L/ $^{√}$N$_{b}$ = ¯ A 1 / 2 (4)\n4 Simulation Details and Results\n3 Sample Creation"}]}
+{"image": "doclay/doclay_55031.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "UCI CYCLING REGULATIONS \nPosition  One-day races  14 2 15 1\nFinal results in the Continental Championships  Position  European Continental Championships  Asian, African, American and Oceanian \nFinal results in the Continental Championships  Position  European Continental Championships  Asian, African, American and Oceanian  Championships  Men Under 23  Road Race  Men Under 23  Ind. Time Trial  Men Under 23  Road Race  Men Under 23  Ind. Time Trial  1  10  10  8  8  2  8  8  5  5  3  6  6  3  3  4  5  5  1  1  5  4  4  6  3  3  7  2  2  8  1  1 \nFinal results in the UCI Road World Championships  Position  UCI Road World Championships  Men Under 23  Road Race  Men Under 23  Ind. Time Trial  1  50  30  2  35  25  3  30  20  4  25  15  5  20  10  6  15  5  7  10  3  8  10  3  9  10  3  10  10  3  11  5  2  12  5  2  13  5  2  14  3  1  15  3  1  16  3  17  2  18  2  19  1  20  1 \nFinal results in the UCI Road World Championships  Position  UCI Road World Championships \nNote: Points in the UCI Road World Championships will be awarded for the first time  from the 2021 edition of the UCI Road World Championships. \n(text modified on 1.07.11; 1.01.17; 9.11.20). \nE170421 \nROAD RACES \n179 "}]}
+{"image": "doclay/doclay_53641.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "mysql_tzinfo_to_sql — Load the Time Zone Tables\nThe path to the directory that  mysql_ssl_rsa_setup  should check for default SSL and RSA files and in which it should create files if they are missing. The default is the compiled-in data directory.\nThe suffix for the Common Name attribute in X.509 certificates. The suffix value is limited to 17 characters. The default is based on the MySQL version number.\nThe name of the user who should be the owner of any created files. The value is a user name, not a numeric user ID. In the absence of this option, files created by  mysql_ssl_rsa_setup  are owned by the user who executes it. This option is valid only if you execute the program as  root  on a system that supports the  chown()  system call.\nVerbose mode. Produce more output about what the program does. For example, the program shows the  openssl  commands it runs, and produces output to indicate whether it skips SSL or RSA file creation because some default file already exists.\nDisplay version information and exit.\nThe  mysql_tzinfo_to_sql  program loads the time zone tables in the  mysql  database. It is used on systems that have a  zoneinfo  database (the set of files describing time zones). Examples of such systems are Linux, FreeBSD, Solaris, and macOS. One likely location for these files is the  /usr/share/ zoneinfo  directory ( /usr/share/lib/zoneinfo  on Solaris). If your system does not have a zoneinfo database, you can use the downloadable package described in Section 5.1.15, “MySQL Server Time Zone Support” .\nmysql_tzinfo_to_sql  can be invoked several ways:\nmysql_tzinfo_to_sql  tz_dir mysql_tzinfo_to_sql  tz_file tz_name mysql_tzinfo_to_sql --leap  tz_file\nFor the first invocation syntax, pass the zoneinfo directory path name to  mysql_tzinfo_to_sql  and send the output into the  mysql  program. For example:\nmysql_tzinfo_to_sql /usr/share/zoneinfo | mysql -u root mysql\nmysql_tzinfo_to_sql  reads your system’s time zone files and generates SQL statements from them. mysql  processes those statements to load the time zone tables.\nThe second syntax causes  mysql_tzinfo_to_sql  to load a single time zone file  tz_file  that corresponds to a time zone name  tz_name :\nmysql_tzinfo_to_sql  tz_file tz_name  | mysql -u root mysql\nIf your time zone needs to account for leap seconds, invoke  mysql_tzinfo_to_sql  using the third syntax, which initializes the leap second information.  tz_file  is the name of your time zone file:\nmysql_tzinfo_to_sql --leap  tz_file  | mysql -u root mysql\n403\n• --datadir= dir_name\n• --suffix= str\n• --uid=name ,  -v\n• --verbose ,  -v\n• --version ,  -V\n4.4.4 mysql_tzinfo_to_sql — Load the Time Zone Tables"}]}
+{"image": "doclay/doclay_61081.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "a MH RB 526/152\n200510079024. 1\n29\noe FF Br 300 (3X2 Prd ob Fe Ginter FAP BTR EAI LM 48 Fi] SOF] 5] FLARE HF).\nA RRA A RAFI HEB IL HA 95 MA FAKRELA 90 ( FAI/RAFORF LAB 90 HRS) +, BEBZERZWA BRAF Fo/RPAAA A. Bde:\n© VMLEES TRAE HPA RAHA HY HFOLSLAZR 90, RHE BM AR KORA, AB/RABLARDENRBREZHH Hew YS Bl RAP FAH S ML HH 90.\n@ HAO ASALF LAK IO TANS (RELA AY) RHF Fo/ RIG KH OS REBRAAPE,\n© HRN SSA RBS EASON F/RAMHFALSLAR 90 HALKA.\nBSAHFLAKTR-AIFH\n6ER FÄHBSLHELAEIN TU—-M LH, AURA aia, EER HIP:\n@ 4% Fl 4 PF 300a. RFI RAT 4 FPA 400a. AGEALAY 500a Fo BEHFH 200 (IHM), TRAARZHAIE 106 um 10 4 FRE.\n@ 41F eas FP 200a. A A 1R A e AT 300b. AK AGE uA] 500b Fe AF ARAFAT EFA 400b (A bak), TUARMRK AAT HA 124 LH — ERS.\n. FAHEREHFT 2000. AiEHH 5000. EA] HP 3006 Aare AIBRERHTEHH I NEM), AARIHFSHARKH 128 METE.\n© BPSALSLARAM AM ABS (ANSP, EAEHF I, 2 ekee HPT 200d. MAIR TARA 400c Fiz 500a- BAH 3), PARRA FTAA 130.\nEKATMBR, 4 HSALSLA 900 ORRIN, HSA HLSVAAKHAMAST ARERR UF RA.\nABRBRFRRNLTKE BHABRSREAMBAYHASALE LARRY\nTER, HERERAWFEHR,. RERACRA, FAHSA"}]}
+{"image": "doclay/doclay_74634.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "© 2001 Accenture\nAll rights reserved. \nIX00000228\n"}]}
+{"image": "doclay/doclay_78136.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "CHAPTER 68. PERLXS\n68.1. DESCRIPTION\n68.1.13 The INIT: Keyword\n68.1.14 The NO_INIT Keyword\n68.1.15 Initializing Function Parameters\n1037\nThe following code demonstrates how to supply initialization code for function parameters. The initialization code is eval’d within double quotes by the compiler before it is added to the output so anything which should be interpreted literally [mainly $ , @ , or \\\\ ] must be protected with backslashes. The variables $var, $arg, and $type can be used as in typemaps.\nC function parameters are normally initialized with their values from the argument stack (which in turn contains the parameters that were passed to the XSUB from Perl). The typemaps contain the code segments which are used to translate the Perl values to the C parameters. The programmer, however, is allowed to override the typemaps and supply alternate (or additional) initialization code. Initialization code starts with the first = , ; or + on a line in the INPUT: section. The only exception happens if this ; terminates the line, then this ; is quietly ignored.\nThe following example shows a variation of the rpcb_gettime() function. This function uses the timep variable only as an output variable and does not care about its initial contents.\nThe NO_INIT keyword is used to indicate that a function parameter is being used only as an output value. The xsubpp compiler will normally generate code to read the values of all function parameters from the argument stack and assign them to C variables upon entry to the function. NO_INIT will tell the compiler that some parameters will be used for output rather than for input and that they will be handled before the function terminates.\nAnother use for the INIT: section is to check for preconditions before making a call to the C function:\nThe INIT: keyword allows initialization to be inserted into the XSUB before the compiler generates the call to the C function. Unlike the CODE: keyword above, this keyword does not a ff ect the way the compiler handles RETVAL.\nbool_t rpcb_gettime(host,timep) char *host time_t &timep INIT: printf(\"# Host is %s\n\", host ); OUTPUT: timep\nlong long lldiv(a,b) long long a long long b INIT: if (a == 0 && b == 0) XSRETURN_UNDEF; if (b == 0) croak(\"lldiv: cannot divide by 0\");\nbool_t rpcb_gettime(host,timep) char *host time_t &timep = NO_INIT OUTPUT: timep"}]}
+{"image": "doclay/doclay_58775.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "AAATHE\n● return and wait near your vehicle (well away from the  carriageway and hard shoulder) \n● if you feel at risk from another person, return to your vehicle  by a left-hand door and lock all doors. Leave your vehicle  again as soon as you feel this danger has passed. \n276. Before you rejoin the carriageway after a breakdown, build up  speed on the hard shoulder and watch for a safe gap in the traffic.  Be aware that other vehicles may be stationary on the hard  shoulder. \n277. If you cannot get your vehicle onto the hard shoulder \n● do not attempt to place any warning device on the  carriageway \nhighwaycodeuk.co.uk 142 \nLaws MT(E&W)R reg 14 & MT(S)R reg 12 \n"}]}
+{"image": "doclay/doclay_76757.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "arXiv:1001.2684v4 [cond-mat.soft] 11 Mar 2010\nFluctuation-induced collective motion: A single-particle density analysis\nChiu Fan Lee ∗\nMax Planck Institute for the Physics of Complex Systems, N¨ othnitzer Str. 38, 01187 Dresden, Germany\n(Dated: August 14, 2018)\nIn a system of noisy self-propelled particles with interactions that favor directional alignment, collective motion will appear if the density of particles increases beyond a certain threshold. In this paper, we argue that such a threshold may depend also on the profiles of the perturbation in the particle directions. Specifically, we perform mean-field, linear stability, perturbative and numerical analyses on an approximated form of the Fokker-Planck equation describing the system. We find that if an angular perturbation to an initially homogeneous system is large in magnitude and highly localized in space, it will be amplified and thus serves as an indication of the onset of collective motion. Our results also demonstrate that high particle speed promotes collective motion.\nPACS numbers: 05.40.-a, 45.50.-j, 05.65.+b, 64.60.-i\nThe interesting phenomena of flocking in animals [1–3] and self-organized patterns in motile cells [4–6] are cur- rently driving the intense theoretical study of collective motion among self-propelled particles [7–17]. In particu- lar, a comprehensive linear stability analysis on the onset of collective motion from the perspective of Boltzmann equation has recently appeared [18]. Models for collec- tive motion usually involve motile particles that possess alignment interactions and angular noise. Collective mo- tion is then observed if the density of particles increases beyond a certain threshold. Besides density fluctuations, fluctuations in the heading directions of the particles con- stitute another important aspect of the system. Here, we study a minimal model for collective motion and show that the threshold for collective motion transition may depend on the profiles of directional fluctuations. Specif- ically, we find that an initial directional perturbation to a spatially homogeneous system will be amplified, if the perturbation is large in magnitude and is highly localized in space. We also demonstrate that high particle speed promotes collective motion.\nTo achieve our results, we first write down the Fokker- Planck equation describing the single-particle density dis- tribution of the system in Sect. II. We then investigate in Sect. III the equation in the Fourier space of the direc- tional component, and argue that only the lower order modes are important at the onset of collective motion. As a result, the dynamics of the distribution function can be captured by a set of three nonlinear coupled differen- tial equations, which we subsequently study with linear stability analysis in Sect. IV. In Sect. V, we go beyond the linear stability regime by investigating the dynamical equations perturbatively and numerically.\n$^{∗}$Electronic address: cflee@pks.mpg.de\nIn this work, we follow [16] and consider a minimal model for collective motion in two dimensions, where ev- ery particle is assumed to have constant speed and that their interactions consist only of directional alignment mechanism. Noise is incorporated in the direction of travel. Specifically, let there be N particles in a volume of V , their equations of motion are:\nwhere 1 ≤ i ≤ N , R ≡ ( r $_{1}$, . . . , r $_{N}$), Θ ≡ ( θ$_{1}$, . . . , θ$_{N}$ ), v ( θ ) ≡ (cos θ, sin θ ), and the noise is assumed to be Gaus- sian characterized by the following moments:\nMoreover, the alignment interaction is assumed to be of very short range and thus can be approximated by a delta function:\nIf we denote the probability distribution of the density of particles in the state ( R , Θ) at time t by f ( t, R , Θ), then the Fokker-Planck equation corresponding to the system is [19]:\nNaturally, we are not interested in all the information captured by f , and we will from now on focus on the single-particle density function, ρ ,\nρ ( r $_{1}$, θ$_{1}$ ) = ( N !) ∫ d r$_{2}$ · · · d r$_{N}$ d θ$_{2}$ · · · d θ$_{N}$ f ( R , Θ) ( N − 1)! . (6)\n∂f ∂t = ∑ i { D ∂ 2 ∂θ 2 i f − 2 u π ∇ r i · [ v ( θ$_{i}$ ) f ] } + g π ∑ i<j ∂ ∂θ$_{i}$ [ δ $^{(2)}$( r i − r $_{j}$) sin( θ$_{i}$ − θ$_{j}$ ) f ] . (5)\nU ( R , Θ) = − g π ∑ i<j δ $^{(2)}$( r i − r $_{j}$) cos( θ$_{i}$ − θ$_{j}$ ) . (4)\n〈 η$_{i}$ ( t ) 〉 = 0 , 〈 η$_{i}$ ( t ) η$_{j}$ ( t $^{′}$) 〉 = δ$_{ij}$ δ ( t − t $^{′}$) (3)\nd r i d t = 2 u π v ( θ$_{i}$ ) (1) $_{Θ) +}$√$_{2}$$_{Dη}$$_{i}$$_{(}$$_{t}$$_{)}$\nd t π d θ$_{i}$ d t = − ∂U ∂θ$_{i}$ ( R , $_{Θ) +}$√$_{2}$$_{Dη}$$_{i}$$_{(}$$_{t}$$_{)}$ (2)\nII. MODEL\nI. INTRODUCTION"}]}
+{"image": "doclay/doclay_61510.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "2 \nEP 2 000 003 B1\n1\nBeschreibung\n[0001] Die vorliegende Erfindung betrifft Hoch lei- stungsstrahlermodule, insbesondere NIR-Module. Der- artige Module sind Flächenstrahler und enthalten übli- cherweise mindestens zwei parallel nebeneinander an- geordnete Infrarotstrahler, die ein einfaches Rundrohr oder ein Doppelrohr aufweisen. Bei Modulen mit einer Flächenleistung bis 150 kW/m$^{2}$ eignen sich luftgekühlte Goldreflektoren, um die Strahlung auf das zu bestrah- lende Objekt zu fokussieren. Anschlussleistungen von 200kW/m$^{2}$ und darüber könnennur mit wassergekühlten Reflektoren ausgeführt werden, da die Reflektoren an- dernfalls durch Überhitzung sehr schnell zerstört wür- den. Solche mit einer zusätzlichen Wasserkühlung ver- sehenen Module sind aus der DE 101 56 915 oder aus der DE 101 25 888 bekannt.\n[0002] Aufwändige Wasserkühlung ist in elektrischen Anlagen nicht erwünscht. Erstens aufgrund der zusätz- lichen Kosten und zweitens, da stets die Gefahr vonWas- seraustritt besteht. Wasseraustritt kann zum einen die zubestrahlenden Produkteschädigen undzum anderen verheerende Auswirkungen für die elektrischen Einrich- tungen oder die heißen Teile der Anlage haben. Wasser ist daher unter demGesichtspunktder Betriebssicherheit ein äußerst unerwünschtes Medium.\n[0003] In der DE 101 56 915 werden zudem kerami- sche Faserplatten alsHitzeschutzdesGehäuses undals Hitzeschutzeiner Kammer in der die elektrischen Zufüh- rungen und die Kühlwasserschläuche offenbart. Diese Faserplatten schützen dasGehäuse vor Streustrahlung, die trotz der Goldreflektoren in den Kühlkanälen noch in Richtung des Moduls ausgesendet wird.\n[0004] Auchdie JP 07-198949 A und die JP 05-024853 A beschreibenIR- Strahler, welchemit einemHitzeschutz versehen sind.\n[0005] Die Aufgabe der vorliegenden Erfindung be- steht darin, Hochleistungsstrahlermodule mit verringer- tem Gefahrenpotential bereit zu stellen.\n[0006] Lösungen der Aufgabe erfolgen nach den un- abhängigen Ansprüchen. Bevorzugte Ausführunge n sind in den abhängigen Ansprüchen beschrieben.\n45 50 [0007] Erfindungsgemäß wirdeinbezüglich seiner op- tischen Dichte inhomogener, aus anorganischem oxidi- schen Material bestehender Hitzeschutz zwisch en Strahler und Gehäuse einesModulsangeordnet. Der er- findungsgemäße Hitzeschutz ermöglicht Anschlussflä- chenleistungen von 200 kW/m 2 und mehr. Hochle i- stungsstrahler mit demerfindungsgemäßen Hitzeschutz sind äußerst robust und für den Dauerbetrieb geeignet, d.h. der Strahler kann beim vollständigen Erreichen des Gleichgewichts mit der Umgebung betrieben werden. Dieser Gleichgewichtszustand stellt sich üblicherweise nach 5 bis 15 Minuten ein.\n[0008] Fasern sind für den erfindungsgemäßen Hitze- schutz nicht mehr nötig, weshalb das von Fasermaterial ausgehende Gefahrenpotential erfindungsgemäß elimi- niert wird.\n[0009] Zur Herstellung eines Körpers, insbesondere monolithischen Sinterkörpers, der als Hitzeschutz, ins- besondereeinstückiger Hitzeschutz oder als Hitzeschut- zelement geeignet ist, eignen sich die in EP 1 159 227 beschriebenen Verfahren. Grundsätzlich sind monolithi- sche Sinterkörper aus Schlicker, wie z. B. Quarzmehl- schlicker, durch Sintern herstellbar.\n[0010] Es hat sich bewährt, wenn pro Strahler oder Doppelrohrstrahler je ein Hitzeschutzelement oder ein einstückiger Hitzeschutz für alle Strahler eines Moduls verwendet wird.\n[0011] Insbesondere\n[0012] Maßgeblich ist, dass die optische Dichte des Hitzeschutzes hinsichtlich IR-Strahlung und ggf. bezüg- lich UV-Strahlung schwankt, insbesondere im Mikrobe- reich uneinheitlich ist. Hierzu haben sich Bläschen oder Dotierungen bewährt. Insbesondere sind die Dimensio- nen dieser Einschlüsse kleiner als 1 mm, vorzugsweise kleiner als 100  P m und besonders bevorzugt kleiner als 10  P m.\n[0013] In bevorzugter Ausführung besteht der bezüg- lich IR-Strahlung optisch inhomogene Hitzeschutz aus einem an sich für IR-Strahlung transparentem Material, wie Quarzglas oder Al$_{2}$O$_{3}$-Keramik. Es werden jedoch Schwankungen in der optischen Dichte, insbesondere durch unterschiedliche Phasen innerhalb des anorgani- schen oxidischen Materials gebildet, so dass diese Schwankungen bezüglich der optischen Dichte des Ma- terials wesentliche Strahlungsanteile streuen. Aufgrund seinerspeziellen Strukturweist dieseserfindungsgemäß in seiner optischen Dichte bezüglich IR-Strahlung oder ggf. UV-Strahlung uneinheitliche Material in dem Wel- lenlängenbereich, in dem bei homogener und einphasi- ger Ausführung des Materials eine sehr hohe Transpa- renz erreicht würde, nicht die Energieübertragung auf, diedasGehäuse beschädigen würde.Dies ist für Quarz- glas je nach Zusammensetzung und Anteil an Spuren- verunreinigungen der Wellenlängebereich von 180 nm bis 5000 nm. Dabei ist der Bereich von 180 bis 400 nm, insbesondere 200 nm bis 380 nm für UV- Strahler maßgeblich und der Bereich von 760 bis 5000 nm, ins- besondere780bis4000nm, für IR- Strahler maßgeblich. Erreicht wird diese Eigenschaft durch eine optische In- homogenität des Quarzglases, wie z.B. durch gezieltes und homogenes Einbringen von Blasen und Störungen.\n2\n- ist der Hitzeschutzoder sind dieHitzeschutzelemen- te ein oder jeweils ein Sinterkörper;\n- weist der Hitzeschutz oder weisen die Hitzeschutz- elemente Material mit einer KörnungimNanometer- oder Mikrometerbereich auf;\n- ist der Hitzeschutzoder sind dieHitzeschutzelemen- te ein oder jeweils ein Monolith;\n- weist das Material des Hitzeschutzes oder der Hit- zeschutzelemente Einschlüsse imNanometer- oder Mikrometerbereich auf, beispielsweise Hohlräume oder Kristalle."}]}
+{"image": "doclay/doclay_56268.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "MongoDB Documentation, Release 3.0.4\nIf you have an existing data set and want to disable the default index key length validation so that you can upgrade before resolving these indexing issues, use the failIndexKeyTooLong parameter.\nPrevious versions did not create the index but did not error.\nWrite Method Acknowledgements\nensureIndex and Existing Indexes\nIndex Specifications Validate Field Names\n• Secondaries allow index build and rebuild operations on a collection that contains an indexed field whose corresponding index entry exceeds the limit but with warnings in the logs.\n• With mixed version replica sets where the secondaries are version 2.6 and the primary is version 2.4, secondaries will replicate documents inserted or updated on the 2.4 primary, but will print error messages in the log if the documents contain an indexed field whose corresponding index entry exceeds the limit.\nSolution Run db.upgradeCheckAllDBs() to find current keys that violate this limit and correct as appropriate. Preferably, run the test before upgrading; i.e. connect the 2.6 mongo shell to your MongoDB 2.4 database and run the method.\nDescription In MongoDB 2.6, create and re-index operations fail when the index key refers to an empty field, e.g. \"a..b\" : 1 or the field name starts with a dollar sign ( $ ).\n• db.collection.ensureIndex() will not create a new index with an invalid or empty key name.\n• db.collection.reIndex() , compact , and repairDatabase will error if an index exists with an invalid or empty key name.\n• Chunk migration will fail if an index exists with an invalid or empty key name.\nSolution Run db.upgradeCheckAllDBs() to find current keys that violate this limit and correct as appropriate. Preferably, run the test before upgrading; i.e. connect the 2.6 mongo shell to your MongoDB 2.4 database and run the method.\nPrevious versions of MongoDB allow the index.\nDescription db.collection.ensureIndex() now errors:\n• if you try to create an existing index but with different options; e.g. in the following example, the second db.collection.ensureIndex() will error.\n• if you specify an index name that already exists but the key specifications differ; e.g. in the following example, the second db.collection.ensureIndex() will error.\ndb.mycollection.ensureIndex( { x: 1 } ) db.mycollection.ensureIndex( { x: 1 }, { unique: 1 } )\ndb.mycollection.ensureIndex( { a: 1 }, { name: \"myIdx\" } ) db.mycollection.ensureIndex( { z: 1 }, { name: \"myIdx\" } )\n857\n12.2. Previous Stable Releases\nDescription The mongo shell write methods db.collection.insert() , db.collection.update() , db.collection.save() and db.collection.remove() now integrate the write concern (page 78) directly into the method rather than with a separate getLastError command to provide safe writes (page 78)"}]}
+{"image": "doclay/doclay_68161.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "This document was created or updated on October 21, 2016.\nSend us your comments in one of the following ways: Use the online Contact us review form found at:\nTrademarks\nThis document is available online at http://www.ibm.com/redbooks/abstracts/tips1344.html .\nIBM, the IBM logo, and ibm.com are trademarks or registered trademarks of International Business  Machines Corporation, registered in many jurisdictions worldwide. Other product and service names  might be trademarks of IBM or other companies. A current list of IBM trademarks is available on the web  at “Copyright and trademark information” at http://www.ibm.com/legal/copytrade.shtml\nThe following terms are trademarks or registered trademarks of International Business Machines  Corporation, and might also be trademarks or registered trademarks in other countries. \nDB2® IBM® Redbooks® Redbooks (logo)®\nThe following terms are trademarks of other companies:\nLinux is a trademark of Linus Torvalds in the United States, other countries, or both. Windows, and the Windows logo are trademarks of Microsoft Corporation in the United States, other  countries, or both. UNIX is a registered trademark of The Open Group in the United States and other countries.\nOther company, product, or service names may be trademarks or service marks of others.\nMaximizing Performance of IBM DB2 Backups\n10\nSend us your comments in one of the following ways: Use the online Contact us review form found at: z ibm.com/redbooks Send your comments in an e-mail to:\nibm.com/redbooks Send your comments in an e-mail to: z redbooks@us.ibm.com Mail your comments to:\nredbooks@us.ibm.com Mail your comments to: z IBM Corporation, International Technical Support Organization Dept. HYTD Mail Station P099 2455 South Road Poughkeepsie, NY 12601-5400 U.S.A."}]}
+{"image": "doclay/doclay_35007.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "8\nAcknowledgments\nOhm’s law has a gravitational analog that relates energy flow (current) from a black hole, or during gravitational collapse, to the “gravitational electric” field (see Sec. 4.4 of [11]). Perhaps the instability of the black hole can be summarized in a negative “gravitational conductivity”.\nA potential application of our findings is to supercon- ducting cosmic strings, where massless QED in 1+1 di- mensions is expected to apply for fermion zero modes on the string [12]. Our analysis shows that if superconduct- ing strings really behave as 1+1 dimensional systems, they will carry oscillatory currents because of the back- reaction of the induced currents on the external electric fields. (Oscillatory currents were also discussed in [13], though these occurred due to the periodic dynamics of the strings.)\nWhile our analysis has enabled us to fully treat back- reaction of the Schwinger process, our results cannot be transported to 3+1 QED for two reasons. First, the elec- tron has a non-zero mass. For electric fields smaller than the electron mass squared, the Schwinger process is ex- ponentially suppressed and the vacuum is essentially an insulator. In situations where the electric field is larger than the electron mass squared, the exponential suppres- sion is absent and the dynamics may be closer to what we have found. The second reason is that the larger number of dimensions can change the picture dramatically. In\n1+1 dimensions, the inter-charge potential is linear and electric charge is confined. In 3+1 dimensions, electric charges interact by the Coulomb potential and are not confined. This suggests that our system may be closer to the case of chromo-electric fields in 3+1 dimensions with massless quarks. While this has some features that re- semble the model we have considered, there are essential differences due to the non-Abelian nature of the interac- tions.\nWe thank Edward Witten for suggesting the mass- less Schwinger model for the backreaction problem, Ioan- nis M. Besieris for sharing his notes on the solution to the massive Klein-Gordon equation, and Ratin Akhoury, Daniel Green, Zohar Komargodski, Juan Maldacena, Dmitry I. Podolsky, David Shih and Yuji Tachikawa for helpful comments and discussions. We thank Peter J. Kernan and Pascal M. Vaudrevange for invaluable com- puting help. This work was supported by the U.S. De- partment of Energy at Case Western Reserve Univer- sity. TV was also supported by grant number DE-FG02- 90ER40542 at the Institute for Advanced Study.\n[1] J. S. Schwinger, Phys. Rev. 82 , 664 (1951).\n[2] Y. Kluger, J. M. Eisenberg, B. Svetitsky, F. Cooper and E. Mottola, Phys. Rev. D 45 , 4659 (1992). Y. Kluger, J. M. Eisenberg, B. Svetitsky, F. Cooper and E. Mottola, Phys. Rev. Lett. 67 , 2427 (1991). F. Cooper and E. Mottola, Phys. Rev. D 40 , 456 (1989).\n[3] E. T. Akhmedov and P. Burda, arXiv:0912.3435 [hep-th].\n[4] D. Bazeia, F. A. Brito, W. Freire and R. F. Ribeiro, Int. J. Mod. Phys. A 18 , 5627 (2003) [arXiv:hep-th/0210289].\n[5] I.S. Gradshteyn and I.M. Ryzhik Table Of Integrals, Se- ries and Products , fourth edition, Academic Press, New York (1980).\n[6] P. M. Morse and H. Feshbach, Methods of Theoretical Physics , Part II, McGraw Hill (1953), § 12.3\n[7] S. R. Coleman, R. Jackiw and L. Susskind, Annals Phys. 93 , 267 (1975); S. R. Coleman, Annals Phys. 101 , 239 (1976).\n[8] K. Fujikawa, arXiv:0902.2066 [hep-th].\n[9] C. M. Naon, Phys. Rev. D 31 , 2035 (1985).\n[10] J. von Delft and H. Schoeller, Annalen Phys. 7 , 225 (1998) [arXiv:cond-mat/9805275].\n[11] “General Relativity”, R.M. Wald, University of Chicago Press, Chicago (1984).\n[12] E. Witten, Nucl. Phys. B 249 , 557 (1985).\n[13] M. Aryal, A. Vilenkin and T. Vachaspati, Phys. Lett. B 194 , 25 (1987)."}]}
+{"image": "doclay/doclay_38360.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Form 5: Committment letter by identified subcontractor \n(To be filled in by each the identified subcontractors)\nI, the undersigned, Name:  ________________________________________________  Function:  ________________________________________________  Entity (Company):  ________________________________________________  Registered address:  ________________________________________________  VAT Number:  ________________________________________________  having the legal capacity required to act on behalf of  [insert name of the entity]  hereby confirm  that  [insert name of the entity] [please tick the box(es) which apply]  [tick this box if the identified subcontractor will carry out part of the tasks of the contract] agrees to participate as subcontractor in the tender of  [insert name of the candidate/tenderer]  for  the procurement procedure  [insert reference number]  –  [insert title of procedure and, if applicable  lot number]  and to carry out the services that will be subcontracted to it in compliance with the  terms of the contract.  [tick this box if the tenderer intends to rely on the capacity of the identified subcontractor in  order to fulfil the minimum levels required for technical and professional capacity]  authorises  [insert name of the candidate/tenderer]  to rely on its technical and professional capacity in order  to meet the minimum levels required for the procurement procedure  [insert reference number]  –  [insert title of procedure and, if applicable lot number] .  [tick this box if the tenderer intends to rely on the capacity of the identified subcontractor in  order to fulfil the minimum levels required for financial and economic capacity]  authorises  [insert name of the candidate/tenderer]  to rely on its financial and economic capacity in order to  meet the minimum levels required for the procurement procedure  [insert reference number] –  [insert title of procedure and, if applicable lot number] .  In the event that the tender of the aforementioned candidate/tenderer is successful,  [insert name  of the entity]  commits itself to make available the resources necessary for performance of the  contract. It further declares that it is not subject to conflicting interests which may negatively  affect the contract performance and that it accepts the general conditions attached to the  procurement documents for the above procurement procedure, in particular the contractual  provisions related to checks and audits. Done at:  ________________________________________________  Name: ________________________________________________  Position:  ________________________________________________  Signature:  ________________________________________________ \nPage 9 of 16 "}]}
+{"image": "doclay/doclay_50988.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "SQL Statements for Controlling Replica Servers\nREQUIRE_TABLE_PRIMARY_KEY_CHECK Enables a replica to select its own policy for primary key checks. When the option is set to  ON  for a replication channel, the replica always uses the value  ON  for the  sql_require_primary_key system variable in replication operations, requiring a primary key. When the option is set to  OFF , the replica always uses the value  OFF for the  sql_require_primary_key  system variable in replication operations, so that a primary key is never required, even if the source required one. When the  REQUIRE_TABLE_PRIMARY_KEY_CHECK option is set to  STREAM , which is the default, the replica uses whatever value is replicated from the source for each transaction. REQUIRE_TABLE_PRIMARY_KEY_CHECK  is available as of MySQL 8.0.20. For multisource replication, setting REQUIRE_TABLE_PRIMARY_KEY_CHECK  to  ON  or  OFF  enables a replica to normalize behavior across the replication channels for different sources, and keep a consistent setting for the sql_require_primary_key  system variable. Using  ON  safeguards against the accidental loss of primary keys when multiple sources update the same set of tables. Using  OFF  allows sources that can manipulate primary keys to work alongside sources that cannot. When  PRIVILEGE_CHECKS_USER  is set, setting REQUIRE_TABLE_PRIMARY_KEY_CHECK  to  ON  or  OFF  means that the user account does not need session administration level privileges to set restricted session variables, which are required to change the value of  sql_require_primary_key  to match the source’s setting for each transaction. For more information, see Section 17.3.3, “Replication Privilege Checks” . SOURCE_CONNECTION_AUTO_FAILOVER Activates the asynchronous connection failover mechanism for a replication channel if one or more alternative replication source servers are available (so when there are multiple MySQL servers or groups of servers that share the replicated data).  SOURCE_CONNECTION_AUTO_FAILOVER  is available as of MySQL 8.0.22. The asynchronous connection failover mechanism takes over after the reconnection attempts controlled by  MASTER_CONNECT_RETRY  and  MASTER_RETRY_COUNT  are exhausted. It reconnects the replica to an alternative source chosen from a specified source list, which you manage using the asynchronous_connection_failover_add_source  and asynchronous_connection_failover_delete_source functions. To add and remove managed groups of servers, use the asynchronous_connection_failover_add_managed  and asynchronous_connection_failover_delete_managed functions instead. For more information, see Section 17.4.9, “Switching Sources with Asynchronous Connection Failover” .\nImportant1. You can only set SOURCE_CONNECTION_AUTO_FAILOVER = 1  when GTID auto-positioning is in use ( MASTER_AUTO_POSITION = 1 ).\n2755"}]}
+{"image": "doclay/doclay_24605.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Faster Rates for Policy Learning\nAlexander R. Luedtke 1,2 and Antoine Chambaz 3,4\n1 Vaccine and Infectious Disease Division, Fred Hutchinson Cancer Research Center, USA\n$^{2}$Public Health Sciences Division, Fred Hutchinson Cancer Research Center, USA\n$^{3}$Modal’X, UPL, Univ Paris Nanterre, F92000 Nanterre France\n$^{4}$Division of Biostatistics, School of Public Health, UC Berkeley, USA\nThis article improves the existing proven rates of regret decay in optimal policy estimation. We give a margin-free result showing that the regret decay for estimating a within-class optimal policy is second-order for empirical risk minimizers over Donsker classes, with regret decaying at a faster rate than the standard error of an efficient estimator of the value of an optimal policy. We also give a result from the classification literature that shows that faster regret decay is possible via plug-in estimation provided a margin condition holds. Four examples are considered. In these examples, the regret is expressed in terms of either the mean value or the median value; the number of possible actions is either two or finitely many; and the sampling scheme is either independent and identically distributed or sequential, where the latter represents a contextual bandit sampling scheme.\nKeywords: individualized treatment rules; personalized medicine; policy learning; precision medicine\n1\nAbstract\narXiv:1704.06431v1 [math.ST] 21 Apr 2017"}]}
+{"image": "doclay/doclay_56481.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Spatial Convenience Functions\nFROM product; +-------------------------------+ | result | +-------------------------------+ | MULTIPOINT((28 -77)) | | MULTIPOINT((28 -77),(60 -24)) | | MULTIPOINT((60 -24),(28 -77)) | | MULTIPOINT((28 -77),(38 60)) | | MULTIPOINT((38 60),(60 -24)) | | MULTIPOINT((60 -24),(28 -77)) | +-------------------------------+\nThis function was added in MySQL 8.0.24.\nThe functions in this section provide convenience operations on geometry values.\nUnless otherwise specified, functions in this section handle their geometry arguments as follows:\n2339\n•Supported geometry argument combinations are  Point  and  Point , or  Point  and  MultiPoint (in any argument order). If at least one of the geometries is neither  Point  nor  MultiPoint , and its SRID is 0, an  ER_NOT_IMPLEMENTED_FOR_CARTESIAN_SRS  error occurs. If at least one of the geometries is neither  Point  nor  MultiPoint , and its SRID refers to a geographic SRS, an ER_NOT_IMPLEMENTED_FOR_GEOGRAPHIC_SRS  error occurs. If any geometry refers to a projected SRS, an  ER_NOT_IMPLEMENTED_FOR_PROJECTED_SRS  error occurs.\nST_Distance_Sphere()  handles its arguments as described in the introduction to this section, with these exceptions:\nIf both geometry parameters are valid  Point  or  MultiPoint  values in a geographic spatial reference system (SRS), the return value is the shortest distance between the two geometries on a sphere with the provided radius. If omitted, the default radius is equal to the mean radius, defined as (2a+b)/3, where a is the semi-major axis and b is the semi-minor axis of the SRS.\nIf both geometry parameters are valid Cartesian  Point  or  MultiPoint  values in SRID 0, the return value is shortest distance between the two geometries on a sphere with the provided radius. If omitted, the default radius is 6,370,986 meters, Point X and Y coordinates are interpreted as longitude and latitude, respectively, in degrees.\nReturns the mimimum spherical distance between  Point  or  MultiPoint  arguments on a sphere, in meters. (For general-purpose distance calculations, see the  ST_Distance()  function.) The optional radius  argument should be given in meters.\n• ST_Distance_Sphere( g1 ,  g2  [,  radius ])\n•Otherwise, the return value is non- NULL .\n•For functions that take multiple geometry arguments, if those arguments are not in the same SRS, an ER_GIS_DIFFERENT_SRIDS  error occurs.\n•If any geometry argument is a syntactically well-formed geometry in an undefined spatial reference system (SRS), an  ER_SRS_NOT_FOUND  error occurs.\n•If any geometry argument is not a syntactically well-formed geometry, an  ER_GIS_INVALID_DATA  error occurs.\n•If any argument is  NULL , the return value is  NULL .\nThese convenience functions are available:\n12.17.13 Spatial Convenience Functions"}]}
+{"image": "doclay/doclay_15148.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Any stockholder, who so requests, may obtain a printed copy of any of these documents from the Company.\nChanges in or waivers to our Code of Business Conduct and Ethical Practices involving directors and executive officers of the Company will be posted on its website.\nBoth the market for offshore drilling and production equipment and services and the Company’s business are substantially dependent on the condition of the oil and gas industry and, in particular, the willingness of oil and gas companies to make capital expenditures on exploration, drilling and production operations offshore. The level of capital expenditures has generally been dependent upon the prevailing view of future oil and gas prices, which are influenced by numerous factors affecting the supply and demand for oil and gas, including worldwide economic activity, interest rates and the cost of capital, environmental regulation, tax policies, and the ability of OPEC and other producing nations to set and maintain production levels and prices. The price of crude oil began to drop sharply during the fourth quarter of 2014. In November 2014, OPEC met and decided to continue its 30 million barrel per day production target in an effort to retain its market share. OPEC’s December 2014 and January 2015 production averaged 30.24 million barrels per day and 30.37 million barrels per day, respectively.\nProduction at this rate could produce a market oversupply which would cause prices to continue to decline amid softening demand and global economic weakness. Capital expenditures are also dependent on the cost of exploring for and producing oil and gas, the availability, expiration date and price of offshore leases, the discovery rate of new oil and gas reserves in offshore areas and technological advances. Oil and gas prices and the level of offshore drilling and production activity have historically been characterized by significant volatility.\nDeclines in oil and gas prices may adversely affect the willingness of some oil and gas companies to make capital expenditures on exploration, drilling and production operations offshore, which could have an adverse impact on the Company’s results of operations, financial position and cash flows.\nIn 2012, Brent Crude oil prices ranged between $88.69 per barrel and $128.14 per barrel with an average price of $111.57 per barrel and ended the year at $110.80 per barrel. In 2013, Brent Crude oil prices ranged between $96.84 per barrel and $118.90 per barrel with an average price of $108.56 per barrel and ended the year at $109.95 per barrel. In 2014, Brent Crude oil prices ranged between $55.27 per barrel and $115.19 per barrel with an average price of $98.97 per barrel and ended the year at $55.27 per barrel. We expect this decrease to have a significant effect on major integrated, large independent and foreign national oil and gas companies’ capital expenditure budgets. Many companies have already announced significant reductions in their 2015 capital budget plans.\nThe Company expects continued volatility in both crude oil and natural gas prices, as well as in the level of drilling and production related activities. Even during periods of high prices for oil and natural gas, companies exploring for oil and gas may cancel or curtail programs, or reduce their levels of capital expenditures for exploration and production, for a variety of reasons. A significant and prolonged decline in hydrocarbon prices would likely have a material adverse effect on the Company’s results of operations. See “Item 1A. Risk Factors—A material or extended decline in expenditures by the oil and gas industry could significantly reduce our revenue and income.”\nDril-Quip’s revenues are generated from two sources: products and services. Product revenues are derived from the sale of offshore drilling and production equipment. Service revenues are earned when the Company provides technical advisory assistance services for installation of the Company’s products, reconditioning services of its customer-owned products and rental of running tools for installation and retrieval of the Company’s products. In 2014, the Company derived 83% of its revenues from the sale of its products and 17% of its revenues from services compared to 84% and 16% in 2013 and 83% and 17% in 2012, respectively.\nProducts and Services\n6\nOverview and Industry Outlook"}]}
+{"image": "doclay/doclay_44876.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "BACK EXEC XPND$^{Modify}$ Wpt Arwy Library KSQL SUNOL  21.7 ECA  55.0 027  21.7 DIST V195   33.3 BRG 060°   21.7 discontinuity BRG ---   --- FPL n m n m n m GPS ENR FLAGGED 119.000 121.600 114.10 116.00 1200 A  C  T A  C  T S  B  Y S  B  Y S  B  Y --.- vor BACK EXEC XPND Active KSQL 027 SUNOL  21.7 ECA  55.0 027  73.3 No Active Leg DIST ETE BRG 060°   21.7 V195   33.3 BRG 049°   18.3 FPL n m n m n m GPS ENR FLAGGED 119.000 121.600 114.10 116.00 1200 A  C  T A  C  T S  B  Y S  B  Y S  B  Y --.- vor route discontinuity appears when the  FMS cannot proceed from one waypoint  to the next. A route discontinuity can  simply be deleted. S B S B When a route discontinuity is deleted,  the FMS proceeds directly to the next  waypoint in the programmed route.\nFigure 3-15. A route discontinuity and deletion.\nwas selected in the FMS. Every advanced cockpit offers  buttons or switches that allow you to choose which navigation  indications will be shown on which display or instrument.\nThis situation becomes complicated in aircraft that contain  dual FMS/RNAV installations and redundant selectable  displays or instruments. The pilot must learn how to configure  each navigation instrument to show indications from each  possible navigation source.\nFigure 3-16  shows an example of a primary flight display  (PFD) navigation indicator that combines a course deviation  indicator (CDI) and a radio magnetic indicator (RMI), and  allows the pilot to display indications from one of two FMS  on either indicator.\nThe annunciations showing which navigation sources are  displayed on which navigation instruments are often small, so  there is significant potential for displaying a navigation source  other than the one you intended to select. The consequences  of losing track of which navigation signals you are following \ncan be significant: you may think you are steering along one  course when in fact you are steering along a different one.  Be sure to verify these settings prior to departure, and again  each time you make changes to any navigation instrument.  Some installations compound this potential with automatic  source switching. The most common switching mode is a  GPS source to be automatically deselected when the VOR  is set to an ILS localizer frequency and a signal is present.  Typically, that is not a problem since the pilot intends to  switch to the ILS anyway. However, the error arises upon  missed approach, when the pilot selects another frequency  to follow a VOR missed approach routing. At that point,  some units revert back to the previous GPS or other RNAV  routing selected instead of the VOR frequency that the  pilot just picked. This can result in gross navigation errors  and loss of obstruction clearances. In some units, this is a  shop programmable or jumper selected option. Check your  unit’s features. Always check for correct navigation source  selection and cross‑check against the published procedure.  Be ready and able to fly and navigate manually.\nCommon Error: Displaying the Wrong Navigation  Source\n3-12"}]}
+{"image": "doclay/doclay_68368.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Notices\nThis information was developed for products and services offered in the US. This material might be available from  IBM in other languages. However, you may be required to own a copy of the product or product version in that  language in order to access it. \nIBM may not offer the products, services, or features discussed in this document in other countries. Consult your local  IBM representative for information on the products and services currently available in your area. Any reference to an  IBM product, program, or service is not intended to state or imply that only that IBM product, program, or service may  be used. Any functionally equivalent product, program, or service that does not infringe any IBM intellectual property  right may be used instead. However, it is the user's responsibility to evaluate and verify the operation of any non-IBM  product, program, or service.\nIBM may have patents or pending patent applications covering subject matter described in this document. The  furnishing of this document does not grant you any license to these patents. You can send license inquiries, in writing,  to: \nIBM Director of Licensing, IBM Corporation, North Castle Drive, MD-NC119, Armonk, NY 10504-1785, US\nINTERNATIONAL BUSINESS MACHINES CORPORATION PROVIDES THIS PUBLICATION “AS IS” WITHOUT  WARRANTY OF ANY KIND, EITHER EXPRESS OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED  WARRANTIES OF NON-INFRINGEMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.  Some jurisdictions do not allow disclaimer of express or implied warranties in certain transactions, therefore, this  statement may not apply to you.\nThis information could include technical inaccuracies or typographical errors. Changes are periodically made to the  information herein; these changes will be incorporated in new editions of the publication. IBM may make  improvements and/or changes in the product(s) and/or the program(s) described in this publication at any time without  notice.\nAny references in this information to non-IBM websites are provided for convenience only and do not in any manner  serve as an endorsement of those websites. The materials at those websites are not part of the materials for this IBM  product and use of those websites is at your own risk.\nIBM may use or distribute any of the information you provide in any way it believes appropriate without incurring any  obligation to you.\nThe performance data and client examples cited are presented for illustrative purposes only. Actual performance  results may vary depending on specific configurations and operating conditions.\nInformation concerning non-IBM products was obtained from the suppliers of those products, their published  announcements or other publicly available sources. IBM has not tested those products and cannot confirm the  accuracy of performance, compatibility or any other claims related to non-IBM products. Questions on the capabilities  of non-IBM products should be addressed to the suppliers of those products.\nStatements regarding IBM's future direction or intent are subject to change or withdrawal without notice, and represent  goals and objectives only.\nThis information contains sample application programs in source language, which illustrate programming techniques  on various operating platforms. You may copy, modify, and distribute these sample programs in any form without  payment to IBM, for the purposes of developing, using, marketing or distributing application programs conforming to  the application programming interface for the operating platform for which the sample programs are written. These  examples have not been thoroughly tested under all conditions. IBM, therefore, cannot guarantee or imply reliability,  serviceability, or function of these programs. The sample programs are provided “AS IS”, without warranty of any kind.  IBM shall not be liable for any damages arising out of your use of the sample programs.\n© Copyright International Business Machines Corporation 2018-2019. All rights reserved.\nThis information contains examples of data and reports used in daily business operations. To illustrate them as  completely as possible, the examples include the names of individuals, companies, brands, and products. All of these  names are fictitious and any similarity to actual people or business enterprises is entirely coincidental.\nCOPYRIGHT LICENSE:\nIBM Storage Networking SAN128B-6 Switch\n9"}]}
+{"image": "doclay/doclay_48502.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\n- Seite 5 von 10 -"}]}
+{"image": "doclay/doclay_40128.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Contract number: [ complete ] \nService contract conditions of December 2018 \nInterest on late payment  II.23.3.\nRecovery rules in the case of joint tender  II.23.4.\nCHECKS AND AUDITS  II.24.\nIf the contractor does not honour the obligation to pay the amount due by the date set by the  contracting authority in the debit note, the amount due bears interest at the rate indicated in  Article II.21.8. Interest on late payments will cover the period starting on the day after the due  date for payment and ending on the date when the contracting authority receives the full  amount owed.\nAny partial payment is first entered against charges and interest on late payment and then  against the principal amount. \nIf the contract is signed by a group (joint tender), the group is jointly and severally liable  under the conditions set out in Article II.6 (liability). The contracting authority shall send the  debit note first to the leader of the group.\nIf the leader does not pay by the due date the whole amount, and if the amount due cannot be  offset or can only be offset partially in accordance with Article II.23.2 (a), then the  contracting authority may claim the amount still due to any other member or members of the  group by respectively  notifying  them with a debit note in conformity with the provisions laid  down in Article II.23.2.\nSuch checks and audits may be initiated at any moment during the  performance of the  contract  and up to five years starting from the payment of the balance.\nThe audit procedure is initiated on the date of receipt of the relevant letter sent by the  contracting authority. Audits are carried out on a confidential basis. \nII.24.4  On the basis of the findings made during the audit, a provisional report is drawn up.  The contracting authority or its authorised representative must send it to the  contractor, who has 30 days following the date of receipt to submit observations. The \nII.24.3  The contractor must grant the contracting authority’s staff and outside  personnel authorised by the contracting authority the appropriate right of access to sites and  premises where the contract is performed and to all the information, including  information in electronic format, needed to conduct such checks and audits. The  contractor must ensure that the information is readily available at the moment of the  check or audit and, if so requested, that information is handed over in an appropriate  format.\nII.24.2  The contractor must keep all original documents stored on any appropriate medium,  including digitised originals if authorised under national law, for a period of five years  starting from the payment of the balance.\nII.24.1  The contracting authority and the European Anti-Fraud Office may check or require an  audit on the  performance of the contract . This may be carried out either by OLAF’s  own staff or by any outside body authorised to do so on its behalf.\n37 "}]}
+{"image": "doclay/doclay_9858.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "We have audited the accompanying consolidated balance sheets of The Estée Lauder Companies Inc. (a Delaware corporation)and subsidiaries as of June 30, 2001 and 2000, and the related consolidated statements of earnings, stockholders’ equity and comprehensive income and cash flows for each of the three years in the period ended June 30, 2001. These financial statements are the responsibility of the Company’s management. Our responsibility is to express an opinion on these financial statements based on our audits.\nTo The Estée Lauder Companies Inc.:\nWe conducted our audits in accordance with auditing standards generally accepted in the United States. Those  standards require that we plan and perform the audit to obtain reasonable assurance about whether the financial statements are free of material misstatement. An audit includes examining, on a test basis, evidence supporting  the amounts and disclosures in the financial statements. An audit also includes assessing the accounting principles used and significant estimates made by management, as well as evaluating the overall financial statement presentation. We believe that our audits provide a reasonable basis for our opinion.\nIn our opinion, the financial statements referred to above present fairly, in all material respects, the financial position of The Estée Lauder Companies Inc. and subsidiaries as of June 30, 2001 and 2000, and the results of their operations and their cash flows for each of the three years in the period ended June 30, 2001 in conformity with accounting principles generally accepted in the United States.This is a copy of the audit report previously issued by Arthur Andersen LLP in connection with our filing on Form 10-K  for the fiscal year ended June 30, 2001. This audit report has not been reissued by Arthur Andersen LLP in connection  with this filing on Form 10-K. See Exhibit 23.2 for further discussion.\nNew York, New York August 10, 2001\nREPORT OF INDEPENDENT PUBLIC ACCOUNTANTS\n83\nTHEEST{E LAUDER COMPANIES INC."}]}
+{"image": "doclay/doclay_69405.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "cloudctl catalog load-archive --archive nfs-client-provisioner-bundle.tgz  --registry mycluster.icp:8500/kube-system --repo mgmt-charts --username  admin --password super_secure_password\nNote:  If you are using macOS, add  --username value  and  --password value , or set  these values in the environment as  DOCKER_USER  and  DOCKER_PASSWORD .\nExample 2-2 shows typical output for this command.\ncloudctl catalog load-archive --archive nfs-client-provisioner-bundle.tgz  --registry <cluster_CA_domain>:8500/kube-system --repo mgmt-charts\nExample 2-2 Output of the command\nExpanding archive OK Importing docker image(s) Processing image: nfs-client-provisioner-s390x:latest Loading Image Tagging Image Pushing image as:  mycluster.icp:8500/kube-system/nfs-client-provisioner-s390x:latest ... Uploading helm chart(s) Processing chart: charts/nfs-client-provisioner-multiarch-2.tgz Updating chart values.yaml Uploading chart Loaded helm chart OK Synch charts Synch started OK\nd. Click  Catalog  in the IBM Cloud Private console, and then search for  nfs-client . If the  import was successful, the  nfs-client  tile is visible on the IBM Cloud Private Catalog  page as in Figure 2-5.\nChapter 2. Planning for installation  29"}]}
+{"image": "doclay/doclay_23091.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "PART II ITEM 8 Financial Statements and Supplementary Data\nCigna Corporation Consolidated Balance Sheets\nAs of December 31, (In millions, except per share amounts) 2012 2011 ASSETS Investments: Fixed maturities, at fair value (amortized cost, $15,481; $14,257) $ 17,705 $ 16,217 Equity securities, at fair value (cost, $121; $124) 111 100 Commercial mortgage loans 2,851 3,301 Policy loans 1,501 1,502 Real estate 83 87 Other long-term investments 1,255 1,058 Short-term investments 154 225 Total investments 23,660 22,490 Cash and cash equivalents 2,978 4,690 Accrued investment income 258 252 Premiums, accounts and notes receivable, net 1,777 1,358 Reinsurance recoverables 6,256 6,256 Deferred policy acquisition costs 1,198 817 Property and equipment 1,120 1,024 Deferred income taxes, net 374 803 Goodwill 6,001 3,164 Other assets, including other intangibles 2,355 1,750 Separate account assets 7,757 8,093 TOTAL ASSETS $ 53,734 $ 50,697 LIABILITIES Contractholder deposit funds $ 8,508 $ 8,553 Future policy benefits 9,265 8,593 Unpaid claims and claim expenses 4,062 3,936 Global Health Care medical claims payable 1,856 1,305 Unearned premiums and fees 549 502 Total insurance and contractholder liabilities 24,240 22,889 Accounts payable, accrued expenses and other liabilities 6,667 6,627 Short-term debt 201 104 Long-term debt 4,986 4,990 Separate account liabilities 7,757 8,093 TOTAL LIABILITIES 43,851 42,703 Contingencies — Note 24 Redeemable noncontrolling interest 114 - SHAREHOLDERS’ EQUITY Common stock (par value per share, $0.25; shares issued, 366; authorized, 600) 92 92 Additional paid-in capital 3,295 3,188 Net unrealized appreciation, fixed maturities $ 883 $ 739 Net unrealized appreciation, equity securities 4 1 Net unrealized depreciation, derivatives (28) (23) Net translation of foreign currencies 69 3 Postretirement benefits liability adjustment (1,599) (1,507) Accumulated other comprehensive loss (671) (787) Retained earnings 12,330 10,787 Less: treasury stock, at cost (5,277) (5,286) TOTAL SHAREHOLDERS’ EQUITY 9,769 7,994 Total liabilities and equity $ 53,734 $ 50,697 SHAREHOLDERS’ EQUITY PER SHARE $ 34.18 $ 28.00\nThe accompanying Notes to the Consolidated Financial Statements are an integral part of these statements.\n66 CIGNA CORPORATION -  2012 Form  10-K"}]}
+{"image": "doclay/doclay_39871.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Contract number: ECHA/2020/724  Restricted \nService contract conditions of December 2018 \nContractor (or leader in the case of a joint tender):  [ Full name ]  Function [ Company name ]  Full official address ]  E-mail: [ complete ] \nThe following provisions supersede Article II.13 and apply to the use of the solution/product  licensed to the contracting authority, as such databases or data are described in the  technical specifications, in the tender of the contractor or in any other documentation  provided by the contractor and agreed to by the contracting authority. \n(a) the data controller is the Agency. ECHA is the sole controller of the data processing  and the contractor and its partners or subcontractors may act as processor only  under the instructions of the controller and cannot process the data further for their  own purposes;  (b) the data protection notice is available at \nown purposes;  (b) the data protection notice is available at  https://www.echa.europa.eu/documents/10162/13612/annex2_privacy_stateme nt_procurement_procedures_en.pdf/ed81cf95-4056-4bdf-adb5-c0f1bd0d57a5 \n(a) the subject matter and purpose of the processing of personal data by the contractor  are the provision of the unlimited and interactive database and the originals  documents when requested; \n(b) The localisation of and access to the personal data processed by the contractor shall  comply with the following:  i. the personal data shall only be processed within the territory of the European \ncomply with the following:  i. the personal data shall only be processed within the territory of the European  Union and the European Economic Area and will not leave that territory;  ii. the data shall only be held in data centres located with the territory of the \nUnion and the European Economic Area and will not leave that territory;  ii. the data shall only be held in data centres located with the territory of the  European Union and the European Economic Area;  iii. no access shall be given to such data outside of [the European Union and \nEuropean Union and the European Economic Area;  iii. no access shall be given to such data outside of [the European Union and  the European Economic Area;  iv. the contractor may not change the location of data processing without the \nthe European Economic Area;  iv. the contractor may not change the location of data processing without the  prior written authorisation of the contracting authority;  v. any transfer of personal data under the contract to third countries or \nprior written authorisation of the contracting authority;  v. any transfer of personal data under the contract to third countries or  international organisations shall fully comply with the requirements laid  down in Chapter V of Regulation (EU) 2018/1725 3 . \n3 Regulation (EU) 2018/1725 of 23 October 2018 on the protection of natural persons with regard to the  processing of personal data by the Agency institutions, bodies, offices and agencies and on the free  movement of such data, and repealing Regulation (EC) No 45/2001 and Decision No 1247/2002/EC, OJ L  295/39,21.11.2018,  https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:32018R1725&from=EN  4 This article must be adapted with care. All information is in the Explanatory note on IPR on: \nhttps://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:32018R1725&from=EN  4 This article must be adapted with care. All information is in the Explanatory note on IPR on:  http://myintracomm.ec.testa.eu/budgweb/EN/imp/procurement/Documents/ipr-note-en.pdf \n7 \nI.10. EXPLOITATION OF THE RESULTS OF THE CONTRACT 4\nI.9.2  Processing of personal data by the contractor  For the purpose of Article II.9.2,\nI.9.1  Processing of personal data by the contracting authority  For the purpose of Article II.9.1,\nI.9. PROCESSING OF PERSONAL DATA \nI.9.1  Processing of personal data by the contracting authority  For the purpose of Article II.9.1,\nI.9.2  Processing of personal data by the contractor  For the purpose of Article II.9.2,"}]}
+{"image": "doclay/doclay_8985.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "To keep The Har tford’s par tnership with our customers  and agents working as efficiently and effortlessly as possible,  we expanded our web-based  Electronic Business Center . \nThis resource center makes it easier to provide small business customers with the fastest service, best pricing and most effec- tive coverage.\nThe Electronic Business Center allows agents to view bill- ing, claims and policies online, as well as process endorsement requests on the spot.\nThrough the Electronic Business Center, agents can access  a web-based tool, called “Icon 2.0,” which allows them to sub- mit business inquiries and obtain quotes quickly and efficiently\nThroughout its 115-year history, The Hartford Conservatory has  provided a nurturing environment for emerging performing artists such as, from left to right,  Mario Santos ,  Jordan Bartucca and  David Hiestand .\nLocated in the same Asylum  Hill neighborhood as The Hartford Financial Services Group, the Conservatory found its best insur- ance coverage with The Hartford. Pat Priest, an agent with the Webster Insurance Agency of Wallingford, CT, notes that as a non-profit organization, having  the right coverage at the right  cost is critical to the Conser- vatory. “The Hartford was able  to provide that,” Pat points out.\nJackie Rowley, Director of Finance for the Conservatory, is pleased to “have everything with one company. It’s a lot easier for us and The Hartford has such a good reputation.”\nPat notes that, from the agent’s point of view, “the ease of working with The Hartford’s online quote system is a plus. It offers immediate underwriting guidelines for quotes, is quick and precise, and includes broad coverages for each client’s needs.”\n  reality from students’ dreams23\n21 % premium growth in small business insurance, from 2003"}]}
+{"image": "doclay/doclay_45998.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "received. A thorough preflight and route planning needs to  be accomplished. This planning also includes ridge selection  based on the current winds. The horizontal distance from the  ridge varies with height above the ridge, since the best lift  zone, or optimum lift zones (OLZ) tilts upwind with height  above the ridge. These zones, or OLZ, vary but usually are  slightly off the top of the ridge, with a slight angle into the  prevailing wind. The bottom of the OLZ may be slightly down  from the top line under normal conditions. These OLZ vary  with the size and terrain makeup of the ridge.  [Figure 10-14]\nExceptions to normal or typical thermals are numerous. For  instance, instead of stronger sink at the edge of a thermal,  weak lift sometimes continues for a distance after leaving a  thermal. Glider pilots should be quick to adapt to whatever the  air has to offer at the time. The mechanics of simply flying the  glider become second nature with practice, as do thermaling  techniques. Expect to land early because anticipated lift was  not there on occasion—it is part of the learning curve.\nIf thermal waves are suspected, climb in the thermal near  cloud base, then head toward the upwind side of the Cu.  Often, only very weak lift, barely enough to climb at all, is  found in smooth air upwind of the cloud. Once above cloud  base and upwind of the Cu, climb rates of a few hundred fpm  can be found. Climbs can be made by flying back and forth  upwind of an individual Cu, or by flying along cloud streets if  they exist. If no clouds are present, but waves are suspected,  climb to the top of the thermal and penetrate upwind in search  of smooth, weak lift. Without visual clues, thermal waves  are more difficult to work. Thermal waves are most often  stumbled upon as a pleasant surprise.\nEfficient slope soaring (also called ridge soaring or ridge  running) is fairly easy; simply fly in the updraft along the  upwind side of the ridge. Although the appearance may seem  simple, it is very complicated and can be very hazardous for  the untrained glider pilot. Ridge soaring can also be very  demanding on the glider and the pilot. Even though it is  easy to fly, there are many situations in which a glider pilot  can be exposed to hazards if proper training has not been \nSurface winds of 15–20 knots that are perpendicular to the  ridge are ideal. Wind flow within 45° of the perpendicular  line also provides adequate lift. Winds less than 10 knots  have also produced adequate ridge soaring dependent on  the terrain, but with 10 knots of wind or less, pilots should  avoid flying low over any ridge due to the possibility of  encountering sink. Local ridge pilots know about of these  conditions and the need for good preflight planning and  training is required.  [Figure 10-15]\nEven though the idea is simple, traps exist for both new and  expert glider pilots. Obtain instruction when first learning to  ridge soar/slope soar. Avoid approaching from the upwind  side perpendicularly to the ridge. Instead, approach the ridge \n•  Airflow mirrors a hill or ridge shape. Imagine a flow of  water around the ridge instead of air. However, air is  thinner and can be compressed as in a “venturi effect”  and can be “squeezed” and accelerated, especially  along the ridge.  [Figure 10-16]\n•  Ridges that have an irregular profile are hazardous.  The more complicated the ridge is, the more erratic  the airflow may become.  [Figure 10-17]\nRidge/Slope Soaring\nAtypical Thermals\nFigure 10-14.  Optimum lift zone of a ridge.\nFigure 10-13.  When thermaling, avoid flying in another glider’s  blind spot, or directly above or below another glider.\nTraps $_{W}$ind  Optimum lift zones (OLZ)\n10-10"}]}
+{"image": "doclay/doclay_462.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\n65\nNOTE 14 — PROPERTY TRANSACTIONS, NET\nProperty transactions, net consisted of the following:\nIn 2004, there were no material unusual property transactions. In 2003 the Company sold 315 acres of land in North Las Vegas, Nevada near Shadow Creek for approximately $55 million, which resulted in a pretax gain of approximately $37 million. Also in 2003, the Company recorded write-downs and impairments of assets abandoned or replaced with new construction, primarily at MGM Grand Las Vegas in preparation for new restaurants and the new theatre. Prior to 2003, the Company classified gains and losses on routine asset sales or disposals as a  non-operating item at some resorts and as an operating item at other resorts. Management believes the preferable presentation of these items is as an element of operating income. Prior period statements have not been reclassified as such transactions were not material in the prior periods. Until 2003, demolition costs were typically capitalized as part of new construction. The Company began  expensing demolition costs on major construction projects as incurred on January 1, 2003, and is accounting for this change in policy prospectively. Demolition costs were not material in prior periods. Demolition costs in 2004 and 2003 relate  primarily to preparation for the Bellagio standard room remodel, Bellagio expansion and new theatre at MGM Grand Las Vegas.\nAt December 31, 2004, the Company owed $2 million for legal fees to a firm  affiliated with one of the Company’s directors. The Company also engaged in  transactions with its unconsolidated affiliates. In each of 2004 and 2003, the Company paid Monte Carlo $4 million as a result of closing the tram between Bellagio and Monte Carlo in preparation for the Bellagio expansion. The Company leases two acres of land to Borgata and received $1 million in each of 2004, 2003 and 2002 under this lease. Borgata is required to pay for a portion of the master- plan improvements at Renaissance Pointe, and the Company is responsible for  environmental cleanup costs incurred by Borgata. The net amount reimbursed to the Company under these arrangements for the years ended December 31, 2004, 2003 and 2002 was $1 million, $10 million and $8 million, respectively.\nThe Company’s related party transactions consisted of the following revenues (expenses):\nIn 2002, Tropical Storm Isidore caused property damage at Beau Rivage totaling $8 million, including clean-up costs. The amount of the write-down for damaged assets was determined based on the net book value of the assets and engineering estimates. In connection with the revised development agreement in Detroit, the Company wrote off $5 million, which was the net book value of previously incurred develop- ment costs associated with the riverfront permanent casino site ($9 million), offset by previously accrued obligations no longer required under the revised development agreement ($4 million). Also in 2002, the Company recorded write-downs and impairments of assets abandoned or replaced with new construction.\nNOTE 15 — RELATED PARTY TRANSACTIONS\nY ear Ended December 31 (In thousands) 2004 2003 2002 Gain on sale of North Las Vegas land . . . . . . . . . . . . .  $ — $ (36,776) $ — Siegfried & Roy theatre write-down – The Mirage . . . .  — 1,408 — Storm damage – Beau Rivage . . . . . . . . . . . . . . . . . .  — — 7,824 Write-off of Detroit development costs. . . . . . . . . . . . .  — — 4,754 Impairment of assets to be disposed of. . . . . . . . . . . .  473 5,764 2,134 Demolition costs. . . . . . . . . . . . . . . . . . . . . . . . . . . . .  7,057 6,614 — Other net losses on asset sales or disposals . . . . . . . .  1,135 4,049 — $ 8,665 $ (18,941) $ 14,712\nY ear Ended December 31 (In thousands) 2004 2003 2002 Hotel and other revenue from related parties . . . . . . .  $ 416 $ 871 $ 764 License fees to entities under common ownership . . .  (1,000) (1,000) (1,000) Professional fees to directors or firms  affiliated with directors. . . . . . . . . . . . . . . . . . . . . . (4,084) (1,551) (1,815) Other related party expenses . . . . . . . . . . . . . . . . . . .  (62) (468) (224) $ (4,730) $ (2,148) $ (2,275)"}]}
+{"image": "doclay/doclay_67342.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "– Mirror pools:\n– aio_cache logical volumes\nMirror pools make it possible to divide the physical volumes of a VG into separate  pools.\nA mirror pool is made up of one or more physical volumes. Each physical volume can  belong to only one mirror pool at a time. When creating a logical volume, each copy of  the logical volume being created can be assigned to a mirror pool. Logical volume  copies that are assigned to a mirror pool allocate only partitions from the physical  volumes in that mirror pool, which can restrict the disks that a logical volume copy can  use. \nWithout mirror pools, the only way to restrict which physical volume is used for  allocation when creating or extending a logical volume is to use a map file. Thus, using  mirror pools greatly simplify this process. Think of mirror pools as an  operating-system-level feature similar to storage consistency groups that are used  when replicating data.\nAlthough mirror pools are an AIX and not a GLVM-specific component, it is a best  practice to use them in all GLVM configurations. However, they are required only when  configuring asynchronous mode of GLVM.\nAn aio_cache is a special type of logical volume that stores write requests locally while  it waits for the data to be written to a remote disk. The size of this logical volume  dictates how far behind the data is allowed to be between the two sites. There is one  defined at each site and they are  not  mirrored. Similar to data volumes, these volumes  must be protected locally, usually by some form of RAID.\nFigure 7-1 on page 269 shows a relatively basic two-site GLVM implementation. It consists of  only one node at each site, although PowerHA does support multiple nodes within a site.\nThe New York site is considered the primary site because its node primarily hosts RPV  clients. The Texas site is the standby site because it primarily hosts RPV servers. However,  each site contains both RPV servers and clients based on where the resources are running.\nEach site has two data disk volumes that are physically associated with the site node. In this  case, the disks are hdisk1 and hdisk2 at both sites. However, the hdisk names do not need to  match across sites. These two disks are also configured as RPV servers on each node. In  turn, these are logically linked to the RPV clients at the opposite site. This configuration  creates two more pseudo-device disks that are known as hdisk3 and hdisk4. Their associated  disk definitions clearly state that they are RPV clients and not real physical disks.\nGLVM example \n268  IBM PowerHA SystemMirror V7.2.3 for IBM AIX and V7.2.2 for Linux"}]}
+{"image": "doclay/doclay_30035.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "than those following from the measurements of Ref. [23]. The advantage of the constraints of Ref. [57] is that they are obtained at a high confidence level, whereas the confidence level of the constraints obtained from the data of Ref. [23] cannot be determined on a solid basis.\nVII. CONCLUSIONS AND DISCUSSION\nIn the foregoing we have considered constraints on the Yukawa-type corrections to New- tonian gravity in micrometer and submicrometer interaction ranges following from the mea- surements of the Casimir and Casimir-Polder forces. This field of research has already re- ceived wide recognition as an important adjunct to the gravitational experiments of E¨ otvos- and Cavendish-type. Novel constraints on the parameters of Yukawa-type interactions from the Casimir effect were obtained at a high confidence level and were used for constrain- ing masses of predicted light elementary particles and other parameters of the theory of fundamental interactions beyond the Standard Model [58].\nIn this paper we have analyzed several experiments on measuring the Casimir and Casimir-Polder force which were not used up to date for constraining corrections to Newto- nian gravity. The most striking result obtained above is that recent experiment on measuring the lateral Casimir force between corrugated surfaces of a sphere and a plate [38] leads to a great strengthening of the previously known high confidence constraints up to a factor of 2 . 4 × 10 $^{7}$. The constraints obtained from this experiment are shown to be the strongest in the interaction range from 1.6 to 14 nm. This raises a question on the role of corrugated surfaces in other experimental configurations used to obtain constraints on the parameters of Yukawa-type interactions.\nThe influence of sinusoidal corrugations on the Yukawa force was calculated above by using the approximate method of geometrical averaging. This method is applicable under several conditions which are well satisfied for the experimental configurations considered in the paper. In fact, the geometrical averaging works better for the Yukawa force than for the Casimir force. The point is that the Yukawa force is static and is not influenced by the diffraction-type effects which are essential for the Casimir force (the better applicability of the geometrical averaging to the electrostatic than to the Casimir force was also noted in Ref. [38]). We have shown that the replacement of a plane plate with a sinusoidally corrugated plate in the experiment on measuring the normal Casimir force in a sphere-plate\n19"}]}
+{"image": "doclay/doclay_7058.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Consolidated Statements of Earnings\nIn thousands except share data Years ended December 31, 2002 2001 2000 Revenues: Airfreight $ 1,206,057 971,980 1,053,461 Ocean freight and ocean services 728,174 590,684 542,411 Customs brokerage and import services 362,672 320,406 310,854 Total revenues 2,296,903 1,883,070 1,906,726 Operating Expenses: Airfreight consolidation 921,103 717,478 828,033 Ocean freight consolidation 564,060 451,803 427,437 Customs brokerage and import services 129,527 107,253 102,901 Salaries and related costs 359,769 325,545 290,581 Rent and occupancy costs 40,816 36,294 29,253 Depreciation and amortization 22,725 23,544 22,481 Selling and promotion 19,796 20,163 20,231 Other 68,098 54,973 58,285 Total operating expenses 2,125,894 1,737,053 1,779,202 Operating income 171,009 146,017 127,524\n38 expd 02 Earnings"}]}
+{"image": "doclay/doclay_5031.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "For the years ended December 31, 2002 and 2001 (expressed in thousands of dollars)\ndf, Westshore Terminals Ltd. Statements of Earnings and Deficit\ndf, Westshore Terminals Ltd. Statements of Earnings and Deficit\n2002 2001 $ $ Revenue Coal 109,581 126,186 Other 2,085 879 111,666 127,065 Expenses Operating 52,445 61,922 Administrative 5,867 6,286 58,312 68,208 Earnings before depreciation, interest and income taxes 53,354 58,857 Depreciation 10,201 10,023 Interest expense (note 3) 43,865 50,164 Loss before income taxes (712) (1,330) Recovery of income taxes (note 5) 1,543 3,378 Net earnings for the year 831 2,048 Deficit - Beginning of year (569,966) (572,014) Deficit - End of year (569,135) (569,966)\n19"}]}
+{"image": "doclay/doclay_35577.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "9\n0 0,5 1 1,5 2 Λ 0 0,1 0,2 0,3 0,4 0,5 0,6 φ$^{0}$ Experiment,  Δ =0.15 Experiment,  Δ =0.24 Experiment,  Δ =0.42 Present Theory,  Δ =0.15 Present Theory,  Δ =0.24 Present Theory,  Δ =0.42 Lebedev  et al.  Theory TT inclination angle for C$_{a}$=100\nFigure 6: inclination angle of vesicles in TT phase for large C$_{a}$.\n+ b$_{5}$∂$_{i}$f$_{2}$∂$_{ij}$E$_{2}$∂$_{j}$f$_{2}$ + b$_{6}$E$_{2}$f$_{4}$ ) + O ( ε $^{3}$) , F$_{4}$ = ε ( c$_{1}$f$_{4}$ + c$_{2}$f 2 $_{2}$) + ε $^{2}$( c$_{3}$f 3 2 + c$_{4}$f$_{2}$f$_{4}$ )+\n+ εd$_{1}$E$_{2}$f$_{2}$ + ε $^{2}$( d$_{2}$f$_{4}$E$_{2}$ + d$_{3}$f 2 $_{2}$E$_{2}$ + d$_{5}$f$_{2}$∂$_{i}$E$_{2}$∂$_{i}$f$_{2}$ )+ O ( ε $^{3}$) .\nThe coefficients are then written as\na$_{1}$ = − 24 Z$_{0}$ + 6¯ κ 23 λ + 32 a$_{2}$ = 24 (49 λ + 136) Z$_{0}$ + (432 λ + 1008)¯ κ (23 λ + 32) 2 b$_{1}$ = 120 23 λ + 32 b$_{2}$ = 2400 λ − 2 (23 λ + 32) 2 b$_{6}$ = − 40 241 λ + 344 (23 λ + 32) 2 c$_{1}$ = − 40 Z$_{0}$ + 20¯ κ 19 λ + 20 c$_{2}$ = 16 3 $^{(92}$− 3 λ ) Z$_{0}$ + (1822 λ + 3112)¯ κ (19 λ + 20)(23 λ + 32) d$_{1}$ = 20 3 1047 λ + 1072 (23 λ + 32)(19 λ + 20) d$_{2}$ = 10 257 λ − 32 (23 λ + 32)(19 λ + 20) d$_{3}$ = 1 $_{6}$− 125055 λ $^{3}$+ 594716 λ $^{2}$+ 1107168 λ + 392320 (2 λ + 5)(23 λ + 32)(19 λ + 20) 2\na$_{3}$ = − 8 175 (2479595 λ $^{3}$+ 6703156 λ $^{2}$+ 18601472 λ + 16622592 (23 λ + 32) $^{3}$(19 λ + 20) $^{Z$_{0}$}$− − 8 175 78181390 λ $^{3}$+ 390845256 λ $^{2}$+ 713624832 λ + 429094912 (23 λ + 32) $^{3}$(19 λ + 20) ¯ κ\nF$_{2}$ = a$_{1}$f$_{2}$ + εa$_{2}$f 2 $_{2}$+ ε $^{2}$( a$_{3}$f 3 $_{2}$+ a$_{4}$f$_{2}$f$_{4}$ )+ b$_{1}$E$_{2}$ + εb$_{2}$E$_{2}$f$_{2}$ + + ε $^{2}$( b$_{3}$f$_{2}$∂$_{i}$f$_{2}$∂$_{i}$E$_{2}$ + b$_{4}$∂$_{i}$f$_{2}$∂$_{ij}$f$_{2}$∂$_{j}$E$_{2}$ +\nphase border in a quite large range of the capillary num- ber.\nWe hope that this work will incite future experimental research. It will also be interesting to investigate ex- perimentally the presence of widening of the VB band as a function of shear rate. Finally, we did not in- clude third order spherical harmonics in the expansion of the shape function, restricting our calculations only to centro-symmetric vesicles. In the full numerical simu- lation [16], no symmetry restriction is imposed and so far no manifestation of the third order harmonic has been observed. This confers to our assumption of centro- symmetry a certain legitimacy.\nAcknowledgements: We would like to thank G. Danker, S. S. Vergeles, and P. M. Vlahovska for helpful discussions. A.F. and C.M. acknowledge financial sup- port from CNES (Centre National D’études Spatiales) and ANR (Agence Nationale pour la Recherche); \"MOSI- COB project\".\nAppendix A: The shape evolution equations and the expression of various coefficients in terms of physical parameters\nWe remind that"}]}
+{"image": "doclay/doclay_53393.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Selecting General Query Log and Slow Query Log Output Destinations\nMySQL Server has several logs that can help you find out what activity is taking place.\nBy default, no logs are enabled, except the error log on Windows. (The DDL log is always created when required, and has no user-configurable options; see The DDL Log.) The following log-specific sections provide information about the server options that enable logging.\nBy default, the server writes files for all enabled logs in the data directory. You can force the server to close and reopen the log files (or in some cases switch to a new log file) by flushing the logs. Log flushing occurs when you issue a  FLUSH LOGS  statement; execute  mysqladmin  with a  flush-logs or  refresh  argument; or execute  mysqldump  with a  --flush-logs  or  --master-data  option. See Section 13.7.8.3, “FLUSH Statement” , Section 4.5.2, “mysqladmin — A MySQL Server Administration Program” , and Section 4.5.4, “mysqldump — A Database Backup Program” . In addition, the binary log is flushed when its size reaches the value of the  max_binlog_size  system variable.\nYou can control the general query and slow query logs during runtime. You can enable or disable logging, or change the log file name. You can tell the server to write general query and slow query entries to log tables, log files, or both. For details, see Section 5.4.1, “Selecting General Query Log and Slow Query Log Output Destinations” , Section 5.4.3, “The General Query Log” , and Section 5.4.5, “The Slow Query Log” .\nThe relay log is used only on replicas, to hold data changes from the replication source server that must also be made on the replica. For discussion of relay log contents and configuration, see Section 17.2.4.1, “The Relay Log” .\nFor information about log maintenance operations such as expiration of old log files, see Section 5.4.6, “Server Log Maintenance” .\nFor information about keeping logs secure, see Section 6.1.2.3, “Passwords and Logging” .\nMySQL Server provides flexible control over the destination of output written to the general query log and the slow query log, if those logs are enabled. Possible destinations for log entries are log files or the general_log  and  slow_log  tables in the  mysql  system database. File output, table output, or both can be selected.\n1022\n•Log Control at Server Startup\n•Log Control at Runtime\n•Log Table Benefits and Characteristics\n5.4.1 Selecting General Query Log and Slow Query Log Output Destinations\nLog Type Information Written to Log Error log Problems encountered starting, running, or stopping mysqld General query log Established client connections and statements received from clients Binary log Statements that change data (also used for replication) Relay log Data changes received from a replication source server Slow query log Queries that took more than  long_query_time seconds to execute DDL log (metadata log) Metadata operations performed by DDL statements"}]}
+{"image": "doclay/doclay_60331.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "CONTENTS\n2\nThe Python Language Reference, Release 3.9.5"}]}
+{"image": "doclay/doclay_17442.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "SECTION 4  Capital structure and equity\n4.4  Borrowings\nTREASURY SHARES\nINTEREST RATE RISK\nCarlsberg Group Annual Report 2013\nParent Company SECTION 4: CAPITAL STRUCTURE AND EQUITY 149\n2012  The fixed-rate mortgages comprised one mort- gage with a time to maturity of more than five years.\nSwaps were settled in 2012, so there were no fair value  adjustment in 2013 (2012: DKK -8m).\n2013  The fixed-rate mortgage is one loan which has a fixed interest rate until 2017. \nNon-current borrowing consists of employee bonds  that carry a fixed interest rate and one mortgage carrying a fixed interest.\nAt 31 December 2013 the fair value of treasury shares amounted to DKK 14m (2012: DKK 1m).\nB shares  carry two votes per DKK 20 share. A prefer- ential right to an 8% non-cumulative dividend is  attached to B shares. Apart from votes and dividends,  all shares rank equally.\nA shares  carry 20 votes per DKK 20 share. \nThe fair value of borrowings in subsidiaries corresponds to the carrying amount in all material respects.\nBorrowings are measured at amortised cost.\nOther non-current borrowings include employee bonds of DKK 13m (2012: DKK 18m). No bonds have been issued  in 2013 or 2012.\n4.5  Interest rate risk\nSHARE CAPITAL\nClass A shares Class B shares Total share capital Shares of  DKK 20 Nominal  value,  DKK ’000 Shares of  DKK 20 Nominal  value,  DKK ’000 Shares of  DKK 20 Nominal  value,  DKK ’000 1 January 2012 33,699,252 673,985 118,857,554 2,377,151 152,556,806 3,051,136 No change in 2012 - - - - - - 31 December 2012 33,699,252 673,985 118,857,554 2,377,151 152,556,806 3,051,136 No change in 2013 - - - - - - 31 December 2013 33,699,252 673,985 118,857,554 2,377,151 152,556,806 3,051,136\nShares of  DKK 20 Nominal  value, DKKm Percentage of share capital 1 January 2012 33,498 - 0.0% Acquisition of treasury shares 141,000 3 0.1% Used to settle share options -172,911 -3 -0.1% 31 December 2012 1,587 - 0.0% 1 January 2013 1,587 - 0.0% Acquisition of treasury shares 288,582 6 0.2% Used to settle share options -266,228 -5 -0.2% 31 December 2013 23,941 1 0.0% TREASURY SHARES\nDKK million Average effective  interest rate 2013 Interest rate  Fixed for Carrying amount Interest  rate risk Mortgages Fixed-rate Fixed 3.12% 2-3 years 209 Fair value Total mortgage 3.12% 209 2012 Mortgages Fixed-rate Fixed 2.85% 3-4 years 209 Fair value Total mortgages 2.85% 209 INTEREST RATE RISK\nDKK million 2013 2012 Non-current borrowings Mortgages 209 209 Other non-current borrowings 13 18 Total 222 227 Current borrowings Current portion of other non-current borrowings 5 - Borrowings from subsidiaries 1,093 740 Total 1,098 740 Total non-current and current borrowings 1,320 967 Fair value 1,327 980"}]}
+{"image": "doclay/doclay_17993.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "CORPORATE INFORMATION CORPORATE STRUCTURE\n26  DIRECTORS’ REPORT\n26  DIRECTORS’ REPORT\nBLUESTONE  AUSTRALIA PTY LTD ACN 108 490 820 METALS  EXPLORATION  PTY LTD ACN 005 483 009 CHINGGIS METALS  PTY LTD ACN 149 449 150 MAD METALS PTY LTD ACN 149 449 169  AGATON PHOSPHATE  PTY LTD ACN 129 901 097  BLUESTONE  MINES TASMANIA PTY LTD ACN 108 492 628 50% of Bluestone  Mines Tasmania  Venture Project BLUESTONE  NOMINEES  PTY LTD  ACN 092 257 013 Collingwood  Tin Project METEX NICKEL PTY LTD ACN 108 243 358 Central Musgrave  Project Exploration  Project HINCKLEY RANGE  PTY LTD ACN 052 098 496 Wingellina Nickel  Exploration  Project AUSTRAL NICKEL PTY LTD ACN 092 816 558 Claude Hills Nickel BLUESTONE MINES  TASMANIA JOINT  VENTURE PTY LTD ACN 141 265 974 Manager of  Unincorporated  Bluestone Mines  Tasmania Joint Venture 100% 75% 100% 10 0% 10 0 % 50% 10 0 % 100%"}]}
+{"image": "doclay/doclay_44246.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "AIM\n8/15/19  12/31/20\nsatellites. GPS status information is also available by means of the U.S. Coast Guard navigation information service: (703) 313 − 5907, Internet: http://www.navcen.uscg.gov/ . Additionally, satel- lite status is available through the Notice to Airmen (NOTAM) system.\n(b) GNSS operational status depends on the type of equipment being used. For GPS − only equipment TSO − C129 or TSO-C196(), the opera- tional status of non − precision approach capability for flight planning purposes is provided through a prediction program that is embedded in the receiver or provided separately.\n3. Receiver Autonomous Integrity Monitoring (RAIM). RAIM is the capability of a GPS receiver to perform integrity monitoring on itself by ensuring available satellite signals meet the integrity require- ments for a given phase of flight. Without RAIM, the pilot has no assurance of the GPS position integrity. RAIM provides immediate feedback to the pilot. This fault detection is critical for performance-based navigation (PBN)(see Paragraph 1 − 2 − 1, Perform- ance − Based Navigation (PBN) and Area Navigation (RNAV), for an introduction to PBN), because delays of up to two hours can occur before an erroneous satellite transmission is detected and corrected by the satellite control segment.\n(a) In order for RAIM to determine if a satellite is providing corrupted information, at least one satellite, in addition to those required for navigation, must be in view for the receiver to perform the RAIM function. RAIM requires a minimum of 5 satellites, or 4 satellites and barometric altimeter input (baro − aiding), to detect an integrity anomaly. Baro − aiding is a method of augmenting the GPS integrity solution by using a non-satellite input source in lieu of the fifth satellite. Some GPS receivers also have a RAIM capability, called fault detection and exclusion (FDE), that excludes a failed satellite from the position solution; GPS receivers capable of FDE require 6 satellites or 5 satellites with baro − aiding. This allows the GPS receiver to isolate the corrupt satellite signal, remove it from the position solution, and still provide an integrity-as- sured position. To ensure that baro − aiding is available, enter the current altimeter setting into the receiver as described in the operating manual. Do not use the GPS derived altitude due to the large GPS\n(b) GPS receivers used for VFR navigation vary from fully integrated IFR/VFR installation used to support VFR operations to hand − held devices. Pilots must understand the limitations of the receivers prior to using in flight to avoid misusing navigation information. (See TBL 1 − 1 − 6.) Most receivers are not intuitive. The pilot must learn the various\n(a) GPS navigation has become an asset to VFR pilots by providing increased navigational capabilities and enhanced situational awareness. Although GPS has provided many benefits to the VFR pilot, care must be exercised to ensure that system capabilities are not exceeded. VFR pilots should integrate GPS navigation with electronic navigation (when possible), as well as pilotage and dead reckoning.\nb. Operational Use of GPS.  U.S. civil operators may use approved GPS equipment in oceanic airspace, certain remote areas, the National Airspace System and other States as authorized (please consult the applicable Aeronautical Information Publica- tion). Equipage other than GPS may be required for the desired operation. GPS navigation is used for both Visual Flight Rules (VFR) and Instrument Flight Rules (IFR) operations.\n4. Selective Availability. Selective Availability (SA) is a method by which the accuracy of GPS is intentionally degraded. This feature was designed to deny hostile use of precise GPS positioning data. SA was discontinued on May 1, 2000, but many GPS receivers  are designed to assume that SA is still active. New receivers may take advantage of the discontinuance of SA based on the performance values in ICAO Annex 10.\n(b) There are generally two types of RAIM fault messages. The first type of message indicates that there are not enough satellites available to provide RAIM integrity monitoring. The GPS navigation solution may be acceptable, but the integrity of the solution cannot be determined. The second type indicates that the RAIM integrity monitor has detected a potential error and that there is an inconsistency in the navigation solution for the given phase of flight. Without RAIM capability, the pilot has no assurance of the accuracy of the GPS position.\nvertical errors that will make the integrity monitoring function invalid.\n1. VFR Operations\nNavigation Aids\n1 − 1 − 19"}]}
+{"image": "doclay/doclay_20645.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Financial instruments designated as held-for-trading\nInterest rate swap\nEmbedded derivative\nForeign currency contracts\nThe Corporation has foreign currency contracts to mitigate the currency risk for interest payments on the shareholder loan due from Värmevärden in  SEK and dividends from Bristol Water in pounds sterling. Capstone's options to sell foreign currencies as at December 31, 2013, are summarized as follows: \nThe Corporation has determined that its gas purchase contract contains embedded derivative features, which include mitigation options and electricity indexing features requiring separation and measurement at fair value. \nThe Corporation has interest rate swap contracts to effectively fix the interest cost on its long-term debt with variable rates, summarized as follows:\nThe Corporation invests its cash and cash equivalents and restricted cash balances in financial instruments of highly rated financial institutions and government securities with original maturities of 90 days or less. Short-term deposits have original maturities of greater than 90 days. As at December 31, 2013, the carrying values of cash and cash equivalents, restricted cash and short-term deposits are considered to be  approximately at their fair value due to their short-term nature, which is consistent with the prior year.\nDerivative financial instruments and hedging instruments\n•  Amherstburg project debt swap has a notional amount of $86,680. The Corporation pays a fixed rate of 4.1925% in return for a floating rate equal to 1.275%.\n•  Bristol Water has a swap with a notional amount of £10,000 for a bank loan drawn in October 2008 by Bristol Water. The swap exchanges LIBOR rates on a six monthly basis for a fixed rate of 5.025% and expires December 7, 2017. The swap meets the requirement to be accounted for as a cash flow hedge as it was assessed to be highly effective as at December 31, 2013.\nSwedish Krona (SEK)  UK Pound Sterling (£) Expiry Notional Amount Conversion Rate Notional Amount Conversion Rate 2014 21,400 6.5165 £3,500 1.6230 2015 9,800 6.5165 £2,600 1.6230 2015 12,000 6.5165 £1,500 1.5500 2016 9,000 6.4000 £2,250 1.5500 2016 9,100 6.5165 2017 15,000 6.4000 2018 6,500 6.4000 82,800 £9,850\nThe Corporation has determined the fair value of derivative financial instruments as follows:\nDue to the lack of observable market quotes on the Corporation's embedded derivatives, their fair values, classified as Level 3, were derived using valuation models that rely on a combination of observable and unobservable inputs, including interest rates, forward gas prices and volatility, foreign exchange curves, credit spreads, estimates on gas volumes and sales, fixed and variable gas transportation costs and a forecasted Direct Customer  Rate (“DCR”) curve based on historical averages.\nCapstone's finance department, with the assistance of third-party experts, is responsible for performing the valuation of financial instruments,  including Level 3 fair values. The valuation processes and results are reviewed and approved each reporting period. These critical estimates are  discussed as part of the Audit Committee's quarterly review of the financial statements.\n72 CAPSTONE INFRASTRUCTURE CORPORATION\nInterest rate swap • The fair value of the interest rate swap contracts fluctuates with changes in market interest rates. • A discounted cash flow valuation based on a forward interest rate curve was used to determine their fair value. Interest rate swap (Cash flow hedges) • The market price of comparable instruments at the statement of financial position date is used to determine the fair value of cash flow hedges at Bristol Water. Embedded derivative • The determination of the fair value of the Corporation's embedded derivatives requires the use of option pricing models involving significant judgment based on management's estimates and assumptions. Foreign currency contracts • The fair value of the foreign currency contracts fluctuates with changes in the relative currencies to the Canadian dollar. • A Black-Scholes model, based on the current spot price, discount rate, volatility in the underlying currency and time to  maturity, is used to determine fair value.\nNOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS"}]}
+{"image": "doclay/doclay_46100.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "the maneuver. [Figure 9-9] The cyclic is held into the wind a sufficient amount to maintain the desired ground track for the takeoff. The heading is maintained with the use of the antitorque pedals. In other words, the rotor is tilted into the wind so that the sideward movement of the helicopter is just enough to counter- act the crosswind effect. To prevent the nose from turning in the direction of the rotor tilt, it is necessary to increase the antitorque pedal pressure on the side opposite the rotor tilt.\nNormal takeoff from the surface is used to move the helicopter from a position on the surface into effective translational lift and a normal climb using a minimum amount of power. If the surface is dusty or covered with loose snow, this technique provides the most favorable visibility conditions and reduces the possibility of debris being ingested by the engine.\nPlace the helicopter in a stationary position on the sur- face. Lower the collective to the full down position, and reduce the r.p.m. below operating r.p.m. Visually clear the area and select terrain features, or other objects, to aid in maintaining the desired track during takeoff and climb out. Increase the throttle to the proper r.p.m. and raise the collective slowly until the helicopter is light on the skids. Hesitate momentarily and adjust the cyclic and antitorque pedals, as neces- sary to prevent any surface movement. Continue to apply upward collective and, as the helicopter breaks ground, use the cyclic, as necessary to begin forward movement as altitude is gained. Continue to acceler- ate, and as effective translational lift is attained, the helicopter begins to climb. Adjust attitude and power, if necessary to climb in the same manner as a takeoff from a hover.\nAfter approximately 50 feet of altitude is gained, make a coordinated turn into the wind to maintain the desired ground track. This is called crabbing into the wind. The stronger the crosswind, the more you have to turn the helicopter into the wind to maintain the desired ground track. [Figure 9-10]\nIf the takeof is made during crosswind conditions, the helicopter is flown in a slip during the early stages of\n9-11\nFigure 9-10. T compensate for wind drift at altitude, crab the helicopter into the wind.\nFigure 9-9. During a slip, the rotor disc is tilted into the wind.\nNORMAL TAKEOFF FROM THE SURFACE\nTECHNIQUE\nCROSSWIND CONSIDERATIONS  DURING TAKEOFFS\n3. Too abrupt application of the collective when departing the surface, causing r.p.m. and heading control errors.\n2. Using excessive power combined with a level attitude, which causes a vertical climb.\n1. Departing the surface in an attitude that is too nose-low. This situation requires the use of exces- sive power to initiate a climb.\nCOMMOM ERRORS\n6. Failing to adjust the throttle to maintain proper r.p.m.\n5. Failing to maintain proper airspeed during the climb.\n4. Failing to maintain a straight flight path over the surface (ground track).\n3. Assuming an extreme nose-down attitude near the surface in the transition from hovering to forward flight.\nWindGLYPH<.notdef> Movement Helicopter GroundGLYPH<.notdef> Tr a c k HelicopterGLYPH<.notdef> Heading\nWindGLYPH<.notdef> Movement HelicopterGLYPH<.notdef> Side Movement"}]}
+{"image": "doclay/doclay_40860.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Very early break: land straight ahead. Tow vehicle, if used, should clear runway to make way for the glider. SNAP Airborne break: lower nose and promptly land straight ahead. SNAP If towline is parachute equipped, avoid parachute when lowering nose after towline break or normal release.\nFigure 8-16.  Ground launch towline break.\nThe pilot of a self-launching glider should formulate  emergency plans for any type of failure that might occur.  Thorough knowledge of aircraft performance data, normal  takeoff/landing procedures, and emergency procedures as  outlined in the GFM/POH are essential to the successful  management of any emergency situation.\nMismanagement of the aircraft systems through lack of  knowledge may cause serious difficulty. For instance, if  the spoilers/dive brakes are allowed to open during takeoff  and climb, the self-launching glider may be incapable of  generating sufficient power to continue climbing. Other  emergency situations may include inflight fire, structural  failure, encounters with severe turbulence/wind shear,  canopy failure, and inadvertent encounter with instrument  meteorological conditions (IMC).\nPossible options for handling emergencies are influenced by  the altitude above the terrain, wind, and weather conditions.  As a part of preflight planning, pilots should review the  effects of density altitude on glider performance. The takeoff  runway length and landing areas near the gliderport and  existing air traffic affect the pilot’s approach and landing  decision. Emergency options may include landing ahead on \nthe remaining runway, landing off field, or returning to the  gliderport to land on an available runway. The appropriate  emergency procedures may be found in the GFM/POH for  the specific self-launching glider.\nAllowing the nose of the glider to get excessively low during  a steep turn may result in a significant increase in airspeed  and loss in altitude, creating a spiral dive. If the pilot attempts  to recover from this situation by applying only back elevator  pressure, the limiting load factor may be exceeded, causing  structural failure. To recover from a spiral dive properly, the  pilot should first reduce the angle of bank with coordinated  use of the rudder and aileron, then smoothly increase pitch  to the proper attitude.\nCommon errors during spiral dives include: \nAll flight instructor applicants must be proficient in spins.  A spin may be defined as an aggravated stall that results \nSelf-Launch Takeoff Emergency  Procedures\nEmergency Procedures\nSpiral Dives\nSpins\n•  Failure to recognize when a spiral dive is developing.\n•  Rough, abrupt, and/or uncoordinated control  application during recovery.\n•  Improper sequence of control applications.\n8-15"}]}
+{"image": "doclay/doclay_58608.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "II. BRANDING 2.01 Identification - ATP Tour Tournaments\nII. BRANDING 2.01 Identification - ATP Tour Tournaments (See ATP Addendum, page 373)\nI. ATP CIRCUIT REGULATIONS can be made up to two (2) days prior to the first day of the reservation except \nATP CIRCUIT REGULATIONS can be made up to two (2) days prior to the first day of the reservation except  that a player still competing in either singles or doubles in the prior week’s tourna - ment must also confirm his reservations when travel plans are finalized. Failure to  make or modify the reservation by the deadlines stated above shall result in the  automatic loss of hospitality for that tournament week.\n2) Alternates.  Players that move into the main draw between the entry deadline and  all day Thursday before the event, must notify the tournament two (2) days in ad - vance if their arrival is later than Saturday, unless provisions specified above for  players still competing apply. Players moving into the main draw after Thursday  must notify the tournament of their arrival by by 2:00 PM Eastern Time, USA on  the Friday prior to the event. Players moving into the main draw after this deadline  must confirm arrival day/date with the tournament as soon as possible.\n3) Doubles-Only Players.  Tournaments shall provide hospitality from Sunday. Play - ers that wish to start their hospitality later than Sunday must make such change  by 3:00 PM local time on the Saturday before the tournament starts. Players that  fail to make their change by the deadline will be charged at the published rate for  each night they are a no show. A refusal to pay shall result in automatic loss of  hospitality for the remainder of the tournament week.\n4) Penalties for breaching obligation:\nA.  Each ATP Tour tournament shall identify itself clearly to the public as being part of  the ATP Tour and shall cooperate fully with ATP in furthering public awareness of the  ATP Tour. Participation in the ATP Tour shall not restrict the right of the tournament to  obtain individual sponsorship or to retain its usual title.\nB.Trademark and Logo Identification . Each ATP Tour tournament and ATP Challeng - er Tour tournament shall comply with the terms and conditions for the use of the ATP  Tour and the ATP Challenger Tour trademark and logo outlined in “Exhibit B and G”.\nC.  Except as otherwise approved by ATP, each ATP Tour tournament shall comply with  the ATP Tour Branding Application Requirements and shall assume all costs asso - ciated with such compliance. Branded nets and microphone flags will be provided,  without cost, to all tournaments by ATP. ATP Tour and ATP Challenger Tour Applica - tion Requirements will be provided to each tournament by ATP.\na) Failure to make a reservation two (2) weeks prior to a tournament shall result  in a player losing his hotel accommodation privileges for that tournament. b) Player forfeits hotel accommodations for nights reserved but not used.\nin a player losing his hotel accommodation privileges for that tournament. b) Player forfeits hotel accommodations for nights reserved but not used. c) Player forfeits hotel accommodation privileges for four (4) consecutive tour\nb) Player forfeits hotel accommodations for nights reserved but not used. c) Player forfeits hotel accommodation privileges for four (4) consecutive tour - naments when he either: i) Does not pay all incidental costs charged to a room; or \nnaments when he either: i) Does not pay all incidental costs charged to a room; or   ii) Does not personally stay in the room as required; or\ni) Does not pay all incidental costs charged to a room; or   ii) Does not personally stay in the room as required; or iii)  Does not cancel reservation(s) previously made at tournament hotel(s); \n ii) Does not personally stay in the room as required; or iii)  Does not cancel reservation(s) previously made at tournament hotel(s);  or iv) Damages a room or hotel facilities;\nor iv) Damages a room or hotel facilities; v)  Exhibits unprofessional or abusive behavior towards any hotel employee \niv) Damages a room or hotel facilities; v)  Exhibits unprofessional or abusive behavior towards any hotel employee  or guest; vi)  Exhibits severe unprofessional behavior in or on the hotel premises and \nor guest; vi)  Exhibits severe unprofessional behavior in or on the hotel premises and  not specifically covered above. Other Reservations. Players can request additional room reservations at the \nnot specifically covered above. 5) Other Reservations. Players can request additional room reservations at the  player rate if they contact the tournament no later than two (2) weeks prior to the  start of the tournament.\n6)  Qualifier Reservations. (See Challenger Addendum, page 395). Players  participating in the qualifying competition who wish to receive a player rate at a  tournament hotel must make a hotel reservation no later than five (5) days prior to  the start of qualifying with either the hotel or the tournament, as specified on the  tournament detail sheet. Reservation changes can be made up to forty-eight (48)  hours prior to the start of the reservation except that a player still competing in ei - ther singles or doubles in the prior week’s tournament must confirm reservations  when his travel plans are finalized.\nfor Official Stamps below. iii) Minimum Size  To ensure the ATP Tour Official Tournament Stamps are reproduced to \niii) Minimum Size  To ensure the ATP Tour Official Tournament Stamps are reproduced to  best effect, the tournaments must adhere to the application rules stated \nboth tours. •  Size relationship: WTA logo The ATP Tour Official Tournament Stamp must be the same visual \nsize (cover the same surface area) as the WTA logo. •  Size Relationship: Tournament Logo When the ATP Tour Official Tournament Stamp is used in conjunction \nSize relationship: WTA logo The ATP Tour Official Tournament Stamp must be the same visual  size (cover the same surface area) as the WTA logo. Size Relationship: Tournament Logo\nSize Relationship: Tournament Logo When the ATP Tour Official Tournament Stamp is used in conjunction  with the WTA logo, the Official Stamp must be at a minimum equal  size to the WTA logo or 30% of the surface area of the tournament  logo, whichever is greater. This is subject to the minimum size rules  for Official Stamps below. iii) Minimum Size \n1) ATP Tour Official Tournament Stamps: Application Rules (“Exhibit A.01”)\nAll ATP Tour tournaments must display the appropriate ATP Tour Official Tourna - ment Stamp (Masters 1000, 500, or 250) on all compulsory materials containing  the tournament logo, as identified in the rules below. The tournament logo is the  official identity of the tournament that includes the tournament name. When a text  alternative to the tournament logo is used, it will be regarded as the tournament  logo and the rules below will continue to apply. When a tournament logo is used  repeatedly, or if both tournament logo and tournament title are used, application  rules will apply to the largest tournament logo or title. For multiple page external  documents, the ATP Tour Official Tournament Stamp must be applied on the front  page in accordance with the rules below.\na) Size Relationship i)  Men only events (“Exhibit A.02”)\nSize Relationship i)  Men only events (“Exhibit A.02”) The ATP Tour Official Tournament Stamp must be a minimum of 60% of \nTournament Stamps below.  ii) Combined events (“Exhibit A.03”) The ATP Tour Official Tournament Stamp should be presented with the \nMen only events (“Exhibit A.02”) The ATP Tour Official Tournament Stamp must be a minimum of 60% of  the surface area of the tournament logo or tournament title, whichever is  larger. This is subject to the minimum size rules for the ATP Tour Official  Tournament Stamps below.  ii) Combined events (“Exhibit A.03”)\nii) Combined events (“Exhibit A.03”) The ATP Tour Official Tournament Stamp should be presented with the  WTA logo to communicate to audiences that the tournament is part of  both tours. •  Size relationship: WTA logo\n22\n23"}]}
+{"image": "doclay/doclay_64360.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Algae are preferably provided in the form of a wet algal  biomass, which is a water suspension. In a preferred  embodiment, the water content in the water suspension is at  least 50 wt. %, more preferably 75-90 wt. %. This is an  advantage of the present method, which can be applied  directly to harvested biomass (optionally after some con- centration) and which does not require complete dewatering  and drying of the biomass, which may consume a lot of  energy. Any suitable type of algae can be used. \nIn a further step, algae are subjected to cell lysis with the  ionic liquid. This can take place, for example, in a lysis  reactor. In one embodiment, the algae together or separately  with the ionic liquid are introduced in a lysis reactor. In  another embodiment, the ionic liquid is formed in situ, e.g.  in the lysis reactor, from a respective base and an acid. This  is particularly convenient if the acid in the ionic liquid is  carbonic acid; the conjugate can then be generated in situ by  addition of a gaseous CO$_{2 }$ to the base. \nIn a preferred embodiment, an organic solvent, preferably,  an alcohol, and more preferably methanol or ethanol, can be  added to the mixture of the ionic liquid and the algae. 50  Organic solvents can in this way reduce the viscosity, on one  hand, and on the other hand act as (trans)esterification  agents, that is, they favor fatty acid esters formation. Fatty  acids methyl esters (or other alcohol esters) can be directly  formed during the lysis process. The preferred organic 55  solvent is methanol as it results in fatty acid methyl esters,  which is favourable for the use in biofuel. The use of  methanol can lead to a transesterification yield higher than  90%, in combination with the ionic liquids used in the  present invention. Conventional ionic liquids such as  [BMIM]Cl do not achieve such high transesterification  yields as seen in Example 9 below.  60\nThe ratio of the conjugated ionic liquid to algae suspen› sion, which can be used, depends on the base. In the absence  of alcohol, the mass ratio of the conjugated ionic liquid to  cell suspension is preferably in the range of 5: 1 to 3: 1  ( calculated based on the water content of the cell suspension \n30  85 wt. %). In the presence of methanol, the mass ratio of  conjugate acid to cells suspension (water content 85 wt.%)  is preferably in the range of 7: 1 to 3: 1 and the mass ratio of  alcohol to cell suspension ( containing about 85 wt. % of  water) is in the range of 2:1 to 0.5:1. \nPreferably, the cell lysis is performed at temperatures of  100°  C., or less (generally about 80°  C.). Preferably, a closed  apparatus is used, optionally, under CO$_{2 }$ pressure. The  duration of the cell lysis should be sufficient to effect lysis  but is generally less than 60 min. \nAs a result of the cell lysis, at least two phases are formed,  including a hydrophobic phase and a hydrophilic phase.  These phases are substantially immiscible. The hydrophilic  phase mainly contains water, the ionic liquid, alcohol (if  used) and hydrophilic algae components (glycerol, water  soluble proteins,  carbohydrates and metabolites). The  hydrophobic phase mainly contains fatty acids and their  glycerol esters, waxes and, optionally, the extractant (if  used). Optionally, a solid phase is additionally formed as a  third phase. This solids phase may for example contain a part  of ionic liquid in the form of a precipitate, which is undis› solved at the lysis or separation temperature. \nSubsequently, the hydrophobic phase is separated by  physical separation methods such as decanting, centrifuga› tion, etc. The hydrophobic phase has generally a lower  density than the hydrophilic phase is therefore the present as  the upper layer. The upper hydrophobic layer can be recov- ered by mechanical separation or spilling. The two or three  phases may be allowed to separate using the forces of  gravity or separation might be accelerated, for example by  centrifugation. The precipitated ionic liquid can be filtered  off and reused in the step of algal cell lysis. \nOnce the lipid-containing hydrophobic layer is separated  from the mixture, the hydrophilic phase containing the ionic  liquid, water, hydrophilic algae components and optionally  alcohol can be recovered for reuse in the step of algal cell  lysis. The phases separation and oil recovery can be favored  by temperature reduction, preferably at room temperature or \n35 \n40 \n45 \n60\n65\nUS 10,035,971 B2 \n6 \n5 \nTABLE I-continued \nTABLE I-continued  pKa pKa  Base  Structural  formula  water other solvent  1,8-diazabicyclo-[5.4.0]undec- 7-ene (DBU)  1,5,7-Triazabicyclo[4.4.0]dec-5- ene(TBD)  imino-tris-(dimethylamino)› phosphorane  H  0~  I  H  G:~)  N  N  I  I  H  H  24.3  (Acetonitrile)  21.7 (THF)  27.9 (THF) "}]}
+{"image": "doclay/doclay_4220.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "(11)\nJP 2017-66264 A 2017.4.6\n磨速度、表⾯粗さ、形状悪化量）は悪化すると考えられる。\n なお、ＫＯＨに⽐べＫ ２ ＣＯ ３ の配合量の⽐率が⼤きくなっていくと凝集傾向が⾼くな る理由として、Ｋ ２ ＣＯ ３ はＫＯＨよりも塩濃度が⾼い（等モル⽐で考えたとき、Ｋ Ｃ Ｏ ３ はＫＯＨよりもカリウムイオンが２倍となる）ことが挙げられる。Ｋ ２ ＣＯ は塩        濃度が⾼いので、⽔中（アルカリ条件下）で静電反発により安定化している粒⼦同 ⼠間にカリウムイオン（電解質）が介在することにより粒⼦の電荷が遮蔽され、砥粒の凝 集が起こりやすくなる。\n 以上、上述した実施の形態は本発明を実施するための例⽰に過ぎない。よって、本発明 は上述した実施の形態に限定されることなく、その趣旨を逸脱しない範囲内で上述した実 施の形態を適宜変形して実施することが可能である。\n この発明の本実施形態による研磨⽤組成物は、アミノ酸と、無機アルカリ化合物と、キ レート剤と、砥粒と、を含む。\n この発明の本実施形態による研磨⽤組成物に含まれるアミノ酸は、好ましくは、塩基性 荷電アミノ酸である。\n この発明の本実施形態による研磨⽤組成物に含まれるアミノ酸が塩基性荷電アミノ酸で ある場合、塩基性荷電アミノ酸は、好ましくは、Ｌ−アルギニン、Ｌ−リシン塩酸塩、ま たはＬ−ヒスチジンである。\n この発明の本実施形態による研磨⽤組成物には、好ましくは、２種類の無機アルカリ化 合物が含まれる。\n この発明の本実施形態による研磨⽤組成物に２種類の無機アルカリ化合物が含まれる場 合、無機アルカリ化合物は、⽔酸化カリウム及び炭酸カリウムであることが好ましい。\n この発明の本実施形態による研磨⽤組成物は、さらに、⽔溶性⾼分⼦を含んでいてもよ い。\n【産業上の利⽤可能性】\n 本発明は、研磨⽤組成物について利⽤可能である。\n【００６７】\n【００６６】\n【００６５】\n【００６４】\n【００６３】\n【００６２】\n【００６１】\n【００６０】\n【００５９】"}]}
+{"image": "doclay/doclay_1509.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "8\nWe tested our method for prioritizing the crawling queue using Bengali language Twitter users. In order to properly compare the various methods we first collected a data set of 10,785 Twitter users. (5,684 users came from our search queries and an additional 5,103 came from those users’ social connections.) The way the queue ranking works is to first download a small set of users and use that as training data to learn a ranking for the rest of the download queue. We randomly selected 300 users for our training set. The ranking methods were used to order the remaining 10,000+ users in the simulated download queue.\nIn Figure 2, we show the cumulative in-vocabulary tokens obtained as an additional 500 users are processed from the download queue for each of the three prioritization strategies. The predictive ranking provides three times as many in- vocabulary tokens as either the edge count ranking or the random baseline. Figure 3 is similar but shows the cumulative vocabulary coverage (types) where the vocabulary is taken from a held-out dev set different from the text used to produce the Twitter queries. The horizontal line represents the type coverage of the in-domain training data. The predictive\nranking covers an additional 10% of the dev-set vocabulary compared to either of the other strategies. More than 53% of the vocabulary types and about 9% of the tokens in the dev- set are not found in the in-domain training data. The Twitter data downloaded using the predictive ranking covers 56% of these previously unseen vocabulary types, substantially out- performing the edge count ranking and the random baseline. The match between the vocabulary of the data obtained with the predictive ranking with the in-domain data is an indication of the value of the predictive ranking strategy.\nThe most important features for the predictive ranking (as measured by the average decrease in node impurity in the random forest regression model) are average number of reverse followers in the training set, average sentence count after filtering among followers in the training set and aver- age sentence count after filtering among mentioners in the training set. Even though edge features highly influence the predictive ranking model, the edge count ranking is worse than the predictive ranking on both of the type coverage and the cumulative IV token metrics. This is because there are high edge count connections from Bengali speaking Twitter users to international celebrities, which fools the edge count ranking strategy but not the random forest regression. (The top followed Twitter user by Bengali speakers is @BarackObama followed by @BillGates.)\nWe created language models from the downloaded data to compare the effectiveness of the ranking strategies. The language models used the data from the 300 users in the training set as well as the additional users selected by each of the respective ranking strategies. Table VI lists the resulting perplexities on the held-out in-domain data. The predictive ranking LM achieved a 17% reduction in perplexity over the random baseline after downloading 500 users from the queue. When less than 500 additional users are downloaded, the predictive ranking has a better perplexity than the edge\nB. Queue Prioritization Experiment\nFig. 2. IV Tokens Gathered by Crawling Strategy\n"}]}
+{"image": "doclay/doclay_46907.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Figure 5-22. Straight-and-level flight (normal cruising speed).  Figure 7-22.  Straight-and-level flight (normal cruising speed).\nFigure 5-23. Straight-and-level flight (airspeed decreasing).  Figure 7-23.  Straight-and-level flight (airspeed decreasing).\n7-10\n30.0  29.9  29.8  Primary pitch Supporting pitch and bank Primary power Supporting bank Primary bank Supporting pitch Supporting power\n30.0  29.9  29.8  Primary pitch Supporting pitch and bank Supporting bank Primary bank Supporting pitch Primary power as airspeed approaches desired value Primary power as throttle is set"}]}
+{"image": "doclay/doclay_27725.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "145\nChapter 7 Conclusions and Outlook\nExperiment drives physics. Our description of natural laws evolved not from aesthetics but falsifiable predictions compared to data. Scientific advance led us to the Standard Model of particle physics, with SU (3) the gauge group of the strong force coupling to fundamental quarks of fractional charge. Every tractable theory of nuclear physics points to a new paradigm at scales on the order of Λ$_{QCD}$, at which point quarks and gluons are presumably liberated from their hadronic prisons. It is clear that the prerequisite densities are reached at $_{Rhic}$, but many questions remain, theoretically and experimentally.\nIf one were to sum up the discoveries at Rhic in two words they would be flow and jets. The low- p$_{T}$ azimuthal anisotropy appears to saturate the ideal hydrodynamics bound. High- p$_{T}$ jets are quenched, and, shockingly, heavy quarks are suppressed at a level similar to light quarks and gluons. Addi- tionally the intermediate- p$_{T}$ v$_{2}$ is surprisingly high for both light hadrons and nonphotonic electrons.\nHydrodynamics results hold the tantalizing possibility for direct evidence"}]}
+{"image": "doclay/doclay_3265.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "(b) B undertook a day 2 test that generated a positive result. \n(a) the end of the default self-isolation period; \n(b) the day on which P receives the result of their day 8 test. \n(a) until the end of the 10th day after the day P undertook the test; \n(b) where P undertakes a test to which sub-paragraph (7) applies and the test generates a  negative result, until the later of— \n(i) the end of the default self-isolation period, \n(ii) the day on which P receives the negative result; or \n(c) where P undertakes a test to which sub-paragraph (7) applies and the test generates a  positive result, until the end of the 10th day after the day P undertook the test. \n(a) a day 8 test; \n(b) a test— \n(i) complying with the requirements for a day 8 test specified in paragraphs 8 and 9  (other than the requirement in paragraph 9(1)(e) that the test be administered or  provided to P no earlier than the end of the seventh day after the day on which P  arrived in England), \n(ii) undertaken in the circumstances specified in paragraph 10 (other than the  circumstances in paragraph 10(2) about when a test must be undertaken), and \n(iii) undertaken during the period specified in sub-paragraph (5)(a). \n(a) is a non-Schedule 11 passenger who is required to comply with regulation 9, and \n(b) undertakes a day 2 test which generates a negative or inconclusive result. \n(a) P is a non-Schedule 11 passenger; \n(b) P undertakes a day 2 test which generates a negative result; \n(c) while P is self-isolating under these Regulations, P subsequently undertakes a test other  than in accordance with these Regulations; and \n(d) P is notified that such test generates a positive result. \n60\n(4) Subject to paragraph 4, where P’s day 2 test and day 8 test both generate a negative result, P  must continue to self-isolate in accordance with the relevant self-isolation provisions until the later  of— \n(5) Where a mandatory test undertaken by P generates an inconclusive result P must continue to  self-isolate in accordance with the relevant self-isolation provisions— \n(6) Where sub-paragraph (5)(c) applies, P is not required to undertake a day 8 test in accordance  with regulation 6. \n(7) This sub-paragraph applies to— \n4. —(1) This paragraph applies where P— \n(2) P may undertake a test in accordance with Schedule 10 (optional testing after arrival in  England), and, where the test generates a negative result, P ceases to be required to self-isolate  from the time that P is notified of that result. \n(3) P must in any event undertake the day 8 test booked in accordance with regulation 6. \n(4) Where P ceases to be required to self-isolate under these Regulations in accordance with  regulation 9(16), paragraph 3(1), (4) and (5) do not apply in relation to P’s day 8 test. \n5. —(1) This paragraph applies where— \nTests other than in accordance with these Regulations \nOptional tests "}]}
+{"image": "doclay/doclay_70316.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "4. Enter  6  and press Enter. A window similar to the window that is shown in Figure 10-6  opens. Db2 subsystems that cannot be selected because they are not enabled for  incremental updates are listed. Under “Select a database system”, you see the Db2  subsystems that you can select.\n5. Enter the number of the Db2 subsystem that you want to enable and press Enter. The  message that is shown in Figure 10-7 is displayed.\nThe performance measurement used as many as 500 IBM Retail Data Warehouse  LINEITEM-like tables to simulate the customer’s use case. Each table includes approximately  24 million rows and is in a partition by range table space. Concurrent insert and update  transactions were run against these 500 tables. The measurement is to compare the  replication throughput of a single apply to multiple apply with a default of four parallel apply  threads. \nThe measurements showed up to 98% replication throughput improvement comparing  parallel apply by using four threads to apply by using a single thread. \nChapter 10. IBM Db2 Analytics Accelerator for z/OS 309\nPerformance results\nPerformance measurement\nFigure 10-7 Enabling the feature promptFigure 10-6 Available Db2 subsystems\n"}]}
+{"image": "doclay/doclay_5541.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "14. BORROWINGS\nA summary of the borrowings, including the outstanding balance of lines of credit, from the FHLBB is as follows:\nShort- and long-term borrowings from the FHLBB consist of both fixed and adjustable rate borrowings and are collateralized by all stock in the FHLBB and a blanket lien on qualified collateral consisting primarily of loans with first mortgages secured by one-to-four family properties, certain pledged investment securities and other qualified assets. The carrying value of loans pledged as collateral was $236,254,000 and $194,659,000 at December 31, 2002 and 2001, respectively. The FHLBB at its discretion can call $101,000,000 of the CompanyGLYPH<213>s long-term borrowings. The Company, through its bank subsidiaries, has an available line of credit with FHLBB of $12,980,000 at December 31, 2002 and 2001. The Company had no outstanding balance on its line of credit with the FHLBB at December 31, 2002 or 2001.\nThe Company utilizes other borrowings in the form of treasury, tax and loan deposits and repurchase agreements secured by U.S. government or agency securities. Balances outstanding at December 31 are shown in the table below:\nThe CompanyGLYPH<213>s postretirement plans provide medical and life insurance to certain eligible retired employees. It is the CompanyGLYPH<213>s policy to fund the cost of postretirement health care and life insurance plans as premiums are paid; therefore, there are no  plan assets.\nOn October 17, 2000, the Company terminated the defined-benefit noncontributory pension plan, which covered substantially all eligible employees over 21 years of age with 1 year of employment. Total plan assets of $5,168,000 were distributed to eligible\n54 Camden National Corporation and Subsidiaries\n15. EMPLOYEE BENEFIT PLANS\nPension and Other Postretirement Plans\n2002 2001 Treasury, tax and loan deposits $ 1,000 $ 1,058  Securities sold under repurchase agreements 45,960  40,953 Total other borrowed funds $46,960 $42,011 Weighted-average rate at the end of period 1.74% 3.68%\nPrincipal Amounts Interest Rates Maturity Date $ 76,405 1.35% — 6.12% 2003 12,000 3.27% — 5.19% 2004 28,101 3.97% — 5.55% 2006 19,395 4.27% — 4.47% 2007 12,000 4.88% — 4.97% 2009 10,000 4.95% 2010 34,000 4.07% — 5.02% 2011 $191,901\nPrincipal Amounts Interest Rates Maturity Date $ 24,578 4.82% — 5.19% 2002 45,000 4.24% — 6.12% 2003 12,000 3.27% — 5.19% 2004 31,254 3.97% — 5.55% 2006 12,000 4.88% — 4.97% 2009 10,000 4.95% 2010 34,000 4.07% — 5.02% 2011 $168,832\nDECEMBER 31, 2001\nDECEMBER 31, 2002\nInformation regarding the postretirement benefit plan is as follows:\nemployees during the first half of 2001. During 2000, the Company recognized $437,000 of net income due to the over accrual of the benefit obligation at the date of plan termination.\n2002 2001 2000 Change in benefit obligation Benefit obligation at beginning of the year $ 765 $ 724 $ 481 Service cost 57 43 38 Interest cost 53 50 32 Actuarial gain (loss) 15 (22) 200 Benefits paid (38) (30) (27) Benefit obligation at end of year 852 765 724 Funded status (852) (765) (724) Unrecognized net actuarial loss 242 237 273 Unrecognized net prior service cost (62) (78) (94) Accrued benefit cost, included in other liabilities $(672) $(606) $(545) Weighted-average discount rate assumption 7.0% 7.0% 7.0%\n2002 2001 2000 Components of net periodic benefit cost Service cost $ 57 $43 $ 38 Interest cost 53 50 32 Amortization of prior service cost (16) (16) (16) Recognized net actuarial loss 11 14 3 Net periodic benefit cost $105 $ 91 $ 57\nFor measurement purposes, a 6.2% annual rate of increase in the per capita cost to cover health care benefits was assumed for 2003. The rate was assumed to decrease gradually to a 6.0% annual growth rate after 3 years, and remain at a 6.0% annual growth rate thereafter. A 1.0% increase or decrease in the assumed health care cost trends rate would not have a material impact on the accumulated postretirement benefit obligation due to a built-in cap on annual benefits.\nThe Company also sponsors an unfunded, non-qualified supplemental retirement plan for certain officers. The agreement provides that participants will be paid a life annuity upon retirement or death. Prior to September 1, 1999, the plan provided supplemental retirement payments over 15 years upon retirement or death. \nThe expense of this supplemental plan was $403,000, $399,000 and $274,000 in 2002, 2001 and 2000, respectively. The accrued liability of this plan at December 31, 2002 and 2001 was $1,788,000 and $1,562,000, respectively.\nThe Company has a 401(k) plan whereby substantially all employees participate in the plan. Employees may contribute up to 15% of their compensation subject to certain limits based on federal tax laws. The Company makes matching contributions and may make additional contributions subject to the discretion of the Board of Directors. For the years ended December 31, 2002, 2001 and 2000, aggregate expenses under the plan amounted to $772,000, $527,000 and $214,000, respectively.\nThe Company maintained a Bank Recognition and Retention Plan (GLYPH<210>BRRPGLYPH<211>) as a method of providing certain officers and other employees of the Company with a proprietary interest in the Company. During 1994, the Company contributed funds to the BRRP  to enable such Company officers and employees to acquire, in the aggregate, 56,045 shares of common stock of the Company. The Company recognizes expense related to the BRRP based on the vesting schedule. Participants are vested at a rate of 20% per year commencing 1 year from the date of the award. Total expense related to the BRRP was $5,712 for 2002, 2001 and 2000.\nCamden National Corporation and Subsidiaries 55\n401(k) / Profit Sharing Plan\nBank Recognition and Retention Plan"}]}
+{"image": "doclay/doclay_79560.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Chapter 70\nperlguts\n70.1 DESCRIPTION\n70.2 Variables\n70.2.1 Datatypes\n70.2.2 What is an \"IV\"?\n70.2.3 Working with SVs\n1065\nIntroduction to the Perl API\nThis document attempts to describe how to use the Perl API, as well as to provide some info on the basic workings of the Perl core. It is far from complete and probably contains many errors. Please refer any questions or comments to the author below.\nPerl has three typedefs that handle Perl’s three main data types:\nEach typedef has specific routines that manipulate the various data types.\nPerl uses a special typedef IV which is a simple signed integer type that is guaranteed to be large enough to hold a pointer (as well as an integer). Additionally, there is the UV, which is simply an unsigned IV.\nPerl also uses two special typedefs, I32 and I16, which will always be at least 32-bits and 16-bits long, respectively. (Again, there are U32 and U16, as well.) They will usually be exactly 32 and 16 bits long, but on Crays they will both be 64 bits.\nAn SV can be created and loaded with one command. There are five types of values that can be loaded: an integer value (IV), an unsigned integer value (UV), a double (NV), a string (PV), and another scalar (SV).\nThe seven routines are:\nSV Scalar Value\nAV Array Value\nHV Hash Value"}]}
+{"image": "doclay/doclay_21952.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "73\nADAMS is one of the largest independent insurance direct  marketing services companies in Asia by both geographic  footprint and premiums. ADAMS specializes in direct and affinity  marketing, and services business partners across the direct  marketing value chain. It has developed significant capabilities in  customer analytics and data management, integrated marketing  and operational execution, and is investing in and building digital  and e-commerce capabilities to expand opportunities with  existing business partners beyond telemarketing.\nSince early 2012, all actively distributed Aegon Sony Life  products had an underlying policyholder fund with a volatility- control mechanism which uses the simple index funds of major  economies. Target volatilities are in the range of 4.5% to 6%.\nSince 2010, SARe has reinsured all minimum guarantees offered  on Aegon Sony Life’s variable annuity products. \nThe focus of TLB is on building strong relationships with  private and priority banks, local and international brokers  and intermediaries.\nAegon-CNOOC offers non-life products – mainly short-term  accidental and short-term health – to all channels, although  sales are concentrated in the group channel, for which the main  products are group medical policies.\nAegon provides a broad range of life insurance products through  its businesses in China and India. These include unit-linked and  traditional life products, as well as endowment, term life, health,  group life, accident, and annuities.\nAegon Religare sells a health product with the same features  as a defined-benefit product, which pays benefits specified  for the categories of hospitalization, surgery or critical illness,  irrespective of the actual expense incurred by the policyholder. In  May 2012, Aegon Religare launched online health plan iHealth,  in line with the company’s focus on digital channels. The off-line  version is sold by all channels of the joint venture, including  agency, direct and business alliances.\nIn China, Aegon-CNOOC’s agency channel mainly sells regular  premium endowment with high-sum assured protection  and critical illness products. Regular premium participating  endowment and single-pay universal life are key products for  the bancassurance channel. Telemarketers largely sell return of  premium products. Popular products in the brokerage channel  are return of premium, participating endowment, and critical  illness.\nADAMS has multiple international business partners across  Asia, including banks and non-financial institutions. ADAMS  focuses on protection products that generate risk premiums,  such as term life insurance, personal accident insurance, and  supplemental health insurance.\nAt the end of 2013, Aegon Religare had a number of term plans,  traditional individual participating products, traditional pension  participating products, unit-linked plans, and health products. \nAs of November 30, 2013, there were 70 life insurance  companies in the market, including 42 domestic life companies  and 28 foreign life insurers. As of November 30, 2013,  Aegon-CNOOC ranked thirty-ninth among life insurance  companies and twelfth among foreign life companies, based  on total premium income . The company’s market share  among foreign-invested companies was 2.5% 1 . In descending  order, Aegon-CNOOC’s channel contributions were brokerage,  bancassurance, direct marketing, group and agency annual  premium equivalent production and bancassurance, group,  brokerage, and direct marketing and agency first year  premium production. \nTLB main products consist of USD Guaranteed Universal Life  (GUL) and USD term plans in 2013 for the high-net-worth  market, and a new range of products was launched in the  fourth quarter of 2013.\nAegon Sony Life sells variable annuities. It provides a guaranteed  lifetime withdrawal benefit (GLWB) with a rollup function of 3%  per annum during the deferral period and a guaranteed minimum  accumulation benefit (GMAB). The GMAB product has a 105%  trigger feature that allows the customer to receive either  a lump-sum withdrawal of the difference between the initial  premium and account value or have the difference transferred  into a separate non-guaranteed account.\nOn November 14, 2013, the CIRC announced the China Life  Insurance Experienced Critical Illness Table (2006-2010). As  of December 31, 2013, the table is to be used as the basis for  evaluating the statutory reserves of critical illness products.  The table is expected to have a profound impact on product  innovation in the life insurance industry in China. \n1 Source: China Insurance Regulatory Commission (CIRC).\nNon-life\nOverview of business lines \nLife and savings\nCompetition\nChina - Aegon-CNOOC\nUniversal life and term products\nIndividual savings and retirement"}]}
+{"image": "doclay/doclay_14934.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "62 Dialog Semiconductor Plc | Annual report and accounts 2012  |  Section 4 | Consolidated financial statements and notes\nNotes to the consolidated financial statements\nFor the year ended 31 December 2012 \nThe amendments to IAS 19 Employee Benefits were issued in December 2010 and are effective for annual periods beginning on or after 1 January 2013.  The amendments especially relate to:\nSince the Group does not operate any defined benefit plan, the Group does not expect a material effect on its financial statements resulting from this  amendment. \nImprovements to IFRSs – a collection of amendments to International Financial Reporting Standards (annual improvements project)  The IASB has also issued a collection of amendments to various IFRSs (“Improvements to IFRSs”) in May 2012, which are effective for annual periods  beginning on or after 1 January 2013. This includes amendments to various existing IFRSs. Dialog does not expect a material impact on the financial  position nor the financial performance of Dialog. The amended standards have not yet been endorsed by the EU. \nIn addition, the following interpretation has been issued: \nThe Group does not intend to make early application of the amended or revised Standards and Interpretation listed above. \nThe consolidated financial statements include Dialog Semiconductor Plc and its subsidiaries as at 31 December each year: \nPrinciples of consolidation and investments in affiliated companies \nInterpretation Title  Effective date  IFRIC 20 $^{1)}$  Stripping Costs in the Production Phase of a Surface Mine  1 January 2013 \n$^{1)}$ IFRIC 20 is not relevant to the operations of the Group \n eliminating an option to defer the recognition of gains and losses, known as the ‘corridor method’, improving comparability and faithfulness of  presentation;\n streamlining the presentation of changes in assets and liabilities arising from defined benefit plans, including requiring remeasurements to be  presented in other comprehensive income (OCI), thereby separating those changes from changes that many perceive to be the result of an entity’s  day-to-day operations;\n enhancing the disclosure requirements for defined benefit plans, providing better information about the characteristics of defined benefit plans  and the risks that entities are exposed to through participation in those plans.\nName  Country of incorporation Participation Dialog Semiconductor GmbH  Germany 100% Dialog Semiconductor B.V.  The Netherlands 100% Dialog Semiconductor (UK) Limited UK 100% Dialog Semiconductor Inc.  USA 100% Dialog Semiconductor KK  Japan 100% Dialog Semiconductor Hong Kong Limited  Hong Kong  100% Dialog Semiconductor (Italy) S.r.l.  Italy 100% Dialog Semiconductor Arastirma Gelistirme ve Ticaret A.S.  Turkey 100% Dialog Semiconductor Trading (Shanghai) Limited China 100%\nSubsidiaries are fully consolidated from the date of acquisition, being the date on which Dialog obtains control, and continue to be consolidated until  the date such control ceases. \nThe financial statements of the subsidiaries are prepared for the same reporting period as the parent company, using consistent accounting policies. \nAll intra-group balances, transactions, unrealised gains and losses resulting from intra-group transactions and dividends are eliminated in full. \nIAS 19 Employee Benefits (amended) \n2. Summary of significant accounting policies continued\n"}]}
+{"image": "doclay/doclay_6407.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "An Dao Makeup Artist, Ballroom Dancer, New Yorker\nAt  35 , An Dao is decades younger than most heart valve recipients. Yet, before her valve replacement surgery, the New York makeup artist who enjoys tennis and dancing says: “I’d reached a point where I felt old.” One day, while crossing the street, Dao doubled over, gasping for breath. She knew then she could no longer ignore the valve problem that, years earlier, doctors had warned her about. Her timing was fortunate. In September  2000 , Dao became one of the first U.S. patients to receive the newly approved Carpentier-Edwards mitral PERIMOUNT pericardial tissue heart valve in a surgery performed  by Dr. Delos M. Cosgrove at the renowned Cleveland Clinic. Today, Dao enjoys all kinds of activities, including her favorite, ballroom dancing. “I appreciate life so much more now,” she says.\nChoosing the right  replacement heart valve is an important decision, and clinicians and patients faced with this choice are increasingly selecting  tissue valves because  of the quality-of-life  advantages they offer  over mechanical valves."}]}
+{"image": "doclay/doclay_33020.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "– 11 –\n0 . 9 × 150 , 000 = 135 , 000 . As we will discuss in § 4, the decline in received light produced by a transit can be balanced by the gravitational lensing produced by the white dwarf. While this may make it difficult or impossible to detect transits in some systems, lensing produces strong, distinctive signatures, including ati-transits, in others.\nWe can derive a rough estimate of the fraction of Kepler targets that might be orbited by transiting white dwarfs by generating a population of stars, including both singles and binaries, and then considering the evolution of each system. We identify those that will become main sequence stars that are both (1) in a range of masses likely to be monitored by Kepler , and (2) orbited by white dwarfs. We then compute the probability that the white dwarf will transit during the time of Kepler monitoring. For short orbital periods, the probability is R ∗ /a , where R ∗ is the radius of the monitored star and a is the final orbital separation. For orbital periods longer than τ$_{monitor}$ , the duration of monitoring, we multiply by a factor of τ$_{monitor}$/P$_{orb}$.\nWe assume that 40% of all stellar systems are singles, and that the remainder are of higher multiplicity. We use a Miller-Scalo IMF (Miller & Scalo 1979) to select the masses of all single stars, and to select the primary mass for all multiples. This has the effect of favoring low-mass stars, even though we generate the full mass spectrum. The only multiple systems we explicitly consider are binaries. We select the secondary mass as follows: M 2 = M $_{1}$× u 0 . $^{8}$, where u is a random number chosen from a uniform distribution in the range 0 − 1 . We then generate orbital separations, selecting uniformly in log space from separations as small as three times the radius of the primary, and as large as 10 4 AU.\nPrimary stars will fill their Roche lobes at some point in their evolution if the orbital separation lies within roughly an AU. This range of separations encompasses a large fraction of all binaries. Roche-lobe filling will lead either to a common envelope phase or to stable mass transfer. While a large fraction of common envelopes may end in mergers, those binaries that survive will have small orbital separations and therefore high probability of yielding transits. When mass transfer is stable, the final separation may be somewhat larger than the initial separation, but most orbits are smaller than a few AU (see Figure 3).\nThe paragraph above describes the key reason why transiting white dwarfs must be common: they are produced by a large fraction of all primordial binaries. We used a simple\nvalue to which we normalize can therefore be viewed as a sort of average.\n3.1. Calculations"}]}
+{"image": "doclay/doclay_73530.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS OF AMERICAN AIRLINES GROUP INC.\nIn certain transactions, including certain aircraft financing leases and loans, the lessors, lenders and/or other parties have rights to terminate the transaction based on changes in foreign tax law, illegality or certain other events or circumstances. In such a case, we may be required to make a lump sum payment to terminate the relevant transaction.\nWe have general indemnity clauses in many of our airport and other real estate leases where we as lessee indemnify the lessor (and related parties) against liabilities related to our use of the leased property. Generally, these indemnifications cover liabilities resulting from the negligence of the indemnified parties, but not liabilities resulting from the gross negligence or willful misconduct of the indemnified parties. In addition, we provide environmental indemnities in many of these leases for contamination related to our use of the leased property.\nUnder certain contracts with third parties, we indemnify the third-party against legal liability arising out of an action by the third-party, or certain other parties. The terms of these contracts vary and the potential exposure under these indemnities cannot be determined. We have liability insurance protecting us for some of the obligations we have undertaken under these indemnities.\nAmerican is required to make principal and interest payments for certain special facility revenue bonds issued by municipalities primarily to build or improve airport facilities and purchase equipment, which are leased to American. The payment of principal and interest of certain special facility revenue bonds is guaranteed by AAG. As of December 31, 2019, the remaining lease payments through 2035 guaranteeing the principal and interest on these bonds are $589 million and the current carrying amount of the associated operating lease liability in the accompanying consolidated balance sheet is $321 million.\nAs of December 31, 2019, AAG had issued guarantees covering approximately $725 million of American’s special facility revenue bonds (and interest thereon) and $8.1 billion of American’s secured debt (and interest thereon), including the Credit Facilities and certain EETC financings.\nWe have agreements with companies that process customer credit card transactions for the sale of air travel and other services. Our agreements allow these credit card processing companies, under certain conditions, to hold an amount of our cash (referred to as a holdback) equal to a portion of advance ticket sales that have been processed by that company, but for which we have not yet provided the air transportation. Additional holdback requirements in the event of material adverse changes in our financial condition will reduce our liquidity in the form of unrestricted cash by the amount of the holdbacks. These credit card processing companies are not currently entitled to maintain any holdbacks pursuant to these requirements.\n(g) Credit Card Processing Agreements\n(h) Labor Negotiations\nAs of December 31, 2019, we employed approximately 133,700 active full-time equivalent employees, of which 29,500 were employed by our regional operations. Approximately 85% of employees are covered by collective bargaining agreements (CBAs) with various labor unions and approximately 22% of employees are covered by CBAs that will become amendable within one year. Agreements in principle were reached on January 30, 2020 for joint collective bargaining agreements (JCBAs) covering our mainline maintenance, fleet service, stock clerks, maintenance control technicians and maintenance training instructors. Those agreements are subject to membership ratification vote. Additionally, the post- Merger JCBAs covering our pilots and flight attendants became amendable in January 2020 and December 2019, respectively. Negotiations continue for new agreements for these workgroups as well as for CBAs covering certain employee groups at our wholly-owned regional subsidiaries.\nSupplemental disclosure of cash flow information and non-cash investing and financing activities are as follows (in millions):\n13. Supplemental Cash Flow Information\nYear Ended December 31, 2019 2018 2017 Non-cash investing and financing activities: Settlement of bankruptcy obligations $ 7 $ — $ 15 Equity Investment — — 120 Supplemental information: Interest paid, net 1,111 1,091 1,040 Income taxes paid 8 18 20\n111"}]}
+{"image": "doclay/doclay_9333.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "DANAHER CORE V ALUES\nTHE BEST TEAM WINS\nCUSTOMERS TALK, WE LISTEN\nCONTINUOUS IMPROVEMENT ( KAIZEN )  IS OUR WAY OF LIFE \nLEADING EDGE INNOVATION  DEFINES OUR FUTURE\nWE COMPETE FOR SHAREHOLDERS\nProfits are important because they attract and retain  loyal shareholders.\nShareholders secure our future by providing capital for  investment and growth.\nWe continuously apply our creativity to the technologies  of products, services, and processes.\nOut-of-the-Box ideas, both large and small,  add value to our enterprise.\nWe accomplish GLYPH<210>breakthroughsGLYPH<211> through the  Policy Deployment process.\nWe aggressively and continuously eliminate waste in every  facet of our business processes.\nThe Danaher Business System IS our culture.\nRobust, repeatable processes yield superior Quality, Delivery,  and Costs that satisfy our customers beyond their expectations.\nWe base our strategic plan on the Voice-of-the-Customer.\nQuality First, ALWAYS!\nAssociates are our most valued assets.\nWeGLYPH<213>re passionate about retaining, developing  and recruiting the best talent available.\nDanaher and its associates win because:\nWE ARE TEAM-ORIENTED WITH INVOLVEMENT BY ALL.\nWE SEEK FACT-BASED, ROOT CAUSE SOLUTIONS; NOT BLAME. \nWE ARE ACCOUNTABLE FOR RESULTS, AND WE DELIVER.\nWE ARE NON-POLITICAL AND NOT BUREAUCRATIC.\nWE HAVE HIGH INTEGRITY AND RESPECT FOR OTHERS.\nWINNING IS FUN."}]}
+{"image": "doclay/doclay_861.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "SMFG Capital Ratio Information\n■  Standardized Approach\n1. Scope\n2. Credit Risk-Weighted Asset Calculation Methodology\n3. Exposure Balance by Risk Weight Segment\n■  Credit Risk Mitigation (CRM) Techniques\n1. Risk Management Policy and Procedures\nA. Collateral (Eligible Financial or Real Estate Collateral)\nB. Guarantees and Credit Derivatives\n(1) Scope and Management\nThe following consolidated subsidiaries have adopted the standardized approach for exposures as of March 31, 2011 (i.e. consolidated  subsidiaries not listed in the “Internal Ratings-Based (IRB) Approach: 1. Scope” on page 181).\nSumitomo Mitsui Finance and Leasing Co., Ltd., Kansai Urban Banking Corporation and Cedyna Financial Corporation\nThese are consolidated subsidiaries judged not to be significant in terms of credit risk management based on the type of business, scale,  and other factors. These subsidiaries will adopt the standardized approach on a permanent basis. \nA 100% risk weight is applied to claims on corporates in accordance with Article 45 of the Notification, and risk weights corresponding to  country risk scores published by the Organization for Economic Co-operation and Development (OECD) are applied to claims on sovereigns  and financial institutions.\nIn calculating credit risk-weighted asset amounts, SMFG takes into account credit risk mitigation (CRM) techniques. Specifically, amounts  are adjusted for eligible financial or real estate collateral, guarantees, and credit derivatives or by netting loans against the obligors’ deposits  with SMFG financial institutions. The methods and scope of these adjustments and methods of management are as follows.\nSMBC designates deposits and securities as eligible financial collateral, and land and buildings as eligible real estate collateral. \nReal estate collateral is evaluated by taking into account its fair value, appraisal value, and current condition, as well as our lien  position. Real estate collateral must maintain sufficient collateral value in the event security rights must be exercised due to delinquency.  However, during the period from acquiring the rights to exercising the rights, the property may deteriorate or suffer damage from  earthquakes or other natural disasters, or there may be changes in the lien position due to, for example, attachment or establishment of  liens by a third party. Therefore, the regular monitoring of collateral is implemented according to the type of property and the type of  security interest.\nGuarantors are sovereigns, municipal corporations, credit guarantee corporations and other public entities, financial institutions, and  C&I companies. Counterparties to credit derivative transactions are mostly domestic and overseas banks and securities companies.\nCredit risk-weighted asset amounts are calculated taking into account credit risk mitigation of guarantees and credit derivatives  acquired from entities with sufficient ability to provide protection such as sovereigns, municipal corporations and other public sector  entities of comparable credit quality, and financial institutions and C&I companies with sufficient credit ratings.\nSMFG  2011 190\nNotes: 1. The above amounts are exposures after CRM (but before deduction of direct write-offs). Please note that for off-balance sheet assets the credit equivalent amount has been  included.\n2. “Securitization exposures” have not been included.\nMarch 31 Billions of yen 2011 2010 Of which assigned  country risk score Of which assigned  country risk score 0% ............................................................................................ ¥ 8,773.2  ¥ 81.6  ¥ 6,454.8 ¥ 89.9 10% .......................................................................................... 243.3 — 277.8 — 20% .......................................................................................... 814.8 298.2 801.0 343.4 35% .......................................................................................... 1,061.6 — 1,126.2 — 50% .......................................................................................... 377.7 2.8 210.7 1.2 75% .......................................................................................... 3,242.1 — 1,352.8 — 100% ........................................................................................ 5,645.9 0.1 5,567.0 0.1 150% ........................................................................................ 78.4 — 41.1 — Capital deduction ..................................................................... 0.0 — 0.0 — Others ....................................................................................... 0.0 — 0.0 — Total .......................................................................................... ¥20,237.0 ¥382.8 ¥15,831.4 ¥434.5\n(1) Consolidated Subsidiaries Planning to Adopt Phased Rollout of the IRB Approach\n(2) Other Consolidated Subsidiaries"}]}
+{"image": "doclay/doclay_52976.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Information Functions\nChecks whether the lock named  str  is in use (that is, locked). If so, it returns the connection identifier of the client session that holds the lock. Otherwise, it returns  NULL .\nThis function is unsafe for statement-based replication. A warning is logged if you use this function when binlog_format  is set to  STATEMENT .\nReleases all named locks held by the current session and returns the number of locks released (0 if there were none)\nThis function is unsafe for statement-based replication. A warning is logged if you use this function when binlog_format  is set to  STATEMENT .\nReleases the lock named by the string  str  that was obtained with  GET_LOCK() . Returns  1  if the lock was released,  0  if the lock was not established by this thread (in which case the lock is not released), and  NULL  if the named lock did not exist. The lock does not exist if it was never obtained by a call to GET_LOCK()  or if it has previously been released.\nThe  DO  statement is convenient to use with  RELEASE_LOCK() . See Section 13.2.3, “DO Statement” .\nThis function is unsafe for statement-based replication. A warning is logged if you use this function when binlog_format  is set to  STATEMENT .\n2279\nName Description BENCHMARK() Repeatedly execute an expression CHARSET() Return the character set of the argument COERCIBILITY() Return the collation coercibility value of the string argument COLLATION() Return the collation of the string argument CONNECTION_ID() Return the connection ID (thread ID) for the connection CURRENT_ROLE() Return the current active roles CURRENT_USER() ,  CURRENT_USER The authenticated user name and host name DATABASE() Return the default (current) database name FOUND_ROWS() For a SELECT with a LIMIT clause, the number of rows that would be returned were there no LIMIT clause ICU_VERSION() ICU library version LAST_INSERT_ID() Value of the AUTOINCREMENT column for the last INSERT ROLES_GRAPHML() Return a GraphML document representing memory role subgraphs\nTable 12.20 Information Functions\n12.16 Information Functions\n• RELEASE_LOCK( str )\n• RELEASE_ALL_LOCKS()"}]}
+{"image": "doclay/doclay_5475.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "FINANCIAL SECTION\n12 HARSCO CORPORATION 2003 ANNUAL REPORT\nGLOSSARY OF FINANCIAL  TERMS\nEconomic Value Added (EVA ® )\nReturn on Sales\nReturn on Average Equity  (ROE)\nCurrent Ratio\nTotal Debt to Total Capital\nReturn on Average Assets (RO A)\nReturn on Capital (ROC)\nGross Profit\nEVA is net operating profit after  tax minus an appr opriate charge for  the  opportunity  cost  of  all  capital invested. As such, EVA is an  estimate of true \"economic\" pr ofit, or  the  amount  by  which  ear nings  exceed or fall short of the required  minimum rate of r etur n that shar eholders  and  lenders  could  get  by  investing  in other securities of comparable  risk.\nMeasures income in relation to  sales. Retur n on sales is  calculated  by  dividing  income  fr om  continuing operations by total revenues.\nMeasures the rate of return on the equity held by common stock  shar eholders.  Retur n  on  average  equity  is calculated by dividing income from continuing operations by the quarterly  weighted  average  equity .\nMeasures the short-term liquidity  of  the  Company  by  r eflecting  its  ability  to  meet  curr ent  obligations  fr om current assets. The current ratio  is  calculated  by  dividing  curr ent  assets  by  curr ent  liabilities.\nMeasures the relative capital  contributions of debt and equity and  indicates  the  degr ee  of  leverage.  T otal debt to capital is calculated by  dividing total debt (short-term borr owings and  long-term  debt  including current maturities) by total capital (the sum of total debt  and  shar eholders'  equity).\nMeasures how efficiently the  Company's total assets ar e being utilized.  Retur n  on  average  assets  is calculated by dividing income from continuing operations befor e inter est expense,  income  taxes  and minority interest by quarterly  weighted average assets (excluding assets of  discontinued  operations).\nMeasures how effectively the  Company is using capital to pr oduce  ear nings.  Retur n  on  capital  is  calculated by dividing income from  continuing operations, excluding after -tax inter est expense  charges,  by  quarterly weighted average total debt and  equity .\nMeasures the profitability of the  Company  by  calculating  total  r evenues  less  costs  and  expenses  associated directly with or allocated to pr oducts sold or services r ender ed.\n"}]}
+{"image": "doclay/doclay_58334.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "UCI CYCLING REGULATIONS \nSeparating tied nations  Following each event, nations that are tied on points in the general ranking shall be \nSeparating tied nations  2.14.055  Following each event, nations that are tied on points in the general ranking shall be  separated by the greatest number of 1 st places, 2 nd places, etc. considering only the  places for which points are awarded. \n2.14.056 For one-day events, the leading nation in the UCI Women Junior Nations’ Cup ranking  shall appear on the podium for the official ceremony. \n2.14.057 The UCI shall award a distinctive mark to the riders of the nation which is leading the  UCI Women Junior Nations’ Cup ranking and riders must wear this emblem during  podium ceremonies, according to the UCI’s instructions guidelines. \n2.14.058 The UCI shall award a trophy to the nation which wins the final ranking of the UCI Women  Junior Nations’ Cup. \n2.14.059 The order of team cars in the race will be determined as follows: \n-  First event of the year:  1.  the car of the team which won the preceding UCI Women Junior Nations’ \nFirst event of the year:  1.  the car of the team which won the preceding UCI Women Junior Nations’  Cup (for the first year of the competition, the car of the winner of the last  UCI Women Junior Nations’ Cup ranking for the preceding year);  2.  the cars of national teams represented at the sports directors’ meeting; \nUCI Women Junior Nations’ Cup ranking for the preceding year);  2.  the cars of national teams represented at the sports directors’ meeting;  3.  the cars of mixed teams; \n2.  the cars of national teams represented at the sports directors’ meeting;  3.  the cars of mixed teams;  4.  the cars of teams which failed to confirm their starting riders by the \n3.  the cars of mixed teams;  4.  the cars of teams which failed to confirm their starting riders by the  deadline set under article 1.2.090;  5.  the cars of teams not represented at the sports directors’ meeting. \ndeadline set under article 1.2.090;  5.  the cars of teams not represented at the sports directors’ meeting. \n-  For the other events:  1.  the cars of the teams represented at the sports directors’ meeting in the \nFor the other events:  1.  the cars of the teams represented at the sports directors’ meeting in the  order of the UCI Women Junior Nations’ Cup ranking, as established the  day before the race;  2.  the cars of the teams represented at the sports directors’ meeting which \nday before the race;  2.  the cars of the teams represented at the sports directors’ meeting which  have not yet earned any points in the UCI Women Junior Nations’ Cup  ranking;  3.  the cars of teams which failed to confirm their starting riders by the time \nranking;  3.  the cars of teams which failed to confirm their starting riders by the time  limit set under article 1.2.090;  4.  the cars of teams not represented at the sports directors’ meeting. \nlimit set under article 1.2.090;  4.  the cars of teams not represented at the sports directors’ meeting. \nThe car of a team covered by point 1, 2 or 3, but which falls into the categories  covered by points 4 or 5, will be in group 4 or 5 as appropriate. \nWithin groups 2, 3, 4 and 5 the order is determined by drawing lots. \n(text modified on 1.01.17) \nFor stage races, the nation leading the UCI Women Junior Nations’ Cup ranking shall be  presented on the start podium for each stage and on the finish podium for the official  ceremony after the final stage. \nNations tied on points in the final ranking shall be ranked on the basis of the largest  number of 1$^{st}$ places, 2$^{nd}$ places, etc. \nIf there is still a tie, the best place in the most recent event shall decide the nations'  rankings. \nE170421 \nROAD RACES \n188 "}]}
+{"image": "doclay/doclay_45686.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "7.  Radio Communication Procedures \nMany airports are now providing completely automated weather, radio check capability and airport  advisory information on an automated UNICOM system. These systems offer a variety of features,  typically selectable by microphone clicks, on the UNICOM frequency. Availability of the automated  UNICOM will be published in the Airport/Facility Directory and approach charts. \nUnderstanding Communication on a Common Frequency  The key to communications at an airport without an operating control tower is selection of the  correct common frequency. The acronym CTAF, which stands for Common Traffic Advisory  Frequency, is synonymous with this program. A CTAF is a frequency designated for the purpose of  carrying out airport advisory practices while operating to or from an airport without an operating  control tower. The CTAF may be a UNICOM, MULTICOM, FSS, or tower frequency and is identified in  appropriate aeronautical publications. \nCommunication/Broadcast Procedures  A MULTICOM frequency of 122.9 will be used at an airport that is non-towered and does not have a  FSS or UNICOM. \nRecommended Traffic Advisory Practices  Although a remote pilot-in-command is not required to communicate with manned aircraft when in  the vicinity of a non-towered airport, safety in the National Airspace System requires that remote  pilots are familiar with traffic patterns, radio procedures, and radio phraseology. \nWhen a remote pilot plans to operate close to a non-towered airport, the first step in radio  procedures is to identify the appropriate frequencies. Most non-towered airports will have a  UNICOM frequency, which is usually 122.8; however, you should always check the Cart Supplements  U.S. or sectional chart for the correct frequency. This frequency can vary when there are a large  number of non-towered airports in the area. For non-towered airports that do not have a UNICOM  or any other frequency listed, the MULTICOM frequency of 122.9 will be used. These frequencies  can be found on a sectional chart by the airport or in the Chart Supplements publication from the  FAA.\nWhen a manned aircraft is inbound to a non-towered airport, the standard operating practice is for  the pilot to “broadcast in the blind” when 10 miles from the airport. This initial radio call will also  include the position the aircraft is in relation to north, south, east or west from the airport. For  example: \nTown and Country traffic, Cessna 123 Bravo Foxtrot is 10 miles south inbound for landing,  Town and Country traffic. \nRecommended Traffic Advisory Practices  Although a remote pilot-in-command is not required to communicate with manned aircraft when in \nCommunication/Broadcast Procedures  A MULTICOM frequency of 122.9 will be used at an airport that is non-towered and does not have a \nUnderstanding Communication on a Common Frequency  The key to communications at an airport without an operating control tower is selection of the \nAn airport may have a full or part-time tower or flight  service station (FSS) located on the airport, a full or  part-time universal communications (UNICOM) station or no aeronautical station at all. There are  three ways for pilots to communicate their intention and obtain airport/traffic information when  operating at an airport that does not have an operating tower—by communicating with an FSS, a  UNICOM operator, or by making a self-announce broadcast. Figure 7-1.  Phonetic Alphabet.\nRemote Pilot – Small Unmanned Aircraft Systems Study Guide \n40"}]}
+{"image": "doclay/doclay_62246.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Page 4 of 4 \nCERTIFICATE OF CORRECTION (continued)  U.S.  Pat.  No.  9,104,101 B2 \n0~  0  Col. 181, lines 35-45, Above \"Using each\" delete\" R=  1(1-:r  H \".  Col. 181, line 53, \"(P AB)\" should be --(PAB)--.  Col. 181, line 58, \"keY,\" should be --keV,--.  Col. 181, line 66, \"\"L/pattem\")\" should be --\"LIS pattern\")--.  In the Claims  Col. 186, line 36 (claim 7), \"R$^{9}$ato R 9 c\" should be --R $^{9}$ato R9 c __ _ "}]}
+{"image": "doclay/doclay_8629.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "exploration overview\nAustralia\nRavenswood\nopen pit), the Buck Reef West underground mine and potentially the Mt Wright deposit. Historically Sunset, Grant and Rob Roy, a series of narrow, high grade (+30g/t Au), flat to moderate dipping quartz veins were exploited. \nThe Ravenswood deposits represent four styles of mineralisation.\nRavenswood is located approximately 125km south-west of Townsville and 80km east of Charters Towers in  north-east Queensland.\nResolute assumed management  control of the Ravenswood mine on 1 March 2004. \nThe project encompasses a series of exploration permits and mining leases covering an area of approximately 700km 2 . These extend from Mingela in the north to south of Ravenswood, a distance of more than 50km.\nWith the acquisition of the Ravenswood mine a significant land package with a long history for gold and base metals exploration was acquired. Reappraisal of this land package and reprioritisation of exploration targets is in progress.\nThe Ravenswood mine comprises mining operations on the Sarsfield open pit (which includes part of the Nolan’s\nThe vein hosted gold mineralisation at Ravenswood occurs within the upper portion of the 410 million year old Jessops Creek Tonalite. The Tonalite is a heterogeneous body and a number of unnamed diorite bodies and other mafic differentiates occur within the unit.\n• Sarsfield and Nolan’s represent a network of flatly dipping sulphide- quartz veins within the host tonalite\n• Sunset vein types are a series of high grade (+30g/t Au), moderately to flat dipping quartz-sulphide veins\n• Buck Reef West is a sulphidic fault breccia deposit, containing pyrrhotite or pyrite, and post dates the Sunset vein system\n• Mt Wright is a rhyolite breccia \nGeology and Mineralisation \nRavenswood Ravenswood Mine Area QUEENSLAND Charters Towers Mingela Mt Wright Townsville 25km Mining Leases Exploration Permits FIGURE 6 Ravenswood location 18\nRESOLUTE MINING LIMITED 2004 ANNUAL REPORT"}]}
+{"image": "doclay/doclay_69421.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Draft Document for Review December 5, 2019 4:33 pm\n8456ch_DS_HMC_Plan.fm\n8\nIBM DS8900F Management  Console planning and setup\nThis chapter describes the planning tasks that are involved in the setup of the required  DS8900F Management Console, which is also known as the Hardware Management Console  (HMC).\nThis chapter covers the following topics:\n203\n' Copyright IBM Corp. 2 019. All rights reserved.\nGLYPH<SM590000> DS8900F Management Console overview\nGLYPH<SM590000> Management Console software\nGLYPH<SM590000> Management Console activities\nGLYPH<SM590000> Management Console Network Settings\nGLYPH<SM590000> Management Console user management\nGLYPH<SM590000> Secondary Management Console\n"}]}
+{"image": "doclay/doclay_64534.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "US 9,703,193 B2 \n138 \n137 \n-continued \n-continued \n-continued  0~  S 03 - 0  Q  0-s+  -6  0  0  ~  SO3 - 0  Q  0-r  0  Q  0-r \n0  CF3  O ~S03- 0  O~S03-"}]}
+{"image": "doclay/doclay_6705.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "\nTransmission  Control Module\nEngine Timing  System\nAir Flow  System\nkeys to earning this business. According  to Kunihiko, it requires around-the-clock  communications and sharing of technol- ogy and experience.\nBorgWarner benefits from being a “local”  company for our customers, wherever  they may be. In Japan, our chain products  business and our major joint venture for  transmission products have operated in  that country since the mid-1960s. We  have been in Germany for over 50 years.  This local presence, along with leading  technology, continues to allow us to  balance our sales growth with the shifting  market shares of our customers.\nWith global customers come global programs, like the family of four-cylinder  gasoline engines produced by the Global  Engine Alliance, a joint venture between  Hyundai, DaimlerChrysler and Mitsubishi;  or VW/Audi’s gasoline 4-cylinder world  engine to be built in China. Consistent  quality and manufacturing of our engine  products, coordinated with facilities in  North America, Europe and Asia, are \nIn the past five years BorgWarner has  won new business that gives it one of the  broadest customer bases in the industry.  This transition reflects years of work  behind the scenes, building relationships  and demonstrating and proving our tech- nology to customers like Honda, Hyundai  and VW/Audi. Kunihiko Mishima and his  fellow engineers have been in the forefront  of this endeavor, designing customized  chain products for the needs of Japanese  automakers as they develop more efficient  engines that benefit from the durability of  chain timing systems.Engineering Supervisor  Morse TEC  Nagoya, Japan\nKunihiko Mishima\nOur understanding of powertrain function sets us apart from our competitors. Our expertise  is showcased in intelligent all-wheel drive systems like those used by Hyundai, in our new  transmission technology being rolled out by Volkswagen/Audi, and in variable cam timing that  will be introduced by General Motors in 2006 models.\n16\n“ Local support for automakers builds our global  customer  base.”\nP R O D UCT LEADERS HIP M EANS CUST O MER DIVE R S ITY\n17"}]}
+{"image": "doclay/doclay_26872.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "that Assumption 2 holds. Define the subset of all continuously differentiable characteristic functions by ¯ C $^{(1)}$.\nIn model 5 equations involve a product of the regression function g with f$_{x}$ ∗ . Products of generalized functions in S ∗ do not always exist and so addi- tional restrictions are needed in that model. If g is an arbitrary element of S $^{∗}$, then for the product to exist, f$_{x}$ ∗ should be in O$_{M}$ . On the other hand, if f$_{x}$ ∗ is an arbitrary generalized density it is sufficient that g and h$_{k}$ belong to the space of d times continuously differentiable functions with derivatives that are majorized by polynomial functions for gf$_{x}$ ∗ , h$_{k}$f$_{x}$ ∗ to be elements of S $^{∗}$. Indeed, the value of the functional h$_{k}$f$_{x}$ ∗ for an arbitrary ψ ∈ S is defined by\nhere F is the distribution (ordinary bounded) function and this integral ex- ists because ψ and all its derivatives go to zero at infinity faster than any polynomial function. Denote by ¯ S B, 1 the space of continuously differentiable functions g ∈ S ∗ such that the functions h$_{k}$ ( x ) = x$_{k}$g ( x ) are also continu- ously differentiable with all derivatives majorized by polynomial functions . Since the products are in S ∗ then the Fourier transforms of the products are defined in S $^{∗}$. Further restrictions requiring the Fourier transforms of the products gf$_{x}$ ∗ and h$_{k}$f$_{x}$ ∗ to be continuously differentiable functions in S ∗ would remove any restrictions on f$_{u}$ for the convolution to exist. Denote the space of all continuously differentiable functions in S ∗ by ¯ S $^{(1)}$.\n( h$_{k}$f$_{x}$ ∗ , ψ ) = ( − 1) d ∫ F$_{x}$ ∗ ( x ) ∂ (1 ,..., $^{1)}$( h$_{k}$ ( x ) ψ ( x )) dx ;\n33"}]}
+{"image": "doclay/doclay_13682.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "\nOPHTHALMOLOGY – FROM THE OCULAR SURFACE TO THE OPTIC NERVE.\nA grandfather, unknowingly under siege by a silent thief of sight. A mother, suffering from painfully dry eyes that make it impossible to watch an outdoor soccer game. A child, miserable with an eye infection. Since our inception over 50 years ago, allergan has relentlessly pursued and developed new therapeutic agents to treat eye diseases that affect millions of people around the world.\nAcross the pharmaceutical eye care spectrum, we have multiple growth platforms that present hope for people suffering from ocular diseases. Our full line of eye care pharmaceutical products addresses a wide range of ocular conditions, including dry eye, infection, inflammation, allergies and glaucoma. And we are continually looking into the future for ways to apply our research and development expertise to improve treatments for other ocular conditions.\nDRY EYE DISEASE – A THERAPEUTIC BREAKTHROUGH. In the healthy eye, natural tears are secreted by the eye’s lacrimal and accessory glands and perform such vital functions as providing lubrication, defending against bacteria and flushing away foreign particles. In chronic dry eye disease, one of the most prevalent problems eye care professionals address in their practices, abnormalities and deficiencies in the tear film result in pain and irritation. Initiated by a variety of causes, moderate to severe dry eye is often associated with inflammation and can result in permanent damage to the tear producing lacrimal glands. The incidence increases with age; after menopause in women; and in patients with systemic diseases such as rheumatoid arthritis, diabetes and lupus.\nPreviously, doctors could only help patients temporarily alleviate symptoms with artificial tears. With Allergan’s intro- duction of RESTASIS (cyclosporine ophthalmic emulsion 0.05%), people afflicted with painfully dry eyes have access to a medication that increases normal tear production by treating the underlying cause of the disease.\nAllergan intends to build on its RESTASIS success by introducing other innovative therapeutic dry eye solutions. For example, we are working with Inspire Pharmaceuticals, Inc. on diquafosol, a novel agent for potential use by dry eye sufferers. "}]}
+{"image": "doclay/doclay_25316.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "of no replicability null hypotheses. In the alternative procedure, H$_{j}$ is rejected if p$_{1}$$_{j}$ ≤ α/m and p$_{2}$$_{j}$ ≤ α/m . The two procedures differ in the thresholds used in each of the studies. The cut-off for p$_{1}$$_{j}$ is larger in the alternative procedure, since α$_{1}$ < α . However, the cut-off for p$_{2}$$_{j}$ may be substantially smaller in the alternative procedure, since ( α − α$_{1}$ ) / ∑ m i $_{=1}$I [ p$_{1}$$_{j}$ ≤ α$_{1}$/m ] may be significantly larger than α/m . This is so in the common setting where signal is sparse in the primary study, i.e. ∑ m j $_{=1}$h$_{1}$$_{j}$ ≪ m . Example E.1. Suppose we have m independent normal outcomes in each of the two\n∑ Example E.1. Suppose we have m independent normal outcomes in each of the two studies T$_{1}$$_{j}$, T$_{2}$$_{j}$, j = 1 . . . , m . In this example, E ( T$_{11}$ ) = µ$_{11}$, E ( T$_{21}$ ) = µ$_{21}$, V ar ( T$_{11}$ ) = V ar ( T$_{21}$ ) = 1 , and outcomes j = 2 , . . . , m have expectation 0 and variance 1. Con- sider first the power of the alternative procedure that applies Bonferroni on the max- imum of the two study p -values for FWER control at level α = 0 . 05 :\nwhere ∼ Φ ( · ) is the right tail of the standard normal distribution. Next, we compute the power of Procedure 3.1 with Bonferroni as the FWER controlling procedure. The probability of correctly selecting (PCS) the non-null hypothesis in the first study as well as k − 1 null hypotheses along with it is\nso the power is\nFigure 5 shows the power of the Bonferroni on maximum p -values procedure (left panel) and the power of Procedure 3.1 (right panel) for different configurations of ( µ$_{11}$, µ$_{21}$ ) , where ( α$_{1}$, α ) = (0 . 025 , 0 . 05) . In most configurations of µ$_{11}$ and µ$_{21}$ , Procedure 3.1 is more powerful than the Bonferroni on maximum p -values proce-\n36\nπ$_{2}$ = m ∑ k =1 P CS ( k ) × ∼ Φ ( z$_{1}$$_{−}$$_{(}$$_{α}$$_{−}$$_{α}$$_{1}$$_{)}$$_{/k}$ − µ$_{21}$ ) .\nP CS ( k ) = ∼ Φ ( z$_{1}$$_{−}$$_{α}$$_{1}$$_{/m}$ − µ$_{11}$ ) ( m − 1 k 1 ) ( α$_{1}$/m ) k − $^{1}$(1 − α$_{1}$/m ) m − $^{k}$,\nπ$_{1}$ = ∼ Φ ( z$_{1}$$_{−}$$_{α/m}$ − µ$_{11}$ ) × ∼ Φ ( z$_{1}$$_{−}$$_{α/m}$ − µ$_{21}$ ) ,"}]}
+{"image": "doclay/doclay_40032.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Europol Public Information \nmanuals, process definitions and procedures, flowcharts and  all such other documentation that is required to be supplied  by the Contractor to Europol under the  Framework Contract either pre-existing at the moment of the  Contract Date or  that must be generated by the Contractor for the purpose of  performing this  Framework Contract ;\n19 Regulation (EU) 2016/794 of the EU Parliament and of the Council of 11 May 2016 on the European Union  Agency for Law Enforcement Cooperation (Europol) and repealing Council Decisions 2009/371/JHA, 2009/934/JHA,  2009/935/JHA, 2009/936/JHA and 2009/968/JHA; \nPage 24 of 79 \nEuropol’s initials: \nContractor’s initials: \nForce Majeure: any unforeseeable and exceptional situation or event beyond the control of the parties which prevents either of  them from performing any of their obligations under the  Framework Contract  and/or the relevant  Specific Contract(s) or  Purchase Order(s), provided that such event(s) or situation(s) was not due to error or negligence on their part  or on the part of a sub-contractor, and could not have been  avoided by the exercise of due diligence. Defects in  equipment or material or delays in making it available,  labour disputes, strikes or financial problems cannot be \nEuropol Premises :  the offices of Europol, located at its headquarters at Eisenhowerlaan 73, 2517 KK, The Hague, The Netherlands  and its satellite building located at Jan Willem Frisolaan 13,  2517JR, The Hague, the Netherlands, any other future  Europol buildings/sites in the Netherlands and any other  site(s) identified in the Tender Specifications and/or Special  Conditions; \nEuropol :  the EU Agency for Law Enforcement Cooperation, as established by the “Europol Regulation” 19 and any legal  successor thereto and generally refers to the totality of  Europol staff and other staff of law enforcement agencies or  institutions and intergovernmental organisations performing  their tasks on  Europol’s Premises or in the EU Member  States or in other countries with whom Europol and/or the  European Union has concluded international agreements, as  required under the Europol’s legal framework. This includes  (without limitation) Liaison officers, Seconded national experts and Europol contractors;\ne-System:  EU Commission communication platform, intended for the  exchange of contractual and implementation electronic documents between EUIs (including Europol) and contractors.\nDue Remuneration :  the wage and any work related allowances to which the  Contractor’s Personnel  is entitled by virtue of law, and taking  into account relevant collective labour agreement and the  contract as agreed between the Contractor and the Contractor’s Personnel  in an employment contract; "}]}
+{"image": "doclay/doclay_45691.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "reference to the horizon, the pilot must be prepared  to fly IFR.\nThe human eye will see nothing outside that is dimmer than  the flight deck lighting. Always fly at night with the interior  lights as dim as possible. As the flight progesses and the  eyes adjust to the darkness, usually the interior lights can  be dimmed further, aiding the outside vision. If the interior  lights will not dim, that would increase the risk factors by  restricting the pilot’s outside vision—probably not the time  for a night flight.\nAlthough weather, terrain, airport conditions, and night versus  daylight flying each produce unique challenges, together  these factors conspire against a pilot’s senses. It is important  to understand that unwittingly these factors can create  visual illusions and cause spatial disorientation producing challenges the pilot did not anticipate.  [Figure 3-9]  Even the best trained pilots sometimes fail to recognize  problem  until it is too late to complete a flight safely.\nAn accident involving a Piper PA-32 and an airline transport  pilot illustrates how visual illusions can create problems  that lead to an accident. In this case, the aircraft collided with terrain during a landing. The sole occupant of the  airplane was an airline transport pilot who was not injured.  The airplane owned and operated by the pilot, sus tained substantial damage. The personal transportation flight was being operated in visual meteorological conditions (VMC) in mid-afternoon. Although it was not snowing, there was  snow on the ground.\nFigure 3-9.  Visual illusions are easy to see when shown in the examples above. The illusion on the left represents how the brain processes  color. The “brown” square on top and the “orange” square on the side are actually the same color. The illusion on the right appears  to have red lines that curve; however, they are straight. These illusions are representative of things we see in everyday life, except we  do not see them as they really are until it is sometimes too late. Understanding that visual illusions exist is a prime ingredient to being  better prepared to cope with risk.\nFigure 3-8.  A  chemical stick is useful to carry onboard the aircraft  at night. It comes in various colors, intensities, and durations, and  it provides ample illumination within the flight deck. This does not  replace the regulatory requirement of carrying flashlights.\n• Will the flight conditions allow a safe emergency  landing at night?\n•  Preflight all aircraft lights, interior and exterior, for  a night flight. Carry at least two flashlights—one for  exterior preflight and a smaller one that can be dimmed  and kept nearby.  [Figure 3-8]\nVisual Illusions\n3-7"}]}
+{"image": "doclay/doclay_58742.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Server System Variables\nType Integer Default Value 16777216 Minimum Value 16384 Maximum Value (64-bit platforms) 18446744073709547520 Maximum Value (32-bit platforms) 4294967295 Block Size 1024\nDeprecated Yes System Variable max_insert_delayed_threads Scope Global, Session Dynamic Yes SET_VAR  Hint Applies No Type Integer\nCommand-Line Format --max-join-size=# System Variable max_join_size Scope Global, Session Dynamic Yes SET_VAR  Hint Applies Yes Type Integer Default Value 18446744073709551615\nThis variable sets the maximum size to which user-created  MEMORY  tables are permitted to grow. The value of the variable is used to calculate  MEMORY  table  MAX_ROWS  values. Setting this variable has no effect on any existing  MEMORY  table, unless the table is re-created with a statement such as  CREATE TABLE  or altered with  ALTER TABLE  or  TRUNCATE TABLE . A server restart also sets the maximum size of existing  MEMORY  tables to the global  max_heap_table_size  value.\nThis variable is also used in conjunction with  tmp_table_size  to limit the size of internal in-memory tables. See Section 8.4.4, “Internal Temporary Table Use in MySQL” .\nmax_heap_table_size  is not replicated. See Section 17.5.1.21, “Replication and MEMORY Tables” , and Section 17.5.1.39, “Replication and Variables” , for more information.\nAs of MySQL 8.0.26, setting the session value of this system variable is a restricted operation. The session user must have privileges sufficient to set restricted session variables. See Section 5.1.9.1, “System Variable Privileges” .\n• max_insert_delayed_threads\n• max_join_size\nThis variable is a synonym for  max_delayed_threads . Like  max_delayed_threads , it is deprecated (because  DELAYED  inserts are not supported) and subject to removal in a future MySQL release.\nAs of MySQL 8.0.26, setting the session value of this system variable is a restricted operation. The session user must have privileges sufficient to set restricted session variables. See Section 5.1.9.1, “System Variable Privileges” .\n832"}]}
+{"image": "doclay/doclay_42358.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "AIM  7110.65R CHG 2 AIM\n8/15/19 3/15/07 1/30/20\nFIG 5 − 2 − 1\nDiverse Departure Obstacle Assessment to 25/46 NMNOTE −\nTAKEOFF OBSTACLE NOTES: Rwy 14, trees 2011’ from DER, 29’ left of centerline, 100’ AGL/3829’ MSL. Rwy 32, trees 1009’ from DER, 697’ left of centerline, 100’ AGL/3839’ MSL. Tower 4448’ from DER, 1036’ left of centerline, 165’ AGL/3886’ MSL. “TAKEOFF MINIMUMS: RWY 27, Standard with a minimum climb of 280’ per NM to 2500.” A climb of at least 280 FPNM is required to 2500 and is mandatory when the departure procedure is included in the ATC clearance. NOTE Some SIDs still retain labeled “ATC” climb gradients\nNOTE − Compliance with 14 CFR Part 121 or 135 one − engine − in- operative (OEI) departure performance requirements, or similar ICAO/State rules, cannot be assured by the sole use of “low, close − in” obstacle data as published in the TPP. Operators should refer to precise data sources (for example, GIS database, etc.) specifically intended for OEI departure planning for those operations.\ncenterline, 100’ AGL/3839’ MSL. Tower 4448’ from DER, 1036’ left of centerline, 165’ AGL/3886’ MSL. NOTE −\nDER, 1036’ left of centerline, 165’ AGL/3886’ MSL. Some SIDs still retain labeled “ATC” climb gradients published or have climb gradients that are established to meet a published altitude restriction that is not required for obstacle clearance or procedure design criteria. These procedures will be revised in the course of the normal procedure amendment process.\n6. Climb gradients may be specified only to an altitude/fix, above which the normal gradient applies.\nAn ATC − required altitude restriction published at a fix, will not have an associated climb gradient pub- lished with that restriction. Pilots are expected to determine if crossing altitudes can be met, based on the performance capability of the aircraft they are op- erating.\n“Minimum climb 340 FPNM to ALPHA.” The pilot climbs at least 340 FPNM to ALPHA, then at least 200 FPNM to MIA.\n7. A Visual Climb Over Airport (VCOA) procedure is a departure option for an IFR aircraft, operating in visual meteorological conditions equal to or greater than the specified visibility and ceiling, to visually conduct climbing turns over the airport to the published “climb − to” altitude from which to proceed with the instrument portion of the departure. VCOA procedures are developed to avoid obstacles\nDeparture Procedures\n5 − 2 − 8\n5. Climb gradients greater than 200 FPNM are specified when required to support procedure design constraints, obstacle clearance, and/or airspace restrictions. Compliance with a climb gradient for these purposes is mandatory when the procedure is part of the ATC clearance, unless increased takeoff minimums are provided and weather conditions allow compliance with these minimums. \nNOTE −\nEXAMPLE −\nClimb gradients for ATC purposes are being phased out on SIDs.\n“Cross ALPHA intersection at or below 4000; maintain 6000.”The pilot climbs at least 200 FPNM to 6000. If 4000 is reached before ALPHA, the pilot levels off at 4000 until passing ALPHA; then immediately resumes at least 200 FPNM climb.\nEXAMPLE −\nEXAMPLE −\nEXAMPLE −"}]}
+{"image": "doclay/doclay_30572.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "– 28 –\n5.2. The Origin of the Opacity Holes\nThe four different mechanisms that have been proposed to explain the inner holes of transition disks can be distinguished when disk masses, accretion rates and multiplicity information are available (Najita et al., 2007; Cieza, 2008; Alexander, 2008). In this section, we compare the properties of our transition disk sample to those expected for objects whose opacity holes have been produced by these four mechanisms: photoevaporation, tidal truncation in close binaries, grain-growth, and giant planet formation.\nAs shown in Figure 8, our transition disks span the range λ$_{turn}$$_{−}$$_{off}$ = 2.2 to 8.0 µ m and α$_{excess}$ ∼ -2.5 to 1, while typical CTTSs occupy a much more restricted region of the parameter space. Based on the median and quartile SEDs presented by Furlan et al (2006), 50% of late-type (K5–M2) CTTSs have λ$_{turn}$$_{−}$$_{off}$ = 1.25 µ m, -1.0 > α$_{excess}$ > -0.64, and fractional disk luminosities in the 0.07 to 0.15 range. As discussed by Cieza et al. (2005), CTTS are likely to have J-band excesses. However, since this excess is at the ≲ 30-40% level, the observed J-band fluxes are still dominated by the stellar photospheres, satisfying our λ$_{turn}$$_{−}$$_{off}$ definition. Figure 8 also shows that, as expected, transition disks with different L$_{D}$/L$_{∗}$ values occupy different regions of the α$_{excess}$ vs. λ$_{turn}$$_{−}$$_{off}$ space. Objects with L$_{D}$/L$_{∗}$ > 10 − 2 lay close to the CTTSs loci, while objects with L$_{D}$/L$_{∗}$ < 10 − 3 all have λ$_{turn}$$_{−}$$_{off}$ = 8.0 µ m and α$_{excess}$ ≲ 0.0. The objects in the latter group are all non-accreting.\nTheir very low fractional disk luminosities and lack of accretion suggest they are already in a debris disk stage (see § 5.2.1)."}]}
+{"image": "doclay/doclay_32705.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Couple of points to note here. In the borderline regime σ ∼ h $^{2}$M$_{P}$ , the cubic and quartic interaction terms are comparable. The inflaton decay happens due to a combination of resonant and tachyonic instabilities. If h ≪ m$_{φ}$/M$_{P}$ and σ ≪ m 2 $_{φ}$/M$_{P}$ , the inflaton decays perturbatively via the cubic interaction term. However this requires very small couplings; h, ( σ/m$_{φ}$ ) < 10 − $^{6}$. Therefore, unless the inflaton is only gravitationally coupled to other fields, the initial stage of its decay will be generically non-perturbative.\nResonant particle production and re-scatterings lead to the formation of a plasma con- sisting of φ and χ quanta with typical energies ∼ 10 − $^{1}$( hm$_{φ}$M$_{P}$ ) 1 / $^{2}$, see [100, 115, 725, 796]. This plasma is in kinetic equilibrium but full thermal equilibrium is established over a much longer time scale than preheating [102, 104].\nThe occupation number of particles in the preheat plasma is ≫ 1 (which is opposite to the situation after the perturbative decay). This implies that the number density of particles is larger than its value in full equilibrium, while the average energy of particles is smaller than the equilibrium value. It gives rise to large effective masses for particles which, right after preheating, is similar to their typical momenta [100, 115, 796]. Large occupation numbers also lead to important quantum effects due to identical particles and significant off-shell effects in the preheat plasma. Because of all these, a field theoretical study of thermalization is considerably more complicated in case of preheating. Due to the large occupation numbers, one can consider the problem as thermalization of classical fields at early stages [101–104]. In the course of evolution towards full equilibrium, however, the occupation numbers decrease. Therefore a proper (non-equilibrium) quantum field theory treatment will be inevitably required at late stages when occupation numbers are close to one.\nPreheating ends due to back reaction as well as the expansion of the universe. Preheating does not destroy the zero mode of the inflaton condensate completely, although the amplitude of the inflaton oscillations diminish, but the inflaton decay is completed when the zero mode perturbatively decays into the SM or some other degrees of freedom, see [97–100]. It was found that the relevant time scale for thermalization after preheating is given by [101, 102]:\nwhere c$_{r}$ is the fraction of the inflaton energy density stored in the coherent oscillations at the onset of the turbulent phase and p ∼ 1 / 7 obtained from the numerical simulations.\n179\nΓ$_{th}$ ∼ ( m$_{φ}$ ( c$_{r}$ρ$_{inf}$ ) 1 / 4 ) 1 /p , (382)"}]}
+{"image": "doclay/doclay_27428.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Beissbarth, T., Hyde, L., Smyth, G. K., Job, C., Boon, W.-M., Tan, S.-S., et al. (2004). Statistical modeling of sequencing errors in SAGE libraries. Bioinformatics , 20 Suppl 1 (NIL), I31-I39.\nBilodeau, M., & Brenner, D.(1999). Theory of multivariate statistics . New York: Springer.\nChen, M.-H., Shao, Q.-M., & Ibrahim, J. G. (2000). Monte carlo methods in bayesian computation .\nChristensen, R. (1997). Log-linear models and logistic regression (2 ed.). New York, USA: Springer Verlag.\nColinge, J., & Feger, G. (2001). Detecting the impact of sequencing errors on SAGE data. Bioinformatics , 17 , 840-842.\nGelman, A., Carlin, B., Stern, H., & Rubin, D. (2005). Bayesian data analysis (2 ed.). Chapman and Hall.\nGhosh, J. K., Delampady, M., & Samanta, T.(2006). An introduction to bayesian analysis . New York: Springer.\nGilchrist, M., Qin, H., & Zaretzki, R. (2007, In Press). Modeling SAGE tag formation and its effects on data interpretation within a Bayesian framework. (In Press)\nKuznetsov, V. A.(2006). Statistical methods in serial analysis of gene expression(SAGE). In W. Zhang & I. Shmulevich (Eds.), Computational and statistical approaches to genomics (p. 163-2008). New York: Springer Verlag. (2nd Edition)\nKuznetsov, V. A., Knott, G. D., & Bonner, R. F. (2002). General Statistics of Stochastic Process of Gene Expression in Eukaryotic Cells. Genetics , 161 (3), 1321-1332.\n26"}]}
+{"image": "doclay/doclay_29625.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "is appropriate for comparisons with the lattice data, the following work must be done: 1.) the mass of the heavy quark must be changed whenever the drag coefficient is changed, since we are concerned with results for G ( τ ) with different values of η but the same “effective” mass, 2.) the maximum entropy method must be applied to G ( τ ), so that the spectral function corresponding to the correlation function will be extracted with high precision, 3.) this spectral function must have the zero-mode contribution added and be cut so that the perturbative result for the spectral function is used at large ω instead, and finally 4.) this spectral function should be used to calculate G ( τ ). However, let us note here that this work can be put to greater use in examining quarkonium in heavy-ion collisions.\nLet us argue one last time for treating quarkonium above deconfinement as an open quantum system: typically in particle physics, the rate for the scattering of an N -particle state into another is determined from the square of the matrix element whose indices are the initial and final states, where these states are in the momentum basis. This makes per- fect sense in high-energy experiments, where the incoming and outgoing states are basically each 2-particle momentum eigenstates and the matrix element can be expanded in terms of a small coupling. Such an approach, however, seems entirely inappropriate for quarko- nium formed in a heavy-ion collision, whose constituent quarks are localized in position relative to the surrounding medium and are strongly coupled both to the medium and each other. Non-perturbative techniques and experiment both suggest that quarkonium rapidly thermalizes and interacts strongly with the medium. The most reasonable approach for explaining the observables is to describe quarkonium with a reduced density matrix, whose evolution is determined by a potential and a drag coefficient which are both determined non-perturbatively.\nWe would like to thank E. Shuryak and D. Teaney for very useful and detailed suggestions concerning our work. CY thanks the Institute for Nuclear Theory at the University of Washington for its hospitality during the completion of this work. CY was supported by the US-DOE grants DE-FG02-88ER40388 and DE-FG03-97ER4014. KD was supported by\nV. ACKNOWLEDGMENTS\n11"}]}
+{"image": "doclay/doclay_68896.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "The total amount of cache memory reserved for the FlashCopy bitmaps limits the amount of  capacity that can be used as a FlashCopy target. Table 6-4 illustrates the relationship of  bitmap space to FlashCopy address space, depending on the size of the grain and the kind of  FlashCopy service being used.\nMapping consideration:  For multiple FlashCopy targets, you must consider the number of  mappings. For example, for a mapping with a 256 KB grain size, 8 KB of memory allows  one mapping between a 16 GB source volume and a 16 GB target volume. Alternatively,  for a mapping with a 256 KB grain size, 8 KB of memory allows two mappings between one  8 GB source volume and two 8 GB target volumes.\nWhen you create a FlashCopy mapping, if you specify an I/O Group other than the I/O  Group of the source volume, the memory accounting goes towards the specified I/O  Group, not towards the I/O Group of the source volume.\nThe default amount of memory for FlashCopy is 20 MB. This value can be increased or  decreased by using the  chiogrp  command. The maximum amount of memory that can be  specified for FlashCopy is 2048 MB (512 MB for 32-bit systems). The maximum combined  amount of memory across all copy services features is 2600 MB (552 MB for 32-bit systems).\nBitmap allocation:  When creating a FlashCopy mapping, you can optionally specify the  I/O group where the bitmap is allocated. If you specify an I/O Group other than the  I/O Group of the source volume, the memory accounting goes towards the specified I/O  Group, not towards the I/O Group of the source volume. This option can be useful when an  I/O group is exhausting the memory that is allocated to the FlashCopy bitmaps and no  more free memory is available in the I/O group.\nThe following implementation restrictions apply to FlashCopy:\nTable 6-4 Relationship of bitmap space to FlashCopy address space for the specified I/O Group\nCopy Service Grain size in KB 1 MB of memory provides the following  volume capacity for the specified  I/O Group FlashCopy 256 002 TB of target volume capacity FlashCopy 064 512 GB of target volume capacity Incremental FlashCopy 256 001 TB of target volume capacity Incremental FlashCopy 064 256 GB of target volume capacity\nFlashCopy general restrictions\nGLYPH<SM590000> The size of source and target volumes in a FlashCopy mapping must be the same.\nGLYPH<SM590000> Multiple FlashCopy mappings that use the same target volume can be defined, but only  one of these mappings can be started at a time. This limitation means that no multiple  FlashCopy can be active to the same target volume.\nGLYPH<SM590000> Expansion or shrinking of volumes defined in a FlashCopy mapping is not allowed. To  modify the size of a source or target volume, first remove the FlashCopy mapping.\nGLYPH<SM590000> In a cascading FlashCopy, the grain size of all the FlashCopy mappings that participate  must be the same.\nGLYPH<SM590000> In a multi-target FlashCopy, the grain size of all the FlashCopy mappings that participate  must be the same.\nChapter 6. Copy services  157"}]}
+{"image": "doclay/doclay_77783.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "\nFigure 4-2.  Large format printer. \nfree of oil, grease, or other unclean matter that can soil or  smudge the print. \nNever make notes or marks on a print, as they may confuse  others and lead to incorrect work. Only authorized individuals  are permitted to make notes or changes on prints, and they  must sign and date any changes they make. \nWhen finished with a drawing, fold and return it to its proper  place. Prints are folded originally in an appropriate size for  filing. Care should be taken so that the original folds are  always used. \nDrawings must give information such as size and shape of  the object and all its parts, specifications for material to be  used, how the material is to be finished, how the parts are to  be assembled, and any other information essential to making  and assembling the object. Drawings may be divided into  three classes: detail, assembly, and installation. \nA detail drawing is a description of a single part, describing  by lines, notes, and symbols the specifications for size, shape,  material, and methods of manufacture to be used in making  the part. Detail drawings are usually rather simple. When  single parts are small, several detail drawings may be shown  on the same sheet or print.  [Figure 4-3] \nAn assembly drawing is a description of an object made up  of two or more parts.  [Figure 4-4]  It describes the object’s  size and shape. Its primary purpose is to show the relationship  of the various parts. An assembly drawing is usually more  complex than a detail drawing and is often accompanied by  detail drawings of various parts. \nEvery print must have some means of identification.  This is provided by a title block.  [Figure 4-4A]  The title  block consists of a drawing number and certain other data  concerning the drawing and the object it represents. This \nFigure 4-9  is an illustration of removed sections. Section  A-A shows the cross-sectional shape of the object at cutting  plane line A-A. Section B-B shows the cross-sectional shape  at cutting plane line B-B. These sectional views are drawn  to the same scale as the principal view.  Title Blocks \nA removed section illustrates parts of an object. It is drawn  like revolved sections, except it is placed at one side and  often drawn to a larger scale than the view indicated to bring  out pertinent details. \nA revolved section drawn directly on the exterior view shows  the shape of the cross section of a part, such as the spoke  of a wheel. An example of a revolved section is shown in  Figure 4-8 . \nIn a half section, the cutting plane extends only halfway  across the object, leaving the other half of the object as an  exterior view. Half sections are used with symmetrical objects  to show both the interior and exterior.  Figure 4-7  is a half  sectional view of a Capstan servo. \nA full section view is used when the interior construction  or hidden features of an object cannot be shown clearly by  exterior views. For example,  Figure 4-6  is a sectional view  of a cable connector and shows the internal construction of  the connector. \nA section or sectional view is obtained by cutting away part  of an object to show the shape and construction at the cutting  plane. The part or parts cut away are shown by using section  (crosshatching) lines. Types of sections are described in the  following paragraphs. \nAn installation drawing is one that includes all necessary  information for a part or an assembly in the final installed  position in the aircraft. It shows the dimensions necessary  for the location of specific parts with relation to the other  parts and reference dimensions that are helpful in later work  in the shop.  [Figure 4-5] \nInstallation Drawing \nSectional View Drawings \nFull Section \nHalf Section \nRemoved Section \nRevolved Section \nTypes of Drawings \nDetail Drawing \nAssembly Drawing \n4-3 "}]}
+{"image": "doclay/doclay_63474.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "(45)  Date of Patent:  *Mar. 3, 2015 \n(IO)  Patent No.:  US 8,968,989 B2 \nc12)  United States Patent \nOuattara et al. \n(54)  ASSIST LAYERS FOR EUV LITHOGRAPHY \n(71)  Applicant:  Brewer Science Inc.,  Rolla, MO (US) \n(72)  Inventors:  Tantiboro Ouattara,  Eureka, MO (US);  Carlton Washburn,  Rolla, MO (US);  Vandana Krishnamurthy,  Rolla, MO  (US);  Douglas Guerrero,  Rolla, MO  (US);  Aline Collin,  Fairbanks, AK (US) \n(73)  Assignee:  Brewer Science Inc.,  Rolla, MO (US) \n( *)  Notice:  Subject to any disclaimer, the term ofthis  patent is extended or adjusted under 35  U.S.C. 154(b) by 33 days.  This patent is subject to a terminal dis› claimer. \n(21)  Appl. No.:  13/682,050 \n(22)  Filed:  Nov. 20, 2012 \n(60)  Provisional application No. 61/562,166, filed on Nov.  21, 2011. \n(51)  Int. Cl. \n(52)  U.S. Cl.  CPC ..............  G03F  71092  (2013.01);  G03F  712004  (2013.01);  G03F  7111  (2013.01);  B82Y 30/00  (2013.01);  YJ0S 977/755  (2013.01);  B82Y  40/00  (2013.01)  USPC ............................  430/323;  430/322; 977/755 \n( 58)  Field of Classification Search  CPC ............. G03F 7/092; G03F 7/11; G03F 7/20;  G03F 7/2004  USPC .................................................. 430/322, 323  See application file for complete search history. \n(56)  References Cited \nU.S. PATENT DOCUMENTS \nFOREIGN PATENT DOCUMENTS \nOTHER PUBLICATIONS \n(57)  ABSTRACT \n15 Claims, 18 Drawing Sheets \n(65)  Prior Publication Data \nRelated U.S. Application Data \nG03F  7126  (2006.01)  G03F  7109  (2006.01)  G03F  7120  (2006.01)  G03F  7111  (2006.01)  B82Y 30/00  (2011.01)  B82Y 40/00  (2011.01) \n6,140,023 A  *  6,740,469 B2  8,257,910 Bl  2007/0148602 Al  2009/0123878 Al  2009/0297784 Al  2011/0123779 Al  10/2000 Levinson et al .............. 430/313  5/2004 Krishnamurthy et al.  9/2012 Guerrero et al.  6/2007 Lee et al.  5/2009 Miyoshi et al.  12/2009 Xu et al.  5/2011 Fuller et al. \n1111111111111111 11111 1111111111 11111 1111111111 1111111111 111111111111111111  US008968989B2 \nJP  2002-198283  7/2002 \nGoldberg et al.,  \"An  EUV Fresnel zoneplate mask-imaging micro› scope for lithography generations reaching 8 nm,\" Proc. of SPIE,  2011, vol. 7969, 796910-1-796910-12. \nRoberts et al., \"Sensitivity ofEUV resists to out-of-band radiation,\"  Proc. ofSPIE, 2009, vol. 7273, 72731W-l-72731W-13. \nXu et al., \"Underlayer designs to enhance the performance ofEUV  resists,\" Proc. ofSPIE, 2009, vol. 7273, 72731J-l-72731J-ll. \nInternational Search Report and Written Opinion dated Mar. 4, 2013  in corresponding PCT/US2012/066074 filed Nov. 20, 2012. \nThackeray et al., \"EUV Resists based on Low Acid Diffusion,\" Dow  Electronic Materials, 2009 International Symposium on Extreme  Ultraviolet Lithography, Oct. 19, 2009, 31 pages. \nMeagley, Robert P., \"Fundamental Challenges for Lithographic  Roadmap,\" Intel Corporation, Sep. 16, 2004, NSF/SRC ERC, 14  pages. \nMeagley, Robert P., Manager, Lithography, Fab Materials Operation  (FMO), Intel Corporation, J. Vac. Sci. Tech. B, 24(4),  Jul.I  Aug. 2006,  pp. 1822-1826. \n* cited by examiner \nPrimary Examiner  - Kathleen Duda \n(74)  Attorney, Agent, or Firm  - Hovey Williams LLP \nThe present invention provides novel methods of fabricating  microelectronics structures, and the resulting structures  formed thereby, using EUV lithographic processes. The  method involves utilizing an assist layer immediately below  the photoresist layer. The assist layer can either be directly  applied to the substrate, or it can be applied to any interme› diate layer(s) that may be applied to the substrate. The pre› ferred assist layers are formed from spin-coatable, polymeric  compositions. The inventive method allows reduced critical  dimensions to be achieved with improved dose-to-size ratios,  while improving adhesion and reducing or eliminating pat› tern collapse issues. \nUS 2013/0129995 Al  May 23, 2013 \nI 1111111111111111 11111 1111111111 11111 1111111111 1111111111 111111111111111111 "}]}
+{"image": "doclay/doclay_71302.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "million, $104 million and $30 million, respectively, as operating and maintenance expense under this partial TUA assignment agreement.\nUnder each of these TUAs, SPLNG is entitled to retain 2% of the LNG delivered to the Sabine Pass LNG terminal.\nWe currently expect that SPL’s capital resources requirements with respect to the SPL Project will be financed through project debt and borrowings, cash flows under the SPAs and equity contributions from Cheniere Partners. We believe that with the net proceeds of borrowings, available commitments under the 2020 SPL Working Capital Facility, 2019 CQP Credit Facilities, cash flows from operations and equity contributions from Cheniere Partners ,  SPL will have adequate financial resources available to meet its currently anticipated capital, operating and debt service requirements with respect to Trains 1 through 6 of the SPL Project. Additionally, SPLNG generates cash flows from the TUAs, as discussed above.\nThe following table provides a summary of our capital resources from borrowings and available commitments for the Sabine Pass LNG Terminal, excluding equity contributions to our subsidiaries and cash flows from operations (as described in  Sources and Uses of Cash ), at December 31, 2020 and 2019 (in millions):\n(1) Includes SPL’s 2021 SPL Senior Notes, 6.25% Senior Secured Notes due 2022, 5.625% Senior Secured Notes due 2023, 5.75% Senior Secured Notes due 2024, 5.625% Senior Secured Notes due 2025, 5.875% Senior Secured Notes due 2026 (the “2026 SPL Senior Notes”), 5.00% Senior Secured Notes due 2027 (the “2027 SPL Senior Notes”), 4.200% Senior Secured Notes due 2028 (the “2028 SPL Senior Notes”), 2030 SPL Senior Notes and 5.00% Senior Secured Notes due 2037 (the “2037 SPL Senior Notes”) (collectively, the “SPL Senior Notes”), as well as Cheniere Partners’ $1.5 billion of 5.250% Senior Notes due 2025 (the “2025 CQP Senior Notes”), $1.1 billion of 5.625% Senior Notes due 2026 (the “2026 CQP Senior Notes”) and the 4.500% Senior Notes due 2029 (the “2029 CQP Senior Notes”) (collectively, the “CQP Senior Notes”).\n(2) Includes outstanding balances under the 2015 SPL Working Capital Facility, 2020 SPL Working Capital Facility and 2019 CQP Credit Facilities, inclusive of any portion of the 2020 SPL Working Capital Facility and 2019 CQP Credit Facilities that may be used for general corporate purposes.\n(3) Consists of 2015 SPL Working Capital Facility, 2020 SPL Working Capital Facility and 2019 CQP Credit Facilities.\n(4) Does not include equity contributions that may be available from Cheniere’s borrowings and available cash and cash equivalents.\nSPL Senior Notes\nThe SPL Senior Notes are governed by a common indenture (the ��SPL Indenture”) and the terms of the 2037 SPL Senior Notes are governed by a separate indenture (the “2037 SPL Senior Notes Indenture”). Both the SPL Indenture and the 2037 SPL Senior Notes Indenture contain terms and events of default and certain covenants that, among other things, limit SPL’s ability and the ability of SPL’s restricted subsidiaries to incur additional indebtedness or issue preferred stock, make certain investments or pay dividends or distributions on capital stock or subordinated indebtedness or purchase, redeem or retire capital stock, sell or transfer assets, including capital stock of SPL’s restricted subsidiaries, restrict dividends or other payments by restricted subsidiaries, incur liens, enter into transactions with affiliates, dissolve, liquidate, consolidate, merge, sell or lease all or substantially all of SPL’s assets and enter into certain LNG sales contracts. Subject to permitted liens, the SPL Senior Notes are secured on a  pari passu  first-priority basis by a security interest in all of the membership interests in SPL and substantially all of SPL’s assets. SPL may not make any distributions until, among other requirements, deposits are made into debt service reserve accounts as required and a debt service coverage ratio test of 1.25:1.00 is satisfied.\n55\nDecember 31, 2020 2019 Senior notes (1) $ 17,750  $ 17,750  Credit facilities outstanding balance (2) —  —  Letters of credit issued (3) 413  414  Available commitments under credit facilities (3) 1,537  1,536  Total capital resources from borrowings and available commitments (4) $ 19,700  $ 19,700 \nCapital Resources"}]}
+{"image": "doclay/doclay_38175.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Annex I  - Tender specifications (reference No [ complete ]  of  [ insert date ] ) \nAnnex II  - Contractor's tender (reference No [ complete ]  of  [ insert date ] ) \nAnnex III  –  Declaration on pre-existing rights 3\nwhich form an integral part of this contract (“the contract”).\nThis contract sets out the obligations of the parties during and after the duration of this contract. \nAll documents issued by the contractor (end-user agreements, general terms and conditions, etc.)  except its tender are held inapplicable, unless explicitly mentioned in the special conditions of this  contract. In all circumstances, in the event of contradiction between this contract and documents  issued by the contractor, this contract prevails, regardless of any provision to the contrary in the  contractor’s documents.\n3 It is important that the awarded contractor fully understands the implications of signing this declaration and it is therefore advisable that a  contractor consults with their legal advisors and/or seeks further clarification from EFSA in case of doubt.\n2 "}]}
+{"image": "doclay/doclay_20269.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "PART II\nItem 5. Market for Registrant’s Common Equity, Related Stockholder Matters and Issuer Purchases of Equity  Securities\n11\nMarket information  — Our common stock trades on the New York Stock Exchange (NYSE) under the symbol \"DAN.\" The  following table shows the high and low prices of our common stock as reported by the NYSE for each of our fiscal quarters  during 2014 and 2013.\nStockholder return  — The following graph shows the cumulative total shareholder return for our common stock since  December 31, 2009. The graph compares our performance to that of the Standard & Poor ’s 500 Stock Index and the Dow  Jones US Auto Parts Index. The comparison assumes $100 was invested at the closing price on December 31, 2009. Each of  the returns shown assumes that all dividends paid were reinvested.\nHolders of common stock  — Based on reports by our transfer agent, there were approximately 3,889 registered holders of our  common stock on February 6, 2015.Performance chart\nIndex\n2014 2013 High Low High Low Fourth quarter $ 22.36 $ 16.81 $ 23.46 $ 18.32 Third quarter 24.82 18.93 23.17 19.42 Second quarter 24.48 20.60 19.76 15.51 First quarter 23.28 18.06 18.24 15.17\n12/31/2009 12/31/2010 12/31/2011 12/31/2012 12/31/2013 12/31/2014 Dana Holding Corporation $ 100.00 $ 157.33 $ 111.79 $ 144.73 $ 182.62 $ 203.50 S&P 500 100.00 115.06 117.49 136.30 180.44 205.14 Dow Jones US Auto Parts 100.00 158.18 139.53 156.14 243.66 269.56"}]}
+{"image": "doclay/doclay_27555.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Ann. Statist., 9, 501-513.\nYohai, V. J., 1987. High breakdown-point and high efficiency estimates for regression. Ann. Statist., 15, 642-656.\n11"}]}
+{"image": "doclay/doclay_44955.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Figure 7-5.  Glider training log. \nLesson Plans \nAnother benefit of using a syllabus is that it helps in the development of lesson plans. A well-constructed syllabus already contains  much of the essential information that is required in a lesson plan, including objectives, content, and completion standards. \nA lesson plan is an organized outline for a single instructional period. It is a necessary guide for the instructor because it tells what to  do, in what order to do it, and what procedure to use in teaching the material of a lesson. Lesson plans should be prepared for each  training period and be developed to show specific knowledge and/or skills to be taught. \nA mental outline of a lesson is not a lesson plan. A lesson plan should be put into writing. Another instructor should be able to take  the lesson plan and know what to do in conducting the same period of instruction. Written out, the lesson plan can be analyzed for  adequacy and completeness. \nLesson plans make excellent recordkeeping forms that can become a permanent part of a pilot’s training record. They can be  formatted for the instructor to carry in the aircraft and include a checklist for indicating what portions of the lesson were completed,  date of completion, the flight instructor’s signature, and time flown. The lesson plan can also have a notation section for flight  instructor comments. \n7-7 \n"}]}
+{"image": "doclay/doclay_80525.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "17\nв предусмотренном федеральным законом порядке и установлена вступившим в законную силу приговором суда.\n2. Обвиняемый не обязан доказывать свою невиновность.\n3. Неустранимые сомнения в виновности лица толкуются в пользу обвиняемого.\nСтатья 50\nСтатья 51\nСтатья 52\nСтатья 53\nКаждый имеет право на возмещение государством вреда, причиненного незаконными действиями (или бездействием) органов государственной власти или их должностных лиц.\nПрава потерпевших от преступлений и злоупотреблений властью охраняются законом. Государство обеспечивает потерпевшим доступ к правосудию и компенсацию причиненного ущерба.\n2. Федеральным законом могут устанавливаться иные случаи освобождения от обязанности давать свидетельские показания.\n1. Никто не обязан свидетельствовать против себя самого, своего супруга и близких родственников, круг которых определяется федеральным законом.\n1. Никто не может быть повторно осужден за одно и то же преступление.\n2. При осуществлении правосудия не допускается использование доказательств, полученных с нарушением федерального закона.\n3. Каждый осужденный за преступление имеет право на пересмотр приговора вышестоящим судом в порядке, установленном федеральным законом, а также право просить о помиловании или смягчении наказания."}]}
+{"image": "doclay/doclay_74699.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "The price quotations reported above were supplied by the New York Stock Exchange.\n(a) In the third quarter of 2003, the Company reduced the effective tax rate for the year to 30.5% from 31.0%, thereby decreasing income tax expense by $2.3.\n70\n2004 Quarter Ended 2003 Quarter Ended March 31 June 30 Sept. 30 Dec. 31  March 31 June 30 Sept. 30 Dec. 31 Net sales $1,035.1 $1,043.0 $1,028.7 $1,155.5 $846.9 $891.7 $885.4 $1,001.3 Gross profit 666.9 678.3 663.6 743.4 546.1 564.8 556.6 645.4 Earnings before income taxes 194.1 218.2 72.4 232.3 150.9 155.8 152.9 192.9 Net earnings 135.9 152.7 14.4 162.7 104.1 107.5 107.8 (a) 134.1 Net earnings per share of common stock: Basic .34 .38 .04 .40 .26 .27 .27 .34 Diluted .33 .37 .04 .40 .26 .26 .26 .33 Market price of common stock: High 47.20 55.94 57.66 48.81 35.25 36.72 39.63 42.68 Low 41.77 44.21 43.71 40.30 29.83 31.48 33.88 37.34\nSUMMARY OF QUARTERLY DATA (UNAUDITED) Stryker Corporation and Subsidiaries\n(in millions, except per share data)"}]}
+{"image": "doclay/doclay_65527.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Figur 20: die Ansicht gemäß Figur 19 am Ende der Kraftbegrenzung,\nFigur 21: eine teilweise Explosionsansicht einer fünftenAusführungsform mit einem in Reihe mit den Kraftbegrenzungselementen der ers- ten Kraftbegrenzungseinrichtung geschalteten Torsionsstab einer zweiten Kraftbegrenzungseinrichtung,\nFigur 22: eine Schnittansicht durch die Ausführungsformgemäß Figur 21 und\nFigur 23 : eine Darstellung eines Kraftverlaufs mit drei Kraftniveaus.\nFigur 24a: Beispiele einer Verbindung der Kraftbegrenzungselemente\nFigur 24b: ein weiteres Beispiel einer Verbindung der Kraftbegrenzungs- elemente mit reduziertem Bauraum\nFigur 24c: ein weiteres Beispiel einer Verbindung der Kraftbegrenzungs elemente mit reduziertem Bauraum\nDer in den Figuren 1 bis 13 dargestellte Gurtaufroller umfasst einen Gehäuse- rahmen 1, in dem eine Gurtwelle 2 drehbar gelagert ist.\nDer Gurtaufroller umfasst eine zweistufige erste Kraftbegrenzungseinrichtung 4, überdie die Gurtwelle 2 mit einem Profilkopf 3 in einer ersten Kraftbe- grenzungsstufe und in einer zweiten Kraftbegrenzungsstufe gekoppelt ist.\nDie erste Kraftbegrenzungseinrichtung 4 umfasst hierzu eine Schalteinrich tung 13, die zwei Klinken 14, einen Wellenring 15, einen Stellring 16 und ei nen Antriebselement 17 in Form eines Gasgenerators aufweist. In dem in den"}]}
+{"image": "doclay/doclay_18042.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "COMMANDER RESOURCES LTD.  (An Exploration Stage Company)  Notes to Financial Statements  For the Years Ended December 31, 2012 and 2011  (Expressed in Canadian dollars) \n9.  Exploration and Evaluation Assets (Continued) \n(a) Baffin Island Properties, Nunavut \nExpenditures incurred on mineral properties as at December 31, 2011 were as follows:\nThe Baffin Island Properties consist of two separate properties named Qimmiq and Bravo Lake (collectively, the  “Baffin Properties”). The Company owns 100% of the Qimmiq property, subject to an underlying agreement with  Nunavut Tunngavik Inc. and certain future considerations to BHP Billiton. The Company owns 100% of the Bravo  Lake property subject to certain future considerations to Xstrata Nickel, a business unit of Xstrata Canada  Corporation.\nIn 2009, the Company entered into a Farm-in and Joint Venture Agreement (the “Agreement”) with AngloGold  Ashanti Limited’s subsidiary, AngloGold Ashanti Holdings Plc (“AngloGold”), related to the Baffin Properties. Pursuant to the Agreement, AngloGold may earn a 51% participating interest in the Baffin Properties by funding \nAshanti Limited’s subsidiary, AngloGold Ashanti Holdings Plc (“AngloGold”), related to the Baffin Properties. Pursuant to the Agreement, AngloGold may earn a 51% participating interest in the Baffin Properties by funding  $20 million by December 31, 2014, with an additional requirement to fund $5.5 million of the $20 million in  exploration expenditures before December 31, 2010. \nIn March 2012, AngloGold decided not to put forward a 2012 exploration program on Baffin Island and has  withdrawn from the Agreement.\nFor the year ended December 31, 2012, total recoveries on the Baffin Properties from AngloGold amounted to  $537,369 (2011 - $2,957,403). The recoveries included AngloGold’s final settlement for the joint venture program  as it withdrew from its Agreement with the Company and discontinued exploration program on Baffin Island in  March 2012. The Company now retains 100% interest of the property. \n- 20 - \nNunavut Ontario Other  Newfoundland Qimmiq Bravo Lake Glenmorangie Storm Omineca StumpLake Sabin Properties Green Bay Total Balance at December 31, 2010 10,041,959 $ 2,590,023 $ - $ 116,144 $ 106,642 $ - $ 127,027 $ 8,133,079 $ 769,268 $ 21,884,142 $ Acquisition costs - - 60,373 - - 109,433 - 1,440 1,750 172,996 Exploration costs Drilling 568,026 71,414 63,722 1,200 - 304 450 2,203 565,516 1,272,835 Geochemistry 45,364 5,449 46,938 521 - 49,530 - - - 147,802 Geology 800,468 242,613 233,417 162,419 15,345 286,235 10,526 48,535 162,696 1,962,254 Geophysics  255,992 - 267 725,012 - 110,134 - - - 1,091,405 Property  111,828 - 970 14,829 - 3,386 3,870 7,803 3,107 145,793 Other  16,426 6,338 - 135 - 3,784 27 198 440 27,348 1,798,104 325,814 345,314 904,116 15,345 453,373 14,873 58,739 731,759 4,647,437 Less Recoveries (2,596,363) (361,040) - (90,000) - - - (12,000) (222,450) (3,281,853) Write-down  - - - - - - - (3,958,279) - (3,958,279) Net additions (798,259) (35,226) 405,687 814,116 15,345 562,806 14,873 (3,910,100) 511,059 (2,419,699) Balance at December 31, 2011 9,243,700 $ 2,554,797 $ 405,687 $ 930,260 $ 121,987 $ 562,806 $ 141,900 $ 4,222,979 $ 1,280,327 $ 19,464,443 $ Baffin, Nunavut  Yukon British Columbia"}]}
+{"image": "doclay/doclay_18624.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "(b) The fair value above represents the implied fair value of the goodwill assigned to the five impaired markets in 2009 and four impaired  markets in 2008 for which we were required to calculate this amount. It excludes carrying values related to goodwill of $604.2 million  and $804.1 million at December 31, 2009 and 2008, respectively, for which we were not required to calculate the fair value. \nThe key assumptions used to determine the fair value of our reporting units to test our goodwill for impairment and to  determine the fair value of our broadcast licenses consist of discount rates, revenue and expense growth rates, constant growth  rates and comparable business multiples. The revenue and expense growth rates used in our goodwill impairment testing and the  revenue, expense and constant growth rates used in determining the fair value of our broadcast licenses have decreased slightly  from 2009 to 2010. However, the baseline cash flows to which these growth rates are applied have increased due to a stronger  than expected recovery in revenue in 2010. The growth rates are based on market studies, industry knowledge and historical  performance. \nThe discount rates used to determine the fair value of our reporting units to test our goodwill for impairment and to determine  the fair value of our broadcast licenses have slightly decreased from 2009 to 2010. The discount rate is based on a number of  factors including market interest rates, a weighted average cost of capital analysis based on the target capital structure for a  television station, and includes adjustments for market risk and company specific risk. The minimal decrease in the discount rate  is primarily due to a slight decrease in the general cost of equity in 2010.\nThe comparable business multiple used to determine the fair value of our reporting units to test our goodwill for impairment  has not changed from 2009 to 2010 due to the lack of data from sales transactions in the market in the past two years. It is an  estimate of the multiple that would most likely be paid for a mature, cash flowing television station in the current marketplace.\nAs of December 31, 2010 and 2009, the carrying amount of our broadcast licenses related to continuing operations was as  follows (in thousands): \nThe change in the carrying amount of goodwill related to continuing operations was as follows (in thousands): \nDefinite-lived intangible assets and other assets subject to amortization are being amortized on a straight-line basis over periods  of 5 to 25 years. We analyze specific definite-lived intangibles for impairment when events occur that may impact their value in  accordance with the respective accounting guidance for long-lived assets. There was no impairment charge recorded for the years  ended December 31, 2010 and 2009, respectively.\n2010 2009 Balance as of January 1, $ 1,073,590  $ 1,073,590  Accumulated impairment losses  (413,573)  (249,402)  660,017  824,188  Impairment losses (a)  —  (164,171)  Balance as of December 31,  Goodwill  1,073,590  1,073,590  Accumulated impairment losses  (413,573)  (413,573)  $ 660,017  $ 660,017 \nAs of December 31, 2010 2009 Beginning balance $ 51,988  $ 132,422  Broadcast license impairment charge (a)  (4,613)  (80,434)  Ending balance (b)  $ 47,375  $ 51,988 \n(a) In 2010 and 2009, an impairment of $0.2 million and $4.5 million, respectively, was recorded against purchase option assets  included in other assets in the consolidated balance sheet. These purchase options give us the right to purchase the license assets  of certain stations. \n(b) Approximately $4.2 million and $4.3 million of broadcast licenses relate to consolidated VIEs as of December 31, 2010 and  2009, respectively. \n(a) In 2009, all of the goodwill impairment charge related to our broadcast segment.\n2010 Annual Report    43 "}]}
+{"image": "doclay/doclay_56518.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Server Command Options\nplugin from the libary. The server looks for plugin library files in the directory named by the  plugin_dir system variable.\nFor example, if plugins named  myplug1  and  myplug2  are contained in the plugin library files myplug1.so  and  myplug2.so , use this option to perform an early plugin load:\nQuotes surround the argument value because otherwise some command interpreters interpret semicolon ( ; ) as a special character. (For example, Unix shells treat it as a command terminator.)\nEach named plugin is loaded early for a single invocation of  mysqld  only. After a restart, the plugin is not loaded early unless  --early-plugin-load  is used again.\nIf the server is started using  --initialize  or  --initialize-insecure , plugins specified by  -- early-plugin-load  are not loaded.\nIf the server is run with  --help , plugins specified by  --early-plugin-load  are loaded but not initialized. This behavior ensures that plugin options are displayed in the help message.\nInnoDB  tablespace encryption relies on the MySQL Keyring for encryption key management, and the keyring plugin to be used must be loaded prior to storage engine initialization to facilitate  InnoDB recovery for encrypted tables. For example, administrators who want the  keyring_file  plugin loaded at startup should use  --early-plugin-load  with the appropriate option value (such as keyring_file.so  on Unix and Unix-like systems or  keyring_file.dll  on Windows).\nFor information about  InnoDB  tablespace encryption, see Section 15.13, “InnoDB Data-at-Rest Encryption” . For general information about plugin loading, see Section 5.6.1, “Installing and Uninstalling Plugins” .\nFor MySQL Keyring, this option is used only when the keystore is managed with a keyring plugin. If keystore management uses a keyring component rather than a plugin, specify component loading using a manifest file; see Section 6.4.4.2, “Keyring Component Installation” .\nNote\n• --exit-info[= flags ] ,  -T [ flags ]\n• --external-locking\nCommand-Line Format --exit-info[=flags] Type Integer\nCommand-Line Format --external-locking[={OFF|ON}] Type Boolean\nThis is a bitmask of different flags that you can use for debugging the  mysqld  server. Do not use this option unless you know  exactly  what it does!\n739mysqld --early-plugin-load=\"myplug1=myplug1.so;myplug2=myplug2.so\""}]}
+{"image": "doclay/doclay_63383.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "US 10,274,819 B2 \nSheet 2 of 10 \nU.S. Patent \nApr. 30, 2019 \n$^{N }$.  <..9  LL \n0  C\\l  ,- C\\l  N  N •-------- m  ~~  /  co,./  0  .,....  C\\I  0  C\\I "}]}
+{"image": "doclay/doclay_15802.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "NGN services, such as VoIP, and all managed services, including MOD and VPN. \nWe currently have intelligent networks installed over our public switched telephone networks for our domestic long distance  and international networks, as well as a local intelligent network in the Taipei, Taichung and Kaohsiung metropolitan areas. Our  intelligent network is designed to facilitate the use of value-added services by providing more information about calls and allowing  greater management of those calls. \nAs of December 31, 2011, our domestic network included 17.6 million installed telephone lines, and reached virtually all  homes and businesses in Taiwan. \nInternational network.  Our international transmission infrastructure consists of both submarine cable and satellite  transmission systems, which link our national network directly to 101 telecommunications service providers in 45 international  destinations. \nInternational calls are routed between Taiwan and international destinations through one of our two international switching  centers, one located in Taipei and the other in Kaohsiung. Each center had two time-division multiplexing, or TDM, international  gateway switches and two NGN international gateway switch. We had a trunk capacity of 143,040 channels in total as of December  31, 2011. \nAs of December 31, 2011, we have invested in 16 submarine cables, seven of which land in Taiwan. After the number of  submarine cables we invest in has increased from 14 in 2010 to 16 in 2011, we have increased the capacity of each of our current  submarine cables, increasing our aggregate total capacity from 774 Gbps in 2010 to 1,058 Gbps in 2011.\nMobile Services Network \nOur mobile services network consists of: \n●  cell sites, which are physical locations equipped with a base station consisting of transmitters, receivers and other equipment  used to communicate through radio channels with customers’ mobile handsets within the range of a cell; \n●  BSC (base station controllers) for GSM or RNC (radio network controller) for 3G, which connect to, and control , the base  station within each cell site; \n●  cellular switching service centers, which control the base station controllers and the processing and routing of telephone calls; \n●  GGSN (gateway GPRS support nodes), which connect our GPRS network to the internet; \n●  SGSN (serving GPRS support nodes), which connect the GPRS network to the base station controllers; and \n●  transmission lines, which link (i) with respect to the GSM or 3G network, the mobile switching service centers, base station  controllers, base stations and the public switched telephone network, and (ii) with respect to the GPRS network, the base  station controllers, the support nodes and the internet. \nThe following table sets forth selected information regarding our mobile networks as of the dates indicated. \nAs of December 31, 2009 2010 2011 GSM system GSM base stations 9,384 9,336 9,531  Switches 49 44 44 Lines of capacity (in thousands) 7,700 6,500 6,500  Taiwan population coverage 99.9% 99.9% 99.9%\nP AR T I\n44"}]}
+{"image": "doclay/doclay_52782.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Among different  isolation levels , non-repeatable reads are prevented by the  serializable read  and  repeatable read  levels, and allowed by the  consistent read , and  read uncommitted  levels. See Also ACID, consistent read, isolation level, READ UNCOMMITTED, REPEATABLE READ, SERIALIZABLE, transaction.\n An industry term that means the same as  asynchronous I/O . See Also asynchronous I/O.\n A database design strategy where data is split into multiple tables, and duplicate values condensed into single rows represented by an ID, to avoid storing, querying, and updating redundant or lengthy values. It is typically used in  OLTP  applications.\nnonblocking I/O\nnormalized\nFor example, an address might be given a unique ID, so that a census database could represent the relationship lives at this address  by associating that ID with each member of a family, rather than storing multiple copies of a complex value such as  123 Main Street, Anytown, USA .\nFor another example, although a simple address book application might store each phone number in the same table as a person’s name and address, a phone company database might give each phone number a special ID, and store the numbers and IDs in a separate table. This normalized representation could simplify large-scale updates when area codes split apart.\nNormalization is not always recommended. Data that is primarily queried, and only updated by deleting entirely and reloading, is often kept in fewer, larger tables with redundant copies of duplicate values. This data representation is referred to as  denormalized , and is frequently found in data warehousing applications. See Also denormalized, foreign key, OLTP, relational.\n A broad term for a set of data access technologies that do not use the  SQL  language as their primary mechanism for reading and writing data. Some NoSQL technologies act as key-value stores, only accepting single-value reads and writes; some relax the restrictions of the  ACID  methodology; still others do not require a pre-planned  schema . MySQL users can combine NoSQL-style processing for speed and simplicity with SQL operations for flexibility and convenience, by using the  memcached  API to directly access some kinds of MySQL tables. The  memcached  interface to  InnoDB  tables is available in MySQL 5.6 and higher; see Section 15.20, “InnoDB memcached Plugin”  for details. The  memcached  interface to  NDB  tables is available in NDB Cluster 7.2 and later; see ndbmemcache—Memcache API for NDB Cluster (NO LONGER SUPPORTED). See Also ACID, InnoDB, memcached, schema, SQL.\n A type of  constraint  that specifies that a  column  cannot contain any  NULL  values. It helps to preserve referential integrity , as the database server can identify data with erroneous missing values. It also helps in the arithmetic involved in query optimization, allowing the optimizer to predict the number of entries in an index on that column.\nSee Also column, constraint, NULL, primary key, referential integrity.\n A special value in  SQL , indicating the absence of data. Any arithmetic operation or equality test involving a NULL  value, in turn produces a  NULL  result. (Thus it is similar to the IEEE floating-point concept of NaN, “not a number” .) Any aggregate calculation such as  AVG()  ignores rows with  NULL  values, when determining how many rows to divide by. The only test that works with  NULL  values uses the SQL idioms  IS NULL  or  IS NOT NULL .\nNULL  values play a part in  index  operations, because for performance a database must minimize the overhead of keeping track of missing data values. Typically,  NULL  values are not stored in an index, because a query that tests an indexed column using a standard comparison operator could never match a row with a  NULL  value for\n6171\nNULL\nNOT NULL constraint\nNoSQL"}]}
+{"image": "doclay/doclay_56678.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "ndb_select_all — Print Rows from an NDB Table\nYou can employ the same technique to restore a parallel backup to an older version of NDB Cluster (prior to NDB 8.0.16) that does not support parallel backups, using the  ndb_restore  binary supplied with the older version of the NDB Cluster software.\nndb_select_all  prints all rows from an  NDB  table to  stdout .\n23.4.24 ndb_select_all — Print Rows from an NDB Table\nUsage\nOptions that can be used with  ndb_select_all  are shown in the following table. Additional descriptions follow the table.\nndb_select_all -c  connection_string tbl_name  -d  db_name  [>  file_name ]\nTable 23.44 Command-line options used with the program ndb_select_all\nFormat Description Added, Deprecated, or Removed --character-sets-dir=path Directory containing character sets (Supported in all NDB releases based on MySQL 8.0) --connect-retries=# Number of times to retry connection before giving up (Supported in all NDB releases based on MySQL 8.0) --connect-retry-delay=# Number of seconds to wait between attempts to contact management server (Supported in all NDB releases based on MySQL 8.0) --connect- string=connection-string , -c Same as --ndb-connectstring (Supported in all NDB releases based on MySQL 8.0) --core-file Write core file on error; used in debugging (Supported in all NDB releases based on MySQL 8.0) --database=dbname , -d Name of database in which table is found (Supported in all NDB releases based on MySQL 8.0) --defaults-extra- file=path Read given file after global files are read (Supported in all NDB releases based on MySQL 8.0) --defaults-file=path Read default options from given file only (Supported in all NDB releases based on MySQL 8.0) --defaults-group- suffix=string Also read groups with concat(group, suffix) (Supported in all NDB releases based on MySQL 8.0) --delimiter=char , -D Set column delimiter (Supported in all NDB releases based on MySQL 8.0) --descending , -z Sort resultset in descending order (requires --order) (Supported in all NDB releases based on MySQL 8.0) --disk Print disk references (useful only for Disk Data tables having nonindexed columns) (Supported in all NDB releases based on MySQL 8.0) --gci Include GCI in output (Supported in all NDB releases based on MySQL 8.0)\n4399"}]}
+{"image": "doclay/doclay_22294.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "30 FINANCIAL RISK MANAGEMENT OBJECTIVES AND POLICIES  (continued)\n(d) Fair values  (continued)\nThe fair value of the financial instruments as well as the methods used to estimate the fair value are summarised in the table below.\n2014 2013 Valuation  technique-  market observable  inputs (Level 2)  $’000 Total  $’000 Valuation  technique-  market observable  inputs (Level 2)  $’000 Total  $’000 Financial assets: Derivatives 254 254 5,035 5,035 Total 254 254 5,035 5,035 Financial liabilities: Secured and unsecured borrowings 471,269 471,269 408,010 408,010 Derivatives 1,957 1,957 7,588 7,588 Total 473,226 473,226 415,598 415,598\nThe net fair values of the financial instruments are determined using valuation techniques that utilise data from observable and unobservable market data.  Assumptions are based on market conditions existing at each reporting date. The fair value is calculated as the present value of the estimated future cash  flows using an appropriate market based yield curve, which is independently derived. As a result, these derivatives have been classified based on the  observable market inputs as Level 2.\nThe net fair values of the secured and unsecured borrowings are determined based on the weighted average market-based interest rates that are  applicable to the borrowings. As a result, these borrowings have been classified based on the observable market inputs as Level 2.\n(e) Derivative financial instruments\n2014  $’000 2013  $’000 Current assets: Forward currency contracts – cash flow hedges 254 2,835 Interest rate caps and collars – held for trading – 2,147 254 4,982 Non-current assets: Forward currency contracts – cash flow hedges – 53 Current liabilities: Interest rate swap contracts – held for trading – 3,280 Interest rate swap contracts – cash flow hedges 902 645 Interest rate collars – held for trading – 2,128 Forward currency contracts – cash flow hedges 514 112 1,416 6,165 Non-current liabilities: Interest rate swap contracts – cash flow hedges 528 57 Interest rate collars – held for trading – 1,366 Forward currency contracts – cash flow hedges 13 – 541 1,423\nInstruments used by the Group\nThe Group uses derivative financial instruments such as forward currency contracts and interest rate swaps and collars (floors and caps) to hedge its  risks associated with interest rate and foreign currency fluctuations. Such derivative financial instruments are initially recognised at fair value on the date  on which a derivative contract is entered into and are subsequently remeasured to fair value. Refer Note 1(c)(ix).\nThe Group enters into derivative transactions under International Swaps and Derivatives Association (“ISDA”) agreements, which allow for the netting of  relevant transactions which are to be settled at the same time, which does not occur regularly in practice. In certain situations, such as a default, all  outstanding transactions under the relevant ISDA are able to be terminated, and a net amount for settlement determined. The ISDA agreements do not  meet the criteria for offsetting in the statement of financial position, due to no default having occurred.\nCLOSE FILE X\n71 ANNUAL REPORT 2014"}]}
+{"image": "doclay/doclay_32820.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "problem [291–295].\n• Low primordial tensor to scalar ratio: One of the bold predictions of string theory models of inflation is that the tensor\n• Cosmic (super)strings, localized gravity waves: In brane-anti-brane case, inflation ends via annihilation of the branes. This process\n• Embedding MSSM in a stringy setup: There are tremendous progress in embedding MSSM in a stringy setup, with the help\nOne of the bold predictions of string theory models of inflation is that the tensor to scalar ratio will be generically small, i.e. r < 0 . 001. In order to obtain large tensor to scalar ratio, i.e. r ∼ 0 . 1, one requires field values to be in the range, where Δ φ ≫ M$_{P}$ [210]. In a stringy setup the scale of inflation is always below the 4 d Planck scale, M$_{P}$ . Note that the chaotic type inflation is now driven with the help of assisted inflation [287, 557], where the largest tensor to scalar ratio could be detectable by the future experiments if r < 0 . 13. Similar arguments hold for brane inflation models, where the brane-anti-brane separation acts as an inflaton, but the tensor to scalar ratio remains quite small [879, 880].\nIn brane-anti-brane case, inflation ends via annihilation of the branes. This process is likely to generate cosmic strings [459–461, 881], see Sec. III G 2. However their longevity is a model dependent issue [460]. Brane-anti-brane annihilation would also lead to exciting gravity waves on sub-Hubble scales with a peak frequency governed by the string scale and a distinct sharp spectrum [727]. If the string scale is close to TeV, then there is a possibility of detecting them in future gravitational wave observatories.\nStringy models of inflation also bring various challenges, whose roots are tied to the origin of particle phenomenology. One of the issues is pertaining to exciting the SM degrees of freedom, baryons and cold dark matter. Reheating and thermalization of the SM degrees of freedom in stringy models of inflation are poorly understood [882–886].\nThere are tremendous progress in embedding MSSM in a stringy setup, with the help of intersecting branes in Type IIA/B theories. Typically these theories have quantized fluxes in presence of sources which lead to a warped geometry. Embedding MSSM in a realistic warped geometry is not well understood yet. Most of the constructions are done in a simple background geometry [887–894]. Furthermore, besides the SM gauge group there are extra U (1)’s which appear in the spectrum, which can be advantageous for cosmology, such as a natural embedding for neutrino masses, leptogenesis, for a\n223"}]}
+{"image": "doclay/doclay_79909.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "US 2020/0081341 Al \n17 \nMar. 12, 2020 \n-continued  (++)  (++)  Ii  ro  Ii  ro  0  b  ~  (++) (++)  Ii  ro  Ii  ro  0~  0  0  (++)  Ii  ro  0  (++)  Ii  ro  0  CN \n-continued  (++)  Ii  ro  0  O~OO,CH  --=::S  o::---11  0  0  0  (++)  Ii  ro  0~  0 "}]}
+{"image": "doclay/doclay_33087.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "\nFIG. 13: The representation of the maximization analysis δS = 0 along the direction ( − sin θ, cos θ ) for one point in the jamming power-law curve. Here c$_{1}$ = Γ and c$_{2}$ = ( φ − φ$_{c}$ )( N V$_{g}$/φ $^{2}$).\n26"}]}
+{"image": "doclay/doclay_33343.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "18\nD$_{i}$D$_{j}$ ( (2) Ψ − (2) Φ ) + { ( − Δ + 2 ∂ 2 η + 4 H ∂$_{η}$ − 2 K ) (2) Ψ + ( 2 H ∂$_{η}$ + 2 ∂$_{η}$ H + 4 H 2 + Δ + 2 K ) (2) Φ } γ$_{ij}$ − 1 a $_{2}$∂$_{η}$ a $^{2}$D$_{(}$$_{i}$ (2) ν$_{j}$$_{)}$ ) + 1 2 ( ∂ 2 η + 2 H ∂$_{η}$ + 2 K − Δ (2) χ ij − 8 πG ( ∂$_{η}$ϕ∂$_{η}$ϕ$_{2}$ − a $^{2}$ϕ$_{2}$ ∂V ∂ϕ ( ϕ ) γ$_{ij}$ = Γ$_{ij}$ , (6.22)\nwhere Γ$_{0}$, Γ$_{i}$ Γ$_{ij}$ are the collection of the quadratic term of the first-order perturbations as follows:\nHere, we used Eqs. (4.8), (5.12), (5.14), (5.16) and (5.18).\nThe tensor part of Eq. (6.22) is given by\nThis tensor mode is also called the second-order gravitational waves.\nFurther, the vector part of Eqs. (6.21) and (6.22) yields the initial value constraint and the evolution equation of the vector mode (2) ν$_{j}$ :\n( ∂ 2 η + 2 H ∂$_{η}$ + 2 K − Δ ) (2) χ$_{ij}$ = 2Γ$_{ij}$ − 2 3 γ$_{ij}$ Γ k k − 3 ( D$_{i}$D$_{j}$ − 1 3 γ$_{ij}$ Δ ) (Δ + 3 K ) − 1 ( Δ − $^{1}$D $^{k}$D$_{l}$ Γ l k − 1 3 Γ k k ) +4 { D$_{(}$$_{i}$ (Δ + 2 K ) − $^{1}$D$_{j}$$_{)}$ Δ − $^{1}$D $^{l}$D$_{k}$ Γ k l − D$_{(}$$_{i}$ (Δ + 2 K ) − $^{1}$D $^{k}$Γ$_{j}$$_{)}$$_{k}$ } . (6.26)\nΓ$_{i}$ := 16 πG∂$_{η}$ϕ$_{1}$D$_{i}$ϕ$_{1}$ − 4 ∂$_{η}$ (1) Φ D$_{i}$ (1) Φ +8 H (1) Φ D$_{i}$ (1) Φ − 8 (1) Φ ∂$_{η}$D$_{i}$ (1) Φ +2 D j (1) Φ ∂$_{η}$ (1) χ$_{ji}$ − 2 ∂$_{η}$D j (1) Φ (1) χ$_{ij}$ − 1 2 ∂$_{η}$ (1) χ$_{jk}$ D$_{i}$ (1) χ kj − (1) χ$_{kl}$ ∂$_{η}$D$_{i}$ (1) χ lk + (1) χ kl ∂$_{η}$D$_{k}$ (1) χ$_{il}$ ; (6.24)\nΓ$_{ij}$ := 16 πGD$_{i}$ϕ$_{1}$D$_{j}$ϕ$_{1}$ + 8 πG { ( ∂$_{η}$ϕ$_{1}$ ) 2 − D$_{l}$ϕ$_{1}$D $^{l}$ϕ$_{1}$ − a $^{2}$( ϕ$_{1}$ ) $_{2}$∂$^{2}$V ∂ϕ 2 } γ$_{ij}$ − 4 D$_{i}$ (1) Φ D$_{j}$ (1) Φ − 8 (1) Φ D$_{i}$D$_{j}$ (1) Φ + ( 6 D$_{k}$ (1) Φ D k (1) Φ +4 (1) Φ Δ (1) Φ +2 ( ∂$_{η}$ (1) Φ ) 2 + 8 ∂$_{η}$ H ( (1) Φ ) 2 + 16 H 2 ( (1) Φ ) 2 + 16 H (1) Φ ∂$_{η}$ (1) Φ − 4 (1) Φ ∂ 2 η (1) Φ ) γ$_{ij}$ − 4 H ∂$_{η}$ (1) Φ (1) χ$_{ij}$ − 2 ∂ 2 η (1) Φ (1) χ$_{ij}$ − 4 D k (1) Φ D$_{(}$$_{i}$ (1) χ$_{j}$$_{)}$$_{k}$ +4 D k (1) Φ D$_{k}$ (1) χ$_{ij}$ − 8 K (1) Φ (1) χ$_{ij}$ +4 (1) Φ Δ (1) χ$_{ij}$ − 4 D $^{k}$D$_{(}$$_{i}$ (1) Φ (1) χ$_{j}$$_{)}$$_{k}$ +2Δ (1) Φ (1) χ$_{ij}$ +2 D$_{l}$D$_{k}$ (1) Φ (1) χ lk γ$_{ij}$ + ∂$_{η}$ (1) χ$_{ik}$ ∂$_{η}$ (1) χ k j − D k (1) χ$_{il}$ D$_{k}$ (1) χ l j + D k (1) χ$_{il}$ D l (1) χ$_{jk}$ − 1 2 D$_{i}$ (1) χ lk D$_{j}$ (1) χ$_{lk}$ − (1) χ$_{lm}$ D$_{i}$D$_{j}$ (1) χ ml +2 (1) χ lm D$_{l}$D$_{(}$$_{i}$ (1) χ$_{j}$$_{)}$$_{m}$ − (1) χ lm D$_{m}$D$_{l}$ (1) χ$_{ij}$ − 1 4 ( 3 ∂$_{η}$ (1) χ$_{lk}$ ∂$_{η}$ (1) χ kl − 3 D$_{k}$ (1) χ$_{lm}$ D k (1) χ ml +2 D$_{k}$ (1) χ$_{lm}$ D l (1) χ mk − 4 K (1) χ$_{lm}$ (1) χ lm ) γ$_{ij}$. (6.25)\n(2) ν$_{i}$ = 2 Δ + 2 K { D$_{i}$ Δ − $^{1}$D $^{k}$Γ$_{k}$ − Γ$_{i}$ } , ∂$_{η}$ ( a 2 (2) ν$_{i}$ ) = 2 a 2 Δ + 2 K { D$_{i}$ Δ − $^{1}$D $^{k}$D$_{l}$ Γ l k − D$_{k}$ Γ k i } . (6.27)\nΓ$_{0}$ := 4 πG ( ∂$_{η}$ϕ$_{1}$ ) 2 + D$_{i}$ϕ$_{1}$D $^{i}$ϕ$_{1}$ + a $^{2}$( ϕ$_{1}$ ) $_{2}$∂$^{2}$V ∂ϕ 2 ) − 4 ∂$_{η}$ H ( (1) Φ ) 2 − 2 (1) Φ ∂ 2 η (1) Φ − 3 D$_{k}$ (1) Φ D k (1) Φ − 10 (1) Φ Δ (1) Φ − 3 ( ∂$_{η}$ (1) Φ ) 2 − 16 K ( (1) Φ ) 2 − 8 H 2 ( (1) Φ ) 2 + D$_{l}$D$_{k}$ (1) Φ (1) χ lk + 1 8 ∂$_{η}$ (1) χ$_{lk}$ ∂$_{η}$ (1) χ kl + H (1) χ$_{kl}$ ∂$_{η}$ (1) χ lk − 3 8 D$_{k}$ (1) χ$_{lm}$ D k (1) χ ml + 1 4 D$_{k}$ (1) χ$_{lm}$ D l (1) χ mk − 1 2 (1) χ lm Δ (1) χ$_{lm}$ + 1 2 K (1) χ$_{lm}$ (1) χ $^{lm}$; (6.23)"}]}
+{"image": "doclay/doclay_80859.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "133 STAT. 992 \nPUBLIC LAW 116–25—JULY 1, 2019 \n26 USC 7803. \nas issued by the National Taxpayer Advocate or provide  the National Taxpayer Advocate with the reasons for any  modification or rescission made or upheld by the Commis- sioner pursuant to such appeal.’’.  (2) REPORT\nsioner pursuant to such appeal.’’.  (2) REPORT TO CERTAIN COMMITTEES OF CONGRESS  REGARDING DIRECTIVES.—Section 7803(c)(2)(B)(ii) is amended  by redesignating subclauses (VIII) through (XI) as subclauses  (IX) through (XII), respectively, and by inserting after subclause  (VII) the following new subclause:  ‘‘(VIII) identify any Taxpayer Advocate Direc-\n(VII) the following new subclause:  ‘‘(VIII) identify any Taxpayer Advocate Direc- tive which was not honored by the Internal Rev- enue Service in a timely manner, as specified  under paragraph (5);’’.  NATIONAL TAXPAYER ADVOCATE ANNUAL REPORTS TO CON-\nunder paragraph (5);’’.  (b) NATIONAL TAXPAYER ADVOCATE ANNUAL REPORTS TO CON- GRESS.— \n(1) INCLUSION OF MOST SERIOUS TAXPAYER PROBLEMS.—  Section 7803(c)(2)(B)(ii)(III) is amended by striking ‘‘at least  20 of the’’ and inserting ‘‘the 10’’.  (2) COORDINATION WITH TREASURY INSPECTOR GENERAL FOR \n20 of the’’ and inserting ‘‘the 10’’.  (2) COORDINATION WITH TREASURY INSPECTOR GENERAL FOR  TAX ADMINISTRATION.—Section 7803(c)(2) is amended by adding  at the end the following new subparagraph:  ‘‘(E) COORDINATION WITH TREASURY INSPECTOR GEN-\nat the end the following new subparagraph:  ‘‘(E) COORDINATION WITH TREASURY INSPECTOR GEN- ERAL FOR TAX ADMINISTRATION.—Before beginning any  research or study, the National Taxpayer Advocate shall  coordinate with the Treasury Inspector General for Tax  Administration to ensure that the National Taxpayer Advo- cate does not duplicate any action that the Treasury  Inspector General for Tax Administration has already  undertaken or has a plan to undertake.’’.  (3) STATISTICAL SUPPORT.— \nundertaken or has a plan to undertake.’’.  (3) STATISTICAL SUPPORT.—  (A) IN GENERAL.—Section 6108 is amended by adding \n(3) STATISTICAL SUPPORT.—  (A) IN GENERAL.—Section 6108 is amended by adding  at the end the following new subsection:  ‘‘(d) STATISTICAL SUPPORT NATIONAL TAXPAYER ADVO-\nat the end the following new subsection:  ‘‘(d) STATISTICAL SUPPORT FOR NATIONAL TAXPAYER ADVO- CATE.—Upon request of the National Taxpayer Advocate, the Sec- retary shall, to the extent practicable, provide the National Tax- payer Advocate with statistical support in connection with the  preparation by the National Taxpayer Advocate of the annual report  described in section 7803(c)(2)(B)(ii). Such statistical support shall  include statistical studies, compilations, and the review of informa- tion provided by the National Taxpayer Advocate for statistical  validity and sound statistical methodology.’’.  (B) DISCLOSURE OF REVIEW.—Section 7803(c)(2)(B)(ii), \nvalidity and sound statistical methodology.’’.  (B) DISCLOSURE OF REVIEW.—Section 7803(c)(2)(B)(ii),  as amended by subsection (a), is amended by striking ‘‘and’’  at the end of subclause (XI), by redesignating subclause  (XII) as subclause (XIII), and by inserting after subclause  (XI) the following new subclause:  ‘‘(XII) with respect to any statistical informa-\n(XI) the following new subclause:  ‘‘(XII) with respect to any statistical informa- tion included in such report, include a statement  of whether such statistical information was  reviewed or provided by the Secretary under sec- tion 6108(d) and, if so, whether the Secretary  determined such information to be statistically  valid and based on sound statistical methodology;  and’’.  CONFORMING\nand’’.  (C) CONFORMING AMENDMENT.—Section  7803(c)(2)(B)(iii) is amended by adding at the end the fol- lowing: ‘‘The preceding sentence shall not apply with "}]}
+{"image": "doclay/doclay_63974.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "(6) JP 2017-66267 A 2017.4.6\nため、本実施形態の熱伝導性組成物を、電⼦部品と放熱器との間に介在させて積層⽅向に 圧⼒を付与すると、コアシェル粒⼦１が電⼦部品⼜は放熱器の表⾯形状に沿って変形して 、コアシェル粒⼦１と電⼦部品⼜は放熱器との接触⾯積が広くなるので、コアシェル粒⼦ １と電⼦部品⼜は放熱器との間の界⾯熱抵抗が低くなる。⾼分⼦材料の弾性率の下限は、 ⼀般に１ＭＰａである。\n コア粒⼦２は球状であることが好ましい。ここで、球状とは完全な球⾯体である必要は なく、楕円体状であってもよいし、⼀部に平坦⾯を有していてもよい。コア粒⼦２を構成 する⾼分⼦材料の例としては、シリコーン樹脂、アクリル樹脂、フェノール樹脂、スチレ ン樹脂、ポリエチレンテレフタレート（ＰＥＴ）、シリコーンゴム、フッ素ゴム及びウレ タンゴムを挙げることができる。これらの⾼分⼦材料の中で好ましいのは、シリコーン樹 脂、シリコーンゴム（シリコーン樹脂またはシリカ粒⼦コートシリコーンゴムを含む）及 びアクリル樹脂（特に、⾼架橋密度アクリル樹脂）である。\n コアシェル粒⼦１のシェル３は、図１に⽰すように、アスペクト⽐（⻑軸ａと短軸ｂと の⽐＝ａ／ｂ）が⾼く、厚さが薄い⾼アスペクト⽐⾦属領域４をランダムな⽅向に配向さ せた状態で結合させた形態を有していると考えることができる。すなわち、シェル３は、 ⾦属繊維をランダムな⽅向に配向させた状態で凝集させたものと同様の形態を有するため 、⾼い熱伝導性を⽰す。\n シェル３を構成する⾦属層は、単層であっても⼆層以上であってもよい。⾦属層は、単 ⼀の⾦属の層であってもよいし、⼆種以上の⾦属を含む合⾦の層であってもよい。シェル ３は、⾦、銀、銅、ニッケル及びアルミニウムからなる群より選択される少なくとも⼀つ の⾦属の層を含むことが好ましい。シェル３の厚さは、０．１μｍ以上であることが好ま しい。シェル３の厚さが０．１μｍより薄いと、シェル３を連続した⾦属層とすることが 難しくなり、熱伝導性組成物の熱伝導性が低下することがある。シェル３の厚さの上限は 、⼀般に１０μｍである。また、シェル３は、熱伝導組成物全体に対する体積含有量が５ 体積％以上、４０体積％以下であることが好ましい。シェル３の体積含有量が５体積％よ り少ないと、コアシェル粒⼦１の熱伝導度が⼗分に⾼くならないことがある。シェル３の 体積含有量が４０体積％を超えると、熱伝導組成物が硬くなり、全体としての変形量が⼩ さくなり、シェル３が塑性変形しにくくなることがある。コアシェル粒⼦１の⼒学的特性 は、シェル３の影響を受けるので、シェル３が塑性変形しにくくなると、コアシェル粒⼦ １が変形しにくくなる。\n シェル３を構成する⾦属層は、無電解めっきによって作製されたものであることが好ま しい。無電解めっきによると、コア粒⼦２の表⾯に⾦属の⽪膜を均⼀に形成することがで き、また被膜の膜厚の制御が容易となる。無電解めっきによってコア粒⼦２の表⾯を銀層 で被覆する⽅法としては、コア粒⼦２に対して、３０〜４５℃に加熱した錫化合物の⽔溶 液による前処理を⾏う⼯程と、前記コア粒⼦２に、還元剤を⽤いて無電解銀めっきを⾏う ⼯程を有する⽅法を⽤いることができる。無電解めっきによってコア粒⼦２の表⾯を銀層 で被覆する⽅法は、特許第５４９７１８３号に記載されている。\n 次に、本実施形態の熱伝導性組成物で⽤いる基油について説明する。基油としては、⼀ 般的な熱伝導性組成物に⽤いられるものを使⽤することができる。基油の例としては、シ リコーンオイル系基油、鉱油系基油、合成炭化⽔素系基油、エステル系基油、エーテル系 基油及びグリコール系基油⼜はそれらの組合せを挙げることができる。シリコーンオイル 系基油は、ジメチルシリコーンオイル及びメチルフェニルシリコーンオイルのようなスト レートシリコーンオイル、並びにネオペンチルポリエーテルシリコーンオイル、⾼級脂肪 酸エステルシリコーンオイル及びフルオロアルキルシリコーンオイルのような変性シリコ ーンオイルを含む。鉱油系基油は、例えば、ナフテン系鉱油、パラフィン系鉱油、芳⾹族\n【００３４】\n【００３３】\n【００３２】\n【００３１】\n【００３０】"}]}
+{"image": "doclay/doclay_69616.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Figure 6-82 Creating a new IBM MQ instance - 22\nFigure 6-83 Creating a new IBM MQ instance - 23\n19.After you close the pop-up window, you see that the new queue manager is displayed in  the MQ tile.\n18.When you have confirmed the queue manager is up and running, go back to the window  where you initiated the deployment and click  Done  to close the pop-up window.\n222  Accelerating Modernization with Agile Integration"}]}
+{"image": "doclay/doclay_63852.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Nov. 22, 2018 \n20 \nUS 2018/0335696 Al \n-continued  0~1  I~  #  0  0 \ns~  ~F "}]}
+{"image": "doclay/doclay_976.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Meanwhile, our basic policy on returns to shareholders is to  increase returns consistently and continuously through the sustain- able growth of enterprise value, by sustaining a consolidated payout  ratio of over 20%, while prudently managing the level of retained  earnings to maintain our financial soundness in view of the public  nature of banking business operations.\nOur group has been rapidly expanding our business operations as  each group company has been growing to become a major player in  its business area and we have increased the number of group com- panies through acquisitions, including SMBC Nikko Securities. Also,  in order to meet the global strengthening of financial regulations, we  are required to focus further on the enhancement of our risk-return  and cost-return profiles and steadily expand our bottom-line profit.  Therefore, we will strengthen our group management capabilities  including risk management, control consolidated overhead ratio at  50-55% and develop human resources required for global business  expansions.\nIn order to achieve these two goals, we will proactively allocate  risk-adjusted assets into strategic business areas while controlling  aggregate volume of risk-adjusted assets by reducing low-yielding  assets, and strengthen our capital base by consistently accumulat- ing retained earnings. We will consider any increases of shareholders  returns, by taking into account the level of our regulatory capital,  payout ratio and dividends.\n◎ Establish a solid financial base and corporate  infrastructure\n◎ Capital Policy and Returns for Shareholders\nWe shall sincerely and faithfully pursue these initiatives to meet  the expectations of our stakeholders.\nIn the medium-term management plan, we have set a management  goal to achieve Core Tier I ratio* of approximately 8% on March  31, 2014. This means that we will strive to achieve a capital ratio  of approximately 1% higher than the Basel III required level of 7%  by five years earlier than the Basel III full implementation deadline of  March 2019.\n* Calculated based on the definition under Basel III in 2019; all regulatory  adjustments are deducted from Common Equity Tier I, excluding net unreal- ized gains (losses) on other securities (SMFG consolidated).\n◎ Group Structure*\nSeptember 2011\nTakeshi Kunibe President and CEO Sumitomo Mitsui  Banking Corporation\nKoichi Miyata President Sumitomo Mitsui Financial Group, Inc.\n* As of Jun. 30, 2011 for shareholding ratio and as of Mar. 31, 2011 for other figures.\nConsolidated total assets ¥138 trillion 12.47% 40% 60% 100% 100% 100% 100% 100% 22% 66% 100% 51% 34% ¥115 trillion ¥74 trillion ¥55 trillion approx. 26 million approx. 119,000 Consolidated Tier I ratio Total assets Deposits Loans Number of retail accounts Number of corporate loan clients Sumitomo Mitsui Finance and Leasing Japan Research Institute SMBC Nikko Securities SMBC Friend Securities SMFG Card & Credit Sumitomo Mitsui Card Sumitomo  Corporation (Consumer finance) (Credit card) (Securities) (System engineering and  management consulting, etc.) (Leasing) NTT DOCOMO Cedyna Promise ORIX Credit Corporation Sumitomo Mitsui Financial Group Sumitomo Mitsui Banking Corporation Became a wholly-owned subsidiary (Oct. 2009) Became a consolidated subsidiary (Jul. 2009) Became a wholly-owned subsidiary (May 2011) SUMITOMO MITSUI Banking Corporation\nSMFG  2011 7"}]}
+{"image": "doclay/doclay_20127.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Radian Group Inc. Notes to Consolidated Financial Statements - (Continued)\nThe risk analytics team is responsible for the analysis of market risk factors and their potential impact on our loss  estimates. Key market risk factors, including interest-rate risk and credit spreads, are assessed on an individual credit and  insured portfolio basis. The risk analytics team has developed quantitative tools and models to measure these risks, which  incorporate the risk assessments and internal ratings assigned by each of the teams within risk management.  Additionally, we  use an internal economic capital methodology to attribute economic capital to each individual credit exposure within our  insured portfolio. This methodology relies heavily on our ability to quantify the individual risks of default and prepayment  underlying each transaction in our insured portfolio. Economic capital is also the basis for calculating risk-adjusted returns on  our capital, which allows us to evaluate the credit risk relative to the premium received. \nIn our financial guaranty reinsurance business, the primary obligation for assessing and mitigating claims rests with our  ceding companies. To help align the ceding company’s interests with ours, we generally have required that the ceding company  retain a significant portion of the exposure on any single risk that we reinsure. Our portfolio management group is responsible  for the periodic diligence and evaluation of the underwriting and surveillance capabilities of the ceding companies. Each of the  ceding companies is obligated to provide us with quarterly updates to their own watch and reserve lists, including reserve  information. In the event that we have identified a potential deficiency in the surveillance activities of a ceding company ,  appropriate personnel in our risk management department may conduct an independent analysis to the extent adequate  information is available. We also may have an independent view on assumed credits where we also have direct exposure based  on the information obtained through our independent credit review . As a result, we may assess credits and establish reserves  based upon information in addition to that received from the ceding company . \nOur risk management department reviews both performing and under -performing transactions. Performing credits  generally have investment grade internal ratings, denoting nominal to moderate credit risk. However , net claim liabilities may  be established for performing credits if the expected losses on the credit exceed the unearned premium revenue for the contract  based on the present value of the expected net cash outflows. If our risk management department concludes that a directly  insured transaction should no longer be considered performing, it is placed in one of three designated watch list categories for  deteriorating credits: Special Mention, Intensified Surveillance or Case Reserve.  Assumed exposures in financial guaranty’ s  reinsurance portfolio are generally placed in one of these categories if the ceding company for such transaction downgrades it  to an equivalent watch list classification. However , should our financial guaranty risk management group disagree with the risk  rating assigned by the ceding company, we may assign our own risk rating rather than use the risk rating assigned by the ceding  company. \nOur financial guaranty business has a  Watch and Reserve Committee that meets at least quarterly to review under - performing credits and establish reserves for transactions.  The Watch and Reserve Committee is chaired by the head of the  portfolio management group and includes senior management, credit, legal and finance personnel from both the financial  guaranty business and Radian Group. Radian Group’ s board of directors has formed a Credit Committee of independent  directors to assist the board in its oversight responsibilities for our credit risk management policies and procedures, including  heightening board-level awareness of the impact of developing risk trends in our portfolio. Our risk management group updates  this committee, no less frequently than on a quarterly basis, on all aspects of risk management, including portfolio/sector  analysis, risk management policies and Watch and Reserve Committee recommendations and decisions.  The following is  additional information regarding financial guaranty’ s categories for deteriorating credits: \n229"}]}
+{"image": "doclay/doclay_43871.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Perspiration causes damage to the parachute much like salt  water does. Small amounts are not significant and may be  ignored. For larger areas heavily contaminated, clean the  parachute in accordance with the Removal of Salt Water  Contamination section above.\nrepair. Identification of these conditions and rigger-applied  repairs determine their effect on the airworthiness of the  parachute assembly.\nNylon that has been contaminated by acid may have  irregular shaped spots of gray or dead white color. The  acid-contaminated fabric may also become powdery when  scraped lightly. Parachute components suspected of acid  contamination may be tested with blue litmus paper. Dampen  the suspect area with distilled water. Then lay the litmus  paper on the area in question. If the paper turns pink, acid is  present. Be careful not to touch the litmus paper, as touching  the paper can cause an erroneous response.\nDry parachute assembly in accordance with the section titled,  Drying a Parachute. \nThe following steps should be taken when removing mildew  from the parachute:\nIf an area tests positive for acid and the effected area is  known to be localized, that area should be neutralized  with a solution of distilled water and ammonia. Household  ammonia works. Ammonia does not damage nylon or  hardware. The damaged area should be removed and  the resulting hole should be patched. If the extent of  contamination cannot be determined or if it effects large  portions of the parachute, the parachute should be first  destroyed, then disposed of.\nHydrocarbons usually do not harm nylon. Petroleum  products, such as oil or grease, have a greenish or brownish  appearance. Wash the affected area by repeated applications  of mild soap and water solution until the affected area is  clean. Each application shall be followed by a rinse in clean  fresh water. Once complete, hang assembly in drying tower  in accordance with the section titled, Drying a Parachute. \nThe following steps should be taken when removing  bloodstains from the parachute:\nCrystals of dry salt and the presence of pale brown circular  stains are often evidence of salt-water exposure. If the  parachute is allowed to dry after salt-water immersion  without being rinsed in fresh water, salt crystals form causing  damage to the fabric and suspension lines.\nParachutes exposed to salt water should be rinsed out several  times in warm fresh water in a smooth tub. Use of a water  softener is recommended. Hang assembly in drying tower  in accordance with the section within this chapter titled,  Drying a Parachute. The maximum complete salt-water  immersion limits for the parachute are listed below. The  parachute assembly should be cleaned within 8 hours of  immersion. Remove from service any parachute assembly  or sub-assembly for any of the following conditions:\nThe following steps should be taken when removing soil  from the parachute:\nRemoval of Perspiration\nAcid Contamination\nRemoval of Fresh Water\nRemoval of Mildew\nAction\nRemoval of Petroleum Products\nSalt Water Contamination\nAction\nRemoval of Bloodstains\nRemoval of Soil\n7-10\n1. Wash affected area with mild soap and water solution.\n2. Rinse affected area thoroughly with fresh, clear water.\n3. Hang assembly in drying tower in accordance with  the section titled, Drying a Parachute. \n1. Soak the stained area in cold water.\n2. Hand wash affected area with mild soap and  water solution.\n3. Rinse affected area thoroughly with fresh clean water.\n4. Hang assembly in drying tower in accordance with  the section titled Drying a Parachute.\n1. Hang the parachute and shake to remove most of the  dirt and sand. \n2. Brush lightly with a soft-bristled brush.\n3. If the assembly is extremely contaminated, perform  the following: \n1. Immersion in salt water for more than 6 hours if the  parachute contains cadmium plated parts.\n2. Immersion in salt water for more than 24 hours if  the parachute contains stainless steel parts (i.e.,  slider stops).\n3. Immersion in salt water and cannot be cleaned for  36 hours."}]}
+{"image": "doclay/doclay_41790.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "In order to prevent the feathering spring and counterweights  from feathering the propeller when the engine is shut down  and the engine stopped, automatically removable high-pitch  stops were incorporated in the design. These consist of spring- loaded latches fastened to the stationary hub that engage  high-pitch stop plates bolted to the movable blade clamps.  When the propeller is in rotation at speeds over 600–800 rpm,  centrifugal force acts to disengage the latches from the high- pitch stop plates so that the propeller pitch may be increased  to the feathering position. At lower rpm, or when the engine  is stopped, the latch springs engage the latches with the high- pitch stops, preventing the pitch from increasing further due to  the action of the feathering spring. As mentioned earlier, the  engine load would be excessive, especially on fixed-turbine  turboprop engines. One safety feature inherent in this method  of feathering is that the propeller feathers if the governor oil  pressure drops to zero for any reason. As the governor obtains  its supply of oil from the engine lubricating system, it follows  that if the engine runs out of oil or if oil pressure fails due  to breakage of a part of the engine, the propeller feathers  automatically. This action may save the engine from further  damage in case the pilot is not aware of trouble.\nUnfeathering can be accomplished by any of several methods,  as follows:\nNormal in-flight unfeathering is accomplished when the pilot  positions the propeller condition lever into the normal flight  (governing) range.  [Figure 7-26]  This causes the governor to  disconnect the propeller oil supply from drain and reconnects  it to the governed oil supply line from the governor. At that  point, there is no oil available from the engine oil pump to  the governor; therefore, no governed oil is available from the  governor for controlling the propeller blade angle and rpm.  As the engine is started, its speed increases, the governor \nsupplies oil to the propeller, and the blade angle decreases.  As soon as the engine is operating, the governor starts to  unfeather the blades. Soon, windmilling takes place, which  speeds up the process of unfeathering.\nIn general, restarting and unfeathering of propellers can  be classified as reciprocating engine restart unfeathering,  turboprop engine restart unfeathering, and accumulator  unfeathering. When reciprocating unfeathering is used, the  engine takes a little longer to start turning enough to provide  oil pressure to the governor and then to the propeller. This  delay can cause vibration as the propeller is unfeathered.  Many aircraft can use an accumulator to provide stored  pressure to unfeather the propeller much quicker.\nSpecial unfeathering systems are available for certain aircraft  where restarting the engine is difficult or for training purposes.  The system consists of an oil accumulator connected to the  governor through a valve.  [Figure 7-26]  The air or nitrogen  pressure in one side of the accumulator pushes a piston to  force oil from the other side of the accumulator through  the governor to the propeller piston to move the propeller  blades from feather to a lower blade angle. The propeller  then begins to windmill and permits the engine to start. When  the unfeathering pump is used, it is an additional pump that,  once the propeller control is in the correct position, the (full  increase rpm) pump is actuated and the oil pressure from the  pump unfeathers the propeller.\nIce formation on a propeller blade, in effect, produces a  distorted blade airfoil section that causes a loss in propeller  efficiency. Generally, ice collects asymmetrically on a  propeller blade and produces propeller unbalance and  destructive vibration and increases the weight of the blades.\nA typical fluid system includes a tank to hold a supply of  anti-icing fluid.  [Figure 7-27]  This fluid is forced to each  propeller by a pump. The control system permits variation  in the pumping rate so that the quantity of fluid delivered to  a propeller can be varied, depending on the severity of icing.  Fluid is transferred from a stationary nozzle on the engine  nose case into a circular U-shaped channel (slinger ring)  mounted on the rear of the propeller assembly. The fluid  under pressure of centrifugal force is transferred through  nozzles to each blade shank.\nBecause airflow around a blade shank tends to disperse  anti-icing fluids to areas where ice does not collect in large  quantities, feed shoes, or boots, are installed on the blade\n7-17\n1.  Start the engine, so the governor can pump oil back  into the propeller to reduce pitch. In most light twins,  this procedure is considered adequate since the  feathering of the propeller would happen infrequently.  Vibration can occur when the engine starts and the  propeller starts to come out of feather.\n2.  Provide an accumulator connected to the governor  with a valve to trap an air-oil charge when the propeller  is feathered but released to the propeller when the rpm  control is returned to normal position. This system is  used with training aircraft because it unfeathers the  propeller in a very short time and starts the engine  wind milling.\n3.  Provide an unfeathering pump that provides pressure  to force the propeller back to low pitch quickly using  engine oil.\nAnti-Icing Systems\nIce Control Systems \nPropeller Auxiliary Systems\nUnfeathering"}]}
+{"image": "doclay/doclay_62510.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "US 9,256,127 B2 \n102 \n101 \n-continued \n-continued \nio  )  o Y ~(  ~o  ~o  0  0  6  o \n~o  ~o  \" o  O  ,06cro  +  ~o  ~o  0  0  ~  ~o "}]}
+{"image": "doclay/doclay_33392.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Coarse-graining dynamics by telescoping down time-scales: comment for Faraday FD144\narXiv:1001.1166v1[cond-mat.soft]7 Jan 2010\nArd A. Louis 1\n$^{1}$Rudolf Peierls Centre for Theoretical Physics, 1 Keble Road, Oxford OX1 3NP, United Kingdom\n(Dated: November 4, 2018)\nI briefly review some concepts related to coarse-graining methods for the dynamics of soft mat- ter systems and argue that such schemes will almost always need to telescope down the physical hierarchy of time-scales to a more compressed, but more computationally manageable, separation.\nPACS numbers:\nThe question of how to properly coarse-grain a dynam- ical simulation is a very interesting one. I think there is no single answer, but want to use an example here from our simulations of colloidal hydrodynamics to make some points that I believe are of more general relevance.\nConsider a buoyant colloid of mass M$_{c}$ and a radius a = 1 µm in H 2 O . As described in more detail in [1], its behaviour is governed by a series of different timescales shown in table I. If you are only interested in the be- haviour of the colloids, then the two fastest time-scales, the solvent collision time τ col and the solvent relaxation time τ$_{f}$ , can be ignored as long as they are shorter than any other colloidal time-scales. The first physi- cally relevant time-scale is the Fokker Planck time-scale τ$_{FP}$ ≈ 10 $_{−}$13 over which the colloid loses memory of the short-time forces acting on it [2]. For the example colloid, the next time-scale up is the sonic time t$_{cs}$ ≈ 6 . 7 × 10 $^{$_{−}$10}$s . Then comes the Langevin time τ$_{B}$ ≈ 2 . 2 × 10 $^{$_{−}$7}$s that measures the exponential decay time of the velocity auto- correlation function within the Langevin approximation. Interestingly, for colloids this time-scale is artificial and does not have direct physical meaning (see appendix of [1]). Next up is the kinematic time τ$_{ν}$ ≈ 10 $^{$_{−}$6}$s over which vorticity diffuses away from the colloid. If your colloid moves a significant fraction of its radius within the time τ$_{ν}$ , then the colloid will feel the effects of its own motion from a time τ$_{ν}$ back, and finite Reynolds number ( Re ) effects start to kick in. For that reason, it needs to be kept small compared to time-scales of colloidal diffusion or advection. The largest time-scale we consider here is the diffusion time τ$_{D}$ ≈ 5 s . However, if the colloid also moves under an external force with a velocity v$_{s}$ , then there is an additional time-scale t$_{s}$ = a/v$_{s}$ that measures how long it takes to advect over its radius, and you can then also define a related Peclet number P e = t$_{s}$/τ$_{D}$ that measures the relative importance of convection over diffusion.\nFrom the Fokker Planck time on up to the diffusion time covers 13 orders of magnitude. It is clearly not possible to capture all of these in a simulation. Instead, what is needed is time-scale separation. As long as the time-scales are properly separated, you should still be simulating the correct underlying physics. This process can visualized in Figure 1 (taken from ref. [1]) which shows an example of how the hierarchy of time-scales is\ntelescoped down to a more computationally manageable separation in order maximise simulation efficiency, but in such a way that the times are still sufficiently separated to correctly resolve the underlying physical behaviour. A good example of the rationale behind this thinking can be illustrated with the sonic time t$_{cs}$ . Physically it needs to be much smaller than the diffusion time, or else locally you have supersonic behaviour. But if it is too small, the simulation will spend most of its time resolving sound waves that may not be that interesting for the colloidal behaviour you are trying to reproduce, making the simulation very inefficient.\nIn order to correctly interpret the physical meaning of you simulation you need to telescope the time-scale hi- erarchy back out to the physical one you want to study. For example, if you are interested in physics that is dom-\nFIG. 1: Telescoping down: The hierarchy of time-scales for a colloid (here the example taken is for a colloid of radius 1 µm in H 2 0) is compressed in the coarse-grained simulations to a more manageable separation. As long as the physically important times are clearly separated, the simulation should still generate the correct physical picture. Once the simu- lations are completed, they can be related in more detail to particular experiments by telescoping back out to the relevant experimental time-scales.\n10 −8  s  τ col −sonic τ cs − Fokker−Planck τ FP B τ 10 −7  s  10$^{−15}$s − fluid collision 10$^{−13}$s  10$^{−12}$s  10$^{−11}$s  10$^{−10}$s  10 −9  s  10 −6  s  10 −0  s  10 −1  s  τ D −sonic τ cs − Fokker−Planck τ FP −kinematic τ ν −3  s  10 −2  s  10 D τ −colloid diffusion 10 −1 10 −0  s  s  10 −14 − fluid de−correlation τ f −Browinian (Langevin) s  −kinematic τ ν −colloid diffusion Telescoping down"}]}
+{"image": "doclay/doclay_840.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Directors’ Report 57\nAdditional Statutory Disclosures \nDirectors’ Report\nDetails of remuneration \nDetails of the nature and amount of each major element of the remuneration of the Directors and the Group executive managers are set out in the following tables.\n1   Non-monetary benefits relate to car parking, travel, life insurance, relocation, and accommodation allowance provided by the Company. Relocation and accommodation  allowance is applicable to interstate recruitment of relevant personnel.\n2   Amortised value of rights comprises the fair value of performance and deferred rights expensed during the year. This is the first year rights were issued. This is an accounting  expense and does not reflect the value to the executive of rights that vested in the financial year. Refer to the table on page 60 for the value of rights that have vested. \n3  Consulting Fees of $100,000 were paid or payable to Norwest Mining Consultants Ltd, of which Peter McAleer is an officer and director.\nYear Ended 30 June 2013 Short-term benefits Post-  employment  benefits Share-based  payment Name Cash salary and fees $ Cash bonus $ Non-monetary  benefits 1 $ Super- annuation $ Amortised value  of rights 2 (Accounting  Expense) $ Total $ Non-Executive Directors Ross Smyth-Kirk 160,000 – 12,258 14,400 – 186,658 Peter McAleer 3 100,000 – – – – 100,000 Craig Carracher 90,500 – – 18,500 – 109,000 Peter Alexander 100,000 – – 9,000 – 109,000 Sub-total Non-Executive Directors Compensation 450,500 – 12,258 41,900 – 504,658 Executive Director Gavin Thomas 1,055,000 – 68,587 25,000 410,974 1,559,561 Other Key Management Personnel Duane Woodbury  475,000 – 6,157 26,398 136,367 643,922 Tim Benfield 483,524 – – 16,476 21,029 521,029 Ron James  400,000 – 2,478 – 109,093 511,571 Ross Coyle 365,000 – 13,189 25,000 106,366 509,555 Joel Forwood  305,000 – 11,928 25,000 38,132 380,060 Brett Dunstone 168,355 – 43,591 9,611 – 221,557 Phil MacIntyre  781,245 – 29,205 – – 810,450 Sub-total Executive Director and other Key  Management Personnel Compensation 4,033,124 – 175,135 127,485  821,961 5,157,705 TOTAL 4,483,624 – 187,393 169,385 821,961 5,662,363\ncontinued u"}]}
+{"image": "doclay/doclay_15860.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "continue to costs lower IMPROVE productivity that growth leverage\nLeverage that growth, continue to lower costs and improve productivity. 2.\nOur capacity is sufficient to handle substantial new sales growth without additional fixed costs, which will allow operating earnings to grow faster than sales. And everyone, everywhere at Crane is committed to finding additional ways of doing more with less to improve our sales per employee."}]}
+{"image": "doclay/doclay_47322.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "(1)  Area  (2)  Plot Reference Number(s)  shown on land plans  (3)  Purpose(s) for which rights  over land may be acquired protecting, accessing and  maintaining the new bridge;  and, for the benefit of the  undertaker and relevant  statutory undertakers, for the  provision of private means of  access to land as shown on  sheet 2 of the rights of way  and access plans, and in  connection with the diversion,  protection and maintenance of,  and access to, statutory  undertakers’ apparatus. 3-41  New rights (including the  imposition of restrictive  covenants) for the benefit of  the undertaker for the purpose  of providing and maintaining  appropriate visibility across  the new public highway. 3-45, 3-47  New rights (including the  imposition of restrictive  covenants) required for the  benefit of the undertaker for  the purpose of constructing,  protecting, accessing and  maintaining the new bridge  southern approach, and for the  benefit of the undertaker and  relevant statutory undertakers  for the provision of private  means of access as shown on  sheet 2 of the rights of way  and access plans, and in  connection with the diversion,  protection and maintenance of,  and access to, statutory  undertakers’ apparatus. The land plans – sheet 4  In the administrative area of  East Suffolk Council  4-05  New rights (including the  imposition of restrictive  covenants) for the benefit of  the undertaker for the purpose  of providing and maintaining  appropriate visibility across  the new public highway. 4-07, 4-08, 4-09  New rights (including the  imposition of restrictive  covenants) required for the  benefit of relevant statutory  undertakers in connection with  the diversion, protection and  maintenance of, and access to \n80"}]}
+{"image": "doclay/doclay_28534.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "projects FP6 NMP4-CT-2003-505699 and FP6 2002-IST-1-507879 are acknowledged.\n[1] H. Raether, Surface Plasmons (Springer, Berlin, 1988).\n[2] B. Hecht, H. Bielefeldt, L. Novotny, Y. Inouye, and D. W. Pohl, Phys. Rev. Lett. 77 , 1889 (1996).\n[3] S. I. Bozhevolnyi, and F. A. Pudonin, Phys. Rev. Lett. 78 , 2823 (1997).\n[4] H. Ditlbacher, J. R. Krenn, N. Felidj, B. Lamprecht, G. Schider, M. Salemo, A. Leitner, and F. R. Aussenegg, Appl. Phys. Lett. 80 , 404 (2002).\n[5] H. Ditlbacher, J. R. Krenn, G. Schider, A. Leitner, and F. R. Aussenegg, Appl. Phys. Lett. 81 , 1762 (2002).\n[6] A. Drezet, A. L. Stepanov, H. Ditlbacher, A. Hohenau, B. Steinberger, F. R. Aussenegg, A. Leitner, and J. R. Krenn, Appl. Phys. Lett. 86 , 074104 (2005).\n[7] A. Bouhelier, Th. Huser, H. Tamaru, H. -J. G¨ untherodt, D. W. Pohl, Fadi I. Baida and D. Van Labeke, Phys. Rev. B. 63 , 155404 (2001).\n[8] A. stepanov, J. R. Krenn, H. Ditlbacher, A. Hohenau, A. Drezet, B. Steinberger, A. Leitner, and F. Aussenegg, Opt. Lett. 30 ,1524 (2005)\n[9] A. Zeilinger, Am. J. Phys. 49 , 882 (1981). C. H. Holbrow, E. Galvez, and M. E. Parks, Am. J. Phys. 70 , 260 (2002).\n[10] H. Ditlbacher, Phd Thesis, Karl-Franzens Universit¨ at Graz (2003).\n[11] Each dipole generate at x, y a scalar field\n[12] M. Brun, A. Drezet, H. Mariette, N. Chevalier, J. C. Woehl, and S. Huant, Europhys. Lett. 64 , 634 (2003).\n[13] If we don’t neglect the SPP damping we obtain V$_{1}$ = 2 | R || T | / ( | R | $^{2}$e − δ/ (2 L SPP ) + | T | $^{2}$e − δ/ (2 L SPP $^{)}$) and V$_{2}$ = 2 | R || T | / ( | R | $^{2}$e − δ/ (2 L SPP ) + | T | $^{2}$e − δ/ (2 L SPP $^{)}$) for respectivelly the\n10\n[2, 4, 12]. r = √ ( x − x$_{s}$ ) 2 + ( y − y$_{s}$ ) 2 is the distance separating the source located at x$_{s}$, y$_{s}$ from the observation point, and Θ is the angle between the dipole P and the vector position r going from the source to the observation point. The dipole is induced by the local electric field E $_{0}$( x$_{s}$, y$_{s}$ ) and thus P = χ E $_{0}$( x$_{s}$, y$_{s}$ ) where χ is the dipole polarizability.\nΨ( x, y ) ∝ cos (Θ) e ik SPP $^{r}$e − r/ (2 L SPP ) $_{/}$√$_{r}$"}]}
+{"image": "doclay/doclay_6568.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "ENVIRONMENTAL REGULATION\ndirectors’ report\non the Financial Report of Transurban City Link Limited and Controlled Entity.\nGeoffrey O Cosgriff BAppSc, Company Director Diploma, FIE (Aust), FAICD\nINFORMATION ON DIRECTORS\nLaurence G Cox AO, B Com, FCPA, FSIA\nJeremy G A Davis BEc, MBA, MA, FAICD \nKimberley Edwards BE, MAdmin (Bus), FIE (Aust)\nSusan M Oliver BP&C\nW H John Barr AM\nGeoffrey R Phillips BE (Chem), MBA, MAICD\nPeter C Byers B Com (Hons)\nAs Operator, TLO must ensure it complies with EPA regulations. To meet this obligation, TLO monitors the emission of carbon monoxide, oxides of nitrogen and particulate matter from the Domain and Burnley Tunnel ventilation stacks. In addition, the Operator monitors ambient air quality around the tunnels. Current monitoring indicates emission levels from the stacks are well below the EPA licence limits, and that there has been an improvement in air quality since the tunnels opened.\nTLO is also required to regularly test the quality of the groundwater being discharged into the Yarra River. Tests show the water meets the standards under State Environment Protection Policy for water.\nMr Laurie Cox has had many years’ experience in Australia’s financial markets. He was the Chairman of the Australian Stock Exchange Limited from 1989 to 1994. Prior to joining Transurban, Mr Cox was Executive Chairman of the Potter Warburg Group of Companies and a Director of S G Warburg Securities of London. He is a director of Macquarie Bank Limited and Smorgon Steel Group Ltd and Chairman of Argosy Asset Management Australia Ltd, The Murdoch Childrens Research Institute and SMS Management Group and Technology Ltd. Age 62.\nMr Kim Edwards has extensive experience managing major commercial and infrastructure projects in Australia, UK and the Middle East. Prior to joining Transurban, he was General Manager - Projects for Transfield, and was responsible for assembling the successful bid for the Melbourne City Link Project. He was Project Director for Jennings Group’s $650 million Southgate development in Melbourne and has worked overseas on large port infrastructure projects. Age 50.\nMr John Barr has considerable experience in the Australian minerals and metals industry. He was Managing Director of the Australian subsidiary of Metallgesellschaft AG from 1974 until his retirement in June 1994. He is Chairman of Utilities of Australia Pty Ltd and The Swish Group Ltd, and a director of Iluka Resources Ltd and Oxiana Resources NL. Age 64.\nMr Peter Byers is a founding director and current Chairman of the Investment Committee of the Superannuation Scheme for\nAustralian Universities. He was formerly business manager and deputy principal of the University of Tasmania. He is a director of Adelaide Airport Ltd and Hills Motorway Ltd, a director of the responsible entity of Hills Motorway Trust and a director of the Blair Athol Group. He is an alternate director for Hancock Victorian Plantations Holdings Ltd. Age 60.\nGeoff Cosgriff is the Managing Director of Energy and Utilities Logica Pty Ltd following the sale of the MITS business to Logica Pty Ltd. He was the Managing Director of MITS Limited since the company commenced operation in 1990. Over this period, MITS grew to 600 staff and nearly $100m in sales of information technology solutions. He is also director of Utility Services Corporation and Skilltech Consulting Services. Previously Geoff held executive management roles with Melbourne & Metropolitan Board of Works and has had extensive experience in the information technology industry. Age 48.\nProfessor Jeremy Davis holds the AMP Chair of Management in the Australian Graduate School of Management at the University of NSW. His academic interests are in the fields of business policy and corporate performance. He is Chairman of Capral Aluminium Ltd and a Fellow of the Australian Institute of Company Directors. Professor Davis is a former vice-president and director of the Boston Consulting Group, and a former director of the Australian Stock Exchange, AIDC Ltd and Nucleus Ltd. Age 58.\nMs Susan Oliver is chair of Screen Sound Australia – The National Screen and Sound Archive and a director of Medical Benefits Fund and Programmed Maintenance Services Ltd. Ms Oliver was formerly a Senior Manager of Andersen Consulting. She has held board positions with the Victorian Institute of Marine Sciences, Interact Events Limited, FHA Design Pty Ltd and The Swish Group Ltd. Ms Oliver was also Managing Director of the Australian Commission for the Future Ltd. Age 50.\nMr Geoffrey Phillips was appointed Finance Director on 28 August 1998 and has been with Transurban for five years. Prior to joining Transurban, he worked for the Potter Warburg Group for 6 years as director in both the Corporate Finance and Fixed Interest Divisions. He is currently a director of Yarra Valley Water Limited. Age 57.\n29"}]}
+{"image": "doclay/doclay_67560.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "To power off a node canister by using the CLI, use the command that is shown in  Example 12-6.\nIf you power off the canister from the GUI, Figure 12-135 shows the system progress to power  off this canister. \nTo power off the entire system by using the GUI, complete the following steps:\n1. Browse to  Monitoring →  System , click  Actions → Power Off System , as shown in  Figure 12-136 on page 723.\nPowering off the system\nExample 12-6 Powering off a canister by using the CLI\nFigure 12-135 Power Off Canister\n> svctask stopsystem -node 2 Are you sure that you want to continue with the shut down? (y/yes to confirm)722  Implementing the IBM Storwize V5000 Gen2 with IBM Spectrum Virtualize V8.2.1"}]}
+{"image": "doclay/doclay_66053.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "[0052] As described above, a set of instructions is used in the processing of various embodiments of the invention. The servers may include software or computer programs stored in the memory ( e.g ., non-transitory computer readable medium containing program code instructions executed by the processor) for executing the methods described herein. The set of instructions may be in the form of a program or software or app. The software may be in the form of system software or application software, for example. The software might also be in the form of a collection of separate programs, a program module within a larger program, or a portion of a program module, for example. The software used might also include modular programming in the form of object oriented programming. The software tells the processor what to do with the data being processed.\n[0053] Further, it is appreciated that the instructions or set of instructions used in the implementation and operation of the invention may be in a suitable form such that the processor may read the instructions. For example, the instructions that form a program may be in the form of a suitable programming language, which is converted to machine language or object code to allow the processor or processors to read the instructions. That is, written lines of programming code or source code, in a particular programming language, are converted to machine language using a compiler, assembler or interpreter. The machine language is binary coded machine instructions that are specific to a particular type of processor, i.e ., to a particular type of computer, for example. Any suitable programming language may be used in accordance with the various embodiments of the invention. For example, the programming language used may include assembly language, Ada, APL, Basic, C, C++, COBOL, dBase, Forth, Fortran, Java, Modula-2, Pascal, Prolog, REXX, Visual Basic, JavaScript and/or Python. Further, it is not necessary that a single type of instructions or single programming language be utilized in"}]}
+{"image": "doclay/doclay_19334.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "PA RT I I\nMarket for Registrant’s Common Equity, Related Stockholder Matters and Issuer Purchases of Equity Securities ITEM 5\ncaption ‘‘Highlights’’ on page 31 of this Form 10-K. Cigna’s common stock is listed with, and trades on, the New York Stock Exchange under the symbol ‘‘CI’’.\nThe information under the caption ‘‘Quarterly Financial Data-Stock and Dividend Data’’ appears on page 127 and the number of shareholders of record as of December 31, 2012 appears under the\nIssuer Purchases of Equity Securities\nThe following table provides information about Cigna’s share repurchase activity for the quarter ended December 31, 2012:\nApproximate dollar value of shares Total # of shares Average price paid Total # of shares purchased as part of that may yet be purchased as part Period purchased (1) per share publicly announced program (2) of publicly announced program (3) October 1-31, 2012 2,467,731 $ 49.55 2,464,898 $ 314,709,797 November 1-30, 2012 4,612 $ 53.07 – $ 314,709,797 December 1-31, 2012 9,501 $ 53.13 – $ 314,709,797 TOTAL 2,481,844 $ 49.57 2,464,898 N/A\n(1) Includes shares tendered by employees as payment of taxes withheld on the exercise of stock options and the vesting of restricted stock granted under the Company’s equity compensation plans. Employees tendered 2,833 shares in October, 4,612 in November and 9,501 shares in December 2012.\n(2) Cigna has had a repurchase program for many years, and has had varying levels of repurchase authority and activity under this program. The program has no expiration date. Cigna suspends activity under this program from time to time and also removes such suspensions, generally without public announcement. Through December 31, 2012, the Company had repurchased approximately 4.4 million shares for approximately $208 million. Remaining authorization under the program was approximately $315 million as of December 31, 2012. On February 27, 2013, the Company’s Board of Directors increased share repurchase authority by $500 million, making the remaining authorization $815 million as of February 28, 2013.\n(3) Approximate dollar value of shares is as of the last date of the applicable month.\n30 CIGNA CORPORATION -  2012 Form  10-K"}]}
+{"image": "doclay/doclay_4010.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "*EP003800018A1*Fig. 1\n(54) SENSORVORRICHTUNG FÜR EINEN MESSERHALTER\n(57) Die vorliegende Erfindung betrifft eine Sensor- vorrichtung (4) für einen Messerhalter (1), umfassend - einen Grundkörper (6) zur Befestigung der Sensorvor-\nvorrichtung (4) für einen Messerhalter (1), umfassend - einen Grundkörper (6) zur Befestigung der Sensorvor- richtung (4) an einem Messerhalter (1), - mindestens einen an dem Grundkörper (6) befestigten\nrichtung (4) an einem Messerhalter (1), - mindestens einen an dem Grundkörper (6) befestigten Sensor (7) zur Erfassung einer Größe und - einen an dem Grundkörper (6) befestigten Sender (8)\nSensor (7) zur Erfassung einer Größe und - einen an dem Grundkörper (6) befestigten Sender (8) zur kabellosen Übertragung der von dem Sensor (7) er- fassten Größe.\n(43) Veröffentlichungstag:  07.04.2021 Patentblatt 2021/14\n(21) Anmeldenummer:  19200966.0\n(22) Anmeldetag:  02.10.2019\n(84) Benannte Vertragsstaaten:  AL AT BE BG CH CY CZ DE DK EE ES FI FR GB  GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO  PL PT RO RS SE SI SK SM TR Benannte Erstreckungsstaaten:  BA ME Benannte Validierungsstaaten:  KH MA MD TN\n(71) Anmelder:  Dienes Werke für Maschinenteile  GmbH & Co. KG 51491 Overath (DE)\n(72) Erfinder:  • Thielen, Rolf\nErfinder:  • Thielen, Rolf 50733 Köln (DE)\n• Klöcker, Gerd 51061 Köln (DE)\n(74) Vertreter:  Feucker, Max Martin et al Becker & Müller  Patentanwälte  Turmstraße 22 40878 Ratingen (DE)\nBemerkungen: Geänderte Patentansprüche gemäss Regel 137(2)  EPÜ.\n(19)\n(12) EUROPÄISCHE PATENTANMELDUNG\nInt Cl.: B26D 1/16 (2006.01) B26D 1/18 (2006.01) B26D 5/00 (2006.01) B26D 7/26 (2006.01) B23Q 17/09 (2006.01)\n(51) Int Cl.: B26D 1/16\nEP 800 018 A1\nPrinted by Jouve, 75001 PARIS (FR)\n(11) EP 3 800 018 A1"}]}
+{"image": "doclay/doclay_29315.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "[4] M. Bluhm and B. K¨ ampfer, Phys. Rev. D 77 0344004 (2008), ibid. 77 , 114016 (2008); F.G. Gardim and F.M. Steffens, Nucl. Phys. A 825 , 222 (2009); F. Brau and F. Buisseret, Phys. Rev. D 79 , 114007 (2009).\n[5] M.I. Gorenstein and O.A. Mogilevsky, Z. Phys. C 38 , 161 (1988).\n[6] R.D. Pisarsky, Phys. Rev. D 74 , 121703 (2006); Prog. Theor. Phys. Suppl. 168 , 276 (2007).\n[7] V.V. Begun, M.I. Gorenstein, and O.A. Mogilevsky, in preparation.\n[8] M. Panero, Phys. Rev. Lett. 103 , 23200 (2009).\n8"}]}
+{"image": "doclay/doclay_28772.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Concerning the quark zero modes, the flavor structure of the above models as well as the phe- nomenology can be captured by using the following simple rules [69, 74, 75]. In the 5D interaction basis, where the bulk masses k C ij x are diagonal ( x = Q, U, D ; i, j = 1 , 2 , 3; k is the AdS curvature), the value f$_{x}$ i of the profile of the quark zero modes is given by\nHere c$_{x}$ i are the eigenvalues of the C$_{x}$ matrices, ϵ = exp[ − ξ ], ξ = log[ M$_{Pl}$/ TeV], and M$_{Pl}$ is the reduced Planck mass. If c$_{x}$ i < 1 / 2, then f$_{x}$ i is exponentially suppressed. Hence, order one variations in the 5D masses yield large hierarchies in the 4D flavor parameters. We consider the cases where the Higgs VEV either propagates in the bulk [76] or is localized on the IR brane. For a bulk Higgs case, the profile is given by ˜ v ( β, z ) ≃ v √ k (1 + β )¯ z 2+ $^{β}$/ϵ , where ¯ z ∈ ( ϵ, 1) (¯ z = 1 on the IR brane), and β ≥ 0. The β = 0 case describes a Higgs maximally-spread into the bulk (saturating the AdS stability bound [77]). The relevant part of the effective 4D Lagrangian, which involves the zero modes and the first KK gauge states can be approximated by [69, 74]\n[ ] where φ u,d = ˜ φ, φ , g$_{∗}$ stands for a generic effective gauge coupling and summation over i, j is implied. The correction for the couplings from the case of fully IR-localized KK and Higgs states is given by the functions r φ 00 [74] and r g 00 [78, 79]: √ √$_{2}$\n− − − where r φ $_{00}$( β, c$_{L}$, c$_{R}$ ) = 1 for brane-localized Higgs and x$_{1}$ ≈ 2 . 4 is the first root of the Bessel function, J$_{0}$ ( x$_{1}$ ) = 0.\nIn Table VI we present an example of a set of f$_{x}$ i -values that, starting from anarchical 5D Yukawa couplings, reproduce the correct hierarchy of the flavor parameters. We assume, for simplicity, an IR localized Higgs. The values depend on two input parameters: f$_{U}$ 3 , which has been determined assuming a maximally localized t$_{R}$ ( c$_{u}$ 3 = − 0 . 5), and y$_{5D}$ , the overall scale of the 5D Yukawa couplings in units of k , which has been fixed to its maximal value assuming three KK states. On general grounds, the value of y$_{5D}$ is bounded from above, as a function of the number of KK levels, by the requirement that Yukawa interactions are perturbative below the cutoff of the theory, Λ$_{5D}$ ∼ N$_{KK}$k , and it is bounded from below in order to account for the large top mass. Hence the following range for y$_{5D}$ is obtained (see e.g. [76, 80]):\nf 2 x i = (1 − 2 c$_{x}$ i ) / (1 − ϵ 1 − 2 $^{c$_{x}$$_{i}$}$) . (6.4)\nL 4 D ⊃ ( Y u,d 5D )$_{ij}$ φ u,d ¯ Q$_{i}$f$_{Q}$$_{i}$ ( U, D )$_{j}$ f$_{U}$$_{j}$$_{,D}$$_{j}$r φ $_{00}$( β, c$_{Q}$$_{i}$, c$_{U}$$_{j}$$_{,D}$$_{j}$ ) + g$_{∗}$G $^{1}$x † $_{i}$x$_{i}$ [ f 2 x i r g $_{00}$( c$_{x}$ i ) − 1 /ξ ] , (6.5) ˜\n00 00 r φ $_{00}$( β, c$_{L}$, c$_{R}$ ) ≈ √ 2(1 + β ) 2 + β − c$_{L}$ − c$_{R}$ , r g $_{00}$( c ) ≈ √$_{2}$ J$_{1}$ ( x$_{1}$ ) 0 . 7 6 − 4 c ( 1 + e c/ 2 ) , (6.6)\n1 2 ≲ y$_{5D}$ ≲ 2 π N$_{KK}$ for brane Higgs ; 1 2 ≲ y$_{5D}$ ≲ 4 π √$_{N}$$_{KK}$ for bulk Higgs , (6.7)\n24"}]}
+{"image": "doclay/doclay_65359.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "representation 202 for the associated object 120 to indicate that the item has been completed. Following the modification of the logical representation 202, the object 120 will no longer be displayed in the region 118 for to-do items and, instead, can be shown in a region 118 for presenting completed items.\n[0084] FIG. 10 is a flow diagram showing a routine 1000 that illustrate aspects of the operation of the computing device 102 described above for providing dynamic whiteboard templates 116 and regions 118. It should be appreciated that the logical operations described herein with regard to FIG. 10, and the other FIGS., can be implemented (1) as a sequence of computer implemented acts or program modules running on a computing device and/or (2) as interconnected machine logic circuits or circuit modules within a computing device.\n[0085] The particular implementation of the technologies disclosed herein is a matter of choice dependent on the performance and other requirements of the computing device. Accordingly, the logical operations described herein are referred to variously as states, operations, structural devices, acts, or modules. These states, operations, structural devices, acts and modules can be implemented in hardware, software, firmware, in special- purpose digital logic, and any combination thereof. It should be appreciated that more or fewer operations can be performed than shown in the FIGS and described herein. These operations can also be performed in a different order than those described herein.\n[0086] The routine 1000 begins at operation 1002, where the whiteboard application 104 can present a UI 106 that includes a canvas 114. The routine 1000 then proceeds from operation 1002 to operation 1004, where a user can add a template 116 to the canvas 114, such as the manner described above with regard to FIG. 5. The routine 1000 then proceeds from operation 1004 to operation 1006.\n[0087] At operation 1006, a user can move an object 120 from the canvas 114 into a region 118 in the template 116 or from one region 118 in the template 116 to another region 118 in the template 116. In response thereto, the routine 1000 proceeds from operation 1006 to operation 1008, where the template 116 or the region 118 can modify the logical representation 202 associated with the moved object 120 in the manner described above. The destination region 118 can then generate a visual representation 206 of the object 120 at operation 1010 in the manner described above.\n[0088] From operation 1010, the routine 1000 proceeds to operation 1012, where the template 116 or region 118 can initiate one or more actions 702 based upon the change to the logical representation 202. For example, a structured summary 604 might be"}]}
+{"image": "doclay/doclay_25811.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "241\nAppendix F: Heavy Quark Production Radiation Derivation\nand\nFrom Eq. (F.46) we find\nwhere we have used the vector identity ( ⃗ a × ⃗ b ) · ( ⃗ c × ⃗ d ) = ( ⃗ a · ⃗ c )( ⃗ b · ⃗ d ) − ( ⃗ a · ⃗ d )( ⃗ b · ⃗ c ), and\nPlugging these pieces into Eq. (F.21) we find that\n⃗ E$_{k}$ · ⃗ E ∗ k = k 0 2 ⃗ A 2 k + ⃗ k 2 A 0 k 2 − 2 k $^{0}$A0 $_{k}$⃗ k · ⃗ A$_{k}$ . (F.72)\n⃗ B$_{k}$ · ⃗ B$_{−}$$_{k}$ = $^{[}$i ( ⃗ k × ⃗ A$_{k}$ ) ][ − i ( ⃗ k × ⃗ A$_{−}$$_{k}$ ) ] = ⃗ k 2 ⃗ A$_{k}$ · ⃗ A$_{−}$$_{k}$ − ⃗ k · ⃗ A$_{k}$ ⃗ k · ⃗ A$_{−}$$_{k}$ (F.73)\n= ⃗ B ∗ k · ⃗ B ∗ − $_{k}$, (F.74)\n⃗ B$_{k}$ · ⃗ B ∗ k = ⃗ k 2 ⃗ A 2 k − ( ⃗ k · ⃗ A$_{k}$ ) $^{2}$. (F.75)\nE$_{Proca}$ = 1 4 ∫ d $^{3}$k (2 π ) 3 $^{[}$⃗ k $^{2}$A0 $_{k}$A 0 − k − k 0 2 ⃗ A$_{k}$ · ⃗ A$_{−}$$_{k}$ + ⃗ k 2 ⃗ A$_{k}$ · ⃗ A$_{−}$$_{k}$ + ( ⃗ k · ⃗ A$_{k}$ )( ⃗ k · ⃗ A$_{−}$$_{k}$ ) + µ $^{2}$A0 $_{k}$A 0 − k + µ 2 ⃗ A$_{k}$ · ⃗ A$_{−}$$_{k}$ $^{]}$cos 2 k $^{0}$t + k 0 2 ⃗ A 2 k + ⃗ k 2 A 0 k 2 − 2 k $^{0}$A0 $_{k}$⃗ k · ⃗ A$_{k}$ + ⃗ k 2 ⃗ A 2 k − ( ⃗ k · ⃗ A$_{k}$ ) 2 + µ 2 A 0 k 2 + µ 2 ⃗ A 2 $_{k}$. (F.76)\nFirst let’s prove that the coefficient of the cos term is 0. It’s clear that the"}]}
+{"image": "doclay/doclay_36884.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "3. Wofür verarbeiten wir Ihre Daten und aufgrund welchen Gesetzes (Zweck der  Verarbeitung)? \na) Zur Erfüllung von vertraglichen Pflichten\nb) Wahrung berechtigter Interessen\nc) Aufgrund Ihrer Einwilligung\nd) Aufgrund gesetzlicher Vorgaben\n4. Wer bekommt Ihre Daten? \nWir verarbeiten Ihre personenbezogenen Daten im Rahmen des Vergabeverfahrens auf der  Grundlage  des  Art.  6  Abs.  1  lit.  a,  b,  c  und  e,  Abs.  3  DSGVO  und  des  wie folgt: \nDie Verarbeitung von Daten erfolgt zur Erbringung von Dienstleistungen im Rahmen der  fiskalischen Bedarfsdeckung für Behörden und andere staatliche Organisationen. Die Zwecke der  Datenverarbeitung  richten  sich  in  erster  Linie  nach  den  konkreten  Produkten  (z.B.  Bedarfserhebung, Abfragen und Analysen unter Behördenkunden künftig auch u. U. mittels des  Bedarfserhebungstools;  Durchführung  von  Vergabeverfahren  zur  Durchführung  von  vorvertraglichen und vertraglichen Maßnahmen, und der Abwicklung von Rahmenvereinbarungen  im Rahmen des E-Procurements). Die weiteren Einzelheiten zu den Datenverarbeitungszwecken  können Sie den maßgeblichen Geschäfts- und Nutzungsbedingungen entnehmen. \nSoweit erforderlich verarbeiten wir Ihre Daten über die eigentliche Erfüllung des Vertrages hinaus  zur Erfüllung rechtlicher Pflichten oder zur Wahrnehmung im öffentlichen Interesse liegender  Aufgaben, insbesondere zur:\nDie Zusendung unseres Newsletters über Neuerungen bei der e-Vergabe oder Informationen über  zukünftige Vergaben in von Ihnen ausgesuchten Produktbereichen beruht auf Ihrer Einwilligung. \nZudem unterliegen wir als öffentlicher Auftraggeber rechtlichen Verpflichtungen, das heißt  gesetzlichen  Anforderungen  (z.  B.  Gesetz  gegen  Wettbewerbsbeschränkungen,  Vergabeverordnungen, Wettbewerbsregistergesetz,  Steuergesetze).  Zu  den  Zwecken  der  Verarbeitung gehören unter anderem die Identitätsprüfung, Betrugs- und Geldwäscheprävention,  die Erfüllung steuerrechtlicher Kontroll- und Meldepflichten. \nIhre Daten bekommen nur die für die Bearbeitung zuständigen Personen und diejenigen, die ein  berechtigtes Interesse durch ihre Beteiligung darlegen können. So bekommen insbesondere bei  Beschaffungen nur Personen bei dem Bedarfsträger und der Vergabestelle Angebote zur  Kenntnis. Außerdem können zuständige Datenschutzbeauftragte, Vorgesetzte, Qualitätsmanager,  Innenrevisoren,  Nachprüfstellen,  Vergabekammern,  Rechnungs-  und  Preisprüfer  sowie  Angehörige der Rechnungshöfe in erforderlichem Umfang Einblick in Ihre Daten bekommen. Auch  von uns eingesetzte Auftragsverarbeiter können zu diesem Zweck Daten erhalten. Soweit Ihre \nSeite 2 \nHVA B-StB Information Datenschutz 08-19 \n- Prüfung  und  Optimierung  von  Verfahren  zur  Bedarfsanalyse  zwecks  direkter  Kundenansprache, \n- Geltendmachung rechtlicher Ansprüche und Verteidigung bei rechtlichen Streitigkeiten, \n- Gewährleistung der IT-Sicherheit und des IT-Betriebs, \n- Verhinderung und Aufklärung von Straftaten, \n- Videoüberwachungen zur Wahrung des Hausrechts, für Zutrittskontrollen, \n- Geschäftssteuerung und Weiterentwicklung von Dienstleistungen und Produkten. "}]}
+{"image": "doclay/doclay_68525.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "2. Select the wanted host. Click  Actions →  Edit Throttle , as shown in Figure 5-107.\n3. Enter the wanted type of I/O throttle (IOPS or Bandwidth). In our example, we set up an  IOPS throttle by entering the  IOPS limit , as shown in Figure 5-108.\nFigure 5-107 Selecting Edit Throttle option\nFigure 5-108 Setting IOPS throttle\nNote:  While defining a throttle for a host, you can define a throttle in terms of IOPS or  bandwidth, but not both at the same time. If you want to have host throttle defined for both  IOPS and bandwidth, you must define them one after the other.\n4. Click  Create . A task completion window opens. Click  Close .\nChapter 5. Host configuration  303"}]}
+{"image": "doclay/doclay_76078.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "With f ( w ) defined as above, [ Q ] is represented by the polynomial\nP ( x, y ) := ( − 1) f ( w $^{)}$y$_{1}$ . . . y$_{n}$$_{−}$$_{1}$ ∏ i ≤ p<p +1 <j ( x$_{i}$ + y$_{w}$ − $^{1}$( j $_{)}$)( x$_{i}$ − y$_{w}$ − $^{1}$( j $_{)}$) .\nProof. First consider ρ ( w Φ $^{+}$), the elements of s ∗ obtained by first applying the standard representative w to the positive roots, then restricting to s . They are as follows:\n• X$_{i}$ ( i ̸ = p + 1), with multiplicity 2. (One is the restriction of w ( Y$_{i}$ + Y$_{n}$ ) = Y$_{w}$$_{(}$$_{i}$$_{)}$ + Y$_{p}$$_{+1}$ , the other the restriction of w ( Y$_{i}$ − Y$_{n}$ ) = Y$_{w}$$_{(}$$_{i}$$_{)}$ − Y$_{p}$$_{+1}$ .)\n• X$_{i}$ + X$_{j}$ ( i < j , i, j ̸ = p + 1), with multiplicity 1.\n• For each i < j with i, j ̸ = p + 1, exactly one of ± ( X$_{i}$ − X$_{j}$ ), with multiplicity 1.\nRemoving roots of K , we have the following set of weights:\n• X$_{i}$ ( i ̸ = p + 1), with multiplicity 1.\n• X$_{i}$ + X$_{j}$ ( i ≤ p < p + 1 < j ), with multiplicity 1.\n• For each i < j with i ≤ p < p + 1 < j , exactly one of ± ( X$_{i}$ − X$_{j}$ ), with multiplicity 1.\nRecall that w is an honest permutation, with no sign changes. This means that the only way to get a weight of the form − ( X$_{i}$ − X$_{j}$ ) by the action of w is to apply w to some Y$_{k}$ − Y$_{l}$ ( k < l ) with w ( k ) > w ( l ). (Clearly, we want k, l ̸ = n .) For this root to remain after discarding roots of K , it must be the case that w ( k ) > p + 1, while w ( l ) ≤ p . Thus for each k < n such that w ( k ) > p + 1 (this says that k ∈ I$_{w}$ ), we count the number of l with k < l < n − 1 such that w ( l ) ≤ p (this says that l ∈ C ( k )). Adding up the total number of such pairs as we let k range over I$_{w}$ , we arrive at f ( w ). This says that the number of weights of the form − ( Y$_{i}$ − Y$_{j}$ ) contained in ρ ( w Φ $^{+}$) \\ ( ρ ( w Φ $^{+}$) ∩ Φ$_{K}$) is f ( w ).\nNow we consider the set ρ ( w $^{′}$w Φ $^{+}$) \\ ( ρ ( w $^{′}$w Φ $^{+}$) ∩ Φ$_{K}$) with w ′ ∈ W$_{K}$ , and compute the restriction [ Q ] |$_{w}$ $^{′}$w at an arbitrary S -fixed point. Since the action of w ′ on t commutes with\n125"}]}
+{"image": "doclay/doclay_70221.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "6. Read and accept the license agreement, and then click  Next  (Figure 14-5).\n7. Specify the installation options (Figure 14-6 on page 484):\na. In the  Fully qualified host name  field, type the fully qualified host name  of the installation target system.\nb. In the  User name  field, type the administrator account name.\nc. Select the  Create user account  check box to create a new user.\nd. In the  Password  and  Confirm password  fields, type the password of the  administrator account.\ne. From the Server type list, select  Master: All on one server .\n Chapter 14. Installing and configuring IBM Watson Content Analytics  483\nFigure 14-5 Software Agreement\n"}]}
+{"image": "doclay/doclay_62898.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "259 \nUS 9,323,153 B2 \n260 \n-continued \nIn addition, examples of the divalent heterocyclic hydro- carbon group (preferably  1  to 20 carbon atoms) in which the  Ra’s are bonded to each other to form or the derivative thereof  include a group where a group derived from a heterocyclic  compound such as pyrrolidine, piperidine, morpholine,  1,4,  5,6-tetrahydropyrimidine, 1,2,3,4-tetrahydroquinoline, 1,2,  3,6-tetrahydropyridine, homopiperazine, 4-azabenzimida- zole, benzotriazole, 5-azabenzotriazole,  1  H-1,2,3-triazole,  1,4,  7-triazacyclononane, tetrazole, 7-azaindole, indazole,  benzimidazole, imidazo[l ,2-a]pyridine,  (1  S,4S)-(  +  )-2,5-di- azabicyclo[2.2.1 ]heptane, 1,5,7-triazabicyclo[ 4.4.0]deck-5- en, indole, indoline, 1,2,3,4-tetrahydroquinoxaline, perhyd› roquinoline, 1,5,9-triazacyclododecane, or a group where the  group is derived from a heterocyclic compound is substituted  with one or more kinds of or one or more groups of a group  derived from a linear or branched alkane, a group derived  from a cycloalkane, a group derived from a aromatic com- pound, a group derived from a heterocyclic compound, and a  functional group such as a hydroxyl group, a cyano group, an  amino group, a pyrrolidino group, a piperidino group, a mor- pholino group, an oxo group. \nSpecific examples of the particularly preferable compound  (D) in the present invention are shown below, but the present  invention is not limited thereto. \n[Chem. 60-1] \na group where the substituent above is substituted with a  functional group such as a hydroxyl group, a cyano  group, an amino group, a pyrrolidino group, a piperidino  group, a morpholino group, and an oxo group. \n(D-1) \n(D-2) \n(D-3) \n(D-4) \n(D-5) \n(D-6) \n(D-7) \n(D-8) \n(D-9) \n(D-10) \n(D-11) \n(D-12) \n(D-13) \n(D-14) "}]}
+{"image": "doclay/doclay_35596.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Fluctuations and correlations during the shear flow of elastic particles near the jamming transition\nClaus Heussinger, Pinaki Chaudhuri and Jean-Louis Barrat ∗\nNovember 1, 2018\nAbstract\nWe present a numerical study of the flow of an as- sembly of frictionless, soft discs at zero tempera- ture, in the vicinity of and slightly above the jam- ming density. We find that some of the flow prop- erties, such as the fluctuations in the number of contacts or the shear modulus, display a critical like behaviour that is governed by the proximity to the jamming point. Dynamical correlations dur- ing a quasistatic deformation, however, are non critical and dominated by system size. At finite strain rates, these dynamical correlations acquire a finite, strain-rate dependent amplitude, that de- creases when approaching the jamming point from above.\nManuscript submitted to the themed Issue on granular and jammed materials of Soft Matter\nas changing the inclination angle of the support) can lead to large scale structural rearrangements (“avalanches”) or even to the complete fluidization of the material. A few years ago, Liu and Nagel 1 have suggested a “phase-diagram” for this type of solid-liquid transition (“jamming”). At zero tem- perature the axes relate to the ways an unjamming transition can be triggered, either by increasing the external driving (e.g. shear stress) or by decreasing the density of the material. The present study will probe the vicinity of this ”unjamming line” using quasistatic and finite strain rate simulations of a model granular system.\nIf one applies a shear stress, which is small and below a certain threshold (“yield-stress”), the ma- terial will respond as an elastic solid. Increasing the stress above the yield-stress, the particles will un- jam and start to flow. This flow behavior is called “plastic flow” as the material will not revert to its original shape when the stress is removed.\nIn the following we will assume that the sys- tem can flow at arbitrary small strain-rates without showing flow-localization. That this is possible is by no means guaranteed, as in some instances co- existence of flowing and jammed states is observed . 2 We have not observed such a persistent strain localization in the simulations that are presented here.\nPlastic flow is observed in a large number of glassy materials, that are a priori very different from the athermal granular systems close to point J (see below) studied in this paper. However, all ma- terials display a rather universal behavior, that was illustrated already in early studies on the plastic- flow of metallic glasses. 3,4 These studies have given indications that in the flowing phase the main plas- tic activity is spatially localized to so called shear transformation zones. 5,6 These zones are non per-\n1\nThe properties of granular materials, in particu- lar sand, are a constant source of fascination for children and adults alike, and are intrinsically re- lated to the ability of such systems to exist in either solid or fluid states, under very similar conditions. For the scientist this fascination may arise through the apparent contradiction between the rigidity of the individual grains and the fragility of the as- sembly as a whole. This means that, for exam- ple, small changes in the loading conditions (such\n1 Introduction and back- ground\narXiv:1001.0658v2 [cond-mat.mtrl-sci] 23 Jun 2010\n∗ Universit´e Lyon 1, Laboratoire de Physique de la Mati`ere Condens´ee et Nanostructures, CNRS, UMR 5586 Domaine Scientifique de la Doua F-69622 Villeurbanne Cedex, France"}]}
+{"image": "doclay/doclay_21857.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "113 ANNUAL REPORT 2010\nThe table below shows an analysis of financial instruments  recorded at fair value by level of the fair value hierarchy:\nAdditional information is provided in the section headed ‘Effect  of changes in significant unobservable assumptions to  reasonably possible alternatives’ below.\nFinancial assets carried at fair value Level I Level II Level III Total 2010 Available-for-sale investments Shares 680 63 555 1,298 Debt securities 18,148 73,000 3,788 94,936 Money market and other short-term instruments – 10,141 – 10,141 Other investments at fair value 60 10 805 875 18,888 83,214 5,148 107,250 Fair value through profi t or loss Shares 813 264 1 1,078 Debt securities 46   1,611   132  1,789  Money market and other short-term instruments 289   370   –  659  Other investments at fair value –   581   1,205  1,786  Investments for account of policyholders  1 81,442  61,309   2,352  145,103  Derivatives  24   6,049   178  6,251  82,614   70,184   3,868  156,666  TOTAL FINANCIAL ASSETS AT FAIR VALUE 101,502   153,398   9,016  263,916  Financial liabilities carried at fair value Investment contracts –  –   1,656  1,656  Investment contracts for account of policyholders 5,020  20,405   178  25,603  Borrowings  2 520   467   –  987  Derivatives  10   4,911   1,050  5,971  5,550   25,783   2,884   34,217 \n1  The investments for account of policyholders included in the table above represents those investments carried at fair value through profit or loss. \n2  Borrowings included in the table above contain those borrowings that are carried at fair value through profit or loss. Total borrowings on the balance  sheet also contain borrowings carried at amortized cost that are not included in the above schedule. \nSHARPENING OUR FOCUS\n"}]}
+{"image": "doclay/doclay_76975.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "18 of 18 \nLot 1- Construction of Giresun Wastewater Treatment Plant VOLUME 2 - Section 3: Particular Conditions \nUnion or national law requires a longer storage of personal data. \nIf part or all of the processing of personal data is subcontracted to a third party, the  contractor shall pass on the obligations referred to in the present article in writing to  those parties, including subcontractors. At the request of the contracting authority,  the contractor shall provide a document providing evidence of this commitment. \n3_Vol2_d4_particularconditions_en_.docx "}]}
+{"image": "doclay/doclay_78803.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "CHAPTER 76. PERLHACK\n76.1. DESCRIPTION\nHowever, it’s impossible to perform the operations in this order: you have to find the values of $b and $c before you add them together, for instance. So, the other thread that runs through the op tree is the execution order: each op has a field op_next which points to the next op to be run, so following these pointers tells us how perl executes the code. We can traverse the tree in this order using the exec option to B::Terse :\nThis probably makes more sense for a human: enter a block, start a statement. Get the values of $b and $c , and add them together. Find $a , and assign one to the other. Then leave.\nThe way Perl builds up these op trees in the parsing process can be unravelled by examining perly.y , the YACC grammar. Let’s take the piece we need to construct the tree for $a = $b + $c\nThe grammar gives you the following rule: you can make the thing on the left of the colon if you see all the things on the right in sequence. This is called a \"reduction\", and the aim of parsing is to completely reduce the input. There are several di ff erent ways you can perform a reduction, separated by vertical bars: so, term followed by = followed by term makes a term , and term followed by + followed by term can also make a term .\nSo, if you see two terms with an = or + , between them, you can turn them into a single expression. When you do this, you execute the code in the block on the next line: if you see = , you’ll do the code in line 2. If you see + , you’ll do the code in line 4. It’s this code which contributes to the op tree.\n| term ADDOP term { $$ = newBINOP($2, 0, scalar($1), scalar($3)); }\nWhat this does is creates a new binary op, and feeds it a number of variables. The variables refer to the tokens: $1 is the first token in the input, $2 the second, and so on - think regular expression backreferences. $$ is the op returned from this reduction. So, we call newBINOP to create a new binary operator. The first parameter to newBINOP , a function in op.c , is the op type. It’s an addition operator, so we want the type to be ADDOP . We could specify this directly, but it’s right there as the second token in the input, so we use $2 . The second parameter is the op’s flags: 0 means ‘nothing special’. Then the things to add: the left and right hand side of our expression, in scalar context.\n1229\n1 term : term ASSIGNOP term 2 { $$ = newASSIGNOP(OPf_STACKED, $1, $2, $3); } 3 | term ADDOP term 4 { $$ = newBINOP($2, 0, scalar($1), scalar($3)); }\n% perl -MO=Terse,exec -e ’$a=$b+$c’ 1 OP (0x8179928) enter 2 COP (0x81798c8) nextstate 3 SVOP (0x81796c8) gvsv GV (0x80fa4d4) *b 4 SVOP (0x8179798) gvsv GV (0x80efeb0) *c 5 BINOP (0x8179878) add [1] 6 SVOP (0x816dd38) gvsv GV (0x80fa468) *a 7 BINOP (0x81798a0) sassign 8 LISTOP (0x8179900) leave\nProgram | Statement | = / \\ / \\ $a + / \\ $b $c\nIf you’re not used to reading BNF grammars, this is how it works: You’re fed certain things by the tokeniser, which generally end up in upper case. Here, ADDOP , is provided when the tokeniser sees + in your code. ASSIGNOP is provided when = is used for assigning. These are ‘terminal symbols’, because you can’t get any simpler than them.\nThe grammar, lines one and three of the snippet above, tells you how to build up more complex forms. These complex forms, ‘non-terminal symbols’ are generally placed in lower case. term here is a non-terminal symbol, representing a single expression."}]}
+{"image": "doclay/doclay_54567.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Server Status Variables\nThe number of events discarded from the Performance Schema  error_log  table to make room for new events.\nThe number of events currently present in the Performance Schema  error_log  table. As with Error_log_buffered_bytes , it is possible for the value to decrease.\nThis variable was added in MySQL 8.0.22.\nThis variable was added in MySQL 8.0.22.\n• Error_log_buffered_events\n• Error_log_expired_events\n• Error_log_latest_write\n• Flush_commands\n• group_replication_primary_member\nThe number of times the server flushes tables, whether because a user executed a  FLUSH TABLES statement or due to internal server operation. It is also incremented by receipt of a  COM_REFRESH packet. This is in contrast to  Com_flush , which indicates how many  FLUSH  statements have been executed, whether  FLUSH TABLES ,  FLUSH LOGS , and so forth.\nThis variable was added in MySQL 8.0.22.\nThe time of the last write to the Performance Schema  error_log  table.\nThis variable was added in MySQL 8.0.22.\nShows the primary member’s UUID when the group is operating in single-primary mode. If the group is operating in multi-primary mode, shows an empty string.\nThe  group_replication_primary_member  status variable is deprecated and is scheduled to be removed in a future version.\nThe number of internal  COMMIT  statements.\nThe number of times that rows have been deleted from tables.\nThe server increments this variable for each call to its  external_lock()  function, which generally occurs at the beginning and end of access to a table instance. There might be differences among storage engines. This variable can be used, for example, to discover for a statement that accesses a partitioned table how many partitions were pruned before locking occurred: Check how much the counter increased for the statement, subtract 2 (2 calls for the table itself), then divide by 2 to get the number of partitions locked.\nThe number of times the server uses a storage engine’s own Multi-Range Read implementation for table access.\n• Handler_mrr_init\n• Handler_external_lock\n• Handler_delete\n• Handler_commit\n954"}]}
+{"image": "doclay/doclay_58746.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "# Signals need to be contained in a QObject or subclass in order to be correctly # initialized. # classSignaller (QtCore.QObject): signal=Signal( str, logging .LogRecord) # # Output to a Qt GUI is only supposed to happen on the main thread. So, this # handler is designed to take a slot function which is set up to run in the main # thread. In this example, the function takes a string argument which is a # formatted log message, and the log record which generated it. The formatted # string is just a convenience - you could format a string for output any way # you like in the slot function itself. # # You specify the slot function to do whatever GUI updates you want. The handler # doesn't know or care about specific UI elements. # classQtHandler (logging .Handler): def __init__ (self, slotfunc, *args,**kwargs): super() .__init__ (*args,**kwargs) self.signaller=Signaller() self.signaller.signal.connect(slotfunc) def emit(self, record): s =self.format(record) self.signaller.signal.emit(s, record) # # This example uses QThreads, which means that the threads at the Python level # are named something like \"Dummy-1\". The function below gets the Qt name of the # current thread. # def ctname(): return QtCore.QThread .currentThread() .objectName() # # Used to generate random levels for logging. # LEVELS =(logging .DEBUG, logging .INFO, logging.WARNING, logging .ERROR, logging.CRITICAL) # # This worker class represents work that is done in a thread separate to the # main thread. The way the thread is kicked off to do work is via a button press # that connects to a slot in the worker. # # Because the default threadName value in the LogRecord isn't much use, we add # a qThreadName which contains the QThread name as computed above, and pass that # value in an \"extra\" dictionary which is used to update the LogRecord with the # QThread name. # # This example worker just outputs messages sequentially, interspersed with # random delays of the order of a few seconds. # classWorker (QtCore.QObject): @Slot () def start(self): extra ={ 'qThreadName ': ctname() } logger.debug( 'Started work', extra =extra) i =1\n(continued from previous page)\n(continues on next page)\n44"}]}
+{"image": "doclay/doclay_62172.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "US 9,612,535 B2 \n130 \n129 \n-continued \n-continued  0  F  O=~~  I  F  0N  \\  F  O=S  II  F  O  F \n-continued  CH3  I  ~C:x  ~CH¢c;H~  ¢  ~  102  S02  S02  ~I  OCH3  ~CH9  0  I  :$s:  F  F  F  F  O=S=O  I  0  I  O\"’ \n-continued "}]}
+{"image": "doclay/doclay_1147.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\nSMFG\nfrom these operating sections, reviews their assessment. The  reserves are provided for based on the results of these  assessments.\nThe reserve for possible loan losses of other consolidated  subsidiaries for general claims is provided for in the amount  deemed necessary based on the historical loan-loss ratios, and  for doubtful claims in the amount deemed uncollectible based  on assessment of each claim.\nFor collateralized or guaranteed claims on bankrupt borrow- ers and effectively bankrupt borrowers, the amount exceeding  the estimated value of collateral and guarantees is deemed to  be uncollectible and written off against the total outstanding  amount of the claims. The amount of write-off was ¥867,866  million ($10,437 million) and ¥843,781 million at March 31,  2011 and 2010, respectively.\nUnrecognized prior service cost is amortized using the  straight-line method, primarily over 9 years, over the employ- ees’ estimated average remaining service period from the fiscal  year of its incurrence.\nUnrecognized net actuarial gain or loss is amortized using  the straight-line method, primarily over 9 years, over the  employees’ average remaining service period, commencing  from the next fiscal year of incurrence.\n“Partial Amendments to Accounting Standard for  Retirement Benefits (Part 3)” (Accounting Standard Board of  Japan (“ASBJ”) Statement No. 19, issued on July 31, 2008)  became effective from the fiscal year beginning on and after  April 1, 2009. Accordingly, SMFG has applied them from the  fiscal year ended March 31, 2010. This accounting method  has no impact on the consolidated financial statements for the  fiscal year ended March 31, 2010.\nSMFG  2011\n80\nAs for the portfolio hedges to offset market fluctuation,  SMBC assesses the effectiveness of such hedges by clas- sifying the hedged items (such as deposits and loans) and  the hedging instruments (such as interest rate swaps) by  their maturity. As for the portfolio hedges to fix cash flows,  SMBC assesses the effectiveness of such hedges by verifying  the correlation between the hedged items and the hedging  instruments. \nSMBC applies deferred hedge accounting stipulated in  “Treatment for Accounting and Auditing of Application  of Accounting Standard for Financial Instruments in  Banking Industry” (Japanese Institute of Certified Public  Accountants (“JICPA”) Industry Audit Committee Report  No. 24) to portfolio hedges on groups of large-volume,  small-value monetary claims and debts. \n(7) Reserve for employee bonuses The reserve for employee bonuses is provided for payment of  bonuses to employees, in the amount of estimated bonuses,  which are attributable to the respective fiscal year.\n(8) Reserve for executive bonuses The reserve for executive bonuses is provided for payment of  bonuses to executives, in the amount of estimated bonuses,  which are attributable to the respective fiscal year.\n(9) Reserve for employee retirement benefits The reserve for employee retirement benefits is provided for  payment of retirement benefits to employees, in the amount  deemed accrued at the fiscal year-end, based on the projected  retirement benefit obligation and the fair value of plan assets  at the fiscal year-end.\n(12) Reserve for reimbursement of deposits The reserve for reimbursement of deposits which were  derecognized as liabilities under certain conditions is provided  for the possible losses on the future claims of withdrawal based  on the historical reimbursements.\n(13) Reserve for loss on interest repayment The reserve for loss on interest repayment is provided for the  possible losses on future claims of repayment of interest based  on historical interest repayment experience.\n(14) Reserve under the special laws The reserve under the special laws is a reserve for eventual  future operating losses from financial instruments transactions  pursuant to Article 46-5 of the Financial Instruments and  Exchange Act.\n(15) Translation of foreign currency assets and liabilities Assets and liabilities of SMFG and SMBC denominated in  foreign currencies and accounts of SMBC overseas branches are  translated into Japanese yen mainly at the exchange rates  prevailing at the consolidated balance sheet date, with the  exception of stocks of subsidiaries and affiliates translated at  rates prevailing at the time of acquisition.\n(16) Lease transactions\n(a) Recognition of income on finance leases Interest income is allocated to each period, based on the  interest method.\n(b) Recognition of income on operating leases Primarily, lease-related income is recognized on a  straight-line basis over the term of the lease, based on the  contractual amount of lease fees per month.\n(c) Recognition of income and expenses on installment sales Primarily, installment-sales-related income and installment- sales-related expenses are recognized on a due-date accrual  basis over the period of the installment sales.\n(17) Hedge accounting\n(a) Hedging against interest rate changes  As for the hedge accounting method applied to hedging  transactions for interest rate risk arising from financial  assets and liabilities, SMBC applies deferred hedge  accounting.\n(10) Reserve for executive retirement benefits The reserve for executive retirement benefits is provided for  payment of retirement benefits to directors, corporate auditors  and other executive officers, in the amount deemed accrued at  the fiscal year-end based on the internal regulations. \n(11) Reserve for point service program The reserve for point service program is provided for the  potential future redemption of points awarded to customers  under the “SMBC Point Pack,” credit card points programs,  and other customer points award programs. The amount  is calculated by converting the outstanding points into a  monetary amount, and rationally estimating and recognizing  the amount that will be redeemed in the future.\nOther consolidated subsidiaries’ assets and liabilities  denominated in foreign currencies are translated into Japanese  yen at the exchange rates prevailing at their respective balance  sheet dates."}]}
+{"image": "doclay/doclay_17477.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS — (Continued)\ncommunications and consumer products and electronic component distributors. Ongoing credit evaluations of customers’ financial condition are performed and collateral, such as letters of credit and bank guarantees, are required whenever deemed necessary.\nIn both fiscal years 2011 and 2010 the Company had three customers, each with greater than ten percent of net revenue; Foxconn, Nokia and Samsung Electronics. In fiscal years 2009 the Company’s greater than ten percent customers were Asian Information Technology, Samsung Electronics and Sony Ericsson Mobile Communications.\nThe Company’s greater than ten percent customers comprised the following percentages of net revenue:\nAt September 30, 2011, the Company’s three largest accounts receivable balances comprised 53% of aggregate gross accounts receivable. This concentration was 60% and 34% at October 1, 2010 and October 2, 2009, respectively.\n* Customer did not represent greater than ten percent of net revenue\n(1) Earnings per share calculations for each of the quarters are based on the weighted average number of shares outstanding and included common stock equivalents in each period. Therefore, the sums of the quarters do not necessarily equal the full year earnings per share.\nPage 121\nSkyworks / Annual Report 2011\n19. QUARTERLY FINANCIAL DATA (UNAUDITED)\nFiscal Years Ended September 30, 2011 October 1, 2010 October 2, 2009 Company A ........................................ 27% 13% * Company B ........................................ 13% 12% * Company C ........................................ 11% 13% 15% Company D ........................................ * * 12% Company E ........................................ * * 11%\nFirst Quarter Second Quarter Third Quarter Fourth Quarter Fiscal Year (In thousands, except per share data) Fiscal 2011 Net revenue ................. $335,120 $325,411 $356,075 $402,316 $1,418,922 Gross profit ................. 148,538 140,981 156,225 174,560 620,304 Net income ................. 60,868 49,960 51,548 64,209 226,585 Per share data(1) ............. Net income, basic .......... $ 0.34 $ 0.27 $ 0.28 $ 0.35 $ 1.24 Net income, diluted ......... $ 0.32 $ 0.26 $ 0.27 $ 0.34 $ 1.19 Fiscal 2010 Net revenue ................. $245,138 $238,058 $275,370 $313,283 $1,071,849 Gross profit ................. 102,554 99,854 118,266 136,159 456,833 Net income ................. 28,010 27,744 34,736 46,804 137,294 Per share data(1) ............. Net income, basic .......... $ 0.16 $ 0.16 $ 0.20 $ 0.26 $ 0.78 Net income, diluted ......... $ 0.16 $ 0.15 $ 0.19 $ 0.25 $ 0.75"}]}
+{"image": "doclay/doclay_20099.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS — (Continued)\nSHORT-TERM DEBT\n10. INCOME TAXES\nPage 106 Skyworks / Annual Report 2011\nThe remaining unamortized discount on the 1.50% Notes will be amortized over the next six months. The number of shares underlying the remaining 1.50% Notes was approximately 2.8 million for both fiscal years ended September 30, 2011 and October 2, 2010, respectively.\nAs of September 30, 2011, the $26.1 million carrying value of the 1.50% Notes was classified as short-term debt.\nThe Company’s short-term debt balance as of October 1, 2010 consisted of a $50.0 million credit facility, which the Company repaid and terminated during the first quarter of fiscal 2011.\nIncome before income taxes consists of the following components (in thousands):\nThe provision (benefit) for income taxes consists of the following (in thousands):\nFiscal Years Ended September 30, 2011 October 1, 2010 October 2, 2009 United States ....................................... $208,926 $164,094 $65,603 Foreign ........................................... 84,960 30,980 4,153 $293,886 $195,074 $69,756\nFiscal Years Ended September 30, 2011 October 1, 2010 October 2, 2009 Current tax expense (benefit): Federal ............................................ $25,421 $11,855 $ (251) State .............................................. 422 946 (413) Foreign ........................................... 4,340 684 966 30,183 13,485 302 Deferred tax expense (benefit): Federal ............................................ 35,053 44,072 — State .............................................. (1,048) (2,846) — Foreign ........................................... 961 235 (93) 34,966 41,461 (93) Change in valuation allowance ......................... 2,152 2,834 (25,436) Provision (benefit) for income taxes ..................... $67,301 $57,780 $(25,227)"}]}
+{"image": "doclay/doclay_28089.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "\nFIG. 1: Paleoclimatic data showing ice ages and interglacials $^{2–5}$.\nIV. LIMIT STATES\nThis sensitivity of opacity to water vapor pressure, combined with the sensitivity of equilibrium vapor pressures to temperature, qualitatively suggests a bistable system: There may be a cold state in which the water precipitates and the atmosphere is transparent, with little water vapor absorption, and a warm state in which the atmosphere is warm, humid and opaque and in which absorbed solar energy is carried through the troposphere by convection (resembling present tropical or temperate summer conditions).\nThese limit states are stable: in the cold state perturbations to the temperature have little effect on the infrared opacity because it remains very low, while in the warm state the opacity has little effect on the heat transfer. In either case there is little feedback to the heat balance from changes in the tropospheric water vapor content. At intermediate temperatures increases in temperature produce a positive feedback by increasing the infrared opacity (and vice versa for decreases), so that perturbations grow exponentially until one of the stable limit states is approached.\n3"}]}
+{"image": "doclay/doclay_23964.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "NOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS\nReconciliation of Financial Position December 31, 2012\n62 AKITA DRILLING LTD.  ANNUAL REPORT\n(1) IFRS 11 “Joint Arrangements”\n(2) IAS 19 (Revised 2011) “Employee Benefits”\nReconciliation of Financial Position December 31, 2012 Adjustments for changes in accounting policies $Thousands  Before  Accounting  Policy  Changes IFRS 11  (1) IAS 19  (2) After  Accounting  Policy  Changes Assets Current Assets Cash and cash equivalents  $ 13,285   $ (2,282)  $ -   $ 11,003  Accounts receivable  66,116   (6,112) -   60,004  Income taxes recoverable  4,487  -  -   4,487  Prepaid expenses and other  216   (57) -   159   84,104   (8,451) -   75,653  Non-current Assets Restricted cash  3,000  -  -   3,000  Other long term assets  921  -  -   921  Investments in joint ventures -   4,825  -   4,825  Property, plant and equipment  204,969  -  -   204,969  Total Assets  $292,994   $ (3,626)  $ -   $ 289,368  Liabilities Current Liabilities Accounts payable and accrued liabilities  $ 44,669   $ (1,580)  $ -   $ 43,089  Deferred revenue  2,141   (2,046) -   95  Dividends payable  1,255  -  -   1,255   48,065   (3,626) -   44,439  Non-current Liabilities Deferred income taxes  18,989  -   (103)  18,886  Pension liability  1,942  -   406   2,348  Total Liabilities  68,996   (3,626)  303   65,673  Shareholders’ Equity Class A and Class B shares  23,186  -  -   23,186  Contributed surplus  3,060  -  -   3,060  Accumulated other comprehensive income -  -   (21)  (21) Retained earnings  197,752  -   (282)  197,470  Total Equity  223,998  -   (303)  223,695  Total Equity and Liabilities  $292,994   $ (3,626)  $ -   $ 289,368 "}]}
+{"image": "doclay/doclay_17182.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "due to the reclassification of treasury shares. Initial application  has not affected basic and diluted earnings per share in these  periods. \nThe amount of the adjustment for each line item affected in the  Consolidated statement of cash flows is as follows: \nConsolidated statement of cash flows (extract) \naccordance with the transitional provisions, AASB 2012-2 has  been applied retrospectively. The application of AASB 2012 in  the current financial year has not had a material impact on the  financial position nor performance of the Consolidated Entity,  however has resulted in additional disclosures of certain netting  arrangements as provided in note 40. \nAASB 2011-9  Amendments to Australian Accounting Standards  – Presentation of Items of Other Comprehensive Income\nAASB 2011-9  requires items included in other comprehensive  income (OCI) in the Statement of comprehensive income  (including prior period comparatives) to be grouped according  to whether they may be reclassified subsequently to profit or  loss. For the year ended 31 March 2014, all items have been  presented as “Items that may be reclassified subsequently to  profit or loss”. \nAASB 2012-3  Amendments to Australian Accounting Standards  – Offsetting Financial Assets and Financial Liabilities\nAASB 2012-3 amends AASB 132  Financial Instruments:  Presentation  to clarify that to set off an asset with a liability: \nInitial application of AASB 11, AASB 127 (Dec 2012) and AASB  128 (Dec 2012) has not resulted in any material impact in the  current or prior financial year. \nAASB 12  sets out disclosures for interests in entities that are  subsidiaries, associates, joint ventures and unconsolidated  structured entities. The application of AASB 12 in the current  financial year has not affected any of the amounts recognised in  the financial statements, however has resulted in additional  disclosures of structured entities as provided in note 36. AASB  2012-10 provides relief from disclosing comparatives for  interests in unconsolidated structured entities when AASB 12 is  applied for the first time. \nAASB 2012-3 is effective for annual reporting periods beginning  on or after 1 January 2014. The Consolidated Entity will first  apply AASB 2012-3 in the financial year beginning 1 April 2014.  The Consolidated Entity is continuing to assess the impact of  AASB 2012-3. \nAASB 2011-4  Amendments to Australian Accounting Standards  to Remove Individual Key Management Personnel Disclosure  Requirements \nAASB 2011-4 removes the individual Key Management  Personnel disclosure requirements from AASB 124  Related  Party Disclosures,  and is effective for annual reporting periods  beginning on or after 1 July 2013. The Consolidated Entity will  first apply the amendments in the financial year beginning 1  April 2014. Whilst the amendments may reduce the disclosures  provided, it will not affect any of the amounts recognised in the  financial statements. \nAASB 9  Financial Instruments  and consequential amendments\nAASB 2012-2  requires additional disclosures of enforceable  master netting arrangements and their effect, even if assets and  liabilities are not offset on the statement of financial position. In \nAASB 13  became effective in the current financial year. AASB  13 explains how to measure fair value and aims to enhance fair  value disclosures. In accordance with the transitional provisions,  AASB 13 has been applied prospectively from 1 April 2013. The  application of AASB 13 in the current financial year has not had  a material impact on the financial position nor performance of  the Consolidated Entity, however has resulted in additional fair  value disclosures as provided in note 39. \n– the right of set-off must be available and legally enforceable  for all counterparties in the normal course of business, as  well as in the event of default, insolvency or bankruptcy  – certain gross settlement mechanisms (such as through a \nwell as in the event of default, insolvency or bankruptcy  – certain gross settlement mechanisms (such as through a  clearing house) may be equivalent to net settlement  – master netting arrangements where the legal right of offset \nclearing house) may be equivalent to net settlement  – master netting arrangements where the legal right of offset  is only enforceable on the occurrence of a future event  (such as default of the counterparty) continue to not meet  the requirements for netting. \nAASB 2012-2  Amendments to Australian Accounting Standards  – Disclosures – Offsetting Financial Assets and Financial  Liabilities\nAASB 13  Fair value measurement\nNew Accounting Standards and amendments to Accounting  Standards that are not yet effective \n103 \nConsolidated  2013  $m  Amount of  adjustment  Cash flows from operating activities:  Life investment contract premiums received,  disposal of investment assets and other  unitholder contributions  (7,139)  Life investment contract payments, payments  for investment assets and other unitholder  maturities  7,139  Net cash flows used in operating activities  - "}]}
+{"image": "doclay/doclay_48858.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\nlfd. Nr. Land Straße Straße Projektbezeichnung Bauziel Dringlichkeit  949 NW A 553 AK Köln-Godorf (A 555) AD Köln-Lind (A 59) N 4 Vordringlicher Bedarf NW A 553 A 555 AK Köln-Godorf (A 555) KN NW A 553 AK Köln-Godorf AD Köln-Lind N 4 NW A 553 A 059 AD Köln-Lind (A 59) KN  950 NW A 559 AD Köln-Porz (A 59) AK Köln-Gremberg (A 4) E 6 Vordringlicher Bedarf – Engpassbeseitigung  951 NW A 560 AD Sankt Augustin/West (A 59) AS Sankt Augustin E 6 Weiterer Bedarf mit Planungsrecht  952 NW A 565 AS Bonn/Hardtberg AK Bonn/Nord (A 555) E 6 Vordringlicher Bedarf NW A 565 AS Bonn/Hardtberg AS Bonn-Poppelsdorf E 6 NW A 565 AS Bonn/Poppelsdorf AK Bonn/N E 6 NW A 565 A 555 AK Bonn/N (A 555) KN  953 NW A 565 AK Bonn-N AD Bonn-NO E 6 Weiterer Bedarf mit Planungsrecht NW A 565 AK Bonn-N AS Bonn-Beuel E 6 NW A 565 AS Bonn-Beuel AD Bonn-NO E 6  954 NW B 001 B 066 Horn/Bad Meinberg Barntrup N 2/3 Vordringlicher Bedarf NW B 001 OU Blomberg/ Herrentrup N 2 NW B 001 OU Blomberg/Istrup N 3\n- Seite 69 von 100 -"}]}
+{"image": "doclay/doclay_11845.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "TheJ.M.Smucker Company Year Ended April 30, (Dollars in thousands, except per share data) 2003 2002 Net sales  $1,311,744 $687,148 Net income and net income per common share: Net income  $ 96,342  $ 30,851 Net income per common share – assuming dilution  $ 2.02  $ 1.31 Income and income per common share before restructuring and merger and integration costs: (1)  Income  $ 104,432 $ 34,011 Income per common share – assuming dilution  $ 2.19  $ 1.45 Common shares outstanding at year end  49,767,540  23,504,129 Number of employees  2,775 2,300  (1) Reconciliation to net income: Income before income taxes  $ 155,390  $ 50,198 Merger and integration costs  10,511  5,031 Cost of products sold – restructuring  1,256  — Other restructuring costs  1,281  — Income before income taxes, restructuring,  and merger and integration costs 168,438  55,229 Income taxes  64,006  21,218 Income before restructuring and merger and integration costs  $ 104,432  $ 34,011\nTheJ.M.Smucker Company\nFinancial Highlights\n■■■ Contents\n■■■ On Our Cover\n“Making Jam” ©Ann Baker\nThe painting featured on this year’s annual report cover depicts American values of home, family, and handmade, quality products. The painting was in the personal  collection of Paul H. and Lorraine E. Smucker.\nCalifornia artist Ann Baker, known as “Mrs. B”, is  highly regarded for her primitive-style scenes of  19th-century American life. Her whimsical bumblebee  “signature” appears on all of her compositions.\nLetter to Shareholders 1 Five-Year Summary of Selected Financial Data 10 Summary of Quarterly Results of Operations 11 Stock Price Data 11 Management’s Discussion and Analysis 12 Management’s Report on Responsibility for  Financial Reporting  18 Report of Independent Auditors 18 Consolidated Financial Statements 19 Notes to Consolidated Financial Statements 24 Directors, Officers, and General Managers 40 Properties 40 Shareholder Information 41\n"}]}
+{"image": "doclay/doclay_35186.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "12\n(2008).\n(2008). 31 A. R. Champagne, A. D. K. Finck, J. P. Eisenstein, L. N. Pfeiffer, and K. W. West, Phys. Rev. B 78 , 205310 (2008). 32\nPfeiffer, and K. W. West, Phys. Rev. B , 205310 (2008). 32 L. Tiemann, Y. Yoon, W. Dietsche, K. von Klitzing, and W. Wegscheider, Phys. Rev. B 80 , 165120 (2009). 33\nW. Wegscheider, Phys. Rev. B 80 , 165120 (2009). 33 I. B. Spielman, Ph.D. Thesis, California Institute of Tech- nology (2004). 34\nnology (2004). 34 A. Stern and B. I. Halperin, Phys. Rev. Lett. 88 , 106801 (2002). 35\n(2002). 35 M. Abolfath, A. H. MacDonald, and L. Radzihovsky, Phys. Rev. B 68 , 155318 (2003). 36\nRev. B 68 , 155318 (2003). 36 D. Pesin and A. H. MacDonald, in preparation.\n37 S. Q. Murphy, J. P. Eisenstein, G. S. Boebinger, L. N. Pfeiffer, and K. W. West, Phys. Rev. Lett. 72 , 728 (1994). 38\nPfeiffer, and K. W. West, Phys. Rev. Lett. , 728 (1994). 38 D. Yoshioka and A. H. MacDonald, Phys. Rev. B 53 , R16168 (1996). 39\nR16168 (1996). 39 J. P. Eisenstein and A. H. MacDonald, unpublished. 40\nJ. P. Eisenstein and A. H. MacDonald, unpublished. 40 P. R. Eastham, N. R. Cooper and D. K. K. Lee, Phys. Rev. B 80 , 045302 (2009). 41\nB 80 , 045302 (2009). 41 H. A. Fertig and G. Murthy, Phys. Rev. Lett. 95 , 156802 (2005). 42\n(2005). 42 B. Roostaei, K. J. Mullen, H. A. Fertig, and S. H. Simon, Phys. Rev. Lett. 101 , 046804 (2008)."}]}
+{"image": "doclay/doclay_35278.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Possible indication to the QCD evolution of double parton distributions?\nA.M. Snigirev\nM.V. Lomonosov Moscow State University, D.V. Skobeltsyn Institute of Nuclear Physics, 119991, Moscow, Russia\n(Dated: October 25, 2018)\nFor the first time the process-independent parameter of double parton scattering, σ exp eff , has been measured newly in the D0 experiment at the three different resolution scales. If we interpret the measurement as a decrease of the effective cross section with a growth of the resolution scale it can indicate the QCD evolution of double parton distributions.\nPACS numbers: 12.38.-t\nThe presence of multiple parton interactions in high energy hadron collisions has been convincingly demon- strated by the AFS [1], UA2 [2] and CDF [3] Collab- orations using events with the four-jet final state and later by the CDF Collaboration [4] using events with the γ + 3 jets final state. Recently the D0 Collaboration has measured the process-independent parameter of double parton scattering, σ exp eff , using the γ + 3 jets events at the three different resolution (energy) scales [5] provid- ing new and complementary information on the proton structure. The possibility of observing two separate hard collisions has been proposed since long [6], and from that has also developed in a number of works [7, 8, 10–13]. A brief review of the current situation and some progress in the modeling with account of correlated flavor, color, longitudinal and transverse momentum distributions can be found in Ref. [10].\nIn order to introduce the denotations and to be clear let us recall that, for instance, the inclusive differential cross section for the four-jet production due to the si- multaneous interaction of two parton pairs within one p ¯ p collision, σ$_{dp}$ , can be given by [7]\nwhere σ$_{ij}$ stands for the two-jet production cross section. The dimensional phenomenological parameter σ$_{eff}$ in the denominator is a factor characterizing a size of the ef- fective interaction region of the hadron (the factor 2 is introduced due to the identity of the two parton subpro- cesses). The relatively small value of ( σ$_{eff}$ )$_{CDF}$ measured by the CDF Collaboration [4] with respect to the naive expectation was, in fact, considered [8, 9] as evidence of nontrivial correlation effects between partons in the transverse space. But, apart from these correlations, the longitudinal momentum correlations can also exist and they were investigated in Ref. [14]. The factorization ansatz is just applied to the two-parton distributions en- tering Eq. (1):\nMultiple interactions require an ansatz for the struc- ture of the interacting hadrons, i.e. correlations between the constituent partons. As a simple ansatz, usually, the two-parton distributions (of the parton momentum frac- tion) are supposed to be the product of two single-parton distributions times a momentum conserving phase space factor. In recent papers [14] it has been shown that this hypothesis is in some contradiction with the leading loga- rithm approximation of perturbative QCD (in the frame- work of which a parton model, as a matter of fact, was es- tablished in the quantum field theories [15]). Namely, the two-parton distribution functions being the product of two single distributions at some reference resolution scale become dynamically correlated at any different scale of a hard process.\nwhere D$_{p}$ ( x$_{i}$, Q $^{2}$) are the single quark/gluon momentum distributions at the scale Q 2 (determined by a hard pro- cess).\nHowever multi-parton distribution functions sat- isfy the generalized Gribov-Lipatov-Altarelli-Parisi- Dokshitzer (GLAPD) evolution equations derived for the first time in Refs [16, 17] as well as single parton dis- tributions satisfy more known and cited GLAPD equa- tions [15, 18]. Under certain initial conditions these gen- eralized equations lead to the solutions, which are iden- tical with the jet calculus rules proposed originally for multiparton fragmentation functions by Konishi-Ukawa- Veneziano [19] and are in some contradiction with the factorization hypothesis (2). Here one should note that at the parton level this is a strict assertion within the leading logarithm approximation.\nThe main purpose of the present letter is to show that these QCD dynamical correlations result effectively in a dependence of the experimentally measured effective cross section σ exp eff on the resolution scale unlike naive accepted expectations.\nThe paper is organized as follows. Section II is de- voted to what is known from perturbative QCD theory on the two-parton distribution functions. The possible manifestation of correlations induced by QCD evolution is discussed in Sec. III. We summarize and conclude in Sec. IV.\nD$_{p}$ ( x$_{i}$, x$_{j}$, Q $^{2}$) = D$_{p}$ ( x$_{i}$, Q $^{2}$) D$_{p}$ ( x$_{j}$, Q $^{$^{2}$)(1}$− $^{x$_{i}$}$−x$_{j}$ ) , (2)\nσ$_{dp}$ = ∑ q/g ∫ σ$_{12}$σ$_{34}$ 2 σ$_{eff}$ D$_{p}$ ( x$_{1}$, x$_{3}$ ) D$_{¯}$ $_{p}$( x$_{2}$, x$_{4}$ ) dx$_{1}$dx$_{2}$dx$_{3}$dx$_{4}$, (1)\nII. DOUBLE PARTON DISTRIBUTIONS IN THE LEADING LOGARITHM APPROXIMATION\nI. INTRODUCTION\narXiv:1001.0104v3 [hep-ph] 5 Feb 2010"}]}
+{"image": "doclay/doclay_48096.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Article 27 \nSCHEDULE 8 \nLAND IN WHICH ONLY AIRSPACE AND NEW RIGHTS MAY BE  ACQUIRED \n(1)  Area  (2)  Plot Reference  Number(s) shown on  land plans  (3)  Height above  Ordnance Datum (m)  (4)  Purpose(s) for which  airspace and new  rights may be  acquired  The land plans – sheet 2  In the administrative  area of East Suffolk  Council  2-26, 2-28  7.805 metres  Airspace for the  construction and  operation of the new  bridge and new rights  (including restrictive  covenants) below, for  the protection and  maintenance of the  new bridge.  2-29  8.315 metres  Airspace for the  construction and  operation of the new  bridge and new rights  (including restrictive  covenants) below, for  the protection and  maintenance of the  new bridge.  2-32  8.155 metres  Airspace for the  construction and  operation of the new  bridge and new rights  (including restrictive  covenants) below, for  the protection and  maintenance of the  new bridge.  2-33  8.230 metres  Airspace for the  construction and  operation of the new  bridge and new rights  (including restrictive  covenants) below, for  the protection and  maintenance of the  new bridge.  The land plans – sheet 3  In the administrative  area of East Suffolk  Council  3-33  8.230 metres  Airspace for the  construction and  operation of the new  bridge and new rights  (including restrictive \n87"}]}
+{"image": "doclay/doclay_5052.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Management’s Discussion and Analysis of Financial Condition and Results of Operations\nA portion of our costs in India are denominated in local currency and subject to exchange fluctuations, which has an impact on our results of operations.\nAs described in Note 1 to the consolidated financial statements, on February 13, 2003 (the “Split-Off Date”), IMS Health distributed all of the Cognizant common stock that IMS Health owned in an exchange offer to IMS Health stockholders (the “Split-Off”). As a result of the Split-Off, IMS Health is no longer a related party as of the Split-Off Date. Accordingly, our revenues from IMS Health subsequent to the Split-Off Date are classified as third party revenues. We recognized related party revenues from IMS Health totaling approximately $2.6 million and $20.4 million in 2003 and 2002, respectively. Total revenues from IMS Health during 2003, including related party revenues prior to the Split-Off Date, were approximately $22.7 million.\nOur most significant costs are the salaries and related benefits for our programming staff and other professionals. Competition in India, the United States and Europe for professionals with advanced technical skills necessary to perform our services offered have caused wages to increase at a rate greater than the general rate of inflation. As with other IT service providers, we must adequately anticipate wage increases, particularly on our fixed-price contracts. There can be no assurance that we will be able to recover cost increases through increases in the prices that we charge for our services in the United States and elsewhere.\nOn December 16, 2004, the Financial Accounting Standards Board (FASB) issued SFAS No. 123 (revised 2004), “Share-Based Payment” (SFAS No. 123(R)), which is a revision of SFAS No. 123, “Accounting for Stock-Based Compensation” (SFAS No. 123). SFAS No. 123(R) supersedes APB Opinion No. 25, “Accounting for Stock Issued to Employees” (APB No. 25), and amends SFAS No. 95, “Statement of Cash Flows.” Generally, the approach in SFAS No. 123(R) is similar to the approach described in SFAS No. 123. However, SFAS No. 123(R) requires all share-based payments to employees, including grants of employee stock options and issuances under employee stock pur- chase plans, to be recognized in the income statement based on their fair values. Pro forma disclosure is no longer an alternative under the new standard.\nIn accordance with the SEC’s amendment on April 14, 2005 of the compliance dates of SFAS No. 123(R), we must adopt SFAS No. 123(R) no later than January 1, 2006. Early adoption is permitted in periods in which financial statements have not yet been issued. We expect to adopt SFAS No. 123(R) on January 1, 2006. SFAS No. 123(R) allows for two transition methods. The basic difference between the two methods is that the modified-prospective transition method does not require restatement of prior periods, whereas the modified-retro- spective transition method will require restatement.\nAs permitted by SFAS No. 123, we currently account for share-based payments to employees using APB No. 25’s intrinsic value method and, as such, generally recognize no compensation cost for employee stock options or stock issuances under the employee stock pur- chase plan. Although the full impact of our adoption of SFAS No. 123(R)’s fair value method has not yet been determined, we expect that it will have a significant impact on our results of operations. The disclosure under SFAS No. 123 of pro forma net income and earnings per share as if we had recognized compensation cost for share-based payments under SFAS No. 123 for the three years ended December 31, 2004 is not necessarily indicative of the potential impact of recognizing compensation cost for share-based payments under SFAS No. 123(R) in future periods. The potential impact of adopting SFAS No. 123(R) is dependent on levels of share-based payments granted, the specific option pricing model utilized to determine fair value and the transition methodology selected.\nForeign Currency Translation\nRelated Party Transactions\nEffects of Inflation\nRecent Accounting Pronouncements\n24 COGNIZANT ANNUAL REPORT 2004"}]}
+{"image": "doclay/doclay_40534.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Contract number: [ complete ] \n 2019 \nII.23.2  Interest on late payment \nII.23.3  Recovery rules in the case of joint tender \nII.24. CHECKS AND AUDITS \nIf no observations have been submitted or if, despite the observations submitted, the contracting  authority decides to pursue the recovery procedure, it must confirm recovery by  formally  notifying  a debit note to the contractor, specifying the date of payment. The contractor must pay  in accordance with the provisions specified in the debit note. \nIf the contractor does not pay by the due date, the contracting authority may, after informing  the contractor in writing, recover the amounts due: \nIf the contractor does not honour the obligation to pay the amount due by the date set by the  contracting authority in the debit note, the amount due bears interest at the rate indicated in  Article II.21.8. Interest on late payments will cover the period starting on the day after the due  date for payment and ending on the date when the contracting authority receives the full amount  owed.\nAny partial payment is first entered against charges and interest on late payment and then  against the principal amount. \nIf the contract is signed by a group (joint tender), the group is jointly and severally liable under  the conditions set out in Article II.6 (liability). The contracting authority first claims the full  amount to the leader of the group.\nIf the leader does not pay by the due date and if the amount cannot be offset in accordance with  Article II.23.2 (a), the contracting authority may claim the full amount to any other member of  the group by  notifying  the debit note already sent to the leader under Article II.23.2.\nSuch checks and audits may be initiated at any moment during the  provision of services and up to five years, starting from the payment of the balance of the last specific  contract issued under this FWC.\nThe audit procedure is initiated on the date of receipt of the relevant letter sent by the  contracting authority. Audits are carried out on a confidential basis. \n38 \n(a) by offsetting them against any amounts owed to the contractor by the European Centre  for Disease Prevention and; (b) by calling in a financial guarantee if the contractor has submitted one to the \nfor Disease Prevention and; (b) by calling in a financial guarantee if the contractor has submitted one to the  contracting authority; (c) by taking legal action.\ncontracting authority; (c) by taking legal action.\nII.24.1 The contracting authority and the European Anti-Fraud Office may check or require  an audit on the  implementation of the FWC . This may be carried out either by OLAF’s  own staff or by any other outside body authorised to do so on its behalf."}]}
+{"image": "doclay/doclay_68253.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Detail Data DR Phase Name PRE Current System Physical Memory 42949672960 -->> This is 40 GB, which is the current running memory  size. Memory that is requested to remove 34359738368 -->> This is 32 GB, which you want to remove. ProbeVue Max Pinned Memory tunable value 4294967296 -->> This is 4 GB, which is current maximum pinned memory  for ProbeVue.\n# probevctrl -c max_total_mem_size=3276 Attention: The command \"/usr/sbin/bosboot -a\" must be run for the change to  take effect in the next boot.\n#  probevctrl -c trace=off Attention: The command \"/usr/sbin/bosboot -a\" must be run for the change to  take effect in the next boot.\n6.4.2 Configuration steps for ROHA\nIn the ROHA solution, it is possible that PowerHA SystemMirror removes memory to a low  value, such as in the procedure of  Automatic resource release after OS failure . To avoid this  situation, consider the following items:\nTherefore, you can set the maximum pinned memory size with the command that is shown  in Table 6-9.\nSet it to 3276 MB, which is less than 3276.8 (8 GB*40%). This change takes effect  immediately. But, if you want this change to take effect after the next restart, you must run  /usr/sbin/bosboot -a  before the restart.\nGLYPH<SM590000> If you want to enable the ProbeVue component, set the maximum pinned memory less or  equal to (40% *minimum memory value of one LPAR’s profile). For ex ample, in this case,  the minimum memory size is 8 GB, so 40% is 3276.8 MB. \nGLYPH<SM590000> If you do not want the ProbeVue component online, you can turn it off with the command  that is shown in Example 6-10.\nGLYPH<SM590000> Cluster name\nGLYPH<SM590000> Nodes in the cluster\nGLYPH<SM590000> Cluster Aware AIX (CAA) repository disk \nGLYPH<SM590000> Shared volume group (VG)\nGLYPH<SM590000> Application controller\nGLYPH<SM590000> Service IP\n196  IBM PowerHA SystemMirror V7.2.3 for IBM AIX and V7.2.2 for Linux\nThis change takes effect immediately. But, if you want this change to take effect after the  next restart, you must run  /usr/sbin/bosboot -a  before the restart.\nAfter finishing all of the preparations and considerations outside of PowerHA SystemMirror,  you must configure PowerHA SystemMirror.\nFirst, you must configure some generic elements for the PowerHA SystemMirror cluster:\nExample 6-10 Turning off ProbeVue\nExample 6-9 Changing max_total_mem_size"}]}
+{"image": "doclay/doclay_73939.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Table of Contents\nIndex to Financial Statements\nLeasehold acreage as of December 31, 2019\nProducing wells as of December 31, 2019\n41\ncapital investments, we refer you to “ Management’s Discussion and Analysis of Financial Condition and Results of Operations – Liquidity and Capital Resources – Capital Investing .” We also refer you to Item 6, “ Selected Financial Data ” in Part II of this Annual Report for information concerning natural gas, oil and NGLs produced.\nThe information regarding natural gas and oil properties, wells, operations and acreage required by Item 1208 of Regulation S-K is set forth below:\n(1) The exploration licenses for 2,518,519 net acres in New Brunswick, Canada, have been subject to a moratorium since 2015. These licenses expire in 2021, and we impaired their value to $0 in 2016.\nThe following table summarizes the leasehold acreage expiring over the next three years, assuming successful wells are not drilled to develop the acreage and leases are not extended:\nLease Expirations\n(1) Of this acreage, 1,726 net acres in 2020, 2,173 net acres in 2021 and 6,907 net acres in 2022 can be extended for an average of 4.9 years.\n(2) Exploration licenses were extended through 2021 but have been subject to a moratorium since 2015. We impaired their value to $0 in 2016.\nNatural Gas Oil Total Gross Wells Operated Gross Net Gross Net Gross Net Northeast Appalachia 711  631  —  —  711  631  641  Southwest Appalachia 533  386  —  —  533  386  505  Other 6  3  11  11  17  14  17  1,250  1,020  11  11  1,261  1,031  1,163 \nFor the years ended December 31, Net acreage expiring: 2020 2021 2022 Northeast Appalachia 3,082  1,750  4,567  Southwest Appalachia  (1) 15,584  5,804  14,536  Other: US – Other Exploration 11,949  5,679  650  US – Sand Wash Basin 5,630  3,425  —  Canada – New Brunswick  (2) —  2,518,519  — \nUndeveloped Developed Total Gross Net Gross Net Gross Net Northeast Appalachia 69,643  53,435  126,926  120,559  196,569  173,994  Southwest Appalachia 353,847  205,222  118,431  82,471  472,278  287,693  Other: US – Other Exploration 26,880  18,278  5,034  2,263  31,914  20,541  US – Sand Wash Basin 15,551  9,056  14,977  10,792  30,528  19,848  Total US 465,921  285,991  265,368  216,085  731,289  502,076  Canada – New Brunswick  (1) 2,518,519  2,518,519  —  —  2,518,519  2,518,519  2,984,440  2,804,510  265,368  216,085  3,249,808  3,020,595 "}]}
+{"image": "doclay/doclay_43241.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Once the boundary layer of the air adheres to the wing by  friction, further resistance to the airflow is caused by the  viscosity, the tendency of the air to stick to itself. When  these two forces act together to resist airflow over a wing,  it is called drag. \nPressure is the force applied in a perpendicular direction to the  surface of an object. Often, pressure is measured in pounds of  force exerted per square inch of an object, or PSI. An object  completely immersed in a fluid will feel pressure uniformly  around the entire surface of the object. If the pressure on one  surface of the object becomes less than the pressure exerted  on the other surfaces, the object will move in the direction  of the lower pressure. \nAlthough there are various kinds of pressure, pilots are  mainly concerned with atmospheric pressure. It is one of  the basic factors in weather changes, helps to lift an aircraft,  and actuates some of the important flight instruments. These  instruments are the altimeter, airspeed indicator, vertical  speed indicator, and manifold pressure gauge. \nAir is very light, but it has mass and is affected by the  attraction of gravity. Therefore, like any other substance,  it has weight, and because of its weight, it has force. Since  air is a fluid substance, this force is exerted equally in all  directions. Its effect on bodies within the air is called pressure.  Under standard conditions at sea level, the average pressure  exerted by the weight of the atmosphere is approximately  14.70 pounds per square inch (psi) of surface, or 1,013.2  millibars (mb). The thickness of the atmosphere is limited;  therefore, the higher the altitude, the less air there is above.  For this reason, the weight of the atmosphere at 18,000 feet  is one-half what it is at sea level. \nThe pressure of the atmosphere varies with time and location.  Due to the changing atmospheric pressure, a standard  reference was developed. The standard atmosphere at sea  level is a surface temperature of 59 °F or 15 °C and a surface  pressure of 29.92 inches of mercury (\"Hg) or 1,013.2 mb.  [Figure 4-2] \nA standard temperature lapse rate is when the temperature  decreases at the rate of approximately 3.5 °F or 2 °C per  thousand feet up to 36,000 feet, which is approximately –65  °F or –55 °C. Above this point, the temperature is considered  constant up to 80,000 feet. A standard pressure lapse rate is  when pressure decreases at a rate of approximately 1 \"Hg  per 1,000 feet of altitude gain to 10,000 feet.  [Figure 4-3]  The International Civil Aviation Organization (ICAO) has  established this as a worldwide standard, and it is often \nreferred to as International Standard Atmosphere (ISA) or  ICAO Standard Atmosphere. Any temperature or pressure  that differs from the standard lapse rates is considered  nonstandard temperature and pressure. \nFigure 4-3.  Properties of standard atmosphere. \nFigure 4-2.  Standard sea level pressure. \nAtmospheric Pressure \nPressure \n30  25  20  15  10  5  0  Inches of  Mercury  Millibars  1016  847  677  508  339  170  0  29.92  Standard  Sea Level  Pressure  Hg  1013  Standard  Sea Level  Pressure  mb  Atmospheric Pressure\nAltitude (ft)  Pressure (Hg)  Temperature  (°C)  (°F)  Standard Atmosphere  0  1,000  2,000  3,000  4,000  5,000  6,000  7,000  8,000  9,000  10,000  11,000  12,000  13,000  14,000  15,000  16,000  17,000  18,000  19,000  20,000  29.92  28.86  27.82  26.82  25.84  24.89  23.98  23.09  22.22  21.38  20.57  19.79  19.02  18.29  17.57  16.88  16.21  15.56  14.94  14.33  13.74  15.0  13.0  11.0  9.1  7.1  5.1  3.1  1.1  -0.9  -2.8  -4.8  -6.8  -8.8  -10.8  -12.7  -14.7  -16.7  -18.7  -20.7  -22.6  -24.6  59.0  55.4  51.9  48.3  44.7  41.2  37.6  34.0  30.5  26.9  23.3  19.8  16.2  12.6  9.1  5.5  1.9  -1.6  -5.2  -8.8  -12.3 \n4-3 "}]}
+{"image": "doclay/doclay_3983.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "03809453. 3\nbe A fh 12/17\n16\nK-50, ERBERP, ATPRIVI, ZCHRA SAP 20RZ, UR P 200IMEA THAD, BREA, AP 10 RGBATHR Vd MUR TAR SOWA, ZRAAGLEA 4 BY RERAMAREA 50,\nA4EFR-HRHAAMNFER, APRA, PTW HRSH LAA AWD (ATIPS) BH. RRA REA SV SEP REA VZMA MEG (AER), BEIBFRRR HERAN. RERZSPRAA 30 WAAL 20 sw 30. AAR 4 PHAMIAA—F, ARE AAA 20, BPHTAAP 20. AP 20 RARER I0RA. ARI, AP 20 Eel AR KA 50, RWS 30 Aww REA 0 HO ATs RAR FTF M ATE RAFERE A SOK EH AMS 30 HZ cookie, XK HBA 320 Hae LA PRA, WARD R IL AHTAw, 8 JEILA ERA EPH, FUR Ila, AREA 50 MRS 30 HK ALA ERAMASY, HLEMAAP 20. TARAS ARMA AMITEE HM, HPAP 0 4AARKRRRAA A MAAK S IRL Hea E LI. A FUP lic, MIKREK 50 RiAR “localhost” (HFA 40 aFA a) Ate E HE LI, THR la SF HR Ilo VLR EKA 40 £EEZAPR IL, WRAA MEERA 40 (HARE) ARAM 4, MPU eA “localhost” HASHMI. RH, HRA-* ASE LABRASN, TAREE ABE ALEERKABRAA. BK A, SARPRA ORBEA IO, BRP AP eA AS ERS A400, Axe pT BAA P REAWRMAAEAARRLOA PERE RAY, ASH, CKROGRII GSFHR lla, RHA HTTP FZ 2, PME REA 50 ORS 30 RURAL, WATFRI, Ar it] WR 30 SEERA 40, RRA HAH, HY HTTP bee fos VAS H—UMX, Bio SOAP (MBM RDA) ME. AM, AIK AERA SID AEF PR 11d PEM. HREM (HIWEDR 1 PiF RAR GAY URL) RTA, HRI, AAR TAMIA PTA by SAK 40 OY AFA, RIF REA 50 MIP BH AAAS & IRI AH, WI LA Ep Se AIR VA Bik Bodh (A AF HR Ve PUR). HOR sme, LAT ASRRAER. MW “AM” HHRZELAATOR IVe ¥ 4 ¢e 2 AAROURL Masi 255 FH, MAF HR 1ld RGAE EL, GS"}]}
+{"image": "doclay/doclay_25536.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "usual nonparametric rate in (ordinary) function spaces. For example, as demonstrated in Zinde-Walsh (2008) kernel estimators of density that may diverge if the distribution function is not absolutely continuous, are always (under the usual assumptions on kernel/bandwidth) consistent in the weak topology of the space of generalized functions, where the density problem is well-posed. Here, well-posedness holds for deconvolution as long as the error density is not super-smooth.\nWhen well-posedness cannot be ensured, plug-in estimation will not provide consistent results and some regularization is required; usually spectral cut-off is employed for the problems considered here. In the context of these non- parametric models regularization requires extra information: the knowledge of the rate of decay of the Fourier transform of some of the functions.\nFor model 1 this is not a problem since φ$_{u}$ is assumed known; the regular- ization uses the information about the decay of this characteristic function to construct a sequence of compactly supported solutions with support increas- ing at a corresponding rate. In S ∗ no regularization is required for plug-in estimation unless the error distribution is super-smooth. Exponential growth in φ − 1 u provides a logarithmic rate of convergence in function classes for the estimator (Fan, 1991). Below we examine spectral cut-off regularization for the deconvolution in S ∗ when the error density is super-smooth.\nWith super-smooth error in S ∗ define a class of generalized functions\n50\n5.2 Regularization in plug-in estimation"}]}
+{"image": "doclay/doclay_73752.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Table of Contents\nCITIZENS, INC.\nREVENUES\nEndowment sales represent a significant portion of new business sales internationally with the 20-year endowment and endowment to age 65 representing our top products. In addition, most of our life insurance policies contain a policy loan provision, which allows the policyholder to use cash value within a policy to pay premiums. The policy loan asset balance increased 1.5% in 2019 and 9.6% in 2018 and remains in line with historical levels when compared to policy benefit liabilities.\nNet Investment Income. Net investment income increased 9.8% to $59.5 million in 2019 compared to $54.2 million in 2018, despite a decline in overall market yields. The annualized yield increased by nineteen basis points in 2019 compared to 2018. We have been successful in achieving higher yields while maintaining a prudent risk profile for our portfolio in 2019 despite facing an increasingly challenging investment environment. During the fourth quarter of 2018, we repositioned our portfolio into more diversified holdings and maturities as part of our investment management strategy to improve our portfolio credit quality. In doing so, we increased our purchases of investment grade securities while reducing our municipal holdings. While these purchases improved the overall credit rating of our portfolio, these securities generally have lower yields. In addition, net investment income and the annualized yield on our portfolio were lower during 2018 due to the need to maintain sufficient cash balances to fund our Bermuda novation as previously noted.\nPremium Income. Premium income derived from life, accident and health, and property insurance sales decreased 1.9% during 2019 compared to 2018 and decreased 5.0% during 2018 compared to 2017. The decrease in 2019 was driven primarily by a decline in renewal premiums in our Life insurance segment and was partially offset by an increase in first year premiums in that segment. The decrease in 2018 was primarily due to a decline in first year and renewal premiums in our Life insurance segment. See details on the distribution of premiums below and further discussion within Segment Operations.\nDecember 31, 2019 | 10-K 32\nInsurance revenues are primarily generated from premium revenues and investment income. In addition, realized gains and losses on investment holdings can significantly impact revenues from year to year.\nYears ended December 31, (In thousands) 2019 2018 2017 Revenues: Premiums: Life insurance $ 178,351 181,825 191,342 Accident and health insurance 1,383 1,218 1,392 Property insurance 4,613 4,817 4,986 Net investment income 59,531 54,205 53,146 Realized investment gains 5,249 108 518 Other income 1,418 1,833 1,243 Total revenues $ 250,545 244,006 252,627\nYears ended December 31, (In thousands) 2019 2018 2017 Premiums: First year $ 17,508 17,639 23,726 Renewal 166,839 170,221 173,994 Total premiums $ 184,347 187,860 197,720"}]}
+{"image": "doclay/doclay_70953.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "114\nОПК-2. Способен применять методы математического И алгоритмического моделирования, современный математический аппарат В научно- исеследовательской и опЫТтно- конструкторской деятельности ОПК-3. Способен использовать методы физического моделирования и современное экспериментальное оборудование в профессиональной деятельности ОПК-4. Способен понимать принципы работы современных информационных технологий и использовать их для решения задач профессиональной деятельности (опік. Способен использовать в педагогической деятельности научные основы знаний в сфере математики и механики ОПК-6. Способен разрабатывать алгоритмы и компьютерные программы, пригодные для практического применения\n»,\n88. В федеральном государственном образовательном стандарте высшего образования – бакалавриат по направлению подготовки 01.03.04 Прикладная математика, утвержденном приказом Министерства образования и науки Российской Федерации от 10 января 2018 г. № 11 (зарегистрирован Министерством юстиции Российской Федерации 6 февраля 2018 г., регистрационный № 49944), с изменениями, внесенными приказом Министерства науки и высшего образования Российской Федерации от 8 февраля 2021 г. № 83 (зарегистрирован Министерством юстиции Российской Федерации 12 ма��та 2021 г., регистрационный № 62739) (далее – Приказ № 11):"}]}
+{"image": "doclay/doclay_7246.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "A Higher IQ for Healthcare IT\n2004 ANNUAL  REPOR T"}]}
+{"image": "doclay/doclay_42820.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Figure 1-34. New charting standard without ATC annotations. \n1-39 \nNOT FOR NAVIGATION NOT FOR NAVIGATION SW -4, XX XXX 201 1 to XX XXX 201 1  SW-4, XX XXX 2011 to XX XXX 2011 SW -4, XX XXX 201 1 to XX XXX 201 1  SW-4, XX XXX 2011 to XX XXX 2011"}]}
+{"image": "doclay/doclay_32151.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "o 1 2 3 4 t$_{o}$ t 2 E (k ) ||  x k$_{x}$ B$_{1}$ A$_{1}$ A$_{2}$ B\nFIG. 1: On the l.h.s. of the figure is picture a four leg ladder with equal hopping along and between the legs of the ladder. On the r.h.s are pictured the corresponding four bands, A$_{1}$$_{,}$$_{2}$ , B$_{1}$$_{,}$$_{2}$ of such a ladder.\nwhere c$_{n}$ is the corresponding annihilation operator of an electron on the n-th leg of the ladder.\nClose to half filling the Fermi velocities of the outer band pair labeled by B are smaller than those of the inner bands labeled by A , so that in the presence of interactions the effective dimensionless coupling constants for electrons in the inner bands are smaller than those for the outer bands. In the weak coupling limit, i.e. an onsite interaction characterized by U ≪ t , this Fermi velocity difference leads to a large difference in the characteristic energy scales and to a decoupling of the RG flows of the two band pairs. The outer band pair has the larger critical energy scale and flows to strong coupling first as the energy scale is lowered. 21–23 The inner band pair has a lower critical scale. Therefore in the first approximation one can treat inner and outer bands of individual 4-leg ladders as decoupled from each other. Then each band pair will effectively constitute a two-leg ladder. It is well known that two-leg ladders acquire spectral gaps for quite general interaction patterns. For the inner bands the smaller dimensionless couplings lead to smaller spectral gaps. At half filling each band pair is exactly half filled and behaves as a half filled 2-leg Hubbard ladder. The difference in the energy scales leads to a finite doping range x < x$_{c}$ where all the doped holes enter the inner band pair and the outer band pair remains exactly half filled. We note in passing that similar behavior is found also in the strong coupling limit, U ≫ t . 24 Given that a 4-leg ladder can be reduced to two 2-leg ladders, we will now recall some\n≫ Given that a 4-leg ladder can be reduced to two 2-leg ladders, we will now recall some basic facts about 2-leg ladders. For general interactions they become either Luttinger liquids or dynamically generate spectral gaps. In the latter case an increased symmetry appears\n4"}]}
+{"image": "doclay/doclay_69540.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "8464ch08_Migrate.fm\nDraft Document for Review February 7, 2020 3:15 pm\na. Change the Cloud Premigration Rank in Storage Group (SG) and Partition in the  Storage Class (SC) constructs to allow copies to be sent to the selected cloud  repository.\nb. Determine the list of existing private virtual volumes that are intended to be reallocated  to the cloud storage layer.\nA user can list the status of virtual volumes by using the  BVIR VOLUME STATUS command. The output of the resulting report can be filtered and then used to create a  list of virtual volumes that should be sent to the cloud.\nc. Use the library request interface to process each virtual volume in volume list so that it  can be moved to the cloud storage system:  LI REQ PARTRFSH,<volser>,MMOUNT\nThis option updates the cloud attributes of target virtual volumes by mimicking a  mount/demount, so the user does not need to specifically exercise such operation for  new attributes to occur. \nGLYPH<SM590000> Cloud ghost copy processing\na. Join a new cluster to a grid.\nb. Change the Copy Mode in Management Class (MC) to allow copies to the new cluster.\nc. Generate a list of private virtual volumes that were premigrated to the cloud, which  must be copied to the new cluster.\n8. Run  Copy Refresh  on each logical volume in the list that was created in Step 3 to produce  a new ghost copy of the data in the new cluster. Copy Refresh with “ghost” option can be  run by using the  LI REQ COPYRFSH,<volser>,CLDGHOST  command.\nGLYPH<129> BVIRMES\nGLYPH<129> VESYNC\nGLYPH<129> BVIRVTS\nGLYPH<129> COPYRFSH\nIf the grid includes a TS7700C and virtual volumes were premigrated to the cloud storage  repository, cloud copies can be made directly accessible to a new TS7700C cluster joining  the grid, a need does not exist for explicit copy processing through the grid links. The  following steps must be completed:\nFor more information about how to join a new cluster to a grid, see 7.4, “Adding  clusters to a grid” on page 282.\nMC can be configured from MI. For more information, see 9.3.8, “Constructs icon” on  page 453.\nFor more information about Copy Mode, see 4.2.2, “Defining grid copy mode control”  on page 158.\nA user can list the status of virtual volumes by using the  BVIR VOLUME STATUS command, and verify which volumes were premigrated to cloud by using the  BVIR  CLOUD VOLUME MAP  command. The output of the resulting reports can be filtered and  then used to create a list of virtual volumes that are copied to the new TS7700C  cluster.\nThe following IBM Tape Tools are available to support this process:\nThe  Copy Refresh  command can be submitted from a host or the MI, and the data is copied  only in a logical level through the gridlinks. No Host I/O ia done through the FICON adapters,  nor bandwidth consumption through grid links for copies required, and all data in the TCDB  and tape management remain unchanged. This method can be used only if the data  migration is inside a grid with target volumes previously premigrated to the cloud storage  repository. The BVIR AUDIT parameter provides an easy method to ensure that all data is  copied.\n308  IBM TS7700 Release 5.0 Guide"}]}
+{"image": "doclay/doclay_32719.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "0.1 0.2 0.3 0.4 ρ ∗ 0.2 0.3 0.4 0.5 T *\nFIG. 10: Cascade of water-like anomalies in the density-temperature plane. The solid line lim its the region of density anomaly, the dashed line illustrates the region of diffusion anomaly and the dot-dashed line shows the region of structural anomaly. The filled circles represent the density of minimum and maximum s$_{2}$ and the stars represent the region of minimum and maximum F$_{im}$ .\nWe demonstrate that the diffusivity and the excess entropy of a core-softened fluid with isotropic pair interactions obey Rosenfeld-type excess entropy scaling of transport properties. The use of macroscopic reduction parameters for the diffusivity based on temperature and density is particularly appropriate for fluids with multiple length scales where defining an effective hard-sphere radius is inappropriate. We also show that the substituting the excess entropy by the pair correlation entropy leads to a weak isochore dependence of the Rosenfeld- scaling parameters, not seen in simple liquids but observed in other water-like liquids. 66\nThe instantaneous normal mode spectra, including the Einstein frequency and the fraction of imaginary modes, is computed over a wide range of temperatures and densities. INM analysis is shown to provide unexpected insights into the dynamical consequences of the interplay between length scales characteristic of anomalous fluids that cannot be obtained from an equilibrium transport property such as the diffusivity.\nBoth the real and imaginary branches of the INM spectra exhibit bimodality that has so far not been observed. As a function of density along an isotherm, the bimodality in the real branch of the INM spectrum persists to very high densities well beyond the structurally\n17"}]}
+{"image": "doclay/doclay_11893.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "\nAlexandria Real Estate Equities, Inc. 2004 Annual Report \nF I N A N C I A L S\n"}]}
+{"image": "doclay/doclay_12686.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "EXPANDING MARKETS\nCOMMERCE NATIONAL BANK…OUR FIRST OHIO AFFILIATE\nThe acquisition of Commerce National Bank (CNB) was completed effective March 1, 2003 and provides First Merchants with its first banking foray outside Indiana.\nCNB was an entrepreneurial effort started in 1991 in Columbus, Ohio and has grown to an asset size of $320 million. CNB operates in the economically vibrant Franklin County, which has the lowest unemployment rate in Ohio and also below the national rates. Over 200,000  new jobs  have been created in the Columbus MSA since 1990. 38.7% of all Franklin County households had income of over $50,000 and the median household income is in excess of $42,000. 11.6% of households have an annual income of more than $100,000.\nColumbus is the capital of Ohio as well as home to The Ohio State University. A vibrant and diverse area, more than 1.06 million people live in Columbus and Franklin County. Columbus is ranked as the #11 Best City to Live and Work ( Employment Review /June 2003, the #1 City in the US for African American Families (Black Entertainment Network {BET}/October 2002, and the #1 City in the Midwest for Entrepreneurs ( Entrepreneur/ October 2002) among accolades constantly received.\nCNB brings a unique business model to First Merchants. CNB began with the vision to serve the banking needs of privately owned businesses and their owners involved in small to mid-size operations. CNB has earned its reputation as “the Bank for Business” through its focused business banking strategy and high-touch approach to its clients. CNB delivers its services through a single location and the use of mobile branches, private bankers, and web-based technology. High-touch\nservices also include offering seminars to its corporate and private clients that cover current business issues, an outstanding approach to two economic publications,  Business Climate Outlook  and  Financial Forecasts,  that keep its clients on the forefront of current economic conditions, and a series of updates on financial fraud published on the web.\n24\nthe cnb mobile banking team"}]}
+{"image": "doclay/doclay_53479.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "2.2. The Interpreter and Its Environment\n7\nPython Tutorial, Release 3.9.5\n#!/usr/bin/env python3 # -*- coding: cp1252 -*-"}]}
+{"image": "doclay/doclay_78673.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "CHAPTER 10. PERLTOOC\n10.3. CLASS DATA AS PACKAGE VARIABLES\nAny actual values set on the template object will be copied to the new object. But attributes undefined in the template object, being translucent, will remain undefined and consequently translucent in the new one as well.\nNow let’s change the color attribute on the entire class:\nThat color change took e ff ect only in the first pair of objects, which were still translucently accessing the meta-object’s values. The second pair had per-object initialized colors, and so didn’t change.\nOne important question remains. Changes to the meta-object are reflected in translucent attributes in the entire class, but what about changes to discrete objects? If you change the color of $ob3, does the value of $ob4 see that change? Or vice-versa. If you change the color of $ob4, does then the value of $ob3 shift?\nWhile one could argue that in certain rare cases it should, let’s not do that. Good taste aside, we want the answer to the question posed in the comment above to be \"chartreuse\", not \"amethyst\". So we’ll treat these attributes similar to the way process attributes like environment variables, user and group IDs, or the current working directory are treated across a fork(). You can change only yourself, but you will see those changes reflected in your unspawned children. Changes to one object will propagate neither up to the parent nor down to any existing child objects. Those objects made later, however, will see the changes.\nIf you have an object with an actual attribute value, and you want to make that object’s attribute value translucent again, what do you do? Let’s design the class so that when you invoke an accessor method with undef as its argument, that attribute returns to translucency.\nHere’s a complete implementation of Vermin as described above.\n138\npackage Vermin; # here’s the class meta-object, eponymously named. # it holds all class attributes, and also all instance attributes # so the latter can be used for both initialization # and translucency. our %Vermin = ( # our() is new to perl5.6 PopCount => 0, # capital for class attributes color => \"beige\", # small for instance attributes ); # constructor method # invoked as class method or object method sub spawn { my $obclass = shift; my $class = ref($obclass) || $obclass; my $self = {};\nVermin->color(\"azure\"); print $ob1->color(); # prints \"azure\" print $ob2->color(); # prints \"azure\" print $ob3->color(); # prints \"chartreuse\" print $ob4->color(); # prints \"chartreuse\"\n$ob3->color(\"amethyst\"); print $ob3->color(); # prints \"amethyst\" print $ob4->color(); # hmm: \"chartreuse\" or \"amethyst\"?\n$ob4->color(undef); # back to \"azure\"\n$ob4 = $ob3->spawn(); # $ob3 now template, not %Vermin print $ob4->color(); # prints \"chartreuse\""}]}
+{"image": "doclay/doclay_10167.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "for the year ended November 30 (millions) 2004 2003 2002 Operating activities Net income $214.5 $ 210.8 $179.8 Net income from discontinued operations – (4.7) (6.0) Gain on sale of discontinued operations – (9.0) – Cumulative effect of accounting change – 2.1 – Net income from continuing operations  214.5 199.2 173.8 Adjustments to reconcile net income from continuing operations to  net cash provided by continuing operating activities: Depreciation and amortization 72.0 65.3 53.4 Deferred income taxes (1.7) 15.6 21.1 Income from unconsolidated operations (14.6) (16.4) (22.4) Changes in operating assets and liabilities: Receivables (35.5) 9.8 (35.0) Inventories 33.8 (50.0) (18.7) Prepaid allowances 27.2 13.5 2.7 Trade accounts payable 5.7 (17.1) 13.3 Other assets and liabilities  38.5 (38.7) 1.3 Dividends received from unconsolidated affiliates 9.6 20.6 19.1 Net cash provided by continuing operating activities 349.5 201.8 208.6 Investing activities Acquisitions of businesses (74.5) (202.9) (1.4) Purchase price adjustment – 50.0 – Capital expenditures (69.8) (91.6) (100.4) Proceeds from sale of discontinued operations – 133.9 – Proceeds from sale of property, plant and equipment 2.8 9.9 6.5 Net cash used in continuing investing activities (141.5) (100.7) (95.3) Financing activities Short-term borrowings, net (14.3) 17.2 (73.8) Long-term debt borrowings 50.1 – – Long-term debt repayments (16.5) (.8) (.6) Proceeds from exercised stock options 53.0 29.5 23.2 Common stock acquired by purchase (173.8) (119.5) (5.1) Dividends paid (76.9) (64.1) (58.6) Net cash used in continuing financing activities (178.4) (137.7) (114.9) Effect of exchange rate changes on cash and cash equivalents 15.6 19.0 9.5 Net cash (used in)/provided by discontinued operations – (4.6) 8.1 Increase /(decrease) in cash and cash equivalents 45.2 (22.2) 16.0 Cash and cash equivalents at beginning of year 25.1 47.3 31.3 Cash and cash equivalents at end of year $ 70.3 $ 25.1 $ 47.3\nSee Notes to Consolidated Financial Statements, pages 41-55.\n39\nconsolidated statement of cash flows\nMCCORMICK & COMPANY 2004 ANNUAL REPORT"}]}
+{"image": "doclay/doclay_39391.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "1 of 18 \nConstruction of Giresun Wastewater Treatment Plant  Tender Dossier Volume 3 Employer’s Requirements  Section 06: Concrete and Steel Works \nIf a joint ends at another part of the structure, such as the connection between a wall and a bottom slab,  the waterstop shall also be placed at least 300 mm inside the adjacent part of the structure. \nWaterstops shall be placed in accordance with the manufacturer's specifications. Waterstops shall be  carefully placed and maintained in position during concreting and compaction operations. Concrete  shall be carefully compacted around the waterstops so as to leave no cavities.\nWaterstops shall fulfil the following requirements: \nProperty at 25$^{o}$C  Rubber  PVC  Minimum  tensile  strength  (N/mm$^{2}$)  20  15  Minimum elongation at break  (%)  450  285  Hardness (IRHD/ Shore A)  60 - 75  70 - 75  Softness (BS 2571)  42$^{o}$C - 52$^{o}$C  Specific gravity  1.1 (+5%)  1.3 +(5%) \nThe Contractor shall submit details of the waterstops, including a description of the installation of the  waterstops, to the Engineer for his approval at least one month before commencement of the formwork  at site. \n6.1.13 Testing of tanks\nAll tanks shall be tested for water tightness in accordance with EN 1992-3. The testing procedure shall  be according to the following procedure. \nExcavation for tanks shall not be filled and tank wall faces shall not be coated or plastered outside and  inside before the watertightness tests have been passed successfully. \n The test may not be commenced before the concrete has hardened for 28 days. \n Filling of tanks with water shall take place with a constant flow rate. The chosen flow rate  shall raise the level in the tank not more than 2 m height in 24 hours. \n A period of 1 week shall be allowed for saturation and stabilization (admission of water into  the concrete). \n Water levels shall be measured by approved means at 24 hours intervals for a test period of  5 days. \n During the test period the total permissible water level drop, after allowing for evaporation  and rainfall, shall not exceed 1/500 of the average water depth of the full tank or 10 mm,  whichever is greater. \nThe testing procedure shall be used also for small chambers (flow confluence or distribution cham- bers) and for manholes of gravity pipelines. \nNotwithstanding the satisfactory completion of the above test, any leakage or soaking visible on the  outside face of the tank walls shall be stopped, after allowing for self-sealing. Any sealing or making \n6_Vol3_d4.3_Section 6 Concrete and steel works_en_GIR_rev6.docx "}]}
+{"image": "doclay/doclay_24430.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "max z$_{u,m}$,x$_{u,b}$ ∈{ 0 , 1 } ,γ$_{u,b}$,θ$_{u,m}$ ∈ [0 , 1] ∀ u ∈U ,b ∈B$_{m}$ ,m ∈M { ∑ u ∈U ∑ m ∈M ( w$_{u}$R$_{u,m}$θ$_{u,m}$ + ∑ b ∈B$_{m}$ w$_{u}$x$_{u,b}$R$_{u,b}$γ$_{u,b}$$^{)}}$ s . t . ∑ m ∈M z$_{u,m}$ ≤ 1; ∑ b ∈B$_{m}$ x$_{u,b}$ = z$_{u,m}$, ∀ u ∈ U , m ∈ M ; ∑ u ∈U θ$_{u,m}$ ≤ 1 & ∑ u ∈U γ$_{u,b}$ ≤ 1 ∀ b ∈ B$_{m}$ , m ∈ M ; R$_{u,m}$θ$_{u,m}$ + ∑ b ∈B$_{m}$ x$_{u,b}$R$_{u,b}$γ$_{u,b}$ ∈ [ z$_{u,m}$R min u , z$_{u,m}$R max u ] , ∀ u ∈ U . (1)\nmaximization problem that adopts the weighted sum rate (WSR) system utility under per-user rate constraints. The WSR problem is posed in (1). w$_{u}$ > 0 , ∀ u ∈ U denotes any input weight or priority assigned to user u . In (1) the binary valued variable z$_{u,m}$ is one if user u is associated with macro TP m and zero otherwise, so that the first set of constraints in (1) ensures that each user is associated with at-most one macro. Further, exploiting dual connectivity, each user that is associated to the macro TP m is also associated with any one pico TP in B$_{m}$ . Indeed, the indicator variable x$_{u,b}$ is one if user u is associated to TP b and zero otherwise. Consequently, { x$_{u,b}$ = 1 }$_{u}$$_{∈U}$$_{,b}$$_{∈B}$$_{m}$ yields the user set such that each user in that set is associated to any one TP in B$_{m}$ as well with the macro TP m . The continuous variables { γ$_{u,b}$, θ$_{u,m}$ } are referred to here as allocation fractions and their respective sums are upper bounded by unity for each macro TP as well as each pico TP, as depicted in the second set of constraints. Although (1) does not enforce that each user must be associated with a macro TP, it does enforce (in the third set of constraints) that each user associated to any macro TP must be assigned at-least its minimum rate but should not exceed a maximum rate. Notice also that (1) is always feasible. 1 The minimum rate constraints are useful in enforcing that a minimum expected quality is provided to each served user and are based on the observation that in many scenarios serving a user at a rate below its minimum threshold is futile. On the other hand, the maximum rate limits can be used to cap the rates of any set of users such as those that have subscribed to a lower tier of service.\n$^{1}$Note that single-TP only association is subsumed by (1). Indeed, with x$_{u,b}$ = 1 for some u ∈ U , b ∈ B$_{m}$ , by choosing θ$_{u,m}$ = 0 ( γ$_{u,b}$ = 0 ) we can ensure that user u will receive data only from the pico node b (macro node m ). Also, each user u that is not associated with any macro TP gets zero rate and must have θ$_{u,m}$ = 0 , γ$_{u,b}$ = 0 , ∀ b ∈ B$_{m}$ , m ∈ M due to the third set of constraints."}]}
+{"image": "doclay/doclay_45390.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "\nFigure 3-21.  Other mistakes arise under pressure. For example, a technician or pilot might perform a cursory inspection of an  aircraft to save time, only to have a problem manifest itself later. \nErrors are reduced when visible reminders are present and actively used. Checklists and other published procedures are examples of  reminders. Many aircraft instruments such as heading indicators offer bugs that can be used to remind the pilot about assigned  headings and courses and some may also prompt altitudes and airspeeds. Mechanics and pilots alike can use notepads to jot down  reminders or information that should otherwise be committed to memory. \nThe use of standardized procedures for routine tasks is widely known to help reduce error. Even when a checklist procedure is  unavailable or impractical, learners can help reduce the occurrence of error by adopting standardized procedures. \nAnother line of defense against errors is to raise one’s awareness when operating in conditions under which errors are known to  happen (e.g., changes in routine, time pressure), or in conditions under which defenses against errors have been compromised (e.g.,  fatigue, lack of recent practice). \nGiven that the occasional error is inevitable, it is a worthwhile exercise to practice recovering from commonly made errors, or those  that pose serious consequences. All flight learners need to learn and practice a lost procedure to ensure that they can recover from the  situation in which they have lost their way. It is useful to devote the same sort of preparation to other common learner errors. \nUsing Reminders \nDeveloping Routines \nRaising Awareness \nError Recovery \nLearning from Error \nError can be a valuable learning resource. Learners naturally make errors, which instructors can utilize in training to help while being  careful not to let the individual practice doing the wrong thing. When a learner makes an error, it is useful to ask them to consider  why the error happened, and what could be done differently to prevent the error from happening again in the future. In some cases,  errors are slips that simply reveal the need for more practice. In other cases, errors point to aspects of learner methods or habits that  might be improved. For example, beginning instrument flight learners commonly make errors when managing two communications  radios, each with an active and standby frequency. When the same learners understand each radio’s specific purpose (e.g., ATIS,  ground, tower frequencies), error rates often drop quickly. \n3-34 "}]}
+{"image": "doclay/doclay_54006.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Extending and Embedding Python, Release 3.9.5\nChapter 3. Embedding the CPython runtime in a larger application\n62\nUpon return of the function,$_{pValue}$is either$_{NULL}$ or it contains a reference to the return value of the function. Be sure to release the reference after examining the value.\n(continued from previous page)\nfprintf(stderr, \"Cannot find function \" %s \"\n \", argv[ 2]); } Py_XDECREF(pFunc); Py_DECREF(pModule); } else { PyErr_Print(); fprintf(stderr, \"Failed to load \" %s \"\n \", argv[ 1]); return 1; } if (Py_FinalizeEx() <0) { return 120 ; } return 0; }\nThis code loads a Python script using argv[1] , and calls the function named in argv[2] . Its integer arguments are the other values of the$_{argv}$array. If you compile and link this program (let’s call the finished executable$_{call}$ ), and use it to execute a Python script, such as:\ndef multiply (a,b): print(\"Will compute \", a,\"times\", b) c =0 for i in range(0, a): c =c +b return c\n$ call multiply multiply 32 Will compute 3 times 2 Result of call: 6\nPy_Initialize(); pName =PyUnicode_DecodeFSDefault(argv[ 1]); /* Error checking of pName left out */ pModule =PyImport_Import(pName);\npFunc =PyObject_GetAttrString(pModule, argv[ 2]); /* pFunc is a new reference */ if (pFunc&&PyCallable_Check(pFunc)) { ... } Py_XDECREF(pFunc);\nthen the result should be:\nAlthough the program is quite large for its functionality, most of the code is for data conversion between Python and C, and for error reporting. The interesting part with respect to embedding Python starts with\nAfter initializing the interpreter, the script is loaded using$_{PyImport_Import()}$ . This routine needs a Python string as its argument, which is constructed using the$_{PyUnicode_FromString()}$ data conversion routine.\nOnce the script is loaded, the name we’re looking for is retrieved using$_{PyObject_GetAttrString()}$ . If the name exists, and the object returned is callable, you can safely assume that it is a function. The program then proceeds by constructing a tuple of arguments as normal. The call to the Python function is then made with:\npValue=PyObject_CallObject(pFunc, pArgs);"}]}
+{"image": "doclay/doclay_12266.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "The following tables (dollars shown in millions) set forth information about the Company’s operations by its three reportable business segments and by geographic area.\nOperations by Reportable Business Segment\nRevenues 2002 2001  2000  Operating profit 2002  2001  2000  Assets  2002  2001  2000  Depreciation and amortization 2002  2001  2000  Capital expenditures 2002 2001  2000  Barnes Distribution $ 286.7 298.4 291.1 $ 7.5 5.5 12.9 $  168.5 171.5 178.6 $ 7.7 9.9 9.0 $ 7.4 6.0 5.5 Other $ (7.4) (9.2) (13.5) $ — — — $ 76.3 79.5 54.6 $ 1.2 0.6 0.5 $ 1.0 0.2 2.7 Total  BGI $ 784.0 768.8 740.0 $ 46.4 41.3 64.9 $ 652.5 636.5 636.9 $ 33.6 37.0 35.9 $ 19.4 24.9 28.0 Barnes  Aerospace $ 183.0 200.4 135.1 $ 10.8 16.4 8.0 $ 123.9 141.4 130.1 $ 9.2 9.7 8.6 $ 4.5 10.0 5.6 Associated Spring $ 321.7 279.2 327.3 $ 28.1 19.4 44.0 $ 283.8 244.1 273.6 $ 15.5 16.8 17.8 $ 6.5 8.7 14.2\nNotes:\nIn 2002 and 2001, respectively, one customer accounted for 11% and 13% of the Company’s total revenue. In 2000, sales from any one customer did not exceed 10% of the Company’s total revenues.\n“Other” revenues represent the elimination of intersegment sales, the majority of which are sales by Associated Spring  to Barnes Distribution.\nThe operating profit of Associated Spring includes income from its equity investment in NASCO of $1.1 million, $0.4 million and $1.6 million in 2002, 2001 and 2000, respectively.\nThe assets of Associated Spring include the NASCO investment of $9.9 million, $9.4 million and $10.0 million in 2002, 2001 and 2000, respectively.\n“Other” assets include corporate controlled assets, the majority of which are cash and deferred tax assets.\nBack to Table of Contents\nPAGE 37\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS\nBARNES GROUP INC."}]}
+{"image": "doclay/doclay_8058.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\nDecember 31, 2002, 2001, and 2000\n1 \nORGANIZATION AND OPERATIONS\nCalifornia Water Service Group (Company) is a holding company that through its wholly- owned subsidiaries provides water utility and other related services in California,Washington and New Mexico. California Water Service Company (Cal Water),Washington Water Service Company (Washington Water) and New Mexico Water Service Company (New Mexico Water) provide regulated utility services under the rules and regulations of their respective state’s regulatory commissions (jointly referred to as Commissions). CWS Utility Services provides non-regulated water utility and utility-related services.\nThe Company operates primarily in one business segment, providing water and related utility services.\nPrinciples of Consolidation The consolidated financial statements include the accounts of the Company and its wholly-owned subsidiaries. Intercompany transactions and balances have been eliminated.\nReclassifications The accounting records of the Company are maintained in accordance with the uniform system of accounts prescribed by the Commissions. Certain prior years’ amounts have been reclassified, where necessary, to conform to the current presentation.\nUse of Estimates The preparation of consolidated financial statements in conformity with accounting principles generally accepted in the United States of America requires management to make esti- mates and assumptions that affect the reported amounts of assets and liabilities and disclosure of contingent assets and liabilities at the date of the financial statements and the reported amounts of revenues and expenses during the reporting period. Actual results could differ from those estimates.\nRevenue Revenue consists of monthly cycle customer billings for regulated water and waste water service at rates authorized by the Commissions and billings to certain non-regulated customers. Revenue from metered accounts includes unbilled amounts based on the estimated usage from the latest meter reading to the end of the accounting period. Flat-rate accounts, which are billed at the beginning of the service period, are included in revenue on a pro rata basis for the portion applicable to the current accounting period.\nExpense balancing and memorandum accounts are used to track suppliers’ rate increases for purchased water, purchased power and pump taxes that are not included in customer water rates.The cost increases are referred to as “Offsetable Expenses” because under certain circumstances they are recoverable from customers in future rate increases designed to offset the higher costs.The Company does not record the balancing and memorandum accounts until the Commission has authorized a change in customer rates and the customer has been billed.\nUtility Plant Utility plant is carried at original cost when first constructed or purchased, except for certain minor units of property recorded at estimated fair values at dates of acquisition. Cost of depreciable plant retired is eliminated from utility plant accounts and such costs are charged against accumu- lated depreciation. Maintenance of utility plant is charged primarily to operation expenses. Interest is capitalized on plant expenditures during the construction period and amounted to $1,473,000 in 2002, $858,000 in 2001, and $703,000 in 2000.\nIntangible assets acquired as part of water systems purchased are stated at amounts as pre- scribed by the Commissions. All other intangibles have been recorded at cost and are amortized over their useful life. Included in intangible assets is $6,515,000 paid to the City of Hawthorne in 1996 to lease the city’s water system and associated water rights.The asset is being amortized on a straight-line basis over the 15-year life of the lease.\nDepreciation Depreciation of utility plant for financial statement purposes is computed on the straight-line remaining life method at rates based on the estimated useful lives of the assets, ranging from 5 to\nCALIFORNIA WATER SERVICE GROUP\n41\n2 \nSUMMARY OF SIGNIFICANT ACCOUNTING POLICIES"}]}
+{"image": "doclay/doclay_48472.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\nlfd. Nr. Land Straße Straße Projektbezeichnung Bauziel Dringlichkeit  41 BW B 010 Gingen-O Geislingen-M N 2/3 Vordringlicher Bedarf  42 BW B 010 Geislingen-M Geislingen-O N 2 Weiterer Bedarf mit Planungsrecht  43 BW B 010 OU Amstetten N 2 Vordringlicher Bedarf  44 BW B 010 OU Urspring N 2 Vordringlicher Bedarf  45 BW B 010 Süßen-O Gingen-O N 3/4 Laufend und fest disponiert  46 BW B 012 OU Großholzleute N 2 Vordringlicher Bedarf  47 BW B 014 Backnang-West Nellmersbach N 4+E 4 Vordringlicher Bedarf  48 BW B 014 OU Michelfeld N 2 Vordringlicher Bedarf  49 BW B 014 OU Oppenweiler N 2 Vordringlicher Bedarf  50 BW B 014 Rottweil Tuttlingen N 2 Vordringlicher Bedarf BW B 014 OU Spaichingen N 2 BW B 014 OU Rietheim- Weilheim N 2  51 BW B 014 OU Stockach N 2 Vordringlicher Bedarf  52 BW B 014 Backnang-West Nellmersbach (BA 1.1+1.2) N 4+E 4 Laufend und fest disponiert  53 BW B 014 B 019 Verlegung in Schwäbisch Hall N 4 Laufend und fest disponiert  54 BW B 019 B 298 OU Gaildorf (sö Abschnitt) N 2 Vordringlicher Bedarf  55 BW B 027 B 028 Tübingen (Bläsibad) B 28 (Schindhaubasistunnel) N 4 Vordringlicher Bedarf  56 BW B 027 Neukirch Balingen N 2 Vordringlicher Bedarf BW B 027 OU Neukirch N 2\n- Seite 7 von 100 -"}]}
+{"image": "doclay/doclay_41355.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "to prevent excess air pressure loss but not enough to hinder  movement of the cable. Pressure seals should be inspected  at regular intervals to determine that the retaining rings are  in place. If a retaining ring comes off, it may slide along the  cable and cause jamming of a pulley.  [Figure 2-74]\nControl surfaces should move a certain distance in either  direction from the neutral position. These movements must  be synchronized with the movement of the flight deck  controls. The flight control system must be adjusted (rigged)  to obtain these requirements. The tools for measuring surface  travel primarily include protractors, rigging fixtures, contour  templates, and rulers. These tools are used when rigging  flight control systems to assure that the desired travel has  been obtained. Generally speaking, the rigging consists of  the following:\nFairleads may be made from a nonmetallic material, such as  phenolic, or a metallic material, such as soft aluminum. The  fairlead completely encircles the cable where it passes through  holes in bulkheads or other metal parts. Fairleads are used to  guide cables in a straight line through or between structural  members of the aircraft. Fairleads should never deflect the  alignment of a cable more than 3° from a straight line.\nPressure seals are installed where cables (or rods) move  through pressure bulkheads. The seal grips tightly enough \n1.  Positioning the flight control system in neutral and  temporarily locking it there with rig pins or blocks;\n2.  Adjusting system cable tension and maintaining  rudder, elevator, and ailerons in the neutral position;  and\n3.  Adjusting the control stops to the aircraft manufacturer’s  specifications.\nFigure 2-73.  Pulley wear patterns. \nFigure 2-74.  Cable guides.\n2-44\nTravel Adjustment\nExcessive cable tension Pully wear from misalignment Pully too large for cable Cable misalignment Frozen bearing Normal condition\nGuard pin Pulley Bracket Solid fairlead Rubstrip Split fairlead Fairlead Control cable Bulkhead groove Bulkhead Air seal Retaining rings Pressurized Unpressurized"}]}
+{"image": "doclay/doclay_64393.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "(19)  United States \n(12)  Patent Application Publication  MUKHOPADHYAY \n(10)  Pub. No.: US 2002/0153319 Al \n( 43)  Pub. Date:  Oct. 24, 2002 \n(54)  METHOD AND APPARATUS FOR HIGH  EFFICIENCY REVERSE OSMOSIS  OPERATION \n(76)  Inventor:  DEBASISH MUKHOPADHYAY,  PALO ALTO, CA (US) \n( *)  Notice:  This is a publication of a continued pros- ecution application (CPA) filed under 37  CFR 1.53(d). \n(21)  Appl. No.:  09/243,237 \n(22)  Filed:  Feb. 2, 1999 \n(62)  Division of application No. 08/909,861, filed on Aug.  12, 1997, now patented. \n(51)  Int. Cl.7  .....................................................  BOID 61/00 \n(52)  U.S. Cl.  ............................................  210/652;  210/638 \n1111111111111111 IIIIII IIIII 11111 1111111111 1111111111 111111111111111 IIIII IIIIII IIII 11111111  US  20020153319Al \nCorrespondence Address:  R REAMS GOODLOE JR  10725 SE 256TH STREET  SUITE 3  KENT, WA 980316426 \nUnique ultrapure water produced by reverse osmosis equip› ment. The high purity or ultrapure water is characterized by  extremely low levels of Total Organic Carbon that are  achieved after a single pass reverse osmosis process step.  The feedwater to the reverse osmosis process is preferably  pretreated to remove hardness and non-hydroxide alkalinity  by simultaneous removal in a weak acid cation exchange  resin. The process includes ionization of sparingly ionizable  components, such as silica, by adjusting the pH up to about  10.5 or higher. The passage of boron, silica, and TOC is  therefore significantly reduced. Consequently, the high  purity water is produced with high recovery rates from the  entering feedwater. Therefore, a unique ultrapure water  product is provided that significantly reduces costs for  post-treatment in downstream polishing steps. \nRelated U.S. Application Data \nPublication Classification \n(57)  ABSTRACT \n10  RAW  WATER  Ca(OH)2  ..[47  r------------ ------------,  I  I  I  I  I  I  I  I  I  I  I  I  I  I  I  I  48  MEMBRANE  32  49  u  REJECT  V \n1111111111111111 IIIIII IIIII 11111 1111111111 1111111111 111111111111111 IIIII IIIIII IIII 11111111 "}]}
+{"image": "doclay/doclay_65662.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "of the first and second elongated connectors to the second and first adhesive-backed anchoring members forms an attached portion and a bridging portion for each individual elongated connector, wherein the average width of the bridging portion of each elongated connector is less than the average width of the attached portion. In embodiments of the two-component medical device disclosed, the bridging portions are substantially free of adhesive. In embodiments of the two-component medical device disclosed, the first and second adhesive-backed anchoring members are perforated in a direction generally perpendicular to their respective wound edges thereby facilitating removal of a portion of the device thereby reducing the size of the device or creating multiple devices.\nIn instances of the two-component medical device disclosed, the device contains embedded infection indicators useful for detecting the development of infection. In embodiments of the two-component medical device disclosed, the device is adapted for transdermal drug delivery. In embodiments of the two-component medical device disclosed, the device comprises an elastic tension indicator element. In instances of the two-component medical device disclosed, the one or more discontinuities comprise one or more punches. In embodiments of the two-component medical device disclosed, the first elongated component and the second elongated component, or elements thereof, are die cut from sheet stock. In embodiments of the two-component medical device disclosed, the first and second elongated components are interlaced. In embodiments of the two-component medical device disclosed, the first and second elongated components are mated in a keyhole arrangement. In embodiments of the two-component medical device disclosed, the width of the attached portions is constant.\nIn embodiments of the two-component medical device disclosed, at least the first and second adhesive-backed anchoring members are produced from colored or opaque stock. In embodiments of the two-component medical device disclosed, the discontinuities increase breathability of the material. In embodiments of the two-component medical device disclosed, the discontinuities facilitate transfer of sweat from the skin beneath the first and second adhesive-backed anchoring members when in use. In embodiments of the two-component medical device disclosed, the discontinuities results in elastic-like properties. In embodiments of the two-component medical device disclosed, the discontinuities are invisible to a user. In embodiments of the two-component medical device disclosed, the slices in adhesive-backed anchoring members create a plurality of adhering subdomains."}]}
+{"image": "doclay/doclay_69702.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Performance metrics\nzEDC to z15 zlib Program Flow for z/OS\nSoftware support\nOn-chip compression introduces the following system reporting changes:\nThe z/OS provided zlib library is statically linked into many IBM and ISV products and  remains functional. However, to get the best optimization for z15, some minor changes are  made to zlib.\nThe current zlib and the new zlib function on z14 and earlier servers and z15 hardware. It  functions with or without the z15 z/OS PTFs on z14 and earlier servers.\nSupport of the On-Chip Compression function is compatible with zEDC support and is  available in z/OS V2R1 or later for data compression and decompression. Support for data  recovery (decompression) in the case that zEDC or On-Chip Compression not available;  however, it is provided through software in z/OS V2R2, and V2R1 with the appropriate  program temporary fixes (PTFs). \nSoftware decompression is slow and can involve considerable processor resources.  Therefore, it is not recommended for production environments.\nA specific fix category that is named  IBM.Function.zEDC  identifies the fixes that enable or use  the zEDC and On-Chip Compression function.\nz/OS guests that run under z/VM V6.4 with PTFs and later can use the zEDC Express feature  and z15 On-Chip Compression.\nFor more information, see the Enhancements to z/VM 6.4 page of the IBM Systems website.\nIBM 31-bit and 64-bit SDK for z/OS Java Technology Edition, Version 7 Release 1 (5655-W43  and 5655-W44) (IBM SDK 7 for z/OS Java) now provides use of the zEDC Express feature  and Shared Memory Communications-Remote Direct Memory Access (SMC-R), which is  used by the 10GbE RoCE Express feature.\nFor more information about how to implement and use the IBM Z compression features, see  Reduce Storage Occupancy and Increase Operations Efficiency with IBM zEnterprise Data  Compression , SG24-8259 .\n506  IBM z15 (8561) Technical Guide\nGLYPH<SM590000> No RMF PCIE reporting for zEDC\nGLYPH<SM590000> Synchronous executions are not recorded (just an instruction invocation)\nGLYPH<SM590000> Asynchronous executions are recorded:\n– SMF30 information is captured for asynchronous usage\n– RMF EADM reporting is enhanced (RMF 74.10)\n– SAP utilization is updated to  include time spent compressing and decompressing"}]}
+{"image": "doclay/doclay_55236.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "MongoDB Documentation, Release 3.0.4\nThe privileges array lists the privileges that the appAdmin role specifies. This role has a single privilege that permits its actions ( \"insert\" , \"dbStats\" , \"collStats\" , \"compact\" , \"repairDatabase\" ) on all the collections in the myApp database excluding its system collections. See Specify a Database as Resource (page 418).\nThe roles array lists the roles, identified by the role names and databases, from which the role appAdmin inherits privileges.\nsystem.users Collection\nChanged in version 2.6.\nThe system.users collection in the admin database stores user authentication (page 320) and authorization (page 324) information. To manage data in this collection, MongoDB provides user management commands .\nThe documents in the system.users collection have the following schema:\nsystem.users Schema\n{ _id: <system defined id>, user: \"<name>\", db: \"<database>\", credentials: { <authentication credentials> }, roles: [ { role: \"<role name>\", db: \"<database>\" }, ... ], customData: <custom information> }\nEach system.users document has the following fields:\nadmin.system.users. user\nThe user (page 416) field is a string that identifies the user. A user exists in the context of a single logical database but can have access to other databases through roles specified in the roles (page 416) array.\nadmin.system.users. db\nThe db (page 416) field specifies the database associated with the user. The user’s privileges are not necessarily limited to this database. The user can have privileges in additional databases through the roles (page 416) array.\nadmin.system.users. credentials\nThe credentials (page 416) field contains the user’s authentication information. For users with externally stored authentication credentials, such as users that use Kerberos (page 372) or x.509 certificates for authentica- tion, the system.users document for that user does not contain the credentials (page 416) field.\nadmin.system.users. roles\nThe roles (page 416) array contains role documents that specify the roles granted to the user. The array contains both built-in roles (page 405) and user-defined role (page 325).\nA role document has the following syntax:\n{ role: \"<role name>\", db: \"<database>\" }\nA role document has the following fields:\nadmin.system.users.roles[n]. role\nThe name of a role. A role can be a built-in role (page 405) provided by MongoDB or a custom user-defined role (page 325).\nChapter 6. Security\n416"}]}
+{"image": "doclay/doclay_27509.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Figure 5 | Adding secondary optical elements to active beam-shaping OLEDs. a) The normalized brightness distribution along the evaluation line for forward (left) and sideward (right) emission are shown with and without additional optical elements placed on top of the OLED. The images on the projection screen obtained with a half sphere b) and prism c), respectively.\nUsing the above transformation, the beam shape can be predicted if the spectral information is provided either by simulation or the goniometer measurement, which is of great importance for further optimization. Using CIE2006 colour matching func- tions and a subsequent linear transformation to RGB-colour space, a displayable picture of the beam’s shape is achieved. 33, 34 In Fig. 4c a calculated image is compared to a photograph. Both the brightness distribution and the colour are well repro- duced. To prove the reliable reproduction of colours, OLEDs were build that emit green in the centre of the spot and red to the sides (cf. Fig. 4d). The brightness-colour distribution is still well reproduced. Further information on this transformation is given in the Supplementary Information (cf. Fig. S5 and S6).\nThere remains an influence on the shape of the beam that has not yet been discussed. In the considerations above, the OLED has been treated as a point source. This gives rise to question the limits in which this assumption is right. There are two general ways to investigate this behaviour: either the size of the OLED or its distance to the screen must be varied. In the following discussion, the ratio of the size of the pixel l$_{dia}$ and the distance d$_{scr}$ will be analysed, wherein the size denotes the length of the diagonal of the square pixel. This ratio will be referred to as the relative size S$_{rel}$ = l$_{dia}$ / d$_{scr}$ . For large values of S$_{rel}$ , rays emitted under various angles at different points of the source will hit the screen on the same spot, blurring the contrast. Experiments are carried out with beam-shaping OLEDs of l$_{dia}$ = 28 mm pixel size. Using shadow-masks, the pixel size could be varied stepwise at a constant distance to the screen of 105 mm. As expected, the resulting contrast increases with decreasing relative size, as shown in black in Fig. 4b. More surprising is the result for a constant pixel size of l$_{dia}$ = 24 mm. For relative sizes larger than 0.3 the values add nicely to the ones in black, but around 0.3 the curve is\n8\nNormalized brightness Angle [°] -80 -40 0 40 80 0 1 1 Normalized brightness Angle [°] -80 -40 0 40 80 0 a b c Referen ce Half-sph ere Prism x x y Half-sphere Prism y"}]}
+{"image": "doclay/doclay_11274.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "TABLE 9 Volume/Rate Analysis of Changes in Net Interest In come (teb) ($ millions)\n2002/2001 2001/2000 Increase (decrease) due to change in: Increase (decrease) due to change in: A verage Average Average Average For the year ended October 31 balance rate Total balance rate Total Assets Canadian Dollars Deposits with other banks 11 (47) (36) (5) (16) (21) Securities 169 (450) (281) 19 (115) (96) Loans Residential mortgages 273 (358) (85) 18 6 24 Non-residential mortgages 7 (11) (4) 1 (1) — Consumer instalment and other personal  34 (307) (273) 8 (58) (50) Credit card  19 6 25 19 1 20 Businesses and governments (27) (565) (592) 114 (95) 19 Total loans 306 (1,235) (929) 160 (147) 13 Other non-interest bearing assets — — Change in Canadian dollar interest income 486 (1,732) (1,246) 174 (278) (104) U.S. Dollar and Other Currencies Deposits with other banks (118) (236) (354) (114) (16) (130) Securities (241) (316) (557) (195) (138) (333) Loans Residential mortgages 40 (31) 9 66 (1) 65 Non-residential mortgages 24 (23) 1 23 (2) 21 Consumer instalment and other personal  104 (107) (3) 75 (14) 61 Credit card  1 (1) — 1 — 1 Businesses and governments (419) (1,333) (1,752) (68) (808) (876) Total loans (250) (1,495) (1,745) 97 (825) (728) Other non-interest bearing assets — — Change in U.S. dollar and other currencies interest income (609) (2,047) (2,656) (212) (979) (1,191) Total All Currencies Change in total interest income (123) (3,779) (3,902) (38) (1,257) (1,295) Liabilities Canadian Dollars Deposits Banks (16) (39) (55) (20) (4) (24) Businesses and governments 133 (1,075) (942) 2 (56) (54) Individuals 130 (433) (303) 28 (60) (32) Total deposits 247 (1,547) (1,300) 10 (120) (110) Subordinated debt and other interest bearing liabilities 73 (163) (90) 105 (115) (10) Other non-interest bearing liabilities — — Change in Canadian dollar interest expense 320 (1,710) (1,390) 115 (235) (120) U.S. Dollar and Other Currencies Deposits Banks (287) (426) (713) (296) (164) (460) Businesses and governments (82) (698) (780) (72) (603) (675) Individuals 77 (334) (257) 88 (86) 2 Total deposits (292) (1,458) (1,750) (280) (853) (1,133) Subordinated debt and other interest bearing liabilities (249) (807) (1,056) (37) (308) (345) Other non-interest bearing liabilities — — Change in U.S. dollar and other currencies interest expense (541) (2,265) (2,806) (317) (1,161) (1,478) Total All Currencies Change in total interest expense (221) (3,975) (4,196) (202) (1,396) (1,598) Change in total net interest income 98 196 294 164 139 303\nBMO FINANCIAL GROUP ANNUAL REPORT 2002 57"}]}
+{"image": "doclay/doclay_39983.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Europol Public Information\no Ensure proper cleaning of dust on top of the racks and the roof of the cold isles. The  cleaning also must include the area inside the racks (excluding any Europol equipment  installed) and the Data Centres floor. \no Once yearly visit of the Europol Data Centres (HQ, JWF13, DR and future sites). The  maintenance will be scheduled in agreement with Europol. \n• Corrective Maintenance \no All racks – Maintenance and Support of the existing racks, cabling and all their active  and passive components including their management tools. \no When a component fails, the tenderer is required to replace the component/device  with a component/device with equivalent characteristics that can be managed from  the existing management platform.\n• Data Centers and Satellite Equipment Room cleaning \n• Floors that needs to be polished to reduce the static charge; \n• under raised floors, but cables that may lay there may not be moved; \n• access doors of MERs and SERs inside and out including card readers; \n• all horizontal surfaces like window sills (SERs), energy meters (MERs) etc.; \n• removal of all visible dust in/from all racks, including top of rack; cable trays where  cables may not be moved; front and back doors; inside and outside of racks; reachable  side panels; bottom of rack; PDUs and cable managers; \n• Under raised floor: \no Vacuuming  o Under floor removal of dust \no o Under floor removal of dust  o Vacuuming cable ducts \no o Vacuuming cable ducts  o Vacuuming pedestals and (if present) stringers \no o Vacuuming pedestals and (if present) stringers \n• Above raised floor: \no Measure / report ESD value (1/50)  o Removal of dust \no o Removal of dust  o Removal of dust on cable ducts (mopping or vacuuming) \no o Removal of dust on cable ducts (mopping or vacuuming)  o Stripping with slightly alkaline stripping agent \no o Stripping with slightly alkaline stripping agent  o Flat mops with ESD cleaner \no o Flat mops with ESD cleaner  o Blocking with high speed single-disc machine \no o Blocking with high speed single-disc machine \nAt least the following activities need to take place: \nThe cleaning activities need to be ESD safe and include cleaning of at least: \nEuropol has the intention to have all MERs and SERs cleaned according to HEPA standards every year. \n Page 30 of 35 "}]}
+{"image": "doclay/doclay_65151.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "41 \n5,886,235 \n42 \nwherein  R 2  represents a substituted or unsubstituted  divalent hydrocarbon radical containing from 4 to 40  carbon atoms or greater,  W  represents a substituted or  unsubstituted monovalent hydrocarbon radical contain› ing from 1 to 18 carbon atoms or greater,  X\"  represents  an oxygen  (0)  atom, a substituted or unsubstituted  divalent nitrogen (N) atom-containing radical, a sub› stituted or unsubstituted divalent sulfur (S) atom-\nAs  used herein, the term \"substituted\" is contemplated to 65  include all permissible substituents of organic compounds  unless otherwise indicated. In a broad aspect, the permis-\nFor purposes of this invention, the term \"hydrocarbon\" is  contemplated to include all permissible compounds having  at least one hydrogen and one carbon atom. Such permis› sible compounds may also have one or more heteroatoms. In  a broad aspect, the permissible hydrocarbons include acyclic  (with or without heteroatoms) and cyclic, branched and  unbranched, carbocyclic and heterocyclic, aromatic and  nonaromatic organic compounds which can be substituted or  unsubstituted. \nAn alternate method of transferring acidity from the  reaction product fluid to an aqueous fraction is through the  intermediate use of a heterocyclic amine which has a fluo› rocarbon or silicone side chain of sufficient size that it is  immiscible in both the reaction product fluid and in the  aqueous fraction. The heterocyclic amine may first be con› tacted with the reaction product fluid where the acidity  present in the reaction product fluid will be transferred to the  nitrogen of the heterocyclic amine. This heterocyclic amine  layer may then be decanted or otherwise separated from the  reaction product fluid before contacting it with the aqueous  fraction where it again would exist as a separate phase. The  heterocyclic amine layer may then be returned to contact the  reaction product fluid. \nwherein  R  1  represents a substituted or unsubstituted  trivalent hydrocarbon radical containing from 4 to 40  carbon atoms or greater, each  X’  is the same or different  and represents an oxygen  (0)  atom, a substituted or  unsubstituted divalent nitrogen (N) atom-containing  radical, a substituted or unsubstituted divalent sulfur  (S)  atom-containing radical or a substituted or unsub› stituted divalent hydrocarbon radical containing from 2  to 40 carbon atoms or greater, provided at least one  X’  is other than a substituted or unsubstituted divalent  hydrocarbon radical containing from 2 to 40 carbon  atoms or greater and at least one  X’  is other than an  oxygen  (0)  atom, and each d is the same or different  and is a value of 0 or 1, provided that the normal  valencies of  R  1 ,  N’ and phosphorus  (P)  are satisfied; \n(ii) a diorganophosphorus ligand represented by the for› mula: It is to be understood that while it may be preferred to  employ only one free heterocyclic nitrogen compound at a  time in any given process, if desired, mixtures of two or  more different free heterocyclic nitrogen compounds may  also be employed in any given process. Moreover the  amount of such free heterocyclic nitrogen compounds  present during harsh conditions, e.g., the vaporization  procedure, need only be that minimum amount necessary to  furnish the basis for at least some minimization of such  catalyst deactivation as might be found to occur as a result  of carrying out an identical metal catalyzed liquid recycle  hydroformylation process under essentially the same  conditions, in the absence of any free heterocyclic nitrogen  compound during vaporization separation of the aldehyde  product. Amounts of such free heterocyclic nitrogen com› pounds ranging from about 0.01 up to about 10 weight  percent, or higher if desired, based on the total weight of the  reaction product fluid to be distilled should be sufficient for  most purposes. \n1.  A  process for separating one or more phosphorus acidic  compounds from a reaction product fluid containing said one  or more phosphorus acidic compounds, a metal› organophosphorus ligand complex catalyst and optionally  free organophosphorus ligand which process comprises  treating said reaction product fluid with water sufficient to  remove at least some amount of said one or more phospho- rus acidic compounds from said reaction product fluid,  wherein said reaction product fluid comprises an organic  phase and said water comprises a separate aqueous or water  phase, and wherein said metal-organophosphorus ligand  complex catalyst comprises a Group 8, 9 or 10 metal  complexed with an organophosphorus ligand selected from  the following: \nThus the possibility of metal catalyst deactivation due to  such harsh conditions is said to be minimized or prevented  by carrying out such distillation of the desired product from  the metal-organopolyphosphorus catalyst containing reac› tion product fluids in the added presence of a free hetero› cyclic nitrogen compound having a five or six membered  heterocyclic ring consisting of 2 to 5 carbon atoms and from  2 to 3 nitrogen atoms, at least one of said nitrogen atoms  containing a double bond. Such free heterocyclic nitrogen  compounds may be selected from the class consisting of  diazole, triazole, diazine, and triazine compounds, such as,  e.g., benzimidazole or benzotriazole, and the like. The term  \"free\" as it applies to said heterocyclic nitrogen compounds  is employed therein to exclude any acid salts of such  heterocyclic nitrogen compounds, i.e., salt compounds  formed by the reaction of any phosphorus acidic compound  present in the reaction product fluid with such free hetero- cyclic nitrogen compounds as discussed herein above. \nWe claim: \nsible substituents include acyclic and cyclic, branched and  unbranched, carbocyclic and heterocyclic, aromatic and  nonaromatic substituents of organic compounds. Illustrative  substituents include, for example, alkyl, alkyloxy, aryl,  aryloxy, hydroxy, hydroxyalkyl, amino, aminoalkyl, halo› gen and the like in which the number of carbons can range  from 1 to about 20 or more, preferably from 1 to about 12.  The permissible substituents can be one or more and the  same or different for appropriate organic compounds. This  invention is not intended to be limited in any manner by the  permissible substituents of organic compounds. \nintermediate rhodium species that was formed during vapor› ization separation as mentioned above, thereby reforming  the active catalyst in the hydroformylation reactor. \n(i) a monoorganophosphorus ligand represented by the  formula: \n"}]}
+{"image": "doclay/doclay_13562.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Before\nAfter (Refurbished by Ergonomics Design)\nPT. Badak NGL (a subsidiary of PERTAMINA) is operating one of the largest LNG production complexes in the world – eight LNG trains with associated utility and offsite facilities. The first four trains (Trains-A/B & C/D) were commissioned in 1977 and 1983 respectively, and were being mon- itored and controlled by panel-mounted electrical controllers using 1970’s technology. To enhance the reliability, operability, and maintainability of those four trains, an entire revamp/upgrade of the control, safety and the electrical system was done by Chiyoda.\nThrough this DCS Retrofit Project, PT. Badak’s existing drawings have been up-dated, which enhances the maintainability and reliability of those four trains.\nThree of the remaining four trains were also constructed in late 1980’s and 1990’s by Chiyoda with the latest monitoring and control technologies (DCS). As a result of this DCS Retrofit Project, PT. Badak operates all of eight LNG trains under fully automated technologies with high reliability.\nPT. Badak operates 365 days a year to produce and supply LNG to Japan, Korea, and Taiwan.\nChiyoda will continue to support PERTAMINA and PT. Badak, and contribute to Japanese and East Asian energy security through its activities.\nDCS Retrofit & Instrumentation Upgrade for Bontang LNG Trains in Indonesia\nMizushima LNG Receiving Terminal \nChiyoda was awarded a full-turnkey contract for the Mizushima LNG Receiving Terminal from Mizushima LNG Company Limited, which was jointly established by Chugoku Electric Power Co., Inc., and Nippon Oil Corporation. \nThe scope of work for the project includes removing existing tanks within the premises of Mizushima Refinery and installing one above-ground PC LNG tank with a capacity of 160,000 kilo- liters, and receiving and transshipment facilities mainly for use at the Mizushima power plant of Chugoku Electric Power. Commercial operation is scheduled to commence in April 2006. The capacity of LNG handled will be 600,000 tpa. \nWe believe this new contract is in recognition of Chiyoda’s outstanding achievements and expe- rience in performing engineering, procurement and construction (EPC) for LNG terminals. \nIn 1969, Chiyoda constructed Japan’s first LNG receiving terminal for Tokyo Gas Co., Ltd. at Negishi in Yokohama Harbor. Since then, among all the 24 terminals constructed and operated by electric power companies and city gas companies in Japan, we have participated in engineering and construction of 12, fully half of all LNG terminals, which may account for our excellent reputa- tion. \nMizushima LNG Receiving Terminal. (bird’s eye view of 3D model)\n16EHE = Ss FEB\n"}]}
+{"image": "doclay/doclay_34866.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "11\n{ L J L ′ ℓ ′ ℓ$_{1}$ ℓ } ≈ ( − 1) L + J + ℓ $^{′}$− ℓ$_{1}$ √$_{2}$$_{ℓ}$$_{1}$ Π$_{L}$ ′ C L $^{′}$( ℓ $^{′}$− ℓ$_{1}$ ) L ( ℓ − ℓ$_{1}$ ) J ( ℓ ′ − ℓ ) ≈ ( − 1) J + ℓ + ℓ ′ √$_{2}$$_{ℓ}$$_{1}$ Π$_{J}$ C J ( ℓ − ℓ $^{′}$) L ( ℓ − ℓ$_{1}$ ) L ′ ( ℓ$_{1}$ − ℓ ′ $_{)}$. (A9)\n( A J N ℓℓ ′ ) l =0 ≈ 4 π ∫ k $^{2}$dk 2 π 2 P$_{0}$ ( k ) ∑ ℓ$_{1}$LL ′ ( − 1) ℓ + ℓ $^{′}$+ ℓ$_{1}$ + L + L ′ Π$_{LL}$ ′ √$_{2}$$_{ℓ}$$_{1}$ Π$_{J}$ β$_{ℓ}$$_{1}$$_{ℓ}$ β ∗ ℓ$_{1}$ℓ ′ C J ( ℓ − ℓ $^{′}$) L ( ℓ − ℓ$_{1}$ ) L ′ ( ℓ$_{1}$ − ℓ ′ ) { ˜ Δ L ℓ$_{1}$ℓ ⊗ ˜ Δ L ′ ℓ$_{1}$ℓ ′ } $_{J N}$. (A10)\nfunction as given in equation (9.9.1) from [48]\nUsing the above relation, the asymptotic limit to the BipoSH coefficients turn out to be\nAppendix B: Generalized evolution equation for statistical isotropy breakdown\nStarting with equation (29), putting P$_{ℓ}$ ( ˆ k · ˆ n ) = 4 π 2 ℓ +1 ∑ m Y ∗ $_{ℓm}$( ˆ k ) Y$_{ℓm}$ (ˆ n ) and evaluating the double integral using the equation\nthe most general evolution equation becomes\n∫ d Ω$_{ˆ}$ $_{n}$Y$_{ℓm}$ (ˆ n ) Y$_{ℓ}$$_{1}$$_{m}$$_{1}$ (ˆ n ) Y$_{ℓ}$$_{2}$$_{m}$$_{2}$ (ˆ n ) ∗ = 1 √$_{4}$$_{π}$ Π$_{ℓℓ}$$_{1}$ Π$_{ℓ}$$_{2}$ C ℓ$_{2}$ 0 ℓ 0 ℓ$_{1}$ 0 C ℓ$_{2}$m$_{2}$ ℓmℓ$_{1}$$_{m$_{1}$}$, (B1)\n˜ Δ LM ℓ$_{1}$$_{ℓ$_{2}$}$( k, τ ) = 1 β$_{ℓ}$$_{1}$$_{ℓ}$$_{2}$ ∑ ℓ ( − i ) ℓ Π 2 ℓ j$_{ℓ}$ ( k Δ τ ) ∑ ℓ$_{3}$ ℓ$_{4}$L ′ M ′ β$_{ℓ}$$_{3}$$_{ℓ}$$_{4}$ ˜ Δ L $^{′}$M ′ ℓ$_{3}$ℓ$_{4}$ ( k, τ$_{s}$ ) Π$_{ℓ}$$_{1}$$_{ℓ}$$_{4}$ Π$_{ℓ}$$_{2}$$_{ℓ}$$_{3}$ C g , (B2)\nC g = C ℓ$_{3}$ 0 ℓ 0 ℓ$_{1}$ 0 C ℓ$_{2}$ 0 ℓ 0 ℓ$_{4}$ 0 ∑ m$_{1}$m$_{2}$ C LM ℓ$_{1}$m$_{1}$ℓ$_{2}$m$_{2}$ ∑ m$_{3}$m$_{4}$ C L $^{′}$M ′ ℓ$_{3}$m$_{3}$ℓ$_{4}$m$_{4}$ ∑ m C ℓ$_{3}$m$_{3}$ ℓmℓ$_{1}$m$_{1}$ C ℓ$_{2}$m$_{2}$ ℓmℓ$_{4}$$_{m$_{4}$}$. (B3)\n∑ mm$_{1}$m$_{2}$m$_{3}$m$_{4}$ C L $^{′}$M ′ ℓ$_{3}$m$_{3}$ℓ$_{4}$m$_{4}$ C ℓ$_{3}$m$_{3}$ ℓ$_{1}$m$_{1}$ℓm C LM ℓ$_{1}$m$_{1}$ℓ$_{2}$m$_{2}$ C ℓ$_{2}$m$_{2}$ ℓmℓ$_{4}$m$_{4}$ = δ$_{L}$ ′ $_{L}$δ$_{M}$ ′ $_{M}$( − 1) ℓ$_{1}$ + ℓ + ℓ$_{4}$ + L $^{′}$Π$_{ℓ}$$_{2}$$_{ℓ}$$_{3}$ { ℓ$_{1}$ ℓ ℓ$_{3}$ ℓ$_{4}$ L ′ ℓ$_{2}$ } , (B4)\n˜ Δ LM ℓ$_{1}$$_{ℓ$_{2}$}$( k, τ ) = ∑ ℓℓ$_{3}$ℓ$_{4}$ ( − i ) ℓ Π$_{ℓℓℓ}$$_{1}$$_{ℓ}$$_{4}$ β$_{ℓ}$$_{3}$$_{ℓ}$$_{4}$ β$_{ℓ}$$_{1}$$_{ℓ}$$_{2}$ ( − 1) ℓ$_{3}$ + ℓ$_{4}$ + L j$_{ℓ}$ ( k Δ τ ) ˜ Δ LM ℓ$_{3}$ $_{ℓ$_{4}$}$( k, τ$_{s}$ ) C ℓ$_{3}$ 0 ℓ 0 ℓ$_{1}$ 0 C ℓ$_{2}$ 0 ℓ 0 ℓ$_{4}$ 0 { ℓ$_{1}$ ℓ ℓ$_{3}$ ℓ$_{4}$ L ℓ$_{2}$ } = ∑ ℓℓ$_{3}$ℓ$_{4}$ ( − i ) ℓ Π$_{ℓℓℓ}$$_{1}$$_{ℓ}$$_{4}$ β$_{ℓ}$$_{3}$$_{ℓ}$$_{4}$ β$_{ℓ}$$_{1}$$_{ℓ}$$_{2}$ ( − 1) ℓ$_{3}$ + ℓ$_{4}$ + L j$_{ℓ}$ ( k Δ τ ) ˜ Δ LM ℓ$_{3}$ $_{ℓ$_{4}$}$( k, τ$_{s}$ ) C ℓ$_{3}$ 0 ℓ 0 ℓ$_{1}$ 0 C ℓ$_{2}$ 0 ℓ 0 ℓ$_{4}$ 0 { ℓ$_{1}$ L ℓ$_{2}$ ℓ$_{4}$ ℓ ℓ$_{3}$ } . (B5)\nC ( L, ℓ, ℓ$_{1}$, ℓ$_{2}$ ) = ( − i ) ℓ Π$_{ℓℓℓ}$$_{1}$$_{ℓ}$$_{4}$ β$_{ℓ}$$_{3}$$_{ℓ}$$_{4}$ β$_{ℓ}$$_{1}$$_{ℓ}$$_{2}$ ( − 1) ℓ$_{3}$ + ℓ$_{4}$ + $^{L}$C ℓ$_{3}$ 0 ℓ 0 ℓ$_{1}$ 0 C ℓ$_{2}$ 0 ℓ 0 ℓ$_{4}$ 0 { ℓ$_{1}$ L ℓ$_{2}$ ℓ$_{4}$ ℓ ℓ$_{3}$ } , (B6)\n˜ Δ LM ℓ$_{1}$$_{ℓ$_{2}$}$( k, τ ) = ∑ ℓℓ$_{3}$ℓ$_{4}$ C ( L, ℓ, ℓ$_{1}$, ℓ$_{2}$ ) j$_{ℓ}$ ( k Δ τ ) ˜ Δ LM ℓ$_{3}$$_{ℓ$_{4}$}$( k, τ$_{s}$ ) . (B7)\nwhere\nUsing the summation formula for four Clebsch-Gordon coefficients given by equation (9.1.8) from [48],\nequation (B2) simplifies to\nSubstituting the multipole dependent coefficients as\nthe generalized evolution equation for deviations of statistical isotropy in the CMB brightness fluctuation reduces to"}]}
+{"image": "doclay/doclay_51602.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "On macOS and Linux\n1. Open up a terminal window.\n2. Download the  jenkinsci/blueocean  image and run it as a container in Docker using the following docker run  command:\ndocker run \\  -u root \\  --rm \\ ①  -d \\  ②  -p 8080:8080 \\  ③  -v jenkins-data:/var/jenkins_home \\  ④  -v /var/run/docker.sock:/var/run/docker.sock \\  jenkinsci/blueocean  ⑤\n① (  Optional  ) Automatically removes the Docker container (which is the instantiation of the jenkinsci/blueocean  image below) when it is shut down. This keeps things tidy if you need to quit Jenkins.\n② (  Optional  ) Runs the  jenkinsci/blueocean  container in the background (i.e. \"detached\" mode) and outputs the container ID. If you do not specify this option, then the running Docker log for this container is output in the terminal window.\n③ Makes (i.e. \"publishes\") port 8080 of the  jenkinsci/blueocean  container to port 8080 on the host machine. The 1st number represents the port on the host while the 2nd represents the container’s port. Therefore, if you specified  -p 49001:8080  for this option, you would be accessing Jenkins on your host machine through port 49001.\n④ Maps the  /var/jenkins_home  directory in the container to the Docker volume with the name jenkins-data . If this volume does not exist, then this  docker run  command will automatically create the volume for you.\nNotes:  This volume could also be created independently using the  docker volume create command:\n⑤ The  jenkinsci/blueocean  Docker image itself. If this image has not already been downloaded, then this  docker run  command will automtically download the image for you. Furthermore, if any updates to this image were published since you last ran this command, then running this command again will automatically download these published image updates for you. Note:  This Docker image could also be downloaded (or updated) independently using the docker pull  command:\ndocker pull jenkinsci/blueocean\ndocker volume create jenkins-data\nInstead of mapping the  /var/jenkins_home  directory to a Docker volume, you could also map this directory to one on your machine’s local file system. For example, specifying the option -v $HOME/jenkins:/var/jenkins_home  would map the container’s  /var/jenkins_home  directory to the  jenkins  subdirectory within the  $HOME  directory on your local machine, which would typically be  /Users/<your-username>/jenkins  or  /home/<your-username>/jenkins .\nNote:  If copying and pasting the command snippet above does not work, try copying and pasting this annotation-free version here:\n5"}]}
+{"image": "doclay/doclay_24724.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "m GLYPH<Equal> 0, c GLYPH<Equal> 1.87 m GLYPH<Equal> 0.46, c GLYPH<Equal> 1.59 m GLYPH<Equal> 0.86, c GLYPH<Equal> 1.32 m GLYPH<Equal> 1.32, c GLYPH<Equal> 1.04 0 2 4 6 8 10 Ρ 0 0.5 1 1.5 Ω$_{6}$\nFigure 4.2: Solutions for the ω$_{6}$ flow when ω$_{5}$ = 0 showing the dependence of the condensate on the quark mass\ngeometry a very interesting model to study other properties of QCD.\nWe now turn our attention to the presence of Goldstone bosons. Numerical solutions discussed in the last section have demonstrated that this system dynamically breaks the classical U (1)$_{A}$ symmetry by forming a quark con- densate. We first met Goldstone’s theorem [25] in chapter 1.2.8, and in that section we analysed the spontaneous breaking of the U (1)$_{L}$ × U (1)$_{R}$ sym- metry to U (1)$_{V}$ . We identified the η ′ (958) meson as the relevant Goldstone boson. However, matters were complicated by the presence of instantons, which made the η ′ (958) heavier than would otherwise be expected. Here, at large N, there are no instantons and so the equivalent η ′ meson should still be light.\nHenceforth we will describe the pseudo-Goldstone boson resulting from the spontaneous breaking of the U (1)$_{A}$ symmetry of this geometry as a pion.\n4.4 Pions and their Interactions\n67"}]}
+{"image": "doclay/doclay_60366.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "in the cab. The control valve allows you to open  and shut the tractor protection valve. The tractor  protection valve will close automatically if air  pressure is low (in the range of 20 to 45 psi). When  the tractor protection valve closes, it stops any air  from going out of the tractor. It also lets the air out  of the trailer emergency line. This causes the trailer  emergency brakes to come on, with possible loss  of control. (Emergency brakes are covered later.) \nEmergency lines are often coded with the color red  (red hose, red couplers, or other parts) to keep  from getting them mixed up with the blue service  line.\nThe trailer air supply control on newer vehicles is a  red eight-sided knob, which you use to control the  tractor protection valve. You push it in to supply the  trailer with air, and pull it out to shut the air off and  put on the trailer emergency brakes. The valve will  pop out (thus closing the tractor protection valve)  when the air pressure drops into the range of 20 to  45 psi. Tractor protection valve controls or  \"emergency\" valves on older vehicles may not  operate automatically. There may be a lever rather  than a knob. The \"normal\" position is used for  pulling a trailer. The \"emergency\" position is used  to shut the air off and put on the trailer emergency  brakes. \nEvery combination vehicle has two air lines, the  service line and the emergency line. They run  between each vehicle (tractor to trailer, trailer to  dolly, dolly to second trailer, etc.) \nService Air Line. The service line (also called the  control line or signal line) carries air, which is  controlled by the foot brake or the trailer hand  brake. Depending on how hard you press the foot  brake or hand valve, the pressure in the service  line will similarly change. The service line is  connected to relay valves. These valves allow the  trailer brakes to be applied more quickly than  would otherwise be possible. \nEmergency Air Line. The emergency line (also  called the supply line) has two purposes. First, it  supplies air to the trailer air tanks. Second, the  emergency line controls the emergency brakes on  combination vehicles. Loss of air pressure in the  emergency line causes the trailer emergency  brakes to come on. The pressure loss could be  caused by a trailer breaking loose, thus tearing  apart the emergency air hose. Or it could be  caused by a hose, metal tubing, or other part  breaking, letting the air out. When the emergency  line loses pressure, it also causes the tractor  protection valve to close (the air supply knob will  pop out). \nSome vehicles have \"dead end\" or dummy  couplers to which the hoses may be attached  when they are not in use. This will prevent water  and dirt from getting into the coupler and the air  lines. Use the dummy couplers when the air lines  are not connected to a trailer. If there are no  dummy couplers, the glad hands can sometimes  be locked together (depending on the couplings). It  is very important to keep the air supply clean. \nOlder trailers do not have spring brakes. If the air  supply in the trailer air tank has leaked away there  will be no emergency brakes, and the trailer  wheels will turn freely. If you crossed the air lines,  you could drive away but you wouldn't have trailer  brakes. This would be very dangerous. Always test  the trailer brakes before driving with the hand valve  or by pulling the air supply (tractor protection valve)  control. Pull gently against them in a low gear to  make sure the brakes work. \nIf you do cross the air lines, supply air will be sent  to the service line instead of going to charge the  trailer air tanks. Air will not be available to release  the trailer spring brakes (parking brakes). If the  spring brakes don't release when you push the  trailer air supply control, check the air line  connections. \nWhen coupling, make sure to couple the proper  glad hands together. To help avoid mistakes,  colors are sometimes used. Blue is used for the  service lines and red for the emergency (supply)  lines. Sometimes, metal tags are attached to the  lines with the words \"service\" and \"emergency\"  stamped on them. See Figure 6.6 \nGlad hands are coupling devices used to connect  the service and emergency air lines from the truck  or tractor to the trailer. The couplers have a rubber  seal, which prevents air from escaping. Clean the  couplers and rubber seals before a connection is  made. When connecting the glad hands, press the  two seals together with the couplers at a 90 degree  angle to each other. A turn of the glad hand  attached to the hose will join and lock the couplers. \n2005 Commercial Driver’s License Manual \n6.2.5 – Hose Couplers (Glad Hands) \n6.2.3 – Trailer Air Supply Control \n6.2.4 – Trailer Air Lines \nPage 6-5 \nSection 6 - Combination Vehicles "}]}
+{"image": "doclay/doclay_77035.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "30 of 101\nConstruction of Giresun Wastewater Treatment Plant  Tender Dossier Volume 3 Employer’s Requirements  Section 07: Mechanical Works\nElectric chain hoists shall be equipped with precision hoisting gear to allow accurate and sensitive lift- ing and lowering. Breaks to secure load in case of power failure. Supply has to include all electric ca- bling necessary for operation. All connections have to be equipped with vibration proof terminals. All  motors to be protected by means of thermistor protection. Limit switches for all final positions. \nLocal switch cabinet for each hoist equipped with pilot lamp, switches and an emergency cut-out for  all actuators. Limit of delivery is terminal block in the switch cabinet. Power supply for movable  bridges and lifting devices via trailing cable or trolley wire. \nThe body of electrical chain hoist shall be of aluminium die cast and minimum IP 55. \nThe electrical chain hoist shall have a counter –hour meter to show the hoist’s total on time and num- ber of lowering starts. \nThe electrical chain hoist shall have a chain container which is made of durable plastic or canvas. \nThe electrical chain hoist shall have motorized trolley fitted with drop stop and wheel climb preven- tion lugs (derailment). Rail manufactured as I-profile, corrosion protected according general  specification shall be used for trolley track. Gearboxes, wheels and motors to be maintenance free. \nTo ensure safety, the electric chain hoist shall be equipped with friction clutch and upper lower (limit)  switch. In addition to this electro mechanic or electromagnetic disk brake shall be in hoist for safety  operation. \nTo prevent the motor from burning out due to the excessive usage, a standard thermal protector is in- stalled in the motor. \n7.8.1.4. Overhead Travelling Cranes \nLongitudinaly and transversaly moveable, one or two beams due to static requirements, incl. electric  cable hoisting gear. \nRail manufactured as I-profile, corrosion protected according general specification. Two speed drive  for crane and trolley. Crane runway consisting of one or two beams (due to static requirement), incl.  all rails, mounting plates and fixing material, attachments for cabling etc. and stop blocks for limita- tion of movement. \nCrane bridge shall be distortion free and wheels of crane travel have to operate synchronously to avoid  twisting. Crane bridges constructed as maintenance free box beam. Gearboxes, wheels and motors to  be maintenance free. \nLifting with brake device with precision hoisting. Electric equipment integrated in trolley. \nControl: If not mentioned otherwise by movable suspension switch. \nPlug-in connection or wireless push button control with emergency stop switch for remote control  shall be provided. It shall contoured to comfortably fit into hand. The button has a light operating sen- sation which responds to fine adjustments in pressure. \n7_Vol3_d4 3_Section 7 mechanical works_en_GIR_rev6.docx "}]}
+{"image": "doclay/doclay_7984.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "page 116\nBombardier Inc. Annual Report 2003-04\nNOTE 18. SPECIAL ITEMS (CONT ’ D)\n19 I NCOME TAXES\nThe reconciliation of income taxes allocated to continuing operations computed at the Canadian statutory rates to income tax expense (recovery) was as follows for the years ended January 31:\nDetails of income tax expense (recovery) allocated to continuing operations were as follows for the years ended January 31:\nended January 31: SEVERANCE PROPERTY, AND OTHER PLANT AND INVOLUNTARY EQUIPMENT TERMINATION COSTS WRITE-DOWNS OTHER TOTAL Balance as at January 31, 2003 $ 148 $ – $ 21 $ 169 Current expense 285 211 34 530 Changes in estimates (5) – – (5) Non-cash items – (211) (2) (213) Purchase equation adjustment (54) – – (54) Cash paid (139) – (6) (145) Effect of foreign currency exchange rate changes 2 – 2 4 Balance as at January 31, 2004 $ 237 $ – $ 49 $ 286\nThe following table summarizes provisions for severance and other involuntary termination costs, write-downs and other costs for the years ended January 31:\n2004 2003 $ % $ % Income taxes expense (recovery) at statutory rates 3 33.6 (334) 35.9 Increase (decrease) resulting from: Manufacturing and processing credit (6) 42 Income tax rates differential of foreign investees (35) (31) Non-recognition of tax benefits related to foreign  investees’ losses and temporary differences 292 130 Write-down of deferred income tax assets 110 75 Recognition of previously unrecorded tax benefits (45) (26) Tax-exempt items (140) (145) Effect of substantively enacted income tax rate changes 6 (11) Large corporation tax 12 10 Other 8 69 Income tax expense (recovery) 205 (221)\n2004 2003 Current income taxes Canada $6 7 $9 5 Foreign 60 37 Recognition of previously unrecorded tax benefits – foreign (18) – 109 132 Deferred income taxes Temporary differences and operating losses carried forward 7 (391) Effect of substantively enacted income tax rate changes 6 (11) Write-down of deferred income tax assets 110 75 Recognition of previously unrecorded tax benefits (27) (26) 96 (353) Income tax expense (recovery) $ 205 $(221)"}]}
+{"image": "doclay/doclay_43885.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "D o w n w i n d h alf o f c i r c l e U p w i n d h a lf o f c i r c l e Wind Steepest bank Shallowest bank Shallower bank Steeper bank\n09 Takeoff leg (into the wind) 1 Final approach leg 5 Crosswind leg 2 Base leg 4 Downwind leg 3 Wind\nFigure 9-18.  A standard fixed-wing traffic pattern consists of left  turns, has five designated legs, and is flown at 1,000' AGL. \nFigure 9-17.  Turns around a point. \nTraffic Patterns\nCommon Errors \n9-17\ndrift and varying of the bank angle and wind correction angle  as required, entry into the maneuver may be from any point.  When entering this maneuver at any point, the radius of the  turn must be carefully selected, taking into account the wind  velocity and groundspeed so that an excessive bank is not  required later to maintain the proper ground track.\nA traffic pattern promotes safety by establishing a common  track to help pilots determine their landing order and provide  common reference. A traffic pattern is also useful to control  the flow of traffic, particularly at airports without operating  control towers. It affords a measure of safety, separation,  protection, and administrative control over arriving,  departing, and circling aircraft. Due to specialized operating  characteristics, airplanes and helicopters do not mix well  in the same traffic environment. At multiple-use airports,  regulation states that helicopters should always avoid the  flow of fixed-wing traffic. To do this, be familiar with the  patterns typically flown by airplanes. In addition, learn how  to fly these patterns in case air traffic control (ATC) requests  a fixed-wing traffic pattern be flown. Traffic patterns are  initially taught during the day. Traffic patterns at night may  need to be adjusted; for more information, refer to Chapter  12, Night Operations.\nthe wind. The closer the helicopter is to a direct downwind  heading at which the groundspeed is greatest, the steeper the  bank and the greater the rate of turn required to establish the  proper wind correction angle. The closer the helicopter is to  a direct upwind heading at which the groundspeed is least,  the shallower the bank and the lower the rate of turn required  to establish the proper wind correction angle. Therefore,  throughout the maneuver, the bank and rate of turn must  be varied gradually and in proportion to the groundspeed  corrections made for the wind.\nThe point selected for turns should be prominent and easily  distinguishable, yet small enough to present a precise  reference. Isolated trees, crossroads, or other similar small  landmarks are usually suitable. The point should be in an area  away from communities, livestock, or groups of people on  the ground to prevent possible annoyance or hazard to others.  Additionally, the area should be clear and suitable for any  emergency landings should they be required.\nJust as S-turns require that the helicopter be turned into the  wind in addition to varying the bank, so do turns around a  point. During the downwind half of the circle, the helicopter’s  nose must be progressively turned toward the inside of the  circle; during the upwind half, the nose must be progressively  turned toward the outside. The downwind half of the turn  around the point may be compared to the downwind side of  the S-turn, while the upwind half of the turn around a point  may be compared to the upwind side of the S-turn.\nUpon gaining experience in performing turns around a point  and developing a good understanding of the effects of wind \n1.  Faulty entry technique. \n2.  Poor planning, orientation, or division of attention.\n3.  Uncoordinated flight control application.\n4.  Improper correction for wind drift.\n5.  Failure to maintain selected altitude or airspeed.\n6. Failure to maintain an equal distance around the point. \n7.  Excessive bank angles."}]}
+{"image": "doclay/doclay_14829.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "MANAGEMENT'S  RESPONSIBILITY FOR FINANCIAL REPORTINGThe preparation and presentation of the consolidated financial statements of METRO INC. and the other financial  information contained in this Annual Report are the responsibility of management. This responsibility is based on a  judicious choice of appropriate accounting principles and policies, the application of which requires making estimates  and  informed judgements. It also includes ensuring that the financial information in the Annual Report is consistent with  the consolidated financial statements. The consolidated financial statements were prepared in accordance with  International Financial  Reporting  Standards and  were approved  by  the Board of Directors.\nMETRO INC. maintains accounting systems and internal controls over the financial reporting process which, in the  opinion of management, provide reasonable assurance regarding the accuracy ,  relevance and reliability of financial  information  and  the  well-ordered,  ef ficient  management  of the Corporation's affairs.\nThe  Board of Directors fulfills its duty to oversee management in the performance of its financial reporting responsibilities  and to review the consolidated financial statements and  Annual  Report, principally through its  Audit  Committee. This  Committee  is comprised solely of directors who are independent of the Corporation and is also responsible for making  recommendations  for the nomination of external auditors. Also, it holds periodic meetings with members of management  as  well as internal and external auditors to discuss internal controls, auditing matters and financial reporting issues. The  external  and internal auditors have access to the Committee without management. The Audit Committee has reviewed  the  consolidated financial statements and Annual Report of METRO INC. and recommended their approval to the Board  of  Directors.\nThe  enclosed consolidated financial statements were audited by Ernst & Young LLP and their report indicates the extent  of  their audit  and their  opinion on the  consolidated  financial  statements.\nDecember 12, 2014\nFrançois Thibault Senior  V ice-President, Chief  Financial  Of ficer and Treasurer\nEric  R. La Flèche  President  and  Chief  Executive Officer \n- 36 -"}]}
+{"image": "doclay/doclay_79948.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "등록특허 10-0680001전체 청구항 수 : 총 13 항\n본 발명은 고분자 전하 저장층을 이용한 유기 전계효과 트랜지스터 기반 비휘발성 유기물 트랜지스터 메모리 및 그 제조방 법에 관한 것이다.\n본 발명은 고농도 도핑된 n형 실리콘 반도체 위에 열 산화 방식에 의해 300nm 두께로 실리콘산화물(SiO$_{2}$) 게이트 절연층 을 형성하는 단계와; 상기 실리콘산화물 게이트 절연층 위에 절연체 성질을 띠면서도 전하를 저장할 수 있는 능력을 가진 고분자 전하 저장층(polymeric electret)을 30nm 정도의 두께로 코팅하는 단계와; 코팅된 고분자 전하 저장 절연층의 표 면 위에 유기반도체 물질을 증착하는 단계와; 증착된 유기 반도체 박막 위에 유기 전계효과 트랜지스터의 소스(Source)와 드레인(Drain) 전극을 증착하는 단계를 포함하는 것을 특징으로 하는 고분자 전하 저장층을 이용한 유기 전계효과 트랜지 스터 기반 비휘발성 유기물 트랜지스터 메모리 및 그 제조방법을 제공하고자 한 것이다.\n심사관 : 백양규\n(54) 고분자 전하 저장층을 이용한 유기 전계효과 트랜지스터기반 비휘발성 유기물 트랜지스터 메모리 및 그 제조방법\n(57) 요약\n대표도\n- 1 -\n(19)대한민국특허청(KR)\n(12) 등록특허공보(B1)\n(45) 공고일자 2007년02월08일\n(11) 등록번호 10-0680001\n(24) 등록일자 2007년02월01일\n(65) 공개번호\n(43) 공개일자\n(51) 。Int. Cl. H0 1 L2 1 /3 3 5(2006.01)\n(21) 출원번호 10-2006-0030799\n(22) 출원일자 2006년04월05일 심사청구일자 2006년04월05일\n(73) 특허권자 광주과학기술원 광주 북구 오룡동 1번지\n(72) 발명자 김동유 광주 북구 오룡동 1번지 광주과학기술원 신소재공학과\n(74) 대리인 백남훈 이학수\n(56) 선행기술조사문헌 KR1020050094737 A KR1020050112581 A * 심사관에 의하여 인용된 문헌\n백강준 광주 북구 오룡동 1번지 광주과학기술원 신소재공학과"}]}
+{"image": "doclay/doclay_47966.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "(3) For section 7 (measure of compensation in the case of severance) of the 1965 Act  substitute— \n“ 7.  In assessing the compensation to be paid by the acquiring authority under this Act  regard must be had not only to the extent (if any) to which the value of the land over which  the right is to be acquired is depreciated by the acquisition of the right, but also to the  damage (if any) to be sustained by the owner of the land by reason of its severance from  other land of the owner, or injuriously affecting that other land by the exercise of the  powers conferred by this or the special Act.” \n(4) The following provisions of the 1965 Act (which state the effect of a deed poll executed in  various circumstances where there is no conveyance by persons with interests in the land), that is  to say— \nare modified so as to secure that, as against persons with interests in the land which are expressed  to be overridden by the deed, the right which is to be compulsorily acquired is vested absolutely in  the acquiring authority. \n(5) Section 11( a ) (powers of entry) of the 1965 Act is modified so as to secure that, where the  acquiring authority has served notice to treat in respect of any right, as well as the notice of entry  required by subsection (1) of that section (as it applies to a compulsory acquisition under article  23(1)), it has power, exercisable in the equivalent circumstances and subject to the equivalent  conditions, to enter for the purpose of exercising that right; and sections 11A( b ) (powers of entry:  further notices of entry), 11B( c ) (counter-notice requiring possession to be taken on specified  date), 12( d ) (penalty for unauthorised entry) and 13( e ) (entry on warrant in the event of  obstruction) of the 1965 Act are modified correspondingly. \n(6) Section 20( f ) (protection for interests of tenants at will etc.) of the 1965 Act applies with the  modifications necessary to secure that persons with such interests in land as are mentioned in that  section are compensated in a manner corresponding to that in which they would be compensated  on a compulsory acquisition under this Order of that land, but taking into account only the extent  (if any) of such interference with such an interest as is actually caused, or likely to be caused, by  the exercise of the right in question. \n(7) Section 22 (interests omitted from purchase) of the 1965 Act (as modified by article 23(7)) is  modified so as to enable the acquiring authority, in circumstances corresponding to those referred  to in that section, to continue to be entitled to exercise the right acquired, subject to compliance  with that section as respects compensation. \n(8) For Schedule 2A to the 1965 Act substitute— \n(a) section 9(4) (failure by owners to convey); \n(b) paragraph 10(3) of Schedule 1 (owners under incapacity); \n(c) paragraph 2(3) of Schedule 2 (absent and untraced owners); and \n(d) paragraphs 2(3) and 7(2) of Schedule 4 (common land), \n( a ) Section 11 was amended by section 34(1) of, and Schedule 4 to, the Acquisition of Land Act 1981 (c. 67), section 3 of, and  Part 1 of Schedule 1 to, the Housing (Consequential Provisions) Act 1985 (c. 71), section 14 of, and paragraph 12(1) of  Schedule 5 to, the Church of England (Miscellaneous Provisions) Measure 2006 (No. 1), sections 186(2), 187(2) and 188  of, and paragraph 6 of Schedule 14 and paragraph 3 of Schedule 16 to, the Housing and Planning Act 2016 (c. 22) and S.I.  2009/1307. \n( b ) Section 11A was inserted by section 186(3) of the Housing and Planning Act 2016. \n( c )  Section 11B was inserted by section 187(2) of the Housing and Planning Act 2016. \n( d ) Section 12 was amended by section 56(2) of, and Part 1 of Schedule 9 to, the Courts Act 1971 (c. 23) and paragraph 4 of  Schedule 16 to the Housing and Planning Act 2016. \n( e )  Section 13 was amended by sections 62(3), 139(4) to (9) and 146 of, and paragraphs 27 and 28 of Schedule 13 and Part 3 of  Schedule 23 to, the Tribunals Courts and Enforcement Act 2007 (c. 15).\n( f )  Section 20 was amended by paragraph 4 of Schedule 15 to the Planning and Compensation Act 1991 (c. 34) and S.I.  2009/1307.\n89"}]}
+{"image": "doclay/doclay_18863.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "CHUNGHWA TELECOM CO., LTD. AND SUBSIDIARIES  CONSOLIDATED STATEMENTS OF INCOME \n(In Millions of New Taiwan or U.S. Dollars, Except Earnings Per Share that are in New Taiwan or U.S. Dollars) \nThe accompanying notes are an integral part of the consolidated financial statements.  (With Deloitte & Touche audit report dated March 17, 2011) \nYear Ended December 31 2008 2009 2010 Notes NT$ NT$ NT$ US$ (Note 3) BASIC EARNINGS PER SHARE 27 Before income tax $  6.03  $  5.79  $  5.82  $  0.20  After income tax 4.64  4.51  4.91  0.17  DILUTED EARNINGS PER SHARE 27 Before income tax $  6.02  $  5.77  $  5.80  $  0.20  After income tax 4.63  4.50  4.89  0.17  BASIC EARNINGS PER EQUIVALENT  ADS Before income tax $  60.30  $  57.96  $  58.20  $  2.00  After income tax 46.42  45.16  49.10  1.68  DILUTED EARNINGS PER  EQUIVALENT ADS Before income tax $  60.16  $  57.77  $  58.02  $  1.99  After income tax 46.31  45.01  48.95  1.68  BASIC WEIGHTED AVERAGE  SHARES OUTSTANDING  (THOUSANDS) 27 9,696,808  9,696,808  9,696,808  DILUTED WEIGHTED AVERAGE  SHARES OUTSTANDING  (THOUSANDS) 27 9,717,489  9,725,614  9,725,461  The accompanying notes are an integral part of the consolidated financial statements. \n(Concluded)\n(THOUSANDS) 27 9,717,489  9,725,614  The accompanying notes are an integral part of the consolidated financial statements.  (With Deloitte & Touche audit report dated March 17, 2011) \nF-5"}]}
+{"image": "doclay/doclay_53587.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Section 9.2.1, “Identifier Length Limits” Section 12.16, “Information Functions” Section 13.3.6, “LOCK TABLES and UNLOCK TABLES Statements” Section 8.2.2.4, “Optimizing Derived Tables, View References, and Common Table Expressions with Merging or Materialization” Section 6.2.2, “Privileges Provided by MySQL” Section 17.5.1.8, “Replication of CURRENT_USER()” Section 25.9, “Restrictions on Views” Section 13.7.7.13, “SHOW CREATE VIEW Statement” Section 13.3.3, “Statements That Cause an Implicit Commit” Chapter 25,  Stored Objects Section 26.3.48, “The INFORMATION_SCHEMA VIEWS Table” Section 25.5.3, “Updatable and Insertable Views” Section 25.5.2, “View Processing Algorithms” Section 25.5.1, “View Syntax”\nSection 13.2.12, “TABLE Statement” Section 13.2.14, “VALUES Statement”\n[index top]\nSection 13.5.3, “DEALLOCATE PREPARE Statement” Section 13.5.1, “PREPARE Statement” Section 13.5, “Prepared Statements” Section 25.8, “Restrictions on Stored Programs” Section 5.1.10, “Server Status Variables” Section 27.12.6.4, “The prepared_statements_instances Table”\nSection 13.1.17, “CREATE PROCEDURE and CREATE FUNCTION Statements” Section 13.6.3, “DECLARE Statement” Section 13.6.7.3, “GET DIAGNOSTICS Statement” Section 13.6.7.5, “SIGNAL Statement” Section 13.6.4, “Variables in Stored Programs”\nSection 13.6.7, “Condition Handling” Section 13.6.7.1, “DECLARE ... CONDITION Statement” Section 13.6.7.2, “DECLARE ... HANDLER Statement” Section 13.6.7.5, “SIGNAL Statement”\nSection 13.6.7, “Condition Handling” Section 13.6.7.1, “DECLARE ... CONDITION Statement” Section 13.6.7.2, “DECLARE ... HANDLER Statement” Section 13.6.7.5, “SIGNAL Statement”\nSection 13.1.10, “ALTER TABLESPACE Statement”\n5915\nDEFAULT ENCRYPTION\nDECLARE ... HANDLER\nDECLARE ... CONDITION\nDECLARE\nDEALLOCATE PREPARE\nCREATE VIEW ... SELECT\nD"}]}
+{"image": "doclay/doclay_43680.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Supercharger.  An engine- or exhaust-driven air compressor  used to provide additional pressure to the induction air so the  engine can produce additional power. \nSubsonic.  Speed below the speed of sound. \nStandard atmosphere.  At sea level, the standard atmosphere  consists of a barometric pressure of 29.92 inches of mercury  (\"Hg) or 1013.2 millibars, and a temperature of 15 °C (59  °F).  Pressure and temperature normally decrease as altitude  increases. The standard lapse rate in the lower atmosphere for  each 1,000 feet of altitude is approximately 1 \"Hg and 2 °C  (3.5 °F). For example, the standard pressure and temperature  at 3,000 feet mean sea level (MSL) is 26.92 \"Hg (29.92 – 3)  and 9 °C (15  °C – 6  °C). \nSupersonic.  Speed above the speed of sound. \nSupplemental Type Certificate (STC).  A certificate  authorizing an alteration to an airframe, engine, or component  that has been granted an Approved Type Certificate. \nStandard day.  See standard atmosphere. \nStandard empty weight (GAMA).  This weight consists of  the airframe, engines, and all items of operating equipment  that have fixed locations and are permanently installed in the  airplane; including fixed ballast, hydraulic fluid, unusable  fuel, and full engine oil. \nSwept wing.  A wing planform in which the tips of the wing  are farther back than the wing root. \nTailwheel aircraft.  See conventional landing gear. \nTakeoff roll (ground roll).  The total distance required for  an aircraft to become airborne. \nStandard weights.  These have been established for numerous  items involved in weight and balance computations. These  weights should not be used if actual weights are available. \nStandard-rate turn.  A turn at the rate of 3º per second which  enables the airplane to complete a 360º turn in 2 minutes. \nTarget reverser.  A thrust reverser in a jet engine in which  clamshell doors swivel from the stowed position at the  engine tailpipe to block all of the outflow and redirect some  component of the thrust forward. \nTaxiway lights.  Omnidirectional lights that outline the edges  of the taxiway and are blue in color. \nStarter/generator.  A combined unit used on turbine engines.  The device acts as a starter for rotating the engine, and after  running, internal circuits are shifted to convert the device  into a generator. \nStatic stability.  The initial tendency an aircraft displays  when disturbed from a state of equilibrium. \nTaxiway turnoff lights.  Flush lights which emit a steady  green color. \nTetrahedron.  A large, triangular-shaped, kite-like object  installed near the runway. Tetrahedrons are mounted on a  pivot and are free to swing with the wind to show the pilot  the direction of the wind as an aid in takeoffs and landings. \nStation.  A location in the airplane that is identified by a  number designating its distance in inches from the datum.  The datum is, therefore, identified as station zero. An item  located at station +50 would have an arm of 50 inches. \nThrottle.  The valve in a carburetor or fuel control unit that  determines the amount of fuel-air mixture that is fed to the  engine. \nStick puller.  A device that applies aft pressure on the control  column when the airplane is approaching the maximum  operating speed. \nStick pusher.  A device that applies an abrupt and large  forward force on the control column when the airplane is  nearing an angle of attack where a stall could occur. \nThrust line.  An imaginary line passing through the center of  the propeller hub, perpendicular to the plane of the propeller  rotation. \nThrust reversers.  Devices which redirect the flow of jet  exhaust to reverse the direction of thrust. \nStick shaker.  An artificial stall warning device that vibrates  the control column. \nStress risers.  A scratch, groove, rivet hole, forging defect  or other structural discontinuity that causes a concentration  of stress. \nT\n G-16"}]}
+{"image": "doclay/doclay_30817.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Isomer Δ G [ $^{1}$C$_{4}$ ] a Next b Δ G [Next] c TS d Δ G [TS] e P[ $^{4}$C$_{1}$ ] f P[ $^{1}$C$_{4}$ ] g P[Next] h β -d- Glc 27.1 ± 0.3 $^{3O}$B 30.9 ± 0.2 (1.17,3.19) 45.9 ± 0.5 99.99(1) 0.002(1) 4.17(4) × 10 − 4 β -d- Gal 19.3 ± 0.2 $^{3}$S$_{1}$ 35.6 ± 0.2 (1.17,3.51) 39.7 ± 0.2 99.95(1) 0.051(1) 8.8(1) × 10 − 5 β -d- Man 13.1 ± 0.4 $^{O}$S$_{2}$ 32.9 ± 0.4 (1.17,2.66) 42.7 ± 0.5 99.58(1) 0.42(1) 1.41(3) × 10 − 4 β -d- All 12.5 ± 0.2 $^{3O}$B 21.8 ± 0.2 (1.22,3.19) 36.8 ± 0.3 99.31(1) 0.68(1) 9.23(1) × 10 − 3 β -d- Tal 11.9 ± 0.3 B$_{3O}$ 43.2 ± 0.1 (1.11,3.40) 46.8 ± 0.2 99.53(1) 0.47(1) 3.0(1) × 10 − 6 β -d- Gul 13.3 ± 0.3 $^{O}$S$_{2}$ 31.5 ± 0.4 (1.17,3.19) 45.9 ± 0.5 99.00(2) 0.99(1) 3.4(1) × 10 − 4 β -d- Alt 6.1 ± 0.1 $^{O}$S$_{2}$ 24.7 ± 0.1 (1.17,3.72) 43.8 ± 0.2 93.88(4) 6.12(4) 2.4(1) × 10 − 3 β -d- Ido 4.1 ± 0.3 B$_{25}$ 27.4 ± 0.2 (1.06,5.85) 44.9 ± 0.2 88.51(9) 11.5(2) 8.6(1) × 10 − 4 α -d- Glc 16.2 ± 0.2 $^{1}$S$_{3}$ − $^{14}$B 35.1 ± 0.2 (1.22,2.66) 42.5 ± 0.2 99.88(1) 0.124(1) 8.6(1) × 10 − 5 α -d- Gal 14.5 ± 0.2 $^{1}$S$_{3}$ 44.7 ± 0.2 (1.22,3.19) 48.5 ± 0.4 99.58(1) 0.416(5) 4.0(1) × 10 − 6 α -d- Man 6.5 ± 0.2 $^{O}$S$_{2}$ 22.8 ± 0.1 (1.11,3.19) 32.3 ± 0.3 95.72(3) 4.27(5) 6.0(1) × 10 − 3 α -d- All 8.1 ± 0.2 B$_{3O}$ − $^{1}$S$_{3}$ 27.1 ± 0.2 (1.17,3.40) 38.9 ± 0.2 97.92(2) 2.08(3) 8.7(1) × 10 − 4 α -d- Tal 6.8 ± 0.1 $^{O}$S$_{2}$ 33.7 ± 0.2 (1.65,4.47) 52.5 ± 0.2 91.60(6) 8.40(6) 1.7(1) × 10 − 4 α -d- Gul 4.2 ± 0.2 $^{O}$S$_{2}$ 30.3 ± 0.2 (1.49,3.94) 49.2 ± 0.3 90.44(7) 9.6(1) 1.2(1) × 10 − 4 α -d- Alt 2.8 ± 0.3 B$_{3O}$ 15.0 ± 0.2 (1.06,3.72) 28.9 ± 0.2 79.2(1) 20.7(2) 8.74(1) × 10 − 2 α -d- Ido 1.1 ± 0.2 $^{O}$S$_{2}$ − $^{14}$B 20.6 ± 0.2 (1.11,5.53) 31.6 ± 0.2 51.8(3) 48.2(2) 1.38(1) × 10 − 2 Energies are expressed in kJ/mol, and probabilities in percent; a Free energy of $^{1}$C ; b Next most\nEnergies are expressed in kJ/mol, and probabilities in percent; a Free energy of $^{1}$C 4 ; b Next most populated conformer after $^{4}$C 1 and $^{1}$C 4 ; c Free energy of the next most populated conformer; d Location of the transition state ( θ , φ ); e Free energy of the transition state ; f Population of $^{4}$C 1 (%); g Population of $^{1}$C 4 (%); h Population of the next most populated conformer. When a basin is present, which encompasses many states, all conformers involved are listed.\nTABLE V: Free energy and population of different conformers using the new parameter set."}]}
+{"image": "doclay/doclay_4036.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "EP 3 800 018 A1\nANHANG ZUM EUROPAISCHEN RECHERCHENBERICHT UBER DIE EUROPAISCHE PATENTANMELDUNG NR.\nEP 19 20 0966\nIn diesem Anhang sind die Mitglieder der Patentfamilien der im obengenannten europäischen Recherchenbericht angeführten Patentdokumente angegeben.\nDie Angaben über die Familienmitglieder entsprechen dem Stand der Datei des Europäischen Patentamts am Diese Angaben dienen nur zur Unterrichtung und erfolgen ohne Gewähr.\n17-04-2020\n5\n10\n15\n20\n25\n30\n35\n40\n45\n50\n55\nEPO FORM P0461\nFür nähere Einzelheiten zu diesem Anhang : siehe Amtsblatt des Europäischen Patentamts, Nr.12/82\n9\nIm Recherchenbericht Datum der Mitglied(er) der Datum der angeführtes Patentdokument Veröffentlichung Patentfamilie Veröffentlichung CN 106142145 A 23-11-2016 KEINE 2013109375 02-05-2013 2016088482 24-03-2016 2019159034 23-05-2019 2013063507 02-05-2013 DE 102015108506 01-12-2016 EP 3106261 21-12-2016 US 2016346950 01-12-2016"}]}
+{"image": "doclay/doclay_33620.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "15\nfactor analogous to Eq. (11) (but for a gluon attaching at the p$_{2}$ -spectator) on the right side of the cut, giving an overall factor of i ( − i ) = +1. So, combined with Eq. (36) the relevant factor from extra gluon attachments is again 4 π $^{2}$δ ( l + 1 ) δ ( l − 2 ).\nitly, one can use Eqs. (36) (extracting the overall fac- tor of i ( − i ) = 1 that comes with the two spectator at- tachments) to explicitly calculate the contribution from graphs with gluons on opposite sides of the cut:\nSumming all graphs of the type shown in Fig. 8, there- fore, results in just a single integral. To check it explic-\nHere we have dropped the irrelevant factors of (2 E$_{3(4)}$ ), λ$_{1(2)}$ , and (2 π ) 6 which appeared in Eq. (4). We have also dropped the l$_{1}$ and l$_{2}$ dependence inside the factor in braces. This is permitted because the δ -functions will set l + 1 and l − 2 to zero, and because the other components yield power suppressed corrections. The δ -functions can be used to evaluate the k + 1 , k − 1 , k + 2 , k − 2 , l + 1 , l − 2 and k$_{2}$$_{T}$ integrals, and the l − 1 and l + 2 integrals can be evaluated by contour integration. The result is\nThe factor H ( k$_{1}$, k$_{3}$, k$_{4}$ ) is now the hard part in Eq. (6). The symbol “ · · · ” in the denominators refers to terms that involve only x$_{1}$ , x$_{2}$ and masses. For graphs with both gluons on the same side of the cut, exactly the same result (with the same overall sign) is obtained by using Eq. (35) and taking into account the overall factor of i 2 = − 1 that comes from the two spectator attachments. There are, again, identical results coming from the Her- mitian conjugate graphs.\nThe integral in Eq. (38) is not generally zero as can be checked by considering a fixed q ≡ k$_{3}$$_{T}$ + k$_{4}$$_{T}$ . How- ever, there is no corresponding factorization anomaly term contained in an expansion of Eq. (32) up to or- der g 2 in the Wilson lines. The modified Wilson lines in the TMD PDFs of the generalized TMD-factorization formula are specified by the factorization anomaly terms that arise when gluons are radiated from just one hadron at a time, as in Sect. IV. However, the resulting general- ized TMD-factorization formula is in contradiction with\ngraphs like Fig. 8, where there are simultaneously glu- ons radiated from H$_{1}$ and H$_{2}$ . Thus, generalized TMD- factorization breaks down at the two-gluon level.\nIndeed, at up to two gluons, the generalized TMD- factorization formula Eq. (32) gives no contribution to a DSA beyond what is predicted by the standard TMD- factorization formula Eq. (24). The only factorization anomaly contribution from Eq. (32) is to the unpolar- ized cross section, and arises from graphs with both extra gluons radiated from the same hadron. There must be at least one gluon coming from each hadron at the same time to have spin dependence in both hadrons simulta- neously. So, the only contribution to a double Sivers effect that violates standard TMD-factorization is from the sum of graphs in Fig. 8, and these are not accounted for in Eq. (32). To recover the factorization anomaly in the DSA, one would have to somehow allow each TMD PDF to have a non-vanishing factorization anomaly con- tribution at the level of one extra gluon. This, however,\nC. Together\n2 T 2 $_{F}$( N 2 c − 1) g 4 2 s ∫ d $^{4}$k$_{1}$ (2 π ) 4 ∫ d $^{4}$k$_{2}$ (2 π ) 4 ∫ d $^{4}$l$_{1}$ (2 π ) 4 ∫ d $^{4}$l$_{2}$ (2 π ) $_{4}$(2 π ) $^{4}$δ$^{4}$( k$_{1}$ + k$_{2}$ − k$_{3}$ − k$_{4}$ )(2 π ) $^{2}$δ ( l + 1 ) δ ( l − 2 ) × × { λ ′ 1 $^{2}$λ ′ 2 $_{2}$( k$_{1}$ + k$_{3}$ ) · ( k$_{2}$ + k$_{4}$ ) ( k$_{1}$ − k$_{3}$ ) 2 − M 2 X } 2 2 ϵ$_{jk}$s j $_{1}$l k $_{1}$p + 1 ( m$_{H}$$_{1}$ (1 − x$_{1}$ ) + m$_{ψ}$$_{1}$ ) [ l 2 1 + iϵ ][( k$_{1}$ − l$_{1}$ ) 2 − m 2 q$_{1}$ + iϵ ][( p$_{1}$ − k$_{1}$ + l$_{1}$ ) 2 − m 2 ψ$_{1}$ + iϵ ][ k 2 − m 2 q$_{2}$ + iϵ ] × × 2 ϵ$_{j}$ ′ k ′ s j ′ 2 l k ′ 2 p − 2 ( m$_{H}$$_{2}$ (1 − x$_{2}$ ) + m$_{ψ}$$_{2}$ ) [ l 2 − iϵ ][( k$_{2}$ − l$_{2}$ ) 2 − m 2 q$_{2}$ − iϵ ][( p$_{2}$ − k$_{2}$ + l$_{2}$ ) 2 − m 2 ψ$_{2}$ − iϵ ][ k 2 1 − m 2 q$_{1}$ − iϵ ] (2 π ) $^{2}$δ (( p$_{1}$ − k$_{1}$ ) $^{2}$− m 2 $_{ψ$_{1}$}$) δ (( p$_{2}$ − k$_{2}$ ) $^{2}$− m 2 $_{ψ$_{2}$}$) . (37)\nT 2 $_{F}$( N 2 c − 1) g 4 s ∫ d $^{2}$k$_{1}$$_{T}$ (2 π ) 2 ∫ d $^{2}$l$_{1}$$_{T}$ (2 π ) 2 ∫ d $^{2}$l$_{2}$$_{T}$ (2 π ) 2 H ( k$_{1}$, k$_{3}$, k$_{4}$ ) × × [ ϵ$_{jk}$s j $_{1}$l k $_{1}$( m$_{H}$$_{1}$ (1 − x$_{1}$ ) + m$_{ψ}$$_{1}$ )][ ϵ$_{j}$ ′ k ′ s j ′ 2 l k ′ 2 ( m$_{H}$$_{2}$ (1 − x$_{2}$ ) + m$_{ψ}$$_{2}$ )] l 2 1 $_{T}$l 2 $_{T}$[ k 2 1 T + · · · ][( l$_{1}$$_{T}$ − k$_{1}$$_{T}$ ) 2 + · · · ][( k$_{3}$$_{T}$ + k$_{4}$$_{T}$ − k$_{1}$$_{T}$ ) 2 + · · · ][( l$_{2}$$_{T}$ − k$_{3}$$_{T}$ − k$_{4}$$_{T}$ + k$_{1}$$_{T}$ ) 2 + · · · ] . (38)"}]}
+{"image": "doclay/doclay_77117.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Title here\nTECHNICAL  REPORT\naute irure dolor in reprehenderit in voluptate velit esse cillum dolore eu fugiat nulla pariatur. Excepteur sint  occaecat cupidatat non proident, sunt in culpa qui officia deserunt mollit anim id est laborum. \nTable 5. Example of a more complex table \nAuthor, year  Country  Season  Study population  No. of included  cases  Age group  (years)  Outcome measure  Results  Europe  Forster, 2004  Germany  1999–2001  Paediatric patients of  paediatric practices  and referral children’s  hospitals in 4 cities in  Germany  54 outpatients 77 inpatients < 3  Proportion of outpatients with:  • Croup  • Bronchiolitis  Bronchitis • Pneumonia Proportion of inpatients with:  • Croup  • Bronchiolitis  Bronchitis  • Pneumonia  • Apnoea  4.2%  2.7%  5.5%  5.1%  Montes, 2005  Spain  2001–2004  Children who were  hospitalised for more  than 24h with  confirmed influenza  virus infection in  three regions of  Spain  49 children < 5  Proportion of cases with:  • Bronchiolitis Pneumonia • Bronchitis • Croup  ARI • Febrile syndrome with only  minor respiratory symptoms  (rhinorrhea, cough)  24.5%  18.4%  6.1%  2.0%  26.5%  22.4%  Other Western countries  Krief, 2009  US  1998–2001  Infants in five  different paediatric  emergency  departments  123 infants < 60 days of  age  Proportion of cases with:  • Urinary tract infections  • Wheezing  Bronchiolitis  • Lobar pneumonia  2.4%  1.6%  6.5%  2.8%  Poehling 2006  US  2002–2004  Patients of hospitals  in two US counties  160 hospitalised  cases < 5  Proportion of cases with:  • Otitis media  Pneumonia  • Seizures  28%  6% 1%\nDolor sit amet, consectetur adipisicing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut  enim ad minim veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea commodo consequat. Duis  aute irure dolor in reprehenderit in voluptate velit esse cillum dolore eu fugiat nulla pariatur. Excepteur sint  occaecat cupidatat non proident, sunt in culpa qui officia deserunt mollit anim id est laborum. \nDolor sit amet, consectetur adipisicing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut  enim ad minim veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea commodo consequat. Duis  aute irure dolor in reprehenderit in voluptate velit esse cillum dolore eu fugiat nulla pariatur. Excepteur sint  occaecat cupidatat non proident, sunt in culpa qui officia deserunt mollit anim id est laborum. \nShnipsum \n4 "}]}
+{"image": "doclay/doclay_62698.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Jan.  28,  2021 \n4 \nUS 2021/0026244 Al \n[0050]  Note that the monomer unit (A) is preferably a  structural unit that is derived from a fluoroalkyl ester of  a-chloroacrylic acid from a viewpoint of further improving  main chain scission properties of the copolymer upon irra› diation with extreme ultraviolet light. Furthermore, among  structural units derived from fluoroalkyl esters of a-chloro› acrylic acid, a structural unit that is derived from 2,2,3,3,3- pentafluoropropyl a-chloroacrylate is more preferable as the  monomer unit (A). When the monomer unit (A) is a struc› tural unit that is derived from 2,2,3,3,3-pentafluoropropyl  a-chloroacrylate, the sensitivity of a resist film to extreme  ultraviolet light can be especially increased. \n[0051]  Monomer Unit (B) \n[0052]  The monomer unit (B) is a structural unit that is  derived from a monomer (b) represented by general formula  (IV), shown below. \n[0059]  On the other hand, from a viewpoint of further  increasing the sensitivity of a resist film to extreme ultra› violet light, the plurality of R 2  and/or R 3  groups that are  present in general formula (II) and general formula (IV)  preferably include a fluorine atom or a fluorine atom› substituted alkyl group, and more preferably include a  fluorine atom or a fluorine atom-substituted alkyl group  having a carbon number of not less than 1 and not more than  5. \n[0060]  In particular, from a viewpoint of ensuring ease of  production of the copolymer while also further increasing  the sensitivity of a resist film to extreme ultraviolet light, it  is preferable that, in general formula (II) and general for› mula (IV), p is 5, q is 0, and the five R 2  groups include a  fluorine atom or a fluorine atom-substituted alkyl group,  more preferable that one of the five R  $^{2 }$groups is a fluorine  atom or a fluorine atom-substituted alkyl group and the  remaining four R 2  groups are hydrogen atoms, and even  more preferable that one of the five R  $^{2 }$groups is a fluorine  atom and the remaining four R $^{2 }$groups are hydrogen atoms. \n[0061]  Examples of the monomer (b) represented by the  previously described general formula (IV) that can form the  monomer unit (B) represented by the previously described  general formula (II) include, but are not specifically limited  to, a-methylstyrene (AMS) and derivatives thereof such as  (b-1) to (b-11), shown below. Of these examples, a-meth› ylstyrene and 4-fluoro-a-methylstyrene, which is in accor› dance with general formula (b-2), are preferable as the  monomer (b ). \n[0053]  (In general formula (IV), R 2 , R 3 , p, and q are the  same as in general formula (II).) \n[0054]  The proportion constituted by the monomer unit  (B) among all monomer units of the copolymer is not  specifically limited but can, for example, be set as not less  than 30 mo!  % and not more than 70 mo! %. \n[0055]  Examples of fluorine atom-substituted alkyl groups  that can constitute R 2  or R 3  in general formula (II) and  general formula (IV) include, but are not specifically limited  to, groups having a structure in which all or some of the  hydrogen atoms of an alkyl group are replaced by fluorine  atoms. \n[0056]  Examples of unsubstituted alkyl groups that can  constitute R 2  or R 3  in general formula (II) and general  formula (IV) include, but are not specifically limited to,  unsubstituted alkyl groups having a carbon number of not  less than 1 and not more than 5. Of such alkyl groups, a  methyl group or an ethyl group is preferable as an unsub› stituted alkyl group that can constitute R 2  or R 3 . \n[0057]  From a viewpoint of improving the ease of pro› duction of the copolymer, the plurality of R 2  and/or R 3  groups that are present in general formula (II) and general  formula (IV) are each preferably a hydrogen atom or an  unsubstituted alkyl group, more preferably a hydrogen atom  or an unsubstituted alkyl group having a carbon number of  not less than 1 and not more than 5, and even more  preferably a hydrogen atom. \n[0058]  Note that in general formula (II) and general for› mula (IV), from a viewpoint of improving the ease of  production of the copolymer, it is preferable that pis 5, q is  0, and the five R 2  groups are each a hydrogen atom or an  unsubstituted alkyl group, more preferable that the five R 2  groups are each a hydrogen atom or an unsubstituted alkyl  group having a carbon number of not less than 1 and not  more than 5, and even more preferable that the five R 2  groups are each a hydrogen atom. \n0  (b-1) \n0  F  (b-2) \nl  QF  (b-3) \nl  F~F  (b-4) \n(IV)  CH3 H  I  I  C=C  0 1  H  f--.:::-’f.  (R$^{2}$)p  (OR\\ "}]}
+{"image": "doclay/doclay_156.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "54\nThe following table presents certain unaudited quarterly financial information for each of the past 12 quarters. In the opinion of the Company’s  management, this information has been prepared on the same basis as the consolidated financial statements appearing elsewhere in this report  and includes all adjustments (consisting only of normal recurring accruals) necessary to present fairly the financial results set forth herein.  Results of operations for any previous quarter are not necessarily indicative of results for any future period.\nOn January 5, 2004, the Company finalized the acquisition of Paoli Inc., a subsidiary of Klaussner Furniture Industries, Inc. Paoli is a leading  provider of wood case goods and seating, with well-known brands, broad product offering, and strong independent representative sales and  dealer networks. Further details of the transaction will be included in the Company’s SEC Quarterly Report on Form 10-Q for the first quarter  ended April 3, 2004.\nSubsequent Acquisition\nSummary of Quarterly Results of Operations (Unaudited)\nFirst  Second  Third  Fourth (In thousands, except per share data) Quarter  Quarter  Quarter  Quarter YEAR-END 2003:  Net sales  $ 391,971  $ 406,793  $ 500,091  $ 456,873 Cost of products sold  252,841  260,367  316,412   286,893 Gross profit  139,130  146,426  183,679  169,980 Selling and administrative expenses  114,426  112,979  127,472  125,867 Restructuring-related charges (income)  –  2,265  3,881  2,364 Operating income  24,704  31,182  52,326  41,749 Interest income (expense) – net  (265)  (149)  617  767 Income before income taxes  24,439  31,033  52,943  42,516 Income taxes  8,554  10,861  18,530  14,881 Net income  $ 15,885  $  20,172  $ 34,413  $  27,635 Net income per common share – basic  $  .27  $  .35  $  .59  $  .47 Weighted-average common shares outstanding – basic  58,317  58,143  58,043  58,222 Net income per common share – diluted  $  .27  $  .35  $  .59  $  .47 Weighted-average common shares outstanding – diluted  58,582  58,468  58,448  58,731 As a Percentage of Net Sales Net sales  100.0%  100.0%  100.0%  100.0% Gross profit  35.5  36.0  36.7  37.2 Selling and administrative expenses  29.2  27.8  25.5  27.5 Restructuring-related charges  –  0.6  0.8  0.5 Operating income  6.3  7.7  10.5  9.1 Income taxes  2.2  2.7  3.7  3.3 Net income  4.1  5.0  6.9  6.0 YEAR-END 2002:  Net sales  $ 399,139  $ 399,299  $ 446,274  $  447,910 Cost of products sold  259,398  256,696  285,996  290,653 Gross profit  139,741  142,603  160,278  157,257 Selling and administrative expenses  110,425  111,320  117,274  115,170 Restructuring-related charges (income)  3,900  (900)  –  – Operating income  25,416  32,183  43,004  42,087 Interest income (expense) – net  (580)  (710)  (577)  (269) Income before income taxes  24,836  31,473  42,427  41,818 Income taxes  8,941  11,330  15,274  13,649 Net income  $  15,895  $  20,143  $  27,153  $  28,169 Net income per common share – basic and diluted  $  .27  $  .34  $  .46  $  .48 Weighted-average common shares outstanding – basic  58,777  58,918  59,140  58,546 As a Percentage of Net Sales Net sales  100%  100%  100%  100% Gross profit  35.0  35.7  35.9  35.1 Selling and administrative expenses  27.7  27.9  26.3  25.7 Restructuring-related charges  1.0  (.2)  –  – Operating income  6.4  8.1  9.6  9.4 Income taxes  2.2  2.8  3.4  3.0 Net income  4.0  5.0  6.1  6.3\nH O N I N D U S T R I E S I n c . a n d S U B S I D I A R I E S"}]}
+{"image": "doclay/doclay_77382.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Work.  The amount of energy transferred by a force. \nWiring diagrams.  A diagram that shows the electrical wiring  and circuitry, coded for identification, of all the electrical  appliances and devices used on aircraft. \nZero fuel weight.  The weight of an aircraft without fuel. \nZone numbers.  On drawings, these are similar to the  numbers and letters printed on the borders of a map, used  for locating a particular point in the drawing. \nZ \nG-12 "}]}
+{"image": "doclay/doclay_13342.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "7 5\nSubordinated Indebtedness\nCredit Facilities*\nAutomotive Sector\nFord Motor Company Capital Trust II, a subsidiary trust (“Trust II”), has outstanding 6.50% Cumulative Convertible Trust Preferred  Securities with an aggregate liquidation preference of $5 billion (the “Trust II Preferred Securities”). The sole assets of Trust II are  $5.2 billion principal amount of 6.50% Junior Subordinated Debentures due 2032 of Ford Motor Company (the “Subordinated  Debentures”). At our option, we may redeem the Subordinated Debentures, in whole or in part, on or after January 15, 2007.  To the extent we redeem the Subordinated Debentures or upon the maturity of the Subordinated Debentures, Trust II is required \nDebentures”). At our option, we may redeem the Subordinated Debentures, in whole or in part, on or after January 15, 2007.  To the extent we redeem the Subordinated Debentures or upon the maturity of the Subordinated Debentures, Trust II is required  to redeem the Trust II Preferred Securities at $50 per share plus accrued and unpaid distributions. We guarantee the payment of  all distribution and other payments of the Trust II Preferred Securities to the extent not paid by Trust II, but only if and to the extent  we have made a payment of interest or principal on the Subordinated Debentures.\nAt December 31, 2004, the Automotive sector had $7.2 billion of contractually committed credit agreements with various banks, of  which $7.1 billion were available for use. Eighty percent of the total facilities are committed through June 30, 2009. Of the $7.2 billion, $6.9 billion constitute global credit facilities and may be used, at Ford’s option, by any of its direct or indirect majority- owned subsidiaries on a guaranteed basis. Ford also has the ability to transfer, on a non-guaranteed basis, $2.6 billion of such  global credit facilities to Ford Credit and $518 million to FCE Bank plc. (“FCE”), Ford Credit’s European operation. All of the global  credit facilities are free of material adverse change clauses and restrictive financial covenants (for example, debt-to-equity limitations,  minimum net worth requirements and credit rating triggers that would limit our ability to borrow).\nAutomotive and Financial Services debt as of December 31 was as follows (in millions):\nNOTES TO THE FINANCIAL STATEMENTS\nNOTE 15. DEBT AND COMMITMENTS\nAutomotive  Financial Services  Weighted Weighted Average Average Rate a/ Amount Rate a/ Amount 2004 2003 2004 2003 2004 2003 2004 2003 Debt payable within one year Short-term $ 270 $  608 $ 1,868 $ 1,238 Commercial paper - - 23,303 17,295 Other short-term 9,389 9,234 Total short-term debt 8.6% 5.3% 270 608 2.8% 2.1% 34,560 27,767 Long-term payable within one year Senior indebtedness 707 510 30,896 30,480 Subordinated indebtedness - - - 688 - - - - Total debt payable within one year 977 1,806 65,456 58,247 Long-term debt Senior indebtedness Notes and bank debt 7.4% 7.3% 12,303 13,832 4.1% 4.3% 88,328 99,987 Unamortized discount - - (89) (66) Total senior indebtedness 12,303 13,832 88,239 99,921 Subordinated indebtedness 6.5% 6.5% 5,155 5,155 9.4% 9.4% 843 843 Total long-term debt 17,458 18,987 89,082 100,764 Total debt $ 18,435 $ 20,793 $ 154,538 $ 159,011 Fair value b/ $ 18,301 $ 20,120 $ 156,967 $ 162,635 Maturity There- Average 2005 2006 2007 2008 2009 After (Years) Long-term debt maturities  Automotive $  707 $  538 $  422 $  335 $  157 $ 16,006 25 Financial Services 30,896 24,444 20,105 7,759 14,139 22,635 4\na/ Includes the effect of interest rate swaps.\nb/ Based on quoted market prices or current rates for similar debt with the same remaining maturities."}]}
+{"image": "doclay/doclay_63748.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "173 \nUS 9,958,775 B2 \n174 \n-continued \nQ  C(D~  0  #  0  -o-~  II  0 \n[Chem.101] \n(z54) \n(z55) \n-continued \nOD  ¢o  C  ~  D-HYO  0  0  0  0  F  -o-~  ~  I  ~  ~/N  u\" t  T  t  ’11  ¢o  F  F  0  0  F  0  s  0  (z58)  (z59)  (z60)  (z61) \n(z56)  (z57) "}]}
+{"image": "doclay/doclay_4288.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "US 9,164,380 B2 \n49 \n50 \n-continued \n-continued \n(al-4-6)  Ra  ~o  0  0  0  >  0  1G \n(al-4-7) 35  Ra  ~o  0  0  0  >  0 \n(al-4-8)  Ra  ~o  0  0  0  >  0  0 \n(al-4-9)  Ra  ~o  0  0  0  >  0  0 \n(al-4-10)  Ra  ~o  0 "}]}
+{"image": "doclay/doclay_53074.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "MongoDB Documentation, Release 3.0.4\nNew in version 2.6: rs.printSlaveReplicationInfo() . For previous versions, use db.printSlaveReplicationInfo() .\nUse the serverStatus as in the following operation, to return status of the replication:\ndb.serverStatus( { repl: 1 } )\nSee server status repl fields for documentation of the relevant section of output.\nWhen running with authorization enabled, in master - slave deployments configure a keyFile so that slave mongod instances can authenticate and communicate with the master mongod instance.\nTo enable authentication and configure the keyFile add the following option to your configuration file:\nkeyFile = /srv/mongodb/keyfile\nNote: You may chose to set these run-time configuration options using the --keyFile option on the command line.\nSetting keyFile enables authentication and specifies a key file for the mongod instances to use when authenticating to each other. The content of the key file is arbitrary but must be the same on all members of the deployment can connect to each other.\nThe key file must be less one kilobyte in size and may only contain characters in the base64 set. The key file must not have group or “world” permissions on UNIX systems. Use the following command to use the OpenSSL package to generate “random” content for use in a key file:\nopenssl rand -base64 741\nSecurity (page 317) for more information about security in MongoDB\nIf you want a replication configuration that resembles master - slave replication, using replica sets replica sets, con- sider the following replica configuration document. In this deployment hosts <master> and <slave> 18 provide replication that is roughly equivalent to a two-instance master-slave deployment:\nSee Replica Set Configuration (page 652) for more information about replica set configurations.\n18 In replica set configurations, the host field must hold a resolvable hostname.\n{ _id : 'setName', members : [ { _id : 0, host : \"<master>\", priority : 1 }, { _id : 1, host : \"<slave>\", priority : 0, votes : 0 } ] }\nDeploy Master-Slave Equivalent using Replica Sets\nOngoing Administration and Operation of Master-Slave Deployments\nSee also:\nSecurity\n598\nChapter 9. Replication"}]}
+{"image": "doclay/doclay_8133.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Capital One has everything it needs for  continued success. A winning strategy.  Strong values. Thriving businesses. Best-in-class products and first-rate service. Solid financials.  A powerful brand identity. Significant market opportunities—and the vision, the passion and the people to make the most of them."}]}
+{"image": "doclay/doclay_29506.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "[14] S. Y. Tong, G. Xu, W. Y. Hu, and M. W. Puga, J. Vac. Sci. Technol. B 3 , 1076 (1985).\n[15] K. Shiraishi, H. Tamura, and H. Takayanagi, Appl. Phys. Lett. 78 , 3702 (2001).\n[16] D. Xiao, J. Shi, and Q. Niu, Phys. Rev. Lett. 95 , 137204 (2005).\n[17] Z. Wang and P. Zhang, Phys. Rev. B 76 , 064406 (2007).\n[18] Z. Wang, P. Zhang, and J. Shi, Phys. Rev. B 76 , 094406 (2007).\n[19] M.-C. Chang and Q. Niu, Phys. Rev. B 53 , 7010 (1996).\n[20] G. Sundaram and Q. Niu, Phys. Rev. B 59 , 14915 (1999).\n[21] D. Xiao, Y. Yao, Z. Fang, and Q. Niu, Phys. Rev. Lett. 97 , 026603 (2006).\n[22] T. Thonhauser, D. Ceresoli, D. Vanderbilt, and R. Resta, Phys. Rev. Lett. 95 , 137205 (2005).\n14"}]}
+{"image": "doclay/doclay_2030.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "using di ff erent values of coupling strengths for the scalar diquark and isoscaler vector terms. The EOS at intermediate densities are obtained using a Maxwell construction.\nWe find that the stability of the non-rotating hybrid stars isvery much sensitive to the EOSs for the colour superconducting quark matter and almost independent of the choice for the EOS for the nuclear matter. The stable configurations of the hybrid s tars exist only for the large enough value for the scalar diquark coupling strength. Though, the stability of the hybrid stars are not sensitive to the choice of the EOSs for the nuclear matter, but, compositions of the hybrid stars are at variance for these EOSs. If the EOS for the nuclear matter is sti ff , core of the hybrid star is composed of colour superconducting quark matter which is either in the 2SC or the CFL phase. In the later case, CFL quark matter core is surrounded by a thin layer of the 2SC quark matter and the outer layer composed of nuclear matter .\nThe stability of the rotating hybrid star is sensitive to the choice of the EOS for the nuclear matter as well as that for the colour superconducting quark matter. In particular, we find that the values of the critical rotation frequency vary from about 350 Hz to 1275 Hz depending upon the choice of the EOSs for the nuclear matter and the colour superconducting quark matter. Our results also indicate that the EOSs for the colour superconducting quark matter obtained within the NJL model may be adjusted for the various nuclear matter EOSs in such a way that it yields (a) the maximum mass in the non-rotating limit larger than 1 . 44 $^{M}$⊙ which is the most accurately measured value for the maximum mass of a compact star and (b) the maximum allowed rotation frequency is larger than the current observational limit of 716 Hz.\nFinally, we would like to mention that our present study can be extended in several ways. The quark matter in the crystalline color superconducting phase, expected to appear at the intermediate densities, should also be considered. One might also include the contributions from the hyperons which would soften the hadronic EOS. The phase transition from hadron to the quark matter should proceed via mixed phase which can be constructed using the Gibbs conditions.\n9"}]}
+{"image": "doclay/doclay_11199.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "47\nFujitsu Kansai Digital Technology Ltd. [Osaka] 100% Fujitsu CAD Tech Ltd. [Tochigi] 100% Fujitsu Capital Ltd. [Tokyo] 100% Fujitsu Kyushu Communication Systems Ltd. [Fukuoka] 100% Fujitsu Kyushu Digital Technology Ltd. [Fukuoka] 100% Fujitsu Kochi Systems Engineering Ltd. [Kochi] 100% Fujitsu Kobe Engineering Ltd. [Kobe] 100% Fujitsu Computer Technology Ltd. [Yokohama] 100% Fujitsu System LSI Ltd. [Tokyo] 100% Fujitsu Shizuoka Engineering Ltd. [Shizuoka] 100% Fujitsu Information Network Systems Ltd. [Tokyo] 100% Fujitsu Software Engineering Laboratory Ltd. [Kanagawa] 100% Fujitsu Chugoku Communication Systems Ltd. [Hiroshima] 100% Fujitsu Defense Systems Engineering Ltd. [Kawasaki] 71% Fujitsu Tohoku Communication Systems Ltd. [Sendai] 100% Fujitsu Tohoku Digital Technology Ltd. [Sendai] 100% Fujitsu Tokki Systems Ltd. [Kawasaki] 100% Fujitsu Nagoya Communication Systems Ltd. [Nagoya] 100% Fujitsu Niigata Systems Ltd. [Niigata] 100% Fujitsu Personal Computer Systems Ltd. [Kawasaki] 100% Fujitsu Personal Computer Laboratory Ltd. [Nagano] 100% Fujitsu PAREX Ltd. [Tokyo] 70% Fujitsu Program Laboratories Ltd. [Kawasaki] 100% Fujitsu Hokuriku Communication Systems Ltd. [Ishikawa] 100% Fujitsu Hokkaido Communication Systems Ltd. [Sapporo] 100% Fujitsu Hokkaido Digital Technology Ltd. [Sapporo] 100% Fujitsu Minami-Kyushu Systems Engineering Ltd. [Kumamoto] 70% Fujitsu Refre Ltd. [Kawasaki] 100% Fujitsu Wakayama Systems Engineering Ltd. [Wakayama] 100% Yonago Fujitsu Ltd. [Tottori] 100% YFC Ltd. [Yokohama] 90% Fujitsu Facilities Engineering Ltd. [Fukushima] 100% Fujitsu Tottori Systems Engineering Ltd. [Tottori] 100% Fujitsu Higashi-Hokkaido Systems Engineering Ltd. [Hokkaido] 100% Fujitsu Yamaguchi Information Ltd. [Yamaguchi] 80% Fujitsu Kagawa Systems Engineering Ltd. [Kagawa] 100% Shiga Fujitsu Software Ltd. [Shiga] 60% Fujitsu Shikoku Infortec Ltd. [Kagawa] 100% Fujitsu Mobile Telecommunication Ltd. [Tokyo] 100% Care Net Ltd. [Kawasaki] 100% Two-One Ltd. [Kanagawa] 57% Fujitsu Institute of Management Ltd. [Tokyo] 100% Fujitsu Analysis Laboratory Ltd. [Kawasaki] 100% Fujitsu Techno Research Ltd. [Kawasaki] 100%\nIwaki Electronics Co., Ltd. [Fukushima] 100% Shinano Fujitsu Ltd. [Nagano] 100% Totalizator Engineering Ltd. [Tokyo] 100% Tochigi Fujitsu Ten Ltd. [Tochigi] 100% Fujitsu Advanced Communication Systems Ltd. [Kawasaki] 100% Kyusyu FHP Ltd. [Miyazaki] 100%\nTeamWare Group Holding Oy [Helsinki]  FINLAND 100% Fujitsu France S. A. [Rungis Cedex]  FRANCE 100% Fujitsu Microelectronics Europe GmbH  [Dreieich-Buchschlag]  GERMANY 100% Fujitsu Telecom Deutschland GmbH  [Dreieich-Buchschlag]  GERMANY 100% Fujitsu Deutschland GmbH [Munich]  GERMANY 100% Shinko Microelectronics Ireland Ltd. [Dublin]  IRELAND 100% Fujitsu Italia S.p.A. [Milano] ITALY 100% Fujitsu Microelectronics Italia S.r.l. [Milano]  ITALY 100% Fujitsu International Finance (Netherlands) B.V.  [Amsterdam]  NETHERLANDS 100% Fujitsu Telecommunications Technology of the CIS, LLC  [Moscow]  RUSSIA 60% Fujitsu ICL España, S.A. [Madrid]  SPAIN 100% Fujitsu Nordic AB [Sollentuna]  SWEDEN 100% Fujitsu Europe Ltd. [Middlesex]  U.K.  100% Fujitsu Finance (U.K.) PLC [Middlesex]  U.K.  100% Fujitsu Europe Telecom R&D Centre Ltd. [Middlesex]  U.K.  100% ICL PLC [London]  U.K.  100% Fujitsu Telecommunications Europe Ltd. [Birmingham]  U.K.  100% Fujitsu European Centre for Information Technology Ltd.  [Middlesex]  U.K.  100% Fujitsu Computers (Europe) Ltd. [Berkshire]  U.K.  100%\nFujitsu do Brasil Ltda. [San Paulo]  BRAZIL 100% Fujitsu Canada, Inc. [Ontario]  CANADA 100% Fujitsu America, Inc. [San Jose (CA)]  U.S.A. 100% Amdahl Corporation [Sunnyvale (CA)]  U.S.A. 100% DMR Consulting Group, Inc. (Amdahl Group Company)  [Edison (NJ)]  U.S.A. 100% Fujitsu Microelectronics, Inc. [San Jose (CA)]  U.S.A. 100% Fujitsu Systems Business of America, Inc.  [Santa Clara (CA)]  U.S.A. 100% Fujitsu Computer Packaging Technologies, Inc.  [San Jose (CA)]  U.S.A. 100% Fujitsu Software Corporation [San Jose (CA)]  U.S.A. 100% HAL Computer Systems, Inc. [Campbell (CA)]  U.S.A. 100%\nTHE AMERICAS\nEUROPE"}]}
+{"image": "doclay/doclay_68401.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "5.6 High insert batch workload measurements\n5.6.1 Archive sequential insert\n180  IBM Db2 12 for z/OS Performance Topics\nGLYPH<SM590000> For PTS tables spaces, the CPU time improved by 14% when inserting to the empty  tables, and by 15% when inserting into the populated tables. \nGLYPH<SM590000> For PBR table spaces, the CPU time improved by 22% when inserting to the empty tables,  and by 18% when inserting into populated tables.\nGLYPH<SM590000> For PBG table spaces, the CPU time is improved by 11% when inserting into empty tables,  and by 8% when inserting into the populated tables. \nGLYPH<SM590000> A two-way data sharing group with 100 concurrent threads\nGLYPH<SM590000> Multi-row (100) insert and committing after each rowset insert\nGLYPH<SM590000> A total of 10 partitions for PTS and PBR table spaces\nGLYPH<SM590000> Three tables and six non-unique indexes\nGLYPH<SM590000> Member cluster (MC) and row level locking (RLL)\nGLYPH<SM590000> Three types of tables spaces: Classic partitioned table spaces (PTS), partition-by-growth  (PBG) table spaces, and partition-by-range (PBR) table spaces\nGLYPH<SM590000> Archive sequential insert\nGLYPH<SM590000> Journal table insert \nGLYPH<SM590000> Message queue insert and delete\nGLYPH<SM590000> Random insert and delete workload\nIn this section, we describe the results of several performance measurements that are related  to workloads with high insert rates for the following batch workload scenarios:\nThe measurements were conducted with Db2 11 and Db2 12 by using a two-way data sharing  environment, with operating System z/OS 2.2 and z13 hardware. The analysis focuses on  workload performance differences between Db2 11 and Db2 12.\nIn this scenario, sequential insert performance was evaluated running a workload that used  the following configuration:\nThe programs first insert data to the empty tables. Then, it delete two-thirds of the rows to  create “holes” in the pages. Finally, more rows are inserted into the populated tables.\nThe Db2 class 2 CPU time results (as shown in Figure 5-15 on page 181), demonstrate that  the use of Db2 12 can improve class 2 CPU time by up to 22%. Consider the following points:"}]}
+{"image": "doclay/doclay_23672.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Notes to the Consolidated Financial Statements For the year ended 30 June 2011\nNotes to the Consolidated Financial Statements For the year ended 30 June 2011\n20. KEY MANAGEMENT PERSONNEL DISCLOSURES - continued\n(iii)  Share holdings The numbers of shares in the company held during the financial year by directors and other key management personnel, \n(iii)  Share holdings The numbers of shares in the company held during the financial year by directors and other key management personnel,  including shares held by entities they control, are set out below:\nLoans to key management personnel  There were no loans outstanding at the reporting date to key management personnel and their related parties.\nLoans to key management personnel  There were no loans outstanding at the reporting date to key management personnel and their related parties.\n78\nBalance at  Received as  Options  Other  Balance at 30 June 2009  Remuneration  Exercised  Movements  30 June 2010 Directors Reginald Gillard 748,000  -  600,000  7,732  1,355,732 Mark Calderwood 4,000,000  -  -  (300,000)  3,700,000 Colin Carson  673,200 - - - 673,200 Rhett Brans 475,000 - - - 475,000 Neil Fearis 330,000 - - 7,732 337,732 Sean Harvey - - - 100,000 100,000 Michael Bohm - - - 20,000 20,000 Other key management personnel  Susmit Shah 269,500 - - - 269,500 Jeffrey Quartermaine - - - - - Grant Pierce - - - - - Kevin Thomson  -  -  525,000  (210,000)  315,000 Alexander Scott  -  -  300,000  (300,000)  -\nBalance at  Received as  Options  Other  Balance at 30 June 2010  Remuneration  Exercised  Movements  30 June 2011 Directors Reginald Gillard 1,372,232  -  -  (400,000)  972,232 Mark Calderwood 3,700,000  -  1,200,000  (300,000)  4,600,000 Colin Carson 673,200  -  540,000  (710,000)  503,200 Rhett Brans  475,000  -  1,000,000  (25,000)  1,450,000 Neil Fearis  337,732  -  400,000  (260,000)  477,732 Sean Harvey 100,000 - - - 100,000 Michael Bohm 20,000 - - - 20,000 Other key management personnel Susmit Shah 269,500 - - - 269,500 Jeffrey Quartermaine - - - - - Grant Pierce - - - - - Kevin Thomson 315,000 - - - 315,000WEST AFRICA’S NEWEST LARGE GOLD PRODUCER"}]}
+{"image": "doclay/doclay_22936.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Cleaning Soil, Water & Air\nEnergizing Lithium Demand\n9\nFMC Corporation | 2010 Annual Report\na micro-crystalline cellulose  excipient that revolutionizes the  roller-compaction process for  hard tablets – a major advance  for pharmaceutical production. \nIn our Lithium business, our  focus is on the booming  energy storage market.  Lithium-ion batteries are the  preferred means to power  electronic devices and are  growing rapidly for power tools,  e-bikes and automobiles. FMC  developed Stabilized Lithium  Metal Powder (SLMP TM ), which  is a safe-to-handle powdered  lithium metal that increases  the energy density and life of  lithium-ion batteries. In 2010,  FMC began a program with the  U.S. Department of Energy to  scale up SLMP development at \nour lithium research laboratories  in Bessemer City, North Carolina.\nOur Industrial Chemicals  business is pursuing promising  environmental applications  spanning air, soil and water  treatment. We anticipate  significant growth in these  markets in the coming years  and see opportunities to  broaden our technology  platform through targeted  acquisitions of complementary  and/or adjacent technologies.\nIn Peroxygens, we developed  and demonstrated a novel  process using hydrogen  peroxide to treat wastewater at  a leading Canadian oil sands  operation. VigorOx ®  WWT,  an environmentally friendly \ndisinfectant, was successfully  commercialized in both the  United States and Canada,  offering wastewater treatment  plants an alternative to the  use of chlorine. Additionally,  we completed successful  demonstration trials in 2010  for an innovative technology,  licensed from NASA, using  hydrogen peroxide to reduce  nitrogen oxide emissions from  coal-fired power plants.\nOur Foret business continues  to develop OFFNOx ® , which  converts nitrogen oxide into  nitrates, reducing air pollution.  Used initially in building tiles, the  product is being evaluated for  applications in paints, metals,  cement and concrete under  a grant from Spain and the  European Regional Develop- ment Fund.\nIn 2010, our Alkali Chemicals  division developed a patent  pending process for production  of EnProve TM  TR milled trona to  reduce air pollutants at power  plants and other industrial  facilities. It enables users to  reduce capital costs and energy  consumption while removing  sulfur dioxide, sulfur trioxide,  mercury and hydrochloric acid  from their stack emissions. Another new product innovation  is  Liquid Soda TM  – a less hazard- ous alternative to caustic soda  for the pulp and paper industry. \nThis year we plan to break  ground on a new Asia Innovation  Center in Shanghai that will  service both regional customers  and global innovation across our  FMC businesses. It’s just one  more outgrowth of innovative  research that never rests.\nShanghai, China Istanbul,Turkey Bangalore, India Mumbai, India Brussels, Belgium Sandvika, Norway Villefranche, France Singapore  (opening in 2011)"}]}
+{"image": "doclay/doclay_80851.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "133 STAT. 1007 \nPUBLIC LAW 116–25—JULY 1, 2019 \nin a manner that reduces the administrative burden on taxpayers  who are victims of such fraud. \n(b) STANDARDS AND PROCEDURES TO BE CONSIDERED.—The  guidelines described in subsection (a) may include— \n(1) standards for— \n(A) the average length of time in which a case involving  stolen identity refund fraud should be resolved; \n(B) the maximum length of time, on average, a tax- payer who is a victim of stolen identity refund fraud and  is entitled to a tax refund which has been stolen should  have to wait to receive such refund; and \n(C) the maximum number of offices and employees  within the Internal Revenue Service with whom a taxpayer  who is a victim of stolen identity refund fraud should  be required to interact in order to resolve a case; \n(2) standards for opening, assigning, reassigning, or closing  a case involving stolen identity refund fraud; and \n(3) procedures for implementing and accomplishing the  standards described in paragraphs (1) and (2), and measures  for evaluating such procedures and determining whether such  standards have been successfully implemented. \n(a) IN GENERAL.—Section 6713 is amended— \n(1) by redesignating subsections (b) and (c) as subsections  (c) and (d), respectively; and \n(2) by inserting after subsection (a) the following new sub- section: \n26 USC 6713. \n‘‘(b) ENHANCED PENALTY FOR IMPROPER USE OR DISCLOSURE  RELATING TO IDENTITY THEFT.— \n‘‘(1) IN GENERAL.—In the case of a disclosure or use  described in subsection (a) that is made in connection with  a crime relating to the misappropriation of another person’s  taxpayer identity (as defined in section 6103(b)(6)), whether  or not such crime involves any tax filing, subsection (a) shall  be applied— \n‘‘(A) by substituting ‘$1,000’ for ‘$250’, and \n‘‘(B) by substituting ‘$50,000’ for ‘$10,000’. \n‘‘(2) SEPARATE APPLICATION OF TOTAL PENALTY LIMITA- TION.—The limitation on the total amount of the penalty under  subsection (a) shall be applied separately with respect to disclo- sures or uses to which this subsection applies and to which  it does not apply.’’. \n(b) CRIMINAL PENALTY.—Section 7216(a) is amended by striking  ‘‘$1,000’’ and inserting ‘‘$1,000 ($100,000 in the case of a disclosure  or use to which section 6713(b) applies)’’. \n(c) EFFECTIVE DATE.—The amendments made by this section  shall apply to disclosures or uses on or after the date of the  enactment of this Act. \n26 USC 6713  note. \nSEC. 2009. INCREASED PENALTY FOR IMPROPER DISCLOSURE OR USE  OF INFORMATION BY PREPARERS OF RETURNS. "}]}
+{"image": "doclay/doclay_37297.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "中华人民共和国安全生产法  2002 \n1 \n中华人民共和国安全生产法 \n2014 年修正\n第一章  总  则 \n（2002 年 6 月 29 日第九届全国人民代表大会常务委员会第二十八次会议通过 2002 年 6 月 29 日中华人民 共和国主席令第七十号公布 自 2002 年 11 月 1 日起施行 根据 2014 年 8 月 31 日第十二届全国人民代表 大会常务委员会关于修改《中华人民共和国安全生产法》的决定修正 自 2014 年 12 月 1 日起施行） \n第一条  为了加强安全生产工作，防止和减少生产安全事故，保障人民群众生 命和财产安全，促进经济社会持续健康发展，制定本法。 \n第二条  在中华人民共和国领域内从事生产经营活动的单位(以下统称生产经 营单位)的安全生产，适用本法;有关法律、行政法规对消防安全和道路交通安全、 铁路交通安全、水上交通安全、民用航空安全以及核与辐射安全、特种设备安全另 有规定的，适用其规定。 \n第三条  安全生产工作应当以人为本，坚持安全发展，坚持安全第一、预防为 主、综合治理的方针，强化和落实生产经营单位的主体责任，建立生产经营单位负 责、职工参与、政府监管、行业自律和社会监督的机制。 \n第四条  生产经营单位必须遵守本法和其他有关安全生产的法律、法规，加强 安全生产管理，建立、健全安全生产责任制和安全生产规章制度，改善安全生产条 件，推进安全生产标准化建设，提高安全生产水平，确保安全生产。 \nSource: http://www.nanjing.gov.cn/njszf/qzf/glq/glqcsglj/201412/t20141210_3087125.html  Accessed: 03-Mar-2015 "}]}
+{"image": "doclay/doclay_23036.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "SHARPENING OUR FOCUS\nLIFE INSURANCE PENSIONS ASSET MANAGEMENTANNUAL REPORT 2010"}]}
+{"image": "doclay/doclay_80134.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "\n"}]}
+{"image": "doclay/doclay_54388.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "VI. FACILITIES & ON-SITE CONDITIONS\nVII. THE COMPETITION 7.01 ATP Fees\nVII. THE COMPETITION 7.01 ATP Fees\nA.Entry Fees\nB.Service Fee\nC.Membership Fees \n7.02 Entries\nA.Gender / Age Limitation\n1) ATP Tour Tournaments.  There are no entry fees.\n2) ATP Challenger Tour Tournaments.  There are no entry fees.\n1) Players who are included in the main draw or qualifying (singles or doubles) of  any ATP Tour tournament and who are not members in good standing with ATP  must pay the following service fee to ATP:\n2)  The Tour Manager will identify players who must pay a service fee that will be  withheld from on-site prize money. Players who by virtue of their ranking position  are not eligible for an ATP player membership may use these payments as a  credit toward future membership fees. Service fees paid to ATP may only be  applied against membership dues in the calendar year in which they were paid.\nMembership fees are defined in the ATP By-Laws.\nATP will use the age of a player on the first (1st) day of the qualifying competition.  Male players age sixteen (16) or older are not limited in the number of tournaments  they may enter. Players under the age of sixteen (16) are subject to the following  entry restrictions in ATP Tour or ATP Challenger Tour tournaments (includes entry as  a wildcard):\n1)  Male players under the age of fourteen (14) shall not be eligible for entry into any  ATP Tour or ATP Challenger Tour tournament.\n2)  Male players aged fourteen (14) shall be eligible for entry into a maximum of  eight (8) ATP Tour or ATP Challenger Tour tournaments.\n3) Male players aged fifteen (15) shall be eligible for entry into a maximum of twelve  (12) ATP Tour and ATP Challenger Tour tournaments.\n4) Transgender Athlete Participation.  A trans male (FTM) athlete who has re - ceived a medical exception for treatment with testosterone* for diagnosed Gen der Identity Disorder or gender dysphoria and/or Transsexualism, for purposes  of competition may compete on the ATP Tour or ATP Challenger Tour. A trans  male (FTM) athlete who is not taking testosterone related to gender transition  may also participate in ATP Tour or ATP Challenger Tour events.\n*Must have a valid TUE from the Tennis Anti-Doping Program.\nATP Tour Masters 1000 Main Draw $400/€400 event Qualifying $100/€100 ATP Cup $350 ATP Tour 500 Main Draw $300/€300 event Qualifying $100/€100 ATP Tour 250 Main Draw $200/€200 event Qualifying $100/€100\n102\n103"}]}
+{"image": "doclay/doclay_7553.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "notes to  consolidated  financial  statements\np 48\nTyson Foods, Inc. 2002 annual report\nNote 16: Earnings Per Share\nThe weighted average common shares used in the computation of basic and diluted earnings per share were as follows:\nApproximately 6 million shares of the Company’s option shares outstanding at September 28, 2002, were antidilutive and were not included in the dilutive earnings per share calculation for the year ended September 28, 2002. On September 28, 2001, the Company issued approximately 129 million shares for the remaining IBP shares. These shares were excluded from the fiscal 2001 weighted average share calculation along with the dilutive effect of acquired stock options and restricted shares.\nThe Company operates in five business segments: Beef, Chicken, Pork, Prepared Foods and Other. The Company measures segment profit as operating income. The following information includes 52 weeks and nine weeks of IBP’s operating results for  the periods ending September 28, 2002, and September 29, 2001, respectively.\nBeef segment is primarily involved in the slaughter of live fed cattle and fabrication of dressed beef carcasses into primal and  sub-primal meat cuts and case-ready products. It also involves deriving value from allied products such as hides and variety meats for sale to further processors and others. The beef segment markets its products to food retailers, distributors, wholesalers, restaurants and hotel chains and other food processors in domestic and international markets. Allied products are also marketed  to manufacturers of pharmaceuticals and technical products.\nChicken segment includes fresh, frozen and value-added chicken products sold through domestic foodservice, domestic retail markets for at-home consumption, wholesale club markets targeted to small foodservice operations, small businesses and individuals, as well as specialty and commodity distributors who deliver to restaurants, schools and international markets throughout the world. The chicken segment also includes sales from allied products and the Company’s chicken breeding stock subsidiary.\nPork segment represents the Company’s live swine group, hog slaughter and fabrication operations, case-ready products and related allied product processing activities. The pork segment markets its products to food retailers, distributors, wholesalers, restaurants and hotel chains and other food processors in domestic and international markets. It also sells allied products to pharmaceutical and technical products manufacturers, as well as live swine to pork processors.\nPrepared Foods segment includes the Company’s operations that manufacture and market frozen and refrigerated food products. Products include pepperoni, beef and pork toppings, pizza crusts, flour and corn tortilla products, appetizers, hors d’oeuvres, desserts, prepared meals, ethnic foods, soups, sauces, side dishes, specialty pasta and meat dishes as well as branded and processed meats.\nOther segment includes the logistics group and other corporate groups not identified with specific protein groups.\nNote 17: Segment Reporting\nin millions, except per share data 2002 2001 2000 Numerator: Net Income $ 383 $ 88 $ 151 Denominator: Denominator for basic earnings per share –weighted average shares 348 221 225 Effect of dilutive securities: Stock options and restricted stock 7 1 1 Denominator for diluted earnings per share – adjusted weighted  average shares and assumed conversions 355 222 226 Basic earnings per share $1.10 $0.40 $0.67 Diluted earnings per share $1.08 $0.40 $0.67"}]}
+{"image": "doclay/doclay_77905.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\n2. dass das Gericht nicht geprüft hat, ob der verlangte Unterhalt das im Antrag angegebene Kindeseinkommen berücksichtigt;\n3. dass über den Unterhalt ein Festsetzungsbeschluss ergehen kann, aus dem der Antragsteller die Zwangsvollstreckung betreiben kann, wenn er nicht innerhalb eines Monats Einwendungen erhebt;\n4. welche Einwendungen nach § 252 erhoben werden können, insbesondere, dass der Einwand eingeschränkter oder fehlender Leistungsfähigkeit nur erhoben werden kann, wenn die Auskunft nach § 252 Absatz 4 erteilt wird und Belege über die Einkünfte beigefügt werden.\nIst der Antrag im Ausland zuzustellen, bestimmt das Gericht die Frist nach Satz 2 Nummer 3.\n(2) § 167 der Zivilprozessordnung gilt entsprechend.\n(1) Der Antragsgegner kann Einwendungen gegen die Zulässigkeit des vereinfachten Verfahrens geltend machen. Bei begründeten Einwendungen weist das Gericht den Antrag zurück. Unbegründete Einwendungen weist das Gericht mit dem Festsetzungsbeschluss nach § 253 zurück.\n(2) Andere als die in Absatz 1 Satz 1 genannten Einwendungen, insbesondere Einwendungen nach den Absätzen 3 und 4, sind nur zulässig, wenn der Antragsgegner zugleich erklärt, inwieweit er zur Unterhaltsleistung bereit ist und dass er sich insoweit zur Erfüllung des Unterhaltsanspruchs verpflichtet.\n(3) Der Einwand der Erfüllung ist nur zulässig, wenn der Antragsgegner zugleich erklärt, inwieweit er Unterhalt geleistet hat und entsprechende Belege vorlegt.\n(4) Der Einwand eingeschränkter oder fehlender Leistungsfähigkeit ist nur zulässig, wenn der Antragsgegner zugleich Auskunft über seine Einkünfte und sein Vermögen erteilt und für die letzten zwölf Monate seine Einkünfte belegt. Ein Antragsgegner, der Leistungen zur Sicherung des Lebensunterhalts nach dem Zweiten Buch Sozialgesetzbuch oder dem Zwölften Buch Sozialgesetzbuch bezieht, muss den aktuellen Bewilligungsbescheid darüber vorlegen. Bei Einkünften aus selbständiger Arbeit, Gewerbebetrieb sowie Land- und Forstwirtschaft sind als Belege der letzte Einkommensteuerbescheid und für das letzte Wirtschaftsjahr die Gewinn-und-Verlust- Rechnung oder die Einnahmenüberschussrechnung vorzulegen.\n(5) Die Einwendungen sind nur zu berücksichtigen, solange der Festsetzungsbeschluss nicht erlassen ist.\n§ 252 Einwendungen des Antragsgegners\n§ 253 Festsetzungsbeschluss\n(1) Ist der Antrag zulässig und werden keine oder keine nach § 252 Absatz 2 bis 4 zulässigen Einwendungen erhoben, wird der Unterhalt nach Ablauf der in § 251 Abs. 1 Satz 2 Nr. 3 bezeichneten Frist durch Beschluss festgesetzt. Die Festsetzung durch Beschluss erfolgt auch, soweit sich der Antragsgegner nach § 252 Absatz 2 zur Zahlung von Unterhalt verpflichtet hat. In dem Beschluss ist auszusprechen, dass der Antragsgegner den festgesetzten Unterhalt an den Unterhaltsberechtigten zu zahlen hat. In dem Beschluss sind auch die bis dahin entstandenen erstattungsfähigen Kosten des Verfahrens festzusetzen, soweit sie ohne weiteres ermittelt werden können; es genügt, wenn der Antragsteller die zu ihrer Berechnung notwendigen Angaben dem Gericht mitteilt.\n(2) In dem Beschluss ist darauf hinzuweisen, welche Einwendungen mit der Beschwerde geltend gemacht werden können und unter welchen Voraussetzungen eine Abänderung verlangt werden kann.\nHat der Antragsgegner zulässige Einwendungen (§ 252 Absatz 2 bis 4) erhoben, teilt das Gericht dem Antragsteller dies mit und weist darauf hin, dass das streitige Verfahren auf Antrag eines Beteiligten durchgeführt wird.\n§ 254 Mitteilungen über Einwendungen\n§ 255 Streitiges Verfahren\n(1) Im Fall des § 254 wird auf Antrag eines Beteiligten das streitige Verfahren durchgeführt.\n(2) Beantragt ein Beteiligter die Durchführung des streitigen Verfahrens, ist wie nach Eingang eines Antrags in einer Unterhaltssache weiter zu verfahren. Einwendungen nach § 252 gelten als Erwiderung.\n(3) Das Verfahren gilt als mit der Zustellung des Festsetzungsantrags (§ 251 Abs. 1 Satz 1) rechtshängig geworden.\n- Seite 79 von 129 -"}]}
+{"image": "doclay/doclay_5126.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Contents\nFinancial Highlights . . . . . . . . . . . . . . . . . . .1 Letter to Shareholders . . . . . . . . . . . . . . . . .2 Board of Directors . . . . . . . . . . . . . . . . . . .4 Executive Officers and Key Members of Management . . . . . . . . . . .5 Growth  . . . . . . . . . . . . . . . . . . . . . . . . . . .6 Innovations . . . . . . . . . . . . . . . . . . . . . . . .10 Solutions . . . . . . . . . . . . . . . . . . . . . . . . .14 Partners . . . . . . . . . . . . . . . . . . . . . . . . . .24 Securities & Exchange  Commissions Form 10-K Corporate Information"}]}
+{"image": "doclay/doclay_12797.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "FIRST COMMONWEALTH FINANCIAL CORPORATION AND SUBSIDIARIES\nCONSOLIDATED STATEMENTS OF CHANGES IN SHAREHOLDERS’ EQUITY\n(Dollar Amounts in Thousands)\n Accumulated Additional Other Unearned Total Common Paid-in Retained Comprehensive Treasury ESOP Shareholders’ Stock Capital Earnings Income (Loss) Stock Shares Equity Balance at December 31, 1998 $ 62,525 $ 68,978 $ 235,623 $ 2,199 $ (5,913) $ (8,007) $ 355,405 Comprehensive income Net income -0- -0- 53,030 -0- -0- -0- 53,030 Other comprehensive income, net of tax: Unrealized holding gains (losses) on securities arising during the period -0- -0- -0- (42,137) -0- -0- (42,137) Less: reclassification adjustment for gains on securities included in net income -0- -0- -0- (366) -0- -0- (366) Total other comprehensive income -0-  -0- -0- (42,503) -0- -0- (42,503) Total comprehensive income -0- -0- 53,030 (42,503) -0- -0- 10,527 Cash dividends declared -0- -0- (30,880) -0- -0- -0- (30,880) Net increase in unearned ESOP shares -0- 53 -0- -0- -0- 1,814 1,867 Discount on dividend reinvestment plan purchases -0- (358) -0- -0- -0- -0- (358) Treasury stock acquired -0- -0- -0- -0- (51,331) -0- (51,331) Treasury stock reissued -0- (343) -0- -0- 1,796 -0- 1,453 Balance at December 31, 1999 62,525 68,330 257,773 (40,304) (55,448) (6,193) 286,683 Comprehensive income Net income -0- -0- 47,246 -0- -0- -0- 47,246 Other comprehensive income, net of tax:  Unrealized holding gains (losses) on securities arising during the period -0- -0- -0- 33,630 -0- -0- 33,630 Less: reclassification adjustment for gains on securities included in net income -0-  -0-  -0- (1,134) -0- -0- (1,134) Total other comprehensive income -0- -0- -0- 32,496 -0- -0- 32,496 Total comprehensive income -0- -0- 47,246 32,496 -0- -0- 79,742 Cash dividends declared -0- -0- (32,850) -0- -0- -0- (32,850) Decrease in unearned ESOP shares -0- (113) -0- -0- -0- 906 793 Discount on dividend reinvestment plan purchases -0- (593) -0- -0- -0- -0- (593) Treasury stock acquired -0- -0- -0- -0- (873) -0- (873) Treasury stock reissued -0- (476) -0- -0- 1,655 -0- 1,179 Tax benefit of stock options -0- 75 -0- -0- -0- -0- 75 Balance at December 31, 2000 62,525 67,223 272,169 (7,808) (54,666) (5,287) 334,156 Comprehensive income Net income -0- -0- 50,189 -0- -0- -0- 50,189 Other comprehensive income, net of tax:  Unrealized holding gains (losses) on securities arising during the period -0- -0- -0- 18,639 -0- -0- 18,639  Less: reclassification adjustment for gains on securities included in net income -0- -0- -0- (2,128) -0- -0- (2,128) Total other comprehensive income -0- -0- -0- 16,511 -0- -0-  16,511 Total comprehensive income -0- -0- 50,189 16,511 -0- -0- 66,700 Cash dividends declared -0- -0- (34,139) -0- -0- -0- (34,139) Decrease in unearned ESOP shares -0- 31 -0- -0- -0- 1,161 1,192 Discount on dividend reinvestment plan purchases -0- (612) -0- -0- -0- -0- (612) Treasury stock reissued -0- (735) -0- -0-  3,235 -0- 2,500 Tax benefit of stock options -0- 269 -0- -0- -0- -0- 269 Balance at December 31, 2001 $ 62,525 $ 66,176 $ 288,219 $ 8,703 $ (51,431) $ (4,126) $ 370,066\n18\nThe accompanying notes are an integral part of these consolidated financial statements."}]}
+{"image": "doclay/doclay_79808.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "7.784  7.780  7.775  7.766  7.757  <»---!  I  Yc7.744  r=5.957  4.021  5,954  5,943  5.938  5.921  5.916  --.I-!  I  I  5.906  5.902  5.275  5.265  5.261  5.257  5.247  o,---!  La  ~  1.000  =’fl- 4.709  4.639  2.916  2.904  2.891  2.882  2.871  (71---!  I  J~l:H8  ~-875  2.836  1.187  2.498  2.494  2.490  2.424  2.390  ~---!  I  11-2.281  2.022  1,960  1.901  1.893  1.882  1.833  c,,,---!  I  ~1.846  -1=1.827  1.683  1.659  1.652  --.  1.168  ;;;:a--1.646  1.627  N---!  t;,;;:_  - .._____  3.250  11:ffl  ~--- 2.829  6,165  1.323  1.321  6.361  1.316  1.308  9.342  ::l=1.169  $_{8,325 }$--- ~1.127  .....1.--1,.;,---.-.  -::::=1,029  1.017 \n.,,  - C)  •  ......  (,J \nrv L9£f’Z£0/6IOZ sn \nM  10  £I  Jaaqs 6IOZ  ’i,z  •po \nuonRJ!1qnd uonRJHddv JaaJRd "}]}
+{"image": "doclay/doclay_61983.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Jul. 4, 2019 \n21 \nUS 2019/0204738 Al \n-continued  ~o ~o ~o  ~o  ~o  ~o  1Q  1G 1G \n-continued  ~o ~o ~o  0 ~  ~o  ~o  ~o  t)  rt)  1G "}]}
+{"image": "doclay/doclay_76428.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "[11] M. Koleini, M. Paulsson and M. Brandbyge, Phys. Rev. Lett. 98 , 197202 (2007).\n[12] H.J. Xiang, J.L. Yang, J.G. Hou and Q.S. Zhu, J. AM. Chem. Soc. 128 , 2310 (2006)\n[13] J.M. Soler, E. Artacho, J.D. Gale, A. Garc´ıa, J. Junquera, P. Ordej´ on, and D. S´ anchez-Portal, J. Phys.: Condens. Matter 14 , 2745 (2002).\n[14] D. S´ anchez-Portal, P. Ordej´ on, E. Artacho, and J.M. Soler, Int. J. Quantum Chem. 65 , 453 (1997), and references therein\n[15] P. Ordej´ on, Phys. Status Solidi B 217 , 335 (2000).\n[16] P. Hohenherg and W. Kohn, Phys. Rev. 136 , B864 (1964).\n[17] J.P. Perdew, K. Buike and M. Ernzerhof, Phys. Rev. Lett. 77 , 3865 (1996).\n[18] N. Troullier and J.L. Martins, Phys. Rev.B 43 , 1993 (1991).\n[19] H.M. Weng, T. Ozake and K. Terakura, J. Phys. Society of Japan 77 , 014301 (2008)\n[20] J.D. D` avila , and G.M. Pastor, Phys. Rev. Lett. 81 , 208 (1998).\n[21] R.A.G. L´ opez, J.M.M. Carrizalez and J.L.M. L´ opez, Phys. Rev.B 77 , 134431 (2008).\n[22] Y.W. Son, M.L. Cohen and S.G. Louie, Nature(London). 444 , 387 (2006).\n[23] P. G¨ utlich, A. Hauser and H. Spiering, Angew.Chem. 33 , 2024 (1994).\n[24] T. Tayagaki, and K. Tanaka, Phys. Rev. Lett. 86 , 2886 (2001).\n[25] X.Y. Cui, B. Delley, A.J. Freeman and C. Stampfl, Phys. Rev. Lett. 97 , 016402 (2006).\n7"}]}
+{"image": "doclay/doclay_21602.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "118\n36. FINANCIAL AND CAPITAL RIsk MANAGEMENT (CONTINUED)\n(B) Aud / uSd\n(C) CRediT RiSk\n(d) liquidiTy RiSk\nThe contractual maturity of the Group’s fixed and floating rate derivatives, other financial assets and other financial liabilities are  shown in the tables below. The amounts represent the future undiscounted principal and interest cash flows and therefore may  not equate to the values disclosed in the balance sheet.\nRefer to Note 19(B) for details of the Group’s unused credit facilities at 30 June 2013. \nTo help reduce this risk the Group:\nLiquidity risk is the risk that the Group cannot meet its financial commitments as and when they fall due.\nRefer to Note 8 for an ageing analysis of trade receivables and the movement in the provision for doubtful debts. All other  financial assets are not impaired and are not past due. Based on the credit history of these classes, it is expected that these  amounts will be received when due.\nFinancial assets are considered impaired where there is objective evidence that the Group will not be able to collect all amounts  due according to the original trade and other receivable terms. Factors considered when determining if an impairment exists  include ageing and timing of expected receipts and the credit worthiness of counterparties. A provision for doubtful debts is  created for the difference between the assets carrying value and the present value of estimated future cash flows. The Group’s  trading terms do not generally include the requirement for customers to provide collateral as security for financial assets.\nThe Group’s credit risk is mainly concentrated across a number of customers and financial institutions. The Group does not  have any significant credit risk exposure to a single or group of customers or individual institutions.\nThe Group is exposed to credit risk on financial instruments and derivatives. For credit purposes, there is only a credit risk where  the contracting entity is liable to pay the Group in the event of a closeout. The Group has policies that limit the amount of credit  exposure to any financial institution. Derivative counterparties and cash transactions are limited to financial institutions that  meet minimum credit rating criteria in accordance with the Group’s policy requirements. At 30 June 2013 counterparty credit  risk was limited to financial institutions with S&P credit ratings ranging from A to AA.\nCredit risk is the risk that a contracting entity will not complete its obligations under a financial instrument and cause the Group  to make a financial loss. The Group has exposure to credit risk on all financial assets included in the Group’s balance sheet. To  help manage this risk, the Group:\nComparing the Australian Dollar exchange rate against the United States Dollar, a 15% weaker Australian Dollar would result in  an exchange rate of 0.7763 and a 15% stronger Australian Dollar in an exchange rate of 1.0503 based on the year end rate of  0.9133. This range is considered reasonable given over the last five years, the Australian Dollar exchange rate against the United  States Dollar has traded in the range of 0.6120 to 1.1028.\nIMPACT ON POST-TAX PROFIT IMPACT ON EQUITY (CASH FLOW HEDGE RESERVE) 2013 $’000 2012 $’000 2013 $’000 2012 $’000 If the AUD exchange rate was 15% weaker against the USD with all other  variables held constant – increase/(decrease)  1   (1)  (1,249)  (1,496) If the AUD exchange rate was 15% stronger against the USD with all other  variables held constant – increase/(decrease)  (3)  (148)  1,786   2,955 \n• has a policy for establishing credit limits for the entities it deals with;\n• may require collateral where appropriate; and\n• manages exposures to individual entities it either transacts with or enters into derivative contracts with (through a system of  credit limits).\n• has a liquidity policy which targets a minimum level of committed facilities and cash relative to EBITDA;\n• has readily accessible funding arrangements in place; and\n• staggers maturities of financial instruments.\nNOTEs TO THE FINANCIAL sTATEMENTs \nFAIRFAx MEDIA LIMITED AND CONTROLLED ENTITIES FOR THE PERIOD ENDED 30 JUNE 2013"}]}
+{"image": "doclay/doclay_28944.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "of A [ θ ∗ ( σ ) + β ] in β are suppressed [5] at large √$_{KS}$$_{min}$$_{. The loop expansion goes in the}$ parameter 1 /KS$_{min}$ and only one loop contributes with the given accuracy.\nA comment is needed about the measure for the integration over β ( θ ). As is explained in Appendix A, the measure for the integration over σ ( θ ) involves a factor\n′ ′ ∗ ′ ′ ∗ ′ ∗ ′ ∗ ( $^{3}$) Because β ∼ 1 $_{/}$√$_{KS}$$_{min}$$_{, the second and third terms on the right-hand side are not essential}$ to the given order. Therefore, the measure for the path integration over β ( θ ) in Eq. (14) is the usual one for smooth functions β ( θ ), while this factor will show up to the next order in 1 /KS$_{min}$ .\n1 σ ′ = 1 σ ′ ∗ + β ′ = 1 σ ′ ∗ − β ′ ( σ ′ ∗ ) 2 + ( β ′ ) 2 ( σ ′ ∗ ) 3 + O ( ( β ′ ) $^{3}$) . (15) $_{/}$√$_{KS}$$_{min}$$_{, the second and third terms on the right-hand side are not essential}$\nω = AF ( z √ µ , µ ) − i AK ( √ 1 − µ 2 ) 2 , (16)\nAK ( µ ) = R 2 , AK ( √ 1 − µ 2 ) = T, (18) ) is the complete elliptic integral of the first kind. In deriving Eq. (18)\nF (1 /µ, µ ) = K ( µ ) + i K ( √ 1 − µ 2 ) . (19) to the ration of R/T as\n2 T R = K ( √ 1 − µ 2 ) K ( µ ) . (20)\nEquations (18) relates µ to the ration of R/T as\n( √ ) where K ( µ ) = F (1 , µ ) is the complete elliptic integral of the first kind. In deriving Eq. (18) we used the important identity\n5\n( ) ∫ √ − √ − is the incomplete elliptic integral of the first kind. The two parameters A and µ are related\nto the coordinates of the vertices of the rectangle by\nwhere\nThe conformal map of the upper half plane onto the interior of a rectangle is given by the Schwarz–Christoffel mapping\nIn this section we show how the path integral over reparametrizations captures the L¨ uscher term for a rectangle.\nF ( z √ µ , µ ) = ∫ z 0 d x √ µ − x 2 √ 1 − µx 2 (17) is the incomplete elliptic integral of the first kind. The two parameters A and µ are related\nIII. PATH INTEGRAL OVER REPARAMETRIZATIONS: RECTANGLE"}]}
+{"image": "doclay/doclay_2389.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "2\nwith ρ$_{ab}$ ( t ) ≡ 〈 e$_{a}$ | ˆ ρ ( t ) | e$_{b}$ 〉 and ω$_{ab}$ = ( ϵ$_{a}$ − ϵ$_{b}$ ) / ℏ . The first term on the right hand side of Eq. 5 describes the fully coherent dynamics in the absence of ˆ H$_{sb}$ and the second term describes the irreversible dynamics from the interaction with the phonon bath.\nCorrelations in bath-fluctuations on different sites [20] are taken into account by using the relation g n $_{q}$g m ∗ q = g m q g n ∗ q = g 2 $_{q}$e − R mn /R corr , where R$_{mn}$ ≡ | R$_{mn}$ | is the dis- tance between the sites and R$_{corr}$ is the phonon correla- tion length [21].\nUsing this relation for the electron-phonon couplings, the cross-correlation C$_{mn}$ ( ω ) can now be written as,\nwhere the frequency correlation function C ( ω ) = 2 π [ n ( ω )+1]( J ( ω ) − J ( − ω )), with n ( ω ) the Bose-Einstein distribution and the spectral density of the bath J ( ω ) = ∑ $_{q}$| g$_{q}$ | $^{2}$ω2 $_{q}$δ ( ω − ω$_{q}$ ), where δ ( ω ) is the Dirac delta func- tion. For the Hamiltonian specified in Eq. 1, the Redfield\n∑ For the Hamiltonian specified in Eq. 1, the Redfield tensor elements are given by\nwhere δ$_{ij}$ is the Kronecker delta and\nwith P denoting the Cauchy principal value of the in- tegral and U$_{na}$ = 〈 s$_{n}$ | e$_{a}$ 〉 the transformation matrix el- ements relating the site basis {| s$_{n}$ 〉} and the excitonic basis {| e$_{a}$ 〉} . Since | e$_{a}$ 〉 = ∑ n U$_{na}$ | s$_{n}$ 〉 , then | U$_{na}$ | 2 can be interpreted as the contribution of the n -th site to the a -th eigenstate of ˆ H$_{s}$ .\nHereafter, we will focus on QDs at low temperature (10 K) as our prototypical experimental realization. We neglect possible inversion asymmetry of the crystal, and therefore the contribution of the piezoelectric coupling, and focus instead on the deformation potential coupling. As shown by Calarco et al. [22], the spectral density describing this coupling (in the absence of an external electric field) is given by\nwhere, Θ( ω ) is the Heaviside step function. We use typical values for GaAs QDs for our numerical simula- tions [23, 24], giving η = ( D e − D h ) 2 4 π $^{2}$ρu$^{5}$ℏ = 0 . 035 ps 2 and\nω$_{c}$ = √ 2 u $^{2}$/l2 = 1 . 41 ps − $^{1}$, where D$_{e}$ ( D$_{h}$ ) is the de- formation coupling potential for electron (hole), u the speed of sound within the quantum dot, ρ its mass den- sity and l the ground state localization length, assumed to be the same for electron and holes. We also assume a correlation length, R$_{corr}$ , of 3 nm.\nUsing Eqns. 7-9, the population transfer rates, k$_{ab}$ , be- tween the eigenstates a → b is given by,\nThis equation is central to our insight into designing exci- tonic transfer. Though derived for a different regime, the form of Eq. 11 is similar to the widely used rate equation in F¨ orster theory (incoherent limit), k Forster ab ∝ J 2 $_{ab}$I$_{ab}$ , where J is the electronic coupling, and I is the spectral overlap integral [25]. Both equations are a product of two terms: one dealing primarily with the description of the system ( ζ in this paper or J 2 for F¨ orster theory), and an- other largely depending on and arising from the system- bath interaction ( C ( ω ) in this paper or I for F¨ orster the- ory). F¨ orster theory has been applied in fluorescence res- onance energy transfer (FRET) to design chromophores for biosensing assays [2, 26, 27] and was recently verified experimentally for semiconductor QDs [28]. We use the simple structure of Eq. 11 to gain microscopic and exper- imentally relevant insight into engineering directed and optimized EET.\nWhile C ( ω$_{ab}$ ) depends on the overlap of system eigenenergies with the spectral properties of the phonon bath (e.g., lattice vibrations, solvent, protein environ- ment, etc.), ζ depends on the transformation matrix U in Eq. 9, determined by the relative magnitude of electronic couplings with respect to site energies, site connectivity, and spatial correlation between sites. The aim is then to maximize (minimize) the product of these two factors in Eq. 11 to favor (suppress) the desired rates.\nTo illustrate the applicability of Eq. 11, we choose two three-site examples to highlight the importance of the phonon bath interaction to achieve directed EET. Since multiplying a system Hamiltonian by a scalar does not change the maximum exciton transfer probability in the coherent limit, the distances and site energies for the two cases are chosen so that the Hamiltonians are related by a multiplicative factor (3 . 5 ˆ H 1 s = ˆ H 2 $_{s}$). As a conse- quence, the ζ values are roughly the same for cases 1 and 2 (Table I); slight differences are introduced by the bath correlation term in Eq. 9. In the cases chosen, the fully coherent evolution gives a maximum probability of finding an excitation of 5% (1%) for site 1(2). Therefore, any difference between the two examples is a result of interaction with the environment.\nIn contrast to the ζ factors, the C ( ω$_{ab}$ ) values for cases 1 and 2 at 10 K differ by at least one order of magnitude due the position of the transition frequencies with respect to the spectral density (Table I). Any changes to the system Hamiltonian can affect C ( ω$_{ab}$ ). In our examples, the scalar factor mentioned above changes the C ( ω$_{ab}$ ) such that the largest population transfer rate is switched\nJ ( ω ) = Θ( ω ) ηω $^{3}$e − ω $^{2}$/ω2 c , (10)\nΓ$_{ab,cd}$( ω$_{dc}$ ) = 1 2 ζ$_{ab,cd}$C ( ω$_{dc}$ ) + i 2 π ζ$_{ab,cd}$ P (∫ ∞ −∞ C ( ω ) ω$_{dc}$ − ω d ω ) , (8)\nζ$_{ab,cd}$ = ∑ n,m ( U − $^{1}$)$_{an}$ U$_{nb}$ ( U − $^{1}$)$_{cm}$ U$_{md}$e − R mn /R corr , (9)\nR$_{ab,cd}$ = Γ$_{db,ac}$( ω$_{ca}$ ) + Γ ∗ $_{ca,bd}$( ω$_{db}$ ) − δ$_{bd}$ ∑ e Γ$_{ae,ec}$( ω$_{ce}$ ) − δ$_{ac}$ ∑ e Γ ∗ $_{be,ed}$( ω$_{de}$ ) , (7)\nC$_{mn}$ ( ω ) = e − R mn /R corr C ( ω ) , (6)\nk$_{ab}$ = R$_{bb,aa}$ = ζ$_{ab,ba}$C ( ω$_{ab}$ ) . (11)"}]}
+{"image": "doclay/doclay_19136.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Consolidated financial statements of Aegon N.V. 126\nConsolidated statement of changes in equity of Aegon N.V.  For the year ended December 31, 2012\nConsolidated statement of changes in equity of Aegon N.V.  For the year ended December 31, 2012\nAmounts in EUR million Note Share  capital Retained  earnings Revaluation  reserves Re- measure- ment of  defined  benefit  plans Other  reserves Other  equity  instru- ments Issued  capital and  reserves  1) Non- control- ling  interests Total At January 1, 2012 (restated  for IAS 19) 9,097 9,418 3,464 (979) (964) 4,720 24,756 14 24,770 Changes in accounting policies  relating to IFRS 10  2) - (122) - - - - (122) - (122) Changes in accounting policies  relating to IFRS 11  2) - - 17 - (17) - - - - At January 1, 2012 (restated) 9,097 9,296 3,481 (979) (981) 4,720 24,634 14 24,648 Net income / (loss) recognized  in the income statement - 1,581 - - - - 1,581 1 1,582 Other comprehensive income: Items that will not be  reclassified to profit or loss: Changes in revaluation reserve  real estate held for own use - - (5) - - - (5) - (5) Remeasurements of defined  benefit plans - - - (149) - - (149) - (149) Income tax relating to items  that will not be reclassified - - 1 37 - - 38 - 38 Items that may be reclassified  subsequently to profit or loss: Gains / (losses) on revaluation  of available-for-sale  investments - - 4,176 - - - 4,176 4,176 (Gains) / losses transferred to  income statement on disposal  and impairment of available- for-sale investments - - (465) - - - (465) - (465) Changes in cash flow hedging  reserve - - (86) - - - (86) - (86) Movements in foreign currency  translation and net foreign  investment hedging reserves - - - 6 (116) - (110) - (110) Equity movements of joint  ventures - - - - 27 - 27 - 27 Equity movements of associates - - - - 22 - 22 - 22 Income tax relating to items  that may be reclassified - (6) (1,048) - 3 - (1,051) - (1,051) Transfer from / to other  headings (19) 19 - - - - - - Other - - - - - - - (2) (2) Total other comprehensive  income / (loss) ­ (25) 2,592 (106) (64) ­ 2,397 (2) 2,395 Total comprehensive income /  (loss) for 2012 ­ 1,556 2,592 (106) (64) ­ 3,978 (1) 3,977 Shares issued and withdrawn 2 - - - - - 2 - 2 Treasury shares - 3 - - - - 3 - 3 Dividends paid on common  shares - (148) - - - - (148) - (148) Preferred dividend - (59) - - - - (59) - (59) Coupons on perpetual securities - (172) - - - - (172) - (172) Issuance of non-cumulative  subordinated notes - - - - - 271 271 - 271 Coupons on non-cumulative  subordinated notes - (23) - - - - (23) - (23) Cost of issuance of non- cumulative subordinated  notes (net of tax) - (10) - - - - (10) - (10) Dividend withholding tax  reduction - 3 - - - - 3 - 3 Share options and share-based  incentive plans - - - - - 27 27 - 27 At December 31, 2012 32, 33, 34 9,099 10,446 6,073 (1,085) (1,045) 5,018 28,506 13 28,519\n1  Issued capital and reserves attributable to equity holders of Aegon N.V. 2 \nIssued capital and reserves attributable to equity holders of Aegon N.V. 2  Amounts have been restated for the changes in accounting policies IFRS 10, 11 and IAS 19. Refer to note 2 for details about these changes.\nAnnual Report 2013"}]}
+{"image": "doclay/doclay_39342.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "The  Project Steering Committee  will meet in Brussels for the  Kick-off Meeting , no later than  15 days after the starting date of the contract. The meeting will ensure that the  Contractor  has  a clear understanding of the objectives and obligations in the contract. \nAfter the kick-off, the  Project Steering Committee  will meet for a  Progress Meeting  every  four months.\nThe  Contractor must send the minutes of the Kick-off and all Progress Meetings to INEA  within one week; INEA should approve or reply with a request for clarifications within two  weeks. \nThe  Contractor  shall submit to INEA an  Inception Report  no later than two months after the  starting date of the contract. \nIt will contain the detailed management plan and work plan, the communication and  dissemination plan, and the proposed structure for the Interim Progress and Final reports. It  must be based on these tender specifications but will account for any changes agreed during  the kick-off meeting. It must define measurable performance indicators and targets agreed  upon at the kick-off meeting to allow assessing the work done under the contract. \nThe  Contractor  shall submit to INEA  two Progress Reports . Progress Report 1 will cover  months 1 to 12 and will be due by the end of month 13. Progress Report 2 will cover months  1 to 24 and will be due by the end of month 25. \nThe Progress Reports will present a full overview of progress. They must give a complete  overview of the implementation of the contract and cover any deviations and corrective  actions taken. They must include achievements and impacts, feedback from stakeholders as  well as any problems encountered. Finally, they must include an updated plan of further  activities. In addition, they must include an annex providing a detailed description of the  financial resources used under this contract. \nThe  Contractor  shall submit to INEA a draft  Final Report  by the end of month 34 after the  starting date. INEA will give its feedback within 30 days after submission of this draft. The  Contractor  shall submit the Final Report by the end of month 36. The Final Report follows  the same structure as the Interim Final Reports. It covers the entire duration of the  Technical  and Support Office . \nThe Inception Report, Progress Reports and Final Report must be submitted to the INEA in  unsecured PDF format.\nThe deadlines for submission of the deliverables and the progress reports are listed in Table 1.  The  Contractor  is deemed solely responsible for delays occasioned by subcontractors or other  third parties (except for cases of force majeure). \n19\nProgress and final reporting "}]}
+{"image": "doclay/doclay_24726.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "(1) P ( α$_{n}$ = a | α$_{0}$, . . . , α$_{n}$$_{−}$$_{1}$ ) =     $^{x$_{n}$}$$^{(}$$^{α$_{0}$}$$^{, . . . , α$_{n}$$_{−}$$_{1}$}$$^{)[}$$^{a}$$^{]}$$^{,}$ if n is even , y$_{n}$ ( α$_{0}$, . . . , α$_{n}$$_{−}$$_{1}$ )[ a ] , if n is odd . I call such a sequence of random variables an ( x, y )- random play . If the players play according\n$^{x$_{n}$}$$^{(}$$^{α$_{0}$}$$^{, . . . , α$_{n}$$_{−}$$_{1}$}$$^{)[}$$^{a}$$^{]}$$^{,}$ I call such a sequence of random variables an ( x, y )- random play . If the players play according to the strategy profile ( x, y ), then the expected payoff for player 1 is given by\nrandomizes his action according to x$_{n}$ ( π$_{n}$ ( h )), where π$_{n}$ ( h ) is the atom of P$_{n}$ that contains h . Abusing notations, I sometimes write x$_{n}$ ( h ) instead of x$_{n}$ ( π$_{n}$ ( h )). Behavioral strategies y of player 2 are defined analogously.\nEvery pair x, y of strategies induces a probability distribution µ$_{x,y}$ over the set A N of infinite histories or plays : µ$_{x,y}$ is the joint distribution of a sequence α$_{0}$, α$_{1}$, . . . . . . of A - valued random variables such that\nwhere α$_{0}$, α$_{1}$, . . . is an ( x, y )-random play.\nThe lower value val Γ( W ) and upper value val Γ( W ) of the game Γ( W ) are defined by:\nwhere the suprema are taken over all strategies x of player 1 and the infima over all strategies y of player 2. The game is determined if the lower and upper values are equal, val Γ( W ) = val Γ( W ), in which case their common value is called the value of the game. For ϵ ≥ 0, a strategy x of player 1 is ϵ -optimal if µ$_{x,y}$ ( W ) ≥ val Γ( W ) − ϵ for every strategy y of player 2. We also say that player 1 can guarantee payoff of at least val Γ( W ) − ϵ by playing such a strategy x . ϵ -optimal strategies of player 2 are defined analogously.\nLet ∼$_{n}$ be the equivalence relation over infinite histories such that u ∼$_{n}$ u ′ whenever u |$_{n}$ and u $^{′}$|$_{n}$ belong to the same atom of P$_{n}$ , where u |$_{n}$ and u $^{′}$|$_{n}$ are the initial segments of u and u ′ of length n . The interpretation is that if u, u ′ ∈ A N and u ∼$_{n}$ u $^{′}$, then at stage n the player cannot distinguish between u and u $^{′}$. Say that at stage n the player observes the\n2\n(2) µ$_{x,y}$ ( W ) = P (( α$_{0}$, α$_{1}$, . . . ) ∈ W ) ,\nval Γ( W ) = sup x inf y µ$_{x,y}$ ( W ) , and val Γ( W ) = inf y sup x µ$_{x,y}$ ( W ) ,"}]}
+{"image": "doclay/doclay_6460.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Information about the benefit obligation, assets and funded status of the Company’s defined benefit pension plans is as follows:\nThe fair values of the Company’s long-term debt were estimated using discounted cash flow analysis based on incremental borrowing rates for similar types of borrowing arrangements.\nAll of the Company’s financial instruments are held or issued for purposes other than trading. The carry- ing amounts and estimated fair values of the Company’s financial instruments are summarized as follows:\n(dollars in thousands, except per share data) - continued - \nNOTE G – FAIR VALUE OF FINANCIAL INSTRUMENTS\nNotes to Consolidated Financial Statements\nNOTE H – PENSION PLANS\npension plans is as follows: 2001 2000 Change in benefit obligation:  Benefit obligation at beginning of year  $ 6,606 $ 6,999  Service cost  103 92 Interest cost  407 437  Actuarial loss  239 230 Benefits paid (549) (1,152) Benefit obligation at end of year  6,806  6,606  Change in plan assets:  Fair value of plan assets at beginning of year  2,984 4,070 Actual return on plan assets  (457) (259) Employer contribution  386 324  Benefits paid  (549) (1,151) Fair value of plan assets at end of year  2,364 2,984 Funded status  (4,442) (3,622) Unrecognized actuarial loss  2,139 893  Net amount recognized  $ (2,303) $ (2,729) Amounts recognized in the statement of financial  position consist of:  Accrued liability  $ (4,442) $ (3,622) Accumulated other comprehensive income  2,139 893 Net amount recognized  $ (2,303) $ (2,729) Weighted-average assumptions as of year-end:  Discount rate  6.08% 6.06% Expected return on plan assets  7.50% 8.50%\n2001 2000 CARRYING CARRYING AMOUNT FAIR VALUE AMOUNT FAIR VALUE Financial assets Cash and cash equivalents $ 1,412 $ 1,412 $ 2,591 $ 2,591 Notes receivable (including current portion) 9,841 9,841 6,860 6,860  Escrow funds 251 251 253 253  Financial liabilities Long-term debt (including current portion) 168,246 161,051  201,517 190,102  Interest rate swap (4,028) (4,028) – (1,485)\n22 THE DIXIE GROUP  / 2001 ANNUAL REPORT"}]}
+{"image": "doclay/doclay_5287.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "23\nthe 1999 and 2000 acquisitions. On a pro forma basis, circulation revenues increased 2% in 2000.\nFor local newspapers, morning circulation accounts for approxi- mately 79% of total daily volume, while evening circulation accounts for 21%. On a pro forma basis, local morning and Sunday circula- tion volumes declined 1%, while evening circulation declined 2%. Selected circulation price increases were implemented in 2000 at certain newspapers. Also during 2000, the Green Bay (Wis.)  Press-Gazette converted from an evening to a morning publication.\nUSA TODAY’s average daily circulation for 2000 rose 0.4% to 2,284,024. USA TODAY reported an average daily paid circulation of 2,257,774 in the ABC Publisher’s Statement for the six months ended Sept. 24, 2000, a 1% increase over the comparable period a year ago. \nReported newspaper advertising revenues for 1999 were $342 million greater than in 1998, a 12% increase, while pro forma  revenues presented above reflect a 6% increase. The variance in these two comparisons relates principally to the Newsquest  properties acquired in July 1999.\nPro forma local ad revenues and linage were up slightly for 1999. Ad spending by the larger retailers declined for the year, reflecting closings and consolidations, but this was mostly offset by greater revenue from expanded sales and marketing efforts directed toward small- and medium-sized advertisers.\nPro forma national ad revenues and linage for 1999 rose 13% and 16%, respectively, driven principally by USA TODAY, which reported a 19% gain in revenues on a 14% linage gain. National ad revenue growth was also strong at USA WEEKEND and at several large daily newspaper properties.\nPro forma classified revenue in 1999 rose 7% on a 9% linage gain. Employment ad revenue gains were the strongest, followed by automotive and then real estate. The continued strong economy and the tight labor market were key factors in these revenue gains, along with added marketing and sales resources.\nNewspaper circulation revenues rose $13 million or slightly more than 1% in 1999. Incremental circulation revenues from Newsquest offset declines in domestic circulation revenue. On a pro forma basis, circulation revenues remained even.\nPro forma local morning circulation declined 2% in 1999, evening circulation declined 2% and Sunday circulation declined 2%. Circulation price increases were implemented in 1999 at  certain newspapers. During 1999, the St. Cloud (Minn.) Times  and The Daily Journal at Vineland, N.J., converted from evening  to morning publications.\nUSA TODAY’s average daily circulation for 1999 rose 0.1% to 2,274,621. USA TODAY reported an average daily paid circulation of 2,235,808 in the ABC Publisher’s Statement for the six months ended Sept. 26, 1999, a 1% increase over the comparable period in 1998.\nNewspaper operating expense:  Newspaper operating costs rose $369 million, or 9%, in 2001. The increase was primarily due to incremental costs from the 2000 acquisitions and higher newsprint prices, which were 10% higher on average over 2000. Cost control efforts at all newspaper properties continued as a very high manage- ment priority and employee reductions have been achieved at most properties. As a result, on a pro forma basis, overall operating costs decreased 4%. Newsprint expense decreased 2% in 2001, due to\nlower consumption partially offset by higher average newsprint prices. The consumption added from recent acquisitions was  tempered by a large number of newspapers converting to the new 50-inch web width during 2001 and 2000 and an overall decline in advertising demand. Payroll costs for newspaper operations rose 8% in 2001, primarily due to the newly acquired properties. \nFor 2002, newsprint consumption is expected to increase mod- estly. Consumption in 2002 will be tempered by the full year impact of web width reductions implemented in 2001 and planned web width reductions for 2002. For 2002, newsprint prices are expected to be significantly lower on average than in 2001. Employee count reductions will also benefit cost comparisons in 2002. \nNewspaper operating costs rose $837 million, or 27%, in 2000. The increase was primarily due to incremental costs from the 1999 and 2000 acquisitions. Newsprint expense for the year, including the effect of acquisitions, was 20% higher in 2000. Both consump- tion and average newsprint prices were higher by 17% and 3%, respectively. The increase in consumption was tempered by a large number of newspapers converting to the new 50-inch web width format. Generally, a conversion from a 54-inch web width to a 50- inch web width will result in a more than 7% savings in newsprint consumption. Payroll costs for newspaper operations rose 26% in 2000, primarily due to the newly acquired properties and the impact of the 53rd week in 2000. \nNewspaper operating expenses rose $197 million, or 7%, in 1999. The increase was caused principally by incremental costs from Newsquest properties acquired in July 1999. Newsprint expense for the year, including the effect of acquisitions, was 6% lower than in 1998. While consumption rose nearly 7% (due  principally to Newsquest), average newsprint prices declined 12%.\nPayroll costs for newspaper operations rose 10% in 1999, in part because of the Newsquest acquisition but also because of staffing increases in marketing and ad sales and modest pay increases.\nNewspaper operating income:  Operating profit decreased $121 million or 8%. The decrease in operating profits is due largely to declining advertising revenues and higher newsprint prices for U.S. newspapers during much of 2001. Most of the company’s domestic newspapers reported lower results in 2001.\nNewsquest operating income improved but financial results were translated from British pounds to U.S. dollars using a weight- ed average rate of $1.44 for 2001, as compared to $1.50 in 2000, which mitigated some of the earnings growth in the U.K.\nFor 2002, newspaper operating profits are expected to show modest growth, reflecting revenue gains, the benefit of further web width reductions and lower newsprint prices, and growth in savings from ongoing cost control efforts, including employee count  reductions.\nThe company’s newspapers produced record earnings in 2000. Operating profit rose $231 million or 18%. The increases were due largely to contributions from the Newsquest, Newscom, Thomson and Central acquisitions. However, many other U.S. local newspapers reported earnings gains as well.\nNewsquest financial results were translated from British pounds to U.S. dollars using a weighted average rate of $1.50 for 2000, as compared to $1.62 in 1999, which mitigated some of the strong earnings growth."}]}
+{"image": "doclay/doclay_4524.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "You can also display a Node Comparison by selecting the same information as for the cluster,  and then switching the button, as shown in Figure A-1 and Figure A-2.\nFigure A-2 shows the display after switching the button.\nYou can also use real-time statistics to monitor CPU utilization, volume, interface, and MDisk  bandwidth of your system and nodes. Each graph represents 5 minutes of collected statistics  and provides a means of assessing the overall performance of your system.\nThe real-time statistics are available from the IBM Spectrum Virtualize GUI. Click  Monitoring → Performance  (as shown in Figure A-3) to open the Performance Monitoring  window.Figure A-1 IBM Spectrum Virtualize Dashboard displaying System performance overview\nFigure A-2 IBM Spectrum Virtualize Dashboard displaying Nodes performance overview\nFigure A-3 Selecting performance pane in the monitoring menu\nAppendix A. Performance data and statistics gathering  749"}]}
+{"image": "doclay/doclay_54577.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "myisamchk — MyISAM Table-Maintenance Utility\nTo ensure that  myisamchk  and the server use the same values for full-text parameters, you can place each one in both the  [mysqld]  and  [myisamchk]  sections of an option file:\nAn alternative to using  myisamchk  is to use the  REPAIR TABLE ,  ANALYZE TABLE ,  OPTIMIZE TABLE , or  ALTER TABLE . These statements are performed by the server, which knows the proper full-text parameter values to use.\nmyisamchk  supports the following options for table checking operations:\nCheck the table for errors. This is the default operation if you specify no option that selects an operation type explicitly.\nCheck only tables that have changed since the last check.\nCheck the table very thoroughly. This is quite slow if the table has many indexes. This option should only be used in extreme cases. Normally,  myisamchk  or  myisamchk --medium-check  should be able to determine whether there are any errors in the table.\nIf you are using  --extend-check  and have plenty of memory, setting the  key_buffer_size  variable to a large value helps the repair operation run faster.\nSee also the description of this option under table repair options.\nFor a description of the output format, see Section 4.6.4.5, “Obtaining Table Information with myisamchk” .\nCheck only tables that haven’t been closed properly.\nDo a repair operation automatically if  myisamchk  finds any errors in the table. The repair type is the same as that specified with the  --recover  or  -r  option.\nPrint informational statistics about the table that is checked.\nDo a check that is faster than an  --extend-check  operation. This finds only 99.99% of all errors, which should be good enough in most cases.\n568\n• --read-only ,  -T\n• --medium-check ,  -m\n• --information ,  -i\n• --force ,  -f\n• --fast ,  -F\n• --extend-check ,  -e\n• --check-only-changed ,  -C\n• --check ,  -c\n[mysqld] ft_min_word_len=3 [myisamchk] ft_min_word_len=3\n4.6.4.2 myisamchk Check Options"}]}
+{"image": "doclay/doclay_57523.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "mysqlbinlog — Utility for Processing Binary Log Files\n• --ssl-fips-mode={OFF|ON|STRICT}\n• OFF : Disable FIPS mode.\n• ON : Enable FIPS mode.\n• STRICT : Enable “strict”  FIPS mode.\n• --start-datetime= datetime\n• --start-position= N ,  -j  N\n• --stop-datetime= datetime\n• --stop-never\n--stop-never  is commonly used with  --raw  to make a live binary log backup, but also can be used without  --raw  to maintain a continuous text display of log events as the server generates them.\nThis option is used with  --read-from-remote-server . It tells  mysqlbinlog  to remain connected to the server. Otherwise  mysqlbinlog  exits when the last log file has been transferred from the server. --stop-never  implies  --to-last-log , so only the first log file to transfer need be named on the command line.\nThis option is useful for point-in-time recovery. See Section 7.5, “Point-in-Time (Incremental) Recovery” .\nStop reading the binary log at the first event having a timestamp equal to or later than the  datetime argument. See the description of the  --start-datetime  option for information about the  datetime value.\nThis option is useful for point-in-time recovery. See Section 7.5, “Point-in-Time (Incremental) Recovery” .\nStart decoding the binary log at the log position  N , including in the output any events that begin at position  N  or after. The position is a byte point in the log file, not an event counter; it needs to point to the starting position of an event to generate useful output. This option applies to the first log file named on the command line.\nThis option is useful for point-in-time recovery. See Section 7.5, “Point-in-Time (Incremental) Recovery” .\nStart reading the binary log at the first event having a timestamp equal to or later than the  datetime argument. The  datetime  value is relative to the local time zone on the machine where you run mysqlbinlog . The value should be in a format accepted for the  DATETIME  or  TIMESTAMP  data types. For example:\nmysqlbinlog --start-datetime=\"2005-12-25 11:25:56\" binlog.000003\nIf the OpenSSL FIPS Object Module is not available, the only permitted value for --ssl-fips-mode  is  OFF . In this case, setting  --ssl-fips-mode  to  ON  or STRICT  causes the client to produce a warning at startup and to operate in non- FIPS mode.\nControls whether to enable FIPS mode on the client side. The  --ssl-fips-mode  option differs from other  --ssl- xxx  options in that it is not used to establish encrypted connections, but rather to affect which cryptographic operations to permit. See Section 6.8, “FIPS Support” .\nThese  --ssl-fips-mode  values are permitted:\nNote\n614"}]}
+{"image": "doclay/doclay_7498.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "notes to the financial statements\nfor the year ended 30 June 2001\nl) Employee Entitlements\ng) Income Tax\nm) Borrowing Costs\nh) Receivables \ni) Trade and other creditors\nn) Cash Flows\no) Conditional Receipts\nj) Infrastructure Loan Facilities\nk) Non Interest Bearing Long Term Debt\np) Earnings per Share\n(i) Basic Earnings per Share\nBasic earnings per share is determined by dividing the profit after income tax attributable to shareholders by the weighted average number of shares outstanding during the financial year.\nNon interest bearing long term debt represented by the Concession Notes has been included in the financial statements at the present value of expected future repayments. The present value of expected future repayments is determined using a discount rate applicable to the consolidated entity’s other borrowing arrangements. The present value of expected future repayments will be reassessed periodically.\nThe Company has two Infrastructure Loan facilities. Under the terms of these facilities, the Company must provide cash collateral equal to the utilised amounts of the facilities. This cash collateral has been set-off against the outstanding infrastructure borrowing facilities so that no asset or liability in respect of those facilities has been recorded in the balance sheet of the consolidated entity.\nWhere the consolidated entity has received payments that are provisional or subject to legal dispute, the total value of the receipts will be accounted for as a liability and will not be reclassified as revenue until the nature of the receipt is virtually certain and supports the classification as revenue.\nFor the purpose of the statement of cash flows, cash includes cash on hand, deposits held at call with banks, investments in money market instruments and amounts held on deposit as collateral for the Infrastructure Loan facilities.\nThese amounts represent liabilities for goods and services provided to the consolidated entity prior to the end of the financial year and which are unpaid. The amounts are unsecured and are usually paid within 45 days of recognition.\nCollectibility of trade debtors is reviewed on an ongoing basis. Debts which are known to be uncollectible are written off. A provision for doubtful debts is raised when some doubt as to collection exists.\nBorrowing costs are recognised as expenses in the period in which they are incurred and include:\nIncome tax is brought to account in respect of the Company, which has adopted the liability method of tax effect accounting. Income tax expense is calculated on the operating profit of the Company, adjusted for permanent differences between taxable and accounting income. The tax effect of timing differences which arise from items being brought to account in different periods for income tax and accounting purposes is carried forward in the balance sheet as a future income tax benefit or a deferred tax liability. However, the future tax benefit relating to timing differences and tax losses is not carried forward as an asset unless the benefit is virtually certain of realisation. \nThe Company contributes the statutory minimum to superannuation plans as nominated by the employee. The superannuation plans are all accumulation funds.\nLiabilities for current and deferred employee compensation and annual leave are recognised, and are measured as the amount unpaid at the reporting date at current pay rates in respect of employees’ services up to that date.\nThe cost of current and deferred employee compensation and contributions to employee superannuation plans were charged to the statement of financial performance.\n• Interest on short-term and long-term borrowings\n• Costs incurred in connection with the arrangement of borrowings, and\n• Finance lease charges.\n39"}]}
+{"image": "doclay/doclay_51414.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "DATE_SUB()\nDATEDIFF()\nDAY()\nDAYNAME()\nDAYOFMONTH()\nDAYOFWEEK()\nDAYOFYEAR()\nDEFAULT()\nDEGREES()\nDENSE_RANK()\nE\nELT()\nSection 12.8.3, “Character Set and Collation of Function Results”\n[index top]\nSection 12.21.1, “Window Function Descriptions”\nSection 12.6.2, “Mathematical Functions”\nSection 13.1.9.2, “ALTER TABLE and Generated Columns” Section 11.6, “Data Type Default Values” Section 13.2.6, “INSERT Statement” Section 12.24, “Miscellaneous Functions” Section 13.2.9, “REPLACE Statement”\nSection 12.7, “Date and Time Functions” Section 24.6.3, “Partitioning Limitations Relating to Functions” Section 24.2, “Partitioning Types”\nSection 12.7, “Date and Time Functions” Section 24.6.3, “Partitioning Limitations Relating to Functions”\nSection 12.7, “Date and Time Functions” Section 3.3.4.5, “Date Calculations” Section 24.6.3, “Partitioning Limitations Relating to Functions”\nSection 12.7, “Date and Time Functions” Section 10.16, “MySQL Server Locale Support” Section 5.1.8, “Server System Variables”\nSection 12.7, “Date and Time Functions” Section 24.6.3, “Partitioning Limitations Relating to Functions”\nSection 12.7, “Date and Time Functions” Section 24.6.3, “Partitioning Limitations Relating to Functions”\nSection 11.2, “Date and Time Data Types” Section 12.7, “Date and Time Functions” Section 9.5, “Expressions”\n5682"}]}
+{"image": "doclay/doclay_10784.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "2004 ANNUAL REPORT TO SHAREHOLDERS\nCONDENSED CONSOLIDATED STATEMENTS OF OPERATIONS\nYear Ended December 31 (In Millions–Except Per Share Amounts)\n2004 )  2003) Variance) Revenues  $14,057)  $14,667) ($610) Expenses: Fuel and Purchased Energy  6,445)  6,615)  (170) Maintenance and Other Operation 3,611)  3,660)  (49) Asset Impairments and Other Related Charges  — )  650) (650) Depreciation and Amortization  1,300)  1,307)  (7) Taxes Other Than Income Taxes  710)  681)  29) Total Expenses  12,066)  12,913)  (847) Operating Income  1,991)  1,754)  237) Interest Income  33)  25)  8) Carrying Costs on Texas Stranded Cost Recovery  302)  —)  302) Investment Value Losses  (15)  (70)  55) Gain on Disposition of Equity Investments, Net  153)  — )  153) Other Income, Net 22)  11)  11) Interest and Other Charges  787)  840)  (53) Income Before Income Taxes  1,699)  880)  819) Income Taxes  572)  358)  214) Income Before Discontinued Operations, Extraordinary Item and  Cumulative Effect of Accounting Changes  1,127)  522)  605) Discontinued Operations, Net of Tax  83)  (605)  688) Extraordinary Loss on Texas Stranded Cost Recovery, Net of Tax  (121)  — )  (121) Cumulative Effect of Accounting Changes, Net of Tax  — ) 193)  (193) Net Income  $1,089) $110)  $979) Weighted Average Number of Shares Outstanding  396)  385)  11) Earnings (Loss) Per Share: Income Before Discontinued Operations, Extraordinary Item and  Cumulative Effect of Accounting Changes  $2.85) $1.35)  $1.50) Discontinued Operations, Net of Tax  0.21)  (1.57)  1.78) Extraordinary Loss, Net of Tax  (0.31)  — )  (0.31) Cumulative Effect of Accounting Changes, Net of Tax  — )  0.51)  (0.51) Net Income  $2.75)  $0.29)  $2.46) Cash Dividends Paid Per Share  $1.40)  $1.65)  $(0.25)\n21"}]}
+{"image": "doclay/doclay_56513.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Operators\n• D  ->  F  conversion is done such that  F  is the nearest native binary number to the input decimal string  D .\n2122\nTable 12.3 Operators\n12.4 Operators\nName Description Introduced & Bitwise AND > Greater than operator >> Right shift >= Greater than or equal operator < Less than operator <> ,  != Not equal operator << Left shift <= Less than or equal operator <=> NULL-safe equal to operator % ,  MOD Modulo operator * Multiplication operator + Addition operator - Minus operator - Change the sign of the argument\nCREATE TABLE t SELECT 000000000000000000000;\nCREATE TABLE t SELECT  integer_expr ;\nThese properties imply that  F  ->  D  ->  F  conversions are lossless unless  F  is  -inf ,  +inf , or  NaN . The latter values are not supported because the SQL standard defines them as invalid values for  FLOAT  or  DOUBLE .\nFor  D  ->  F  ->  D  conversions, a sufficient condition for losslessness is that  D  uses 15 or fewer digits of precision, is not a denormal value,  -inf ,  +inf , or  NaN . In some cases, the conversion is lossless even if  D has more than 15 digits of precision, but this is not always the case.\nImplicit conversion of a numeric or temporal value to string produces a value that has a character set and collation determined by the  character_set_connection  and  collation_connection  system variables. (These variables commonly are set with  SET NAMES . For information about connection character sets, see Section 10.4, “Connection Character Sets and Collations” .)\nThis means that such a conversion results in a character (nonbinary) string (a  CHAR ,  VARCHAR , or LONGTEXT  value), except in the case that the connection character set is set to  binary . In that case, the conversion result is a binary string (a  BINARY ,  VARBINARY , or  LONGBLOB  value).\nFor integer expressions, the preceding remarks about expression  evaluation  apply somewhat differently for expression  assignment ; for example, in a statement such as this:\nIn this case, the table in the column resulting from the expression has type  INT  or  BIGINT  depending on the length of the integer expression. If the maximum length of the expression does not fit in an  INT , BIGINT  is used instead. The length is taken from the  max_length  value of the  SELECT  result set metadata (see C API Basic Data Structures). This means that you can force a  BIGINT  rather than  INT  by use of a sufficiently long expression:"}]}
+{"image": "doclay/doclay_23885.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Macquarie Group Limited and its subsidiaries \n2014 Annual Financial Report \nmacquarie.com.au \nDirectors’ Report  –  Remuneration Report  for the financial year ended 31 March 2014  continued \nfor the financial year ended 31 March 2014  continued \nNotes to thestatutoryremuneration disclosures \nNotes on individuals \n(1) The cash portion of each individual’s profit share allocation for the reporting period when they were an Executive KMP. (2) The amount of retained profit share which is deferred to future periods and held as a notional investment in Macquarie managed-fund \nThe cash portion of each individual’s profit share allocation for the reporting period when they were an Executive KMP. (2) The amount of retained profit share which is deferred to future periods and held as a notional investment in Macquarie managed-fund  equity (Post-2009 DPS Plan). (3) The earnings on restricted profit share as described in section 1.3.3. \nequity (Post-2009 DPS Plan). (3) The earnings on restricted profit share as described in section 1.3.3.  (4) The current year amortisation for retained profit share calculated as described in note 1(xxi) to the Financial Statements.\nThe earnings on restricted profit share as described in section 1.3.3.  (4) The current year amortisation for retained profit share calculated as described in note 1(xxi) to the Financial Statements. (5) The current year amortisation for PSUs calculated as described in note 1(xxi) to the Financial Statements. Adjustments were made \nThe current year amortisation for retained profit share calculated as described in note 1(xxi) to the Financial Statements. (5) The current year amortisation for PSUs calculated as described in note 1(xxi) to the Financial Statements. Adjustments were made  during the current and prior year to reduce previously recognised remuneration expense where performance hurdles have not been met,  have been partially met or are not expected to be met.  (6) The prior year amortisation for options as described in note 1(xxi) to the Financial Statements. During the prior year, previously \nhave been partially met or are not expected to be met.  (6) The prior year amortisation for options as described in note 1(xxi) to the Financial Statements. During the prior year, previously  recognised options expense was reversed due to performance hurdles not being met or not expected to be met.\n(7) Mr Downe and Mr McLaughlin are paid in $SG and $US respectively. They have not received a base remuneration increase during the  year. The base salary for FY2014 differs to FY2013 due to exchange rate movements. (8) Mrs Sorbara was appointed to the Executive Committee on 1 January 2013. Disclosed remuneration reflects Mrs Sorbara's time as \nyear. The base salary for FY2014 differs to FY2013 due to exchange rate movements. (8) Mrs Sorbara was appointed to the Executive Committee on 1 January 2013. Disclosed remuneration reflects Mrs Sorbara's time as  KMP.  (9)  Mr Maher ceased to be a member of the Executive Committee on 3 May 2013. Disclosed remuneration reflects Mr Maher's time as \nKMP.  (9)  Mr Maher ceased to be a member of the Executive Committee on 3 May 2013. Disclosed remuneration reflects Mr Maher's time as  KMP. \n76 "}]}
+{"image": "doclay/doclay_66985.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "Assembly or for provincial officers, and upon completion thereof shall make one statement of all votes cas t for each candidates for the Assembly in each Assembly district, and one statement of all the votes, if any, cast for provincial officers Upon the completion of such statement the board shall determine therefrom what person has been elected to the Assembly  from each Assembly district, and what person has been elected to each provincial office.\nS ECTION  567 . Certificate of Result.  — All such determinations shall be reduce to writing, in duplicate, and signed by the members of the provincial board or a majority of them, and sealed with the provincial seal. One copy thereof shall be filed with the p rovincial treasurer, one forthwith with the Executive Secretary, and a certified copy thereof shall also forthwith be delivered to each elected candidate.\n[1582-25; 2582.]\n[1582-25; 2582.]\nS ECTION  568 . Who may be Certified.  — The provincial board of canvassers shall certify as elected to the office of Delegate to the Philippine Assembly and to any provincial office only persons who have obtained a majority of votes and who have filed their c ertificate of candidacy in accordance with the provisions of section five hundred and one hereof.\n[2582.]\nS ECTION  569 . Confirmation by Governor-General.  — Upon the filing of said certificate in the office of the Executive Secretary, the Governor-General shall, except as provided in the next succeeding section hereof, confirm the election of each of the candida tes for provincial office so certified as elected notwithstanding the pendency of any contest of his election in a court. Such confirmation shall not, however, prevail against the decision of the court.\n[1726-3; 2582.]\nS ECTION  570 . Confirmation Protested for Disloyalty.  — Any candidate who has received votes at a provincial election may file with the Governor-General, within thirty days after such election, a protest against the confirmation of the election of a provinci al officer elect, on account of disloyalty to the constituted Government. The Governor-General may then refuse to confirm the election of any provincial officer elect, pending the determination of the protest filed with him, which shall be investigated by  a judge of the Court of First Instance, by the Attorney-General or any of his assistant attorneys whom the Governor-General may designate to make such investigation with the least possible\nCopyright 2012 CD Technologies Asia, Inc. and Accesslaw, Inc.\nPhilippine Law Encyclopedia 2011\n183"}]}
+{"image": "doclay/doclay_2916.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "NAVWEPS OO-BOY-BO  STABIUTY AND CoMml \ndamping in roll is generally referred to as  “autorotation.” \nwarning, and preserves lateral control effec-  tiveness at high angles of attack. Also, the  airplane must maintain positive static longi-  tudinal stability at high lift coe&ients and  should demonstrate satisfactory stall recovery  characteristics. \nWhen the conventional airplane is stalk4  and some rolling-yawing displacement takes  place, the resulting autotiotation rolling mo-  ments and yawing moments start the airplane  into a self-sustaining rolling-yawing motion.  The autorotation rolling and yawing tenden-  cies of the airplane at high angles of attack  are the principal prospin moments of the  conventional airplane configuration and these  tendencies accelerate the airplane into the  spin until  some limiting  condition exists.  The stabilized spin is not necessaray  a simple  steady vertical spiral but may involve some  coupled unsteady oscillatory motion. \nIn order to visualize the principal effects of  an airplane entering a spin, suppose the air-  plane is subjected to the rolling and yawing  velocities shown in figure 4.32. The yawing  velocity to the right tends to produce higher  local velocities on the left wing than on the  right wing.  The rolling  velocity tends to  increase  the angle of attack for the downgoing  right wing (a,) and. decrease the angle of  attack for the upgoing left wing (al).  At  airplane angles of attack below the stall this  relationship produces  roll due to yaw, damping  in roll, etc., and some related motion of the  airplane in unstalled flight.  However, at  angles of attack above the stall, important  changes take place in the aerodynamic char-  acteristics.  Figure 4.32 illustrates the aerodynamic \nAn important characteristic of the mote  conventional airplane configuration is that the  spin shows a predominating contribution of  the autorotation tendency. Generally, the  conventional configuration has a spin motion  which is primarily rolling with moderate yaw.  High directional stability is favorable since it  will limit or minimize the yaw displacement  of the spinning airplane. \nacteristics.  Figure 4.32 illustrates the aerodynamic  characteristics typical of a conventional air-  plane configuration, i.e., moderate or high  aspect ratio and little-if  any-sweepback.  Ifs this airplane is provided a rolling displace-  ment when at some angle of attack above  the stall, the upgoing wing experiences a  decrease  in angle of attack with a correspond-  ing increase  in C, and decrease  in C,,. In other  words, the upgoing wing becomes  less stalled.  Similarly, the downgoing wing experiences  an increase in angle of attack with a corre-  sponding decrease  in CL and increase  in CD. Es-  sentially, the downgoing wing becomes more  stalled.  Thus, the rolling motion is aided  rather than resisted and a yawing moment is  produced in the direction of roll.  At angles  of attack below stall the rolling motion is  resisted by damping in roll and adverse yaw  is usually present. At angles of attack above  the stall, the damping in roll is negative and  a rolling motion produces a rolling moment  in the direction of the roll.  This negative \nThe fundamental requirement of the spin is  that the airplane be placed at an excessive  angle of attack to produce the autorotation  rolling  and yawing  tendencies. Generally  speaking, the conventional airplane must be  stalled .before a spin can take place. This  relationship establishes a fundamental p&r-  ciple of recovery-the airplane must be un-  stalled by decreasing  the wing angle of attack.  The most dfective procedure for the conven-  tional configuration is to use opposite rudder  to stop the sideslip, then lower the angle of  attack with  the elevators. With  sufficient  rudder power this procedure will produce a  positive recovery with  a minimum loss of  altitude.  Care should be taken during pullout  from the ensuing dive to prevent excessive  angle of attack and entry into another spin. \nIt should be appreciated  that a spin is always  a possible corollary of a stall and the self-  sustaining motion of a spin will take place at "}]}
+{"image": "doclay/doclay_49922.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "NDB Cluster Configuration Files\nTo identify a connection between two nodes it is necessary to provide their node IDs in the  [tcp] section of the configuration file as the values of  NodeId1  and  NodeId2 . These are the same unique  Id values for each of these nodes as described in Section 23.3.3.7, “Defining SQL and Other API Nodes in an NDB Cluster” .\nWhen more than this many unsent bytes are in the send buffer, the connection is considered overloaded.\nThis parameter can be used to determine the amount of unsent data that must be present in the send buffer before the connection is considered overloaded. See Section 23.3.3.14, “Configuring NDB Cluster Send Buffer Parameters” , for more information.\nDetermines the preference of DNS resolution for IP version 4 or version 6. Because the configuration retrieval mechanism employed by NDB Cluster requires that all connections use the same preference, this parameter should be set in the  [tcp default]  of the  config.ini  global configuration file.\nIf this parameter and  Checksum  are both enabled, perform pre-send checksum checks, and check all TCP signals between nodes for errors. Has no effect if  Checksum  is not also enabled.\nDefault [none] Range 1 - 255 Restart Type N (NDB 8.0.13)\nVersion (or later) NDB 8.0.13 Type or units bytes Default 0 Range 0 - 4294967039 (0xFFFFFEFF) Restart Type N (NDB 8.0.13)\nVersion (or later) NDB 8.0.26 Type or units enumeration Default 4 Range 4, 6 Added NDB 8.0.26 Restart Type IS (NDB 8.0.13)\nVersion (or later) NDB 8.0.13 Type or units boolean Default false Range true, false Restart Type N (NDB 8.0.13)\n• PreSendChecksum\n• PreferIPVersion\n• OverloadLimit\n4222"}]}
+{"image": "doclay/doclay_69535.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "This section describes how a combination of the IBM FlashSystem and another disk storage  can add redundancy and allow the use of software functionalities in other storage to provide  outstanding performance for the applications with standard I/O behavior.\nThe examples that are included in this section show the possible combinations in a  preferred  read  implementation and how they can be expanded to other applications.\nThe preferred read solution approach allows the application to use the lowest latency for  reads, or read at the speed of the IBM FlashSystem 900, because the main goal of this  solution is to send all read requests to the IBM FlashSystem 900.\nPreferred read presumes a  write mirroring  relationship in which the I/O is written to two or  more storage subsystems. Also, all read I/O requests are served from the IBM FlashSystem  900. \nA high-level example of how preferred read works is shown in Figure 11-2.\nThe preferred read solution adds another level of protection, as shown in Figure 11-3 on  page 403. For example, if a power failure occurs in a disaster situation on the IBM  FlashSystem 900 and it becomes unavailable, the application continues to access the data  without interruption and without data loss because, in preferred read, all the data is mirrored  (to both storage products).\nFigure 11-2 Preferred read overview\n402  Implementing IBM FlashSystem 900 Model AE3\n"}]}
+{"image": "doclay/doclay_28381.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "GLYPH<s45>GLYPH<s50>GLYPH<s48> GLYPH<s45>GLYPH<s49>GLYPH<s53> GLYPH<s45>GLYPH<s49>GLYPH<s48> GLYPH<s45>GLYPH<s53> GLYPH<s48> GLYPH<s45>GLYPH<s50>GLYPH<s48> GLYPH<s45>GLYPH<s49>GLYPH<s53> GLYPH<s45>GLYPH<s49>GLYPH<s48> GLYPH<s45>GLYPH<s53> GLYPH<s48> GLYPH<s45>GLYPH<s49>GLYPH<s53> GLYPH<s45>GLYPH<s49>GLYPH<s48> GLYPH<s45>GLYPH<s53> GLYPH<s48> GLYPH<s45>GLYPH<s49>GLYPH<s53> GLYPH<s45>GLYPH<s49>GLYPH<s48> GLYPH<s45>GLYPH<s53> GLYPH<s48> GLYPH<s68>GLYPH<s68>GLYPH<s45>GLYPH<s80>GLYPH<s67>GLYPH<s49> GLYPH<s80>GLYPH<s67>GLYPH<s45>GLYPH<s76>GLYPH<s65> GLYPH<s49>GLYPH<s112>GLYPH<s32>GLYPH<s51>GLYPH<s47>GLYPH<s50> GLYPH<s49>GLYPH<s112>GLYPH<s32>GLYPH<s49>GLYPH<s47>GLYPH<s50> GLYPH<s49>GLYPH<s100>GLYPH<s32>GLYPH<s53>GLYPH<s47>GLYPH<s50> GLYPH<s83> GLYPH<s105> GLYPH<s110> GLYPH<s103> 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GLYPH<s49>GLYPH<s32>GLYPH<s105>GLYPH<s49>GLYPH<s49>GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s103>GLYPH<s57> GLYPH<s47>GLYPH<s50> GLYPH<s78>GLYPH<s101>GLYPH<s117>GLYPH<s116>GLYPH<s114>GLYPH<s111>GLYPH<s110> GLYPH<s32> GLYPH<s49>GLYPH<s50>GLYPH<s54> GLYPH<s68>GLYPH<s68>GLYPH<s45>GLYPH<s80>GLYPH<s67>GLYPH<s49> GLYPH<s80>GLYPH<s67>GLYPH<s45>GLYPH<s76>GLYPH<s65> GLYPH<s78>GLYPH<s76>GLYPH<s51>GLYPH<s42> GLYPH<s80>GLYPH<s67>GLYPH<s45>GLYPH<s80>GLYPH<s75>GLYPH<s49> GLYPH<s80>GLYPH<s67>GLYPH<s45>GLYPH<s70>GLYPH<s49> GLYPH<s69>GLYPH<s120>GLYPH<s112>GLYPH<s46> GLYPH<s49>GLYPH<s32>GLYPH<s103>GLYPH<s55>GLYPH<s47>GLYPH<s50> GLYPH<s49>GLYPH<s32>GLYPH<s104>GLYPH<s49>GLYPH<s49>GLYPH<s47>GLYPH<s50> GLYPH<s50>GLYPH<s32>GLYPH<s100>GLYPH<s53>GLYPH<s47>GLYPH<s50> GLYPH<s50>GLYPH<s32>GLYPH<s100>GLYPH<s51>GLYPH<s47>GLYPH<s50> GLYPH<s51>GLYPH<s32>GLYPH<s115>GLYPH<s49>GLYPH<s47>GLYPH<s50> GLYPH<s50>GLYPH<s32>GLYPH<s102>GLYPH<s55>GLYPH<s47>GLYPH<s50> GLYPH<s49>GLYPH<s32>GLYPH<s105>GLYPH<s49>GLYPH<s51>GLYPH<s47>GLYPH<s50> GLYPH<s49>GLYPH<s32>GLYPH<s104>GLYPH<s57>GLYPH<s47>GLYPH<s50> GLYPH<s56>GLYPH<s50> GLYPH<s80>GLYPH<s114>GLYPH<s111>GLYPH<s116>GLYPH<s111>GLYPH<s110> GLYPH<s50>GLYPH<s48>GLYPH<s56> GLYPH<s80>GLYPH<s98> GLYPH<s68>GLYPH<s68>GLYPH<s45>GLYPH<s80>GLYPH<s67>GLYPH<s49> GLYPH<s50> GLYPH<s32>GLYPH<s112>GLYPH<s49> GLYPH<s47>GLYPH<s50> GLYPH<s49> GLYPH<s32>GLYPH<s103>GLYPH<s57> GLYPH<s47>GLYPH<s50> GLYPH<s49> GLYPH<s32>GLYPH<s103>GLYPH<s55> GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s100>GLYPH<s53> GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s100>GLYPH<s51> GLYPH<s47>GLYPH<s50> GLYPH<s51> GLYPH<s32>GLYPH<s115> GLYPH<s49> GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s102>GLYPH<s55> GLYPH<s47>GLYPH<s50> GLYPH<s78>GLYPH<s101>GLYPH<s117>GLYPH<s116>GLYPH<s114>GLYPH<s111>GLYPH<s110> GLYPH<s32> GLYPH<s56>GLYPH<s50> GLYPH<s80>GLYPH<s67>GLYPH<s45>GLYPH<s76>GLYPH<s65> GLYPH<s78>GLYPH<s76>GLYPH<s51>GLYPH<s42> GLYPH<s80>GLYPH<s67>GLYPH<s45>GLYPH<s80>GLYPH<s75>GLYPH<s49> GLYPH<s80>GLYPH<s67>GLYPH<s45>GLYPH<s70>GLYPH<s49> GLYPH<s69>GLYPH<s120>GLYPH<s112>GLYPH<s46> GLYPH<s83> GLYPH<s105> GLYPH<s110> GLYPH<s103> GLYPH<s108> GLYPH<s101> GLYPH<s45> GLYPH<s80> GLYPH<s97> GLYPH<s114> GLYPH<s116> GLYPH<s105> GLYPH<s99> GLYPH<s108> GLYPH<s101> GLYPH<s32> GLYPH<s69> GLYPH<s110> GLYPH<s101> GLYPH<s114> GLYPH<s103> GLYPH<s121> GLYPH<s32> GLYPH<s40> GLYPH<s77> GLYPH<s101> GLYPH<s86> GLYPH<s41> GLYPH<s49> GLYPH<s32>GLYPH<s104>GLYPH<s49> GLYPH<s49> GLYPH<s47>GLYPH<s50> GLYPH<s49>GLYPH<s51>GLYPH<s50> GLYPH<s83>GLYPH<s110> GLYPH<s49> GLYPH<s32>GLYPH<s102>GLYPH<s53> GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s112>GLYPH<s51> GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s112>GLYPH<s49> GLYPH<s47>GLYPH<s50> GLYPH<s49> GLYPH<s32>GLYPH<s103>GLYPH<s57> GLYPH<s47>GLYPH<s50> GLYPH<s49> GLYPH<s32>GLYPH<s103>GLYPH<s55> GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s100>GLYPH<s53> GLYPH<s47>GLYPH<s50> GLYPH<s50> GLYPH<s32>GLYPH<s100>GLYPH<s51> GLYPH<s47>GLYPH<s50> GLYPH<s49> GLYPH<s32>GLYPH<s104>GLYPH<s49> GLYPH<s49> GLYPH<s47>GLYPH<s50> GLYPH<s51> GLYPH<s32>GLYPH<s115> GLYPH<s49> GLYPH<s47>GLYPH<s50> GLYPH<s53>GLYPH<s48> GLYPH<s80>GLYPH<s114>GLYPH<s111>GLYPH<s116>GLYPH<s111>GLYPH<s110>\nFIG. 6: (Color online) Same as Fig. 5 but for $^{132}$Sn and $^{208}$Pb.\nFIG. 5: (Color online) The calculated single-particle energies for $^{16}$O and $^{40}$Ca by PC-PK1 in comparison with data [43] and those by DD-PC1, PC-F1, PC-LA, and NL3*.\n30"}]}
+{"image": "doclay/doclay_8682.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "rewards of ownership. We reduced gains on sales of real estate due to maximum exposure to loss by $16 million in 2001, $18 million in 2000 and $8 million in 1999.\nWe contribute to a profit sharing plan for the benefit of employees meeting certain eligibility requirements and electing participation in the plan. Contributions are determined based on a specified percentage of salary deferrals by participating employees. We rec- ognized compensation cost from profit sharing of $58 million in 2001, $55 million in 2000 and $46 million in 1999.\nWe are self-insured for certain levels of general liability, workers’ compensation, employment practices and employee medical cover- age. We accrue estimated costs of these self-insurance programs at the present value of projected settlements for known and incurred but not reported claims. We use a discount rate of 5 percent to deter- mine the present value of the projected settlements, which we con- sider to be reasonable given our history of settled claims, including payment patterns and the fixed nature of the individual settlements.\nMarriott Rewards is our frequent guest incentive marketing pro- gram. Marriott Rewards members earn points based on their spending at our lodging operations and, to a lesser degree, through participation in affiliated partners’ programs, such as those offered by airlines and credit card companies. Points can be redeemed at most Marriott company-operated and franchised properties. Points cannot be redeemed for cash.\nPoints which we accumulate and track on the members’ behalf can be redeemed for hotel stays at most of our lodging operations, airline tickets, airline frequent flier program miles, rental cars, and a variety of other awards.\nWe provide Marriott Rewards as a marketing program to  participating hotels. We charge the cost of operating the pro- gram, including the estimated cost of award redemption, to hotels based on members’ qualifying expenditures.\nEffective January 1, 2000, we changed certain aspects of our method of accounting for the Marriott Rewards program in accor- dance with Staff Accounting Bulletin (SAB) No. 101. Under the new accounting method, we defer revenue received from managed, fran- chised, and Marriott-owned/leased hotels and program partners equal to the fair value of our future redemption obligation. We deter- mine the fair value of the future redemption obligation based on statistical formulas which project timing of future point redemption based on historical levels, including an estimate of the “breakage” for points that will never be redeemed, and an estimate of the points that will eventually be redeemed. These factors determine the required liability for outstanding points. Our management and franchise agreements require that we be reimbursed currently for the costs of operating the program, including marketing, promotion, and com- municating with, and performing member services for the Marriott Rewards members. Due to the requirement that hotels reimburse us for program operating costs as incurred, we receive and recognize the balance of the revenue from hotels in connection with the Marriott Rewards program at the time such costs are incurred and expensed. We recognize the component of revenue from program partners that corresponds to program maintenance services over the expected life of the points awarded. Upon the redemption of points, we recognize\n26\nMarriott International, Inc. 2001 Annual Report\nWe account for the sales of real estate in accordance with FAS No. 66. We reduce gains on sales of real estate by the maximum exposure to loss if we have continuing involvement with the property and do not transfer substantially all of the risks and\nWe are both the lessor and lessee of land under long-term operating leases, which include scheduled increases in mini- mum rents. We recognize these scheduled rent increases on a straight-line basis over the initial lease terms.\n2000 Senior Living Distribution Lodging Services Services Total ($ in millions) SALES Management and  franchise fees $ 907 $ 33 $ — $ 940 Other 1,702 300 1,500 3,502 2,609 333 1,500 4,442 Other revenues from  managed properties 5,302 336 — 5,638 7,911 669 1,500 10,080 OPERATING COSTS AND EXPENSES Operating costs 1,673 351 1,496 3,520 Other costs from  managed properties 5,302 336 — 5,638 6,975 687 1,496 9,158 Operating profit (loss)  before corporate  expenses and interest $ 936 $(18) $ 4 $ 922 1999 Senior Living Distribution Lodging Services Services Total ($ in millions) SALES Management and  franchise fees $ 800 $ 23 $ — $ 823 Other 1,326 267 1,139 2,732 2,126 290 1,139 3,555 Other revenues from  managed properties 4,915 269 — 5,184 7,041 559 1,139 8,739 OPERATING COSTS AND EXPENSES Operating costs 1,299 308 1,118 2,725 Other costs from  managed properties 4,915 269 — 5,184 6,214 577 1,118 7,909 Operating profit (loss)  before corporate  expenses and interest $ 827 $(18) $ 21 $ 830\nGround Leases\nReal Estate Sales\nMarriott Rewards\nProfit Sharing Plan\nSelf-Insurance Programs"}]}
+{"image": "doclay/doclay_36150.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Fractional Vector Calculus and Fractional Special Function\narXiv:1001.2889v1 [math-ph] 17 Jan 2010\nMing-Fan Li, ∗ Ji-Rong Ren, † and Tao Zhu ‡\nInstitute of Theoretical Physics, Lanzhou University, Lanzhou, 730000, China\nFractional vector calculus is discussed in the spherical coordinate framework. A variation of the Legendre equation and fractional Bessel equation are solved by series expansion and numerically. Finally, we generalize the hypergeometric functions.\nPACS numbers: 02.30.Gp, 45.10.Hj, 02.40.Ky\nter we will use Riemann-Liouville fractional integral and Caputo fractional derivative.\nLet f ( x ) be a function defined on the right side of a . Let α be a positive real. The Riemann-Liouville frac- tional integral is defined by\nFractional calculus is the calculus of differentiation and integration of non-integer orders [1, 2]. During last three decades, fractional calculus has gained much attention due to its demonstrated applications in various fields of science and engineering, such as anomalous diffusion [3], fractional dynamical systems [4–6], fractional quantum mechanics [7], fractional statistics and thermodynamics [8], to name a few.\nFractional vector calculus (FVC) is important in de- scribing processes in fractal media, fractional electrody- namics and fractional hydrodynamics [9, 10]. But an effective FVC is still lacking. There are many problems in defining an effective FVC. One is that fractional in- tegral and fractional derivative are defined “half” , that is to say, they are defined only on the right or the left side of an initial point. And if we make fractional series expansion, functions are all expanded on the right or the left neighborhood of the initial point. We cannot across this cutting point. So if we want to describe the behavior near the initial point, we need define both the right and the left functions. The situation will become even more complicated when we deal with high dimensions. In this letter we will define FVC in spherical coordinate frame- work. Since in the spherical coordinate framework the radius is naturally bounded to the positive half, we need just one fractional derivative.\nUsing this frame, we will discuss the Laplacian equa- tion [11] with fractional radius derivative in 3-d space and the heat conduct equation [11] in 2-d space with cylin- drical symmetry. As a result, the corresponding special functions will be generalized. Finally, we will generalize hypergeometric functions [12–14].\nThese properties are just fractional generalizations of\nThey have the following properties:\nFor a ‘good’ function, one can define its fractional Tay- lor series\nTo start, let’s briefly recall some basic facts in frac- tional calculus [1, 2]. There are many ways to define fractional integral and fractional derivative. In this let-\nII. FRACTIONAL CALCULUS\nThe integral has a memory kernel.\nLet A ≡ [ α ] + 1. The Caputo fractional derivative is defined by\nI $^{α}$f ( x ) = 1 Γ( α ) ∫ x a ( x − ξ ) α − $^{1}$f ( ξ ) dξ. (1)\nD $^{α}$f ( x ) = I A − α d A dx $_{A}$f ( x ) = 1 Γ( A − α ) ∫ x a ( x − ξ ) A − α − 1 d A dξ $_{A}$f ( ξ ) dξ. (2)\nD $^{α}$( x − a ) β = 0 , β ∈ { 0 , 1 , ..., [ α ] } ; (3)\nD $^{α}$( x − a ) β = Γ( β + 1) Γ( β − α + 1) ( x − a ) β − $^{α}$, β otherwise; (4)\nI $^{α}$( x − a ) β = Γ( β + 1) Γ( β + α + 1) ( x − a ) β + $^{α}$. (5)\nd n dx $_{n}$x m = m ! ( m − n )! x m − $^{n}$, n ∈ N, m ̸ = 0 , (6)\n∫ x 0 dx x m = m ! ( m + 1)! x m $^{+1}$. (7)\nf ( x ) = ∞ ∑ m =0 ( D $^{α}$)$^{m}$f ( x ) ∣ x = a · [( I $^{α}$)m · 1] . (8)\n( I $^{α}$)m · 1 = 1 Γ( mα + 1) ( x − a ) $^{mα}$. (9)\nExplicitly,\n$^{∗}$Electronic address: limf07@lzu.cn\n$^{†}$Electronic address: renjr@lzu.edu.cn\n$^{‡}$Electronic address: zhut05@lzu.cn\nI. INTRODUCTION"}]}
+{"image": "doclay/doclay_38820.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Contract number: [ complete ] \nService contract conditions of December 2018 \n Interest on late payment...................................................................... 34$_{ }$ II.21.8.  Reimbursements .............................................................................................. 34$_{ }$ II.22.  Recovery.......................................................................................................... 35$_{ }$ II.23.  Recovery procedure ............................................................................ 35$_{ }$ II.23.2.  Interest on late payment...................................................................... 36$_{ }$ II.23.3.  Recovery rules in the case of joint tender........................................... 36$_{ }$ II.23.4.  Checks and audits ............................................................................................ 36$_{ }$ II.24.\n5 "}]}
+{"image": "doclay/doclay_25518.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "with the same quantum numbers as the scalar diquark current, hence it cannot mix under renormalization with any other operators. This greatly simplifies the task of determining the renormalization factor of the scalar diquark current. Composite operators typically require an additional renormalization beyond that of their component fields and parameters. In Chapter 5 the scalar diquark operator renormalization factor is determined to two-loop order by considering the correlation function\nwhere J d is the scalar diquark current (1.53) and colour indices have been omitted for brevity. Conventionally the correlation in Eq. (1.54) is calculated in momentum space and the external quark propagators are amputated, in an identical fashion to the quark self-energy (1.44) However, in the case of Eq. (1.54) the scalar diquark operator is inserted with zero momentum. This is justified because renormalization factors are momentum independent. Then the renormalized correlation function is related to the bare correlation function by\nNotice that this expression is identical to Eq. (1.48), apart from the factor of Z$_{d}$ . This extra factor is the additional renormalization that is required in order to evaluate the limit in Eq. (1.55). This extra factor is precisely the scalar diquark current renormalization factor. In Chapter 5 the scalar diquark operator renormalization factor is calculated to two-loop order using Eq. (1.55).\nRenormalized correlation functions explicitly depend on the renormalization scale µ . How- ever, bare correlation functions which are calculated prior to renormalization do not. For instance, consider an amputated bare correlation function with n = n$_{YM}$ + ˜ n + n$_{F}$ external gluon, ghost and quark propagators. Then the bare correlation function must satisfy\nwhere q$_{i}$ denote the momenta of each external propagator and m$_{i}$ is to distinguish distinct\n29\nµ d dµ Γ$_{B}$ $^{(}$q$_{1}$ , q$_{2}$ , . . . , q$_{n}$ ; α$_{B}$ , a$_{B}$ , m i B ; ϵ ) = 0 , (1.56)\nΓ d $_{R}$( q ; m$_{R}$ , a$_{R}$ , α$_{R}$ ) = lim ϵ → 0 $^{[}$Z$_{d}$ Z − 1 $_{2F}$Γ d B ( q ; m$_{B}$ , a$_{B}$ , α$_{B}$ ) ] . (1.55)\nΓ d = 〈 Ω | T $^{[}$Q ( x ) J $^{d}$(0) q ( y ) $^{]}$| Ω 〉 , (1.54)"}]}
+{"image": "doclay/doclay_10057.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\ncash flows or other valuation methods. When the fair value of the reporting unit is less than its carrying value, we allocate the fair value to all of its assets and liabilities, based on their fair values. The amount that the fair value of the reporting unit exceeds the total of the amounts assigned to its assets and liabilities is the fair value of goodwill.\n• we determine if there is an impairment by compar- ing the carrying value of goodwill to its fair value. Any excess is deducted from earnings.\nThe way we account for a foreign operation depends on whether it is self-sustaining or integrated. A self-sustain- ing foreign operation is largely independent of the parent company. An inte- grated foreign operation depends on the parent  company to finance or run  its operations.\nFor self-sustaining foreign operations, we use:\nTranslation exchange gains and losses are reflected as a currency translation adjustment in shareholders’ equity. When we reduce our net investment in a self-sustaining foreign operation, we recognize a portion of the currency translation adjustment in earnings.\nFor integrated foreign operations, we use:\nTranslation exchange gains and losses are included in Other income in the statement of operations.\nTranslation exchange gains and losses are included in Other income in the statement of operations.\n88 Bell Canada Enterprises  2004 Annual Report\n• the exchange rates on the date of the balance sheet for assets and liabilities\n• the average exchange rates during the year for revenues and expenses.\n• the exchange rates on the date of the balance sheet for monetary assets and liabilities, such as cash, accounts receivable and payable, and long-term debt\n• the historical exchange rates for non-monetary assets and liabilities, such as capital assets\n• the average exchange rates during the year for  revenues and expenses.\n• the exchange rates on the date of the balance sheet for monetary assets and liabilities\n• the historical exchange rates for non-monetary assets and liabilities\n• the average exchange rates during the year for revenues and expenses.\nFor domestic transactions made in foreign currencies, we use:\nWe assess how effective derivatives are in managing risk when the hedge is put in place, and on an on- going basis. If a hedge becomes ineffective, we stop using hedge accounting.\nWe follow these policies when accounting for  derivatives:\n• foreign exchange translation gains or losses on the net investment in foreign subsidiaries are recorded  as a currency translation adjustment. Any realized or unrealized gains or losses on instruments covering the net investment are also recognized as a currency trans- lation adjustment.\n• deferred gains or losses relating to derivatives that qualify for hedge accounting are recognized in earn- ings when the hedged item is sold or when the antici- pated transaction is ended early\n• gains and losses related to hedges of anticipated transactions are recognized in earnings or are recorded as adjustments of carrying values when the transaction takes place\n• derivatives that are economic hedges, but do not qualify for hedge accounting, are recognized at fair value. We record the change in fair value in earnings.\n• any premiums paid for financial instruments are deferred and expensed to earnings over the term of  the contract\nWe do not use derivative financial instruments for speculative or trading purposes. \nWe document all relationships between derivatives and the items they hedge, and our risk management objective and strategy for using various hedges. This process includes linking every derivative to:\n• a specific asset or liability on the balance sheet, or\n• a specific net investment in self-sustaining foreign operations, or\n• a specific firm commitment, or\n• an anticipated transaction.\nWe use various derivative financial instruments to hedge against:\n• interest rate risk\n• foreign exchange rate risk\n• changes in the price of BCE Inc. common shares relating to special compensation payments (SCPs).\nDerivative Financial Instruments\nTranslation of Foreign Currencies\nIntegrated Foreign Operations\nDomestic Transactions and Balances in Foreign Currencies\nSelf-Sustaining Foreign Operations\nTranslation of Foreign Currencies"}]}
+{"image": "doclay/doclay_63691.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "158 \nUS 9,170,489 B2 \n157 \nThe hydrogen atom of each of the alkyl group, cycloalkyl  group, aryl group or aralkyl group represented by R$_{651 }$may be  substituted with a substituent. As the substituents, an alkyl  group, a cycloalkyl group, an aryl group, an aralkyl group, a  hydroxyl group, a carboxyl group, an alkoxy group, an ary› loxy group, an alkylcarbonyloxy group and an alkyloxycar› bonyl group are exemplified. \nAs the solvent having a hydroxyl group, alkylene glycol  monoalkyl ether is preferred, and as the solvent not having a  hydroxyl group, alkylene glycol monoalkyl ether carboxylate  is preferred. \n[ 4] Basic Compounds \nIt  is preferred that the electron beam sensitive or extreme  ultraviolet radiation-sensitive resin composition in the inven› tion contains a basic compound. \nThe basic compound is preferably a nitrogen-containing  organic basic compound. \nUsable compounds are not especially limited and, for  example, compounds classified into the following (1) to (4)  are preferably used. \n( 1) Compound Represented by the Fallowing Formula (BS-1) \nIt  is preferred that, in the compound represented by for› mula (BS-1 ), one alone of three R$_{651 }$ represents a hydrogen  atom, or not all R$_{6}$ s $_{1 }$represent a hydrogen atom. \nAs the specific examples of the compound represented by  formula (BS-1), tri-n-butylamine, tri-n-pentylamine, tri-n› octylamine, tri-n-decylamine, triisodecyl-amine, dicyclo- hexylmethylamine, tetradecylamine, pentadecylamine, hexa› decylamine,  octadecylamine,  didecylamine,  methyloctadecylamine, dimethylundecylamine, N,N-dim› ethy ldodecy !amine, methy ldioctadecy !amine, N,N-dibuty !a› niline, and N,N-dihexylaniline are exemplified. \nFurther, in formula (BS-1 ), a compound in which at least  one R$_{651 }$is an alkyl group substituted with a hydroxyl group  is exemplified as a preferred embodiment. As the specific  compounds, triethanolamine and N,N-dihydroxyethylaniline  are exemplified. \nIn formula (BS-1 ), each of R$_{651 }$ independently represents  any of a hydrogen atom, an alkyl group (straight chain or  branched), a cycloalkyl group (monocyclic or polycyclic), an  aryl group and an aralkyl group. However, not all R$_{651 }$repre› sent a hydrogen atom. \nFurther, the alkyl group represented by R$_{651 }$ may have an  oxygen atom in the alkyl chain to form an oxyalkylene chain.  As the oxyalky lene chain, -CH$_{2}$CH$_{2 }$0-is preferred. As the  specific examples, tris(methoxyethoxyethyl)amine and the  compounds disclosed in U.S. Pat. No. 6,040,112, column 3,  line 60 and after, are exemplified. \nThe carbon atom number of the alky I group represented by  R$_{651 }$ is not especially restricted and is generally 1 to 20, and  preferably 1 to 12. \nThe carbon atom number of the cycloalkyl group repre› sented by R$_{651 }$is not especially restricted and is generally 3 to  20, and preferably 5 to 15. \nThe carbon atom number of the aryl group represented by  R$_{651 }$ is not especially restricted and is generally 6 to 20, and  preferably 6 to 10. Specifically a phenyl group and a naphthyl  group are exemplified. \nFurther, as a preferred basic compound represented by  formula (BS-1 ), a compound having an alkyl group in which  at least one R is substituted with a hydroxyl group is exem› plified. Specifically, for example, triethanolamine and N,N- dihydroxyethylaniline are exemplified. \nThe carbon atom number of the aralkyl group represented  by R$_{651 }$is not especially restricted and is generally 7 to 20, and  preferably 7 to 11. Specifically a benzyl group is exemplified. \nAs the basic compounds represented by formula (BS-1 ),  for example, the following compounds are exemplified. \n(BS-1) \nrO~OH  /0~  N ~ 0 ~0H  rO~OH  HO~O~N~ 0 ~0H  rO~OH  /O~N~O~OH  rO~OH  ~O~N~O~  rO~OH  /O~N~O~OH  ro~  /O~N~O~  rO~OH  /O~N~ 0 ~0H  rO~OH  ........__o~N~o~OH  rO~O~OH  /O~N~o~o~OH  rs~s-......__  /s~N~ 8 ~s-......__  rs~SH  /S~N~S~SH  rs~SH  HO~S~N~S~SH "}]}
+{"image": "doclay/doclay_21004.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "\n36 Dialog Semiconductor Plc | Annual report and accounts 2012 |  Section 3 | Management and governance\nBoard of Directors\nChairman Gregorio joined the Board in December 2003.  He has been working the semiconductor,  data storage, magnetic recording and  telecommunications industry since 1962.  Gregorio began his career with National  Semiconductor, followed by executive positions  with Motorola Inc. and Fairchild Semiconductor  Inc. He was President and CEO of National  Micronetics from 1981 to 1984, and Chairman  and CEO of American Semiconductor  Equipment Technologies from 1986 to 1990.  He co-founded Sunward Technologies in 1985 and was Chairman and CEO until 1994.  He is currently non-executive Chairman of LSI Corporation and a non-executive Director of Seagate Technology.\nJalal is a non-executive director of Lime  Microsystems Ltd since 2005 and the Chairman  of Global Semiconductor Association Europe  since 2011. He has a BSc (Hons) in Electronics  Engineering from Essex University, and holds  a PhD in Electronics from Kent University, UK. \nNon-executive Director Chris joined the Board in July 2006. He has a  career of 30 years in Telecoms and Technology.  Post his degree in Computer Science in 1982,  he spent 15 years in Nortel Research and  Development. Followed by Technology Business  Leadership roles as Chief Technology Officer  (CTO) in Energis Communications (at time of  IPO into the London Stock Exchange), then CTO  at Vodafone UK Ltd. Post-Vodafone Chris has  made over 20 technology investments from his  own investment fund, founded/co-founded  a number of start-up companies, and provides  a Strategy and Technology Advisory service for  some of the biggest technology manufacturers  in the industry as well both private and venture  investors. Presently Chris serves on the public  company boards of Kontron, Tranzeo Wireless,  as well as the private company boards of Aicent,  One Access, Navmii and Muzicall.\nChairman of Audit Committee Aidan joined the Board in October 2004.  He qualified as a Chartered Accountant with  Price Waterhouse in the 1980s before taking  senior accountant roles at Lex Service Plc and  Carlton Communications Plc. He was Finance  Director of the Sage Group Plc from 1993 until  2000 and, from December 2001 to August  2004, was a director of Communisis Plc. He is a director of, and investor in, a number of UK private technology companies.\nChief Executive Officer Jalal joined Dialog as CEO and an executive  board director in September 2005. He was  previously Vice President & General Manager  of the Mobile Multimedia business unit for  Broadcom Corporation. Prior to that Jalal was  the CEO of Alphamosaic, a venture-funded  silicon start-up company in Cambridge, focusing on video processing chips for mobile  applications. He has extensive experience  of the semiconductor industry, through his  previous professional and executive positions  at Sony Semiconductor and Texas Instruments,  managing semiconductor product businesses  and working with customers in the Far East,  Europe and North America.\nGregorio Reyes Chairman\nAidan Hughes Non-executive Director, \nChris Burke Non-executive Director\nDr Jalal Bagherli Chief Executive Officer\nGregorio Reyes Chairman Gregorio joined the Board in December 2003. \nChris Burke Non-executive Director Chris joined the Board in July 2006. He has a \nAidan Hughes Non-executive Director,  Chairman of Audit Committee Aidan joined the Board in October 2004. \nDr Jalal Bagherli Chief Executive Officer Jalal joined Dialog as CEO and an executive "}]}
+{"image": "doclay/doclay_625.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "tempting mid-day meals\ntaking time out for taste\nMemorable homemade sandwiches start with a visit to our  Di Lusso Deli Company counter. This premium line of deli meats, cheeses, and condiments can be found in the deli case in select markets.  Hormel pepperoni is another great choice  for snacks that deliver taste and satisfaction. Our  Di Lusso and other lines of pre-sliced meats generated double-digit sales gains in fiscal 2004.\nCasual lunchtime dining is a tasty mid-day booster with our  Austin Blues  BBQ and sandwiches made from Hormel Foods’ Bread Ready line of pre-sliced luncheon meats. With nearly half of the average family food dollar spent away from home, Hormel Foods has worked to become a preferred supplier of pre- portioned, pre-sliced, and pre-flavored items that build repeat Foodservice business. Foodservice sales were up 22 percent  in fiscal 2004.\nHormel Foods breakfast meats are great eye-openers, whether it’s Hormel Canadian bacon,  Hormel microwave bacon,  Hormel fully cooked bacon, or the increasingly popular  Jennie-O Turkey Store turkey bacon products. The popularity of  Hormel microwave and fully cooked bacon grew again in fiscal 2004, with sales up 19 percent.\ngetting a good start\n> Any time of day, wherever you are, there’s always a great reason to choose Hormel Foods. You provide the hunger, we’ll deliver the great flavor and convenience that keeps you moving throughout the day.\n2004 Annual Report\n13"}]}
+{"image": "doclay/doclay_37373.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "ECHA/2020/666  Annex 1 to Tender Specifications  Technical Specifications Restricted \n73 (77)\nuse third-party support during the evaluation process. The third-party supporting ECHA  shall be bound by confidentiality as laid out in the NDA. \nFrom a general point of view, all the information, reports and other documentation derived  from the contractual relationship between the contractor(s) and the Agency shall belong  to the Agency. The contractor(s) must in any case guarantee the confidentiality of this  information, including the details on the Agency’s net work infrastructure, and other  aspects related to the provided services. \nMore specifically, confidentiality obligations are laid down in Articles I.17, II.8 of the draft  Framework Contract (Annex 2 to the Tender Specifications) , as well as in the Non- Disclosure Agreement annexed to the Framework Contract (see Annex VII to the draft  Framework Contract). It is to be noted that this is the only NDA that the Agency and the  contractor(s) shall sign. In case changes to the NDA are needed, they must be  implemented only after receiving the express written agreement of the Agency. \nIn addition, the outside personnel authorised by the Agency to implement Article II.24.3  of the draft Framework Contract shall be bound by confidentiality, as laid out in the NDA. \nThe place of performance of the services under the Framework Contract shall be the  Contractor’s premises and/or ECHA’s premises, and any other place as agreed in a specific  contract depending on the nature of the tasks. By signing the FWC666, the Contractor  accepts to deliver the services at the place requested by ECHA, i.e. off-site and/or on-site  and in compliance with the existing applicable policies (e.g. Security). \nThe meetings will generally take place either at the Agency’s premises or b e held via  remote conferencing (web, phone, video), or exceptionally take place in any other place  as agreed in the specific contract. \nWhen delivering application management services, which include the possibility of  significant components of extended service hours, the services within a specific contract  may be delivered from several different locations if deemed necessary by the Contractor.  The services must nevertheless be fully compliant with the security requirements defined  in these Specifications. \nWith respect to services (excluding Application Management): \nPayments shall be made in accordance with Articles I.6, I.7, as well as II.21 and II.22 of  the draft Framework Contract, and as also detailed in the Specific Contracts. \nThe schedule and the procedure for approval of payments and the documents to be  submitted will be defined separately in each specific contract depending on the nature of  the tasks and duration of the given contract.\nP.O. Box 400, FI-00121 Helsinki, Finland | Tel. +358 9 686180 | echa.europa.eu \n9.4. Terms of payment\n• Th e Agency requires that Contractor’s staff involved in the implementation of a  specific contract shall be reachable via telephone, video conferencing and e-mail  during normal working hours. \n• Per specific contract, the Agency can accept multiple locations of the Contractor’s  resources. However, the Contractor shall request it and demonstrate that they can  guarantee smooth implementation of the relevant processes. The request shall  follow the escalation procedure (as described in section 6.1 of these specifications)  and ECHA can conclude favourably or unfavourably. The decision-making on this  matter will ultimately lie with the Agency. \n9.3. Place of performance \n9.2.2. Obligations regarding the contractor(s) (awarded contractors)\n"}]}
+{"image": "doclay/doclay_69974.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "To declare an MDisk as self-encrypting, select  Externally encrypted  when adding external  storage in the Assign Storage view, as shown in Figure 13-77.\nIBM Spectrum Virtualize products can detect that an MDisk is self-encrypting by using the  SCSI Inquiry page C2. MDisks that are provided by other IBM Spectrum Virtualize products  report this page correctly. For these MDisks, the Externally encrypted option that is shown in  Figure 13-77  not  selected. However, when added, they are still considered as self-encrypting.\nNote:  You can override external encryption setting of an MDisk detected as self-encrypting  and configure it as unencrypted by using the CLI command  chmdisk -encrypt no .  However, only do so if you plan to decrypt the data on the backend or if the backend uses  inadequate data encryption.\nFigure 13-77 Declaring MDisk as externally encrypted786  Implementing the IBM Storwize V5000 Gen2 with IBM Spectrum Virtualize V8.2.1"}]}
+{"image": "doclay/doclay_5635.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Critical Accounting Policies\nAllowance for Credit Losses \nFinancial Instruments Measured at Fair Value\nAccounting for Securitizations\nIncome Taxes\nPensions and Other Future Employee Benefits\nOther Than Temporary Impairment\nThe Notes to Bank of Montreal’s October 31, 2002 consolidated financial statements outline BMO’s significant accounting poli- cies. The policies discussed below are considered particularly important, as they require management to make significant judgments, some of which may relate to matters that are inher- ently uncertain.\nThe allowance for credit losses adjusts the value of loan assets to reflect existing credit losses. In assessing existing credit losses, we must rely on estimates and exercise judgment regarding matters for which the ultimate outcome is unknown. These  matters include economic factors, developments affecting com- panies in particular industries and specific issues with respect to single borrowers. Changes in circumstances may cause future assessments of credit risk to be materially different than current assessments and may require an increase or decrease in the allowance for credit losses. Additional information on the pro- cess and methodology for determining the allowance for credit losses can be found in the discussion of credit risk on page 29  as well as in Note 4 on page 74 of the consolidated finan- cial statements.\nBMO records trading securities and customer trading derivatives at fair value. We adjust the carrying value of investment securities to fair value when we identify a decline in value that is other than temporary. Fair value represents our estimate of the amounts for which instruments could be exchanged in a current transaction between willing parties. The fair value of most financial instru- ments is determined using quoted market prices. In situations where listed prices or quotes are not available, fair values are determined using valuation models or prices of similar securities with appropriate adjustments for any differences. Valuation models include discounted cash flow and option pricing models. Management must apply judgment in the selection of the appro- priate approach to determining fair value and the assumptions that are inputs into the valuation models. These judgments may affect the fair value and resulting gain or loss reported. Additional information about BMO’s method of determining fair value is included in Note 3 on page 72 and Note 24 on page 90 of the consolidated financial statements.\nSecuritization involves selling loans to off-balance sheet special- purpose entities or trusts (securitization entities), which then issue interest bearing investor certificates in order to fund the purchase of the loans. When these loans are securitized, they are removed from the balance sheet and we record a gain (loss) on sale. In determining the gain (loss), management must estimate future cash flows by relying on estimates of the amount of inter- est and fees to be collected from borrowers, the yield to be paid to investors, the rate at which the loans may be repaid before their scheduled maturity, expected credit losses, the fair value cost  of servicing, and the rate at which to discount these expected\nfuture cash flows. Actual cash flows may differ significantly from those estimated by management. As well, if management’s  estimate of future cash flows had been different, our gains on securitization would also have been different. Additional infor- mation about accounting for securitizations, including sensitivity analysis for key assumptions, can be found in Note 6 on page 76 of the consolidated financial statements.\nOur pensions and other future employee benefits expense is  calculated by our actuaries based on assumptions determined by management. These assumptions include the long-term rate of return on pension assets, the rate of future compensation increases, discount rates for pension and other future employee benefits obligations and the overall health care cost trend rate. If actual experience differs from the assumptions made by manage - ment, our pension and other future employee benefits expense could increase or decrease in future years as a result. Additional information regarding our accounting for pensions and other future employee benefits, including sensitivity analysis for key assumptions, is contained in Note 16 on page 81 of the consoli- dated financial statements.\nInvestment securities that are carried at cost or amortized cost  or accounted for using the equity method are reviewed at each quarter-end reporting period to determine whether the fair value is below the current recorded value. When the fair value of  any of our investment securities has declined below its current recorded value, management is required to assess whether  the decline is other than temporary. In making this assessment, we consider such factors as the type of investment, the length  of time and extent to which the fair value has been less than  the current recorded value, the financial condition and near- term prospects of the issuer, and our intent and ability to hold the investment for a sufficient period of time to allow for any anticipated recovery. The decision to record a write-down, its amount and the period in which it is recorded would change  if management’s assessment of the above factors was different. Additional information regarding our accounting for investment securities is included in Note 3 on page 72 of the consolidated financial statements.\nThe provision for income taxes is calculated based on the  expected tax treatment of transactions recorded in our consol- idated statements of income or shareholders’ equity. In deter- mining both the current and future components of our provision for income taxes, we interpret tax legislation in a variety of jurisdictions as well as make assumptions about the expected timing of the reversal of future tax assets and liabilities. If our interpretations differ from those of tax authorities or if the tim- ing of reversals is not as anticipated, our provision for income taxes could increase or decrease in future periods.\nBMO FINANCIAL GROUP ANNUAL REPORT 2002 25"}]}
+{"image": "doclay/doclay_25325.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Figure 9: The projection of the chaotic solution of the drive GDS system (2.19) on the U − j plane.\nFigure 10: The chaotic behavior of the U coordinate of system (2.19).\nReferences\n[1] M. U. Akhmet and M. O. Fen, “Entrainment by chaos,” Journal of Nonlinear Science $_{24}$, 411-439 (2014).\n[2] H. D. I. Abarbanel, N. F. Rulkov, and M. M. Sushchik, “Generalized synchronization of chaos: The auxiliary system approach,” Phys. Rev. E $_{53}$, 4528-4535 (1996).\n[3] D. D. Šijačić, U. Ebert, and I. Rafatov, “Period doubling cascade in glow discharges: Local versus global differential conductivity,” Phys. Rev. E $_{70}$, 056220 (2004).\n[4] N. F. Rulkov, M. M. Sushchik, L. S. Tsimring, and H. D. I. Abarbanel, “Generalized synchronization of chaos in directionally coupled chaotic systems,” Phys. Rev. E $_{51}$, 980-994 (1995).\n[5] L. Kocarev and U. Parlitz, “Generalized synchronization, predictability, and equivalence of unidi- rectionally coupled dynamical systems,” Phys. Rev. Lett. $_{76}$, 1816-1819 (1996).\n[6] B. R. Hunt, E. Ott, and J. A. Yorke, “Differentiable generalized synchronization of chaos,” Phys. Rev. E $_{55}$, 4029-4034 (1997).\n[7] U. S. Freitas, E. E. N. Macau, and C. Grebogi, “Using geometric control and chaotic synchronization to estimate an unknown model parameter,” Phys. Rev. E $_{71}$, 047203 (2005).\n15\n2.5 3 3.5 4 x 10 6 8 10 12 14 16 time U\n8 10 12 14 16 18 0 0.2 0.4 0.6 0.8 1 x 10 −3 U j"}]}
+{"image": "doclay/doclay_42123.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "17-30"}]}
+{"image": "doclay/doclay_22021.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Exhibit Number Exhibit 10.54 Capped Call Confirmation (Reference No. 99AMQM627) dated as of November 10, 2010 (incorporated by reference to Exhibit 10.2 to the Registrant’s Current Report on Form 8-K (file no. 1-11356) dated November 8, 2010 and filed on November 10, 2010) 10.55 Securities Purchase Agreement, dated as of May 3, 2010, by and between Radian Guaranty Inc. and Sherman Financial Group LLC (incorporated by reference to Exhibit 10.1 to the Registrant’s Current Report on Form 8-K (file no. 1-11356) dated April 30, 2010 and filed on May 4, 2010) +10.56 Amendment to Incentive Awards under 2008 Executive Long-Term Incentive Cash Plan, dated April 5, 2011 (incorporated by reference to Exhibit 99.2 to the Registrant’s Current Report on Form 8-K (file no. 1-11356) dated April 5, 2011 and filed on April 7, 2011) +10.57 Form of 2011 Performance Based Restricted Stock Unit Agreement under the 2008 Equity Compensation Plan (incorporated by reference to Exhibit 10.5 to the Registrant’s Quarterly Report on Form 10-Q (file no. 1-11356) for the period ended June 30, 2011) +10.58 Form of 2011 Stock Option Agreement under the 2008 Equity Compensation Plan (incorporated by reference to Exhibit 10.6 to the Registrant’s Quarterly Report on Form 10-Q (file no. 1-11356) for the period ended June 30, 2011) +10.59 2011 Performance Based Restricted Stock Unit  Agreement under the 2008 Equity Compensation Plan, dated  June 9, 2011, between the Registrant and Sanford  A. Ibrahim (incorporated by reference to Exhibit 10.7 to the  Registrant’s Quarterly Report on Form 10-Q (file no. 1-1 1356) for the period ended June 30, 2011) +10.60 2011 Performance Based Restricted Stock Unit Agreement under the 2008 Equity Compensation Plan, dated June 9, 2011, between the Registrant and C. Robert Quint (incorporated by reference to Exhibit 10.8 to the Registrant’s Quarterly Report on Form 10-Q (file no. 1-11356) for the period ended June 30, 2011) +10.61 2011 Stock Option Agreement under the 2008 Equity Compensation Plan, dated June 9, 2011, between the Registrant and Sanford A. Ibrahim (incorporated by reference to Exhibit 10.9 to the Registrant’s Quarterly Report on Form 10-Q (file no. 1-11356) for the period ended June 30, 2011) +10.62 2011 Stock Option Agreement under the 2008 Equity Compensation Plan, dated June 9, 2011, between the Registrant and C. Robert Quint (incorporated by reference to Exhibit 10.10 to the Registrant’s Quarterly Report on Form 10-Q (file no. 1-11356) for the period ended June 30, 2011) +10.63 Severance Agreement, dated December 23, 2011, between Teresa Bryce Bazemore and the Registrant  (incorporated by reference to Exhibit 10.1 to the Registrant’ s Current Report on Form 8-K (file no. 1-1 1356)  filed December 29, 2011) 10.64 Commutation, Reassumption and Release Agreement, effective as of January 1, 2012 (signed January 24,  2012), between Assured Guaranty Municipal Corp. (formerly Financial Security  Assurance Inc.), Assured  Guaranty (Europe) Ltd. (formerly Financial Security  Assurance (U.K.) Limited), and Radian Asset Assurance  Inc. (incorporated by reference to Exhibit 10.1 to the Registrant’ s Current Report on Form 8-K (file no.  1-11356) dated January 30, 2012 and filed on January 30, 2012) 10.65 Letter Agreement dated February 27, 2012, by and between Radian Guaranty Inc., Radian Mortgage  Assurance Inc., Radian Group Inc. and Federal National Mortgage  Association (incorporated by reference to  Exhibit 10.65 to the Registrant’s Annual Report on Form 10-K (file no. 1-1 1356) for the year ended  December 31, 2011) 10.66 Letter dated February 28, 2012 from Freddie Mac to Radian Guaranty Inc. and Radian Mortgage  Assurance  Inc. (incorporated by reference to Exhibit 10.66 to the Registrant’ s Annual Report on Form 10-K (file no.  1-11356) for the year ended December 31, 2011) 10.67 Letter dated December 20, 2012, from Freddie Mac to Radian Guaranty Inc. and Radian Mortgage  Assurance  Inc. (incorporated by reference to Exhibit 10.1 to the Registrant’ s Current Report on Form 8-K (file no.  1-11356) dated December 20, 2012 and filed on December 21, 2012)\n277"}]}
+{"image": "doclay/doclay_14360.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Court decisions and legislative activity may increase Cigna’s exposure for any of these types of claims. In some cases, substantial non-economic or punitive damages may be sought. Cigna currently has insurance coverage for some of these potential liabilities. Other potential liabilities may not be covered by insurance, insurers may dispute coverage or the amount of insurance may not be sufficient to cover the entire damages awarded. In addition, certain types of damages, such as punitive damages, may not be covered by insurance, and insurance coverage for all or certain forms of liability may become unavailable or prohibitively expensive in the future. It is possible that the resolution of one or more of the legal matters and claims described could result in losses material to Cigna’s results of operations, financial condition and liquidity.\nIn addition, Cigna must obtain and maintain regulatory approvals to market many of its products, to increase prices for certain regulated products and to consummate some of its acquisitions and divestitures. Delays in obtaining or failure to obtain or maintain these approvals could reduce the Company’s revenue or increase its costs. For further information on regulatory matters relating to Cigna, see ‘‘Business – Regulation’’ in Section H of this Form 10-K.\nIn addition, there is heightened review by federal and state regulators of health care and group disability insurance industry business and reporting practices. Cigna is frequently the subject of regulatory market conduct and other reviews, audits and investigations by state insurance and health and welfare departments, attorneys general, the Centers for Medicare and Medicaid Services (CMS) and, the Office of Inspector General (OIG). With respect to Cigna’s Medicare Advantage business, CMS and OIG perform audits to determine a health plan’s compliance with federal regulations and contractual obligations, including compliance with proper coding practices (sometimes referred to as Risk Adjustment Data Validation Audits or RADV audits) and compliance with fraud and abuse enforcement practices through Recovery Audit Contractor (RAC) audits in which third-party contractors conduct post-payment reviews on a contingency fee basis to detect and correct improper payments. In 2012, Cigna significantly expanded its Medicare business with its acquisition of HealthSpring. This expansion of its Medicare business may increase the risks the Company faces from lawsuits, regulatory audits, investigations and other regulatory matters. These regulatory reviews could result in changes to or clarifications of Cigna’s business practices or retroactive adjustments to certain premiums, and also could result in significant fines, penalties, civil liabilities, criminal liabilities or other sanctions, that could have a material adverse effect on the Company’s business, results of operation, financial condition and liquidity. Additionally, the employee benefits industry remains under scrutiny by various state and federal government agencies and could be subject to governmental efforts to bring criminal actions in circumstances that could previously have given rise only to civil or administrative proceedings.\nCigna is routinely involved in numerous claims, lawsuits, regulatory audits, investigations and other legal matters arising in the ordinary course of business, including that of administering and insuring employee benefit programs. These could include benefit claims, breach of contract actions, tort claims, disputes regarding reinsurance arrangements, employment and employment discrimination-related suits, employee benefit claims, wage and hour claims, tax, privacy, intellectual property and real estate related disputes. In addition, Cigna incurs and likely will continue to incur liability for claims related to its health care business, such as failure to pay for or provide health care, poor outcomes for care delivered or arranged, provider disputes, including disputes over compensation, and claims related to self-funded business. Also, there are currently, and may be in the future, attempts to bring class action lawsuits against the industry.\nA description of material pending legal actions and other legal matters in which Cigna is currently involved is included in Note 24 to Cigna’s Consolidated Financial Statements included in this Form 10-K. The outcome of litigation and other legal matters is always uncertain, and outcomes that are not justified by the evidence or existing law can occur. Cigna believes that it has valid defenses to the legal matters pending against it and is defending itself vigorously.\nCigna’s business is regulated at the international, federal, state and local levels. The laws and rules governing Cigna’s business and related interpretations are increasing in number and complexity, are subject to frequent change and can be inconsistent or even conflict with each other. As a public company with global operations, Cigna is subject to the laws of multiple jurisdictions and the rules and regulations of various governing bodies, including those related to financial and other disclosures, corporate governance, privacy, data protection, labor and employment, consumer protection, tax and anti-corruption. Cigna must identify, assess and respond to new trends in the legislative and regulatory environments as well as effectively comply with the various existing regulations applicable to its business. Existing or future laws, rules, regulatory interpretations or judgments could force Cigna to change how it does business, restrict revenue and enrollment growth, increase health care, technology and administrative costs, including pension costs and capital requirements, require enhancements to the Company’s compliance infrastructure and internal controls environment. Existing or future laws and rules could also require Cigna to take other actions such as changing its business practices for disability payments thereby increasing Cigna’s liability in federal and state courts for coverage determinations, contract interpretation and other actions.\nCigna’s business is subject to substantial government regulation that, along with new regulation, could increase its costs of doing business and have a material adverse effect on its profitability.\nCigna faces risks related to litigation, regulatory audits and investigations.\n20 CIGNA CORPORATION -  2012 Form  10-K\nPART I ITEM 1A Risk Factors"}]}
+{"image": "doclay/doclay_61307.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "EP 3 800 003 A1\n[Concept 11]\n[Concept 12]\n[0024] In the liquid flux according to Concept 11, the amount of current may be 10  m A or less. [0025] The rosin-modified product and the flux composition using the rosin-modified product of the present invention\nthe amount of current may be 10  A or less. [0025] The rosin-modified product and the flux composition using the rosin-modified product of the present invention can suppress the occurrence of migration due to the attachment of a water droplet or the like.\n[0026] A liquid flux of the present embodiment may be configured by dissolving a flux composition using a rosin- modified product of the embodiment described below in a solvent. A flux cored solder of the present embodiment may be configured bysealing a fluxcomposed ofaflux composition using a rosin-modifiedproductofthe presentembodiment described below in a wire solder. A solder paste of the present embodiment may be configured by adding a thixotropic agent, a solvent, and solder powder to a flux composition using a rosin-modified product of the embodiment described below.\n[0027] The rosin-modified product of the present embodiment may be produced by reaction of a rosin or a rosin derivative, an organic acid, and alkanolamine. The rosin-modified product produced in this way may be composed of a reactantofa rosinora rosin derivative and alkanolamine representedby the following StructuralFormula(1).Thenumber of carbon atoms in R may be 1 to 5.\n[0028] When a flux or the like is produced, a reactant of two molecules of alkanolamine may be included in addition to the reactant with such alkanolamine. As an example of such a reactant of two molecules of alkanolamine, a reactant of two molecules of diethanolamine can be mentioned. [0029] As an example of the reactant of a rosin or a rosin derivative and alkanolamine, reactants represented by the\nof two molecules of diethanolamine can be mentioned. [0029] As an example of the reactant of a rosin or a rosin derivative and alkanolamine, reactants represented by the following structural formulas can be mentioned. Incidentally, the following Structural Formulas (2) and (3) are an aspect of using diethanolamine as alkanolamine, and in the case of using another alkanolamine, a part corresponding to diethanolamine is replaced by the alkanolamine.\n[0023] A liquid flux may have an amount of current, which is measured by using 289Si manufactured by Fluke Cor- poration under conditions of 25°C and humidity 50% after following process, being 100  m A or less, wherein the process includes 50  l of a flux is applied to a board being a comb type electrode board type 2 (FR-4),\nwherein the process includes 50  m l of a flux is applied to a board being a comb type electrode board type 2 (FR-4), then the flux is dried at 100°C for 10 minutes, then 10  l of ion-exchange water is added dropwise on the flux, and\nthen the flux is dried at 100°C for 10 minutes, then 10  m l of ion-exchange water is added dropwise on the flux, and then a voltage (applied voltage: DC 5 V) is applied to the board for 3 minutes.\n Formula (1) NH$_{3-n}$-(R-OH)$_{n}$ (n  ≤  3)\nDETAILED DESCRIPTION\n1. Rosin-modified product\n4"}]}
+{"image": "doclay/doclay_17076.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Information pertaining to options outstanding at December 31, 2013 is as follows: \nStock -based compensation expense related to the stock options for the years then ended December 31, 2013 and 2012 totaled $ 21, 000 and $ 21, 000, respectively. The unamortized stock option expense was $ 29, 000 at December 31, 2013. This amount will be amortized over a period of 3 years. \nThe following table provides information about nonvested restricted stock for the year ended December 31, 2013: \nStock -based compensation expense related to the non - vested restricted stock for the years then ended December 31, 2013 and 2012 totaled $ 83, 000 and $ 37, 000, respectively. The unamortized compensation cost related to restricted stock at December 31, 2013 was $73, 000. \n34\nOutstanding at January 1,  2013 Granted Vested Forfeited Weighted Average Grant Date Calculated Shares Value 12, 050 $  11. 03 7, 275 11. 00 2, 275)  11. 00 Outstanding at December 31, 2013 17, 050 $  11. 02\nWeighted Average Grant Date Calculated Shares Value Nonvested options, January 1,  2013 16, 670 $  3. 14 Granted 8, 250 3. 02 Vested ( 2, 000)  3. 45 Forfeited /expired - -  Nonvested options, December 31, 2013 22, 920 $  3. 07\nOptions Outstanding Options Exercisable Weighted Average Weighted Weighted Remaining Average Average Number Contractual Exercise Number Exercise Range of Exercise Prices Outstanding Life Price Exercisable Price 8. 00 - $ 11. 49 40, 246 5. 9 years $  10. 12 17, 326 $  8. 95 11. 50 - $ 12. 50 38, 600 3. 8 years 12. 10 38, 600 12. 10 Outstanding at End of Year 78, 846 4. 9 years $  11. 09 55, 926 $  11. 12"}]}
+{"image": "doclay/doclay_65684.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "will understand that if the polyphenol content remains too high after the wash, a second wash is possible. The results for each sample are below. The polyphenol content of several of the samples below is too low. Those samples would have to be discarded. It is usual for some sugars prepared at a sugar mill to not meet specifications for various reasons.\nTable 4 - Example sugars"}]}
+{"image": "doclay/doclay_7108.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Shrink sleeve’s growing popularity is evident in food and beverage and health and beauty product packaging where 360-degree brand appeal and tamper resistance are marketing advantages. Produced as sleeves, these colorful labels are slid onto containers and heated to conform precisely to  the contours of the containers. Multi-Color’s superiority in gravure label production has made us a category leader, promoting brands such as Arizona® Iced Tea, Nestle® Smarties® and Bolthouse ™ Farms juices.\nOur newest label technology, heat transfer (HTL) has positioned us as the market share leader. Heat transfer is desirable for many health and beauty, food and beverage, and home care products, offering strong brand appeal and limitless packaging design options. By transferring ink directly onto the container surface by heat and pressure, Scotts Miracle Gro® Garden Feeder, Ocean Spray® Juice Spritzers and many other brands achieve the “no label” look from HTL technology.\nPressure-sensitive labels, the largest category in the label market because of their simple self-adhesive application, offer Multi-Color significant growth opportunities. We add unique, new features like promotional neck bands, peel-away coupons and resealable labels to give our customers a marketing advantage. Prestone®, Olay, Tropicana and Schweppes® Infusion® are all brands that benefit from the Multi-Color difference.\nPackaging Services helps national retailers and consumer product manufacturers expand their marketing and merchandising programs with gift sets, sampler kits, point-of-purchase displays and more. Known to our customers as Quick Pak, we specialize in turnkey design, assembly and fulfillment services. Such popular brands as Victoria’s Secret, Redken, Bath & Body Works, Jergens, L’Oreal and Garnier rely on Quick Pak to package their success. & “ing a\nAs the inventor of in-mold labels  (IML) for blow-molded containers, Multi-Color remains the acknowledged technology and market share leader. Ongoing development of new materials and processes strengthens our technical leadership. Peel-away coupons and in-mold labels for injection molded containers are recent technological advances. Crisco® Oil, Febreze® Fabric Care and many other well-known brands rely on our IML innovations.\nPackaging Services\nPressure  Sensitive\nShrink Sleeve\nHeat Transfer\nIn-Mold\n1\n"}]}
+{"image": "doclay/doclay_59087.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "UCI CYCLING REGULATIONS \nHowever, the right to the guarantee will apply:  1.  in respect of any contract passed to the auditor by another party; \nIn no case may the amount of the bank guarantee be less than CHF 975,000. \nIf the total contractual benefits increase following the establishment of the guarantee, the  total sum of the bank guarantee must be increased proportionately. UCI WorldTeams  must immediately inform the Professional Cycling Council of this increase indicating the  amount and the reason. They must also forward without delay to the auditor appointed  by the UCI the documentation relative to the increase including, inter alia, the additional  bank guarantee or amendment to the existing bank guarantee. The auditor shall issue a  supplementary report to the Professional Cycling Council. \nIf the amount of the contractual benefits diminishes after a guarantee has been set up,  an adjustment of the guarantee with effect from 1 April of the registration year for which  the reduction has occurred is possible only in the event of a multi-year bank guarantee,  provided that the conditions set out below are satisfied:  $_{-}$  The amount of the contractual benefits diminishes from one registration year to \nUpon the conditions above being fulfilled, the UCI WorldTeam may submit a request for  the UCI to instruct its bank of the reduction, with effect on 1$^{st}$ April of the registration year,  of the amount of the bank guarantee. \n(text modified on 20.10.05; 18.06.07; 1.07.09; 1.01.15; 24.03.17). \n(text modified on 1.01.15; 1.11.15; 24.03.17). \nFor the first registration year covered by the licence, the guarantee must be available  from 1 January of the year of registration. Should the bank guarantee for the first  registration year of the licence period not cover the totality of that period, the bank  guarantee provided from the second registration year may stipulate that it may be called \n2.15.101 The term of the guarantee may vary between one and three years depending on the term  of the UCI WorldTour licence granted to the team. In every case, it must remain valid  until 31 March after the last registration year covered by the guarantee. \n2.15.100 The UCI may not be held responsible for the inadequacy of the guarantee. \n2.15.099 If the bank guarantee proves to be inadequate the UCI WorldTeam shall be liable for a  fine of between CHF 5,000 and 50,000. Further, the UCI WorldTeam will be automatically  suspended if it fails to establish the additional or amended guarantee within one month  of the date of the decision to impose the fine and for so long as he fails to do so. In the  event of persistent default, the UCI may refer the case to the licence commission in  accordance with article 2.15.040. \n$_{-}$  The reduction will apply to the full year of registration;  $_{-}$  The reduction is acknowledged by the UCI auditor during the registration  procedure. \nthe next;  $_{-}$  The reduction will apply to the full year of registration;  $_{-}$  The reduction is acknowledged by the UCI auditor during the registration \nprovided that the conditions set out below are satisfied:  $_{-}$  The amount of the contractual benefits diminishes from one registration year to  the next;  $_{-}$  The reduction will apply to the full year of registration; \n2.15.098 The amount of the guarantee shall represent one quarter of all the gross sums due for  payment by the UCI WorldTeam to riders and persons under contract for the operation  of the team during the registration year plus the amount of CHF 15,000. \n1.  in respect of any contract passed to the auditor by another party;  2.  subsequently to the extent that the guarantee has not been exhausted on its  expiry date. \nHowever, the right to the guarantee will apply:  1.  in respect of any contract passed to the auditor by another party;  2.  subsequently to the extent that the guarantee has not been exhausted on its \nE170421 \n211 \nROAD RACES "}]}
+{"image": "doclay/doclay_73910.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Accelerated depreciation We recognized accelerated depreciation for certain assets primarily in connection with the multi-year implementation of a new global ERP system which is intended to replace our then-existing operating and financial systems.\nUndesignated commodity derivative contracts Net gain (loss) on undesignated commodity derivative contracts represents a net gain (loss) from the changes in fair value of undesignated commodity derivative contracts. The net gain (loss) is reported outside of segment operating results until such time that the underlying exposure is recognized in the segment operating results. At settlement, the net gain (loss) from the changes in fair value of the undesignated commodity derivative contracts is reported in the appropriate operating segment, allowing the results of our operating segments to reflect the economic effects of the commodity derivative contracts without the resulting unrealized mark to fair value volatility.\nNet gain (loss) on foreign currency derivative contracts We recognized a net loss primarily in connection with the settlement of foreign currency forward contracts entered into to fix the U.S. dollar cost of the May 2020 Canopy Investment.\nTransaction, integration, and other acquisition-related costs We recognized transaction, integration, and other acquisition-related costs in connection with our investments, acquisitions, and divestitures.\nImpairment of intangible assets We recognized trademark impairment losses related to our Beer segment’s Four Corners craft beer trademark asset (Fiscal 2021) and Ballast Point craft beer trademark asset (Fiscal 2020). For additional information, refer to Note 7.\nCOVID-19 incremental costs We recognized costs for payments to third-party general contractors to maintain their workforce for expansion activities at the Obregon Brewery and recognized costs for incremental wages and hazard payments to employees.\nOther gains (losses) We recognized other gains (losses) primarily in connection with (i) a gain recognized on the sale of a vineyard (Fiscal 2021), (ii) a gain on the remeasurement of our previously held equity interest in Nelson’s Green Brier to the acquisition-date fair value (Fiscal 2020), (iii) an increase in estimated fair value of a contingent liability associated with a prior period acquisition (Fiscal 2020), and (iv) recognition of previously deferred gain upon release of a related guarantee (Fiscal 2020).\nImpairment of assets held for sale We recognized impairments of long-lived assets held for sale in connection with the (i) Wine and Spirits Divestitures (Fiscal 2021, Fiscal 2020), (ii) the Concentrate Business Divestiture (Fiscal 2021, Fiscal 2020), and (iii) the Ballast Point Divestiture (Fiscal 2020). For additional information, refer to Note 7.\n#WORTHREACHINGFOR I\nConstellation Brands, Inc. FY 2021 Form 10-K\nTable of Con\nPART II ITEM 7. MD&A\nI nventory step-up In connection with acquisitions, the allocation of purchase price in excess of book value for certain inventories on hand at the\nAccelerated depreciation We recognized accelerated depreciation for certain assets primarily in connection with the multi-year implementation of a new\nUndesignated commodity derivative contracts Net gain (loss) on undesignated commodity derivative contracts represents a net gain (loss) from the changes in fair value of\nNet gain (loss) on foreign currency derivative contracts We recognized a net loss primarily in connection with the settlement of foreign currency forward contracts entered into to fix\nTransaction, integration, and other acquisition-related costs We recognized transaction, integration, and other acquisition-related costs in connection with our investments, acquisitions, and\nImpairment of intangible assets We recognized trademark impairment losses related to our Beer segment’s Four Corners craft beer trademark asset (Fiscal\nCOVID-19 incremental costs We recognized costs for payments to third-party general contractors to maintain their workforce for expansion activities at the\nOther gains (losses) We recognized other gains (losses) primarily in connection with (i) a gain recognized on the sale of a vineyard (Fiscal 2021),\nImpairment of assets held for sale We recognized impairments of long-lived assets held for sale in connection with the (i) Wine and Spirits Divestitures (Fiscal\nI nventory step-up In connection with acquisitions, the allocation of purchase price in excess of book value for certain inventories on hand at the date of acquisition is referred to as inventory step-up. Inventory step-up represents an assumed manufacturing profit attributable to the acquired business prior to acquisition.\nSelling, general, and administrative expenses Restructuring and other strategic business development costs\nSelling, general, and administrative expenses Restructuring and other strategic business development costs We recognized costs primarily in connection with costs to optimize our portfolio, gain efficiencies, and reduce our cost structure\nRestructuring and other strategic business development costs We recognized costs primarily in connection with costs to optimize our portfolio, gain efficiencies, and reduce our cost structure within the Wine and Spirits segment."}]}
+{"image": "doclay/doclay_58435.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Pascal Report  147 \n3.  Notation and Terminology \ndeclaring  programs, procedures,  and  functions,  in which a block is  given a name (identifier) by which the block may be denoted. Since  procedures and functions may be nested, scopes may be nested. \nA procedure or function has a fixed number of parameters, each of  which is denoted within the procedure or function by an identifier  called  theformal  parameter. When a procedure or function is activated,  an actual quantity has to be indicated for each parameter; the quantity  can be referenced from inside the block of the procedure or function  through  the  formal  parameter.  This quantity  is  called the  actual  parameter.  There are four kinds  of parameters:  value parameters,  variable  parameters,  procedural  parameters,  and  functional  parameters.  In  the first case, the actual parameter is an expression  which is evaluated, and the value assigned to the formal parameter,  once at the beginning of each activation of the procedure or function.  The formal parameter represents a local variable.  In  the case of a  variable parameter, the actual parameter denotes a variable and the  formal parameter denotes the same variable during the entire activation  of the procedure or function.  In  the case of procedural or functional  parameters, the actual parameter is a procedure or function identifier. \nA function is declared analogously to a procedure, except that the  function yields a result which must possess the type that is specified in  the function declaration. The result type is confined to be a simple type  or a pointer type. Functions may be used as constituents in expressions.  Assignments to non-local variables and other so-called side effects  should be avoided within function declarations. \nSyntactic  constructs  are  denoted  by  descriptive  English  words  (meta-identifiers)  written  in  italics  and  are  defined  by  rules  of  Extended Backus-Naur Form  (EBNF)  [Reference  13].  Each  rule  defines a meta-identifier by means of an EBNF expression, which  consists of one or more alternative phrases  separated by  vertical  bars ( I ). A phrase consists of zero or more elements, each of which is a  meta-identifier,  a  literal  symbol  enclosed in  quotes  (\"  \"),  or an  expression enclosed in  matching braces, brackets,  or parentheses. "}]}
+{"image": "doclay/doclay_43452.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "5-12"}]}
+{"image": "doclay/doclay_74022.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "GE Industrial cash used for operating activities  was $1.3 billion in 2020, an increase of $5.9 billion compared with 2019, primarily due to: a general decrease in net income (after adjusting for the gain on the sale of BioPharma and non-cash losses related to our interest in Baker Hughes), primarily due to COVID-19 impacts in our Aviation segment; GE Pension Plan contributions (which are excluded from GE Industrial free cash flows*) of $2.5 billion; partially offset by a decrease in cash used for operating working capital of $2.0 billion; lower provisions for income taxes of $0.9 billion; and an increase in cash paid for income taxes of $0.5 billion. Increases in Aviation-related customer allowance accruals (which is a component of All other operating activities) of $0.5 billion were $0.2 billion higher compared with 2019.\nWe utilized the provision of the Coronavirus Aid, Relief, and Economic Security Act (CARES Act) which allows employers to defer the payment of Social Security taxes and, as a result, we deferred $0.3 billion as of December 31, 2020.\nThe decrease in cash used for working capital was due to: a decrease in cash used for current receivables of $3.3 billion, which was primarily driven by lower volume, partially offset by a higher decrease in sales of receivables; an increase in cash generated by inventories, including deferred inventory, of $2.5 billion, which was primarily driven by lower material purchases, partially offset by lower liquidations; and changes in current contract assets of $0.7 billion, primarily due to a net unfavorable change in estimated profitability of $1.1 billion at Aviation (see Note 9). These decreases in cash used for working capital were partially offset by: an increase in cash used for accounts payable and equipment project accruals of $2.9 billion, which was primarily as a result of lower volume in 2020 and higher disbursements related to purchases of materials in prior periods; and lower progress collections and current deferred income of $1.7 billion, which included a partial offset due to early payments received at our Aviation Military equipment business of $0.7 billion in 2020 as part of the U.S. Department of Defense's efforts to support vendors in its supply chain during the pandemic.\nGE Industrial cash from investing activities  was $17.7 billion in 2020, an increase of $13.7 billion compared with 2019, primarily due to: net proceeds from the sale of our BioPharma business of $20.3 billion; lower capital contributions from GE Industrial to GE Capital of $2.0 billion; partially offset by the nonrecurrence of proceeds from the spin-off of our Transportation business of $6.2 billion (including the sale of our retained ownership interests in Wabtec); and lower proceeds from sales of our stake in Baker Hughes of $2.6 billion (including the sale of a portion of our retained ownership interests in 2020). Cash used for additions to property, plant and equipment and internal-use software, which is a component of GE Industrial free cash flows*, was $1.7 billion in 2020, down $0.8 billion compared with 2019.\nGE Industrial cash used for financing activities  was $10.9 billion in 2020, an increase of $3.3 billion compared with 2019, primarily due to: higher repayments of intercompany loans from GE Capital of $7.5 billion; a reduction in commercial paper of $3.0 billion; reductions of other debt of $0.8 billion; partially offset by new principal issuances of long-term debt of $7.5 billion in the second quarter of 2020 and lower repurchases of long-term debt of $0.6 billion.\nGE INDUSTRIAL CASH FLOWS FROM DISCONTINUED OPERATIONS . GE Industrial cash used for investing activities in 2019 was primarily due to the deconsolidation of Baker Hughes cash as a result of the reduction in our ownership interest in the segment in the third quarter of 2019. GE Industrial cash used for financing activities in 2019 primarily reflects payments of Baker Hughes dividends to noncontrolling interests.\nGE 2020 FORM 10-K  29\n*Non-GAAP Financial Measure\n2019 CFOA (GAAP) AND FCF BY SEGMENT (NON-GAAP)\n2018 CFOA (GAAP) AND FCF BY SEGMENT (NON-GAAP)\n2018 CFOA (GAAP) AND FCF BY SEGMENT (NON-GAAP) Power Renewable Energy Aviation Healthcare Corporate & Eliminations GE Industrial CFOA (GAAP) $ (1,849) $ 406  $ 5,373  $ 3,485  $ (6,714) $ 701  Add: gross additions to property, plant and equipment (358) (297) (1,070) (378) (131) (2,234) Add: gross additions to internal-use software (66) (11) (73) (90) (67) (306) Less: GE Pension Plan funding —  —  —  —  (6,000) (6,000) Less: taxes related to business sales —  —  —  —  (180) (180) Free cash flows (Non-GAAP) $ (2,273) $ 98  $ 4,230  $ 3,018  $ (731) $ 4,341 \n2019 CFOA (GAAP) AND FCF BY SEGMENT (NON-GAAP) Power Renewable Energy Aviation Healthcare Corporate & Eliminations GE Industrial CFOA (GAAP) $ (1,200) $ (512) $ 5,552  $ 3,024  $ (2,250) $ 4,614  Add: gross additions to property, plant and equipment (277) (455) (1,031) (395) (59) (2,216) Add: gross additions to internal-use software (46) (14) (107) (79) (28) (274) Less: GE Pension Plan funding —  —  —  —  —  —  Less: taxes related to business sales —  —  —  —  (198) (198) Free cash flows (Non-GAAP) $ (1,523) $ (980) $ 4,415  $ 2,550  $ (2,139) $ 2,322 "}]}
+{"image": "doclay/doclay_34581.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "8\n0.01 0.1 1 10 Δ T [K] 0.1 1 10 d [nm] q$_{s}$ = 0.0; N$_{i}$ = 0.5 q$_{s}$ = 0.0; N$_{i}$ = 2.0 q$_{s}$ = 0.5; N$_{i}$ = 0.5 q$_{s}$ = 0.5; N$_{i}$ = 2.0 [q$_{s}$] = C/m$^{2}$; [N$_{i}$] =  µ mol/m 2\n0.01 0.1 1 10 Δ T [K] 0.1 1 10 d [nm] q$_{s}$ = 0.0; N$_{i}$ = 0.5 q$_{s}$ = 0.0; N$_{i}$ = 2.0 q$_{s}$ = 0.5; N$_{i}$ = 0.5 q$_{s}$ = 0.5; N$_{i}$ = 2.0 [q$_{s}$] = C/m$^{2}$; [N$_{i}$] =  µ mol/m 2\nFIG. 5: Thickness of the quasi-liquid layer for the ice/liquid/gold system ( A H = 1 . 573 × 10 $_{−}$21 J). In contrast to the ice/liquid/fused quartz system, Fig. 4, layer collapse occurs at thicknesses above 0 . 1 nm even for the cases with- out surface charges. This is due to the stronger attractive dispersion forces in the ice/liquid/gold system. Layer col- lapse for the cases with surface charges is altered only for the higher impurity density N i = 2 . 0 µ mol/m 2 relative to the ice/liquid/fused quartz system, because at d ≈ 1 nm disper- sion forces are weak compared to the electrostatic force.\nFIG. 4: Thickness d of the quasi-liquid layer for the ice/liquid/fused quartz system ( A H = 3 . 0 × 10 $_{−}$23 J) as a function of the undercooling Δ T . For moderate undercool- ing the system is dominated by the colligative effect. In this regime the layer thickness increases with impurity density N i . At intermediate undercooling the effect of immobile surface charges leads to a thickening of the quasi-liquid layer which is most effective for low impurity concentrations leading to a decrease of the layer thickness when the impurity density is increased. At large undercooling surface charge induced layer collapse is observed, while layer collapse due to dispersion forces alone occurs at layer thicknesses below 0 . 1 nm.\nRepulsive dispersion forces The result of the analysis following Eq. (29) can be tested on the ice/liquid/silicon system which has a Hamaker constant of A$_{H}$ = − 1 . $^{66}$× 10 − 21 J [4], the negative sign implying repulsive disper- sion forces. As shown in Fig. 6 the system displays the expected colligative behavior for low undercooling and an enhanced layer thickness for intermediate un- dercooling where the effect of surface charges enhances the colligative effect, which alone would yield a straight line, d ∝ N − 1 i . For intermediate undercooling the fig- ure reveals a transition from a regime of low impurity density where the layer thickness decreases when N$_{i}$ increases , to a regime of high impurity density where the colligative effect dominates and accordingly an in- crease of d is observed when N$_{i}$ increases . From the fig- ure the locus of the transition can be estimated to be Δ T$_{c}$ ≈ 10 − 20 K, d$_{c}$ ≈ 1 nm, and N$_{i,c}$ ≈ 2 . 5 µ mol/m $^{2}$. This is in good agreement with the analytical result ob- tained from Eq. (29), Δ T$_{c}$ = 9 . 6 K, d$_{c}$ = 1 . 25 nm, and N$_{i,c}$ = 3 . 97 µ mol/m $^{2}$. It should be noted that the an- alytical result is exact only in the limit q$_{s}$ → 0 but the complete solution of Eq. (22) shows that it applies quali- tatively and semi-quantitatively for surface charge densi- ties as high as q$_{s}$ = 0 . 5 C/m $^{2}$. For the ice/liquid/silicon system no layer collapse is observed. This results from the fact that dispersion forces, which dominate at low layer thicknesses, are repulsive and stabilize the quasi- liquid layer. However, at impurity densities N$_{i}$ smaller than those considered in Fig. 6, the Debye-H¨ uckel ex- pression for F$_{elec}$ generates an attractive force in the ice/liquid/silicon system with q$_{s}$ = 0 . 5 C/m 2 at suffi-\nthe existence of an interval of intermediate undercooling where the layer thickness decreases when the impurity density increases. Recall that the reason for this is that at low impurity concentrations the electrostatic force is less effectively screened and hence the repulsion due to surface charges has a stronger effect, leading to a larger layer thickness than for higher impurity concentrations. When the system is undercooled further the collapse of the quasi-liquid layer can be observed in the figure. Here, because of the weakness of dispersion forces, the collapse is a consequence of the electrostatic force becoming at- tractive at low layer thicknesses. Collapse for the cases without surface charges cannot be observed in Fig. 4 as it occurs at thicknesses below 0 . 1 nm (c.f., Fig. 2). In order to see layer collapse at larger layer thicknesses a larger Hamaker constant is required, as provided by the ice-liquid-gold system. To see this, we plot solutions of Eq. (22) for this system in Fig. 5 for the same pa- rameters as considered in Fig. 4 for the ice-liquid-fused quartz system. Layer collapse is now observed at thick- nesses above 0 . 1 nm even for the configurations with- out surface charges. For the configurations with surface charges we observe that for N$_{i}$ = 0 . 5 µ mol/m 2 layer col- lapse is not altered by the stronger dispersion forces while for N$_{i}$ = 2 . 0 µ mol/m 2 the stronger attractive dispersion forces lead to a layer collapse at a larger layer thickness compared to the corresponding configuration considered in Fig. 4. Thus, in this case stronger dispersion forces drive layer collapse."}]}
+{"image": "doclay/doclay_32119.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Point ξ = x\nThe important limiting case in which the expressions (28), (29) are reduced to much simpler forms is the point x = ξ .\nPoint ξ = 1\nAnother notable limiting case is ξ = 1:\nand\nForward limit and G ( E,M ) 0 ( x, t )\nLet us introduce the convenient notations for the combinations of the t -dependent parton densities to which GPDs H g ( E,M ) are reduced in the limit ξ → 0:\n12\nH g ( E $^{)}$( ξ, ξ, t ) = 2 3 π ξ ∫ 1 1$_{−}$ √ 1$_{−}$ ξ 2 ξ dy y ∞ ∑ ν =0 y 2 $^{ν}$G ( E ) 2 ν ( y, t ) [ 1 √ 2 y ξ − y 2 − $_{1}$] ; H g ( M $^{)}$( ξ, ξ, t ) = − ξ 2 ∂ ∂ξ 2 3 π ∫ 1 1$_{−}$ √ 1$_{−}$ ξ 2 ξ dy y ∞ ∑ ν =0 y 2 $^{ν}$G ( M ) 2 ν ( y, t ) [ 1 √ 2 y ξ − y 2 − $_{1}$] . (31)\nH g ( E $^{)}$( x, ξ = 1 , t ) = 1 2 (1 − x $^{2}$)2 ∞ ∑ ν =0 ∫ 1 0 dyy [ 1 (1 − 2 xy + y $^{2}$) 5 2 + 1 (1 + 2 xy + y $^{2}$) 5 2 − 2$^{2}$$^{ν}$ − 2 ∑ j =0 even y j C$^{5}$ 2 j ( x )   G ( E ) 2 ν ( y, t ) ; (32)\nH g ( M $^{)}$( x, ξ = 1 , t ) = 1 2 (1 − x $^{2}$)2 ∞ ∑ ν =0 ∫ 1 0 dy [ 1 (1 − 2 xy + y $^{2}$) 5 2 + 1 (1 + 2 xy + y $^{2}$) 5 2 − 2$^{2}$$^{ν}$ − 2 ∑ j =0 even y j C$^{5}$ 2 j ( x )   y 3 − 2 ν ∂ ∂y ( y 2 ν ∂ ∂y G ( M ) 2 ν ( y, t ) ) . (33)\nH g ( E $^{)}$( x, ξ = 0 , t ) = xg ( x, t ) + τxe $^{g}$( x, t ) ≡ xg ( E $^{)}$( x, t ) ; H g ( M $^{)}$( x, ξ = 0 , t ) = xg ( x, t ) + xe $^{g}$( x, t ) ≡ xg ( M $^{)}$( x, t ) , (34)"}]}
+{"image": "doclay/doclay_910.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS\nIssuance of Senior Notes\nThe table below provides a summary of the senior notes that we issued in 2013 and 2012.\nDate Issued Principal amount Due date Interest rate Discount at issuance Total gross proceeds 1 Transaction costs and discounts 2 2013 Issuances March 7, 2013 US $ 500 2023 3.00% 99.845% March 7, 2013 US $ 500 2043 4.50% 99.055% Subtotal US $ 1,000 Cdn $1,030 Cdn $15 October 2, 2013 US $ 850 2023 4.10% 99.813% October 2, 2013 US $ 650 2043 5.45% 99.401% Subtotal US $ 1,500 Cdn $1,548 Cdn $20 2012 Issuances June 4, 2012 Cdn $ 500 2017 3.00% 99.921% June 4, 2012 Cdn $ 600 2022 4.00% 99.600% Subtotal Cdn $1,100 Cdn $1,100 Cdn $ 9\n1 Gross proceeds before transaction costs and discounts.\n2 Transaction costs and discounts are included as deferred transaction costs in the carrying value of the long-term debt, and recognized in net income using the effective interest method.\nEach of the above senior notes are unsecured and guaranteed by RCP, ranking equally with all of RCI’s other senior notes and debentures, bank credit and letter of credit facilities. We use derivatives to hedge the foreign exchange risk associated with the principal and interest components of all our US dollar denominated senior notes and debentures (see note 20).\nRepayment of Senior Notes and Related Derivative Settlements In June 2013, we repaid or bought the entire outstanding principal amount of our US $350 million ($356 million) senior notes due 2013. At the same time, the associated Debt Derivatives were also settled at maturity. See note 20 for more information about our Debt Derivatives.\nThe table below shows the principal repayments on our long-term debt due in each of the next five years and thereafter as at December 31, 2013.\nAt December 31, 2013 and 2012, we were in compliance with all financial covenants, financial ratios and all of the terms and conditions of our long-term debt agreements.\nThe repayment dates of certain debt agreements can also be accelerated if there is a change in control of RCI.\ndividends, all of which are suspended in the event the public debt securities are assigned investment grade ratings by at least two of three specified credit rating agencies. As at December 31, 2013, these public debt securities were assigned an investment grade rating by each of the three specified credit rating agencies and, accordingly, these restrictions have been suspended as long as the investment grade ratings are maintained. Our other senior notes do not have any of these restrictions, regardless of the related credit ratings.\nOur objectives in managing capital are to ensure we have sufficient liquidity to meet all of our commitments and to execute our business plan. We define capital that we manage as shareholders’ equity (including issued capital, share premium, retained earnings, hedging reserve and available-for-sale financial assets reserve) and indebtedness (including current portion of our long-term debt, long-term debt and short-term borrowings).\nWe manage our capital structure commitments and maturities and make adjustments based on general economic conditions, financial markets and operating risks and our investment and working capital requirements. To maintain or adjust our capital structure, we may, with approval from our Board of Directors, issue or repay debt and/or short- term borrowings, issue shares, repurchase shares, pay dividends or undertake other activities as deemed appropriate under the circumstances. The board reviews and approves any material transactions that are not part of the ordinary course of business, including proposals for acquisitions or other major investments or divestitures, financing transactions and annual capital and operating budgets.\nWe monitor debt leverage ratios such as adjusted net debt to adjusted operating profit as part of the management of liquidity and shareholders’ return to sustain future development of the business, conduct valuation-related analyses and make decisions about capital.\nThe 8.75% debentures due in 2032 contain debt incurrence tests and restrictions on additional investments, sales of assets and payment of\nThe provisions of our $2.0 billion bank credit facility described above impose certain restrictions on our operations and activities, the most significant of which are leverage related maintenance tests.\nOur effective weighted average rate on all debt and short-term borrowings, as at December 31, 2013, including the effect of all of the associated Debt Derivative instruments (see note 20), was 5.5% (2012 – 6.1%).\nWe recorded $23 million in foreign exchange losses in 2013 (2012 – $9 million gain) in finance costs in the consolidated statements of income. These were related to the translation of long-term debt that was not hedged on an accounting basis.\nNOTE 19: CAPITAL RISK MANAGEMENT\nPrincipal Repayments\nForeign Exchange\nWeighted Average Interest Rate\nTerms and Conditions\n112 ROGERS COMMUNICATIONS INC. 2013 ANNUAL REPORT\n2014 $ 1,170 2015 883 2016 1,000 2017 500 2018 1,489 Thereafter 8,394 $ 13,436"}]}
+{"image": "doclay/doclay_17074.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS\nGeographic External Sales and Operating Profit. Geographic external sales and operating profits are attributed to the geographic regions based on their location of origin. U.S. external sales include export sales to commercial customers outside the U.S. and sales to the U.S. government, commercial and affiliated customers, which are known to be for resale to customers outside the U.S. Long-lived assets are net fixed assets attributed to the specific geographic regions.\nMajor Customers. Net Sales include sales under prime contracts and subcontracts to the U.S. government, primarily related to Pratt & Whitney, Hamilton Sundstrand and Sikorsky products, as follows:\nEXTERNAL NET SALES OPERATING PROFITS LONG-LIVED ASSETS (Dollars in millions) 2011 2010 2009 2011 2010 2009 2011 2010 2009 United States Operations $30,438 $ 28,911 $27,990 $4,586 $ 4,112 $ 3,771 $2,974 $ 3,013 $3,096 International Operations Europe 12,601 11,957 12,216 2,136 1,872 1,743 1,210 1,282 1,346 Asia Pacific 9,394 7,986 7,173 1,513 1,229 990 883 839 845 Other 5,380 5,374 4,991 713 759 476 760 804 714 Eliminations and other 377 98 55 (849) (786) (603) 374 342 363 Consolidated $ 58,190 $54,326 $52,425 $8,099 $7,186 $6,377 $6,201 $6,280 $6,364\n(Dollars in millions) 2011 2010 2009 Europe $2,310 $ 1,918 $2,089 Asia Pacific 2,506 2,688 2,430 Other 3,141 2,690 2,477 $7,957 $7,296 $6,996\n(Dollars in millions) 2011 2010 2009 Pratt & Whitney $3,696 $ 4,081 $3,942 Hamilton Sundstrand 1,043 1,137 1,230 Sikorsky 4,967 4,529 3,979 Other 125 153 127 $ 9,831 $9,900 $9,278\n88\nUNITED TECHNOLOGIES CORPORATION\nSales from U.S. operations include export sales as follows:"}]}
+{"image": "doclay/doclay_39321.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Contract number: EEAS-618-DELBRBB-SER-FWC-2019 \n Template of June 2018 Updated November 2018 \nUser roles enabling these  e-PRIOR  authorised persons to sign legally binding documents such  as specific tenders or specific contracts are granted only upon submission of supporting  documents proving that the authorised person is empowered to act as a legal representative of  the contractor.\nII.6. LIABILITY \nII.6.1 The contracting authority is not liable for any damage or loss caused by the contractor,  including any damage or loss to third parties during or as a consequence of  implementation of the FWC .\nII.6.2 If required by the relevant applicable legislation, the contractor must take out an  insurance policy against risks and damage or loss relating to the  implementation of the  FWC . It must also take out supplementary insurance as reasonably required by  standard practice in the industry. Upon request, the contractor must provide evidence  of insurance coverage to the contracting authority. \nII.6.3 The contractor is liable for any loss or damage caused to the contracting authority  during or as a consequence of  implementation of the FWC , including in the event of  subcontracting, but only up to an amount not exceeding three times the total amount of  the relevant specific contract. However, if the damage or loss is caused by the gross  negligence or wilful misconduct of the contractor or of its  personnel  or subcontractors,  the contractor is liable for the whole amount of the damage or loss. \nII.6.4 If a third party brings any action against the contracting authority in connection with  the  implementation of the FWC , including any action for alleged breach of intellectual  property rights, the contractor must assist the contracting authority in the legal  proceedings, including by intervening in support of the contracting authority upon  request. If the contracting authority’s liability towards the third party is established and that  such liability is caused by the contractor during or as a consequence of the  implementation of the FWC , Article II.6.3 applies.\nII.6.5 If the contractor is composed of two or more economic operators (i.e. who submitted a  joint tender), they are all jointly and severally liable to the contracting authority for the  implementation of the FWC . \nII.6.6 The contracting authority is not liable for any loss or damage caused to the contractor  during or as a consequence of  implementation of the FWC , unless the loss or damage  was caused by wilful misconduct or gross negligence of the contracting authority. \nII.7.1 The contractor must take all the necessary measures to prevent any situation of  conflict  of interest  or  professional conflicting interest .\nII.7.2 The contractor must  notify  the contracting authority in writing as soon as possible of  any situation that could constitute a  conflict of interest or a  professional conflicting  interest  during the  implementation of the FWC . The contractor must immediately take  action to rectify the situation.\nII.7. CONFLICT OF INTEREST AND PROFESSIONAL CONFLICTING INTERESTS \n17 "}]}
+{"image": "doclay/doclay_80455.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "4. Click  OK  to complete the operation. If you must abandon the operation, click  Cancel  to  return to the Security Settings window.\nGLYPH<SM590000> Username: The name of a user who is authorized by the selected authentication policy.\nGLYPH<SM590000> Role: The role that is assigned to the user under the selected authentication policy.\nGLYPH<SM590000> Cluster Access: A list of all the clusters in the grid for which the user and user role are  authorized by the selected authentication policy. \n1. On the TS7700 MI, click  Access →  Security Settings  from the left navigation window.\n2. From the menu, select  Add Direct LDAP Policy  and click  GO. \n3. Mark the check boxes to grant a local or remote access to the TS7700 to the IBM SSR so  that the SSR can perform service support.\nGLYPH<SM590000> User Distinguished Name: The user distinguished name is used to authenticate to the  LDAP authentication service. This field supports a maximum length of 254 Unicode  characters, for example:\nGLYPH<SM590000> Password: The password is used to authenticate to the LDAP authentication service. This  field supports a maximum length of 254 Unicode characters.\n474  IBM TS7700 Release 4.2 Guide\nCN=Administrator,CN=users,DC=mycompany,DC=com\nThe values in the following fields are required if secure authentication is used or anonymous  connections are disabled on the LDAP server:\nNote:  LDAP external authentication policies are not available for backup or recovery  through the backup or restore settings operations. Record it, keep it safe, and have it  available for a manual recovery as dictated by the security standards. \nTo add a Direct LDAP Policy for a TS7700 grid, complete the following steps:\nImportant:  When a Direct LDAP policy is enabled for a cluster, service personnel are  required to log in with the setup user or group. Before enabling LDAP authentication,  create an account that can be used by service personnel. Also, the user can enable an  IBM SSR to connect to the TS7700 through physical access or remotely by selecting those  options in the DIRECT LDAP POLICY window. \nA  Direct LDAP Policy  is an external policy that maps user, group, and role relationships.  Users are authenticated and authorized through a direct communication with an LDAP server.  This section highlights the various windows that are required to manage a Direct LDAP policy. \nTo return to the Test Authentication Policy window, click  Close Window . To return to the  Security Settings window, click  Back  at the top of the Test Authentication Policy results  window.\nWhen the authentication policy test completes, the Test Authentication Policy results window  opens to display results for each selected cluster. The results include a statement indicating  whether the test succeeded or failed, and if it failed, the reason for the failure. The Test  Authentication Policy results window also displays the Policy Users table. Information that is  shown on that table includes the following fields:\nAdding a Direct LDAP policy"}]}
+{"image": "doclay/doclay_20834.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "6\nAs part of the celebrations of the  175th anniversary of the formation  of The Australian Gas Light Company,  AGL has been highlighting its long  history of adapting to changes in  energy technologies and customer  needs. The outcomes that have been  achieved this year demonstrate that  AGL is continuing in that proud tradition.  The future promises more change.\nChairman’s  Report\nJeremy Maycock, Chairman\nJeremy Maycock, Chairman\nStrategy\nFinancial Results\nThe statutory net profit of your company was  $114.9 million, compared with $558.7 million  last year. This year’s result includes significant  items totalling $155.1 million, most of which  arise from the acquisition and funding of  the Loy Yang A power station in Victoria’s  Latrobe Valley. These items will not recur  in future years.\nA more useful comparison for shareholders  is AGL’s underlying net profit which increased  to $482.0 million, an increase of 11.8% on  the underlying net profit of $431.1 million  reported in 2011. Underlying profit is  the statutory profit adjusted to exclude  significant items and the effect of marking to  market certain electricity hedges AGL has in  place to manage the wholesale cost of buying  electricity in the National Electricity Market.\nThis has been a year of transformation  for AGL as we continue our strategy  of vertical integration.\nThere are two core elements to  AGL’s strategy.\nThe first concerns the “demand” side of the  business. This relates to the energy products  and services we provide to our customers.  If AGL is to continue to grow over the long  term, it is crucial that we continue to expand  this side of the business as it is this which  underpins investment in our upstream  supply assets.\nThis Annual Report details the considerable  progress made during 2012 in all these  areas. I will highlight just two items that  illustrate the disciplined approach AGL has  taken in making investment decisions to  improve shareholders’ returns.\nIn our Retail business, the number of  new customer accounts increased by  approximately 180,000. Most of these  were new electricity customers acquired  in New South Wales as part of a three year  organic growth strategy we commenced  in January 2011. This followed AGL’s  decision, in late 2010, not to buy one  of the electricity retail businesses being  offered for sale by the New South Wales  government because the price that we  would have been required to pay would not  have represented value for shareholders.  That decision has been vindicated. Since  the launch of the organic growth strategy,  AGL has acquired approximately 200,000  new electricity customers in New South  Wales. The discounts and incentives we have  offered to encourage customers to switch  to AGL have been a small fraction of the  average cost that would have been incurred  had we purchased a retail business from  the New South Wales government. AGL has  also had the advantage of being able to fully  manage the new customer accounts using  our own SAP billing platform.\nThe other concerns the “supply” side of  the business. Over the last few years, we  have been investing substantial amounts  of capital to increase our ownership of the  assets that produce gas and electricity to  meet our customers’ needs. This will allow  us to better manage the wholesale costs  of gas and electricity in the years ahead so  that we can remain a competitive supplier  of energy to our customers.\nIn growing both the demand side and supply  side of the business, it is also important  that the investments we make earn a  satisfactory return for our shareholders.  This means we need to be disciplined in  determining the price we are prepared to  pay to acquire new assets. We need to form  considered views on the range of factors  that may affect investment returns over  the long term. These scenarios involve  financial considerations such as future  wholesale electricity prices, and future  demand for energy. They also include  non-financial considerations including, for  example, future State and Commonwealth  government policies on energy, and the  social and reputational effects of investing  in certain types of assets.\nOn the supply side of the business, the most  significant strategic development was the  decision to buy the Loy Yang A power station.\nWe expect the acquisition to be accretive  to earnings from FY2013. Before the Board  approved the largest transaction AGL  has undertaken since the demerger from  Alinta in 2006, it needed to be convinced  about a number of matters other than just  the immediate effect on earnings. These  included consideration of the effect the \nA fundamental indicator of financial success  is the returns generated on funds employed.  A pleasing feature of this year’s result is the  improvement, from 8.9% to 9.3%, in the  return on funds employed in the business.  Although still below the level we would like  it to be to fully reward shareholders for the  risks of investing in the energy industry, the  improvement shows that we are heading in  the right direction.\nThe Board has declared a fully franked final  dividend of 32 cents per share, an increase  on the final dividend of 31 cents per share  declared last year. Shareholders should also  note that it will be paid on all issued shares,  including those issued at a discount in June  2012. In other words, the new shares will  participate fully in the final dividend even  though the funds received by AGL from  the share issue were only deployed in the  business for a few days during the year.\nReturns to Shareholders\n"}]}
+{"image": "doclay/doclay_22440.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Algonquin Power & Utilities Corp. – Consolidated Financial Statements\nALGONQUIN POWER & UTILITIES CORP.  Notes to the Consolidated Financial Statements \nALGONQUIN POWER & UTILITIES CORP.  Notes to the Consolidated Financial Statements  December 31, 2012 and 2011   (in thousands of Canadian dollars except as noted and amounts per share) \nDecember 31, 2012 and 2011   (in thousands of Canadian dollars except as noted and amounts per share) \n1.  Significant accounting policies (continued)\n(u) Recognition of revenue \nRevenue derived from non-regulated energy generation sales, which are mostly under long- term power purchase contracts, is recorded at the time electrical energy is delivered. \nRevenues related to utility electricity and natural gas sales and distribution are recorded based  on metered consumptions by customers, which occur on a systematic basis throughout a  month, rather than when the electricity or natural gas is delivered. At the end of each month,  the electricity and natural gas delivered to the customers from the date of their last meter read to  the end of the month is estimated and the corresponding unbilled revenues are calculated. These estimates of unbilled sales and revenues are based on the ratio of billable days versus  unbilled days, amount of electricity or natural gas procured during that month, historical  customer class usage patterns, weather, line loss, unaccounted-for gas and current tariffs.\nWater reclamation and distribution revenues are recorded when water is processed or delivered  to customers. At the end of each month, the water delivered and waste water collected from the  customers from the date of their last meter read to the end of the month is estimated and the  corresponding unbilled revenues are calculated. These estimates of unbilled revenues are  based on the ratio of billable days versus unbilled days, amount of water procured and collected  during that month, historical customer class usage patterns and current tariffs. \nRevenue from waste disposal is recognized on actual tonnage of waste delivered to the plant at  prices specified in the contract. Certain contracts include price reductions if specified thresholds  are exceeded. Revenue for these contracts is recognized based on actual tonnage at the  expected price for the contract year. \nInterest from long-term investments is recorded as earned.\nThe Company’s reporting currency is the Canadian dollar.\nThe Company’s US operations are determined to have the U.S. dollar as their functional  currency since the preponderance of operating, financing and investing transactions are  denominated in U.S. dollars. The financial statements of these operations are translated into  Canadian dollars using the current rate method, whereby assets and liabilities are translated at  the rate prevailing at the balance sheet date while revenues and expenses are converted using  average rates for the period. Unrealized gains or losses arising as a result of the translation of  the financial statements of these entities are reported as a component of other comprehensive  income (“OCI”) and are accumulated in a component of equity on the Consolidated Balance  Sheet and are not recorded in income unless there is a complete or substantially complete sale  or liquidation of the investment.\n(v) Foreign currency translation \n2012 Annual Report\n85"}]}
+{"image": "doclay/doclay_59754.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Spatial Operator Functions\nReturns a geometry that represents all points whose distance from the geometry value  g  is less than or equal to a distance of  d . The result is in the same SRS as the geometry argument.\nIf the geometry argument is empty,  ST_Buffer()  returns an empty geometry.\nIf the distance is 0,  ST_Buffer()  returns the geometry argument unchanged:\nmysql>  SET @pt = ST_GeomFromText(’POINT(0 0)’); mysql>  SELECT ST_AsText(ST_Buffer(@pt, 0)); +------------------------------+ | ST_AsText(ST_Buffer(@pt, 0)) | +------------------------------+ | POINT(0 0) |\n2318"}]}
+{"image": "doclay/doclay_55467.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "ndbinfo: The NDB Cluster Information Database\n| 5 | Long message buffer | 67108864 | | 6 | Data memory | 1073741824 | | 6 | Index memory | 1074003968 | | 6 | Long message buffer | 67108864 | +---------+---------------------+------------+\n6 rows in set (0.00 sec)\nIn this case, the  total  column values for index memory are slightly higher than the value set of IndexMemory  due to internal rounding.\nFor the  used_pages  and  total_pages  columns, resources are measured in pages, which are 32K in size for  DataMemory  and 8K for  IndexMemory . For long message buffer memory, the page size is 256 bytes.\nThe  memory_per_fragment  table provides information about the usage of memory by individual fragments.\nThe  memory_per_fragment  table contains the following columns:\nName of this fragment\nName of this fragment’s parent\nType of object; see text for possible values\nTable ID for this table\nNode ID for this node\nKernel block instance ID\nFragment ID (number)\nNumber of bytes allocated for fixed-sized elements\nFree bytes remaining in pages allocated to fixed-size elements\nLength of each fixed-size element in bytes\n4564\n• fixed_elem_size_bytes\n• fixed_elem_free_bytes\n• fixed_elem_alloc_bytes\n• fragment_num\n• block_instance\n• node_id\n• table_id\n• type\n• parent_fq_name\n• fq_name\n23.5.14.37 The ndbinfo memory_per_fragment Table"}]}
+{"image": "doclay/doclay_62519.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Aug.27,2020 \n32 \nUS  2020/0272048  Al \nHO  -0  HO  -0  OH  -continued  0  0  0 \nHO  \\  0  HO  HO  HO  0  OH  \\_J  HO  -continued  0  OH "}]}
+{"image": "doclay/doclay_69337.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "6.2 Cryptography overview\n6.2.1 Modern cryptography\nThroughout history, a need existed for secret communication between people that cannot be  understood by outside parties. \nAlso, it is necessary to ensure that a message cannot be corrupted (message integrity), while  ensuring that the sender and the receiver really are the persons who they claim to be. Over  time, several methods were used to achieve these objectives, with more or less success.  Many procedures and algorithms for encrypting and decrypting data were developed that are  increasingly complicated and time-consuming.\nWith the development of computing technology, the encryption and decryption algorithms can  be performed by computers, which enables the use of complicated mathematical algorithms.  Most of these algorithms are based on the prime factorization of large numbers. \nCryptography is used to meet the following requirements:\nThe protection of data usually is the main concept that is associated with cryptography.  Only authorized persons should be able to read the message or get information about it.  Data is encrypted by using a known algorithm and secret keys, such that the intended  party can de-scramble the data, but an interloper cannot. This concept is also referred to  as  confidentiality .\nThis process decides whether the communication partners are who they claim to be,  which can be done by using certificates and signatures. It must be possible to clearly  identify the owner of the data or the sender and the receiver of the message.\nThe verification of data ensures that what was received is identical to what was sent. It  must be proven that the data is complete and was not altered during the moment it was  transmitted (by the sender) and the moment it was received (by the receiver).\nIt must be impossible for the owner of the data or the sender of the message to deny  authorship. Non-repudiation ensures that both sides of a communication know that the  other side agreed to what was exchanged, and not someone else. This specification  implies a legal liability and contractual obligation, which is the same as a signature on a  contract.\nThese goals should all be possible without unacceptable overhead to the communication. The  goal is to keep the system secure, manageable, and productive.\nThe basic data protection method is achieved by encrypting and decrypting the data, while  hash algorithms, message authentication codes (MACs), digital signatures, and certificates  are used for authentication, data integrity, and non-repudiation. \nGLYPH<SM590000> Data protection\nGLYPH<SM590000> Authentication (identity validation)\nGLYPH<SM590000> Message (data) Integrity\nGLYPH<SM590000> Non-repudiation\nChapter 6. Cryptographic features  219"}]}
+{"image": "doclay/doclay_42833.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "XVI"}]}
+{"image": "doclay/doclay_53961.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Section 11.3.5, “The ENUM Type” Section 1.2.2, “The Main Features of MySQL” Section 11.3.6, “The SET Type” Section 25.5.3, “Updatable and Insertable Views” Section 1.3, “What Is New in MySQL 8.0” Section 12.21.2, “Window Function Concepts and Syntax” Section 12.21.3, “Window Function Frame Specification”\nSection 17.2.1.1, “Advantages and Disadvantages of Statement-Based and Row-Based Replication” Section 12.7, “Date and Time Functions” Section 17.2.1.3, “Determination of Safe and Unsafe Statements in Binary Logging” Section 17.5.1.14, “Replication and System Functions” Section 5.1.7, “Server Command Options” Section 5.1.8, “Server System Variables”\nSection 17.2.1.3, “Determination of Safe and Unsafe Statements in Binary Logging” Section 12.16, “Information Functions” Section 10.2.2, “UTF-8 for Metadata”\n[index top]\nSection 12.6.2, “Mathematical Functions”\nSection 12.7, “Date and Time Functions”\nSection 12.11, “Cast Functions and Operators” Section 12.7, “Date and Time Functions”\nSection 12.7, “Date and Time Functions” Section 24.6.3, “Partitioning Limitations Relating to Functions”\nSection 12.7, “Date and Time Functions”\nSection 12.7, “Date and Time Functions”\nSection 12.7, “Date and Time Functions”\nSection 12.7, “Date and Time Functions” Section 3.3.4.5, “Date Calculations”\n5715\nTIMESTAMPDIFF()\nTIMESTAMPADD()\nTIMESTAMP()\nTIMEDIFF()\nTIME_TO_SEC()\nTIME_FORMAT()\nTIME()\nTAN()\nT\nSYSDATE()\nSYSTEM_USER()"}]}
+{"image": "doclay/doclay_71564.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Genesco Inc. and Subsidiaries Notes to Consolidated Financial Statements\nand Subsidiaries Notes to Consolidated Financial Statements\nTable of Contents\nNote 14 Business Segment Information, Continued\nFiscal 2017 Journeys Group Schuh Group Johnston & Murphy Group Licensed Brands Corporate & Other Consolidated In thousands Sales $ 1,251,646 $ 372,872 $ 289,324 $ 107,210 $ 617 $ 2,021,669 Intercompany sales — — — (838) — (838) Net sales to external customers $ 1,251,646 $ 372,872 $ 289,324 $ 106,372 $ 617 $ 2,020,831 Segment operating income (loss) $ 85,270 $ 20,530 $ 19,330 $ 4,498 $ (29,866) $ 99,762 Asset impairments and other (1) — — — — 8,031 8,031 Earnings from operations 85,270 20,530 19,330 4,498 (21,835) 107,793 Gain on sale of SureGrip Footwear — — — — 12,297 12,297 Other components of net periodic benefit cost — — — — (2,085) (2,085) Interest expense — — — — (5,294) (5,294) Interest income — — — — 47 47 Earnings from continuing operations before income taxes $ 85,270 $ 20,530 $ 19,330 $ 4,498 $ (16,870) $ 112,758 Total assets$^{ }$ongoing operations $ 404,773 $ 214,886 $ 126,559 $ 40,357 $ 142,585 $ 929,160 Assets from discontinued operations 511,839 Total assets (2) 1,440,999 Depreciation and amortization (3) 24,235 14,003 5,987 995 4,723 49,943 Capital expenditures (4) 50,259 11,236 9,221 760 3,449 74,925\n$^{(1)}$Asset Impairments and other includes an $(8.9) million gain for network intrusion expenses as a result of a litigation settlement and a $(0.5) million gain for other legal matters, partially offset by a $1.4 million charge for asset impairments, of which $0.8 million is in the Schuh Group and $0.5 million is in the Journeys Group.\n$^{(2)}$Total assets for the Schuh Group and Journeys Group include $79.8 million and $9.8 million of goodwill, respectively. Goodwill for Schuh Group decreased by $10.5 million from January 30, 2016 due to foreign currency translation adjustments. Goodwill for Journeys Group increased $0.4 million from January 30, 2016 due to foreign currency translation adjustments. Goodwill for Licensed Brands decreased $0.8 million from January 30, 2016 due to the sale of SureGrip Footwear in the fourth quarter of Fiscal 2017. Of the Company's $247.6 million of long-lived assets, $54.3 million and $13.5 million relate to long-lived assets in the United Kingdom and Canada, respectively.\n$^{(3)}$Excludes $25.8 million of depreciation and amortization related to Lids Sports Group. This amount is included in depreciation and amortization in the Consolidated Statements of Cash Flows as the Company did not segregate cash flows related to discontinued operations.\n$^{(4)}$Excludes $19.0 million of capital expenditures related to Lids Sports Group. This amount is included in capital expenditures in the Consolidated Statements of Cash Flows as the Company did not segregate cash flows related to discontinued operations.\n115"}]}
+{"image": "doclay/doclay_34249.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "II. QUANTUM MONTE-CARLO METHOD\nOur starting point is a system (S) interacting with a surrounding environment (E). We assume here that the total system (S+E) is described by the Hamiltonian\nH$_{S}$ (resp. H$_{E}$ ) acts on the system (resp. env.) only while V induces a coupling between the two sub-systems. Starting from an initial total density D (0), the dynamical evolution is given by the Liouville von-Neumann equation on the density:\nIn many physical situations, the total number of degrees of freedom to follow in time prevents from solving exactly this equation. One of the leitmotiv of Open Quantum System (OQS) theory is to find accurate approximations for the system evolution without following explicitly irrel- evant degrees of freedom associated to the environment and therefore reduces the complexity of the initial prob- lem. Conventional strategy to treat dissipation and fluc- tuation in an open quantum system is to reduce the in- formation to the system density only ρ$_{S}$ ( t ) = Tr E ( D ( t )) while accounting approximately for environment effect. Here, we use a different strategy, the dynamics of the total system is first replaced by a set of stochastic evo- lutions where the total density remains separable along each path, i.e. D = ρ$_{S}$ ( t ) ⊗ ρ$_{E}$ ( t ). Then, the stochastic evolution of the environment is projected onto the rele- vant degrees of freedom to obtain a closed equation for the system density. It is shown that the new approach provides a proper treatment of dissipation and fluctua- tion for a system coupled to a surrounding heat-bath.\nRecently, new stochastic formulations [34, 35, 42, 43] have been developed to study the system+environment problem that avoid evaluation of non-local memory ker- nels although non-Markovian effects are accounted for exactly (see also [35, 36, 42, 44–47]). One example of such a theory based on quantum Monte-Carlo method is presented here.\nHereafter, it is assumed that the coupling is separable: V = Q ⊗ B where Q and B act on the system and en- vironment respectively. For simplicity, initial separable density is considered, i.e. D (0) = ρ$_{S}$ (0) ⊗ ρ$_{E}$ (0). We want to replace the evolution of the total density (Eq. (2)) by an ensemble of stochastic evolutions of both the system and environment such that:\nThe discussion above for one time step can then be iterated to show that the exact dynamics of a sys- tem+environment could be replaced by an average over an ensemble of stochastic evolutions of separable densi- ties [34–36]. To be really useful, mainly two difficulties should be overcome (i) in general, the environment cor- responds to a large number of degrees of freedom that could not be followed explicitly in time. (ii) the numeri- cal implementation of such a theory is possible only if the statistical errors do not growth too fast during the time- evolution. This statistical errors are directly connected to the number of trajectories necessary to accurately de- scribe the physical process. Difficulty (i) is solved in the next section by projecting out the effect of the environ- ment on the system leading to a closed equation for the system density only. Let us first concentrate on statis- tical errors. At any time, a measure of the statistical fluctuation around the average trajectory is given by\nthe average evolution over the separable densities that evolve according to Eq. (3) identify with the exact Li- ouville von Neumann equation of motion (Eq. (2)). The possibility to use simple Gaussian noises to incorporate the environment effect might appear surprising. Indeed, noises used in standard approaches for Open Quantum Systems generally reflect properties of the environment. It should be however kept in mind that such environment dependent noises appear once the environment dynam- ics has been projected out on the system density evo- lution. Anticipating the discussion of section II B, once such a projection has been made, the Gaussian noises in- troduced here, transform into new random variables that explicitly depend on the environment properties.\nTherefore, under the condition\nwhere the overline denotes the stochastic average. Along each path, the total density remains separable, i.e. D ( t ) = ρ$_{S}$ ( t ) ⊗ ρ$_{E}$ ( t ). Starting from such a density, at time t + dt , the average evolution deduced from Eq. (3) is given by\nwhere dξ$_{S/E}$ and dλ$_{S/E}$ denote Markovian Gaussian stochastic variables with zero means and where we use Ito convention of stochastic calculus [48]. In the follow- ing, we assume in addition that\n2\ndξ$_{S}$dλ$_{E}$ = dλ$_{S}$dξ$_{E}$ = 0 , (4)\nH = H$_{S}$ + H$_{E}$ + V. (1)\ni $_{ℏ}$dD ( t ) dt = [ H, D ( t )] . (2)\ndD ( t ) = dt i $_{ℏ}$[ h$_{S}$ + h$_{E}$, D ( t )] + dξ$_{S}$dξ$_{E}$ ( Q ⊗ B ) D ( t ) + dλ$_{S}$dλ$_{E}$ D ( t )( Q ⊗ B ) .\ndξ$_{S}$dξ$_{E}$ = dt i $_{ℏ}$, dλ$_{S}$dλ$_{E}$ = − dt i $_{ℏ}$, (5)\n   dρ$_{S}$ = dt i $_{ℏ}$[ H$_{S}$, ρ$_{S}$ ] + dξ$_{S}$Qρ$_{S}$ + dλ$_{S}$ρ$_{S}$Q dρ$_{E}$ = dt i $_{ℏ}$[ H$_{E}$, ρ$_{E}$ ] + dξ$_{E}$Bρ$_{E}$ + dλ$_{E}$ρ$_{E}$B (3)\nΛ$_{stat}$ = Tr { ( D $^{†}$( t ) − D $^{†}$( t ) ) ( D ( t ) − D ( t ) ) } = Tr { D $^{†}$D ( t ) } − Tr { D ( t ) $^{2}$} . (6)\nA. Quantum Monte-Carlo formulation of Open Quantum Systems"}]}
+{"image": "doclay/doclay_35834.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "6\nthe large SRAM cell size, even if a large access device is used for the PCM cell, SRAM performance is hard to match. The performance limiter for PCM is the SET speed, which in turn depends on the crystallization speed of the phase change material. As will be described in de- tail in Section II B, while some researchers have demon- strated the use of SET pulses shorter than 10ns[33–36], most of the realistically large array demonstrations tend to use SET pulses that range from roughly 50 to 500ns in length[53].\nIn any case, the most stringent requirement for any emerging memory technology that seeks to replace SRAM is endurance. For all practical purposes, the read/write endurance of SRAM is infinite. While read endurance is not a likely problem for PCM, the required write endurance for SRAM replacement is probably 10 18 — out of reach for nearly all NVM technologies. Stor- ing data semi-permanently with PCM and most other NVM technologies involves some form of “brute force” that alters an easily observable material characteristic of the memory device. For PCM, this “brute force” is the melt-quench RESET operation, and at such elevated temperatures, it has been shown that the constituent atoms of a phase change material will tend to migrate over time[40, 54], as discussed in Sections IV D and IV C.\nSince non-volatility is not a requirement for SRAM ap- plications, one might be able to trade some data reten- tion for improved endurance. Some remote evidence of this trade-off has been demonstrated by showing a strong correlation between the total energy in the RESET pulse and the resulting PCM endurance[40]. The best-case en- durance, achieved for the lowest-energy RESET pulses, was 10 12 SET–RESET cycles[40]. Yet this is still 6 or- ders of magnitude away from the target specification for SRAM.\n2. PCM as DRAM\n3. PCM as Flash\nE = T$_{life}$ B αC , (1)\nThere are two kinds of Flash memories, NOR and NAND. In (common-source) NOR memory architectures, each cell in a two-dimensional (2D) array is directly con- nected to its word-line and bit-line input lines (with the source electrode of each cell sharing a common ground), whereas in NAND memory architectures, small blocks of cells are connected in series between a high input sig-\nwhere E is endurance, T$_{life}$ is the life expectancy of the system, B is memory bandwidth, α is wear-leveling ef- ficiency, and C is the system memory capacity. As- suming a typical server with a ten year life expectancy, 1 GB/sec bandwidth, 10% wear-leveling efficiency and\nFor stand-alone memories, cost is directly proportional to memory cell size. State of the art DRAM cells oc- cupy 6F 2 in chip area. Thus for PCM to compete in the DRAM arena, PCM cell size would need to be this size or smaller with comparable “area efficiency (the frac- tion of the chip area dedicated to memory devices rather than to peripheral circuitry). Fortunately, such small cell sizes have already been demonstrated using a diode select device[56]. PCM also competes favorably with DRAM in terms of forward scaling into future generations, as DRAM developers are quickly hitting various scaling lim- its associated with storage interference, device leakage, and challenges in integrating high aspect-ratio capaci- tors in tight spaces. Currently, DRAM has fallen behind NAND Flash and standard CMOS logic technologies in terms of scaling to the 45nm technology node and prepa- ration for the 32nm node. However, DRAM is a proven, reliable technology that has been employed in modern computers since the early 1970s. It would be a long jour- ney to displace such a stable technology.\nDRAM is used in a more diversified set of applications than SRAM. Most of the characteristics discussed above for the replacement of SRAM also apply to the replace- ment of DRAM, although in most cases the specifications are slightly relaxed. Access times of tens of nanoseconds would be acceptable for most computer and consumer electronics applications of DRAM. For embedded DRAM used as video RAM and L3 cache[55], however, an access time of 10 nanoseconds or less is required. As for write endurance, the requirement can be estimated using the following equation[52]:\n16 GB capacity, the endurance requirement is approxi- mately 2 × 10 8 — well within the reach of PCM[44, 56].\nThere is also a power argument to be made when dis- cussing PCM as a potential DRAM replacement. This might seem to be a difficult case to make for a tech- nology for which every write cycle involves heating to temperatures ranging from 400 to 700 degrees Celsius. However, DRAM turns out to be a fairly power-hungry technology. This is not due to its periodic refresh, how- ever, which takes place only infrequently, and is not too strongly related to the underlying physical storage mech- anism of charging up a local capacitor. Instead, power inefficiency in DRAM is due to the simultaneous address- ing of multiple banks within the chip. For every bit that passes into or out of a DRAM chip, 8 or even 16 devices are being internally accessed (read and then re- written), somewhat as if your librarian knocked an entire row of books onto the floor each time you asked for a book. Low-power DRAM intended for mobile, battery- powered applications tends to have lower performance, although some developments have been made that can combine high performance with low power[57]. However, the inherent need to re-write after each read access is un- avoidable for a volatile memory like DRAM. Thus sim- ply by being non-volatile, PCM could potentially offer a lower-power alternative to DRAM, despite the inherently power-hungry nature of PCM write operations."}]}
+{"image": "doclay/doclay_48906.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\n§ 1 Grundregel der Zulassung\n§ 2 Eingeschränkte Zulassung\n§ 3 Einschränkung und Entziehung der Zulassung\nII. Führen von Kraftfahrzeugen\n1. Allgemeine Regelungen\n§ 4 Erlaubnispflicht und Ausweispflicht für das Führen von Kraftfahrzeugen\nZum Verkehr auf öffentlichen Straßen ist jeder zugelassen, soweit nicht für die Zulassung zu einzelnen Verkehrsarten eine Erlaubnis vorgeschrieben ist.\n(1) Wer sich infolge körperlicher oder geistiger Beeinträchtigungen nicht sicher im Verkehr bewegen kann, darf am Verkehr nur teilnehmen, wenn Vorsorge getroffen ist, dass er andere nicht gefährdet. Die Pflicht zur Vorsorge, namentlich durch das Anbringen geeigneter Einrichtungen an Fahrzeugen, durch den Ersatz fehlender Gliedmaßen mittels künstlicher Glieder, durch Begleitung oder durch das Tragen von Abzeichen oder Kennzeichen, obliegt dem Verkehrsteilnehmer selbst oder einem für ihn Verantwortlichen.\n(2) Körperlich Behinderte können ihre Behinderung durch gelbe Armbinden an beiden Armen oder andere geeignete, deutlich sichtbare, gelbe Abzeichen mit drei schwarzen Punkten kenntlich machen. Die Abzeichen dürfen nicht an Fahrzeugen angebracht werden. Wesentlich sehbehinderte Fußgänger können ihre Behinderung durch einen weißen Blindenstock, die Begleitung durch einen Blindenhund im weißen Führgeschirr und gelbe Abzeichen nach Satz 1 kenntlich machen.\n(3) Andere Verkehrsteilnehmer dürfen die in Absatz 2 genannten Kennzeichen im Straßenverkehr nicht verwenden.\n(1) Erweist sich jemand als ungeeignet oder nur noch bedingt geeignet zum Führen von Fahrzeugen oder Tieren, hat die Fahrerlaubnisbehörde ihm das Führen zu untersagen, zu beschränken oder die erforderlichen Auflagen anzuordnen. Nach der Untersagung, auf öffentlichen Straßen ein Mofa nach § 4 Absatz 1 Satz 2 Nummer 1 oder ein Kraftfahrzeug nach § 4 Absatz 1 Satz 2 Nummer 1b zu führen, ist die Prüfbescheinigung nach § 5 Absatz 4 Satz 1 unverzüglich der entscheidenden Behörde abzuliefern oder bei Beschränkungen oder Auflagen zur Eintragung vorzulegen. Die Verpflichtung zur Ablieferung oder Vorlage der Prüfbescheinigung besteht auch, wenn die Entscheidung angefochten worden ist, die zuständige Behörde jedoch die sofortige Vollziehung ihrer Verfügung angeordnet hat.\n(2) Rechtfertigen Tatsachen die Annahme, dass der Führer eines Fahrzeugs oder Tieres zum Führen ungeeignet oder nur noch bedingt geeignet ist, finden die Vorschriften der §§ 11 bis 14 entsprechend Anwendung.\n(1) Wer auf öffentlichen Straßen ein Kraftfahrzeug führt, bedarf der Fahrerlaubnis. Ausgenommen sind\n1.  einspurige Fahrräder mit Hilfsmotor – auch ohne Tretkurbeln –, wenn ihre Bauart Gewähr dafür bietet, dass die Höchstgeschwindigkeit auf ebener Bahn nicht mehr als 25 km/h beträgt (Mofas); besondere Sitze für die Mitnahme von Kindern unter sieben Jahren dürfen jedoch angebracht sein,\n1a.  Elektrokleinstfahrzeuge nach § 1 Absatz 1 der Elektrokleinstfahrzeuge-Verordnung,\n1b.  zweirädrige Kraftfahrzeuge der Klasse L1e-B und dreirädrige Kraftfahrzeuge der Klassen L2e-P und L2e-U nach Artikel 4 Absatz 2 Buchstabe a und b der Verordnung (EU) Nr. 168/2013 des Europäischen Parlaments und des Rates vom 15. Januar 2013 über die Genehmigung und Marktüberwachung von zwei- oder dreirädrigen und vierrädrigen Fahrzeugen (ABl. L 60 vom 2.3.2013, S. 52) oder nicht EU- typgenehmigte Fahrzeuge mit den jeweils gleichen technischen Eigenschaften, wenn ihre Bauart Gewähr dafür bietet, dass die Höchstgeschwindigkeit auf ebener Bahn auf höchstens 25 km/h beschränkt ist,\n2.  motorisierte Krankenfahrstühle (einsitzige, nach der Bauart zum Gebrauch durch körperlich behinderte Personen bestimmte Kraftfahrzeuge mit Elektroantrieb, einer Leermasse von nicht mehr als 300 kg einschließlich Batterien jedoch ohne Fahrer, einer zulässigen Gesamtmasse von nicht mehr als 500 kg,\n- Seite 6 von 158 -"}]}
+{"image": "doclay/doclay_46103.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "• Weight—the combined load of the aircraft itself, the  crew, the fuel, and the cargo or baggage. Weight is  a force that pulls the aircraft downward because of  the force of gravity. It opposes lift and acts vertically  downward through the aircraft’s center of gravity (CG). \n• The sum of all upward components of forces (not just  lift) equals the sum of all downward components of  forces (not just weight) \n• The sum of all forward components of forces (not just  thrust) equals the sum of all backward components of  forces (not just drag) \nIn steady flight, the sum of these opposing forces is always  zero. There can be no unbalanced forces in steady, straight  flight based upon Newton’s Third Law, which states that for  every action or force there is an equal, but opposite, reaction  or force. This is true whether flying level or when climbing  or descending. \nIt does not mean the four forces are equal. It means the  opposing forces are equal to, and thereby cancel, the effects of  each other. In  Figure 5-1,  the force vectors of thrust, drag, lift,  and weight appear to be equal in value. The usual explanation  states (without stipulating that thrust and drag do not equal  weight and lift) that thrust equals drag and lift equals weight.  Although true, this statement can be misleading. It should be  understood that in straight, level, unaccelerated flight, it is  true that the opposing lift/weight forces are equal. They are  also greater than the opposing forces of thrust/drag that are  equal only to each other. Therefore, in steady flight: \nThis refinement of the old “thrust equals drag; lift equals  weight” formula explains that a portion of thrust is directed  upward in climbs and slow flight and acts as if it were lift  while a portion of weight is directed backward opposite to the  direction of flight and acts as if it were drag. In slow flight, \nFor an aircraft to start moving, thrust must be exerted and be  greater than drag. The aircraft continues to move and gain  speed until thrust and drag are equal. In order to maintain a \nBy using the aerodynamic forces of thrust, drag, lift, and  weight, pilots can fly a controlled, safe flight. A more detailed  discussion of these forces follows. \nDiscussions of the preceding concepts are frequently omitted  in aeronautical texts/handbooks/manuals. The reason is  not that they are inconsequential, but because the main  ideas with respect to the aerodynamic forces acting upon  an aircraft in flight can be presented in their most essential  elements without being involved in the technicalities of the  aerodynamicist. In point of fact, considering only level flight,  and normal climbs and glides in a steady state, it is still true  that lift provided by the wing or rotor is the primary upward  force, and weight is the primary downward force. \nAnother important concept to understand is angle of attack  (AOA). Since the early days of flight, AOA is fundamental to  understanding many aspects of airplane performance, stability,  and control. The AOA is defined as the acute angle between the  chord line of the airfoil and the direction of the relative wind. \nIn glides, a portion of the weight vector is directed along  the forward flight path and, therefore, acts as thrust. In other  words, any time the flight path of the aircraft is not horizontal,  lift, weight, thrust, and drag vectors must each be broken down  into two components. \nthrust has an upward component. But because the aircraft is in  level flight, weight does not contribute to drag.  [Figure 5-2] \nThrust \nFigure 5-1.  Relationship of forces acting on an aircraft. \nFigure 5-2.  Force vectors during a stabilized climb. \n5-2 \nThrust  Drag  Weight Lift \nRearward component of weight  Thrust  Drag  Flight path Relative wind  Component of weight  opposed to lift  Lift  CL  CG "}]}
+{"image": "doclay/doclay_80190.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "52 \n53 \nallowed credit, as an asset or as a deduction from  loss and unearned premium reserves, for reinsurance  recoverable from an insurer not authorized in this  country but which presents satisfactory evidence that  it meets the applicable standards of solvency required  in this country. \n\"(g) Funds withheld by a ceding insurer under  a reinsurance treaty, provided reserves for unpaid  losses and unearned premiums are adequately  provided. \n\"(h) Deposits or amounts recoverable from  underwriting associations, syndicates and  reinsurance funds, or from any suspended banking  institution, to the extent deemed by the Commissioner  to be available for the payment oflosses and claims  and values to be determined by  him. \n\"(i)  Electronic data processing machines, as  may be authorized by the Commissioner to be acquired  by the insurance company concerned, the acquisition  cost of which  to be amortized in equal annual amounts  within a period of five (5) years from the date of  acquisition thereof. \n\"6)  Investments in mutual funds, real estate  investment trusts, salary loans, unit investment trust  funds and special deposit accounts, subject to the  conditions as may be provided for by the  Commissioner. \n\"(k) Other assets, not inconsistent with the  provisions of paragraphs (a) to G) hereof, which are  deemed by the Commissioner to be readily realizable  and available for the payment oflosses and claims at  values to be determined by  him  in a circular, rule or  regulation. \n\"SEC. 203. In addition to such assets as the  Commissioner may from time to time determine to  be non-admitted assets of insurance companies doing  business  in  the Philippines, the following assets shall \nin no case be allowed as admitted assets of an  insurance company doing business in the Philippines,  in any determination of its financial condition: \n\"(a) Goodwill, trade names, and other like  intangible assets.  . \n\"(b) Prepaid or deferred charges for expenses  and commissions paid by such insUrance company. \nfI(C)  Advances to offioffi.!i (other than policy  loans), which are not adegliately secured and which  are not previously auth-cirized by the Commissioner,  as well as advances to emp}oyees, agents, and other  persons on mere personal security. \n\"(d) Shares of stock of such insurance company,  owned by it, or any equity therein as well as loans  secured thereby, or any proportionate interest in such  shares of stock thrdugh the ownership by such  insurance company of an interest in another  corporation or busin¥s  unit. \n\"(e)  Furniture, furnishing, fixtures, safes,  equipment, library, stationery, literature, and  supplies. \n\"m  Items of bank credits representing checks,  drafts or notes returned unpaid after the date of  statement. \n\"(g) The amount, if any, by which the  aggregate value of investments as carried in the ledger  assets of such insurance company exceeds the  aggregate value thereof as determined in accordance  with the provisions ofthis Code and/or the rules of  the Commissioner. \n\"All non-admitted assets and all other assets of  doubtful value or character included as ledger or  non-ledger assets in any statement submitted by an  insurance company to the Commissioner, or in any  insurance examiner’s report to him, shall also be  reported, to the extent of the value disallowed as  deductions from the gross assets of such insurance "}]}
+{"image": "doclay/doclay_38099.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "[Option 2: Retention money guarantee by financial guarantee] \n[The contractor (or leader in the case of a joint tender) must provide a retention  money guarantee in the form of a financial guarantee for EUR [a mount in figures  and in words]  in accordance with the conditions laid down in Article II.21.5. The guarantee must be released [30] [60] [90] days after the final approval of the services.]\n7 "}]}
+{"image": "doclay/doclay_41513.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "AIM\n8/15/19 \n10 − 1 − 2. Helicopter Instrument Approaches\nNOTE −\nalso be limited to no more than 70 KIAS. Use the published minima, no reductions allowed.\na. Helicopters are capable of flying any published 14 CFR Part 97, Standard Instrument Approach Procedures (SIAPs), for which they are properly equipped, subject to the following limitations and conditions:\n2. Helicopters flying Copter SIAPs may use the published minima, with no reductions allowed. The maximum airspeed is 90 KIAS on any segment of the approach or missed approach.\n3. Helicopters flying GPS Copter SIAPs must limit airspeed to 90 KIAS or less when flying any segment of the procedure, except speeds must be limited to no more than 70 KIAS on the final and missed approach segments. Military GPS Copter SIAPs are limited to no more than 90 KIAS throughout the procedure. If annotated, holding may\nObstruction clearance surfaces are based on the aircraft speed and have been designed on these approaches for 70 knots. If the helicopter is flown at higher speeds, it may fly outside of protected airspace. Some helicopters have a V$_{MINI}$ greater than 70 knots; therefore, they cannot meet the 70 knot limitation to conduct this type of procedure. Some helicopter autopilots, when used in the “go − around” mode, are programmed with a V$_{YI}$ greater than 70 knots, therefore when using the autopilot “go − around” mode, they cannot meet the 70 knot limitation to conduct this type of approach. It may be possible to use the autopilot for the missed approach in the other than the “go − around” mode and meet the 70 knot limitation to conduct this type of approach. When operating at speeds other than V$_{YI}$ or V$_{Y}$, performance data may not be available in the RFM to predict compliance with climb gradient requirements. Pilots may use observed performance in similar weight/altitude/temperature/speed conditions to evaluate the suitability of performance. Pilots are cautioned to monitor climb performance to ensure compliance with procedure requirements.\n4. TBL 10 − 1 − 1 summarizes these require- ments.\n1. Helicopters flying conventional (non − Copter) SIAPs may reduce the visibility minima to not less than one half the published Category A landing visibility minima, or $^{1}$/$_{4}$ statute mile visibility/1200 RVR, whichever is greater unless the procedure is annotated with “ Visibility Reduction by Helicopters NA .” This annotation means that there are penetrations of the final approach obstacle identification surface (OIS) and that the 14 CFR Section 97.3 visibility reduction rule does not apply and you must take precaution to avoid any obstacles in the visual segment. No reduction in MDA/DA is permitted. The helicopter may initiate the final approach segment at speeds up to the upper limit of the highest approach category authorized by the procedure, but must be slowed to no more than 90 KIAS at the missed approach point (MAP) in order to apply the visibility reduction. Pilots are cautioned that such a decelerating approach may make early identification of wind shear on the approach path difficult or impossible. If required, use the Inoperative Components and Visual Aids Table provided in the front cover of the U.S. Terminal Procedures Volume to derive the Category A minima before applying the 14 CFR Section 97.3(d − 1) rule.\n5. Even with weather conditions reported at or above landing minima, some combinations of reduced cockpit cutoff angle, minimal approach/ runway lighting, and high MDA/DH coupled with a low visibility minima, the pilot may not be able to identify the required visual reference(s) during the approach, or those references may only be visible in a very small portion of the pilot’s available field of view. Even if identified by the pilot, these visual references may not support normal maneuvering and normal rates of descent to landing. The effect of such a combination may be exacerbated by other conditions such as rain on the windshield, or incomplete windshield defogging coverage.\n6. Pilots are cautioned to be prepared to execute a missed approach even though weather conditions may be reported at or above landing minima.\nNOTE −\nNOTE − See paragraph 5 − 4 − 21, Missed Approach, for additional information on missed approach procedures.\nHelicopter IFR Operations\n10 − 1 − 3"}]}
+{"image": "doclay/doclay_23141.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Field Operations\nEnvironmental \nIndustry Capacity Constraints\n44 \nHigh levels of field activity can result in shortages of services, products, equipment, or manpower in many or all  necessary components of the exploration and development cycle. Increased demand leads to higher land and service  costs during peak activity periods. In addition, access to transportation and processing facilities may be difficult or  expensive to secure. Storm’ s competitors include companies with far greater resources, including access to capital  and the ability to secure oilfield services at more favourable prices and to build out operations on a scale which  lowers the economic threshold for exploitation of a resource. Storm competes by maintaining a large inventory of  self-generated exploration and development locations, by acting as operator where possible, and through facility \nIn addition to Company-specific environmental concerns, increasing public and political focus on climate change and  its possible amelioration, may cause changes in demand for the Company’ s products and the introduction of  regulations which may result in changes to the Company’ s operating practices as well as additional and  unforeseeable costs and the incurrence of future liabilities, real or contingent. Changes in public policy over the next  several years cannot be determined at this stage, but given that the Company is a producer of primary hydrocarbons  it is likely that its business will be subject to increased regulation and potentially subject to additional taxes, costs and  obligations. \nThe evolution of environmental regulation, in particular as it relates to fracturing applications, cannot be predicted at  this stage. Nevertheless it is reasonable to expect that management of environmental issues and related societal  expectations will become an increasingly important part of the Company’ s business, with a corresponding effect on  costs and economic returns. \nThe Company’ s operations are subject to extensive environmental regulations which are addressed through formal  policies and procedures and application of best field practices. In addition, the Company’ s approach to property  development frequently involves horizontal drilling and fracturing applications. Fracturing involves the use of large  quantities of liquids and chemicals, whose use and subsequent disposal has resulted in the emergence of  environmental concerns, primarily in more heavily populated areas elsewhere in North America. In particular, natural  gas produced by the Company at Umbach contains hydrogen sulfide, which is potentially lethal and has to be  removed from the gas stream. This requires access to specialized processing facilities. Although the Company  considers that access to such facilities is adequate for current and near-term production levels, this may not be the  case in the future. In addition, exploitation of shale gas in the HRB may cause management of carbon dioxide  volumes produced concurrently with natural gas to become an operational issue. \nStorm maintains industry-specific insurance policies, including environmental damage and business interruption, on  important owned and non-owned production and processing facilities. Although the Company believes its current  insurance coverage corresponds to industry standards, there is no guarantee that such coverage will be available in  the future, and if it is, at a cost acceptable to the Company, or that existing coverage will necessarily extend to all  circumstances or incidents resulting in loss or liability. \nThe Company’ s areas of activity are largely remote and relatively undeveloped and, particularly the HRB in northeast  British Columbia, are climatically hostile. In any new area of activity, property access and production require  considerable early stage investment, for example, road construction, access to processing facilities, pipelines and  other transportation arrangements, which is not necessarily applicable to more mature producing areas. In addition,  supervision and maintenance of production facilities is likely to be more expensive than in existing and more  accessible producing areas. \nStorm’ s current and future exploration, development and production activities involve the use of heavy equipment and  the handling of volatile liquids and gases. Catastrophic events such as well blowouts, explosions and fires within  pipeline, gathering, or facility infrastructure, as well as failure of gathering systems or mechanical equipment, could  lead to releases of liquids or gases, spills of contaminants, personal injuries and death and damage to the  environment, as well as uncontrolled cost escalation. With support from suitably qualified external parties, the  Company has developed and implemented policies and procedures to mitigate environmental, health and safety  risks. These policies and procedures include the use of formal corporate policies, emergency response plans, and  other policies and procedures reflecting what management considers to be best oil field practices. These policies  and procedures are subject to periodic review. Storm also manages environmental and safety risks by maintaining its  operations to a high standard and complying with all provincial and federal environmental and safety regulations. Nevertheless, application of best practices to field operations serves only to mitigate, not eliminate, risk."}]}
+{"image": "doclay/doclay_64549.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Aug. 19, 2010 \n8 \nUS 2010/0210871 Al \n[0092]  It  has been found that the temperature has a great  influence on the extraction rate. The higher the temperature of  the aqueous ammonium salt solution, the more rapidly the  reactive extraction proceeds. \n[0093]  In the case of use of a 10% aqueous 2-hydroxy-4- methylthiobutyric acid ammonium salt solution at 50°  C. with  isobutyl methyl ketone as the extractant and with 6 1 of  nitrogen per hour as the entraining gas, after 90 hours of  extraction time, 39% of the 2-hydroxy-4-methylthiobutyric  acid used was found (Example 2). A temperature increase by  30°  C. to 80°  C. under otherwise identical conditions also  increases the amount of 2-hydroxy-4-methylthiobutyric acid  extracted within the same period to 93% (Example 1, FIG.  7). \n[0094]  It  has also been found that the concentration of the  ammonium salt used has an influence on the extraction rate.  The higher the concentration of the ammonium salt in the  aqueous solution, the more slowly the reactive extraction  proceeds. \n[0095]  In the case of use of a 10% aqueous 2-hydroxy-4- methylthiobutyric acid ammonium salt solution at 80°  C. with  isobutyl methyl ketone as the extractant and with 6 1 of  nitrogen per hour as the entraining gas, after 90 hours of  extraction time, 93% of the 2-hydroxy-4-methylthiobutyric  acid used was found (Example 1 ). When the concentration of  the ammonium salt is increased to 20%, under otherwise  identical conditions, 71 % of extracted 2-hydroxy-4-meth› ylthiobutyric acid is obtained within the same period (Ex› ample 3, FIG.  8). \n[0096]  The reactive extraction is not restricted to the use of  isobutyl methyl ketone as the extractant.  It  is possible to use  all water-immiscible or only sparingly water-miscible  organic solvents, such as alcohols, ethers, ketones or hydro› carbons, or mixtures thereof. \n[0097]  In the case of use of a 10% aqueous 2-hydroxy-4- methylthiobutyric acid ammonium salt solution at 50°  C. with  isobutyl methyl ketone as the extractant and with 6 1 of  nitrogen per hour as the entraining gas, after 90 hours of  extraction time, 39% of the 2-hydroxy-4-methylthiobutyric  acid used was found (Example 2). When, under identical  conditions, methyl tent-butyl ether is used as the extractant,  after 90 hours of extraction time, 38% of the 2-hydroxy-4- methylthiobutyric acid used is found in the solvent (Example  4, FIG.  9). \n[0098]  In addition to 2-hydroxy-4-methylthiobutyric acid,  reactive extraction using a stripping medium or entraining gas  is also employable for other hydroxycarboxylic acids. \n[0099]  Examples cited here include the commercially sig› nificant lactic acid, and 2-hydroxyisobutyric acid, which is  used in plastics production as a precursor for MMA. \n[0100]  In the case of use of a 10% aqueous lactic acid  ammonium salt solution at 80°  C. with 1-butanol as the  extractant and with 61 of nitrogen per hour as the entraining  gas, after 21 hours of extraction time, 88% of the lactic acid  used was found (Example 8, FIG.  10). \n[0101]  In the case ofuse ofa 10% aqueous 2-hydroxyisobu› tyric acid ammonium salt solution at 80°  C. with isobutyl  methyl ketone as the extractant and with 6 1 of nitrogen per  hour as the entraining gas, after 21 hours of extraction time,  49% of the 2-hydroxyisobutyric acid used was found (Ex› ample 7, FIG.  11). \n[0102]  The invention cited is not restricted only to the  release ofhydroxycarboxylic acids from the ammonium salts  thereof, but also includes other substituted or unsubsubsti› tuted carboxylic acids, e.g. valeric acid, and sulphonic acids, \ne.g. (+)-camphor-I 0-sulphonic acid, and phosphonic acids,  for example toluenephosphonic acid. \n[0103]  In the case of use of a 10% aqueous valeric acid  ammonium salt solution at 80°  C. with isobutyl methyl ketone  as the extractant and with 6 1 of nitrogen per hour as the  entraining gas, after 21 hours of extraction time, 90% of the  valeric acid used was found (Example 9, FIG.  12). \n[0104]  In the case of use of a 10% aqueous (+)-camphor› ! 0-sulphonic acid ammonium salt solution at 80°  C. with  isobutyl methyl ketone as the extractant and with 6 1 of  nitrogen per hour as the entraining gas, after 66 hours of  extraction time, 25% of the (+)-camphor- I 0-sulphonic acid  used was found (Example 12). \n[0105]  In the case of use of a 10% aqueous toluenephos› phonic acid ammonium salt solution, it was possible at 80°  C.  with isobutyl methyl ketone as the extractant and with 61 of  nitrogen per hour as the entraining gas, after 46 hours of  extraction time, to find 43% of the toluenephosphonic acid  used (Example 13). \n[0106]  The examples cited were performed in a specially  developed perforator (FIG.  1).  The extraction vessel of the  perforator was half-filled with an aqueous ammonium salt  solution of an organic acid and filled with an extractant until  there is overflow to the reservoir. The reservoir itself is like› wise half-filled with extractant. The extraction vessel is  equipped with an inserted distributor and a gas inlet tube with  frit. The distributor is rotated by means of magnetic coupling.  A stripping gas, for example nitrogen, is simultaneously  introduced via the gas inlet tube. The extractant supplied to  the distributor from the condenser above through a tube by  distillation out of the reservoir is accelerated into the aqueous  ammonium salt solution to be extracted as fine droplets out of  small holes of a distributor ring by centrifugal force. This  achieves fine distribution and intimate mixing of the extrac› tant with the material for extraction. At the same time, the gas  stream drives the ammonia out of the aqueous phase. Caused  by the co-rotation of the aqueous ammonium salt solution to  be extracted, the finely distributed extractant laden with the  free organic acid extracted reaches the deposition zone only  after prolonged residence time in the aqueous phase and runs  back into the reservoir (distillation flask), from which the  solvent is recycled into the extraction circuit by re-evapora› tion. The free organic acid collects in the reservoir. The  ammonia stream released is removed with the stripping gas  via the attached jacketed coil condenser and collected in an  aqueous sulphuric acid trap. \n[0107]  An apparatus improvement is the countercurrent  extractor (FIG.  2).  In a reaction tube equipped with random  packings, the aqueous ammonium salt solution of an organic  acid at a controlled temperature is introduced from the top and  pumped in circulation. The extractant is pumped into the  reaction tube in countercurrent through a frit and the entrain› ing gas is introduced into the system. The finely distributed  droplets of the extractant absorb the organic acid released.  The lighter organic phase is removed via an outlet at the upper  end of the reaction tube. After the separation of extractant and  organic acid (for example crystallization, distillation, separa› tion by cooling, separation by back-washing with water), the  extractant is introduced into the circuit again. The entraining  gas and the released ammonia which has been driven out are  removed via the top. Series connection of a plurality of coun› tercurrent extractors makes the process even more efficient  and industrially employable. A cascade reactive extraction is  obtained (FIG.  3). "}]}
+{"image": "doclay/doclay_70187.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "4. After the activation process is complete, you see a green check mark in the column  labeled Licensed for the control enclosure, as shown in Figure 13-11.Figure 13-11 Successful encryption license activation on a running system\nFigure 13-12 Encryption license Activate License Automatically window\n13.3.4 Activate the license automatically\nAutomatic license activation is the faster method to activate the encryption license for IBM  Spectrum Virtualize. You need the authorization code and the workstation that is used to  access the GUI to access to the external network.\nImportant:  To perform this operation, the personal computer that is used to connect to the  GUI and activate the license must connect to the internet.\nTo activate the encryption license for a control enclosure automatically, complete the following  steps:\n1. Select  Activate License Automatically  to open the Activate License Automatically  window, as shown in Figure 13-12.Chapter 13. Encryption  737"}]}
+{"image": "doclay/doclay_78846.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "CHAPTER 94. PERL5004DELTA\n94.3. CORE CHANGES\n94.3.10 Group vector changeable with $)\n94.3.11 Fixed parsing of $ $ < digit > , & $ < digit > , etc.\n94.3.12 Fixed localization of $ < digit > , $ & , etc.\n94.3.13 No resetting of $ . on implicit close\n94.3.14 wantarray may return undef\n94.3.15 eval EXPR determines value of EXPR in scalar context\nused to print something like \"timenowis881399109 | 4\", but now (and in perl4) prints \"4 | 4\".\nPerl (version 5) used to determine the value of EXPR inconsistently, sometimes incorrectly using the surrounding context for the determination. Now, the value of EXPR (before being parsed by eval) is always determined in a scalar context. Once parsed, it is executed as before, by providing the context that the scope surrounding the eval provided. This change makes the behavior Perl4 compatible, besides fixing bugs resulting from the inconsistent behavior. This program:\nThe wantarray operator returns true if a subroutine is expected to return a list, and false otherwise. In Perl 5.004, wantarray can also return the undefined value if a subroutine’s return value will not be used at all, which allows subroutines to avoid a time-consuming calculation of a return value if it isn’t going to be used.\nThe documentation for Perl 5.0 has always stated that $. is not reset when an already-open file handle is reopened with no intervening call to close . Due to a bug, perl versions 5.000 through 5.003 did reset $. under that circumstance; Perl 5.004 does not.\nPerl versions before 5.004 did not always properly localize the regex-related special variables. Perl 5.004 does localize them, as the documentation has always said it should. This may result in $1, $2, etc. no longer being set where existing programs use them.\nHowever, the developers of Perl 5.004 could not fix this bug completely, because at least two widely-used modules depend on the old meaning of \"$$0\" in a string. So Perl 5.004 still interprets \"$$ < digit > \" in the old (broken) way inside strings; but it generates this message as a warning. And in Perl 5.005, this special treatment will cease.\nPerl versions before 5.004 misinterpreted any type marker followed by \"$\" and a digit. For example, \"$$0\" was incorrectly taken to mean \"${$}0\" instead of \"${$0}\". This bug is (mostly) fixed in Perl 5.004.\nIn Perl 5.004, assigning to $) is exactly symmetrical with examining it: The first number in its string value is used as the e ff ective gid; if there are any numbers after the first one, they are passed to the setgroups() C function (if there is one).\nThe $) special variable has always (well, in Perl 5, at least) reflected not only the current e ff ective group, but also the group list as returned by the getgroups() C function (if there is one). However, until this release, there has not been a way to call the setgroups() C function from Perl.\n@a = qw(time now is time); print eval @a; print ’|’, scalar eval @a;\n1474"}]}
+{"image": "doclay/doclay_6862.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "OUR STRATEGIC BUILDING BLOCKS\nA critical part of Darden’s foundation is our strategic framework, which  consists of four strategic imperatives and two strategic enablers. For the  past two years, we have featured one of the Company’s strategic building  blocks in our annual report to shareholders . We began with  Culinary and  Beverage Excellence , which highlighted our commitment to not only contin- ually improving and innovating in this critically important part of our business,  but also to redefining culinary and beverage excellence in casual dining.  Last year, we featured  Service and Hospitality Excellence , underscoring  our fundamental recognition that the restaurant business is about creating  great experiences, not just great menu offerings. Our goal is to establish  and sustain the industry’s very highest service and hospitality standards as  defined by casual dining guests. This year we focus on a third strategic  imperative,  Leadership Excellence.  To achieve our ultimate goal – to be  the best in casual dining now and for generations – we must have leaders  throughout the Company who inspire in their teams a great passion and  enthusiasm for people, restaurants and dining.\nThese strategic imperatives are joined by a fourth –  Brand Building Excellence  – and all are supported by our strategic enablers – diversity excellence and pro- cess and technology excellence. And our entire strategic framework rests  on our core values – Integrity and Fairness, Respect and Caring, Diversity,  Always Learning/AlwaysTeaching, Being “of Service,”Teamwork, and  Excellence. To learn more about our strategies and values, we encourage  you to visit www.darden.com.\nCONTENTS\nLetter to Shareholders  2 Leadership Defined  5-16 Financial Review  17\nShareholder Information  52 Board of Directors  53"}]}
+{"image": "doclay/doclay_49988.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "(continued from previous page)\nself.handler.close() # implicit return of None => don't swallow exceptions\nTo illustrate how it works, we can add the following block of code to the above:\nIf you specify a level value, the logger’s level is set to that value in the scope of the with block covered by the context manager. If you specify a handler, it is added to the logger on entry to the block and removed on exit from the block. You can also ask the manager to close the handler for you on block exit - you could do this if you don’t need the handler any more.\nWe initially set the logger’s level to$_{INFO}$ , so message #1 appears and message #2 doesn’t. We then change the level to$_{DEBUG}$ temporarily in the following$_{with}$ block, and so message #3 appears. After the block exits, the logger’s level is restored to$_{INFO}$ and so message #4 doesn’t appear. In the next$_{with}$ block, we set the level to$_{DEBUG}$ again but also add a handler writing to$_{sys.stdout}$ . Thus, message #5 appears twice on the console (once via$_{stderr}$ and once via$_{stdout}$). After the$_{with}$ statement’s completion, the status is as it was before so message #6 appears (like message #1) whereas message #7 doesn’t (just like message #2).\nIf we run the resulting script, the result is as follows:\nIf we run it again, but pipe$_{stderr}$ to$_{/dev/null}$ , we see the following, which is the only message written to stdout :\nOnce again, but piping$_{stdout}$to$_{/dev/null}$ , we get:\n$ python logctx.py 2>/dev/null 5. This should appear twice - once on stderr and once on stdout.\nIn this case, the message #5 printed to$_{stdout}$doesn’t appear, as expected.\nOf course, the approach described here can be generalised, for example to attach logging filters temporarily. Note that the above code works in Python 2 as well as Python 3.\n40\n$ python logctx.py >/dev/null 1. This should appear just once on stderr. 3. This should appear once on stderr. 5. This should appear twice - once on stderr and once on stdout. 6. This should appear just once on stderr.\n$ python logctx.py 1. This should appear just once on stderr. 3. This should appear once on stderr. 5. This should appear twice - once on stderr and once on stdout. 5. This should appear twice - once on stderr and once on stdout. 6. This should appear just once on stderr.\nif __name__ =='__main__ ': logger=logging.getLogger('foo') logger.addHandler(logging .StreamHandler()) logger.setLevel(logging .INFO) logger.info('1. This should appear just once on stderr. ') logger.debug( '2. This should not appear. ') with LoggingContext(logger, level =logging.DEBUG): logger.debug( '3. This should appear once on stderr. ') logger.debug( '4. This should not appear. ') h =logging.StreamHandler(sys .stdout) with LoggingContext(logger, level =logging.DEBUG, handler=h, close= True ): logger.debug( '5. This should appear twice - once on stderr and once on ␣ ↪ → stdout. ') logger.info('6. This should appear just once on stderr. ') logger.debug( '7. This should not appear. ')"}]}
+{"image": "doclay/doclay_71439.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Supplemental cash flow information related to leases for the years ended December 31, 2020 and December 31, 2019 was as follows:\nSupplemental balance sheet information related to leases as of December 31, 2020 and December 31, 2019 was as follows:\nThe weighted-average remaining lease term and discount rate as of December 31, 2020 are as follows:\n141\nWeighted-Average Remaining Lease Term (Years) Weighted-Average Discount Rate Operating leases 4.5 4.1% Finance leases 13.2 6.7%\nAs of December 31, 2020 December 31, 2019 Balance Sheet Classification (In millions) Operating Leases Operating lease right-of-use assets Other assets $ 136.2  $ 154.5  Current operating lease liabilities Accounts payable and other current liabilities $ 47.1  $ 46.6  Non-current operating lease liabilities Other liabilities 106.4  119.5  Total operating lease liabilities $ 153.5  $ 166.1  Finance Leases Finance lease right-of-use assets Properties, net $ 60.5  $ 73.0  Current finance lease liabilities Current portion of long-term debt and short-term borrowings $ 4.1  $ 34.5  Non-current finance lease liabilities Long-term debt 59.9  60.0  Total finance lease liabilities $ 64.0  $ 94.5 \nYear ended December 31, 2020 Year ended December 31, 2019 (In millions) Cash paid for amounts included in the measurements of lease liabilities: Operating cash flows from operating leases $ 53.2  $ 52.2  Operating cash flows from finance leases $ 7.6  $ 3.8  Financing cash flows from finance leases $ 34.5  $ 2.8  Supplemental non-cash information on right-of-use assets obtained in exchange for new lease liabilities: Operating leases $ 28.5  $ 45.6  Finance leases $ 5.4  $ 9.2 "}]}
+{"image": "doclay/doclay_5926.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "During 2001, the Company adopted the Odyssey Re Holdings Corp. Stock Option Plan (the “Option Plan”), which provides for the grant of stock options to directors and key employees of the Company. Under the Option Plan, such options will generally vest and become exercisable in two equal installments on the fifth and tenth anniversary of the date of grant. As of December 31, 2004 and 2003, respectively, 97,685 and 52,654 options wer issued with an exercise price of zero. For the year ended December 31, 2004, 48,472 options were granted, 741 options wer e exercised and 2,700 options were forfeited, pursuant to the Option Plan. The Company has reflected, in other expense, net, $0.5 million, $0.2 million and $0.4 million of expense for the years ended December 31, 2004, 2003 and 2002 respectively which represents the vested portion of the stock options.\nThe Company provides a compensatory employee stock purchase plan through which all employees who meet the eligibility requirements of the plan have the option to purchase OdysseyRe common stock in an amount up to 10% of their annual base salary. The Company purchases, on the employee’ behalf, OdysseyRe common stock equal to 30% of each employee’s contribution. In the event that the Company meets certain financial objectives, additional shares are purchased for the employee’s benefit. The expense related to this plan for the years ended December 31, 2004, 2003 and 2002 was $0.5 million, $0.3 million and $0.2 million, respectively.\nDuring 2001, the Company adopted the Odyssey Re Holdings Corp. Restricted Share Plan (the “Restricted Share Plan”), which provides for the grant of restricted shares to directors and key employees of the Company. Shares granted under the Restricted Shar Plan generally vest in two equal installments on the fifth and tenth anniversary of the date of grant. As of December 31, 2004 and 2003, respectively, 506,866 and 439,474 shares of r estricted stock were outstanding. During the year ended December 31, 2004, 184,005 restricted shares were granted, 72,272 restricted shares vested and 44,341 restricted shares were forfeited, pursuant to the Restricted Shar Plan. At the time of grant, the market value of the shares awarded is recorded as unearned compensation and is presented as a separate component of stockholders’ equity. The unearned compensation is charged to operations over the vesting period. In respect to the above grants, the compensation expense incurred for each of the years ended December 31, 2004, 2003 and 2002 was $1.8 million, $1.1 million and $1.1 million, respectively, and is included in other expense, net.\nCertain employees of the Company have been granted shares of r estricted Fairfax common stock under the Fairfax Financial Holdings Ltd. Restricted Share Plan. The Fairfax restricted stock, which was granted from 1996 to 2000, vests over a three to ten year period. The Company has reflected $0.4 million, $0.3 million and $0.3 million of expense for the years ended December 31, 2004, 2003 and 2002, respectively, which represents the vested portion of the restricted stock. The Company no longer participates in this plan.\nPre-tax income, before cumulative effects of a change in accounting principle, from domestic companies, was $150.1 million, $286.1 million and $252.9 million for the years ended December 31, 2004, 2003 and 2002, respectively. Pre-tax income from foreign operations was $128.7 million, $92.2 million and $5.2 million for the years ended December 31, 2004, 2003 and 2002, respectively.\n11. FEDERAL AND FOREIGN INCOME TAXES\nDuring 2002 and through March 3, 2003, the Company and its United States subsidiaries filed a separate consolidated tax return. On March 4, 2003, Fairfax increased its ownership interest in the Company to approximately 81%. As a result, the Company and its United States subsidiaries ar included in the United States tax group of Fairfax Inc. Inclusion of the Company into Fairfax Inc.’s tax group did not have an effect on the Company’ tax position. The federal income tax provision is allocated to each of the companies in the consolidated group pursuant to a written agr eement, on the basis of each company’s separate return taxable income. As of December 31, 2001, the Company had a net operating loss carry forward of $186.3 million, which was fully utilized during 2002.\nODYSSEY RE HOLDINGS CORP.\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS, Continued\n73"}]}
+{"image": "doclay/doclay_2272.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "temperature and number of bath spins N is not too large. This is somewhat similar to the Zeno behavior pointed out in Ref. [38].\nof N , in contrast to the results for random couplings and fre- quencies. Clearly, as N gets larger, these recurrences become sharper, until in the limit N → ∞ they become isolated peaks, as shown in the right-side panels of Figs. 4 and 5. In the low temperature limit β Ω → ∞ and | Π$_{N}$ | → exp( N 2 β Ω) , but so does the partition function Z = ∑ 2 $^{N}$− 1 i =0 e − 1 $_{2}$β Ω ∑ N n $_{=1}$( − 1) i n = (2 cosh[ f (0)]) N → exp( N 2 β Ω) , so that χ$_{3}$, χ$_{4}$ → 1 , and all the capacities are saturated at their maximum values. For small, but finite temperatures, the capacities exhibit oscilla- tions with an amplitude that grows with N , as can be seen in the left-side panels of Figs. 4 and 5. This is in contrast to the case of random couplings seen in Figs. 2 and 3; there destruc- tive interference caused a cancellation of these oscillations, while in the case of equal couplings the capacity oscillations survive and grow with the number of bath spins, reflecting the increased information transfer from the system to the bath as a function of bath size.\nWe have studied an exactly solvable spin-star system for transmission of classical and quantum information. The in- formation is encoded into a system spin which interacts with a spin-bath via arbitrary Ising couplings. We considered the “parallel uses” setting of a memoryless quantum channel, where multiple copies of the system spin are transmitted si- multaneously via the same number of copies of the spin bath. As our model is described by the dephasing channel, classical information can be transmitted noiselessly, while the quan- tum capacity can be determined via the “single-letter” for- mula Q = Q$_{1}$ , i.e., it suffices to consider a single copy of the spin-star system. We analytically determined the quan- tum capacities of this communication system, which exhibit a strong dependence on the couplings of the bath spins with the system, and on the bath temperature. The Ising spin bath be- comes noisier as the temperature is increased, and the capac- ities rapidly deteriorate. For random couplings and frequen- cies, recurrences are of small amplitude and die out rapidly. However, for equal couplings and frequencies full periodic recurrences occur independently of the number of bath spins. These recurrences are a signature of the non-Markovian nature of the spin-bath. At low temperature the quantum capacities remain high when the number of bath spins is not too large.\nV. SUMMARY AND CONCLUSIONS\n6\np$_{1}$ ( x$_{1}$, x$_{2}$ ) = cos $^{2}$x$_{1}$ cos $^{2}$x$_{2}$ , p$_{2}$ ( x$_{1}$, x$_{2}$ ) = sin $^{2}$x$_{1}$ cos $^{2}$x$_{2}$ , p$_{3}$ ( x$_{1}$, x$_{2}$ ) = cos $^{2}$x$_{1}$ sin $^{2}$x$_{2}$ , p$_{4}$ ( x$_{1}$, x$_{2}$ ) = sin $^{2}$x$_{1}$ sin $^{2}$x$_{2}$ , (A1)\nN.A. was supported by Higher Education Commission Pak- istan under grant no. 063-111368-Ps3-001 and IRSIP-4-Ps- 08. D.A.L. was supported by the National Science Foundation under grants no. PHY-803304 and CHE-924318.\nWe prove Eq. (30). Without loss of generality the ensem- ble of orthogonal states given by Eq. (29) can be assumed to appear with probabilities parametrized as\nWithout symmetries in the coupling constants or frequen- cies the capacities rapidly decrease to their minimum values and we find no recurrences for N ≫ 1 , high temperature and uniformly distributed random values of g$_{n}$ and Ω$_{n}$ . However, partial recurrences occur in this situation for small tempera- ture.\nAppendix A: Derivation of the result for the classical capacity assisted by limited entanglement\nAcknowledgments\n2. Large N\n3. Short Times\nFIG. 4: Capacities C$_{E}$ (solid, thick), Q$_{E}$ (solid, thin) and Q (dashed) of a qubit coupled to an Ising spin bath with N = 4 , for g$_{n}$ = 1 and Ω$_{n}$ = 1 ∀ n . Left: β = 10 , right: β = 1 .\nFIG. 5: Same as Fig. 4, with N = 100 .\nwhere 0 ≤ θ, x$_{1}$, x$_{2}$ ≤ π $_{4}$. We will show by explicit cal- culation that for our pure dephasing model only the second term in Eq. (8) for the classical capacity assisted by limited entanglement depends on the parameters x$_{1}$, x$_{2}$ . Hence the maximization can be carried out, for fixed θ , by maximizing only this second term.\nThe capacities are flat initially and do not decay exponen- tially in the limit of short times αt ≪ 1 , provided that the"}]}
+{"image": "doclay/doclay_72466.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "ITEM 8. FINANCIAL STATEMENTS AND SUPPLEMENTARY DATA\nINDEX TO CONSOLIDATED FINANCIAL STATEMENTS\nCHENIERE ENERGY, INC. AND SUBSIDIARIES\nManagement’s Report to the Stockholders of Cheniere Energy, Inc. 68 Reports of Independent Registered Public Accounting Firm 69 Consolidated Balance Sheets 72 Consolidated Statements of Operations 73 Consolidated Statements of Stockholders’ Equity 74 Consolidated Statements of Cash Flows 75 Notes to Consolidated Financial Statements 76 Supplemental Information to Consolidated Financial Statements—Summarized Quarterly Financial Data 118\n67"}]}
+{"image": "doclay/doclay_65112.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "UNITED  STATES  PATENT  AND  TRADEMARK  OFFICE \nCERTIFICATE  OF  CORRECTION \nPATENT NO.  :  6,203,934  Bl \nDATED  :  March 20, 2001 \nINVENTOR(S)  : Naoe et al. \nPage 1 of 1 \nIt is  certified that  error appears  in the  above-identified  patent and  that said  Letters Patent  is  hereby corrected  as shown  below: \nClaim 1, \nLine 6, change  \"03.0\" to  -- 0.30 --. \nSigned and  Sealed this \nAttest: \nAttesting  Officer \nTwentieth  Day of  November,  2001 NICHOLAS  P. GODICI  Acting Director  of the United  States Patent  and  Trademark  Office "}]}
+{"image": "doclay/doclay_8008.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS\nVORNADO REALTY TRUST 61\nLIBOR floor of 2.50% on $35,000,000, a three year term and two one-year extension options. The Company accounts for its investment on the equity method.\nOn December 12, 2003, the Company acquired the Bergen Mall for approximately $145,000,000. This purchase was funded as part of a Section 1031 tax-free “like-kind” exchange with a portion of the proceeds from the sale of the Company’s  Two Park Avenue property. The Bergen Mall is a 903,000 square foot shopping center located on Route 4 East in Paramus, New Jersey. The center is anchored by Macy’s, Value City , Marshalls and Off Saks Fifth Avenue. The Company intends to expand, re-tenant and redevelop the center in order to r eposition the asset. On January 27, 2004, the Company entered into an agreement to modify the Value City lease to give the Company a one-year option to terminate the lease no earlier than one year after notification and upon payment of $12,000,000 to the tenant. The present value of this option is reflected in the acquisition price and is included in other liabilities in the consolidated balance sheet.\nOn October 20, 2003 the Company made a $200 million mezzanine loan secured by partnership interests in the General Motors Building. The General Motors Building was acquir ed by Macklowe Properties in September 2003 for approximately $1.4 billion. Vornado’s loan is subordinate to $900 million of other debt. The loan is based on a rate of LIBOR plus 8.685% (with a LIBOR floor of 1.5%) and currently yields 10.185%. Further, on October 30, 2003, the Company made an additional $25 million loan, as part of a $50 million loan, the balance of which was funded by an affiliate of Soros Fund Management LLC. This loan, which is junior to the $1.1 billion of loans noted above, is based on a rate of LIBOR plus 12.81% (with a LIBOR floor of 1.5%) and currently yields 14.31%. These loans matur e in October 2005, with three one-year extensions.\nOn February 3, 2004, the Company acquired the Forest Plaza Shopping Center for approximately $32,500,000, of which $14,000,000 was paid in cash, and $18,500,000 was debt assumed. The purchase was funded as part of Section 1031  tax-free “like kind” exchange with the remaining portion of the proceeds from the sale of the Company’s Two Park Avenue property. Forest Plaza is a 165,000 squar foot shopping center located in Staten Island, New York, anchored by a Waldbaum’s Supermarket. \nOn December 31, 2002, the Company and Crescent Real Estate Equities formed a joint venture to acquire the Carthage, Missouri and Kansas City, Kansas quarries from AmeriCold Logistics, the Company’s tenant at the cold storage warehouses (Temperature Controlled Logistics) facilities for $20,000,000 in cash (appraised value). The Company contributed cash of $8,800,000 to the joint venture representing its 44% inter est. The Company accounts for its investment in the venture on the equity method.\nThe Company entered into an agreement to acquire a 62,000 square foot free-standing retail building located at 25 W. 14th Street in Manhattan for $40,000,000. The building, which was r ecently renovated, is 87% occupied as of December 31, 2003. The acquisition is expected to be completed in the second quarter of 2004. \nThe following sets forth the details of sales, dispositions, write-offs and other similar transactions for the years ended December 31, 2003, 2002 and 2001:\nBERGEN MALL\nGENERAL MOTORS BUILDING MEZZANINE LOANS\nFOREST PLAZA SHOPPING CENTER\nOTHER\nDispositions:"}]}
+{"image": "doclay/doclay_48742.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\n(2) Absatz 1 Nr. 3 Buchstabe c bis f und Nr. 4 Buchstabe a, c und d gilt entsprechend für die Stellvertreter und Stellvertreterinnen, wenn sie die Vertretung ausüben.\nAnhang 3 Flaggen für Dienstkraftfahrzeuge\n- Seite 7 von 11 -"}]}
+{"image": "doclay/doclay_6602.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "FIRST COMMONWEALTH FINANCIAL CORPORATION AND SUBSIDIARIES\nMANAGEMENT’S DISCUSSION AND ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS\nstructure of the transaction as set forth in loan policy.\nCommercial real estate loans are granted for the acquisition or improvement of real property. Generally, commercial real estate loans do not exceed 75% of the appraised value of property pledged to secure the transaction. Repayment of such loans are expected from the operations of the subject real estate and are carefully analyzed prior to approval.\nReal estate construction loans are granted for the purposes of constructing improvements to real property, both commercial and residential. On-site inspections are conducted by qualified individuals prior to periodic permanent project financing, which is generally committed prior to the commencement of construction financing.\nReal estate loans secured by 1-4 family residential housing properties are granted subject to statutory limits in effect for each bank regarding the maximum percentage of appraised value of the mortgaged property. Residential loan terms are normally established in compliance with secondary market requirements. Residential mortgage portfolio interest rate risk is controlled by secondary market sales, variable interest rate loans and balloon maturities.\nLoans to individuals represent financing extended to consumers for personal or household purposes, including automobile financing, education, home improvement and personal expenditures. These loans are granted in the form of installment, credit card or revolving credit transactions.\nConsumer creditworthiness is evaluated on the basis of ability to repay, stability of income sources and past credit history.\nThe Corporation maintains an allowance for credit losses at a level deemed sufficient to absorb losses which are inherent in the loan and lease portfolios at each balance sheet date.\nManagement reviews the adequacy of the allowance on a quarterly basis to ensure that the provision for credit losses has been charged against earnings in an amount necessary to maintain the allowance at a level that is appropriate based on management’s assessment of probable estimated losses. The Corporation’s methodology for assessing the appropriateness of the allowance for credit losses consists of several key elements. These elements include a specific allowance for\nprimary watch list classified loans, a formula allowance based on historical trends, an additional allowance for special circumstances and an unallocated allowance.\nWhile the Corporation consistently applies the following comprehensive methodology and procedure described in Note 1 “Accounting Policies,” allowance for credit loss methodologies incorporate management’s current judgments about the credit quality of the loan portfolio as well as collection probabilities for problem credits.\nAlthough management considers the allowance for credit losses to be adequate based on information currently available, additional allowance for credit loss provisions may be necessary due to changes in management estimates and assumptions about asset impairment, information about borrowers that indicate changes in the expected future cash flows or changes in economic conditions. The allowance for credit losses and the provision for credit losses are significant elements of the Corporation’s financial statements, therefore management periodically reviews the processes and procedures utilized in determining the allowance for credit losses to identify potential enhancements to these processes including development of additional management information systems to ensure that all relevant factors are appropriately considered in the allowance analysis. In addition, the Corporation maintains a system of internal controls which are independently monitored and tested by internal audit and loan review staff to ensure that the loss estimation model is maintained in accordance with internal policies and procedures as well as generally accepted accounting principals.\nSince all identified losses are immediately charged off, no portion of the allowance for credit losses is restricted to any individual credit or groups of credits, and the entire allowance is available to absorb any and all credit losses. For analytical purposes, the following table sets forth an allocation of the allowance for credit losses at December 31 according to the categories indicated. Management feels the unallocated portion of the reserve is necessary due to the uncertain economic and geo-political environment and its impact on a variety of sectors such as health care, lodging and energy.\nAllocation of the Allowance for Credit Losses\n(Dollar Amounts in Thousands)\n2002  2001 2000 1999 1998 Commercial, industrial, financial, agricultural and other $ 7,856 $ 6,315 $ 6,263 $ 6,321 $ 4,375 Real estate-construction 600 432 643 831  414 Real estate-commercial 7,201 9,808 9,064 7,675 5,119 Real estate-residential 5,294 7,379  10,211 9,928  10,319 Loans to individuals 3,035 3,845 4,938 5,131 5,223 Lease financing receivables 259 401 638 586  512 Unallocated 10,251 5,977 1,844 3,067 6,342 Total $34,496 $34,157 $33,601 $33,539 $ 32,304 Allowance as percentage of average total loans 1.33% 1.34% 1.34% 1.39% 1.32%\n52"}]}
+{"image": "doclay/doclay_42198.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "8/15/19\nAIM \nFIG 4 − 5 − 8 En Route  −  ADS − B/ADS − R/TIS − B/FIS − B Service Ceilings/FloorsFIG 4 − 5 − 9 Terminal  −  ADS − B/ADS − R/TIS − B/FIS − B Service Ceilings/FloorsSurveillance Systems\n4 − 5 − 16"}]}
+{"image": "doclay/doclay_43916.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "ROTORCR A FT FLYING HANDBOOK\n2000\nU.S. DEPARTMENT OF TRANSPORTATION FEDERALAVIA TION ADMINISTRATION Flight Standards Service"}]}
+{"image": "doclay/doclay_27133.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Mann-Whitney-Wilcoxon statistic. GLYPH<21> = 0 : 1 , N = 1000 No Autoregressive Errors Added F ( : ) is Normal t-test k = 2 k = 5 k = 10 GLYPH<23> = 1 , No e⁄ect 0.0506 0.0518 0.0484 0.0498 GLYPH<23> = 20 , No interference 0.8020 0.7050 0.9416 0.9710 GLYPH<23> = 20 , Interference A 0.3044 0.2366 0.4294 0.5052 GLYPH<23> = 20 , Interference B 0.3110 0.2466 0.4266 0.5052 GLYPH<23> = 20 , Interference C 0.1094 0.0914 0.1414 0.1598 GLYPH<23> = 20 , Interference D 0.0672 0.0652 0.0714 0.0654 F ( : ) is the t-distribution, 2 df t-test k = 2 k = 5 k = 10 GLYPH<23> = 1 , No e⁄ect 0.0452 0.0544 0.0506 0.0500 GLYPH<23> = 20 , No interference 0.6992 0.6938 0.9316 0.9658 GLYPH<23> = 20 , Interference A 0.2788 0.2476 0.4292 0.4996 GLYPH<23> = 20 , Interference B 0.2624 0.2354 0.4278 0.4956 GLYPH<23> = 20 , Interference C 0.1024 0.0934 0.1364 0.1576 GLYPH<23> = 20 , Interference D 0.0636 0.0646 0.0698 0.0712 Autoregressive Errors Added F ( : ) is Normal t-test k = 2 k = 5 k = 10 GLYPH<23> = 1 , No e⁄ect 0.0480 0.0486 0.0474 0.0434 GLYPH<23> = 20 , No interference 0.4634 0.4254 0.5342 0.5034 GLYPH<23> = 20 , Interference A 0.1600 0.1472 0.1810 0.1604 GLYPH<23> = 20 , Interference B 0.1646 0.1494 0.1852 0.1672 GLYPH<23> = 20 , Interference C 0.0760 0.0736 0.0764 0.0714 GLYPH<23> = 20 , Interference D 0.0500 0.0496 0.0538 0.0516 F ( : ) is the t-distribution, 2 df t-test k = 2 k = 5 k = 10 GLYPH<23> = 1 , No e⁄ect 0.0450 0.0474 0.0460 0.0486 GLYPH<23> = 20 , No interference 0.6610 0.6270 0.8600 0.9030 GLYPH<23> = 20 , Interference A 0.2462 0.2052 0.3372 0.3938 GLYPH<23> = 20 , Interference B 0.2408 0.2000 0.3398 0.3914 GLYPH<23> = 20 , Interference C 0.0978 0.0828 0.1128 0.1274 GLYPH<23> = 20 , Interference D 0.0620 0.0608 0.0648 0.0658\nTable 6: Simulated power with interference in a randomized experiment in a single block, B = 1 , of size N = 1000 , when 10% of trials are successful, GLYPH<21> = 0 : 1 . The case GLYPH<23> = 1 is the null hypothesis of no e⁄ect and hence no interference among e⁄ects, so the simulation is estimating the true size of a test with nominal level 0.05. The statistic k = 2 is the Mann-Whitney-Wilcoxon statistic.\n30"}]}
+{"image": "doclay/doclay_8908.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "CONSOLIDATED BALANCE SHEETS (IN THOUSANDS)\n2001 STRATTEC Annual Report 14\nThe accompanying notes are an integral part of these consolidated balance sheets.\nJuly 1, 2001 July 2, 2000 ASSETS CURRENT ASSETS Cash and cash equivalents $15,298 $13,9150 Receivables, less allowance for doubtful  accounts of $250 at July 1, 2001, and July 2, 2000 27,189 28,731) Inventories 8,605 14,342) Customer tooling in progress 2,588 4,248) Future income tax benefits 1,880 2,092) Other current assets 4,107 3,273) ) ) Total current assets 59,667 66,601) DEFERRED INCOME TAXES 130 - PROPERTY, PLANT, AND EQUIPMENT, NET 41,851 42,381) ) ) $101,648 $108,982) ) ) LIABILITIES AND SHAREHOLDERS’ EQUITY CURRENT LIABILITIES Accounts payable $14,178 $19,694) Accrued liabilities: Payroll and benefits 7,501 10,394) Environmental 2,749 2,770) Income taxes 354 47) Other 1,711 1,196) ) ) Total current liabilities 26,493 34,101) DEFERRED INCOME TAXES - 299) BORROWINGS UNDER REVOLVING CREDIT FACILITY - - ACCRUED PENSION OBLIGATIONS 10,617 9,839 ACCRUED POST-RETIREMENT OBLIGATIONS 4,528 4,293 SHAREHOLDERS’ EQUITY Common stock, authorized 12,000,000 shares  $.01 par value, issued 6,195,889 shares  at July 1, 2001, and 6,120,788 shares at July 2, 2000 62 61) Capital in excess of par value 49,545 47,924) Retained earnings 80,990 67,964) Accumulated other comprehensive loss (1,749) (2,239) Less: Treasury stock, at cost (2,149,800 shares at  July 1, 2001, and 1,668,179 shares at July 2, 2000) (68,838) (53,260)) ) ) Total shareholders’ equity 60,010 60,450) ) ) $101,648 $108,982) ) )"}]}
+{"image": "doclay/doclay_70162.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "8464ch04_Planning.fm\nDraft Document for Review February 7, 2020 3:15 pm\nAfter removal begins, the TS7700 continues to remove virtual volumes until the stop threshold  is met. The stop threshold is a value that is the removal threshold minus 500 GB. A particular  virtual volume cannot be removed from a TS7700 cache until the TS7700 verifies that a  consistent copy exists on a peer cluster. \nIf a peer cluster is not available or a volume copy is not yet completed, the virtual volume is  not a candidate for removal until the appropriate number of copies can be verified later. Time  delayed replication can alter the removal behavior.\nTip:  This field is visible only if the selected cluster is a TS7700 in a grid configuration.\nThe temporary removal threshold lowers the default removal threshold to a value lower than  the stop threshold in anticipation of a service mode event, or before a DR test where  FlashCopy for DR testing is used.\nVirtual volumes might need to be removed before one or more clusters enter service mode.  When a cluster in the grid enters service mode, remaining clusters can lose their ability to  make or validate volume copies, which prevents the removal of enough logical volumes. This  scenario can quickly lead to the TS7700 cache reaching its maximum capacity.\nThe lower threshold creates more free cache space, which enables the TS7700 to accept any  host requests or copies during the service outage without reaching its maximum cache  capacity. \nThe temporary removal threshold value must be greater than or equal to (>=) the expected  amount of compressed host workload that is written, copied, or both to the TS7700 during the  service outage. The default temporary removal threshold is 4 TB, which provides 5 TB (4 TB  plus 1 TB) of existing free space. You can lower the threshold to any value from 2 TB to full  capacity minus 2 TB. \nAll TS7700 clusters in the grid that remain available automatically lower their removal  thresholds to the temporary removal threshold value that is defined for each one. Each  TS7700 cluster can use a different temporary removal threshold. The default temporary  removal threshold value is 4 TB or 1 TB more data than the default removal threshold of 3 TB.  Each TS7700 cluster uses its defined value until the originating cluster in the grid enters  service mode or the temporary removal process is canceled. The cluster that is starting the  temporary removal process does not lower its own removal threshold during this process.\nTemporary removal threshold\n4.2.7 Data management settings (TS7700T CPx in a multi-cluster grid)\nThe following settings for the TS7700 are optional, and they can be configured during the  installation of the TS7700, or later by using the TS7700  LIBRARY REQUEST (LI REQ)  command  interface:\nGLYPH<SM590000> Copies to Follow Storage Class Preference (COPYFSC)\nGLYPH<SM590000> Recalls Preferred to be Removed from Cache (RECLPG0)\nNote:  For more information about the Host Console Request functions and their  responses, see  IBM Virtualization Engine TS7700 Series z/OS Host Command Line  Request User’s Guide , WP101091.\n164  IBM TS7700 Release 5.0 Guide"}]}
+{"image": "doclay/doclay_61956.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Page 2 \nUS 8,691,490 B2 \nOTHER PUBLICATIONS \n* cited by examiner \nDevoe et al., \"Photochemistry and Photophysics of ’Onium Salts*,\" \nAdvances in Photochemistry,  vol. 17, pp. 313-355, 1992, John Wiley  & Sons. \nDamme! et al., \"193 nm Immersion Lithography-Taking the  Plunge,\"  Journal of Photopolymer Science and Technology,  vol. 17, \nNo. 4, pp. 587-602, 2004. \nArimitsu et al., \"Sensitivity Enhancement of Chemical-Ampflica› tion-Type Photo imaging Materials by Acetoacetic Acid Derivatives,\"  Journal of Photopolymer Science and Technology,  vol. 8, No. 1, pp.  43-46, 1995. \nArimitsu et al., \"Effect of Phenolic Hydroxyl Residues on the  Improvement of Acid-Proliferation-Type Photoimaging Materials,\"  Journal of Photopolymer Science and Technology,  vol. 9, No. 1, pp.  29-30, 1996. \nLowe, \"Synthesis of sulphonium salts,\"  The Chemistry of the  Sulphonium Group,  Ed. Stirling et al., Chapter 11, pp. 267-312, 1981,  John Wiley & Sons Ltd. \nJul. 17, 2013 Office Action issued in U.S. Appl. No. 13/476,629.  Sep. 12, 2013 Office Action issued in U.S. Appl. No. 13/476,700.  Sep. 30, 2013 European Search Report issued in European Applica› tion No. 12003989.6. \nDec. 16, 2013 Office Action issued in U.S. Appl. No. 13/476,700. \nFOREIGN PATENT DOCUMENTS \nU.S. PATENT DOCUMENTS \n(56)  References Cited \n10/2009  11/2009  11/2009  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  WO  WO  WO  A-2009-242789  A-2009-269953  A-2009-276363  A-2010-002599  A-2010-107695  A-2010-134012  A-2010-155824  B2-4539865  A-2010-250290  A-2010-271501  A-2011-006398  A-2011-026300  1/2010  5/2010  6/2010  7/2010  7/2010  A-2011-37834  A-2011-037836  A-2011-085878  WO 89/03389 Al  WO 2007 /069640 Al  WO 2010/119910 Al  11/2010  12/2010  1/2011  2/2011  2/2011  2/2011  4/2011  4/1989  6/2007  10/2010 \n6/2010 Harada et al.  6/2010 Ohashi et al.  2010/0136482  Al  2010/0143830  Al  2010/0159392  Al  *  2010/0248149  Al  2010/0297560  Al  2010/0304294  Al  2011/0014566  Al  2011/0189607  Al  2012/0065291  Al  2012/0308920  Al  2012/0308932  Al  6/2010 Hatakeyama et al. ..... 430/286.1  9/2010 Tsuchimura et al.  11/2010 Seshimo et al.  12/2010 Ichikawa et al.  1/2011 Ichikawa et al.  8/2011 Ohashi et al.  3/2012 Matsumura et al.  12/2012 Dornon et al.  12/2012 Sagehashi et al. \nJP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  JP  A-4-230645  A-11-282168  A-2000-159758  A-2000-336121  A-2002-214774  A-2003-66612  A-2004-2252  A-2004-115630  A-2004-531749  B2-3613491  A-2005-8766  A-2005-84365  A-2006-178317  A-2006-306856  A-2007-145797  A-2007-197718  A-2007-297590  A-2007-304490  A-2008-31298  A-2008-80474  A-2008-106045  A-2008-111103  A-2008-122932  A-2008-133448  A-2008-158339  A-2009-7323  A-2009-98638  A-2009-191151  A-2009-192784  8/1992  10/1999  6/2000  12/2000  7/2002  3/2003  1/2004  4/2004  10/2004  11/2004  1/2005  3/2005  7/2006  11/2006  6/2007  8/2007  11/2007  11/2007  2/2008  4/2008  5/2008  5/2008  5/2008  6/2008  7/2008  1/2009  5/2009  8/2009  8/2009 "}]}
+{"image": "doclay/doclay_41946.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "detect when the gear reaches the full retract (UP) position.  Three down-limit switches are used to detect when the gear  reach the full extended (DOWN) position. Each of these  switches is mechanically activated by a component of the  landing gear assembly when the appropriate gear reaches  a given limit.\nand performs two functions (called a circuit breaker switch).  It should also be noted that the avionics contactor is often  referred to as a split bus relay, since the contactor separates  (splits) the avionics bus from the main bus. \nAnother common circuit found on light aircraft operates  the retractable landing gear systems on high-performance  light aircraft. These airplanes typically employ a hydraulic  system to move the gear. After takeoff, the pilot moves  the gear position switch to the retract position, starting an  electric motor. The motor operates a hydraulic pump, and the  hydraulic system moves the landing gear. To ensure correct  operation of the system, the landing gear electrical system  is relatively complex. The electrical system must detect the  position of each gear (right, left, nose) and determine when  each reaches full up or down; the motor is then controlled  accordingly. There are safety systems to help prevent  accidental actuation of the gear. \nThe landing gear system must also provide an indication to  the pilot that the gear is in a safe position for landing. Many  aircraft employ a series of three green lights when all three  gears are down and locked in the landing position. These three  lights are activated by the up- and down-limit switches found  in the gear wheel well. A typical instrument panel showing  the landing gear position switch and the three gears down  indicators is shown in  Figure 9-94 . \nThe hydraulic motor/pump assembly located in the upper left  corner of  Figure 9-95  is powered through either the UP or  DOWN solenoids (top left). The solenoids are controlled by  the gear selector switch (bottom left) and the six landing gear  limit switches (located in the center of  Figure 9-95 ). The three  gear DOWN indicators are individual green lights (center of  Figure 9-95 ) controlled by the three gear DOWN switches.  As each gear reaches its DOWN position, the limit switch  moves to the DOWN position, and the light is illuminated. \nA series of limit switches are needed to monitor the position  of each gear during the operation of the system. (A limit  switch is simply a spring-loaded, momentary contact switch  that is activated when a gear reaches it limit of travel.)  Typically, there are six limit switches located in the landing  gear wheel wells. The three up-limit switches are used to \nLanding Gear Circuit\nFigure 9-94.  Instrument panel showing the landing gear position switch and the three gear down indicators. \n9-52\n"}]}
+{"image": "doclay/doclay_58664.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "\"contribs\" : [ \"Scala\" ] }\nMongoDB Documentation, Release 3.0.4\nChapter 3. MongoDB CRUD Operations\n142"}]}
+{"image": "doclay/doclay_8036.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "John T. Chambers Stephen Friedman Stanley C. Gault David D. Glass Roland Hernandez Dr. Frederick S. Humphries E. Stanley Kroenke Elizabeth A. Sanders H. Lee Scott Jack C. Shewmaker Donald G. Soderquist Dr. Paula Stern Jose Villarreal John T. Walton S. Robson Walton\nOFFICERS:\nDIRECTORS:\nS. Robson Walton Chairman of the Board\nH. Lee Scott President & CEO\nDavid D. Glass Chairman, Executive Committee  of the Board\nPaul R. Carter Executive Vice President & President, Wal-Mart Realty\nBob Connolly Executive Vice President, Merchandise \nThomas M. Coughlin Executive Vice President & President & CEO, Wal-Mart Stores Division\nDavid Dible Executive Vice President, Specialty Division\nMichael Duke Executive Vice President, Administration\nThomas Grimm Executive Vice President & President & CEO, SAM’S CLUB\nDon Harris Executive Vice President, Operations\nJohn B. Menzer Executive Vice President & President & CEO, International Division\nColeman Peterson Executive Vice President, People Division\nThomas M. Schoewe Executive Vice President & Chief Financial Officer\nRobert K. Rhoads Senior Vice President, General Counsel & Secretary\nJ. J. Fitzsimmons Senior Vice President, Finance & Treasurer\nFINANCIAL HIGHLIGHTS\nANNUAL REPORT 2001*Calculated giving effect to the amount by which a lawsuit settlement exceeded established reserves. If this settlement was not considered,  the return was 9.8%.\n1\n1997 $104.9 1998 $118.0 1999 $137.6 2000 $165.0 2001 $191.3 Net Sales\n1997 $.67 1998 $.78 1999 $.99 2000 $1.21 2001 $1.41 Earnings Per Share\n1997 7.9% 1998 8.5% 1999 9.6% 2000 9.5%* 2001 8.7% Return on Assets\n1997 19.2 % 1998 19.8% 1999 22.4% 2000 22.9% 2001 22.0% Return on Shareholder’s Equity"}]}
+{"image": "doclay/doclay_715.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Notes to the Consolidated Financial Statements Dollar amounts are in thousands of Canadian dollars (except share and per share amounts)\n16. Capital Stock and Contributed Surplus (continued)\n17 Share‑Based Compensation\n86 Killam ProPerties inc | 2013\nDividend Reinvestment Plan\nContributed Surplus\nThe exercisable options had a weighted average exercise price of $7.60 at December 31, 2013 (December 31, 2012 ‑ $7.25).\nThe following table summarizes the stock options outstanding:\nOptions exercised or forfeited during the years ended December 31 are as follows:\nKillam did not issue stock options during 2013 or 2012.\nKillam’s Dividend reinvestment Plan (“DriP”) allows common shareholders to elect to have all cash dividends from Killam reinvested in  additional common shares. Shareholders who participate in the DRIP receive an additional dividend of common shares equal to 3% of  each cash dividend that was reinvested. the price per share is calculated by reference to a ten day volume weighted average closing price  of Killam’s common shares on the Toronto Stock Exchange preceding the relevant dividend date, which typically is on or about the 15th day  of the month following the dividend declaration.\n2013 2012 Balance, beginning of year $2,241 $2,251 Stock options expensed 44 116 Stock options exercised (111) (589) restricted share units issued 580 463 restricted share units redeemed (452) ‑ $2,302 $2,241\nFor the years ended December 31, 2013 2012 Stock option plan $44 $116 restricted share unit plan 421 463 Total share based compensation expense  $465 $579\n2013 2012 Number of  Shares Weighted Average  Exercise Price number of  shares Weighted average  Exercise Price Outstanding, beginning of year 694,756 $7.40 1,180,766 $7.49 Exercised (144,349) 6.40 (471,593) 7.65 Forfeited ‑ ‑ (14,417) 7.00 Outstanding, end of year 550,407 $7.66 694,756 $7.40\nAs at December 31, 2013 December 31, 2012 Exercise  Price Number  of Options  Outstanding Remaining  Contractual  Life Options  Exercisable number  of Options  outstanding remaining  contractual  life Options  Exercisable $5.32 97,500 0.35 years 97,500 186,749 1.35 years  155,502 $8.11 ‑ ‑ ‑ 1,250 0.10 years  1,208 $8.16 452,907 1.40 years 399,783 506,757 2.4 years  326,366 550,407 497,283 694,756  483,076"}]}
+{"image": "doclay/doclay_18296.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Part II  iteM 7 Management’s Discussion and analysis of Financial Condition and results of operations\nfor legal reserves and expenses related to discontinued operations.  Discontinued environmental charges include environmental remediation  costs at sites of discontinued businesses for which we are responsible  for environmental compliance.\nNet income attributable to FMC stockholders decreased to $228.5 million  in 2009 compared with $304.6 million in 2008. The decrease was  primarily due to lower Industrial Chemicals segment operating profit  and significantly higher restructuring and other charges (income).  Partially offsetting these decreases were higher profits in our Agricultural  Products segment and to a lesser extent, our Specialty Chemicals segment.\nCash and cash equivalents at December 31, 2010 and 2009 were  $161.5 million and $76.6 million, respectively. We had total debt  of $637.9 million and $643.9 million at December 31, 2010 and  2009, respectively. This included $503.0 million and $588.0 million  of long-term debt (excluding current portions of $116.4 million  and $22.5 million) at December 31, 2010 and 2009, respectively.  Short-term debt, which consists of foreign borrowings, decreased to  $18.5 million at December 31, 2010 compared to $33.4 million at  December 31, 2009.\nOn November 30, 2009, we issued $300 million aggregate principal  amount of 5.20% Senior Notes due 2019. The net proceeds from  the offering were used to pay down existing indebtedness under our  revolving credit agreements and for general corporate purposes.\nOn August 28, 2007, we executed a credit agreement (the “Domestic  Credit Agreement”), which provided for a five-year, $600 million  revolving credit facility. The proceeds from this facility are available for  general corporate purposes, including issuing letters of credit up to a  $300 million sub-limit. The Domestic Credit Agreement also contains  an option under which, subject to certain conditions, we may request  an increase in the facility to $1 billion.\nLoans under the facility bear interest at a floating rate, either a base  rate as defined, or the applicable euro currency rate for the relevant  term plus an applicable margin. The margin is 0.3 percent per year,  subject to adjustment based on the credit rating assigned to our senior  unsecured debt. At December 31, 2010, the applicable borrowing rate  under our Domestic Credit Agreement was 0.6 percent per annum.\nWe had no borrowings under our Domestic Credit Agreement at  December 31, 2010 and December 31, 2009. Letters of credit outstanding  under the Domestic Credit Agreement totaled $130.4 million and  $153.2 million at December 31, 2010 and 2009, respectively. Available  funds under the Domestic Credit Agreement were $469.6 million and  $446.8 million at December 31, 2010 and 2009, respectively.\nOn December 16, 2005, FMC Finance B.V., our Dutch finance  subsidiary, executed a credit agreement (the “European Credit  Agreement”), which provides for an unsecured revolving credit facility \nin the amount of €220 million. Borrowings may be denominated in  euros or U.S. dollars. FMC and our Dutch finance subsidiary’s direct  parent provide guarantees of amounts due under the European Credit  Agreement. On August 13, 2010, we amended this agreement to extend  its maturity to August 2012.\nLoans under the European Credit Agreement bear interest at a euro  currency base rate, which for loans denominated in euros is the Euro  InterBank Offered Rate, and for loans denominated in dollars is London  Interbank Offered Rate (“LIBOR”) in each case plus a margin. The  applicable margin under our European Credit Agreement is subject to  adjustment based on the rating assigned to FMC by each of Moody’s  and S&P. At December 31, 2010, the applicable margin was 1.8  percent and the applicable borrowing rate under the European Credit  Agreement was 2.5 percent per annum.\nAt December 31, 2010 and 2009 we had no borrowings, in revolving  credit facility borrowings under the European Credit Agreement, resulting  in available funds of $289.1 million and $315.4 million, respectively.\nAmong other restrictions, the Domestic Credit Agreement and the  European Credit Agreement contain financial covenants applicable to  FMC and its consolidated subsidiaries related to leverage (measured as  the ratio of debt to adjusted earnings) and interest coverage (measured  as the ratio of adjusted earnings to interest expense). Our actual leverage  for the four consecutive quarters ended December 31, 2010 was 1.2  which is below the maximum leverage of 3.5. Our actual interest  coverage for the four consecutive quarters ended December 31, 2010  was 14.9 which is above the minimum interest coverage of 3.5. We  were in compliance with all covenants at December 31, 2010.\nIncome from continuing operations of $218.5 million reflected  restructuring and other charges of $151.9 million, of which $81.1 million  was for non-cash asset write-downs related to the exit of various facilities  announced in 2010 and $46.1 million of other facilities exit costs to be  settled in cash, mainly for severance costs and lease obligations. Cash  spending on restructuring and other charges in 2010 was $53.4 million.  Also included in income from continuing operations was $14.2 million  for environmental and remediation at our operating sites, which will  be spent in years beyond 2010. Net cash spending on environmental  remediation at our operating sites in 2010 was $8.9 million which  was recorded against pre-existing reserves. Income from continuing  operations is also adjusted for other non-cash items which include stock- based compensation expense and excess tax benefits from share-based  compensation. There was a significant increase in excess tax benefits  from share-based compensation because we utilized our remaining U.S.  federal net operating losses in 2010. See Note 14 to our consolidated  financial statements included in this Form 10-K for further discussion  on these excess tax benefits.\nReceivables were a use of cash of $109.9 million due to revenue increases  in our businesses, particularly for Agricultural Products sales in Brazil  where terms are significantly longer than in the rest of our businesses.  Partially offsetting the higher receivables were accrued customer rebates  which increased by $33.2 million due to increased sales primarily in  our Agricultural Products segment. These rebates are primarily in  North America and Brazil and generally settle in the fourth quarter of  each year, however, have increased from the prior year due to higher \nNet income attributable to FMC stockholders\nLiquidity and Capital resources\n2009 Senior Notes Offering\nDomestic Credit Agreement\nEuropean Credit Agreement\nStatement of Cash Flows\nCash provided by operating activities for 2010  was $399.7 million\n27 FMC Corporation    2010 Form 10K"}]}
+{"image": "doclay/doclay_49674.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "（十三） 誘導炉、アーク炉若しくはプラズマ若しくは電 子ビームを用いた溶解炉又はこれらの部分品若しくは附属 装置\n（十四） アイソスタチックプレス又はその部分品若しく は制御装置（四の項の中欄に掲げるものを除く。） （十五） ロボットであつて、次に掲げるもの若しくはそ の部分品又はこれらの制御装置\n１ 防爆構造のもの\n２ 放射線による影響を防止するように設計したもの （十六） 振動試験装置又はその部分品（四の項の中欄に 掲げるものを除く。）\n（十七） ガス遠心分離機のロータに用いられる構造材料 であつて、次に掲げるもの（四の項の中欄に掲げるものを 除く。）\n１ アルミニウム合金\n２ 炭素繊維、アラミド繊維若しくはガラス繊維、炭素繊 維若しくはガラス繊維を使用したプリプレグ又は炭素繊維 若しくはアラミド繊維を使用した成型品\n３ マルエージング鋼\n４ チタン合金\n（十八） ベリリウム若しくはベリリウム合金の地金若し くはくず若しくはベリリウム化合物又はこれらの半製品若 しくは一次製品（電子機器の部分品に用いるベリリウム酸 化物の半製品及び一次製品を除く。）\n（十九） 核兵器の起爆用のアルファ線源に用いられる物 質又はその原料となる物質（（一）に掲げるものを除 く。）\n（二十） ほう素一〇\n（二十一） 核燃料物質の製造用の還元剤又は酸化剤とし て用いられる物質\n（二十二） アクチニドに対して耐食性のある材料を用い たるつぼ\n（二十三） ハフニウム若しくはハフニウム合金の地金若 しくはくず若しくはハフニウム化合物又はこれらの半製品 若しくは一次製品\n（二十四） リチウム若しくはリチウム合金の地金若しく はくず若しくはリチウム化合物若しくはリチウム混合物又 はこれらの半製品若しくは一次製品\n（二十五） タングステン、タングステンの炭化物又はタ ングステン合金の一次製品（円筒形のもの、半球形のもの 又はこれらを組み合わせたものに限る。）\n（二十六） ジルコニウム若しくはジルコニウム合金の地 金若しくはくず若しくはジルコニウム化合物又はこれらの 半製品若しくは一次製品\n（二十七） ふっ素製造用の電解槽\n（二十八） ガス遠心分離機のロータの製造用若しくは組 立用の装置又はその部分品\n42 "}]}
+{"image": "doclay/doclay_7467.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\n(i) Property, plant and equipment and depreciation \n(j) Leases\n(k) Pension and severance plans\n(l) Provision for loss on repurchase of computers \n(m) Income taxes \n(n) Earnings per share \n(o) Derivative financial instruments\n(p) Change in significant accounting policy\n30\nProperty, plant and equipment, including renewals and additions, are carried at cost. \nDepreciation is computed principally by the declining-balance method at rates based on the estimated useful lives  of the respective assets, which vary according to their general classification, type of construction and function.\nMaintenance and repairs, including minor renewals and improvements, are charged to income as incurred.\nReceivable accounts recognized by the lessors in finance lease transactions are recorded as lease receivables and, assets acquired by lessees in finance lease transactions are recorded in the corresponding asset accounts.\nThe Company and most consolidated subsidiaries in Japan:\nPension costs of major defined benefit plans are based on annual contributions calculated by a projected benefit valuation method. Accrued severance benefits are stated at the present value of the vested benefit obligation which would be required to be paid if all employees voluntarily terminated their services at the balance sheet dates. Most consolidated subsidiaries outside Japan: \nPension costs of major defined benefit plans are calculated by a projected unit credit method.\nCertain computers manufactured by the Group are sold to Japan Electronic Computer Company Limited (“JECC”) and other leasing companies and financial institutions for leasing to the ultimate users under contracts which require that the Group repurchase the computers if they are returned by the users after a certain period. Based on past experience, an estimated amount for the loss arising from such repurchases is provided at the point of sale and is charged to income.\nThe Group has adopted the balance sheet liability method of tax effect accounting in order to recognize the effect of all temporary differences in the recognition of assets and liabilities for tax and financial reporting purposes.\nBasic earnings per share is computed based on the weighted average number of shares of common stock outstanding during the respective years. \nDiluted earnings per share is computed based on the weighted average number of shares after consideration of  the dilutive effect of the shares of common stock issuable upon the exercise of warrants and the conversion of convertible bonds.\nGains and losses on derivative financial instruments used to reduce exposure on receivables and liabilities denominated in foreign currencies are recognized over the lives of the contracts. Gains and losses arising from the related receivables and liabilities are offset.\nThe differentials to be paid or received relating to swap contracts are recognized over the lives of the contracts.\nPrior to the year ended March 31, 1999, the Company and its consolidated subsidiaries in Japan treated finance leases in the same way as operating leases, which is generally accepted in Japan. As Fujitsu Leasing Co., Ltd. became a consolidated subsidiary effective the year ended March 31, 2000, the Group has adopted a method under which the Group, as a lessee, records the leased assets and the corresponding lease obligations, and, as a lessor, records the lease receivables under finance leases.\nThe effect on consolidated net income and total assets caused by this change was immaterial."}]}
+{"image": "doclay/doclay_13705.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "MN WI MI MI OH IN KY TN MO IL OK AR MS AL GA NC VA PA NY VT ME NH ID CO OR WA CA FL AZ SC TDS TELECOM (ILEC) TDS METROCOM (CLEC) USLink (CLEC) States of operation TDS Telecommunications Corporation Corporate Headquarters, Madison, WIOur Virtual Business Office allows customers to get a response whenever they need service.\nCustomers Have Great Expectations \nTDS TELECOM\nThe Next Decade\n• Expand our CLEC business into more mid-size cities.\n• Make acquisitions in existing geographic clusters.\n• Expand high-speed Internet product availability with DSL and Integrated Services Digital Network (“ISDN”) offerings.\n• Raise productivity throughout the company by continually improving our processes and leveraging best practices between our ILEC and CLEC businesses.\n• Continue to work with regulators to make sure that our gains are shared with customers, employees and stockholders.\n• Lead the competition in customer satisfaction.\nMCT, Inc. of Contoocock, New Hampshire which serves 18,000 telephone access lines and 4,000 Internet and DSL customers. MCT lies adjacent to our existing New Hampshire TDS TELECOM exchanges already serving 8,000 access lines in the rapidly growing southern part of the state.\nWhen we ask our customers what they expect from their local phone company, they tell us that reliable, high-quality telephone service is paramount. In addition, they want value for price, smart and helpful employees, a responsive local repair service and new technologies. \nDelivering great service and, more importantly, maintaining a reputation for great service, means continually evaluating our performance. We track customer satisfaction ratings from the Company each month and use the results to help guide our interaction with our customers. Equipped with the data from these surveys, we have implemented new tools designed to retain existing customers and win new ones by enhancing our services. \nThe Virtual Business Office (“VBO”) introduced in 1996 continues to improve. It uses computer telephony integration to join offices together into regional clusters. The VBO structure enables TDS TELECOM to keep employees in local offices close to our customers and still offer the efficiencies of a highly professional, full-time call center. In response to our research findings, we have expanded our call center operations to\nWe owe our success to the outstanding employees who work for us at our operations around the country. With their dedication and the continuing support of you, our shareholders, we can have an outstanding 2002.\nWe are very disciplined in the way we plan our business. We have a strategy to grow that will build value for our shareholders and provide opportunities for our employees as they develop their abilities. We have a strategy to win in each of our markets by delivering state-of-the-art customer service. And, we have a strategy that produces outstanding operating results. Above all we have an outstanding team to achieve these strategies. Here are just a few of the initiatives and goals we have established for 2002 :\nGiven the ever-changing communications environment, I cannot predict what the next ten years will bring. But I know it will be good for TDS TELECOM because our business formula of providing excellent customer service with local operations will succeed even while our telecommunications products continue to change. In the short term, our 2002 initiatives will help us continue our focus on the customer, increase our brand value, and produce excellent financial results.\n24 hours a day, 7 days a week, 365 days per year. Our customers know that they can always get a response when they need service.\nWe have added self-service options to the Internet. Again, after listening to our customers we expanded our e-commerce and e-business capabilities to accommodate their needs with online purchasing and product information.\nWe maintain a local presence in the communities we serve with local customer service, sales, repair, and response teams. We believe that this local commitment is a critical component of our success. A strong local team is imperative to supporting our customers’ desire for a rapid response to a problem or installation request. We encourage employees to become involved in our communities. We also champion economic development in our communities and have worked to secure nearly  $1.3 million in loans for rural community and business development in 2001 through the federal Rural Economic Development program. Strengthening local communities is key to our continuing success. Joe Kirk Director-Mid Center Division Operations Continental, OH\nJoe started at TDS TELECOM as an Installation-Repairman 23 years ago. At every stage of his career he has demonstrated a passion for serving customers: “As telecommunications providers, we know how much our jobs affect our customers’ lives. That makes us perform at our peak. If people don’t have total customer focus when they come in, they get it from the people who are already fortunate to work here.”\nJoe also keeps his team focused on revenue generation, expense control and process improvement. “That way we maintain a challenging and rewarding work environment that celebrates and rewards individual and team contributions.”\n17\n16"}]}
+{"image": "doclay/doclay_8788.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Consolidated Statements of Income\nYear Ended\nAugust 30, August 31, August 25, 2003 2002 2001 (in thousands, except per share data) (52 Weeks) (53 Weeks) (52 Weeks) Net sales $5,457,123 $5,325,510 $4,818,185 Cost of sales, including warehouse and delivery expenses 2,942,114 2,950,123 2,804,896 Operating, selling, general and administrative expenses 1,597,212 1,604,379 1,498,909 Restructuring and impairment charges — — 126,689 Operating profit 917,797 771,008 387,691 Interest expense—net 84,790 79,860 100,665 Income before income taxes 833,007 691,148 287,026 Income taxes 315,403 263,000 111,500 Net income $ 517,604 $ 428,148 $ 175,526 Weighted average shares for basic earnings per share 94,906 104,446 112,834 Effect of dilutive stock equivalents 2,057 2,665 967 Adjusted weighted average shares for diluted earnings per share 96,963 107,111 113,801 Basic earnings per share $ 5.45 $ 4.10 $ 1.56 Diluted earnings per share $ 5.34 $ 4.00 $ 1.54\nSee Notes to Consolidated Financial Statements.\nAutoZone, Inc. 2003 Annual Report\n31"}]}
+{"image": "doclay/doclay_38793.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "6 months  1$^{st}$ stocktaking  meeting with the  European  Commission in  Brussels  1$^{st}$ interim report  Approval and  payment  within 60  calendar days  1$^{st}$ interim  payment  6 month + 10  days  Draft Minutes of the  1$^{st}$ stocktaking  meeting  12 months  2$^{nd}$ stocktaking  meeting with the  European  Commission in  Brussels  2$^{nd}$ interim report  Approval and  payment  within 60  calendar days  2$^{nd}$ interim  payment  12 month + 10  days  Draft Minutes of the  2$^{nd}$ stocktaking  meeting  18 months  Final report Approval and  payment  within 60  calendar days  Final payment \n1.5 Place of performance: where will the contract be performed? \n1.6 Nature of the contract: how will the contract be implemented? \n1.7 Volume and value of the contract: how much do we plan to buy? \nThe estimated total value of this contract is indicated under Heading II.1.5 of the contract  notice.\n  Tenderers need to take full account of the provisions of the Draft contract as the latter will  define and govern the contractual relationship(s) to be established between the  Contracting  authority and the successful tenderer(s). Special attention is to be paid to the provisions  specifying the rights and obligations of the contractor, in particular those on payments,  performance of the contract, confidentiality, and checks and audits. \nIn direct contracts all the terms governing the provision of the services, supplies or works are  defined at the outset. Once signed, they can be implemented directly without any further  contract procedures\nThe procedure will result in the conclusion of a direct contract. \n The services will be performed at the contractor's premises. \n15"}]}
+{"image": "doclay/doclay_25660.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "4\nCL ´ EMENT DOMBRY, MICHAEL FALK, MAXIMILIAN ZOTT\nOutline and terminology. In this paper, we deal with different kinds of records of stochastic processes, generally assuming they are in the max-domain of attraction of an MSP and have continuous univariate marginal df. Let X , X $^{(1)}$, X $^{(2)}$, . . . be an iid sequence of stochastic processes in C ( S ). We call X ( n ) a simple record, if X ( n ) ̸≤ max$_{i}$$_{=1}$$_{,...,n}$$_{−}$$_{1}$ X ( i $^{)}$, and a complete record, if X ( n ) > max$_{i}$$_{=1}$$_{,...,n}$$_{−}$$_{1}$ X ( i $^{)}$.\nWe further define\nBy definition, the first observation X (1) is always a record, so we demand ¯ π$_{1}$ ( X ) = ¯ π$_{1}$ ( X ) = 1. In the univariate case, where X, X $^{(1)}$, X$^{(2)}$, . . . are simply random variables on the real line, records are much easier to handle, and clearly ¯ π$_{n}$ ( X ) = ¯ π$_{n}$ ( X ) = 1 $_{n}$. There are many detailed works on univariate record and record times, see Galambos (1987, Sections 6.2 and 6.3) and Arnold et al. (1998).\nMultivariate records have not been discussed that extensively, yet they haven been approached by e. g. Goldie and Resnick (1989), Goldie and Resnick (1995) or Arnold et al. (1998, Chapter 8).\nA concept that is closely related to the field of complete records is the so- called concurrency of extremes, which is due to Dombry et al. (2015). We say that X $^{(1)}$, . . . , X ( n ) are sample concurrent, if\nIn that case, we call X ( k ) the champion among X $^{(1)}$, . . . , X ( n $^{)}$. We denote the sample concurrence probability by p$_{n}$ ( X ) and obtain due to the iid property\np$_{n}$ ( X ) = P ( n ⋃ i =1 { X ( i ) > max 1 ≤ j ̸ = i ≤ $_{n}$X ( j ) } ) (4) = n ∑ i =1 P ( X ( i ) > max 1 ≤ j ̸ = i ≤ $_{n}$X ( j ) ) = nP ( X ( n ) > max j =1 ,...,n − $_{1}$X ( j ) ) = n ¯ π$_{n}$ ( X ) .\nmax i =1 $_{,...,n}$X ( i ) = X ( k ) for some k ∈ { 1 , . . . , n } .\n¯ π$_{n}$ ( X ) := P ( X ( n ) is a simple record ) , π$_{n}$ ( X ) := P X ( n ) is a complete record ) ."}]}
+{"image": "doclay/doclay_35468.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "the site chosen for adding energy in the beginning will be set as the origin without loss of generality. We are now interested in whether the avalanche dynamics can con- tinue forever or will be terminated in finite time. Unlike the previous study, the (macroscopic) density of active sites is always zero. In this regard, we will call this kind of a phase transition a microscopic absorbing phase tran- sition (miAPT), first coined in Ref. [19]. For comparison, a phase transition in the previous sections, which occurs with nonzero activity density in the infinite-size limit, will be called a macroscopic APT (maAPT).\nThe infinite-time limit of the survival probability P$_{s}$ ( t ) plays the role of the order parameter. P$_{s}$ ( t ) is defined as the probability that the system has an active site at time t . We also study the mean number of active sites N ( t ) at time t that is averaged over all ensembles and the mean spreading R $^{2}$( t ) of the surviving ensemble. In simulations, we measure the mean spreading as\nWhen h$_{o}$ = h$_{e}$ = 2, we claimed that the system is in the active phase for any ζ > 2. Now we discuss the behavior of the activity density in this case. When ζ is close to 2, the initial activity density is very small [ap- proximately ( ζ − 2) $^{2}$/ 2] and the typical distance between two active sites in the initial configuration is ∼ 1 / ( ζ − 2). So the activity density is likely to decrease very quickly in the early stage. But eventually the initial compact clus- ter of active sites, discussed at the end of the previous subsection, will play a dominant role and the activity should spread throughout the system. To confirm this anticipation, we simulated the system with L = 20 000 for h$_{o}$ = h$_{e}$ = 2. The result of eight independent runs is shown in Fig. 5. As anticipated, the density decays very quickly up to ρ$_{a}$ ≈ 10 − $^{8}$. Actually, six out of eight runs lost all active sites around t = 100. However, the activity density in the two remaining runs eventually in- creased and saturated to a finite value, as anticipated. As this example shows, it is very hard to confirm numer- ically that the system is in an active phase for very small ζ$_{0}$ .\n〈 〉 where x$_{min}$ ( x$_{max}$ ) is the minimum (maximum) among the first components of active-site vectors at time t and 〈· · · 〉 s stands for the average over the surviving ensemble. If the system is critical at the transition point, these quantities have asymptotic power-law behaviors as\nwhere θ , η , and z are the spreading exponents.\nFor a concrete discussion, we now specify how the initial absorbing state is constructed. For each site x ∈ Z $^{2}$, z$_{x}$ is assigned 0, 1, 2, or 3 with probability (1 − p$_{3}$ ) p$_{0}$ , (1 − p$_{3}$ ) p$_{1}$ , (1 − p$_{3}$ ) p$_{2}$ , and p$_{3}$ , respectively, where 0 ≤ p$_{i}$ ≤ 1 and p$_{0}$ + p$_{1}$ + p$_{2}$ = 1. The corresponding energy density of the system is ζ = (1 − p$_{3}$ )( p$_{1}$ +2 p$_{2}$ )+3 p$_{3}$ , which is in the range 0 ≤ ζ ≤ 3. After constructing the initial absorbing state, the energy at the origin 0 in- creases by one ( z 0 ↦→ z 0 +1). If the origin becomes active\nIn this section, we study a phase transition of ‘avalanche’ dynamics initiated by adding a unit energy to a randomly chosen site in an absorbing state of an in- finite system. Since the system is infinite, the location of\nR $^{2}$( t ) = 〈 ( x$_{max}$ − x$_{min}$ ) 2 〉 s , (43) x$_{max}$ ) is the minimum (maximum) among the\nP$_{s}$ ( t ) ∼ t − $^{θ}$, N ( t ) ∼ t $^{η}$, R $^{2}$( t ) ∼ t $^{z}$, (44)\nh$_{e}$ = 2. To ensure that we indeed observed the infinite- size limit, we also simulated the system with smaller size ( L = 20 000, actually), to find almost identical behavior up to the observation time (data not shown). We also checked whether the asymptotic behavior can depend on the update rule. We found that the statistically signifi- cant difference is observed only for short time ( t ≤ 10) and the long time behavior is almost identical. So we only show the behavior of the system evolving according to the PU.\nFigure 4 shows the behavior of the effective exponents with b = 10 for (a) h$_{o}$ = 0, h$_{e}$ = 1, (b) h$_{o}$ = h$_{e}$ = 1, and (c) h$_{o}$ = 0, h$_{e}$ = 2. The activity density for each parameter set is the result of the average over 100 inde- pendent runs. Although Fig. 4 uses χ = 0 . 3, varying χ from 0.2 to 0.4 also makes the middle curve resemble a straight line. Estimating the error of the exponents by the range of extrapolated values for different χ , we con- cluded that the critical behavior is indeed universal with δ = 0 . 38 ± 0 . 01. The estimated critical energy density for each case is listed on the last line of Table I, which strongly supports that φ$_{1}$ and φ$_{3}$ give the same critical point. Hence, the answers to the three questions raised in the beginning of this section are all positive. Notice that in Ref. [4] δ was estimated as 0.41 for the case of h$_{o}$ = h$_{e}$ = 0. Since the critical point was set to be 2 . 125 in Ref. [4], which actually corresponds to the absorbing phase [13], slightly larger value than ours is consistent with our estimate. PSfrag replacements\nFIG. 5. Plot of ρ a vs t for h o = h e = 2 and ζ = 2 . 07.\n9\n10 -8 10 -6 10 -4 10 -2 10 0 10 1 10 2 10 3 10 4 10 5 t ρ a\nC. Microscopic absorbing phase transitions"}]}
+{"image": "doclay/doclay_31819.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "D. String theory landscape and a graceful exit\na phase reminiscence to the Hagedorn phase [933]. Note, a very similar picture would unfold in any neighboring throats, (MS)SM throat is not a unique one.\nThe vacuum energy in a string theory landscape can be written as:\nwhere c$_{i}$ < ∼ 1 are constants and n$_{i}$ are flux quantum numbers (note that Λ has dimension mass 2 in our notation as it enters the Einstein equation as Λ g$_{µν}$ ).\nAll in all, string theory (from the landscape point of view) could have from 10 500 to even 10 1000 vacua [45, 56–58], with the vast majority of those having large cosmological constants. In addition, our knowledge of the distribution of gauge groups over the landscape suggests that one out of 10 10 vacua have the SM spectrum, at least in simple models [59–61]. Even if this fraction is much smaller on the whole landscape, there are so many vacua that it seems likely very many will have a SM-like spectrum. From statistical arguments, most vacua should have badly broken SUSY, with large F -terms in the SUSY breaking sector.\nIn addition, there exist vacua with large cosmological constant that are “almost SUSY” in the sense of [57, 934]. These vacua have vanishing (or nearly vanishing) F -terms, and their cosmological constant and SUSY breaking are provided by a D -term, such as that created by an anti-brane. Upon decay of the D -term, the remaining vacuum has small Λ and low energy SUSY. The original model of [55] is almost SUSY in this sense because anti-D3-branes provide both the cosmological constant and SUSY breaking. There are also examples of toy “friendly landscape” models [935], in which the dynamics of N scalars create a landscape of vacua. The landscape can also harbor negative Λ [936]. Also, [877] has discussed the importance of negative Λ vacua in possibly separating parts of the landscape from each other.\nIt is expected that small jumps in Λ with small bubble tension τ to be the most com- mon decays, which can in fact be quite rapid [284]. In Ref. [937] the authors have argued that resonance can also play an important role in tunneling across a landscape of many metastable vacua. Also, the fact that there are many possible decays, as emphasized by [938], the whole landscape, including the MSSM-like vacua, will be populated eventually\n235\nV = M 2 $_{P}$Λ = M 2 $_{P}$Λ$_{0}$ + $_{α}$− 2 ∑ i c$_{i}$n 2 i , (490)"}]}
+{"image": "doclay/doclay_54220.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "SHOW Statements\n| time_zone | SYSTEM | | timestamp | 1530906638.765316 | | tls_version | TLSv1,TLSv1.1,TLSv1.2 | | tmp_table_size | 16777216 | | tmpdir | /tmp | | transaction_alloc_block_size | 8192 | | transaction_allow_batching | OFF | | transaction_isolation | REPEATABLE-READ | | transaction_prealloc_size | 4096 | | transaction_read_only | OFF | | transaction_write_set_extraction | XXHASH64 | | unique_checks | ON | | updatable_views_with_limit | YES | | version | 8.0.12 | | version_comment | MySQL Community Server - GPL | | version_compile_machine | x86_64 | | version_compile_os | Linux | | version_compile_zlib | 1.2.11 | | wait_timeout | 28800 | | warning_count | 0 | | windowing_use_high_precision | ON | +--------------------------------------------+------------------------------+\nWith a  LIKE  clause, the statement displays only rows for those variables with names that match the pattern. To obtain the row for a specific variable, use a  LIKE  clause as shown:\nTo get a list of variables whose name match a pattern, use the  %  wildcard character in a  LIKE  clause:\nWildcard characters can be used in any position within the pattern to be matched. Strictly speaking, because  _  is a wildcard that matches any single character, you should escape it as  \\_  to match it literally. In practice, this is rarely necessary.\nSHOW VARIABLES LIKE ’max_join_size’; SHOW SESSION VARIABLES LIKE ’max_join_size’;\nSHOW VARIABLES LIKE ’%size%’; SHOW GLOBAL VARIABLES LIKE ’%size%’;\nSHOW WARNINGS [LIMIT [ offset ,]  row_count ] SHOW COUNT(*) WARNINGS\n13.7.7.42 SHOW WARNINGS Statement\nSHOW WARNINGS  is a diagnostic statement that displays information about the conditions (errors, warnings, and notes) resulting from executing a statement in the current session. Warnings are generated for DML statements such as  INSERT ,  UPDATE , and  LOAD DATA  as well as DDL statements such as CREATE TABLE  and  ALTER TABLE .\nThe  LIMIT  clause has the same syntax as for the  SELECT  statement. See Section 13.2.10, “SELECT Statement” .\nSHOW WARNINGS  is also used following  EXPLAIN , to display the extended information generated by EXPLAIN . See Section 8.8.3, “Extended EXPLAIN Output Format” .\nSHOW WARNINGS  displays information about the conditions resulting from execution of the most recent nondiagnostic statement in the current session. If the most recent statement resulted in an error during parsing,  SHOW WARNINGS  shows the resulting conditions, regardless of statement type (diagnostic or nondiagnostic).\nThe  SHOW COUNT(*) WARNINGS  diagnostic statement displays the total number of errors, warnings, and notes. You can also retrieve this number from the  warning_count  system variable:\n2966"}]}
+{"image": "doclay/doclay_3520.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "OPERATION  ( cont. )\nModel AY11240\nModel AY11238\nUSING THE 5-HOLE DIAPHRAGM\nCOARSE KNOB ADJUSTMENT - Model AY11240\nMICROSCOPE USAGE\nCONSTRUCTION\n6\n5\n7. To clearly see the outline of the specimen, rotate the coarse adjustment knob and lower  the barrel to the space limiter. 8. Rotate the fine adjustment knob\nthe barrel to the space limiter. 8. Rotate the fine adjustment knob until the image is in sharp focus. When using other objectives, rotate the fine focus adjustment until the image is in focus.\n6. To clearly see the outline of the specimen, rotate the coarse adjustment knob and lower  the barrel to the space limiter. 7. Rotate the fine adjustment knob\nthe barrel to the space limiter. 7. Rotate the fine adjustment knob until the image is in sharp focus. When using other objectives, rotate the fine focus adjustment until the image is in focus.\n1. To obtain the best contrast for observing, match the hole size to the objective that is being used to view the specimen.  2. Each hole has a corresponding number from 1 to 5. 1 is the\nthe objective that is being used to view the specimen.  2. Each hole has a corresponding number from 1 to 5. 1 is the smallest hole; 5 is the largest hole. Use the following guidelines to match the hole number to the\nsmallest hole; 5 is the largest hole. Use the following guidelines to match the hole number to the objective that you have selected:  40x objective: Use #5 hole 10x objective: Use #4 or #3 hole 4x objective: Use #2 or #1 hole\n1. The coarse adjustment knob has an adjustable heavy-light nut (See Fig.1). 2. To adjust the knob loosen or tighten the nut.\n(See Fig.1). 2. To adjust the knob loosen or tighten the nut. NOTE: Adjusting the nut too tight will make focusing difficult.\nTo adjust the knob loosen or tighten the nut. NOTE: Adjusting the nut too tight will make focusing difficult. Adjusting the nut too loose will cause the tube to slide.\nBARSKA Model AY11228 and Model AY11232 are designed for  biological studies such as specimen examination. They can also be used for examining bacteria and for general clinical and medical  studies. Simple design and use is especially useful for school  classroom instruction.\nBARSKA Model AY11228 is a fixed power stereo microscope. It is  constructed with two optical paths at the same angle. It is  equipped with transmitted illumination and oblique illumination. By using this instrument, the user can observe and enlarge the  right side stereo image. BARSKA Model AY11232 is a zoom stereo  microscope. The object being viewed is enlarged through two  identical sized sets of right and left eye lenses. The zoom provides  different magnification and features an inversion system which  allows the image to be viewed normally and right side up.\nFig. 1- Coarse Adjustment Knob\nHeavy-Light Adjustment Nut\nModel AY11228 Model AY11232 Diopter Adjustment Diopter Adjustment Prism Cap Prism Cap Eyepiece Stage Lens Stage Vertical  Pole Illumination Controls Rotary Case Illumination Controls Spring  Clips Spring  Clips Focus Knob Focus Knob Magnification Adjustment Knob Focus Knob Tightening Knob Oblique Illuminator Oblique Illuminator Lens  Housing Eyepiece\nMODEL AY11228/AY11232"}]}
+{"image": "doclay/doclay_42.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "consolidated statements of financial position\n(Dollars In Thousands, Except Per Share Amounts) October 30, 2004 October 25, 2003  Assets Current Assets Cash and cash equivalents $ 288,881  $ 97,976  Accounts receivable 272,738 291,481 Inventories 425,655 403,213 Deferred income taxes  29,254 14,732 Prepaid expenses and other current assets 12,875 16,572 Total Current Assets 1,029,403 823,974 Goodwill 417,728 414,258 Other Intangibles 95,214 95,728 Net Pension Assets 67,037 65,290 Investments in and Receivables from Affiliates 55,232 138,357 Other Assets 165,117 154,172 Property, Plant, and Equipment Land 25,872 26,157 Buildings 455,860 436,660 Equipment 948,244 902,652 Construction in progress 44,666 46,057 1,474,642 1,411,526 Less allowance for depreciation (770,405) (710,184) 704,237 701,342 Total Assets $2,533,968 $2,393,121 Liabilities and Shareholders’ Investment Current Liabilities Accounts payable $ 203,563 $ 195,826  Accrued expenses 31,435 33,996 Accrued marketing expenses 71,855 62,799 Employee compensation 94,548 84,658 Taxes, other than federal income taxes 13,569 21,647 Dividends payable 15,673 14,594 Federal income taxes 17,963 14,175 Current maturities of long-term debt 15,760 14,295 Total Current Liabilities  464,366 441,990 Long-term Debt – less current maturities 361,510 395,273 Accumulated Postretirement Benefit Obligation 257,392 255,914 Other Long-term Liabilities 47,128 36,247 Deferred Income Taxes  4,324 10,962 Shareholders’ Investment Preferred stock, par value $.01 a share – authorized 80,000,000 shares; issued – none Common stock, nonvoting, par value $.01 a share –  authorized 200,000,000 shares; issued – none Common stock, par value $.0586 a share – authorized 400,000,000 shares;  issued 137,875,211 shares October 30, 2004  issued 138,596,084 shares October 25, 2003 8,079 8,122 Additional paid-in capital 0 4,073 Accumulated other comprehensive loss (23,534) (25,144) Retained earnings 1,414,703 1,265,684 Total Shareholders’ Investment 1,399,248 1,252,735 Total Liabilities and Shareholders’ Investment $2,533,968 $2,393,121\nSee notes to consolidated financial statements.\n2004 Annual Report 31"}]}
+{"image": "doclay/doclay_80170.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "167 \n166 \n\"SEC. 406. Every mutual benefit association  licensed  to  do busmess as such shall issue membership  certificates to its.members specifying the benefits to  which such members are entitled. \n\"Such certificates, together with the articles of  incorporation of the association or its constitution and  bylaws, and all existing laws as may be pertinent  shall constitute the agreement, as of the date of its  issuance, between the association and the member.  The membership certificate shall be in a form  previously approved by the Commissioner. \n\"SEC. 407. A mutual benefit association may,  by reinsurance agreement, cede in whole or  in  part  anY individual risk or risks under certificates of  insurance issued by it, only to a life insurance company  authorized to transact business or to a professional  reinsurer authorized to accept life risks in the  Philippines;  Provided,  That a copy of the draft of  such reinsurance agreement shall be submitted to  the Commissioner for his approval. The association  may take credit for the reserves on such ceded risks  to the extent reinsured. \n\"SEC. 408. The constitution or bylaws of a  mutual benefit association must distinctly state the  purpose for which dues andior assessments are made  and collected and the portion thereof which may be  used for expenses. \n\"Death benefit and other relieffunds shall be  created and used exclusively for paying benefits due  the members under their respective membership  certificates. A general fund shall likewise be created  and used for expenses of administration of the  association. \n\"A mutual benefit association shalL only  maintain free and unassigned surplus of not more  than twenty percent (20%) of its total liabilities as  verified by the Commissioner. Any amount in excess  shall be returned to the members by way of dividends, \nenhancing the equity value or providing benefits in  kind and other relevant services. In addition, subject  to  the approval of the Commissioner, a mutual benefit  association may allocate a portion for capacity  building and research and development such as  developing new products and services, upgrading and  improving operating systems and equipment and  continuing member education. \n\"SEC. 409. Every outstanding membership  certificate must have an equity value equival-ent to  at least fifty percent (50%) of the total contributions  collected thereon. The equity value only applies to  basic life insurance product and excludes optional  products. \n\"SEC. 410. Every mutual benefit association  must accumulate and maintain, out of the periodic  dues collected from its members, sufficient reserves  for the payment of claims or obligations for which it  shall hold funds in securities satisfactory to the  Commissioner consisting of bonds of the Government  of the Philippines, or any of its political subdivisions  and instrumentalities, or  in  such other good securities  as may be approved by the Commissioner. \n\"The reserve liahility shall be established in  accordance with actuarial procedures and shall be  approved by the Commissioner. \n\"The articles of incorporation or the constitution  and bylaws of a mutual benefit association must  provide that if its reserve as to all or any class of  certificates becomes impaired, its board of directors  or trustees may require that there shall be paid by  the members to the association the amount of the  members’ equitable proportion of such deficiency as  ascertained by said board and that if the payment be  not made it shall stand as an indebtedness against  the membership certificates of the defaulting members  and draw interest not to exceed five percent (5%) per  annum compounded annually. "}]}
+{"image": "doclay/doclay_31317.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "By writing the delta function as\nthe color-singlet state of the canonical ensemble for the unimodular-like U ( N$_{c}$ ) (i.e. SU ( N$_{c}$ )) reads\nB. Orthogonal symmetry group O$_{(}$$_{S}$$_{)}$ ( N )\nThe unitary Hermitian system may be decomposed into symmetric Hermitian and anti- symmetric Hermitian real orthogonal components. The orthogonal symmetry group is sym- metric one and is invariant under the time-reversal transformation. The unitary Hermitian system can be fully or partially projected into (symmetric) orthogonal Hermitian system. The projection of the unitary Hermitian system into the real symmetric orthogonal system is very relevant to the quark-gluon plasma under extreme conditions such as the hot nuclear matter. The transformation matrix, namely, U of the orthogonal group is a symmetric one. It has N 2 elements and these elements are restricted to N + N ( N − 1) / 2 conditions. These constraints reduce the number of the adjoint variables to N$_{adj}$ = N ( N − 1) / 2 while the num- ber of the fundamental variables remain the same N$_{fun}$ = N in the orthogonal symmetry group. The invariance Haar measure for the orthogonal symmetry group reads\nThe normalisation constant N$_{U}$ is determined by\nWhen the saddle points accumulate around the origin, the invariance Haar measure becomes\n23\n∫ dµ$_{O}$$_{(}$$_{S}$$_{)}$ ( θ$_{1}$ · · · θ$_{N}$ ) e − 1 $_{2}$a ∑ N i $_{=1}$θ 2 i = N$_{O}$ ∫ ∞ −∞ N ∏ i =1 dθ$_{i}$ 2 π N ∏ i<j | θ$_{i}$ − θ$_{j}$ | e − 1 $_{2}$a ∑ N i $_{=1}$θ 2 i . (75)\nN$_{O}$ ∫ π − π N ∏ i =1 dθ$_{i}$ 2 π N ∏ i<j ∣ 2 sin ( θ$_{i}$ − θ$_{j}$ 2 ) ∣ ∣ = 1 . (74)\n∫ dµ$_{O}$$_{(}$$_{S}$$_{)}$ ( θ$_{1}$ · · · θ$_{N}$ ) = N$_{O}$ ∫ π − π N ∏ i =1 dθ$_{i}$ 2 π N ∏ i<j ∣ sin ( θ$_{i}$ − θ$_{j}$ 2 ) ∣ ∣ . (73)\n∫ dµ$_{SU}$ ( θ$_{1}$ · · · θ$_{N}$ ) e − 1 $_{2}$a ∑ N i $_{=1}$θ 2 i = √ 2 πa N ∫ dµ$_{U}$ ( θ$_{1}$ · · · θ$_{N}$ ) e − 1 $_{2}$a ∑ N i $_{=1}$θ 2 i . (72)\nδ ( N ∑ i θ$_{i}$ ) = ∫ ∞ −∞ dx exp ( i x N ∑ i θ$_{i}$ ) , (71)"}]}
+{"image": "doclay/doclay_58087.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "CHAPTER 2. APPLICATION LIFE CYCLE MANAGEMENT\n$ oc new-app my-stream:v1\nYou can create an application from a previously stored template or from a template file, by specifying the name of the template as an argument. For example, you can store a sample application template and use it to create an application.\nUpload an application template to your current project’s template library. The following example uploads an application template from a file called  examples/sample-app/application-template-stibuild.json :\n$ oc create -f examples/sample-app/application-template-stibuild.json\nThen create a new application by referencing the application template. In this example, the template name is  ruby-helloworld-sample :\n$ oc new-app ruby-helloworld-sample\nTo create a new application by referencing a template file in your local file system, without first storing it in OpenShift Container Platform, use the  -f|--file  argument. For example:\n$ oc new-app -f examples/sample-app/application-template-stibuild.json\nWhen creating an application based on a template, use the  -p|--param  argument to set parameter values that are defined by the template:\n$ oc new-app ruby-helloworld-sample \\ -p ADMIN_USERNAME=admin -p ADMIN_PASSWORD=mypassword\nYou can store your parameters in a file, then use that file with  --param-file  when instantiating a template. If you want to read the parameters from standard input, use  --param-file=- . The following is an example file called  helloworld.params :\nADMIN_USERNAME=admin ADMIN_PASSWORD=mypassword\nReference the parameters in the file when instantiating a template:\n$ oc new-app ruby-helloworld-sample --param-file=helloworld.params\nTable 2.2.  new-app  output objects\nThe  new-app  command generates OpenShift Container Platform objects that build, deploy, and run the application that is created. Normally, these objects are created in the current project and assigned names that are derived from the input source repositories or the input images. However, with  new-app you can modify this behavior.\n2.3.4. Modifying application creation\n2.3.3.1. Template parameters\n2.3.3. Creating an application from a template\n25"}]}
+{"image": "doclay/doclay_71110.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Table of Contents\nCOHERENT, INC. AND SUBSIDIARIES\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS (Continued)\n2. SIGNIFICANT ACCOUNTING POLICIES (Continued)\nThe following table presents information necessary to calculate basic and diluted earnings per share (in thousands, except per share data):\nThere were 98,103, 103,547 and 505 potentially dilutive securities excluded from the dilutive share calculation for fiscal 2019, 2018 and 2017, respectively, as their effect was anti-dilutive.\nWe recognize compensation expense for all share-based payment awards based on the fair value of such awards. We value restricted stock units using the intrinsic value method, which is based on the fair market value price on the grant date. We use a Monte Carlo simulation model to estimate the fair value of performance restricted stock units. We amortize the fair value of stock awards on a straight-line basis over the requisite service periods of the awards, which are generally the vesting periods. See Note 13, \"Employee Stock Award and Benefit Plans\" for a description of our stock-based employee compensation plans and the assumptions we use to calculate the fair value of stock-based employee compensation.\nAs part of the process of preparing our consolidated financial statements, we are required to estimate our income tax provision (benefit) in each of the jurisdictions in which we operate. This process involves us estimating our current income tax provision (benefit) together with assessing temporary differences resulting from differing treatment of items for tax and accounting purposes. These differences result in deferred tax assets and liabilities, which are included within our consolidated balance sheets.\nWe account for uncertain tax issues pursuant to ASC 740-10  Income Taxes , which creates a single model to address accounting for uncertainty in tax positions by prescribing a minimum recognition threshold that a tax position is required to meet before being recognized in the financial statements. This standard provides a two-step approach for evaluating tax positions. The first step, recognition, occurs when a company concludes (based solely on the technical aspects of the matter) that a tax position is more likely than not to be sustained upon examination by a taxing authority. The second step, measurement, is only considered after step one has been satisfied and measures any tax benefit at the largest amount that is deemed more likely than not to be realized upon ultimate settlement of the uncertainty. These determinations involve significant judgment by management. Tax positions that fail to qualify for initial recognition are recognized in the first subsequent interim period that they meet the more likely than not standard or when they are resolved through negotiation or litigation with factual interpretation, judgment and certainty. Tax laws and regulations themselves are complex and are subject to change as a result of changes in fiscal policy, changes in legislation, evolution of regulations and court filings. Therefore, the actual liability for U.S. or foreign taxes may be materially different from our estimates, which could result in the need to record additional tax liabilities or potentially to reverse previously recorded tax liabilities.\nWe record a valuation allowance to reduce our deferred tax assets to an amount that more likely than not will be realized. While we have considered future taxable income and ongoing prudent and feasible tax planning strategies in assessing the need for the valuation allowance, in the event we were to determine that we would be able to realize our deferred tax assets in the future in excess of our net recorded amount, an adjustment to the allowance for the deferred tax asset would increase income in the period such determination was made. Likewise, should we determine that we would not be able to realize all or part of our net deferred tax asset in the future, an adjustment to the allowance for the deferred tax asset would be charged to income in the period such determination was made.\n82\nStock-Based Compensation\nIncome Taxes\nFiscal 2019 2018 2017 Weighted average shares outstanding—basic  24,118 24,572 24,487 Dilutive effect of employee stock awards 161 279 290 Weighted average shares outstanding—diluted 24,279 24,851 24,777 Net income from continuing operations $ 53,825 $ 247,360 $ 208,644 Loss from discontinued operations, net of income taxes — (2) (1,522) Net income $ 53,825 $ 247,358 $ 207,122"}]}
+{"image": "doclay/doclay_74425.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "9\n0 10 15 5 20 25 30 35 40 Australian Stock Exchange Deutche Boerse Euronext Hellenic Exchanges Hong Kong Exchanges and Clearing London Stock Exchange OM SFE Corporation Singapore Exchange TSX Group New Zealand Exchange Chicago Mercantile Exchange\nThe global relevance of the Australian market was recognised by inclusion of the S&P ASX50 in the S&P Global 1200 during June 2003. Previously, just 26 Australian companies were represented as part of the S&P Asia Pacific 100 within the S&P Global 1200. The Australian market weighting within the S&P Global 1200 was increased to 1.98% at that time from just 1.44%. \nASX also reached its highest ever ranking within the MSCI global index, reaching eighth position in April 2003 with a weighting of 2.11%. At 30 June ASX was again ranked eighth with a weighting of 2.06%, reflecting the month-to-month fluctuations in global capital market activity and values. These new inclusions and increased weightings are important in directing the investment activity of global fund managers who use the indices as a benchmark for their investment performance. The increased weighting for Australian equities results in further allocation of capital to the Australian market, encouraging listed company expansion and growth  and more fully valuing the performance  of domestic companies.\nSustaining a global standing\nFTSE/MV Exchanges Index weightings (%)\nFebruary 1989\nMarch 1989\nApril 1989\nMay 1989\n30 June 1989\nASX (Perth) hosts the ‘running of the bulls’ 4km fun run to commemorate its centenary.\nThe busiest day of the trading year, with 5,571 trades recorded. At this stage, 1,463 companies have their securities trading electronically on SEATS, while the more actively traded stocks continue  to be floor traded.\nAll Ords 1,567.72\nMikhail S. Gorbachev named Soviet president. \nMore than one million in Beijing demonstrate for democracy; chaos spreads across nation.\nUS jury convicts Oliver North in Iran-Contra affair. \nTens of thousands of Chinese students take over Beijing’s Tiananmen Square in rally for democracy. \nShare Ownership Study discloses that approximately 1 million individuals, or  9% of the adult Australian population, own shares.\nCash interest rates reach 18%, with annualised inflation around 7%\nRuptured tanker Exxon Valdez sends 11 million gallons of crude oil into Alaska’s Prince William Sound.\nRain Man wins four Oscars.\nIran’s Ayatollah Khomeini declares author Salman Rushdie’s book The Satanic Verses offensive and sentences him to death. \nEmperor Hirohito  of Japan dead at 87. \nGeorge Herbert Walker  Bush inaugurated as  41st US president. \nFormation of ASX Surveillance Unit.\nJanuary 1989\nJune 1989\nThousands killed in Tiananmen Square as Chinese leaders take hard line toward demonstrators."}]}
+{"image": "doclay/doclay_8746.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "page 118 Bombardier Inc. Annual Report 2003-04\n21 NET CHANGES IN NON-CASH BALANCES RELATED TO OPERATIONS\nThe net changes in non-cash balances related to operations were as follows for the year ended January 31:\nThe Corporation is subject to currency and interest rate fluctuations. To manage the volatility relating to these exposures, the Corporation nets the exposures on a consolidated basis to take advantage of natural offsets. The Corporation is party to a number of derivative financial instruments, mainly forward foreign exchange contracts, interest-rate swap agreements and cross-currency interest-rate swap agreements to hedge a significant portion of the residual risk. These derivative financial instruments are used to manage currency and interest-rate risks on existing assets and liabilities, as well as on forecasted foreign currency cash flows.\nForward foreign exchange contracts are agreements whereby one counter-party contracts with another, to exchange a specified amount of one currency in exchange for a specified amount of a second currency, at future dates.\nThe Corporation uses forward foreign exchange contracts to manage currency exposure arising from forecasted foreign currency cash flows. For the North American operations, forward foreign exchange contracts allow the Corporation mainly to sell U.S. dollars and buy Canadian dollars at predetermined rates. For the European operations, forward foreign exchange contracts mainly allow the sale or purchase of U.S. dollars, sterling pounds, euros and other Western European currencies at predetermined rates.\nDerivative financial instruments\n22 FINANCIAL INSTRUMENTS\na) Forward foreign exchange contracts\n2004 2003 Bombardier Receivables $( 185) $( 5 7 3) Assets under operating leases (107) (7) Inventories (815) (829) Accounts payable and accrued liabilities (176) 1,435 Advances and progress billings in excess of related costs (206) 524 Accrued benefit liability – net (176) 41 Other (42) (38) (1,707) 553 BC Receivables (54) 146 Accounts payable and accrued liabilities (53) (63) Other 18 11 (89) 94 $(1,796) $ 647"}]}
+{"image": "doclay/doclay_80744.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Part I\nsignificantly. The increased regulation and supervision of JPMorgan Chase has affected the way that it conducts its business and structures its operations. Existing and new laws and regulations and expanded supervision could require JPMorgan Chase to make further changes to its business and operations. These changes could result in JPMorgan Chase incurring additional costs for complying with laws and regulations and could reduce its profitability. For example, existing and new laws and regulations have in the past and could in the future require JPMorgan Chase to:\nThe European Commission (“EC”) has begun its review of MiFID II, which will continue into 2020, with the EC expected to publish a legislative proposal for changes to MiFID II. MiFID II, which became effective in 2018, requires the trading of shares and certain OTC derivatives to take place on trading venues, and also significantly enhanced requirements for pre- and post-trade transparency, transaction reporting and investor protection, and introduced position limits and a reporting regime for commodities. The extent of the changes that will be proposed under the MiFID II review is not known.\nThe EU capital and liquidity legislation for banks and investment firms implemented many of the finalized Basel III capital and liquidity standards, including in relation to the leverage ratio, market risk capital, and a net stable funding ratio. These changes will begin to take effect from June 2021. The final EU legislation also includes a requirement for certain non-EU banks operating in the EU to establish an intermediate parent undertaking (“IPU”) located in the EU. The IPU rule will allow a second IPU to be established if a single IPU would conflict with “home country” bank separation rules or impede resolvability.\nThe EU has also proposed or implemented significant revisions to laws covering securities settlement, mutual funds and pensions, payments, anti-money laundering controls, data security and privacy, transparency and disclosure of securities financing transactions, benchmarks, and resolution of banks, investment firms and market infrastructures, such as central counterparties.\nThe following discussion sets forth the material risk factors that could affect JPMorgan Chase’s financial condition and operations. Readers should not consider any descriptions of these factors to be a complete set of all potential risks that could affect the Firm. Any of the risk factors discussed below could by itself, or combined with other factors, materially and adversely affect JPMorgan Chase’s business, results of operations, financial condition, capital position, liquidity, competitive position or reputation, including by materially increasing expenses or decreasing revenues, which could result in material losses or a decrease in earnings.\nThe content and application of laws and regulations affecting financial services firms sometimes vary according to factors such as the size of the firm, the jurisdiction in which it is organized or operates, and other criteria. For example:\nThese differences in the regulatory framework can result in a firm such as JPMorgan Chase losing market share to competitors that are less regulated or not subject to regulation, especially with respect to unregulated financial products.\nThere can also be significant differences in the ways that similar regulatory initiatives affecting the financial services industry are implemented in the U.S. and in other countries\nJPMorgan Chase has experienced an extended period of significant change in laws and regulations affecting the financial services industry, both within and outside the U.S. The supervision of financial services firms also expanded\nJPMorgan Chase is a financial services firm with operations worldwide. JPMorgan Chase must comply with the laws, rules and regulations that apply to its operations in all of the jurisdictions around the world in which it does business. Regulation of financial services is extensive.\n6\n• larger firms are often subject to more stringent supervision and regulation\n• financial technology companies and other non-traditional competitors may not be subject to banking regulation, or may be supervised by a national or state regulatory agency that does not have the same resources or regulatory priorities as the regulatory agencies which supervise more diversified financial services firms, or\n• the financial services regulatory framework in a particular jurisdiction may favor financial institutions that are based in that jurisdiction.\n• increase the prices that it charges for products and services, which could reduce the demand for them.\n• impose restrictions on certain business activities, or\n• dispose of certain assets, and do so at times or prices that are disadvantageous\n• pay higher taxes, assessments, levies or other governmental charges, including in connection with the resolution of tax examinations\n• recognize losses in the value of assets that it holds\n• stop or discourage it from engaging in business opportunities that it might otherwise pursue\n• reduce the liquidity that it can provide through its market-making activities\n• limit the products and services that it offers\nDifferences in financial services regulation can be disadvantageous for JPMorgan Chase’s business.\nItem 1A. Risk Factors.\nRegulatory\nJPMorgan Chase’s businesses are highly regulated, and the laws and regulations that apply to JPMorgan Chase have a significant impact on its business and operations."}]}
+{"image": "doclay/doclay_31723.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "molecules to the ultracold configuration and back using a single, phase-locked pulse train. Note, that qualitatively same result was obtained for the pule train repetition rate 500 MTz, ( T = 2 ns ), with the only difference in the dynamics duration, which was extended by an order of magnitude to 440 ns.\nOff-resonant Raman transitions are readily induced by a single, standard optical fre- quency comb, provided there are optical frequencies in the comb that satisfy the two-photon resonance condition and differ by exactly the Feshbach-to-ultracold state transitional fre- quency. In Fig.7 the case for the carrier frequency detuned off resonance with the ω 32 transitional frequency is presented for detuning δ = 3 / 2 ω 31 and two values of the Rabi frequency, the Ω$_{R}$ = 0 . 1 ω 31 = 12 . 55 THz and Ω$_{R}$ = 0 . 01 ω 31 = 1 . 26 THz related to the field intensity on the order of 10 14 and 10 12 W/cm 2 respectively. The chosen value of de- tuning δ is about ∼ 10 $^{14}$Hz . Bold black, bold red, and bold green lines show population dynamics in the Feshbach state, the excited electronic state and the final, ultracold state respectively, for the Rabi frequency Ω$_{R}$ = 1 . 26 THz , thin lines - same for the Rabi frequency Ω$_{R}$ = 12 . 55 THz . Since here we demonstrate the effects of the detuning, and the impact of different field intensity on the population dynamics to the deeply bound rovibrational state in the KRb molecule, the pulse train period is chosen to be short to accommodate the com- putational limitations, T = 6400 τ = 0 . 02 ns. (Same as for the resonance case, pulse train period in 2 ns elongates the duration of population accumulation.) Figure Fig.7 shows that almost complete population transfer, ( ∼ 98%), takes place when the carrier frequency is off-resonance with the one-photon transitions in the molecular system. It also demonstrates the field intensity dependence of the duration needed to accumulate population in the ul- tracold state. For the Ω$_{R}$=12.55 THz, ( 10 14 W/cm $^{2}$), the population transfer dynamics is accomplished five times faster than for the Ω$_{R}$=1.26 THz, ( 10 12 W/cm $^{2}$).\nIn conclusion, we have demonstrated a possibility of molecular rovibrational cooling from the Freshbach states using a single femtosecond, optical frequency comb. We focused on the KRb molecule and modeled it by a three-level λ -system with the energy levels taken from [8] and [9]. Coherent accumulation of the population in the cold state is achieved by applying a standard optical frequency comb with zero offset frequency, and by an optical frequency comb generated by a pulse train with a phase modulation in the form of the sinusoidal function across an individual pulse. An optimal dynamics takes place when the carrier- envelope phase is equal to zero, ( f 0 = 0). The mechanism of the accumulative effect leading\n11"}]}
+{"image": "doclay/doclay_80072.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "1^=10 / A$_{100}$ avec :\n- A ιοο Øtant l’allongement,exprimØ en %, du câblesous un effort de 100 MPa, et M 2 =[(F$_{4}$$_{O}$-F$_{3}$$_{O}$) / (A$_{40}$-A$_{30}$)] / S avec :\n- S Øtant la section, exprimØe en mm$^{2}$, telle que S=MI /Mv avec :\n■ Ml Øtant la masse linØique des ØlØments filaires mØtalliques, exprimØe en g par m de câble,\n■ Mv Øtant la masse volumique des ØlØments filaires mØtalliques, exprimØe en g par cm$^{3}$,\n- F$_{40}$ Øtant la force, exprimØe en daN, Øgale à40 % de la force thØorique maximale F$_{t}$ du câble,\n- F$_{30}$ Øtant la force, exprimØe en daN, Øgale à30 % de la force thØorique maximale F$_{t}$ du câble,\n- A$_{40}$ Øtant l’allongementdu câble,exprimØ en %, à40% de la force thØorique maximale F$_{t}$ du câble,\n- A$_{30}$ Øtant l’allongementdu câble,exprimØ en %, à30% de la force thØorique maximale F$_{t}$ du câble,\navec F$_{t}$= Ml x Rm /Mv, exprimØe en daN, avec Rm Øtant la rØsistance mØcanique à rupture moyenne, exprimØe en MPa, des ØlØmentsfilaires mØtalliques constituant la couche unique.\n[010] D’unepart, le câbleselon l’invention,comme le dØmontre les essais comparatifs dØcrits ci-dessous, permet de rØduire le bruit Ømis par le pneumatique en raison d’une valeur de Mi allant de 5 GPa à16 GPa. Mi est reprØsentatif du module du câblepour des efforts subis par le câble lors d’unroulage dans des conditions normales et donc reprØsentatives des conditions dans lesquelles est Ømis le bruit dit « coast-by ». En dessous de 5 GPa, dans le cas d’un effort subi relativement faible, le câblese dØformerait de façontrop importante et atteindrait alors la plage d’allongementscorrespondant au module M$_{2}$ bien plus ØlevØ,module qui serait alors nØfaste notamment au bruit Ømis par le pneumatique mais Øgalement àson confort. Au-dessus de 16 GPa, le câbleprØsenterait un module trop ØlevØet donc serait relativement rigide, augmentant alors le bruit gØnØrØ par le roulage du pneumatique.\n[ 011 ] D’autrepart, le câbleselon l’invention,comme le dØmontre les essais comparatifs dØcrits ci-dessous, prØsente Øgalement une excellente capacitØ de frettage en raison d’une valeur de M$_{2}$ allant de 40 GPa à160 GPa. M$_{2}$ est reprØsentatif du module du câble pour des efforts subis par le câble lorsqu’onexerce de fortes sollicitations sur le pneumatique. En dessous de 40 GPa, le câblene pourra pas assurer une capacitØ de frettage suffisante pour contrebalancer les effets de la force centrifuge liØs àla vitesse de"}]}
+{"image": "doclay/doclay_29484.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "x / λ y / λ -20 -10 0 10 20 -20 -10 0 10 20 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 (c ) x / λ y / λ -20 -10 0 10 20 -20 -10 0 10 20 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 (f) x / λ y / λ -20 -10 0 10 20 -20 -10 0 10 20 (a) x / λ y / λ -20 -10 0 10 20 -20 -10 0 10 20 (b) x / λ y / λ -20 -10 0 10 20 -20 -10 0 10 20 (e) x / λ y / λ -20 -10 0 10 20 -20 -10 0 10 20 (d)\nFIG. 2: (color online) The momentum currents for the model [W] under the condition θ = π/ 360. First row: Left circularly polarized wavepacket σ = +1. Second row: Right circularly polarized wavepacket σ = − 1. The background distribution is depicted as the longitudinal currents and the green arrows is described as the transverse currents. [(a), (d)] Orbital momentum currents p [W] O . [(b), (e)] Spin momentum currents p [W] S . [(c), (f)] Total momentum currents p [W] O + p [W] S . The cross section is chosen as z = z$_{R}$ and the intensity is plotted in normalized units.\nin this polarization model [Figs. 3(b) and 3(e)]. However, the transverse spin currents are polarization-dependent and the longitudinal spin currents are absent [Figs. 3(b) and 3(e)]. For the left circular polarization σ = +1, the total transverse momentum currents present an anticlockwise circulation [Fig. 3(c)]. For the right circular polarization σ = − 1, the total transverse momentum currents present a clockwise circulation [Fig. 3(f)]. The transverse intensity distribution of this model is axially symmetric and the polarization- dependent rotation, if it exists, cannot be observed directly. This is a possible reason why the polarization-dependent split is observed only on the plane which is not perpendicular to the propagation direction of the beam [10].\n8"}]}
+{"image": "doclay/doclay_16360.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Item 1B.  Unresolved Staff Comments.\nItem 2.  Properties.\nItem 3. Legal Proceedings.\nWe are routinely involved in a number of legal actions and proceedings.  The outcome of legal proceedings is often  uncertain. Legal proceedings could result in adverse judgments, settlements, fines, injunctions, restitutions or other relief that  could require significant expenditures or have other ef fects on our business. In accordance with applicable accounting standards  and guidance, we establish accruals for a legal proceeding only when we determine both that it is probable that a loss has been  incurred and the amount of the loss is reasonably estimable.  We accrue the amount that represents our best estimate of the  probable loss; however, if we can only determine a range of estimated losses, we accrue an amount within the range that, in our  judgment, reflects the most likely outcome, and if none of the estimates within the range is more likely , we accrue the minimum  amount of the range. \nIn the course of our regular review of pending legal matters, we determine whether it is reasonably possible that a  potential loss relating to a legal proceeding may have a material impact on our liquidity , results of operations or financial  condition. If we determine such a loss is reasonably possible, we disclose information relating to any such potential loss,  including an estimate or range of loss or a statement that such an estimate cannot be made. On a quarterly and annual basis, we  review relevant information with respect to legal loss contingencies and update our accruals, disclosures and estimates of  reasonably possible losses or range of losses based on such reviews.  We are often unable to estimate the possible loss or range  of loss until developments in such matters have provided suf ficient information to support an assessment of the range of  possible loss, such as quantification of a damage demand from plaintif fs, discovery from other parties and investigation of  factual allegations, rulings by the court on motions or appeals, analysis by experts, and the progress of settlement negotiations.  In addition, we generally make no disclosures for loss contingencies that are determined to be remote. For matters for which we  disclose an estimated loss, the disclosed estimate reflects the reasonably possible loss or range of loss in excess of the amount  accrued, if any.\nAny loss estimates are inherently subjective, based on currently available information, and are subject to management’ s  judgment and various assumptions. Due to the inherently subjective nature of these estimates and the uncertainty and  unpredictability surrounding the outcome of legal proceedings, actual results may dif fer materially from any amounts that have  been accrued.\nWe currently have a co-location agreement with DBSI Inc. that supports data center space and services.  This agreement  expires May 30, 2015. DBSI serves as a production and disaster recovery location.\nWe believe our existing properties are well utilized, suitable and adequate for our present circumstances.\nAt our corporate headquarters in Philadelphia, Pennsylvania, we lease approximately 151,197 square feet of of fice  space and 1,740 square feet of data storage space under a lease that expires in  August 2017. In addition, we also lease the  following:\nNone.\n•  7,314 square feet of of fice space in Ohio and South Carolina, serving as our mortgage insurance service center  (Ohio) and space for a subsidiary of fice (South Carolina). The lease for our Ohio service center expires in 2015  and the space for our South Carolina of fice is month to month;\n•  121,093 square feet of of fice space for our financial guaranty operations in New  York City. The lease for this  space expires in 2015. We occupy 26,538 square feet of this space and sublease 94,555 square feet;\n•  Approximately 500 square feet of of fice space for our mortgage insurance operations in Hong Kong.  The lease for  this space expires on January 31, 2014; and\n•  27,360 square feet of of fice space for our data center in Dayton, Ohio.  The lease for this space expires on March  31, 2016.\n84"}]}
+{"image": "doclay/doclay_20592.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "H&R REIT AND H&R FINANCE TRUST - MD&A - December 31, 2010 \nU.S. Holdco intends to treat the U.S. Holdco Notes as indebtedness for U.S. federal income tax purposes. If the Internal Revenue  Service (“IRS”) or a court were to determine that the U.S. Holdco Notes should be treated for U.S. federal income tax purposes as  equity rather than debt, the interest on the notes could be treated as a dividend, and interest on the notes would not be deductible for  U.S. federal income tax purposes. In addition, if the IRS were to determine that the interest rate on the U.S. Holdco Notes did not  represent an arm’s length rate, any excess amount over arm’s length would not be deductible and could be recharacterized as a  dividend payment instead of an interest payment. This would significantly increase the U.S. federal income tax liability of U.S.  Holdco, potentially including the tax liability for prior years in which U.S. Holdco has claimed a deduction for interest paid on the U.S.  Holdco Notes. In addition, U.S. Holdco could be subject to penalties. The increase in tax liability could materially adversely affect  U.S. Holdco’s ability to make interest payments on the U.S. Holdco Notes or the REIT’s ability to make distribution on its units. Additionally, payments of interest on the U.S. Holdco Notes to non-U.S. holders of Stapled Units could be subject to withholding  taxes.\nTo the extent that the REIT or a related party provided debt financing to U.S. Holdco (e.g., by acquiring U.S. Holdco Notes), in  determining income for U.S. tax purposes, U.S. Holdco is subject to possible limitations on the deductibility of interest, if any, paid to  the REIT. Section 163(j) of the Internal Revenue Code (the “Code”) applies to defer U.S. Holdings’ deduction of interest paid on debt  to the REIT in years that (i) the debt to equity ratio of U.S. Holdings exceeded 1.5:1, and (ii) the net interest expense exceeds an  amount equal to 50% of its “adjusted taxable income” (generally, earnings before interest, taxes, depreciation, and amortization). The REIT intends to take the position that, due to the treatment of the Finance Trust as a grantor trust that is disregarded for U.S.  federal tax purposes, the interest paid to Finance Trust is treated as having been paid to the holders of the Finance Trust units and is  therefore not subject to section 163(j). If section 163(j) applied to interest paid to the Finance Trust, depending on the facts and  circumstances and the availability of net operating losses to U.S. Holdco (which are subject to normal assessment by the IRS), the  U.S. federal income tax liability of U.S. Holdings could increase. In such case, the amount of income available for distribution by the  REIT to its unitholders could be reduced. \nA foreign corporation will be classified as a passive foreign investment company (\"PFIC\") for United States federal income tax  purposes if either (i) 75% or more of its gross income is passive income or (ii) on average for the taxable year, 50% or more of its  assets (by value) produce or are held for the production of passive income. The properties of the REIT are managed by a third party  rather than directly by its own employees. Although the REIT's officers and employees oversee the activities of the manager, it is  likely that the REIT will be characterized as a PFIC for U.S. federal income tax purposes, though this conclusion is uncertain. In the  absence of certain elections being made by a U.S. holder of REIT Units, any distributions in respect of the REIT Units which exceed  125% of the average amount of distributions in respect of such REIT Units during the preceding three years, or, if shorter, during the  preceding years in the U.S. holder's holding period (\"excess distributions\") and any gain on a sale or other disposition of the REIT  units will be treated as ordinary income and will be subject to special tax rules, including an interest charge. U.S. holders should  consult with their own tax advisors regarding the implications of these rules and the advisability of making one of the applicable PFIC  elections, taking into account their particular circumstances. \nIn compliance with U.S. Treasury Department Circular 230, which provides rules governing certain conduct of U.S. tax advisors  giving advice with respect to U.S. tax matters, please be aware that: (i) any U.S. federal tax advice contained herein is not intended  to be used and cannot be used by the reader for the purpose of avoiding penalties that may be imposed under the Code; (ii) such  advice was prepared in the expectation that it may be used in connection with the promotion or marketing (within the meaning of  U.S. Treasury Department Circular 230) of Stapled Units; and (iii) prospective investors should seek advice based on their particular  circumstances from an independent tax advisor. \nAs the Trusts distribute a substantial portion of its income to unitholders, the Trusts may need to obtain additional capital through  capital markets and the Trusts’ ability to access the capital markets through equity issues and forms of secured or unsecured debt  financing may affect the operations of the Trusts as such financing may be available only on disadvantageous terms, if at all. If  financing is not available on acceptable terms, further acquisitions or ongoing development projects may be curtailed and cash  available for distributions or to fund future commitments may be adversely affected. \nThe number of Stapled Units the Trusts are authorized to issue is unlimited. The trustees have the discretion to issue additional  Stapled Units in certain circumstances, including under the REIT’s Unit Option Plan. Any issuance of Stapled Units may have a  dilutive effect on the investors of Stapled Units. \nAbility to Access Capital Markets \nDilution \nPage 41 of 45 "}]}
+{"image": "doclay/doclay_17411.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "MANAGEMENT’S DISCUSSION & ANALYSIS\nRESULTS OF OPERATIONS – YEARS ENDED DECEMBER 31, 2012, 2011, AND 2010\nCONSOLIDATED INCOME STATEMENT\nDuring the year ended December 31, 2012, the Company’s revenue decreased by 11% or $621,000 to $5,165,000 from $5,786,000 and cost of goods sold increased by 7% or $178,000 to $2,716,000 from $2,538,000 in comparison with the same period of 2011.\nThese changes resulted in a decrease in gross margin by 25% or $799,000 to $2,449,000 from $3,248,000. Income from operations has decreased by $1,091,000 to loss of $506,000 from income of $585,000.\nThere was a net loss in the year ended December 31, 2012 of $538,000 in comparison with net income in the same period of 2011 of $578,000.\nDuring the fourth quarter of 2012, the Company’s revenue decreased by 23% or $350,000 to $1,202,000 from $1,552,000 and cost of goods sold increased by 21% or $135,000 to $769,000 from $634,000 in comparison with the same period of 2011. These changes resulted in a decrease in gross margin by 53% or $485,000 to $433,000 from $918,000.\nIncome from operations has decreased by $476,000 to loss of $249,000 from income of $227,000 during the fourth quarter of 2012 in comparison with the same period of 2011.\nThere was a net loss in the fourth quarter of 2012, $237,000 in comparison with net income of $252,000 in the same period of 2011 mostly due to a decrease in gross margin.\nCEAPRO Annual Report 2012 13\n$000S EXCEPT PER SHARE DATA 2012 % 2011 % 2010 % Total revenues 5,165 100% 5,786 100% 5,577 100% Cost of goods sold 2,716 53% 2,538 44% 3,061 55% Gross margin 2,449 47% 3,248 56% 2,516 45% Research and product development 856 17% 997 17% 774 14% General and administration 1,795 35% 1,374 24% 1,279 23% Sales and marketing 199 4% 111 2% 69 1% Finance costs 113 2% 181 3% 203 4% (Loss) income from operations (514) GLYPH<H11537> 10% 585 10% 191 3% Other operating loss (24) 0% (7) 0% (30) GLYPH<H11502> 1% Write-off of property and equipment – 0% – 0% (12) 0% SGGF legal fees recovery – 0% – 0% 315 6% Net (loss) income (538) GLYPH<H11537> 10% 578 10% 464 8% Basic net (loss) income per common share (0.009) 0.009 0.009 Diluted net (loss) income per common share (0.009) 0.009 0.009 Total assets 3,886 4,171 2,820 Long-term financial liabilities 1,089 1,206 1,384"}]}
+{"image": "doclay/doclay_26177.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "A Variational inference and parameter estimation\nA.1 The empirical Bayes ELBO\n19\nThe expected log-sum-exp in (22) has no closed form. For variational inference, we there-\nthe third term becomes\nThe first and second terms of (20) are straightforward to derive; the third term requires more attention. Using the multinomial logit mass function\nThe first term in (20) is the Shannon entropy of the variational distribution. The second and third terms are (minus) an unnormalized cross entropy – the missing normalization constant is the marginal likelihood. Recall that the variational distribution q .GLYPH<12>$_{1:}$$_{H}$ j GLYPH<22>$_{1:}$$_{H}$ ; 6$_{1:}$$_{H}$ / is a product of normal distributions N .GLYPH<22>$_{h}$ ; 6$_{h}$ / .\nFor empirical Bayes in the MML model, the ELBO objective function (11) becomes\nIn this appendix we describe the variational inference and estimation procedures for the mixed multinomial logit model. A few words on notation: A GLYPH<31> 0 means the matrix A is positive definite; A GLYPH<23> 0 means positive semidefinite; j A j is the determinant of A . For a scalar function s : R ! R and a vector v 2 R $^{n}$, s .v/ means the n GLYPH<2> 1 vector . s .v$_{1}$/; : : : ; s .v$_{n}$ // $^{>}$.\nH . q / C H ∑ h D 1$^{❊}$ q log p .GLYPH<12>$_{h}$ j GLYPH<16> ; GLYPH<127>/ C H ∑ h D 1 T$_{h}$ ∑ t D 1 ❊ q log p . y$_{ht}$ j x$_{ht}$ ; GLYPH<12>$_{h}$ / : (20)\np . y$_{ht}$ j x$_{ht}$ ; GLYPH<12>$_{h}$ / D J ∏ j D 1 [ exp . x > $_{ht j}$GLYPH<12>$_{h}$ / ∑ j 0 exp . x > ht j $_{0}$GLYPH<12>$_{h}$ /$^{]}$$^{y}$$^{j}$ ht ; (21)\nH ∑ h D 1 T$_{h}$ ∑ t D 1   J ∑ j D 1 y j $_{ht}$. x > $_{ht j}$GLYPH<22>$_{h}$ / GLYPH<0> ❊ q$_{GLYPH<21>}$ log$^{(}$ J ∑ j D 1 exp . x > $_{ht j}$GLYPH<12>$_{h}$ /$^{)}$$^{}$  : (22)"}]}
+{"image": "doclay/doclay_20555.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements  Years ended December 31, 2012 and 2011\n24. Segmented Information (continued) \nThe geographical distribution of our non-current assets are as follows:\nNon-current assets attributed to geographical locations exclude deferred tax assets and financial and other assets.\nTeck 2012 Annual Report 122\nDecember 31, December 31, (Cdn$ in millions) 2012 2011 Canada $ 20,639 $ 19,460 Chile  4,727 4,565 United States 788 883 Other 688 604 $ 26,842 $ 25,512\n(Cdn$ in millions)  December 31, 2011 Copper Coal Zinc Energy Corporate Total Segment revenues $ 3,108 $ 5,641 $ 3,015 $ – $ – $ 11,764 Less: Inter-segment revenues – – (250) – – (250) Revenues 3,108 5,641 2,765 – – 11,514 Gross profit  1,369 2,800 708 – – 4,877 Other operating income (expenses) (102) (10) (76) – (233) (421) Profit from operations 1,267 2,790 632 – (233) 4,456 Net finance expense (5) (31) (19) – (427) (482) Non-operating income (expenses) – – – – 197 197 Share of losses of associates  –  –  –  (2)  (3)  (5) Profit before tax 1,262 2,759 613 (2) (466) 4,166 Capital expenditures 538 524 106 49 19 1,236 Goodwill 444 1,203 – – – 1,647 Total assets 7,538 17,186 4,952 1,152 3,391 34,219"}]}
+{"image": "doclay/doclay_28268.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "10 6 0 Space Charge (C/m$^{3}$) b) c)c a) d) e) f)\nFIG. 3: (color online) a) and b) Shows the result of a FEM based self-consistent solution of Poisson’s equation giving the potential around a doubly clamped suspended nanowire device 100 nm in diameter and 1.5 µ m long. The separation of the NW and 300 nm thick SiO$_{2}$ is 100 nm. The back plane of the nanowire is the gate held at -5V and the two terminals of the wire are grounded. The maximum of the colorscale bar (red)is 0V and the minimum (blue) is -5 V. c) The space distribution in the cross section of the nanowire for V DC g = -25V shows the gradient. The log- colorscale below varies from 10 C/m 3 (blue) to 10 6 C/m 3 (red). d) Plot of space charge density in the vertical direction at V DC g = -25V through the middle of the wire. The asymmetry along the vertical direction due the gate below the wire is clearly seen. e) The space distribution in the cross section of the nanowire for V DC g = -5V shows the gradient. The log-colorscale below varies from 10 3 C/m 3 (blue) to 10 5 C/m 3 (red). f) The space distribution in the cross section of the nanowire for V$_{g}$ = 5V shows uniform space charge distribution as the electron density in the nanowire is increased when the nanowire field effect transistor is turned on. The log-colorscale below varies from 10 3 C/m 3 (blue) to 10 5 C/m 3 (red).\n14"}]}
+{"image": "doclay/doclay_26135.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "(b), though, a different solution is given here. Thus identification requires differentiability of either γ or φ ; when γ is not differentiable and the result in Cunha et al does not hold identification is still possible in case (b). This also extends the identification result of Evdokimov 2010.\nWe now consider whether when the distributions of the observables are close the unknown functions are also necessarily close.\nA sufficient condition is provided in Zinde-Walsh 2010 (Theorem 4). When identification is based on (b) of Theorem 1 here the model class needs to be restricted to include only measurement error distributions with φ − 1 in Φ( m, V ) for some m, V. Equivalently, when identification is based on (a), the sufficient condition is for the class of models to be restricted to those where the latent factor distribution is such that γ − 1 ∈ Φ( m, V ).\nThese conditions exclude models where both g and f are supersmooth with supp( γ ) unbounded leading to a supersmooth distribution for w$_{1}$. Al- though these conditions are only shown to be sufficient, an example below (from Zinde-Walsh 2009 and 2010) demonstrates that a Gaussian distribution (that violates these conditions) fails well-posedness in the weak topology of generalized functions in S ′ and therefore in any stronger topology or metric (uniform, L$_{1}$, etc. ) .\nExample 4. Consider the function φ ( x ) = e − x $^{2}$, x ∈ R. Consider in S\n10\n3 Well-posedness"}]}
+{"image": "doclay/doclay_30522.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "FIG. 7: Displayed is the autocorrelation of the order parameter (17) for true (+) and for hidden (-) magnetic order on a 4 × 4 × 2 lattice of spin-1/2 moments as a function of Hund’s rule coupling. It is normalized to its value in the true ferromagnetic state (see text).\ncoupling under the previous set of Heisenberg exchange coupling constants. Plotted on the vertical axis is the autocorrelation 〈 O ( k )$_{±}$ · O ( − k )$_{±}$ 〉$_{0}$ of the order parameter\nover the groundstate normalized to its value in the true ferromagnetic state, 〈 O (0)$_{+}$ · O (0)$_{+}$ 〉$_{0}$ = 16 · 17 ¯ h $^{2}$. The relation to the ordered magnetic moment per iron atom, µ ( ± , k ), given there is obtained from the identity | 16 µ ( ± , k ) | 2 = (2 µ$_{B}$/ ¯ h ) $^{2}$〈 O ( k )$_{±}$ · O ( − k )$_{±}$ 〉$_{0}$ that is valid over the 4 by 4 square lattice of spin-1 iron atoms. The top graph in Fig. 7 displays how the square of the ordered moment for true cSDW order (+) decays with decreasing Hund’s rule coupling. It notably accounts for the low ordered moment that is observed by elastic neutron diffraction in an undoped parent compound to the recently discovered ferro- pnictide high- T$_{c}$ superconductors. 2 Also shown there is how hidden ferromagnetic order is\n16\nO ( k )$_{±}$ = ∑ i e i k · $^{r$_{i}$}$[ S$_{i}$ ( a ) ± S$_{i}$ ( b )] (17)\n 0  0.2  0.4  0.6  0.8  1  0  1  2  3  4  5 µ (order) 2  / (17/16) (2  µ B ) 2 - J$_{0}$ / J$_{1}$ ⊥ (A) J$_{1}$ |$^{|}$ = 0, J$_{1}$ ⊥ > 0, J$_{2}$ |$^{|}$ = 0.3 J$_{1}$ ⊥ = J$_{2}$ ⊥ COMMENSURATE SDW ( π ,0)$_{+}$ NEEL ( π ,  π )$_{+}$ HIDDEN FERROMAGNETIC (0,0)$_{-}$  0  0.2  0.4  0.6  0.8  1  0  0.5  1  1.5  2  2.5  3  3.5 µ (order) 2  / (17/16) (2  µ B ) 2 - J$_{0}$ / J$_{1}$ || (B) J$_{1}$ |$^{|}$ > 0, J$_{1}$ ⊥  = 0, J$_{2}$ || = 0.25 J$_{1}$ | $^{|}$ = J$_{2}$ ⊥ COMMENSURATE SDW ( π ,0)$_{+}$ NEEL ( π ,  π )$_{+}$ HIDDEN NEEL ( π ,  π )$_{-}$"}]}
+{"image": "doclay/doclay_16155.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Passive Foreign Investment Company\nWe believe that we were not a “passive foreign investment company,” or PFIC, for U.S. federal income tax purposes for our  taxable year ending on December 31, 2011, and we do not expect to become one for our current taxable year or in the future, although  there can be no assurance in this regard. If we were treated as a PFIC for any taxable year during which you held our shares or ADSs,  you could be subject to additional U.S. federal income taxes on gain recognized with respect to the shares or ADSs and on certain  distributions, plus an interest charge on certain taxes treated as having been deferred under the PFIC rules. \nNon-corporate U.S. holders will not be eligible for reduced rates of taxation on any dividends received from us in taxable  years beginning before January 1, 2013, if we are a PFIC in the taxable year in which such dividends are paid or in the preceding  taxable year. \nIn general, information reporting will apply to dividends in respect of our shares or ADSs and the proceeds from the sale,  exchange or redemption of our shares or ADSs that are paid to you within the United States (and in certain cases, outside the United  States), unless you are an exempt recipient such as a corporation. A backup withholding tax may apply to such payments if you fail to  provide a taxpayer identification number or certification of other exempt status or fail to report in full dividend and interest income. \nAny amounts withheld under the backup withholding rules will be allowed as a refund or a credit against your U.S. federal  income tax liability provided the required information is furnished to the Internal Revenue Service. \nSection 6045B of the Code imposes certain reporting requirements on us with respect to any organizational action that  affects the basis of our shares or ADSs, such as the capital reduction plan described in Item 9 under “A. Offer and Listing Details”.  We intend to comply with the requirements by making available on our website IRS Form 8937, Report of Organizational Actions  Affecting Basis of Securities, with respect to such capital reduction plan and any other such organizational action. \nWe have filed this annual report on Form 20-F, including exhibits, with the SEC. As allowed by the SEC, in Item 19 of this  annual report, we incorporate by reference certain information we filed with the SEC. This means that we can disclose important  information to you by referring you to another document filed separately with the SEC. The information incorporated by reference is  considered to be part of this annual report. \nYou may read and copy this annual report, including the exhibits incorporated by reference in this annual report, at the SEC’s  Public Reference Room at 100 F Street, N.E., Washington, D.C. 20549 and at the SEC’s regional offices in New York, New York and  Chicago, Illinois. You can also request copies of this annual report, including the exhibits incorporated by reference in this annual  report, upon payment of a duplicating fee, by writing information on the operation of the SEC’s Public Reference Room. \n120\nP AR T I\nInformation Reporting and Backup Withholding\nInformation Return under Section 6045B of the Internal Revenue Code\nF. Dividends and Paying Agents\nG. Statement by Experts\nH. Documents on Display\nNot applicable.\nNot applicable. "}]}
+{"image": "doclay/doclay_37391.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "TEIL II   LEISTUNGSPROGRAMM \nABWASSERSAMMELSTATION\n1  Rohrleitungen \nDie Rohrleitungen sind inklusive aller Halterungsunterstützungen, Form - und  Verbindungsstücke zu liefern und vor Ort im Raum 001 und Raum 034 zu  montieren. \nPos.  Leistung  Anzahl  EP  EUR  GP  EUR \n1.1  Rohrleitungen ø10 mm 12m \nMedium: Chemieabwasser III  Nenndruck: PN 10  Temperatur: max. 80°C Werkstoff: 1.4571 Werkstoffbelegung: DIN EN 10204/3.1\n1.2  Rohrleitungen DN 25 80m \nMedium: Chemieabwasser III  Nenndruck: N 10  Temperatur: max. 80°C Werkstoff: PP Werkstoffbelegung: DIN EN 10204/2.2\nSumme Pos. 1.3 (Liefern + Montieren)  ………………  …………..… \n1.3  Rohrleitungen DN 25  60m \nSumme Pos. 1.2 (Liefern + Montieren)  ………………  ……………… \nSumme Pos. 1.1 (Liefern + Montieren)  ………………  ……………… \nMedium: Betriebswasser Nenndruck: PN 10  Temperatur: max. 20°C  Werkstoff: Mepla Systemrohr Werkstoffbelegung: DIN EN 10204/2.2"}]}
+{"image": "doclay/doclay_53155.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "This page intentionally left blank "}]}
+{"image": "doclay/doclay_22284.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS \nThe following tables summarize the difference between the aggregate fair value and the aggregate unpaid principal balance for residential  mortgage loans measured at fair value. \nFair Value of Certain Financial Instruments The following table summarizes carrying amounts and estimated fair values for certain financial instruments, excluding financial instruments  measured at fair value on a recurring basis at: \nFair Value of Certain Financial Instruments The following table summarizes carrying amounts and estimated fair values for certain financial instruments, excluding financial instruments \n122 Fifth Third Bancorp\n($ in millions)  Aggregate  Fair Value Aggregate Unpaid Principal Balance  Difference  As of December 31, 2010 Residential mortgage loans measured at fair value  $1,938 1,913 $25 Past due loans of 90 days or more  5 6 (1) Nonaccrual loans  1 1 - As of December 31, 2009 Residential mortgage loans measured at fair value  $1,496  1,463  $33  Past due loans of 90 days or more  3  4  (1)  Nonaccrual loans  1  1  - \nDecember 31, 2010  ($ in millions)  Carrying  Amount  Fair Value  Financial assets:  Cash and due from banks  $2,159 2,159 Other securities  868 868 Held-to-maturity securities 353 353 Other short-term investments  1,515 1,515 Loans held for sale  324 324 Portfolio loans and leases: Commercial and industrial loans  26,068 27,322 Commercial mortgage loans  10,248 9,513 Commercial construction loans  1,890 1,471 Commercial leases  3,267 2,934 Residential mortgage loans  (a) 8,600 7,577 Home equity  11,248 9,366 Automobile loans  10,910 10,975 Credit card  1,738 1,786 Other consumer loans and leases  622 682 Unallocated allowance for loan and lease losses  (150) - Total portfolio loans and leases, net  (a) 74,441 71,626 Financial liabilities:  Deposits  81,648 81,860 Federal funds purchased  279 279 Other short-term borrowings  1,574 1,574 Long-term debt 9,558 9,921 (a) Excludes  $46  of residential mortgage loans measured at fair value on a recurring basis. \nLong-term debt (a) Excludes  $46  of residential mortgage loans measured at fair value on a recurring basis. \nDecember 31, 2009 ($ in millions)  Carrying  Amount Fair Value Financial assets:  Cash and due from banks  $2,318 2,318 Other securities 893 893 Held-to-maturity securities 355 355 Other short-term investments  3,369 3,369 Loans held for sale 543 543 Portfolio loans and leases, net  (a) 73,004 68,748 Financial liabilities:  Deposits   84,305 84,544 Federal funds purchased  182 182 Other short-term borrowings  1,415 1,415 Long-term debt 10,507 9,899 (a) Excludes $26 of residential mortgage loans measured at fair value on a recurring basis. \nLong-term debt (a) Excludes $26 of residential mortgage loans measured at fair value on a recurring basis. "}]}
+{"image": "doclay/doclay_19933.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "NOTES TO CONSOLIDATED FINANCIAL STATEMENTS — (Continued)\nDEFERRED FINANCING COSTS\nINCOME TAXES\nPage 96\nSkyworks / Annual Report 2011\nCompany’s expected stock price volatility over the term of the awards, and actual and projected employee stock option exercise behaviors. The determination of fair value of restricted share awards is based on the value of the Company’s stock on the date of grant. For more complex awards with market-based performance conditions, the Company employs a Monte Carlo simulation method which calculates many potential outcomes for an award and establishes fair value based on the most likely outcome.\nFinancing costs are capitalized as an asset on the Company’s balance sheet and amortized on a straight-line basis over the life of the financing. If debt is extinguished early, a proportionate amount of deferred financing costs is charged to earnings.\nThe Company uses the asset and liability method of accounting for income taxes. Under the asset and liability method, deferred tax assets and liabilities are recognized for the estimated future tax consequences attributable to differences between the financial statement carrying amounts of existing assets and liabilities and their respective tax basis. This method also requires the recognition of future tax benefits such as net operating loss carry forwards, to the extent that realization of such benefits is more likely than not. Deferred tax assets and liabilities are measured using enacted tax rates expected to apply to taxable income in the years in which those temporary differences are expected to be recovered or settled. The effect on deferred tax assets and liabilities of a change in tax rates is recognized in income in the period that includes the enactment date.\nThe carrying value of the Company’s net deferred tax assets assumes the Company will be able to generate sufficient future taxable income in certain tax jurisdictions, based on estimates and assumptions. If these estimates and related assumptions change in the future, the Company may be required to record additional valuation allowances against its deferred tax assets resulting in additional income tax expense in its consolidated statement of operations. Management evaluates the realizability of the deferred tax assets and assesses the adequacy of the valuation allowance quarterly. Likewise, in the event the Company were to determine that it would be able to realize its deferred tax assets in the future in excess of their net recorded amount, an adjustment to the deferred tax assets would increase income or decrease the carrying value of goodwill in the period such determination was made.\nThe determination of recording or releasing tax valuation allowances is made, in part, pursuant to an assessment performed by management regarding the likelihood that the Company will generate future taxable income against which benefits of its deferred tax assets may or may not be realized. This assessment requires management to exercise significant judgment and make estimates with respect to its ability to generate revenues, gross profits, operating income and taxable income in future periods. Amongst other factors, management must make assumptions regarding overall business and semiconductor industry conditions, operating efficiencies, the Company’s ability to develop products to its customers’ specifications, technological change, the competitive environment and changes in regulatory requirements which may impact its ability to generate taxable income and, in turn, realize the value of its deferred tax assets.\nThe calculation of the Company’s tax liabilities includes addressing uncertainties in the application of complex tax regulations. With the implementation effective September 29, 2007, ASC 740 — Income Taxes (“ASC 740”) clarifies the accounting for uncertainty in income taxes recognized in an enterprise’s financial statements in accordance with GAAP. ASC 740 prescribes a recognition threshold and measurement attribute for the financial statement recognition and measurement of a tax position taken or expected to be taken in a tax return."}]}
+{"image": "doclay/doclay_3330.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\nb) Benennung der drei schwerpunktmäßigen Handlungsbereiche,\n3. zur Situationsaufgabe nach § 6 Absatz 5\na) Benennung des Prüfungsteils unter Angabe des schwerpunktmäßigen Handlungsbereichs,\nb) Benennung und Bewertung der Konzeption und praktischen Umsetzung mit Note sowie\nc)  Benennung und Bewertung der Präsentation mit Fachgespräch mit Note,\n4. die errechnete Gesamtpunktzahl für die gesamte Prüfung,\n5. die Gesamtnote als Dezimalzahl,\n6. die Gesamtnote in Worten,\n7. Befreiungen nach § 7,\n8. Vorliegen des Sachkundenachweises für die Anwendung von Pflanzenschutzmitteln nach § 2 Absatz 2.\n- Seite 9 von 9 -"}]}
+{"image": "doclay/doclay_63414.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "US 10,620,533 B2 \n3 \n4 \nserving as acid pairs with an anion, the hopping of proton is  reduced as the size of anion becomes larger. \nAnother component that is expected effective for mitigat› ing the influence of PPD is a quencher. Conventional  quenchers were developed for the purpose of suppressing  acid diffusion during PEB at high temperature for thereby  enhancing the contrast of deprotection reaction. For miti› gating the influence of PPD, it is desired from a different  viewpoint to develop a quencher capable of suppressing acid  diffusion at room temperature. \ngroup,  CcC$_{20 }$ aryl group, or C$_{7}$ -C$_{12 }$aralkyl or aryloxoalkyl  group, in which at least one hydrogen may be substituted by  a substituent containing an ether, ester, carbonyl, carbonate,  hydroxyl, carboxyl, halogen, cyano, amide, nitro, sultone,  sulfonic acid ester, sulfone, thiol moiety or sulfonium salt, or  R 2  and R 3  may bond together to form a ring with the sulfur  atom to which they are attached; R 5  and R 6  are each  independently a  CcC$_{20 }$ aryl group in which at least one  hydrogen may be substituted by a straight, branched or  cyclic C$_{1 }$-C$_{10 }$alkyl or alkoxy moiety. \nThe resist composition may further comprise an acid  generator capable of generating sulfonic acid, imide acid or  methide acid, and an organic solvent. \nIn a preferred embodiment, the base polymer comprises  recurring units having the formula (al) or recurring units  having the formula (a2). \nPatent Document 1: JP-A 2001-194776  Patent Document 2: JP-A 2002-226470  Patent Document 3: JP-A 2002-363148  Patent Document 4: JP-A 2015-090382  Non-Patent Document 1: SPIE Vol. 5039 pl (2003)  Non-Patent Document 2: SPIE Vol. 6520 p65203L-1  (2007)  Non-Patent Document 3: SPIE Vol. 7639 p76390 W  (2010) \nCITATION LIST \nDISCLOSURE OF INVENTION \nDesired are quenchers capable of suppressing acid diffu› sion at room temperature, providing a high dissolution  contrast, and reducing edge roughness (LWR) rather than  such quenchers as amine quenchers, sulfonium and iodo› nium salts of sulfonic acid and carboxylic acid. \nAn object of the invention is to provide a resist compo› sition which exhibits a high dissolution contrast, a reduced  LWR, and no dimensional changes on PPD, independent of  whether it is of positive tone or negative tone; and a pattern  forming process using the same. \nThe inventors have found that using a sulfonium or  iodonium salt of sulfonic acid containing a morpholino  group as the quencher, a resist film having a reduced L WR,  a high dissolution contrast, and no dimensional changes on  PPD is obtainable. \nIn one aspect, the invention provides a resist composition  comprising a base polymer and a sulfonium or iodonium salt  having the formula (A). \nHerein R  1  is a straight, branched or cyclic C$_{1 }$-C$_{24 }$alkylene  group which may contain a hydroxyl, alkoxy, ether, ester,  sulfonic acid ester moiety, halogen atom, double bond, triple  bond or aromatic moiety. A+ is a sulfonium cation having the  formula (B) or iodonium cation having the formula  (C). \nHerein R 2 , R 3  and R 4  are each independently a straight, 65  branched or cyclic C$_{1 }$-C$_{12 }$ alkyl or oxoalkyl group, a  straight, branched or cyclic C$_{2}$-C$_{12 }$ alkenyl or oxoalkenyl \nHerein R 1  and R 13  are each independently hydrogen or  methyl, R$^{12 }$and R$^{14 }$are each independently an acid labile  group, X is a single bond, ester group, phenylene group,  naphthylene group or a C$_{1 }$-C$_{12 }$ linking group containing  lactone ring, and Y is a single bond or ester group. \nThe resist composition may further comprise a dissolution  inhibitor. \nTypically the resist composition is a chemically amplified  positive resist composition. \nIn another preferred embodiment, the resist composition  is a chemically amplified negative resist composition; the  base polymer is free of an acid labile group; and the resist  composition may further comprise a crosslinker. \nIn a preferred embodiment, the base polymer comprises  recurring units of at least one type selected from the for› mulae  (fl) to (f3). \n(A) \n(B)  R3  I  R $^{2}$-s+-R4 \n(C)  R $^{5}$-I+-R6 \n(al) \n(a2)  ~  y  6  ORl4 \n(fl) "}]}
+{"image": "doclay/doclay_61032.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "351/98 Wl WTS PAY a\n200510079024. 1\n206\nRib eal OF N 4 yf VE Fo oye GY WA AD fy FE af at Bb Ge HK EGW AM BAR s &x% v 8 fy apart 9 e YX _ Lee YE GGA GAD ex | &% Gi LY"}]}
+{"image": "doclay/doclay_28335.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "only when the matrix elements 〈 t | V | ˜ p 〉 become small. On the other hand, the dynamic case has a denominator that changes sign from positive to negative as Δ$_{t}$ sweeps through the plasma energies, and the denominator itself gets large when Δ$_{t}$ gets large. The dynamic screening behavior of the plasmons is missing in the static formula which assumes that no matter what the transition energy, the plasmons can screen it adiabatically. This is obviously erroneous for transitions where Δ$_{t}$ ≳ ˜ ω$_{p}$ . Therefore, the static formula can be improved by adding some dynamic behavior in the screening even if done approximately. This is an example of what was meant in Section 10 regarding the use of plasmon-pole models or model dielectric functions to improve the static COHSEX.\nWe end this section with some observations on the results in Tables II and III and their dependence on the single-particle theory. The parts of the total energy that depend only on the single-particle orbitals, i.e. the kinetic, electron-ion, Hartree, and Fock exchange energies, depend weakly on the choice of LSDA versus HF single-particle orbitals, changing at most ∼ 1%. This is not surprising a posteriori as visual comparison of the radial functions show small differences. However, the correlation energies depend more strongly on the choice of single-particle theory, and this is due to the relatively large differences between the single-particle energies. The HF-based correlation energies are smaller than the LSDA simply because HF transition energies are larger than LSDA: e.g. , for atomic boron the important 2 s -2 p transition is at 0.210 Ha in LSDA but at 0.232 Ha in HF; larger transition energies mean weaker screening and thus weaker correlation. As per Section 8, it matters greatly whether the Green’s function G$_{0}$ is generated by a local or non-local potential.\nThe true many-body Green’s function G obeys Dyson’s Eq. (4) and is thus generated by a non-local (and dynamic) self-energy Σ$_{xc}$( x,x $^{′}$,ω ). A priori , we would expect that a static but non-local potential U$_{0}$ ( x,x $^{′}$) should generate a decent non-interacting G$_{0}$ which should be close to the true G , certainly closer than one generated by a static local potential. However, as discussed in Section 8, choosing the “best” U$_{0}$ via an optimization of the total energy functional is problematic unless constraints are imposed on U$_{0}$ . The outstanding theoretical problem is what constraints to impose and which ones are the “best” ones. This obviously involves creating and justifying metrics that tells us how good each choice of constraints will be in practice.\nOur work has focused on the correlation energy functional with Luttinger-Ward theory (specifically the Klein functional) within the GW -RPA approximation. The Green’s func- tions used in the energy functional are of non-interacting form. The main findings in this work are threefold. First, we present the exact rewriting of the GW -RPA correlation en- ergy functional in Eq. (38) in terms of differences between plasma and interband energies. This form is directly amenable to computation, shows good convergence properties in the atomic tests, and has prospects for having its computational scaling improved by use of ma- trix square root algorithms. Second, we describe the approximate rewriting of the GW -RPA correlation energy functional in Eqs. (44) and (45) where the correlation energy is written as a sum of screened interband transition contributions; the main approximation is to assume that the dominant screening dynamics are much faster than the key interband dynamics;\n12. SUMMARY AND OUTLOOK\n35"}]}
+{"image": "doclay/doclay_17658.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "(b) Principles of Consolidation\nNote 1. Summary of Significant Accounting Policies  (continued)\nThe consolidated financial statements incorporate the assets and liabilities of all subsidiaries of Karoon Gas Australia Ltd as at 30 June 2011 and the results of all subsidiaries for the financial year then ended.\nA subsidiary is any entity controlled by Karoon Gas Australia Ltd whereby it has the power to control the financial and operating  policies of an entity so as to obtain benefits from its activities. The existence and effect of potential voting rights that are currently  exercisable or convertible are considered when assessing whether the Group controls another entity.\nInterests in subsidiaries are set out in Note 21.\nThe acquisition of subsidiaries is accounted for using the acquisition method of accounting. The acquisition method of accounting  involves allocating the cost of the business combination to the fair value of the assets acquired, liabilities and contingent liabilities  assumed at the date of acquisition. Acquisition related costs are expensed as incurred and the associated cash flows are classified  as operating activities in the consolidated statement of cash flows.\nAll subsidiaries have a financial year end of June, with the exception of: Karoon Petróleo & Gas SA; KEI (Peru 112) Pty Ltd,  Sucursal del Peru; and KEI (Peru Z38) Pty Ltd, Sucursal del Peru. These subsidiaries and branches have a financial year end of  December in accordance with relevant Brazilian and Peruvian tax and accounting regulations respectively.\nAccounting policies of subsidiaries have been changed, where necessary, to ensure consistency with the policies applied by the Group.\nIntercompany transactions, balances and unrealised gains on transactions between Group companies are eliminated on consolidation.  Unrealised losses are also eliminated, unless the transaction provides evidence of the impairment of the asset transferred.\nWhere subsidiaries have entered or left the Group during the financial year, their operating results are included or excluded from  the date control was obtained or until the date control ceased respectively.\nOperating segments are reported in a manner consistent with the internal reporting provided to the chief operating decision  maker. The chief operating decision maker, who is responsible for assessing performance and in determining the allocation of resources of the operating segments, has been identified as the Executive Chairman and the Executive Director/Exploration  Director.\nRevenue is recognised and measured at the fair value of the consideration received or receivable to the extent it is probable that  economic benefits will flow to the Group and the revenue can be reliably measured. The following specific recognition criteria  must also be met before revenue is recognised:\nDividend revenue is recognised when the right to receive a dividend has been established.\nInterest income is recognised using the effective interest rate method, which, for floating rate financial assets, is the rate inherent  in the relevant financial asset.\nRevenue from the sale of goods is recognised upon the delivery of goods to the buyer and all significant risks and rewards of  ownership are transferred. Revenue from the rendering of a service is recognised upon the delivery of the service. All revenue is  stated net of the amount of GST.\n(c) Segment Information\n(d) Revenue\nSales Revenue\nDividend Revenue\nInterest Income\nKaroon Gas Australia Ltd  Annual Report 2011\n38\nNOTES TO THE FINANCIAL STATEMENTS CONTINUED\nFOR THE FINANCIAL YEAR ENDED 30 JUNE 2011"}]}
+{"image": "doclay/doclay_33257.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "2\nThe relationship between conductivity and diffusion length is very useful to better understand the transport behavior. By definition, L ( E, t ) = √ D ( E, t ) t , then we can easily find that L ∝ t 1$_{−}$ λ 2 = t $^{α}$, which is verified for all the concentrations simulated, as shown in Fig. 2(a) with a Log-Log plot of diffusion length ( L ) versus time ( t ). Substituting t with L , σ$_{xx}$ scales with L as σ$_{xx}$ ∝ L 2 $^{α$_{−}$}$1 α . By dimensional analysis, σ$_{xx}$ can be expressed as\nσ$_{xx}$ ( L ) = σ$_{0}$ ( e $^{2}$/h )( L/l ) 2 $^{α$_{−}$}$1 α , (2)\nFigure 1: (Color online) Diffusion coefficient ( D ) as a function of time ( t ) for different vacancy concentration ( x ) at E $_{F}$.\nFigure 2: (Color online) (a) Diffusion length ( L ) as a function of time ( t ) for different vacancy concentration ( x ) at E $_{F}$. (b) Scaling exponent α as a function of vacancy concentration ( x ) at E $_{F}$.\nwhere σ$_{0}$ is the conductivity in the diffusive regime in unit of e $^{2}$/ ℏ and l is the electron mean free path. It is im- portant to note that such power-law dependence of con- ductivity on diffusion length is different from the usual logarithmic dependence, σ ( L ) = σ$_{0}$ − ( e $^{2}$/ ℏ π $^{2}$) ln ( L/l ) , as predicted by 2D scaling theory of localization [14]. We at- tribute this difference to the distinct nature of the quasi - localization induced by vacancies. The wave-function amplitude of the localized state induced by vacancies de- cays with the distance as 1 /r [6, 8], which is not normal- izable in 2D. Therefore, such quasi -localized state [6, 8] is different from the usual localized state, whose wave function decays exponentially with the distance [14].\nIt has been predicted that the vacancy-induced quasi - localization will lead to MIT in graphene [6, 8]. However, the critical vacancy concentration where the MIT occurs remains unknown. Here, we will determine the critical vacancy concentration for the MIT. From Fig. 2(a), we derive the scaling exponent, α , from the linear fitting of L versus t , and the resulting α are plotted as a function of x in Fig. 2(b). The curve of α ( x ) can be fit nicely by L ∝ t 1$_{−}$ λ 2 = t $^{α}$, in the whole range of concentration. No- tice that when α = 0 . 5 , λ = 0 , then d D /dt = 0 because D ∝ t − $^{λ}$, which means α = 0 . 5 defines the position of dif- fusive regime. α > 0 . 5 ( λ < 0 ) means the ballistic regime and α < 0 . 5 ( λ > 0 ) means the localization regime. Thus, the power-law scaling holds true for all three transport regimes. α initially decreases rapidly with the increas- ing x , indicating the system quickly leaves the ballistic regime entering the localization regime. The transition point at α = 0 . 5 defines the critical vacancy concentra- tion for MIT, which is found to be x$_{c}$ ≈ 0 . 053% in Fig. 2(b). This value seems to agree quite well with the re- cent experimental result of critical concentration of MIT ( 0 . 08% ) in H-dosed graphene [13]. It implies that similar transport behavior exists in these two disordered systems that both vacancy defect and H impurity create similar localization phenomena in graphene. In addition, the ex- periment suggested other unknown defects rather than H may induce MIT at even lower defect concentrations [13], which might be attributed, at least partly, to vacancies according to our calculation.\nNext, we examine another criticality of the vacancy- induced MIT in graphene, the mobility edge ( E$_{c}$ ), which\nplateau often seen in other systems. (2) Beyond D$_{max}$ , the system enters the localization regime, where D de- cays in a power law D ∝ t − $^{λ}$, similar to the behavior of disordered carbon nanotude [19]. This indicates that the system stays in the localization regime ( d D /dt < 0 ) when x ≥ 0 . 1% at large time scale, in agreement with the previous analytical results [6, 8, 10]. (3) D decreases with the increasing x (inset of Fig. 1). This is because higher vacancy concentration leads to stronger scatter- ing, reducing the diffusion coefficient. We note that at a given vacancy concentration, ρ is a constant independent of time. Therefore, the conductivity σ$_{xx}$ ∼ D ρ will have the same power-law scaling with time, σ$_{xx}$ ∝ t − $^{λ}$, as D . Moreover, higher concentration will cause faster decay (larger λ ) in both diffusion coefficient and conductivity."}]}
+{"image": "doclay/doclay_74848.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "sustainable development\nReducing atmospheric emissions ... Following a recent upgrade project, our Baltimore linear alkylbenzene plant in the USA has eliminated the use of process chlorine and has since reduced emissions of sulphur dioxide and hydrogen sulphide by 30% and 90%, respectively.\nTackling the Aids challenge We have been increasing our efforts to contain, if not reduce, both the personal impacts and the business risks associated with South Africa’s HIV/Aids pandemic. The Sasol board of directors agreed in November 2002 to a five-point policy programme to better manage and, in time, minimise the impact of HIV/Aids in the workplace. Through this policy, our leaders and managers must endeavour to:\nThis, in turn, will support the second SHARP component, which is focused on an intensive prevention drive based on a segmentation approach and multi-channel communication in order to convince high-risk employees of the need for them to change their behaviour. The third SHARP component is a comprehensive wellness and treatment programme that includes making Sasol-funded antiretroviral treatment available to all affected employees who do not have access to it through medical aid schemes.\nPilot launch of SHARP The SHARP programme was launched on a pilot basis at two of our Secunda mines in May 2003. Excellent results were achieved on the first goal:our provision of mandatory education and on-site voluntary testing and counselling facilities resulted in a large majority of the mine’s workforce undergoing voluntary testing and counselling in just one week. Work is now under way to achieve further SHARP goals and to extend the programme rapidly to our entire Secunda workforce.\nWe believe that our workforce HIV/Aids interventions will provide valuable input into our external programmes designed to reduce people’s exposure to HIV and Aids in communities close to our mines and factories. We shall support our community HIV/Aids response programme by helping to extend the reliable distribution of contraceptives and by promoting more effective communication with the support of recognised community role-models.\nThrough the Sasol HIV/Aids Response Programme (SHARP) we are endeavouring to make voluntary HIV testing and counselling available to our entire workforce, especially in Southern Africa where the risks are the highest.\n64\nSafety, health and environmental management\n● instil a culture of zero tolerance of discrimination towards HIV-positive people;\n● drive fundamental behaviour change towards safer sex practices, and to encourage employees to undergo voluntary HIV testing and counselling, and to practice positive living;\n● ensure accessible, safe, effective and sustainable provision of antiretroviral treatment to eligible employees (those who have been diagnosed as HIV-positive after undergoing voluntary testing);\n● reduce the business impact of HIV/Aids; and\n● manage the total cost of an effective HIV/Aids response programme.\nthe successful launch of the sasol hiv/aids response  programme augurs well for risk management\nsustainable development"}]}
+{"image": "doclay/doclay_74019.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "99  / SERVICE EXCELLENCE\n21. Leases\nThe Company’s leases have remaining terms of less than one year to 15 years, some include options to extend up to an additional 10 years, and some include options to terminate within one year.\nResidual value guarantees are provided on certain rolling stock and vehicle operating leases. Cumulatively, these guarantees are limited to $2 million and are not included in lease liabilities as it is not currently probable that any amounts will be owed under these residual value guarantees.\nThe components of lease expense for the year ended December 31 are as follows:\n(in millions of Canadian dollars) 2019 Operating lease cost $ 89 Short-term lease cost 10 Variable lease cost 13 Sublease income (3) Finance Lease Cost Amortization of right-of use-assets 9 Interest on lease liabilities 11 Total lease costs $ 129\nSupplemental balance sheet information related to leases is as follows:\n(in millions of Canadian dollars) Classification 2019 Assets Operating Other assets $ 358 Finance Properties, net book value 177 Liabilities Current Operating Accounts payable and accrued liabilities 69 Finance Long-term debt maturing within one year 7 Long-term Operating Other long-term liabilities 285 Finance Long-term debt 144\nThe following table provides the Company's weighted-average remaining lease terms and discount rates:\n2019 Weighted-Average Remaining Lease Term Operating leases 7 years Finance leases 4 years Weighted-Average Discount Rate Operating leases 3.45% Finance leases 7.07 %"}]}
+{"image": "doclay/doclay_24531.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "If E( ψ ( X$_{1}$ ) | F $_{0}$) = 0, it follows by an application of the continuous mapping theorem to the partial sum process 1 √$_{n}$ ∑ ⌊ nt ⌋ j =1 ψ ( X$_{j}$ ) that T$_{n}$ ( τ$_{1}$, τ$_{2}$ ) D −→ T (1 , τ$_{1}$, τ$_{2}$ ), where T (1 , τ$_{1}$, τ$_{2}$ ) corresponds to (15) with Z$_{1}$ denoting a fractional Brownian motion process with Hurst parameter 1 / 2, i.e. under these assumptions Z$_{1}$ denotes a Brownian motion. Note that in this case the limit does not depend on any unknown parameters. The factor σ that appeared in the limit of the partial sum process is canceled out by self-normalization.\nAs an alternative to the self-normalized CUSUM test, Betken (2016b) proposes to use a self-normalized Wilcoxon test for the detection of changes in the mean of long range dependent time series. For the definition of the corresponding test statistic, we consider the ranks defined by R$_{i}$ := rank( X$_{i}$ ) = ∑ n j $^{$_{=1}$1}${ X$_{j}$ ≤ X$_{i}$ } for i = 1 , . . . , n . The self-normalized two-sample Wilcoxon test statistic is then defined by\nUnder the hypothesis of stationarity, the asymptotic distribution of the test statistic is derived in Betken (2016b) for long range dependent subordinated Gaussian processes. Basically, the asymptotics of the test statistic follow from an application of the continuous mapping theorem to the process\nTheorem 3.3 implies that the above process converges in distribution to the following limit:\n1 nd$_{n,m}$ ⌊ nt ⌋ ∑ i =1 n ∑ j = ⌊ nt ⌋ +1 ( $^{1}${ ψ ( X$_{i}$ ) ≤ ψ ( X$_{j}$ ) } − 1 2 ) , t ∈ [0 , 1] .\n∫ R J$_{m}$ (Ψ$_{x}$ ◦ σ ) dF$_{ψ}$$_{(}$$_{X}$$_{1}$$_{)}$ ( x ) 1 m ! ( Z$_{m}$ ( t ) − λZ$_{m}$ (1)) , t ∈ [0 , 1] .\n∑ ∑ where S$_{t}$ ( j, k ) := ∑ t h = j ( R$_{h}$ − ¯ R$_{j,k}$ ) with ¯ R$_{j,k}$ := 1 k − j +1 ∑ k t = j R$_{t}$ . The self-normalized $^{Wilcoxon change-point test rejects the hypothesis for large values of max$_{k}$}$∈{⌊ nτ 1 ⌋ ,..., ⌊ nτ 2 ⌋} | G$_{n}$ ( k ) | , where 0 < τ$_{1}$ < τ$_{2}$ < 1.\nG$_{n}$ ( k ) := ∑ k i $_{=1}$R$_{i}$ − k n ∑ n i $_{=1}$R$_{i}$ { 1 n ∑ k t $_{=1}$S 2 $_{t}$(1 , k ) + 1 n ∑ n t = k $_{+1}$S 2 $_{t}$( k + 1 , n ) } 1 / $_{2}$, ) := ∑ t ( R$_{h}$ − ¯ R$_{j,k}$ ) with ¯ R$_{j,k}$ := 1 ∑ k R$_{t}$ . The self-normalized\n21"}]}
+{"image": "doclay/doclay_14723.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Foreign Investment Approval\nDepositary Receipts\nOther than: \nforeign investors who wish to make direct investments in the shares of Taiwan companies may submit a “foreign investment  approval” application to the Investment Commission of the Ministry of Economic Affairs of Taiwan or other government authority to  qualify for benefits granted under the Statute for Investment by Foreign Nationals. The Investment Commission or other government  authority reviews each foreign investment approval application and approves or disapproves the application after consultation with  other governmental agencies. Any non-Taiwan person possessing a foreign investment approval may remit capital for the approved  investment and repatriate annual net profits and interests and cash dividends attributable to an approved investment. Stock dividends,  investment capital and capital gains attributable to the investment may be repatriated with approval of the Investment Commission or  other government authority.\nIn addition to the general restrictions against direct investment by non-Taiwan persons in Taiwan companies, non-Taiwan  persons are currently prohibited from investing in prohibited industries in Taiwan under the Negative List promulgated by the  Executive Yuan from time to time. The prohibition on direct foreign investment in the prohibited industries in the Negative List  is absolute with the consequence of certain specific exemption from the application of the Negative List. Under the Negative List,  some other industries are restricted so that non-Taiwan persons may directly invest only up to a specified level and with the specific  approval of the relevant authority which is responsible for enforcing the legislation which the negative list is intended to implement.  The telecommunication industry is a restricted industry under the Negative List. \nIn April 1992, the Securities and Futures Bureau began allowing Taiwan companies listed on the Taiwan Stock Exchange,  with the prior approval of the Securities and Futures Bureau, to sponsor the issuance and sale of depositary receipts evidencing  depositary shares. In December 1994, the Republic of China Ministry of Finance began allowing companies whose shares are traded  on the GreTai Securities Market also to sponsor the issuance and sale of depositary receipts evidencing depositary shares representing  shares of its capital stock. Approvals for these issuances are still required. \nAfter the issuance of a depositary share, a holder of the depositary receipt evidencing the depositary shares may request the  depositary issuing the depositary share to cause the underlying shares to be sold in Taiwan and to distribute the proceeds of the sale  to or to withdraw the shares and deliver the shares to the depositary receipt holder. A citizen of the People’s Republic of China is not  permitted to withdraw and hold our shares. \nIf you are an offshore foreign institutional investor holding the depositary receipts, you must register with the Taiwan Stock  Exchange as a foreign investor before you will be permitted to withdraw the shares represented by the depositary receipts. In addition  to obtaining registration with the Taiwan Stock Exchange, you must also (i) appoint a qualified local agent to, among other things,  open a securities trading account with a local securities brokerage firm and a bank account to remit funds, exercise stockholders’  rights and perform other functions as holders of ADSs may designate, (ii) appoint a custodian bank to hold the securities and cash  proceeds, confirm transactions, settle trades and report and declare other relevant information and; (iii) appoint a tax guarantor as  guarantor for the full compliance of the withdrawing depositary receipt holders’ tax filing and payment obligations in the Republic of  China. A depositary receipt holder not registered as a foreign investor with the Taiwan Stock Exchange, or not has made the necessary  appointments as outlined above, will be unable to hold or subsequently transfer the shares withdrawn from the depositary receipt  facility. \n113\nP AR T I\n●  foreign institutional investors; \n●  foreign individual investors; and \n●  investors in overseas convertible bonds and depositary receipts, "}]}
+{"image": "doclay/doclay_48836.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\n§ 13 Anwendungsvorschrift\n§ 14 Evaluation\n§ 15 Ermächtigungen\nWird ein Steuersatz geändert, ist der neue Steuersatz auf Versicherungsentgelte anzuwenden, die ab dem Inkrafttreten der Änderung des Steuersatzes fällig werden. Wird die Fälligkeit des Versicherungsentgelts auf einen Zeitpunkt vor oder nach Inkrafttreten eines geänderten Steuersatzes geändert und würde die Änderung zur Anwendung eines niedrigeren Steuersatzes führen, ist die Änderung insoweit nicht zu berücksichtigen. Dies gilt entsprechend, wenn ein Versicherungsvertrag zur Änderung der Fälligkeit des Versicherungsentgelts gekündigt und alsbald neu abgeschlossen oder wenn die Fälligkeit des Versicherungsentgelts für einen Zeitpunkt vor Abschluß des Versicherungsvertrags festgelegt wird. Die Sätze 2 und 3 gelten für ab dem 1. August 1993 vorgenommene Änderungen oder Festlegungen der Fälligkeit des Versicherungsentgelts.\nDie Bemessungsgrundlagen (§ 3 Absatz 1) werden jährlich, beginnend mit dem 1. Januar 2012, durch Rechtsverordnung der Bundesregierung, die der Zustimmung des Bundesrates bedarf, derart angepasst, dass das Aufkommen der Feuerschutzsteuer nicht unter den Durchschnitt der Jahre 2009 bis 2011 (Sockelbetrag) sinkt. Die Bemessungsgrundlagen nach § 5 Absatz 1 Nummer 3 des Versicherungsteuergesetzes sind entsprechend anzupassen.\n(1) Die Bundesregierung wird ermächtigt, mit Zustimmung des Bundesrates Rechtsverordnungen über den Anteil an der Bemessungsgrundlage (§ 3 Absatz 1) zu erlassen.\n(2) Der Bundesminister der Finanzen kann dieses Gesetz und die auf Grund dieses Gesetzes erlassenen Rechtsverordnungen in der jeweils geltenden Fassung mit neuem Datum und unter neuer Überschrift im Bundesgesetzblatt bekannt machen.\n- Seite 5 von 5 -"}]}
+{"image": "doclay/doclay_55462.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Picnic cat by  Com-Pac Fisher Cat by Howard Boats\nWhat I can trailer.\niii"}]}
+{"image": "doclay/doclay_39554.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "CONTRATTO  QUADRO DI SERVIZI  ALLEGATO VIII AL CONTRATTO: CLAUSOLE CONTRATTUALI DI  AMBIENTALI  Procedura n. JRC/IPR/2019/OP/0139  Servizi di fabbricazione meccaniche  Pagina 1 di 6  Ref.\nALLEGATO VIII AL CONTRATTO QUADRO DI SERVIZI \nProcedura n. JRC/IPR/2019/OP/0139 \nServizi di fabbricazione meccaniche \nCLAUSOLE CONTRATTUALI AMBIENTALI \nARTICOLO 1 AMBITO DI APPLICAZIONE E DEFINIZIONI \nARTICOLO 2 POLITICA AMBIENTALE DEL SITO JRC DI ISPRA \nTitle: Clausole contrattuali ambientali  Pages 6  ID: IMS-IPR-S6.6-TMP-0001-IT  Version: 2.1  Owner:  JRC.R.I \n2.2 Il JRC di Ispra applica la normativa europea che disciplina la protezione ambientale nel rispetto dei  privilegi ed immunità stabiliti dai Trattati. Il JRC di Ispra applica, inoltre, su base volontaria, come  migliori pratiche le prescrizioni tecniche della legislazione nazionale e regionale italiana. \n2.1 Il sito JRC di Ispra ha adottato una politica ambientale (il cui contenuto è riportato di seguito) volta  alla pianificazione e al controllo delle attività che hanno un impatto sull'ambiente, al fine di  minimizzare l'impatto ambientale, prevenire l'inquinamento e migliorare le prestazioni ambientali  del sito. \nI.3  I riferimenti operati dal presente allegato al personale del Contraente si considerano ricomprendere  i lavoratori dipendenti, i lavoratori somministrati, i collaboratori, i soci lavoratori, i membri  dell'impresa familiare, i subappaltatori nonché ogni persona fisica che svolga le prestazioni oggetto  del contratto per conto del Contraente. Il primo periodo del presente comma si applica anche al  personale dei subappaltatori. \n1.2  I riferimenti operati dal presente allegato a norme di legge o amministrative si considerano  ricomprendere anche le successive modifiche ed integrazioni di dette norme. \n1.1  Le presenti clausole contrattuali ambientali costituiscono a tutti gli effetti parte integrante del  contratto e sono obbligatorie per il Contraente, sia esso un lavoratore autonomo, un libero  professionista, un'impresa costituita o meno in forma societaria, un consorzio, una persona  giuridica organizzata in forma diversa, un organismo di qualsivoglia forma o un'associazione  temporanea o non temporanea di imprese o di organismi. \n. "}]}
+{"image": "doclay/doclay_79865.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "US 2009/0042123 Al \n7 \nFeb. 12,2009 \ning aliphatic sulfonium group, a tetrafluoroborate group, and  a hexafluorophosphonium group. \n[0046]  Usually,aPAGisaddedinanamountof0.1 to20wt  % relative to the amount of a photoresist base material. \n[0047]  As the quenching agent, in addition to known  quenching agents, other compounds having the same effect  can be generally used. A preferable quenching agent and the  amount thereof can be appropriately selected according to the  type of a calixresorcinarane compound as a base material, the  type of a PAG, and a desired shape and size of minute patterns,  and the like. \n[0048]  In the invention, it is preferable to use a basic  organic compound as a quenching agent from the viewpoint  of solubility in a photoresist composition and dispersibility  and stability in a photoresist layer. \n[0049]  As specific examples of the basic organic com› pound, in addition to pyridines such as quinoline, indole,  pyridine, and bipyridine, pyrimidines, pyrazines, piperidine,  piperazine, pyrrolidine, 1,4-diazabicyclo[2.2.2]octane, ali› phatic amines such as triethylamine and trioctylamine, tet› rabutylammonium hydroxide, and the like can be given. \n[0050]  The amount of the quenching agent is usually from  10 to 1x10- $^{3 }$wt% of a photoresist base material or from 50 to  0.01 wt% of a PAG. \n[0051]  One example of a method for microfabrication  using the photoresist composition of the invention will be  described below. \n[0052]  The photoresist composition of the invention is  applied to a substrate as a liquid coating composition by spin  coating, dip coating, painting, and the like. In a common  practice after the application, the coated material is dried by  heating at 80°  C. to 160°  C., for example, in order to remove  the solvent until the photoresist coating layer becomes non› sticky. To improve adhesion with the substrate, hexamethyl› disilazane (HMDS) or the like can be used as an intermediate  layer. The conditions can be appropriately adjusted according  to the types of a base material and solvent used, a desired film  thickness of a photoresist layer, and the like. \n[0053]  After drying, the substrate on which the photoresist  coating layer is no longer sticky is exposed through a photo› mask to EUV or is irradiated with an electron beam by any  method to remove protective groups contained in a base mate› rial, thereby producing solubility differences between the  exposed areas and unexposed areas in the photoresist coating  layer. After the exposure, the substrate is baked to increase the  solubility differences, followed by development with an alka› line developer in order to form relief images. Patterns pro› cessed by ultra-microfabrication can be thus formed on the  substrate in this manner. The above conditions can be deter› mined according to the type of the base material or solvent  used or a desired thickness of a photoresist layer, or the like. \n[0054]  If the photoresist base material and the composition  thereof of the invention are used, patterns with isolated lines  of 100 nm or less, particularly 50 nm or less, a 1: 1 line-and› space (LIS), holes, etc, can be formed at a high sensitivity,  high contrast, and low line edge roughness by ultra-micro› fabrication using extreme ultraviolet radiation or an electron  beam. \nwherein Ar, Ar 1 ,  and  Ar2  are a substituted or unsubstituted  aromatic group having 6 to 20 carbon atoms; R, R 1 , R 2 , R 3 ,  and  RA  are a substituted or unsubstituted aromatic group  having 6 to 20 carbon atoms, and a substituted or unsubsti› tuted aliphatic group having 1 to 20 carbon atoms; and X,  XA,  Y,  and Z are an aliphatic sulfonium group, a fluorine-contain-\n[0055]  A three-neck flask (volume: 500 ml) equipped with  a dripping funnel, a Dimroth condenser, and a thermometer, \nEXAMPLES \nSynthesis Example 1 \nSynthesis of Calixresorcinarene Compound \n"}]}
+{"image": "doclay/doclay_79620.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "70.6. HOW MULTIPLE INTERPRETERS AND CONCURRENCY ARE SUPPORTED CHAPTER 70. PERLGUTS\nsv_setiv(foo, bar);\nand still have it work under all the modes Perl could have been compiled with.\nThis doesn’t work so cleanly for varargs functions, though, as macros imply that the number of arguments is known in advance. Instead we either need to spell them out fully, passing aTHX_ as the first argument (the Perl core tends to do this with functions like Perl_warner), or use a context-free version.\nThe context-free version of Perl_warner is called Perl_warner_nocontext, and does not take the extra argument. Instead it does dTHX; to get the context from thread-local storage. We #define warner Perl_warner_nocontext so that extensions get source compatibility at the expense of performance. (Passing an arg is cheaper than grabbing it from thread-local storage.)\nYou can ignore [pad]THXx when browsing the Perl headers / sources. Those are strictly for use within the core. Extensions and embedders need only be aware of [pad]THX.\ndTHR was introduced in perl 5.005 to support the older thread model. The older thread model now uses the THX mechanism to pass context pointers around, so dTHR is not useful any more. Perl 5.6.0 and later still have it for backward source compatibility, but it is defined to be a no-op.\nWhen Perl is built with PERL_IMPLICIT_CONTEXT, extensions that call any functions in the Perl API will need to pass the initial context argument somehow. The kicker is that you will need to write it in such a way that the extension still compiles when Perl hasn’t been built with PERL_IMPLICIT_CONTEXT enabled.\nThere are three ways to do this. First, the easy but ine ffi cient way, which is also the default, in order to maintain source compatibility with extensions: whenever XSUB.h is #included, it redefines the aTHX and aTHX_ macros to call a function that will return the context. Thus, something like:\nsv_setiv(sv, num);\nin your extension will translate to this when PERL_IMPLICIT_CONTEXT is in e ff ect:\nPerl_sv_setiv(Perl_get_context(), sv, num);\nor to this otherwise:\nPerl_sv_setiv(sv, num);\nYou have to do nothing new in your extension to get this; since the Perl library provides Perl_get_context(), it will all just work.\nThe second, more e ffi cient way is to use the following template for your Foo.xs:\n1092\n#define PERL_NO_GET_CONTEXT /* we want efficiency */ #include \"EXTERN.h\" #include \"perl.h\" #include \"XSUB.h\" static my_private_function(int arg1, int arg2); static SV * my_private_function(int arg1, int arg2) { dTHX; /* fetch context */ ... call many Perl API functions ... }\n70.6.2 So what happened to dTHR?\n70.6.3 How do I use all this in extensions?"}]}
+{"image": "doclay/doclay_2890.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "NAVWEPS 00-8OT-80  AIRPLANE PERFORMAN:CE \nPrPs=parasite  power required corresponding to  some different speed, I ’ , \nThus, induced power required will vary with  lift, aspect ratio, altitude, etc., in the same  manner as the induced drag. The only differ-  ence will be the variation with speed. If all  other factors remain constant, the induced  power required varies inversely with velocity  while induced’drag varies inversely with the  square of the velocity. \nFor example, if an airplane in steady flight is  operated at twice as great a speed, the parasite  drag is four times as great but the parasite  ~;;zr  required is eight times the original \nFigure 2.1 presents the thrust required and  power required for a specific airplane configu-  ration and altitude.  The curves of figure 2.1  are applicable for the following airplane data: \ngross weight, W= 15,000 Ibs.  span, b=40 ft.  equivalent parasite area, f=7.2 sq. ft.  airplane efficiency  factor, c= ,827  sea level altitude, C= 1.000  compressibility corrections neglected \nwhere \nPri,=induced power required corresponding to  some original speed, Vi \nI+;,= induced power required corresponding to  some different speed, V, \nFor example, if an airplane in steady level flight  is operated at.twice as great a speed, the in-  duced drag is one-fourth the original value but  the induced power required is one-half the  original value.  The parasite power required is a function \nThe curve of drag or thrust required versus  velocity shows the variation of induced, para-  site, and total drag. Induced drag predomi-  nates at low speeds. When the airplane is  operated at maximum lift-drag ratio, (L/D)-,  the total drag is at a minimum and the induced  and parasite drags are equal. For the specific  airplane of figure 2.1, (,L/D),,  and minimum  total drag are obtained at a speed of 160 knots. \noriginal value.  The parasite power required is a function  of the parasite drag and velocity. \nThe curve of power required versus velocity  shows the variation of induced, parasite, and  total power required. As before, induced  power required predominates at low speeds  and  parasite power required predominates at high  speeds  and the induced and parasite power are  equal at (L/D),,.  However, the condition of  (L/D&-  defines only the point of minimum  drag and does not define the point of minimum  pozver  required. Ordinarily, the point of mini-  mum power required will  occur at a speed  which is 76 percent of the speed for minimum  drag and, in the case of the airplane configura-  tion of figure 2.1, the speed  for minimum power  required would be 122 knots.  The total drag  at the speed for minimum power required is 15  percent higher than the drag at (L/D)-  but the  minimum power required is 12 percent lower  than the power required at (L/D)-. \nwhere \nPr,=parasite power required, h.p.  D,=paraSite drag, lbs.  V= true airspeed, knots \nThus, parasite power required will vary with  altitude and equivalent parasite area ( f) in the  same manner as  ‘ the parasite drag. However,  the variation with speed will be different. If  all other factors are constant, the parasite drag  varies as the square of velocity but parasite  power varies as the cube of velocity. \nwhere \nPrpl= parasite power required corresponding to  some original speed, Vi \nPb% v* 3  -=(-I  Ph  VI \n97 "}]}
+{"image": "doclay/doclay_27918.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "14\nCL ´ EMENT DOMBRY, MICHAEL FALK, MAXIMILIAN ZOTT\nIn particular, this is the case when at least two components η$_{s}$ , η$_{t}$ , s ̸ = t , are independent, see the argument in Section 2.\nExample 3.5 (Bernoulli model) . Consider a standard max-stable rv η ∈ R d with corresponding D -norm ‖·‖$_{B}$$_{β}$ , β ∈ (0 , 1], known from Example 2.7. It is easy to see that\nFrom the general equality\nwhere ˜ η is some standard max-stable rv with D -norm ‖·‖$_{D}$ , we conclude\nFor another example, namely the logistic model, we refer to Example 4.4.\nwhere Z is a generator of the D -norm corresponding to the copula expan- sion of ( F$_{s}$ ( X$_{s}$ ))$_{s}$$_{∈}$$_{S}$. Hence, the probability that there is a champion among X $^{(1)}$, . . . , X ( n ) does not depend on the univariate margins, but rather on the copula process of X .\nRemark 3.6 . (i) Theorem 3.1 implies that the extremal concurrence probability, just like the dual D -norm function, does not depend on the choice of Z , but only on ‖·‖$_{D}$ .\n(ii) In the preceding theorem, we can replace U , U $^{(1)}$, U $^{(2)}$, . . . by a sequence of iid stochastic processes X , X $^{(1)}$, X $^{(2)}$, . . . whose univariate marginal df F$_{s}$ ( x ) = P ( X$_{s}$ ≤ x ), s ∈ S , are continuous and strictly monontonically increasing on their support. The conditions (6) and (7) will then have to apply to the copula process ( F$_{s}$ ( X$_{s}$ ))$_{s}$$_{∈}$$_{S}$. In that case,\nnP ( X > max i =1 ,...,n − $_{1}$X ( i ) ) →$_{n}$$_{→∞}$ E ( ‖ 1 / Z ‖$_{D}$ ) − $^{1}$1$_{{}$ Z > 0 } ) ,\nE ( ≀≀ η ≀≀$_{B}$$_{β}$ ) = ∑ ̸ = T ⊂{ 1 ,...,d } β | T |− $^{1}$(1 − β ) d −| T $^{|}$E ( ≀≀ η$_{T}$ ≀≀$_{∞}$ ) = d ∑ k =1 ( d k ) β k (1 − β ) d − k 1 − (1 − β ) k\nE ( ≀≀ ˜ η ≀≀$_{∞}$ ) = 1 ‖ 1 ‖$_{D}$ ,\n‖ 1 ‖$_{B}$$_{β}$ = 1 − (1 − β ) d β ."}]}
+{"image": "doclay/doclay_6548.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "The above statement of financial position must be read in conjunction with the accompanying notes.\n53\n SUPER CHEAP AUTO GROUP LIMITED ANNUAL REPORT 2004\n Consolidated  Parent  Notes  entity  entity 2004  2004  $’000  $’000 Current assets Cash assets  7  13,640  0  Receivables  8  5,394  Inventories  9  92,513  0  Tax Assets  10  1,633  1,678  Other  11  1,206  0 Total current assets  114,386  1,678 Non-current assets  Other financial assets  12  0  84,233  Property, plant and equipment  13  36,257  0  Intangible assets  14  45,349  Deferred tax assets  15  5,006  4,876  Other non-current assets  16  440  0 Total non current assets  87,052  89,109 Total assets 201,438  90,787 Current liabilities  Payables  17, 30  46,857  0  Interest bearing liabilities  18  36,184  6,199  Provisions  19, 30  8,643  0  Total non-current liabilities  91,684  6,199 Non-current liabilities  Interest bearing liabilities  20  21,600  0  Deferred tax liabilities  21  355  355  Provisions  22, 30  797  0 Total non-current liabilities  22,752  355 Total liabilities 114,436  6,554 Net assets 87,002  84,233 Equity Contributed equity  23  84,233  84,233  Reserves  24  2  0  Retained profits  2,767  0 Total Equity 87,002  84,233\nSTATEMENT OF FINANCIAL POSITION Super Cheap Auto Group Limited  As at 26 June 2004"}]}
+{"image": "doclay/doclay_12823.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "partnering for the future\nconsolidated balance sheets\nDecember 31, (U.S. dollars in millions, except share data) 2004 2003 assets Current assets:  Cash and cash equivalents $ 4 43 32 2 $ 489 Trade accounts receivable (less allowance of $133 and $100) (Note 18) 1 1,,9 92 28 8 1,495 Inventories (Note 4) 2 2,,6 63 36 6 2,867 Deferred income taxes 9 95 5 93 Other current assets (Note 5) 1 1,,5 57 77 7 1,474 Total current assets 6 6,,6 66 68 8 6,418 Property, plant and equipment, net (Note 6) 2 2,,5 53 36 6 2,090 Goodwill (Note 8) 1 16 67 7 148 Other intangible assets, net (Note 9) 1 15 56 6 92 Investments in affiliates (Note 11) 5 56 64 4 537 Deferred income taxes 2 27 73 3 233 Other non-current assets 5 54 43 3 366 Total assets $ $ 1 10 0,,9 90 07 7 $ 9,884\nCurrent liabilities:  Short-term debt (Note 16) $ 5 54 41 1 $ 889 Current portion of long-term debt (Note 17) 1 14 40 0 128 Trade accounts payable 1 1,,8 89 98 8 1,678 Deferred income taxes 3 38 8 42 Other current liabilities (Note 12) 1 1,,2 28 85 5 1,200 Total current liabilities 3 3,,9 90 02 2 3,937 Long-term debt (Note 17) 2 2,,6 60 00 0 2,377 Deferred income taxes 2 23 32 2 206 Other non-current liabilities 5 51 18 8 433 Commitments and contingencies (Note 21) Minority interest in subsidiaries 2 28 80 0 554 Shareholders’ equity:  Common shares, par value $.01; authorized—240,000,000 shares; issued and outstanding: 2004—110,671,450 shares, 2003—99,908,318 shares 1 1 Additional paid-in capital 2 2,,3 36 61 1 2,010 Retained earnings 1 1,,4 44 40 0 1,022 Accumulated other comprehensive loss ((4 42 27 7)) (656) Total shareholders’ equity 3 3,,3 37 75 5 2,377 Total liabilities and shareholders’ equity $ $ 1 10 0,,9 90 07 7 $ 9,884\nThe accompanying notes are an integral part of these consolidated financial statements.\nliabilities and shareholders’ equity\n53"}]}
+{"image": "doclay/doclay_48372.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de\nLfd. Nr. Teil des Ausbildungsberufsbildes Zu vermittelnde Fertigkeiten, Kenntnisse und Fähigkeiten 1 2 3 d) Daten erfassen, bearbeiten und sichern e) Gespräche organisieren und situationsgerecht und zielorientiert führen f)  Sachverhalte darstellen, Protokolle anfertigen, englische Fachbegriffe anwenden g) Dokumentationen auch in englischer Sprache erstellen h) Kommunikation auch in englischer Sprache durchführen i)  IT-Systeme zur Auftragsplanung und -abwicklung sowie Terminverfolgung anwenden j)  Rolle der nationalen und internationalen Luftfahrtbehörden beachten 3 Montieren und Demontieren von Geräten, Baugruppen und Systemen (§ 3 Absatz 3 Nummer 3) a) Standard- und Spezialwerkzeuge, Prüf- und Messgeräte unterscheiden und unter Beachtung der Richtlinien des Werkzeug- und Betriebsmittelmanagements handhaben b) Werkstoffe, Geräte, Baugruppen und Systeme unter Beachtung deren Funktion und Eigenschaften handhaben c)  elektrische und mechanische Verbindungen nach Eigenschaften und Funktionen unterscheiden, herstellen und sichern d) Aufbau von elektrischen, pneumatischen und hydraulischen Leitungen und deren Verlegungsarten unterscheiden e) Bauteile, insbesondere aus luftfahrtspezifischen Werkstoffen, formen f)  Montage- und Demontagetechniken anwenden und Bauteile anpassen g) Bauteile, Geräte, Baugruppen und Systeme zur Lagerung und zum Transport vorbereiten h) Funktion von Potenzialausgleichsleitern prüfen und beurteilen i)  Übergangswiderstände messen und beurteilen; Isolationswiderstände beachten j)  Einbauorte identifizieren, Bauteile und Geräte einmessen und ausrichten 4 Durchführen von Funktions- prüfungen und Einstellarbeiten (§ 3 Absatz 3 Nummer 4) a) Test- und Prüfgeräte anwenden b) Funktionsprüfungen an Baugruppen, Systemen und Fluggerät nach Beanstandung, Fertigung und Instandhaltung durchführen c)  Einstellarbeiten an Baugruppen, Systemen und Fluggerät nach Fertigung und Instandhaltung durchführen 5 Instandhaltung (§ 3 Absatz 3 Nummer 5) a) Inspektions-, Wartungs-, Instandsetzungs- und Modifikationsarbeiten nach Instandhaltungsunterlagen an luftfahrzeug- und typenspezifischen Systemen durchführen b) Bauteile, Geräte und Baugruppen mit begrenzter Lebensdauer kontrollieren\n- Seite 6 von 32 -"}]}
+{"image": "doclay/doclay_55994.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Chapter 8. Next Steps and Where to Go From Here\nto boot into default mode. Press Enter for maintenance (or press Control-D to continue): root@ubuntu:~#\n• Alternatively the installer can be booted with the rescue=true boot parameter. You’ll be shown the first few screens of the installer, with a note in the corner of the display to indicate that this is rescue mode, not a full installation. Don’t worry, your system is not about to be overwritten! Rescue mode simply takes advantage of the hardware detection facilities available in the installer to ensure that your disks, network devices, and so on are available to you while repairing your system.\n• A trivial option is to just boot the standard installation kernel and initrd without any additional kernel parameter, and select from the inital screen the Start shell entry.\nThis is the network console for the Debian installer. From here, you may start the Debian installer, or execute an interactive shell.\nTo return to this menu, you will need to log in again.\n[!!] Configuring d-i\nNetwork console option:\nStart installer Start installer (expert mode) Start shell\nThe functionality in the debian-installer shell is limited, however, it can still act as a rescue system to fix a broken installation. While not using the rescue mode, be careful to not accidentially repartition or format any disk which may cause data loss.\nIn either case, after you exit the shell, the system will reboot.\nFinally, note that repairing broken systems can be difficult, and this manual does not attempt to go into all the things that might have gone wrong or how to fix them. If you have problems, consult an expert.\n81"}]}
+{"image": "doclay/doclay_58120.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "144 / PART TWO: ENGLISH IN ACTIONFig. 20. Handwritten letter to a local newspaper."}]}
+{"image": "doclay/doclay_13887.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "\nBOBBI BROWN\nLA MER\nM . A . C\nORIGINS\nPRESCRIPTIVES\n03\nIntroduced in 1979 . Sold in ten countries and territories . Select products: Traceless Skin Responsive Tint, False Eyelashes Plush Mascara, Super Line Preventor+, Dermapolish, GLYPH<H22810> magic by Prescriptives and Virtual Youth Lifting Moisture Makeup . Afoundation authority that celebrates women of all skins and all ages with its Colorprinting system, Prescriptives is known for its Custom Beauty approach and technologically innovative skin care and makeup lines.\nIntroduced in 1990 . Sold in more than 25 countries and territories . Select products:  APerfect World White tea skin guardian, Have a Nice Day Super-charged moisture cream and lotion SPF 15, Ginger Souffle Whipped body cream and A Perfect World Intensely hydrating body cream with White Tea . Afeel-good alternative to traditional health and beauty, featuring multi-sensory skin care, color, bath and body, fragrance, hair care products and lifestyle accessories.\nMajority interest acquired in 1994; acquisition completed in 1998 . Sold in more than  45 countries and territories . Select products: Studio Fix Powder Plus Foundation, M . A . C Paints, M . A . C Lipstick in seven formulas and Lipglass  . Abroad line of color-oriented cosmetics, makeup tools, skin care, foundations, fragrances and accessories targeting professional makeup artists and fashion-conscious consumers. M . A . C: All races, All ages, All sexes.\nAcquired in 1995 . Sold in more than 30 countries and territories . Select products: Crème de la Mer, The Face Serum, The Eye Balm, The Concentrate and La Mer SkinColor . An exclusive and highly sought-after treatment line combining the finest ingredients with a unique scientific process. In 1999, La Mer expanded from the original, best-selling Crème de la Mer into a complete range of facial skin care and body products.\nAcquired in 1995 . Sold in more than 30 countries and territories . Select products: Foundation Stick, Creamy Concealer Kit, Lip Color, Lip Gloss, Shimmer Brick Compact, Bobbi Brown Extra, Long-Wear Gel Eyeliner and Bobbi Brown Beach  . Aprofessional beauty line developed by celebrated makeup artist Bobbi Brown, encompassing color cosmetics, skin care,professional makeup brushes, accessories and fragrance."}]}
+{"image": "doclay/doclay_39229.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "5 \n1  Scope of the procurement \n1.1  Contracting authority \nEUOSHA/2021/OP/F/SE/0142 This call for tender is launched and managed by the European Agency for Safety and Health at Work  (EU-OSHA), referred to as the  contracting authority  for the purposes of this call for tender. \nEU-OSHA is an agency of the European Union (EU) and is one of the decentralised Community bodies.  Its central role is to contribute to the promotion of safer, healthier and more productive workplaces by  developing, analysing and disseminating information on occupational safety and health (OSH). \nAs a tripartite organisation, EU-OSHA works closely with governments and employers’ and workers’  representatives to share good practice and to reach workers and workplaces across Europe. \nEU-OSHA’s main safety and health information network is made up of focal points in each EU Member  State and in candidate, potential candidate and European Economic Area (EEA) countries. A country’s  focal point is normally the national OSH authority; the focal points represent EU-OSHA and support its  activities, such as the Healthy Workplaces Campaigns (HWCs). \nLocated in Bilbao, Spain, EU-OSHA has a dedicated staff of safety and health and communication  specialists and a network of partners in all Member States and beyond. As well as running Europe-wide  information campaigns, EU-OSHA also publishes scientific research in print and online media. \nMore information can be found at https://osha.europa.eu/en. \nThe subject of this call for tender is the provision of communication and event services. \n1.2  Subject\n1.3  Time schedule for this tender \nTask  Date  Comments  Launch date  26/04/2021  eTendering  Deadline for request of clarifications  from EU-OSHA  Six working days before deadline  eTendering  Deadline for submission of tenders 14/06/2021 13:00  Opening  15/06/2021 15:00  Date for evaluation of tenders  From 21/06/2021 (lot 1)  From 06/07/2021 (lot 2)  From 07/07/2021 (lot 3)  Estimated  Notification of award(s) to the selected tenderer(s)  September 2021 at the latest  Estimated  Framework contract(s) signature  September 2021  Estimated \n"}]}
+{"image": "doclay/doclay_7004.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Our strategy of expanding selectively and strategically  is working, allowing us to build upon our existing strengths. Expansion in recent years gives us a presence in many of the affluent, fast-growing markets in the United States and complements our national distribution in Canada. Our focus now is on executing our strategy, leveraging our acquisitions to meet our financial performance objectives and delivering results that reach our financial targets.\nIn recent years, we have created an organization that is differentiated as much by the synergies that exist between its complementary businesses as by the uniqueness of its parts. \nThat greater alignment has enabled us to leverage our rep- utation as a trusted advisor. We have in place the breadth of offering and the organizational infrastructure to provide our clients with products and services that are tailored  to their objectives. We can meet people’s financial needs whether they want to build a business, develop a retirement plan or put their kids through school. We have the desire – and the ability – to serve people exceedingly well. That’s always been the secret behind companies that have suc- ceeded in creating great value over a long period of time.\nWe have clear strategies in each of our businesses, and we are dedicated to the successful execution of those strate- gies. To achieve our objectives, the vital role of people must be fully considered in all our strategic  decision- making and implementation plans.\nWith that in mind, we have focused our people strategies on three objectives. We want to make sure that we have top talent in our key roles and throughout our organization.  We want to create a high-performance culture, one whose effectiveness we can measure. And we want to foster an engaged and motivated workforce.\nDespite the uncertain markets of recent years, the  outlook for the wealth management business is very favourable. Our long-standing experience and our recent expansion position us to benefit from the substantial growth we expect.\nThe largest ever demographic group, the baby boom gener- ation, is shifting from consumption to savings, providing significant opportunities for growth in financial services over the next two decades. More than a century of experi- ence in full-service investing and private banking, as well as our leading position in direct investing, give us a solid foundation in the wealth management business.\nBMO FINANCIAL GROUP ANNUAL REPORT 2002 5\nGILLES G. OUELLETTE President and Chief Executive Officer, Private Client Group, BMO Financial Group  and Deputy Chair, BMO Nesbitt Burns\nROSE M. PATTEN Executive Vice-President, Human Resources  and Head, Office of Strategic Management\nWILLIAM A. DOWNE Deputy Chair, BMO Financial Group  and Chief Executive Officer, BMO Nesbitt Burns \n"}]}
+{"image": "doclay/doclay_77577.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "An improper fraction is a fraction in which the numerator is  equal to or larger than the denominator. For example,  4 ⁄ 4 or  15 ⁄ 8 are examples of improper fractions. \nTo add or subtract fractions, they must have a common  denominator. In math, the least common denominator (LCD)  is generally used. One way to find the LCD is to list the  multiples of each denominator and then choose the smallest  number that they all have in common (can be divided by). \nMultiples of 5 are: 5, 10, 15, 20, 25, and so on. Multiples of  10 are: 10, 20, 30, 40, and so on. Notice that 10, 20, and 30  are in both lists, but 10 is the smallest or LCD. The advantage  of finding the LCD is that the final answer should be in the  simplest form. \nA common denominator can also be found for any group of  fractions by multiplying all the denominators together. This  number is not always the LCD, but it can still be used to add  or subtract fractions. \nExample: Add  2 ⁄ 3 +  3 ⁄ 5 +  4 ⁄ 7 by finding a common denominator. \nA common denominator can be found by multiplying the  denominators 3 × 5 × 7 to get 105.\nIn order to add fractions, the denominators must be the same  number. This is referred to as having “common denominators.” \nExample: Add  1 ⁄ 7 to  3 ⁄ 7 \nIf the fractions do not have the same denominator, then one or  all the denominators must be changed so that every fraction  has a common denominator. \nExample: Find the total thickness of a panel made from  3 ⁄ 32-inch thick aluminum, that has a  1 ⁄ 64-inch thick paint  coating. To add these fractions, determine a common  denominator. The LCD for this example is 1, so only the  first fraction must be changed since the denominator of the  second fraction is already in 64ths. \nExample: \nThe use of cancellation when multiplying fractions is a  helpful technique. Cancellation divides out or cancels all  common factors that exist between the numerators and  denominators. When all common factors are cancelled before  the multiplication, the final product is in the simplest form. \nExample: \nMultiplication of fractions does not require a common  denominator. To multiply fractions, first multiply the  numerators. Then, multiply the denominators. \nTherefore,  27 ⁄ 40 is the minimum droop. \nExample: The tolerance for rigging the aileron droop of an  airplane is  7 ⁄ 8 inch ±  1 ⁄ 5 inch. What is the minimum droop to  which the aileron can be rigged? To subtract these fractions,  first change both to common denominators. The common  denominator in this example is 40. Change both fractions to  1 ⁄ 40, as shown, then subtract. \nIf the fractions do not have the same denominator, then one or  all the denominators must be changed so that every fraction  has a common denominator. \nExample: Subtract  2 ⁄ 17 from  10 ⁄ 17 \nTo subtract fractions, they must have a common denominator. \nTherefore,  7 ⁄ 64 is the total thickness. \n15 2  1  ( 14  15  ×  3  ) =  ( 14  7  ×  3  ) =  ( 2 × 1 ) =  7 5 × 1  2  5  5  1 \n3  7  1  3 × 7 × 1  21 ×  ×  =  =  5  8  2  5 × 8 × 2  80 \n( 7  1 ) = ( 7 × 5  1 × 8 ) = ( 35  8  ) = ( 35 – 8 )  27  –  –  –  =  8  5  8 × 5  5 × 8  40  40  40  40 \n10  2  10 – 2  8  –  =  =  17  17  17  17 \n( 3  1  ) = ( 3 × 2  1  ) = ( 6  1  ) = ( 6 + 1 ) =  7 +  +  +  32  64  32 × 2  64  64  64  64  64 \n( 2  3  4  ) = ( 70  63  60  ) =  193  = 1  88 +  +  +  +  3  5  7  105  105  105  105  105 \n1  3  1 + 3  4 +  =  =  7  7  7  7 \nExample: Add  1 ⁄ 5 +  1 ⁄ 10 by finding the LCD. \nFinding the Least Common Denominator \nSubtraction of Fractions \nMultiplication of Fractions \nAddition of Fractions \n3-3 "}]}
+{"image": "doclay/doclay_69947.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "app-logging-elk-client-868db5cbd9-6mhjl 1/1 Running 0 1h app-logging-elk-data-0 1/1 Running 0 1h app-logging-elk-elasticsearch-pki-init-78bzt 0/1 Completed 0 1h app-logging-elk-kibana-86df58d79d-wfgwx 1/1 Running 0 1h app-logging-elk-kibana-init-m9r92 0/1 CrashLoopBackOff 22 1h app-logging-elk-logstash-68f996bc5-92gpd 1/1 Running 0 1h app-logging-elk-master-6c64857b5b-x4j9b 1/1 Running 0 1h\nTip:  If the kibana-init pod fails, it’s because it co uld not initialize the default index in Kibana.  This is not a problem, as the default index can be set through the Kibana UI.\nThis will display the Kibana dashboard. See Figure 5-28.\nhttp://<proxy-ip>:<nodeport>\nThe default Logstash configuration forwards all log data to an index in the format  logstash-<year-month-day> . Whilst this is suitable for the platform logs, it makes sense for  additional ELK stacks, designed to collect logs for specific namespaces, to create indices  based on the namespace the logs originate from. This can be achieved by editing the  Logstash ConfigMap and modifying the output to use the kubernetes namespace field as the  index name instead of the default  logstash . To do this for the ELK stack deployed in previous  sections, edit the  app-logging-elk-logstash-config  ConfigMap in the  elk  namespace and  change the  output.elasticsearch.index  section from\n6. Retrieve the NodePort for the Kibana service:\n7. Use the returned port to access Kibana via an IBM Cloud Private node. For example using  the proxy\nkubectl -n elk get service kibana  -o=jsonpath='{.spec.ports[?(@.port==5601)].nodePort}'Figure 5-28 New Kibana user interface\n8. Set the default index to whichever value you choose. The default is  logstash-  but this may  change depending on how you modify Logstash in this instance. Note that it is not possible  to set the default index until data with that index actually exists in Elasticsearch, so before  this can be set, ensure log data is sent to Elasticsearch first.\nConfiguring namespace based indices\noutput { elasticsearch { hosts => \"elasticsearch:9200\" index => \"logstash-%{+YYYY.MM.dd}\" document_type => \"%{[@metadata][type]}\"\n196  IBM Cloud Private System Administrator’s Guide"}]}
+{"image": "doclay/doclay_17765.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "SUPPLEMENTARY INFORMATION\nPORTFOLIO\nPower\nUtilities\nType of Facility Province Year Built Ownership Interest Total Net Capacity (MW) PPA Counterparty PPA Expiry Fuel Supply Counterparty Fuel Supply Expiry Employees Gas Cogeneration Cardinal ON 1994 100% 156 OPA 2014 Husky 2015 18 Wind Operating ON 2002 - 2009 100% 121 OPA 2021 - 2032 n/a n/a 10 NS 2006 - 2012 49% - 100% 74 NSPI 2021 - 2037 n/a n/a 1 Development ON 2015 - 2016E 50% - 100% 57 OPA 2034 n/a n/a n/a PQ 2014E 51% 12 Hydro Quebec 2034 n/a n/a n/a SK 2016E 100% 10 SaskPower 2035 n/a n/a n/a Biomass (1) Whitecourt AB 1994 100% 32.8 TransAlta 2014 Millar Western 2016 34 Hydro Sechelt and Hluey Lakes BC 1997 and 2000 100% 19 BC Hydro 2017 and 2020 n/a n/a n/a Wawatay and Dryden ON 1992 and 1986 100% 17 OEFC 2020 and 2042 n/a n/a n/a Solar Amherstburg ON 2011 100% 20 OPA 2031 n/a n/a n/a\nBusiness Ownership Interest Capacity Counterparties Length of Network Approximate Population Served Regulated Employees Värmevärden 33.3% Heat production capacity of 639 MWth Mix of industrial and retail customers. 317 kilometres 163,000 No 89 Bristol Water 50% Average daily supply of 266 million litres Mix of commercial and residential customers. 6,671 kilometres 1.2 million Ofwat 547\n(1) Biomass includes Capstone's 31.3% equity accounted interest in Chapais.\n2013 ANNUAL REPORT  101"}]}
+{"image": "doclay/doclay_54191.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Server System Variable Reference\nName Cmd-Line Option File System Var Var Scope Dynamic keyring_hashicorp_ca_path Yes Yes Yes Global Yes keyring_hashicorp_caching Yes Yes Yes Global Yes keyring_hashicorp_commit_auth_path Yes Global No keyring_hashicorp_commit_ca_path Yes Global No keyring_hashicorp_commit_caching Yes Global No keyring_hashicorp_commit_role_id Yes Global No keyring_hashicorp_commit_server_url Yes Global No keyring_hashicorp_commit_store_path Yes Global No keyring_hashicorp_role_id Yes Yes Yes Global Yes keyring_hashicorp_secret_id Yes Yes Yes Global Yes keyring_hashicorp_server_url Yes Yes Yes Global Yes keyring_hashicorp_store_path Yes Yes Yes Global Yes keyring_oci_ca_certificate Yes Yes Yes Global No keyring_oci_compartment Yes Yes Yes Global No keyring_oci_encryption_endpoint Yes Yes Yes Global No keyring_oci_key_file Yes Yes Yes Global No keyring_oci_key_fingerprint Yes Yes Yes Global No keyring_oci_management_endpoint Yes Yes Yes Global No keyring_oci_master_key Yes Yes Yes Global No keyring_oci_secrets_endpoint Yes Yes Yes Global No keyring_oci_tenancy Yes Yes Yes Global No keyring_oci_user Yes Yes Yes Global No keyring_oci_vaults_endpoint Yes Yes Yes Global No keyring_oci_virtual_vault Yes Yes Yes Global No keyring_okv_conf_dir Yes Yes Yes Global Yes keyring_operations Yes Global Yes language Yes Yes Yes Global No large_files_support Yes Global No large_page_size Yes Global No large_pages Yes Yes Yes Global No last_insert_id Yes Session Yes lc_messages Yes Yes Yes Both Yes lc_messages_dir Yes Yes Yes Global No lc_time_names Yes Yes Yes Both Yes license Yes Global No local_infile Yes Yes Yes Global Yes lock_order Yes Yes Yes Global No lock_order_debug_loop Yes Yes Yes Global No\n702"}]}
+{"image": "doclay/doclay_8403.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "66\nMARKETS WE SERVE\nNEWSPAPERS AND NEWSPAPER DIVISION\nDaily newspapers State Circulation Joined Territory City Newspaper Morning Afternoon Sunday Founded Gannett ▲ Alabama Montgomery Montgomery Advertiser 52,068 64,598 1829 1995 (62) Arizona Phoenix The Arizona Republic 472,416 577,744 1890 2000 (91) Tucson Tucson Citizen 38,123 1870 1976 (30)  Arkansas Mountain Home The Baxter Bulletin 11,291 1901 1995 (63) California Palm Springs The Desert Sun 52,824 55,562 1927 1986 (56) Salinas The Californian 18,896 1871 1977 (36) Tulare Tulare Advance-Register 8,121 1882 1993 (61) Visalia Visalia Times-Delta 21,396 1859 1977 (37) Colorado Fort Collins Fort Collins Coloradoan 28,965 35,770 1873 1977 (38) Connecticut Norwich Norwich Bulletin 27,413 32,796 1791 1981 (49) Delaware Wilmington The News Journal 121,399 141,815 1871 1978 (43) Florida Brevard County FLORIDA TODAY 86,425 108,879 1966 1966  (9) Fort Myers The News-Press 89,567 107,522 1884 1971 (24) Pensacola Pensacola News Journal 63,351 80,954 1889 1969 (11) Georgia Gainesville The Times 20,343 24,429 1947 1981 (48) Guam Hagatna Pacific Daily News 21,207 19,851 1944 1971 (23) Hawaii Honolulu The Honolulu Advertiser 145,594 176,387 1856 1993 (60) Idaho Boise The Idaho Statesman 65,600 87,640 1864 1971 (16)\nADDITIONAL OPERATIONS Newspapers Guam Hawaii Newsquest plc United Kingdom (see page 70) USAT Print Sites Belgium United Kingdom Germany Hong Kong  Italy ■ DAILY NEWSPAPERS ● USAT PRINT SITES ★ GNS BUREAUS ▼ TELEVISION STATIONS"}]}
+{"image": "doclay/doclay_34642.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "The integrand is a holomorphic function whereas the factor Z − 1 / 2 X is real. Therefore, due to the non- renormalization theorem [15, 16], there is no quantum correction in the second line in (6). This means that w$_{a}$ does not receive any quantum correction at all scales. On the other hand, the integrand of the first term in (6) is not a holomorphic function and therefore the coefficients k$_{i}$ are renormalized by the visible sector gauge interac- tions and the hidden sector coupling λ in (5). They then satisfy the RGE\n∑ The second term is the leading visible sector contribution. In the first term γ ( t ) is the anomalous dimension at t = ln( µ/M ) arising from the hidden sector interactions (5). The anomalous dimension in the lowest order in λ is\nwhere λ ( t ) is the running hidden sector Yukawa coupling which renormalizes according to\nThe RGE (8) are solved as\n∑ Using this expression, the scalar masses of the visible sector including the RG effects are described by\nwith\n∑ Here the gauge couplings run according to the standard 1-loop formula,\n   α$_{a}$ ( M$_{Z}$ ) − 2 π b$_{a}$ ln M$_{Z}$ , ( µ ≤ M$_{S}$ ) where ( b S $_{1}$, b S $_{2}$, b S $^{$_{3}$) = (}$− 3 , 1 , 33 / 5) for the MSSM and ( b$_{1}$, b$_{2}$, b$_{3}$ $^{) = (}$−7 $^{,}$− 19 / 6 , 41 / 10) for the standard model gauge couplings. M$_{Z}$ and M$_{S}$ are the Z -boson mass and a typical soft mass scale, respectively.\n1 α$_{a}$ ( µ ) =      1 α$_{a}$ ( M$_{Z}$ ) − 1 2 π b$_{a}$ ln M$_{S}$ M$_{Z}$ − 1 2 π b S a ln µ M$_{S}$ , ( µ > M$_{S}$ ) 1 α$_{a}$ ( M$_{Z}$ ) − 1 2 π b$_{a}$ ln µ M$_{Z}$ , ( µ ≤ M$_{S}$ ) (14) where ( b S $_{1}$, b S $_{2}$, b S $^{$_{3}$) = (}$− 3 , 1 , 33 / 5) for the MSSM and\nm 2 $_{i}$( t ) = k$_{i}$ ( t )Λ $^{2}$, (12)\nk$_{i}$ (0) = 2 3 ∑ a =1 ( α$_{a}$ ( M ) 4 π ) 2 C a $_{2}$( R$_{i}$ ) . (13) Here the gauge couplings run according to the standard\nk$_{i}$ ( t ) = exp ( − ∫ 0 t dt $^{′}$γ ( t $^{′}$) ) k$_{i}$ (0) (11) + 1 16 π 2 3 ∑ a =1 8 C a $_{2}$( R$_{i}$ ) ∫ 0 t dsg 6 $_{a}$( s ) exp ( − ∫ s t dt $^{′}$γ ( t $^{′}$) ) G$_{a}$. Using this expression, the scalar masses of the visible\ndλ ( t ) dt = 3 8 π $_{2}$λ$^{3}$( t ) . (10)\nγ ( t ) = λ ( t ) λ $^{†}$( t ) 2 π 2 , (9)\nd dt k$_{i}$ ( t ) = γ ( t ) k$_{i}$ ( t ) − 1 16 π 2 3 ∑ a =1 8 C a $_{2}$( R$_{i}$ ) g 6 $_{a}$( t ) G$_{a}$, G$_{a}$ ≡ w$_{a}$w † $_{a}$. (8) The second term is the leading visible sector contribution.\n3\n2 4 6 8 10 12 100 150 200 250 300 350 400 log$_{10}$ GLYPH<LBracket1> Μ GLYPH<Slash1> GeV GLYPH<RBracket1> Mass GLYPH<LBracket1> GeV GLYPH<RBracket1>\nFIG. 1: The slepton mass RG flows with and without the hidden sector effects. The upper curves (black and blue) are the left-handed, and the lower curves (red and orange) are the right-handed sleptons. The 1st and the 3rd generations are respectively indicated by the solid and the dashed curves. The curves with sharp decline (blue and orange) above the hidden scale M hid = 10 8 . 5 GeV (indicated by the vertical dotted line) are the flows including the hidden sector effects. The straight lines (black and red) are the flows without the hidden sector effects. We have chosen M = 10 12 GeV, λ = 3 . 8 and tan β = 10.\nIII. THE HIDDEN SECTOR RENORMALIZATION GROUP FLOW\nWe shall be interested in the low energy mass spec- tra, in particular determination of the NLSP. The hid- den sector renormalization affects the mass RG flows be- tween the messenger scale µ = M and the hidden scale µ = M$_{hid}$ . Eq. (8) implies that the RGE for the MSSM soft scalar masses are modified as,\nwhile those for the other masses and couplings are un- altered (see, for example, [17]). Below the hidden scale, the hidden sector fields are integrated out and all the masses and the couplings evolve according to the stan- dard MSSM RGE. The low energy mass spectrum is ob- tained by integrating the RGE, from the messenger scale to the hidden scale with the hidden sector effects (15) included, and then down to the electroweak scale in the standard way. In this section we present numerical study of the MSSM RGE including the hidden sector effects at one-loop order. The non-standard parts of the RGE are listed in Appendix A.\nIn our computations we made following approxima- tions. For simplicity only the (3 , 3) family component of the three Yukawa matrices, and only the (3 , 3) family component of the trilinear A-term matrices, are set to be non-zero. The latter are set to vanish at the messenger scale. Throughout our analysis we use following values: tan β = 10, the soft mass scale M$_{S}$ = 500 GeV, and\ndm 2 i dt → dm 2 i dt + λλ † 2 π $_{2}$m 2 $_{i}$, (15)"}]}
+{"image": "doclay/doclay_39176.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "1 INFORMATION ON TENDERING \n1.1 Participation \n1.2 Contractual conditions\n5 \nThe European Centre for Disease prevention and Control (ECDC) is an agency of the European Union,  established by the European Parliament and Council Regulation 851/2004 of 21 April 2004. Further  information about ECDC can be found on the ECDC website www.ecdc.europa.eu. \nThis tender process is governed by Directive 2014/24/EU and Regulation 2018/1046. \nParticipation in this procurement procedure is open on equal terms to all natural and legal persons coming  within the scope of the Treaties, as well as to international organisations, established in the European  Union, European Economic Area and Stabilisation and Association Agreements countries. \nFor economic operators established in the United Kingdom (UK): please be aware that as from 1 February  2020, the UK became a third country and the transition period ended on 31 December 2020. Based on the  status of the UK as a third country, the rules of access to EU procurement procedures of economic  operators established in third countries will apply to tenderers from the UK. Tenderers established in third  countries do not have access to ECDC’s procurements and will be rejected as ineligible. \nPlease note that any attempt by a tenderer to obtain confidential information, enter into unlawful  agreements with competitors or influence the evaluation committee or ECDC during the process of  examining, clarifying, evaluating and comparing tenders will lead to the rejection of his tender and may  result in administrative penalties.\nThe tenderer should take note of the provisions of the draft contract (see section 4. Annexes) which  specifies the rights and obligations of the contractor, particularly those on payments, performance of the  contract, confidentiality, intellectual property rights and checks and audits.\nSignature of the framework contract imposes no obligation on ECDC to order services. Only the  implementation of the framework contract through specific contracts/order forms is binding for ECDC. \nEach specific contract/order form will contain details of deliverables and timelines for particular services  to be provided. \nECDC wishes to conclude a single framework contract for each lot. \nThe article covering the implementation of the framework contract is described in the special conditions  of the draft Framework Contract (see section 4. Annexes). "}]}
+{"image": "doclay/doclay_75524.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "CORPORATE GOVERNANCE\n7\nOther information concerning the Corporate Offi cers and Senior Management of the Company\n7.2 Other information concerning  the Corporate Officers and Senior  Management of the Company\nFamily relationships within the Board of Directors are  as follows:\nTo the best of the Company’s knowledge, no transactions  in Company shares were carried out in Fiscal 2013 by  management and persons concerned by article L.621-18- 2 of the French Monetary and Financial Code (article 223- 26 of the AMF’s General Rules).\nNo loans or guarantees have been made or given to either  members of the Board of Directors or Senior Management  by Sodexo or by any Group company.\nNo assets necessary for the Group’s operations are owned  by either members of the Board of Directors or Senior  Management or by their families.\n• Bernard Bellon (director) is the brother of Pierre Bellon. There are no other family relationships between members  of the Board of Directors and members of the Executive  Committee of Sodexo.\nThere are no potential conflicts of interest between the  duties to Sodexo of members of the Board of Directors  or Senior Management and their private interests. In  particular:\nSodexo has put in place a series of measures in order to  ensure that the control over the Company is not exercised  in an abusive manner. Examples of these measures  include:\nAs far as the Company is aware, no member of the Board  of Directors or of the senior management has during the  past five years been:\nCONTROLLING SHAREHOLDER  MEASURES\n• prohibited by a court to act as a Board member, a  Supervisory Board member, or a member of senior  management of an issuer, or to participate in the  management or business affairs of an issuer.\n• Astrid Bellon, Sophie Bellon, Nathalie Szabo and  François-Xavier Bellon (directors) are the children of  Pierre Bellon, Chairman of the Board of Directors;\n• Pierre Bellon and his four children control 68.5% of  Bellon SA (with agreements preventing them from  selling their shares to third parties), which in turn holds  37.71% of the share capital of Sodexo and 50.91% of  the voting rights; Pierre Bellon and his children created  a 50-year  Société en Participation  (joint venture) in  2008 to prevent direct descendants of Pierre Bellon  from freely disposing of their Bellon SA shares;\n• Bernard Bellon, with other members of his family,  holds 13% of the shares of Bellon SA.\n(a)  the presence of six independent directors among the  thirteen members of the Board of Directors as of  August 31, 2013;\n(b) the existence of three Board Committees that include  independent directors among their members;\n(c) the separation of the roles of Chairman of the Board  and Chief Executive Officer. Effective September 1,  2005, Michel Landel – neither a member of Pierre  Bellon’s family, nor a corporate offi cer of Bellon SA –  succeeded Pierre Bellon as Chief Executive Officer of  Sodexo. Pierre Bellon remained as Chairman of the  Board;\n(d)  the disclosures within this document of the  relationship between Sodexo and Bellon SA:\n• these include the ownership interest of Bellon SA in  Sodexo (changes in which are disclosed in section  5.1.2.4  of this document),\n• further, since 1991 a service agreement between  Bellon SA and Sodexo has been in operation (this  agreement is described below in the paragraph  concerning regulated related-party agreements).  The fees payable under this agreement and changes  in these fees are reviewed annually by the Audit  Committee.\n• convicted of fraud;\n• associated with a bankruptcy, receivership or  liquidation;\n• offi cially incriminated and/or subject to any official  public sanction issued by a statutory or regulatory  authority;\nSodexo  - Registration Document Fiscal 2013 302"}]}
+{"image": "doclay/doclay_66723.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "SECTION  1268 . Excess of Net Earnings — Disposition . — The net earnings of the bank in excess of its expenses and the amount required to maintain the postal savings bank reserve fund shall, with the approval of the board, be used to increase the rate of int erest paid to depositors and for no other purpose.\n[1493-20.]\nSECTION  1272 . Chief Officials of Bureau of Labor . — The Bureau of Labor shall have one chief and one assistant chief, designated, respectively, as the Director of Labor and the Assistant Director of Labor.\n[1868-4; 1966-1.]\nSECTION  1273 . Duties and Functions of Bureau of Labor. —  The Bureau of Labor shall have the power, and it shall be its duty — cIaCTS\nCHAPTER  36\nBureau of Labor\n( a ) To see to the proper enforcement of all laws relating to labor and capital in the Philippine Islands, and to promote the enactment of legislation which shall tend to establish the material, social, intellectual, and moral improvement of workers.\n( b ) To acquire, collect, compile, systematize, and submit from time to time reports to the Secretary of Commerce and Police, statistical data relative to the hours and wages of labor, the number of workers in each trade or occupation, employed and unemploy ed, their place of birth, age, sex, civil status, and moral and mental culture; the estimated number of families of married workers, houses rented by them, and annual rental; property owned by them, the value of such property; the cost of living, the amoun t of labor required, the estimated number of persons dependent on their daily wages, the probable changes in all the persons employed, the condition of shops, factories, railways, tramways, industrial and commercial establishments, and all other places or ce nters of labor, whether public or private, including the penal institutions of these Islands, with respect to the safety of life and health of workers; the means adopted to avoid accidents or make reparation therefor; the number of accidents which take p lace, their causes and the action taken in\n[1868-2 ( a ); 1966-1.]\n374\nCopyright 2012 CD Technologies Asia, Inc. and Accesslaw, Inc. Philippine Law Encyclopedia 2011"}]}
+{"image": "doclay/doclay_56135.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "UCI CYCLING REGULATIONS \nChapter III EQUIPMENT ............................................................................................56$_{ }$ Section 1: general provisions ......................................................................................56$_{ }$ § 1$_{ }$ Principles ...........................................................................................................56$_{ }$ § 2$_{ }$ Technical innovations.........................................................................................57$_{ }$ § 3$_{ }$ Commercialisation..............................................................................................58$_{ }$ Section 2: bicycles.......................................................................................................58$_{ }$ § 1$_{ }$ Principles ...........................................................................................................58$_{ }$ § 2$_{ }$ Technical specifications .....................................................................................59$_{ }$ Section 3: riders' clothing ............................................................................................72$_{ }$ § 1$_{ }$ General provisions .............................................................................................72$_{ }$ § 2$_{ }$ Teams registered with the UCI ...........................................................................74$_{ }$ § 3$_{ }$ Regional and club teams....................................................................................75$_{ }$ § 4$_{ }$ Leaders' clothing ................................................................................................76$_{ }$ § 5$_{ }$ National team clothing........................................................................................77$_{ }$ § 6$_{ }$ World champion's jersey ....................................................................................78$_{ }$ § 7$_{ }$ National champion's jersey.................................................................................80$_{ }$ § 8$_{ }$ Continental champion's jersey............................................................................81$_{ }$ § 9$_{ }$ Order of priority ..................................................................................................81$_{ }$ § 10$_{ }$ Sanctions ...........................................................................................................81$_{ }$ Section 4: identification of riders..................................................................................83$_{ }$ Annexe A UCI LIST OF AUTHORISED BETS ...........................................................85$_{ }$\nE0221 \nGENERAL ORGANISATION OF CYCLING AS A SPORT \n2 "}]}
+{"image": "doclay/doclay_46074.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Figure 1-9.  The De Havilland Mosquito used a laminated wood  construction with a balsa wood core in the fuselage.\nFigure 1-10.  The nearly all composite Cessna Citation Mustang  very light jet (VLJ).\nperformance surfaces. Variable contour wings became easier  to construct. Increases in flight speed accompanying jet travel  brought about the need for thinner wings. Wing loading also  increased greatly. Multispar and box beam wing designs were  developed in response.\nIn the 1960s, ever larger aircraft were developed to carry  passengers. As engine technology improved, the jumbo jet  was engineered and built. Still primarily aluminum with a  semimonocoque fuselage, the sheer size of the airliners of  the day initiated a search for lighter and stronger materials  from which to build them. The use of honeycomb constructed  panels in Boeing’s airline series saved weight while not  compromising strength. Initially, aluminum core with  aluminum or fiberglass skin sandwich panels were used on  wing panels, flight control surfaces, cabin floor boards, and  other applications. \nA steady increase in the use of honeycomb and foam core  sandwich components and a wide variety of composite  materials characterizes the state of aviation structures from  the 1970s to the present. Advanced techniques and material  combinations have resulted in a gradual shift from aluminum  to carbon fiber and other strong, lightweight materials. These  new materials are engineered to meet specific performance  requirements for various components on the aircraft. Many  airframe structures are made of more than 50 percent  advanced composites, with some airframes approaching  100 percent. The term “very light jet” (VLJ) has come to  describe a new generation of jet aircraft made almost entirely  of advanced composite materials.  [Figure 1-10]  It is possible  that noncomposite aluminum aircraft structures will become  obsolete as did the methods and materials of construction  used by Cayley, Lilienthal, and the Wright Brothers. \nThe most common aircraft is the fixed-wing aircraft. As  the name implies, the wings on this type of flying machine  are attached to the fuselage and are not intended to move  independently in a fashion that results in the creation of lift.  One, two, or three sets of wings have all been successfully  utilized.  [Figure 1-12] Rotary-wing aircraft such as  helicopters are also widespread. This handbook discusses  features and maintenance aspects common to both fixed- wing and rotary-wing categories of aircraft. Also, in certain  cases, explanations focus on information specific to only  one or the other. Glider airframes are very similar to fixed- wing aircraft. Unless otherwise noted, maintenance practices  described for fixed-wing aircraft also apply to gliders. The  same is true for lighter-than-air aircraft, although thorough \nThe concentration of this handbook is on the airframe of  aircraft; specifically, the fuselage, booms, nacelles, cowlings,  fairings, airfoil surfaces, and landing gear. Also included are  the various accessories and controls that accompany these  structures. Note that the rotors of a helicopter are considered  part of the airframe since they are actually rotating wings.  By contrast, propellers and rotating airfoils of an engine on  an airplane are not considered part of the airframe.\nAn aircraft is a device that is used for, or is intended to be used  for, flight in the air. Major categories of aircraft are airplane,  rotorcraft, glider, and lighter-than-air vehicles.  [Figure 1-11] Each of these may be divided further by major distinguishing  features of the aircraft, such as airships and balloons. Both  are lighter-than-air aircraft but have differentiating features  and are operated differently.\nGeneral\n1-5"}]}
+{"image": "doclay/doclay_33060.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "FIG. 3:\n17\n0 10 20 30 40 50 60 70 k$_{S}$ 10 0 10 1 10 2 k B C A Randomized CNI Original CNI c\n"}]}
+{"image": "doclay/doclay_1773.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "(2000)), the effect of funds for low-ability pupils (Haan (2012)), the impact of the National School Lunch Program on children’s health (Gundersen et al. (2011)), and various medical treatments (Bhattacharya et al. (2005, 2012)). Researchers sometimes have plausible information on the shape of treatment response functions from economic theory or from empirical results in previous studies. For example, based on di- minishing marginal returns to production, one may find it plausible to assume that the marginal effect of improved maize seed adoption on productivity diminishes as the level of adoption increases, holding other inputs fixed. Also, one may want to assume that the marginal adverse effect of an additional cigarette on infant birth weight diminishes as the number of cigarettes increases as shown in Hoderlein and Sasaki (2013). In the empirical literature, concave treatment response has been assumed for returns to schooling (Okumura (2010)) and convex treatment response for the effect of education on smoking (Boes (2010)). 2\nA considerable amount of the literature has used the Roy model to describe people’s self-selection ranging from immigration to the U.S. (Borjas (1987)) to college entrance (Heckman et al. (2011)). Also, heterogeneity in treatment effects for unobservable subgroups defined by particular sets of potential outcomes has been of central interest in various empirical studies. Heterogeneous peer effects and tracking impacts (Duflo et al. (2011)) and heterogeneous class size effects (Ding and Lehrer (2008)) by the level of students’ performance, and the heterogeneity in smoking effects by potential infant’s birth weight (Hoderlein and Sasaki (2013)) have also been discussed in the literature focusing on heterogeneous average effects.\nI apply my method to an empirical analysis of the effects of smoking on infant birth weight. I propose an estimation procedure and illustrate the usefulness of my approach by showing that MTR has a substantial identifying power for the distribution of smoking effects given marginal distributions. As a support restriction, I assume that smoking has nonpositive effects on infant birth weight. Smoking not only has a direct impact on infant birth weight, but is also associated with unobservable factors that affect infant birth weight. To overcome the endogenous selection problem, I make use of the tax increase in Massachusetts in January 1993 as a source of exogenous variation. I point-identify marginal distributions of potential infant birth weight with and without smoking for compliers, which indicate pregnant women who changed their smoking status from smoking to nonsmoking in response to this tax shock. To estimate the marginal distributions of potential infant birth weight, I use the instrumental variables (IV) method presented in Abadie et al. (2002). Furthermore, I estimate the DTE bounds using plug-in estimators based on the estimates of marginal distribution functions. As a by-product, I find that the average adverse effect of smoking is more severe for women with a higher tendency to smoke and that smoking women with some college and college graduates are less likely to give births to low birth weight infants than other smoking women.\nIn the next section, I give a formal description of the basic setup, notation, terms and assumptions\n$^{2}$All of these studies considered ATE or marginal distributions of potential outcomes only.\n4"}]}
+{"image": "doclay/doclay_72264.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Statements of Cash Flows\n(5) Included in Marketing and selling expenses.\n(4) In 2018, we recognized transaction costs of $53 related to the acquisition of Snyder's-Lance. See Note 4 for additional information.\n(3) In 2020, we recognized a loss of $64 on the sale of the European chips business. See Note 3 for additional information.\n(2) 2020 includes a loss of $45 related to Acre. See Note 16 for additional information.\n(1) See Note 6 for additional information.\n2020 2019 2018 Cash Flows from Operating Activities Other non-cash charges to net earnings Operating lease expense $ 75 $ —  $ —  Amortization of debt issuance costs/debt discount 9 14  4  Benefit related expense 12 6  8  Other 5 4  12  $ 101 $ 24  $ 24  Other Benefit related payments $ (53) $ (60) $ (59) Other (6) (4) 5  $ (59) $ (64) $ (54) Other Cash Flow Information Interest paid $ 287 $ 367  $ 152  Interest received $ 4 $ 3  $ 4  Income taxes paid $ 222 $ 117  $ 128  Non-cash Activity Build-to-suit lease commitment $ — $ 20  $ — \n83"}]}
+{"image": "doclay/doclay_65338.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Patent Application Publication \nJan. 23, 2014 Sheet 4 of 22 \nUS 2014/0021404 Al \nFIG.4 \n0  3Ji  :;:  ffl  lo.  I..  ffl  0  E  - 0  ffl  \"\"’  2J)•--------.,,  ----- 0  2  4  6  10 "}]}
+{"image": "doclay/doclay_43555.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "AIM\n8/15/19\nAppendix 1. Bird/Other Wildlife Strike Report\nBird/Other Wildlife Strike Report\nAppendix 1 − 1\n"}]}
+{"image": "doclay/doclay_24950.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "2.3 Multiscale Simplicial Flat Norm and Integer Lin- ear Programming\nThe problem of finding the multiscale simplicial flat norm of the d -chain t (Equation 2.5) can be cast formally as the following optimization problem.\nThe objective function is piecewise linear in the integer variables x and s . Using standard modeling techniques from linear optimization [7, pg. 18], we can reformulate the problem as the following integer linear program (ILP).\nThe objective function coefficients need to be nonnegative for this formulation to work – indeed, we have w$_{i}$, v$_{j}$ , and λ nonnegative. Integer linear programming is NP-complete [37]. The linear programming relaxation of the ILP above is obtained by ignoring the integer restrictions on the variables.\nmin ∑ m i $_{=1}$w$_{i}$ ( x + i + x − i ) + λ ( ∑ n j $_{=1}$v$_{j}$ ( s + j + s − j ) ) s.t. x + − x − = t − [ ∂$_{d}$$_{+1}$ ]( s + − s $^{−}$) x $^{+}$, x − ≥ 0 , s $^{+}$, s − ≥ 0 (2.9)\n23\nmin ∑ m i $_{=1}$w$_{i}$ ( x + i + x − i ) + λ ( ∑ n j $_{=1}$v$_{j}$ ( s + j + s − j ) ) s.t. x + − x − = t − [ ∂$_{d}$$_{+1}$ ]( s + − s $^{−}$) x $^{+}$, x − ≥ 0 , s $^{+}$, s − ≥ 0 x $^{+}$, x − ∈ Z $^{m}$, s $^{+}$, s − ∈ Z $^{n}$. (2.8)\nminimize ∑ m i $_{=1}$w$_{i}$ | x$_{i}$ | + λ ( ∑ n j $_{=1}$v$_{j}$ ∣ $_{∣}$s$_{j}$ ∣ $_{∣}$) subject to x = t − [ ∂$_{d}$$_{+1}$ ] s , x ∈ Z $^{m}$, s ∈ Z $^{n}$. (2.7)"}]}
+{"image": "doclay/doclay_49276.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "４ ＪＩＳ試験室において、ＪＩＳ試験通則２９．１及び２９．２ に定める振動試験を行つたとき、周期０．３秒、０．５秒及び０． ７秒のそれぞれにおいて、１９５センチメートル毎秒毎秒で加振し たとき、次の（１）又は（２）に掲げる条件に適合すること。ま た、いずれの場合も、消火するまでの間に異常燃焼しないこと。\n4 When a vibration test as specified in the General Rules for JIS  Tests 29.1 and 29.2 is conducted in a JIS Laboratory, and the  heater is vibrated at 195 centimeters per second per second with  each of the frequencies of 0.3 seconds, 0.5 seconds, and 0.7  seconds, the results comply with the conditions set forth in (1)  or (2) below, and no abnormal combustion occurs before the fire  is extinguished. \n（１） １０秒以内に消火装置が作動し、消火装置の作動後に１０ 秒以内で消火すること。\n(1) The fire extinguishing device is activated within 10 seconds,  and the fire is extinguished within 10 seconds after the fire  extinguishing device has been activated. \n（２） ポット式のものにあつては、１０秒以内に消火装置が作動 し、消火装置の作動後に瞬時に灯油を遮断し、５分以内に消火し、 かつ、ＪＩＳ試験通則３０．に定める落下可燃物の着火性試験によ つて、発炎着火しないこと。\n(2) In the case of a pot-type heater, the fire extinguishing device  is activated within 10 seconds, and the heating oil is cut off  instantly after the fire extinguishing device has been activated,  the fire is extinguished within five minutes, and no flaming or  ignition occurs in an ignition test of falling combustible material  as specified in the General Rules for JIS Tests 30. \n５ 圧力噴霧式のものにあつては、ＪＩＳ試験室において、ＪＩＳ 試験通則５２．に定める耐断火性試験を行つたとき、灯油の供給が 再開されたときに、自動的に燃焼を再開しないこと。\n5 In the case of a pressure-spray-type heater, when a flame  failure protection test as specified in the General Rules for JIS  Tests 52. is conducted in a JIS Laboratory, and the supply of  heating oil is resumed, the heater does not automatically  resume combustion. \n６（１） 届出事業者の氏名又は名称が容易に消えない方法により 表示されていること。ただし、届出事業者の氏名又は名称は、経済 産業大臣の承認を受けた略称若しくは記号又は経済産業大臣に届け 出た登録商標をもつて代えることができる。\n6 (1) The heater indicates the name of the Notifying Enterprise  in such a manner whereby it does not fade easily; provided,  however, that an abbreviated name or a mark for which the  approval of the Minister of Economy, Trade and Industry has  been obtained or a Registered Trademark which has been  notified to the Minister of Economy, Trade and Industry may be  indicated in lieu of the name of the Notifying Enterprise. \n62 "}]}
+{"image": "doclay/doclay_54009.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "mysql>  SELECT @@optimizer_switch\\G *************************** 1. row *************************** @@optimizer_switch: index_merge=on,index_merge_union=on, index_merge_sort_union=on,index_merge_intersection=on, engine_condition_pushdown=on,index_condition_pushdown=on, mrr=on,mrr_cost_based=on,block_nested_loop=on, batched_key_access=off,materialization=on,semijoin=on, loosescan=on, firstmatch=on, subquery_materialization_cost_based=on, use_index_extensions=on,condition_fanout_filter=on, derived_merge=on,use_invisible_indexes=off,skip_scan=on, hash_join=on,subquery_to_derived=off, prefer_ordering_index=on\nmysql>  SET optimizer_switch=’index_merge_union=off,index_merge_sort_union=off’; mysql>  SELECT @@optimizer_switch\\G *************************** 1. row *************************** @@optimizer_switch: index_merge=on,index_merge_union=off, index_merge_sort_union=off,index_merge_intersection=on, engine_condition_pushdown=on,index_condition_pushdown=on, mrr=on,mrr_cost_based=on,block_nested_loop=on, batched_key_access=off,materialization=on,semijoin=on, loosescan=on, firstmatch=on, subquery_materialization_cost_based=on, use_index_extensions=on,condition_fanout_filter=on, derived_merge=on,use_invisible_indexes=off,skip_scan=on, hash_join=on,subquery_to_derived=off, prefer_ordering_index=on\nSELECT /*+ NO_RANGE_OPTIMIZATION(t3 PRIMARY, f2_idx) */ f1 FROM t3 WHERE f1 > 30 AND f1 < 33; SELECT /*+ BKA(t1) NO_BKA(t2) */ * FROM t1 INNER JOIN t2 WHERE ...; SELECT /*+ NO_ICP(t1, t2) */ * FROM t1 INNER JOIN t2 WHERE ...; SELECT /*+ SEMIJOIN(FIRSTMATCH, LOOSESCAN) */ * FROM t1 ...; EXPLAIN SELECT /*+ NO_ICP(t1) */ * FROM t1 WHERE ...; SELECT /*+ MERGE(dt) */ * FROM (SELECT * FROM t1) AS dt; INSERT /*+ SET_VAR(foreign_key_checks=OFF) */ INTO t2 VALUES(2);\nAnother way to control the optimizer is by using optimizer hints, which can be specified within individual statements. Because optimizer hints apply on a per-statement basis, they provide finer control over statement execution plans than can be achieved using  optimizer_switch . For example, you can enable an optimization for one table in a statement and disable the optimization for a different table. Hints within a statement take precedence over  optimizer_switch  flags.\nExamples:\nOne means of control over optimizer strategies is to set the  optimizer_switch  system variable (see Section 8.9.2, “Switchable Optimizations” ). Changes to this variable affect execution of all subsequent queries; to affect one query differently from another, it is necessary to change  optimizer_switch  before each one.\nIf the server is using the Index Merge Union or Index Merge Sort-Union access methods for certain queries and you want to check whether the optimizer can perform better without them, set the variable value like this:\nWhen you assign a value to  optimizer_switch , flags that are not mentioned keep their current values. This makes it possible to enable or disable specific optimizer behaviors in a single statement without affecting other behaviors. The statement does not depend on what other optimizer flags exist and what their values are. Suppose that all Index Merge optimizations are enabled:\nOptimizer Hints\n8.9.3 Optimizer Hints\n1791"}]}
+{"image": "doclay/doclay_30431.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "I mean that χ ”( q, ω, p, T ) integrated over all ω and k is χ$_{0}$ . The system of-course has other fluctuations but χ$_{0}$ saturates only part of the total spectral weight.\nThe form (17) is suitable for discussing experiments as a function of ( p − p$_{c}$ ). For analyzing experiments as a function of frequency and temperature, an alternate form may be more useful:\nThermodynamic and transport properties near a Gaussian qcp depend on the cut-off scale ω$_{c}$ , the spectral function χ$_{0}$ , the temperature T and the exponent z . The conventional theory of quantum criticality of ferromagnets gives z = 3 for ferromagnets and z = 2 for antiferromagnets. In this situation, the frequency scale as well as the momentum scale of the fluctuations → 0 as the critical point is approached just as near classical critical points; at a temperature T at p = p$_{c}$ , the frequency-scale of the fluctuation is T , and given in terms of ξ$_{t}$ by (20) away from it.\nLet us look at what such critical fluctuations do for T$_{c}$ through what we have just learnt in the previous section. In the quantum-critical regime, the scale of fluctuations just above T$_{c}$ or the cut-off scale in the fluctuations exchanged is T$_{c}$ itself. This is bad for two reasons: the prefactor of the expression for T$_{c}$ goes down with the cut-off, and as discussed and illustrated for ℓ ̸ = 0 pairing in Fig.(4), inelastic scattering has a particularly bad effect on T$_{c}$ .\nIs this compensated for by increase in the dimensionless coupling constants λ$_{ℓ}$ ? In other words does the peaking of fluctuation at low frequencies and in a region of width ξ − 1 r around the critical wave-vector increase the coupling constants. The answer is sadly, no. The point is that the coupling constant depends on the integrated value of the fluctuations over q and ω and these are essentially fixed by sum-rules. There is a weak (logarithmic) increase in the coupling constant if the spectra peaks at low frequencies which is generally quite uninteresting.\nLet us consider the role of χ$_{0}$ , the spectral weight. It may be taken from the ordered moment < M > far away from p$_{c}$ , where it is a slow function of p , to be ≈ < M > $^{2}$. This is a fraction ¯ χ$_{0}$ of the totals spectral weight of such fluctuations, the rest remaining as incoherent particle-hole fluctuations of fermions. As discuss below, the irreducible vertex is reduced by ¯ χ$_{0}$ compared with the case for phonons.\nIn Sec. IV, we will review the firm experimental evidence for the case of the Cuprates and\n24\nχ ”( q, ω, p, T ) = χ$_{0}$T − d$_{M}$ $^{/z}$F 2 ( k T 1 $_{/z}$, ω T , 1 T ξ$_{t}$$^{)}$ . (20)"}]}
+{"image": "doclay/doclay_25857.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "RBNs (Wuensche, 1998; Gershenson, 2002a), where all nodes have the same function (rule) and the structure is regular, i.e. each node has K = 3, inputs: themselves and their closest neighbors. There are 256 possible “rules” (the possible combinations of Boolean functions for 3 inputs are 2 2 3 = 2 8 = 256), although only 88 equivalence classes (Li and Packard, 1990; Wuensche and Lesser, 1992). There have been several classifications of ECA dynamics, the most popular being Wolfram’s (1984). Roughly, class I and II rules generate ordered dy- namics. Rules from class I tend to point attractors from all initial states, while class II rules tend to cycle attractors. Class III rules have chaotic dynamics. Rules from class IV generate critical dynamics, and some have been proven to be capable of universal computation (Cook, 2004).\nThere are several methods to measure criticality in RBNs, including Derrida’s annealed approximation (Derrida and Pomeau, 1986), Lyapunov exponents (Luque and Sol´ e, 2000), and Hamming distances (Gershenson, 2004b).\nThe study of complexity and related properties of discrete dynamical systems with in- formation theory is becoming a very active area. For example, Fisher information was used recently to measure criticality in RBNs (Wang et al., 2011). Zenil (2010) proposed a compression-based method to detect phase transitions (which are related to complexity). Novel measures of complexity of RBNs have been proposed by Gong and Socolar (2012). Mart´ınez et al. (In Press) study CA with memory, being able to extract critical dynamics from chaotic rules.\n4.2 Experimental setup\nSeveral experiments were performed to explore the measures proposed in Section 3. To measure emergence E , self-organization S , and complexity C , the time series of single nodes were evaluated in equations 3, 5, and 7 and then averaged to obtain the results for the network. To measure homeostasis H , d was measured between the last two states. 1000 RBNs ran from a random initial state for 1000 steps and then 1000 “additional” steps were\n14"}]}
+{"image": "doclay/doclay_78667.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Perl Unicode introduction\nThis document gives a general idea of Unicode and how to use Unicode in Perl.\nUnicode is a character set standard which plans to codify all of the writing systems of the world, plus many other symbols.\nUnicode and ISO / IEC 10646 are coordinated standards that provide code points for characters in almost all modern character set standards, covering more than 30 writing systems and hundreds of languages, including all commercially-important modern languages. All characters in the largest Chinese, Japanese, and Korean dictionaries are also encoded. The standards will eventually cover almost all characters in more than 250 writing systems and thousands of languages. Unicode 1.0 was released in October 1991, and 4.0 in April 2003.\nA Unicode character is an abstract entity. It is not bound to any particular integer width, especially not to the C language char . Unicode is language-neutral and display-neutral: it does not encode the language of the text and it does not define fonts or other graphical layout details. Unicode operates on characters and on text built from those characters.\nUnicode defines characters like LATIN CAPITAL LETTER A or GREEK SMALL LETTER ALPHA and unique numbers for the characters, in this case 0x0041 and 0x03B1, respectively. These unique numbers are called code points .\nThe Unicode standard prefers using hexadecimal notation for the code points. If numbers like 0x0041 are unfamiliar to you, take a peek at a later section, §54.1.14. The Unicode standard uses the notation U+0041 LATIN CAPITAL LETTER A , to give the hexadecimal code point and the normative name of the character.\nUnicode also defines various properties for the characters, like \"uppercase\" or \"lowercase\", \"decimal digit\", or \"punctuation\"; these properties are independent of the names of the characters. Furthermore, various operations on the characters like uppercasing, lowercasing, and collating (sorting) are defined.\nA Unicode character consists either of a single code point, or a base character (like LATIN CAPITAL LETTER A ), followed by one or more modifiers (like COMBINING ACUTE ACCENT ). This sequence of base character and modifiers is called a combining character sequence .\nWhether to call these combining character sequences \"characters\" depends on your point of view. If you are a programmer, you probably would tend towards seeing each element in the sequences as one unit, or \"character\". The whole sequence could be seen as one \"character\", however, from the user’s point of view, since that’s probably what it looks like in the context of the user’s language.\nWith this \"whole sequence\" view of characters, the total number of characters is open-ended. But in the programmer’s \"one unit is one character\" point of view, the concept of \"characters\" is more deterministic. In this document, we take that second point of view: one \"character\" is one Unicode code point, be it a base character or a combining character.\n857\n54.1 DESCRIPTION\n54.1.1 Unicode\nChapter 54\nperluniintro"}]}
+{"image": "doclay/doclay_7588.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "MCCORMICK & COMPANY 2004 ANNUAL REPORT\nreport of independent registered public accounting firm\ninternal control over financial reporting\nreport of management\nThe Board of Directors and Shareholders of  McCormick & Company, Incorporated \nWe are responsible for the preparation and integrity of the consolidated financial statements appearing in our Annual Report. The consolidated financial statements were prepared in conformity with United States generally accepted accounting principles and include amounts based on management’s  estimates and judgments. All other financial information in this report has been presented on a basis consistent with the  information included in the financial statements.\nWe are also responsible for establishing and maintaining adequate internal controls over financial reporting. We maintain a system of internal controls that is designed to provide reason- able assurance as to the fair and reliable preparation and presentation of the consolidated financial statements, as well as to safeguard assets from unauthorized use or disposition.\nOur control environment is the foundation for our system of internal controls over financial reporting and is embodied in our Business Ethics Policy. It sets the tone of our organization and includes factors such as integrity and ethical values.  Our internal controls over financial reporting are supported by formal policies and procedures which are reviewed, modified and improved as changes occur in business conditions  and operations.\nThe Audit Committee of the Board of Directors, which is composed solely of outside directors, meets periodically with members of management, the internal auditors and the inde- pendent auditors to review and discuss internal controls over financial reporting and accounting and financial reporting matters. The independent auditors and internal auditors report to the Audit Committee and accordingly have full and free access to the Audit Committee at any time.\nWe conducted our audit in accordance with the standards of the Public Company Accounting Oversight Board (United States). Those standards require that we plan and perform the audit to obtain reasonable assurance about whether effective internal control over financial reporting was maintained in all material respects. Our audit included obtaining an understand- ing of internal control over financial reporting, evaluating management’s assessment, testing and evaluating the design and operating effectiveness of internal control, and performing such other procedures as we considered necessary in the circumstances. We believe that our audit provides a reasonable basis for our opinion. \nWe have audited management’s assessment, included in the accompanying Report of Management, that McCormick & Company, Incorporated and subsidiaries maintained effective internal control over financial reporting as of November 30, 2004, based on the criteria established in  Internal Control – Integrated Framework issued by the Committee of Sponsoring Organizations of the Treadway Commission (the COSO criteria). The Company’s management is responsible for maintaining effective internal control over financial reporting and for its assessment of the effectiveness of internal control over finan- cial reporting. Our responsibility is to express an opinion on management’s assessment and an opinion on the effectiveness of the Company’s internal control over financial reporting based on our audit. \nWe conducted an evaluation of the effectiveness of our internal controls over financial reporting based on the frame- work in  Internal Control – Integrated Framework issued by the Committee of Sponsoring Organizations of the Treadway Commission. This evaluation included review of the documenta- tion of controls, evaluation of the design effectiveness of controls, testing of the operating effectiveness of controls and a conclusion on this evaluation. Although there are inherent  limitations in the effectiveness of any system of internal controls over financial reporting, based on our evaluation, we have concluded that our internal controls over financial reporting were effective as of November 30, 2004. \nErnst & Young LLP, an independent registered public accounting firm, has issued an attestation report on manage- ment’s assessment of internal control over financial reporting, which is included herein.\nBecause of its inherent limitations, internal control over financial reporting may not prevent or detect misstatements. Also, projections of any evaluation of effectiveness to future \nA company’s internal control over financial reporting is a process designed to provide reasonable assurance regarding the reliability of financial reporting and the preparation of finan- cial statements for external purposes in accordance with generally accepted accounting principles. A company’s internal control over financial reporting includes those policies and procedures that (1) pertain to the maintenance of records that, in reasonable detail, accurately and fairly reflect the transactions and dispositions of the assets of the company; (2) provide reasonable assurance that transactions are recorded as neces- sary to permit preparation of financial statements in accordance with generally accepted accounting principles, and that receipts and expenditures of the company are being made only in accor- dance with authorizations of management and directors of the company; and (3) provide reasonable assurance regarding prevention or timely detection of unauthorized acquisition, use, or disposition of the company’s assets that could have a mate- rial effect on the financial statements. \nContinued on page 36Francis A. Contino Executive Vice President, Strategic Planning & Chief Financial Officer\nKenneth A. Kelly, Jr.  Vice President & Controller, Chief Accounting Officer Kam fat}\nKenneth A. Kelly, Jr.  Vice President & Controller, Chief Accounting Officer\nFrancis A. Contino Executive Vice President, Strategic Planning & Chief Financial Officer\nRobert J. Lawless Chairman, President & Chief Executive Officer\n35"}]}
+{"image": "doclay/doclay_31066.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "GLYPH<s48> GLYPH<s49>GLYPH<s48>GLYPH<s48> GLYPH<s50>GLYPH<s48>GLYPH<s48> GLYPH<s51>GLYPH<s48>GLYPH<s48> GLYPH<s45>GLYPH<s49>GLYPH<s46>GLYPH<s48> GLYPH<s45>GLYPH<s48>GLYPH<s46>GLYPH<s53> GLYPH<s48>GLYPH<s46>GLYPH<s48> GLYPH<s45>GLYPH<s48>GLYPH<s46>GLYPH<s52> GLYPH<s45>GLYPH<s48>GLYPH<s46>GLYPH<s50> GLYPH<s48>GLYPH<s46>GLYPH<s48> GLYPH<s48>GLYPH<s46>GLYPH<s50> GLYPH<s48>GLYPH<s46>GLYPH<s52> GLYPH<s45>GLYPH<s48>GLYPH<s46>GLYPH<s49> GLYPH<s48>GLYPH<s46>GLYPH<s48> GLYPH<s48>GLYPH<s46>GLYPH<s49> GLYPH<s48>GLYPH<s46>GLYPH<s50> GLYPH<s48>GLYPH<s46>GLYPH<s57>GLYPH<s57>GLYPH<s53> GLYPH<s49>GLYPH<s46>GLYPH<s48>GLYPH<s48>GLYPH<s48> GLYPH<s32> GLYPH<s32> GLYPH<s32>GLYPH<s98> GLYPH<s50> GLYPH<s32>GLYPH<s98> GLYPH<s51> GLYPH<s32>GLYPH<s98> GLYPH<s52> GLYPH<s32>GLYPH<s98> GLYPH<s54> GLYPH<s98> GLYPH<s107> GLYPH<s65> GLYPH<s40>GLYPH<s98>GLYPH<s41> GLYPH<s32> GLYPH<s32> GLYPH<s69>GLYPH<s32>GLYPH<s47>GLYPH<s32>GLYPH<s69> GLYPH<s48> GLYPH<s50> GLYPH<s40> GLYPH<s97> GLYPH<s41> GLYPH<s50>GLYPH<s48>GLYPH<s56> GLYPH<s80>GLYPH<s98>\nFIG. 2: (Color online) (a) Energy of $^{208}$Pb with respect to β$_{2}$ and β$_{4}$ deformation with Skyrme energy density functional approach. (b) The value of b$_{k}$ as a function of mass number. The scattered symbols denote the obtained curvatures of the parabolas with the Skyrme force SkM* for a number of nuclei. The solid curves denote the corresponding results with an empirical formula (6).\nsee that the parabola approximation to the change of energy with β$_{2}$ is acceptable. Fig.1(b) shows the value of b$_{2}$ as a function of the mass number. The crosses denote the results of the SkM* interaction for a number of nuclei along the β -stability line. We find that the dependence of b$_{2}$ on the mass number A can be reasonably well described by a formula\nThis form of mass dependence of b$_{2}$ is therefore adopted in the proposed mass formula and the optimal values of g$_{1}$ and g$_{2}$ are finally determined by the 2149 measured nuclear masses [6].\nb$_{2}$ = g$_{1}$A 1 / 3 + g$_{2}$A − 1 / $^{3}$. (5)\n6"}]}
+{"image": "doclay/doclay_21520.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "notes to the Consolidated Financial Statements (cont’d)\n16. SHARE CAPITAl\nThe share capital of the Company is as follows:\nA summary of the Company’s common share transactions is as follows:\nIn the fourth quarter of 2010, the Company wound up a wholly-owned subsidiary company that had previously held a common share  balance of 1,238,418 in the amount of $12,468,552. \nUpon windup, the subsidiary’s cost to repurchase the common shares was $10.07 per share for a total cost of $12.5 million. All shares  held by the subsidiary were cancelled at the time of wind up at an average cost per common share of $4.84 resulting in an increase to  share capital and a reduction to retained earnings of $6.5 million. \nA summary of the Company’s non-voting equity share transactions is as follows:\nIn addition to the cancellation of the 800 shares held by a subsidiary company in the second quarter of 2010, the Company  repurchased 3,185,030 of its non-voting common shares for $8.00 per share for a total cost of $25.5 million. In the fourth quarter of  2010, these shares, in addition to the 800 subsidiary company’s shares, which were purchased for $5.10 per share with an average cost  per share of $8.00 upon cancellation, were also cancelled, resulting in a net reduction of the non-voting equity share capital and  increase in contributed surplus in the amount of $8.9 million. \nDuring the first quarter of 2011, the Company repurchased 50,000 non-voting equity shares for $13.80 per share for a total cost of $0.7 million resulting in a decrease to contributed surplus of $0.3 million.\nDuring the second quarter of 2011, the Company repurchased 31,958 non-voting equity shares for $13.81 per share for a total cost of $0.4 million resulting in a decrease to contributed surplus of $0.2 million.\nDuring the third quarter of 2011, the Company repurchased 6,800 non-voting equity shares for $13.18 per share for a total cost of $89 thousand resulting in a decrease to contributed surplus of $35 thousand.\n83 AnnuAl RepoRt 2011\nDecember 31, 2011 January 1, 2011  January 3, 2010 Authorized  Preference shares of the par value of $25 each, issuable in series  5,999,994  5,999,994  5,999,994  Subordinated redeemable preference shares of the par value of $1 each,  redeemable at par   1,025,542  1,025,542  1,025,542  Non-voting equity shares  200,000,000 200,000,000 200,000,000  Common shares, without par value  200,000,000 200,000,000 200,000,000 \nFifty-two weeks ended  Fifty-two weeks ended December 31, 2011 January 1, 2011 Shares  ($000s)  Shares  ($000s) Common shares:  Balance, beginning of period  13,271,809 $   63,315  13,268,809 $   56,689  Stock options exercised   26,975  451   3,000  33  Cancelled share reclassified to retained earnings   –  –   –  6,593  Balance, end of period  13,298,784 $   63,766  13,271,809 $   63,315  Non–voting equity shares:  Balance, beginning of period   1,876,820 $   15,011   5,061,850 $   49,409  Shares repurchased   (88,758)   (710)  (3,185,030)   (25,480) Cancelled share reclassified to contributed surplus   –  –   –  (8,918) Balance, end of period   1,788,062 $   14,301   1,876,820 $   15,011 "}]}
+{"image": "doclay/doclay_24783.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "We want a static solution to the equations of motion, so it is convenient to set σ 0 = t and σ 1 = x , and assume y = z = 0. We also assume that the string is at a constant angular position in S $^{5}$. Then the action becomes\nwith\nEquation (4.13) is very similar to the integral found when performing Fer- mat’s Principle for the path of light rays [102]. For large separation of endpoints, the trajectory which minimizes S locates itself very nearly at the minimum of n ( r ) for most of its length. Hence the complicated pro- cess of optimizing S is reduced to simply optimizing n ( r ). Furthermore, for small separations Δ x about its minimum, S becomes\nIt is easy to show that n ( r ) is optimized by\nwhich gives\nwith Σ = Δ − δ Δ+ $_{δ}$. (4.16) shows us that this geometry gives us a linear quark- antiquark potential. In other words, it exhibits confinement.\n63\nS = 1 2 πα ′ ∫ dt dx n ( r ) [ 1 + m ( r ) ( dr dx ) 2 ] 1 / 2 (4.13)\nn ( r ) = G$_{xx}$ = $_{H}$− 1 / $^{2}$f (Δ+ δ ) / 4 m ( r ) = $_{G}$− 1 $_{xx}$G$_{rr}$ = H w 4 − b 4 w 4 f (1 − δ +Δ) / 2\nS ≃ n ( r$_{min}$ ) 2 πα ′ Δ x (4.14)\nr 4 min = 2 ω 4 ( Δ+ δ Δ − δ ) 1 /δ − 1 (4.15)\nV (Δ x ) = S (Δ x ) = Σ δ − Δ 4 δ 2 πα $_{′}$√$_{1}$ − Σ Δ x (4.16)"}]}
+{"image": "doclay/doclay_45181.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "System Malfunctions\nAntitorque System Failure\nresult in a 10 percent loss in the engine’s ability to produce  horsepower, making recovery even slower and more difficult  than it would otherwise be. With less power from the engine  and less lift from the decaying rotor rpm, the helicopter will  start to settle. If the pilot raises the collective to stop the  settling, the situation will feed upon itself rapidly leading  to rotor stall. \nairflow through the rotor disk, and the resulting AOA is so  high that even full down collective will not restore normal  airflow. In the helicopter when the rotor stalls, it does not do  so symmetrically because any forward airspeed will produce  a higher airflow on the advancing side than on the retreating  side. This causes the retreating blade to stall first, and its  weight makes it descend as it moves aft while the advancing  blade is climbing as it goes forward. The resulting low aft  blade and high forward blade become a rapid aft tilting of  the rotor disc sometimes referred to as rotor “blow back” or  “flap back.” As the helicopter begins to descend, the upward  flow of air acting on the bottom surfaces of the tail boom  and any horizontal stabilizers tend to pitch the aircraft nose  down. These two effects, combined with any aft cyclic by  the pilot attempting to keep the aircraft level, allow the rotor  blades to blow back and contact the tail boom, in some cases  actually severing the tail boom. Since the tail rotor is geared  to the main rotor, in many helicopters the loss of main rotor  rpm also causes a significant loss of tail rotor thrust and a  corresponding loss of directional control.\nThere are a number of ways the pilot can recognize the low  rotor rpm situation. Visually, the pilot can not only see the  rotor rpm indicator decrease but also the change in torque  will produce a yaw; there will also be a noticeable decrease in  engine noise, and at higher airspeeds or in turns, an increase in  vibration. Many helicopters have a low rpm warning system  that alerts the pilot to the low rotor rpm condition.\nTo recover from the low rotor rpm condition the pilot must  simultaneously lower the collective, increase throttle if  available and apply aft cyclic to maintain a level attitude.  At higher airspeeds, additional aft cyclic may be used to  help recover lost rpm. Recovery should be accomplished  immediately before investigating the problem and must be  practiced to become a conditioned reflex.\nRotor stalls in helicopters are not recoverable. At low altitude,  rotor stall will result in an accident with significant damage  to the helicopter, and at altitudes above approximately 50  feet the accident will likely be fatal. Consequently, early  recognition of the low rotor rpm condition and proper  recovery technique is imperative. \nBy following the manufacturer’s recommendations regarding  operating limits and procedures and periodic maintenance  and inspections, many system and equipment failures can  be eliminated. Certain malfunctions or failures can be traced  to some error on the part of the pilot; therefore, appropriate  flying techniques and use of threat and error management  may help to prevent an emergency\nLow rotor rpm can occur during power-off and power-on  operations. During power-off flight, a low rpm situation  can be caused by the failure to quickly lower the collective  after an engine failure or by raising the collective at too  great a height above ground at the bottom of an autorotation.  However, more common are power-on rotor stall accidents.  These occur when the engine is operating normally but the  pilot demands more power than is available by pulling up  too much on the collective. Known as “overpitching,” this  can easily occur at higher density altitudes where the engine  is already producing its maximum horsepower and the pilot  raises the collective. The corresponding increased AOA of  the blades requires more engine horsepower to maintain the  speed of the blades; however, the engine cannot produce any  additional horsepower, so the speed of the blades decreases.  A similar situation can occur with a heavily loaded helicopter  taking off from a confined area. Other causes of a power-on  low rotor rpm condition include the pilot rolling the throttle  the wrong way in helicopters not equipped with a governor  or a governor failure in helicopters so equipped.\nAntitorque failure usually falls into one of two categories.  One is failure of the power drive portion of the tail rotor disk  resulting in a complete loss of antitorque. The other category  covers mechanical control failures prohibiting the pilot from  changing or controlling tail rotor thrust even though the tail  rotor may still be providing antitorque thrust.\nTail rotor drive system failures include driveshaft failures,  tail rotor gearbox failures, or a complete loss of the tail rotor  itself. In any of these cases, the loss of antitorque normally  results in an immediate spinning of the helicopter’s nose. The  helicopter spins to the right in a counterclockwise rotor disk  and to the left in a clockwise system. This discussion is for a  helicopter with a counterclockwise rotor disk. The severity of  the spin is proportionate to the amount of power being used  and the airspeed. An antitorque failure with a high-power  setting at a low airspeed results in a severe spinning to the \nAs the rpm decreases, the amount of horsepower the engine  can produce also decreases. Engine horsepower is directly  proportional to its rpm, so a 10 percent loss in rpm due  to overpitching, or one of the other scenarios above, will \n11-16"}]}
+{"image": "doclay/doclay_30587.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "excitation spot from the interface will affect our measure ˜ δ$_{PMT}$ . Our absolute positional accuracy is roughly 5 µ m and, by measuring away from the interface on either side for a given experimental alignment, we estimate the introduced error to be roughly 10% of the measured fluctuation for unstable flows at higher flow rates (0.2 kV and above driving voltages) which is also the estimated error found by comparing differing experimental runs (which requires realignment). At lower flow velocities the system noise begins to dominate, and for no-flow conditions run-to-run differences in measured fluctuations is ca. 30%.\nPolymer-free solutions display laminar flow for all driving voltages (Fig. 5.a). In contrast to this laminar flow, fluctuations grow in size as the driving voltage increases for a concen- tration of 120 ppm of the HMW sample (Fig. 5.a). As seen in Fig. 5.b similar behavior occurrs at other concentrations of the HMW sample, both below (60, 90 ppm), and above (480 ppm) the overlap concentration.\nScaling properties of viscoelastic instabilities are not well understood, but the basic ele- ments of curvature and elastic normal stress (stretching) along streamlines are well estab- lished as underlying instability [25] as these mechanisms lead to “hoop-stress” [1] allowing stretched polymers to cross streamlines, disturbing laminar flow. Fluctuations should grow with concentration (as the movement of individual polymer coils underlies the fluctuations). Changing the concentration and investigating fluctuations at a constant (0.2 kV) voltage indicates that fluctuations rapidly grow from the noise floor and then peak and plateau with a gentle decrease as we increase concentration, with fairly uniform measured fluctuations from ≈ 1 $_{10}$X to ≈ 1X the overlap concentration, Fig. 6.\nOur fluctuation measure var ( V 〈 V 〉 $^{)}$takes its maximum possible value of 1 for square-wave signals; the precise maximal value for a given signal is ≤ 1 and depends on the nature of the waveform. Smooth growth in our measure occurs until the maximum, for a given waveform with linear amplitude growth. When the maximal value is reached a sudden apparent threshold will occur and our measure will saturate. The maximal threshold observed here is followed by a mild decrease rather than a strict capping and saturation; this is suggestive of a qualitative change in behavior rather than an artifact of our measure.\nModeling the polymer solution as a colloidal solution [26] one expects hydrodynamic in- teraction mediated molecular crowding effects above a volume fraction φ of approximately 0.1 [27] where such effects are empirically found [51]. To estimate the concentration when hydrodynamic interactions between polymers play a significant role we take c$_{thresh}$ c$_{∗}$ = φ$_{thresh}$ φ$_{∗}$ ,\n9"}]}
+{"image": "doclay/doclay_57034.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Expression condition and nested condition\n// Declarative // pipeline { agent any stages { stage('Example Build') { steps { echo 'Hello World' } } stage('Example Deploy') { when { expression { BRANCH_NAME ==~ /(production|staging)/ } anyOf { environment name: 'DEPLOY_TO', value: 'production' environment name: 'DEPLOY_TO', value: 'staging' } } steps { echo 'Deploying' } } } } // Script //\nParallel\nExample\nStages in Declarative Pipeline may declare a number of nested stages within them, which will be executed in parallel. Note that a stage must have one and only one of either  steps  or  parallel . The nested stages cannot contain further  parallel  stages themselves, but otherwise behave the same as any other  stage . Any stage containing  parallel  cannot contain  agent  or  tools , since those are not relevant without  steps .\nIn addition, you can force your  parallel stage`s to all be aborted when one of them fails, by adding `failFast true  to the  stage  containing the  parallel .\n98"}]}
+{"image": "doclay/doclay_43087.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "A partially opened valve is producing a fraction of the heat  available, but there is no way of knowing what the fraction  is.  [Figure 7-2]\nLevel flight, or equilibrium, is probably the most important  of all flight maneuvers, as it serves as a baseline from which  all other maneuvers are derived. A good pilot maintains level  flight with a series of standard burns. \nLevel flight is achieved when lift exactly matches weight  and the balloon neither ascends nor descends, but remains  at one altitude. For every altitude, there is an equilibrium  temperature. If a pilot is flying at 500 feet mean sea level  (MSL) and wants to climb to 1,000 feet MSL, the balloon  temperature must be increased. This is not only to attain  equilibrium at the new (higher) altitude, but some excess  temperature must also be created to overcome inertia and  get the balloon moving. \nTheoretically, if a pilot were to hold a hot air balloon at a  constant temperature, the balloon would float at a constant  altitude. However, there is no practical way to hold the  envelope air temperature constant. Each time the pilot burns,  the balloon tends to climb. The air in the envelope is always  cooling and the balloon tends to descend. If the subsequent  burns are perfectly timed, the balloon flies in a series of very  shallow sine waves.  [Figure 7-3, Line A] Of course, any  variable changes the balloon flight. A heavier basket load,  higher ambient temperature, or sunny day all require more  fuel (by shortening the interval between burns) to maintain  level flight. \nIn discussions of level flight, the terms “flying light” and  “flying heavy” are sometimes used and bear explanation.  A balloon is said to be “flying light” when the sine wave  being described in the air is predominately on the high side  of the desired altitude  [Figure 7-3, Line B] . Many new or  inexperienced pilots tend to fly light, and use the vent line  in order to return to the desired altitude; this may create a  situation where the pilot gets into a constant overcontrolling  exercise and is best avoided. “Flying heavy” can be described  as a scenario where the sine wave is predominately on the  low side of the desired altitude  [Figure 7-3, Line C] ; if the  balloon is left alone, it tends to fall. Flying heavy can be  hazardous when contour flying. A balloon pilot must use all  visual cues available and exercise a “finesse” type of control  when contour flying (described later in this chapter).\nAnother advantage of briskly opening and closing the valve  is to minimize the presence of a yellow, soft flame. During  inflation, for instance, a strong, narrow, pointed flame that  goes into the mouth opening without overheating the mouth  fabric or crew is desirable. A partial-throttle flame is wide  and short and subject to distortion by wind or the inflation  fan. If less than a full burn is desired, shorten the time the  valve is open and not the amount the valve is open. Due to  burner design (and the inefficiency of a partially opened  valve), four 1-second burns do not produce as much heat as  one 4-second burn.\nThrough experimentation, standards can be established that  may be used as a basis for all flights. With practice and using  the second hand of a wristwatch, a new pilot can fly almost  level. The exercise of learning the pattern of burns (each day  and hour is different) is an interesting training exercise, but  not a practical real-life technique. The ability to hold a hot air  balloon at a given altitude for any length of time is a skill that \nIf the mechanical aspects of flying can be learned, the  systematic cadence can be converted into a rhythm that is  smooth and polished. With practice, the rhythm becomes  second nature and pilots fly with precision, without thinking  about it. Using the standard burn, pilots can better predict the  effect of each burn, minimize the potential danger of a burn  to the envelope, and have a better flame pattern. The standard  burn is referred to when discussing specific maneuvers.\n7-3\n$_{Figure 7-2.}$  Activated burner.Straight and Level Flight"}]}
+{"image": "doclay/doclay_60953.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "200510079024. 1\na“ HW #$ # 590/98 i\n245\n4 JA BE 20 «RAAT bE FE BREE FI HEHE 3 f A 59 BEN By An By Ai BE N m u — un"}]}
+{"image": "doclay/doclay_25146.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "and it follows that ∑ q i $_{=1}$α$_{i}$ − ¯ a ≤ 0 . If ∑ q i $_{=1}$α$_{i}$ − ¯ a = 0 then ¯ G$_{l}$ ( y ) is full rank and so is ¯ G ( y ) . If ¯ G ( y ) is full rank then there is a square submatrix ¯ G$_{l}$ ( y ) of full rank, for the corresponding submatrix in SG ( y )\nand ∑ q i $_{=1}$α$_{i}$ − ¯ a ≥ 0. The equality follows. Proof of Lemma 4.2. By the property (11) some\n∑ Proof of Lemma 4.2. By the property (11) some a for which (13) holds exists and by the Lemma 4.1 either CLDR holds or a is such that q ∑ i =1 α$_{i}$ ̸ = ¯ α. Then by the condition on a ′ if CLDR does not hold then for some i we have α ′ i > α$_{i}$, or α ′ i < α$_{i}$. Then for any { i, j } matrix entry in the matrix SG ( y/λ ) , given by S ′ i $_{·}$G$_{·}$$_{j}$ ( y/λ ) (where for a matrix A, A$_{i}$$_{·}$ denotes the i th row and A$_{·}$$_{j}$ - the j th column)\nIn the first case α ′ i > α$_{i}$ , this matrix entry diverges to infinity. In the second case α ′ i < α$_{i}$ and as λ → ∞ this matrix entry converges to zero for every j, thus the limit matrix lim$_{λ}$$_{→}$$_{+}$$_{∞}$ [ diag ( λ α ′ i ) SG ( y/λ ) ] has deficient rank.\nProof of Lemma 4.3. Start with a q$_{v}$ × p matrix of polynomials G v ( y ) .\nFor each matrix element, { G v ( y ) }$_{ij}$ , which is a polynomial, define the low- est order of homogeneous polynomial, ¯ k$_{{}$$_{G}$ $^{v}$( y ) $_{}$_{ij}$}$. Then select ¯ k$_{v}$ = min i,j { ¯ k$_{{}$ G $^{v}$( y ) } $_{ij}$} .\n40\nλ α ′ i S ′ i $_{·}$G$_{·}$$_{j}$ ( y/λ ) = λ α ′ $_{i}$− $^{α$_{i}$}$λ$^{α$_{i}$}$S ′ i $_{·}$G$_{·}$$_{j}$ ( y/λ )\nlim λ → + $_{$_{∞}$λ}$∑ q i $_{=1}$α$_{i}$ det( ˜ G$_{l}$ ( y/λ )) > 0"}]}
+{"image": "doclay/doclay_68732.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "2. Select the wanted pool into which a new copy is to be created, as shown in Figure 6-50.\n4. Wait until the copies are synchronized. Then, change the role of the copies and make the  new copy of the primary copy, as shown in Figure 6-51.\n3. A task completion window opens. Click  Close .\n5. A task completion window opens. Click  Close .\nFigure 6-50 Add Volume Copy\nFigure 6-51 Making the new copy in a different storage pool as primary\nChapter 6. Volume configuration  351"}]}
+{"image": "doclay/doclay_13553.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "be true."}]}
+{"image": "doclay/doclay_79816.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Nov. 5, 2020 \n7 \nUS 2020/0348591 Al \nadditive as needed or desired. Non-limiting examples of the  additive include a surfactant, a cross-linking agent, a level› ing agent, and any combination thereof. \n[0096]  The surfactant may include, for example, an alkyl  benzene sulfonate salt, an alkyl pyridinium salt, polyethyl› ene glycol, a quaternary ammonium salt, or any combination  thereof, but is not limited thereto. \n[0097]  The cross-linking agent may be, for example, a  melamine-based cross-linking agent, a substituted urea› based cross-linking agent, or a polymer-based cross-linking  agent, but is not limited thereto. The cross-linking agent may  be a cross-linking agent having at least two cross-linking  forming substituents, for example, a compound such as  methoxymethylated  glycoluril,  butoxymethylated  gly› coluril, methoxymethylated melamine, butoxymethylated  melamine, methoxymethylated benzoguanamine, butoxym› ethylated  benzoguanamine,  methoxymethylated  urea,  butoxymethylated urea, methoxymethylated thiourea, and/  or the like. \n[0098]  The leveling agent may be used for improving  coating flatness during printing, and may be a commercially  available or suitable known leveling agent. \n[0099]  The amount of each additive may be selected or  controlled depending on desired or suitable properties. \n[0100]  In some embodiments, the semiconductor resist  composition may further include a silane coupling agent as  an adherence enhancer in order to improve a close-contact› ing force with the substrate ( e.g., in order to improve  adherence of the semiconductor resist composition to the  substrate). The silane coupling agent may be, for example,  a silane compound including a carbon-carbon unsaturated  bond (such as vinyltrimethoxysilane, vinyltriethoxysilane,  vinyl trichlorosilane, or vinyltris(~-methoxyethoxy)silane);  3-methacryloxypropyltrimethoxysilane, 3-acryloxypropylt› rimethoxysilane, p-styryl trimethoxysilane, 3-methacry› loxypropy lmethy ldimethoxysilane, 3-methacry loxypropyl› methyl diethoxysilane; trimethoxy[3-(phenylamino )propyl]  silane, and/or the like, but is not limited thereto. \n[0101]  The semiconductor photoresist composition may  be formed into a pattern having a high aspect ratio without  a collapse. Accordingly, in order to form a fine pattern  having a width of, for example, about 5 nm to about 100 nm,  about 5 nm to about 80 nm, about 5 nm to about 70 nm,  about 5 nm to about 50 nm, about 5 nm to about 40 nm,  about 5 nm to about 30 nm, or about 5 nm to about 20 nm,  the semiconductor resist composition may be used for a  photoresist process using light in a wavelength ranging from  about 5 nm to about 150 nm, for example, about 5 nm to  about 100 nm, about 5 nm to about 80 nm, about 5 nm to  about 50 nm, about 5 nm to about 30 nm, or about 5 nm to  about 20 nm. Accordingly, the semiconductor photoresist  composition according to an embodiment may be used to  realize extreme ultraviolet (EUV) lithography using an EUV  light source of a wavelength of about 13.5 nm. \n[0102]  One or more example embodiments of the present  disclosure provide a method of forming patterns using the  semiconductor photoresist composition. For example, the  manufactured pattern may be a photoresist pattern. \n[0103]  The method of forming patterns according to an  embodiment includes: forming an etching-objective layer on  a substrate, coating the semiconductor photo resist compo› sition on the etching-objective layer to form a photoresist  layer, patterning the photoresist layer to form a photoresist \n[0092]  The resin may have a weight average molecular  weight of about 500 to about 20,000. \n[0093]  The resin may be included in an amount of about  0.1 wt % to about 50 wt% based on a total amount of the  semiconductor resist composition. \n[0094]  When the resin is included within the above› described amount range, the resin may have excellent etch  resistance and/or heat resistance. \n[0095]  The semiconductor resist composition according to  an embodiment may be desirably composed of the organo› metallic compound, solvent, and resin. In some embodi› ments, however, the semiconductor resist composition  according to the above embodiment may further include an \n-continued "}]}
+{"image": "doclay/doclay_46460.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Chapter 3. Airspace\nSection 1. General\nSection 2. Controlled Airspace\nSection 3. Class G Airspace\nSection 3. Airport Marking Aids and Signs\nSection 2. Air Navigation and Obstruction Lighting\n12/31/20\nAIM\nParagraph Page 2-1-9. Airport/Heliport Beacons 2-1-12 ............................................. 2-1-10. Taxiway Lights 2-1-13 .....................................................\n2-2-1. Aeronautical Light Beacons 2-2-1 ........................................... 2-2-2. Code Beacons and Course Lights 2-2-1 ...................................... 2-2-3. Obstruction Lights 2-2-1 ..................................................\n2-3-1. General 2-3-1 ............................................................ 2-3-2. Airport Pavement Markings 2-3-1 ........................................... 2-3-3. Runway Markings 2-3-1 ................................................... 2-3-4. Taxiway Markings 2-3-7 ................................................... 2-3-5. Holding Position Markings 2-3-12 ............................................ 2-3-6. Other Markings 2-3-16 ..................................................... 2-3-7. Airport Signs 2-3-19 ....................................................... 2-3-8. Mandatory Instruction Signs 2-3-20 .......................................... 2-3-9. Location Signs 2-3-23 ...................................................... 2-3-10. Direction Signs 2-3-25 .................................................... 2-3-11. Destination Signs 2-3-28 .................................................. 2-3-12. Information Signs 2-3-29 .................................................. 2-3-13. Runway Distance Remaining Signs 2-3-29 .................................... 2-3-14. Aircraft Arresting Systems 2-3-30 ........................................... 2-3-15. Security Identification Display Area (SIDA) 2-3-31 ............................\n3-1-1. General 3-1-1 ............................................................ 3-1-2. General Dimensions of Airspace Segments 3-1-1 .............................. 3-1-3. Hierarchy of Overlapping Airspace Designations 3-1-1 ......................... 3-1-4. Basic VFR Weather Minimums 3-1-1 ........................................ 3-1-5. VFR Cruising Altitudes and Flight Levels 3-1-2 ...............................\n3-2-1. General 3-2-1 ............................................................ 3-2-2. Class A Airspace 3-2-2 .................................................... 3-2-3. Class B Airspace 3-2-2 .................................................... 3-2-4. Class C Airspace 3-2-4 .................................................... 3-2-5. Class D Airspace 3-2-8 .................................................... 3-2-6. Class E Airspace 3-2-9 ....................................................\n3-3-1. General 3-3-1 ............................................................ 3-3-2. VFR Requirements 3-3-1 .................................................. 3-3-3. IFR Requirements 3-3-1 ..................................................\nTable of Contents\nii"}]}
+{"image": "doclay/doclay_43777.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Lateral stability (rolling).  The stability about the  longitudinal axis of an aircraft. Rolling stability or the ability  of an airplane to return to level flight due to a disturbance  that causes one of the wings to drop. \nLatitude.  Measurement north or south of the equator in  degrees, minutes, and seconds. Lines of latitude are also  referred to as parallels. \nLDA.  See localizer-type directional aid. \nLead radial.  The radial at which the turn from the DME arc  to the inbound course is started. \nLeading edge.  The part of an airfoil that meets the airflow first. \nLeading edge devices.  High lift devices which are found  on the leading edge of the airfoil. The most common types  are fixed slots, movable slats, and leading edge flaps. \nJet stream.  A high-velocity narrow stream of winds, usually  found near the upper limit of the troposphere, which flows  generally from west to east. \nJet route.  A route designated to serve flight operations from  18,000 feet MSL up to and including FL 450. \nJudgment.  The mental process of recognizing and analyzing  all pertinent information in a particular situation, a rational  evaluation of alternative actions in response to it, and a timely  decision on which action to take. \nKIAS.  Knots indicated airspeed. \nKnot.  The knot is a unit of speed equal to one nautical mile  (1.852 km) per hour, approximately 1.151 mph. \nKollsman window.  A barometric scale window of a  sensitive altimeter used to adjust the altitude for the  altimeter setting. \nLeading-edge flap.  A portion of the leading edge of an  airplane wing that folds downward to increase the camber,  lift, and drag of the wing. The leading-edge flaps are  extended for takeoffs and landings to increase the amount  of aerodynamic lift that is produced at any given airspeed. \nLAAS.  See local area augmentation system. \nLag.  The delay that occurs before an instrument needle attains  a stable indication. \nLeans, the.  A physical sensation caused by an abrupt correction  of a banked attitude entered too slowly to stimulate the motion  sensing system in the inner ear. The abrupt correction can  create the illusion of banking in the opposite direction. \nLand breeze.  A coastal breeze flowing from land to sea  caused by temperature differences when the sea surface is  warmer than the adjacent land. The land breeze usually occurs  at night and alternates with the sea breeze that blows in the  opposite direction by day. \nLicensed empty weight.  The empty weight that consists  of the airframe, engine(s), unusable fuel, and undrainable  oil plus standard and optional equipment as specified in the  equipment list. Some manufacturers used this term prior to  GAMA standardization. \nLift.  A component of the total aerodynamic force on an airfoil  and acts perpendicular to the relative wind. \nLand as soon as possible.  Land without delay at the nearest  suitable area, such as an open field, at which a safe approach  and landing is assured. \nLand as soon as practical.  The landing site and duration of  flight are at the discretion of the pilot. Extended flight beyond  the nearest approved landing area is not recommended. \nLimit load factor.  Amount of stress, or load factor, that an  aircraft can withstand before structural damage or failure  occurs. \nLines of flux.  Invisible lines of magnetic force passing  between the poles of a magnet. \nL/MF.  See low or medium frequency. \nLMM.  See locator middle marker. \nLand immediately.  The urgency of the landing is paramount.  The primary consideration is to ensure the survival of the  occupants. Landing in trees, water, or other unsafe areas  should be considered only as a last resort. \nLateral axis.  An imaginary line passing through the center  of gravity of an airplane and extending across the airplane  from wingtip to wingtip. \nL \nK \nJ \nG-17 "}]}
+{"image": "doclay/doclay_76383.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "FIG. 3: The same as in Fig.2 but for R=120 fm.\n13\nΘ = 134 ο 0.5  0  0.2  0.4  0.6  0.8  1 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1 p’ [fm$^{-1}$]   0  0.5  1  1.5  2 Re t(p’,p,x) [fm$^{2}$] \nΘ = 45 ο 1 0.5  0  0.2  0.4  0.6  0.8  1 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1 p’ [fm$^{-1}$]   0  0.5  1  1.5  2 Re t(p’,p,x) [fm$^{2}$] \nΘ = 10 ο 2 1.5 1 0.5  0  0.2  0.4  0.6  0.8  1 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1 p’ [fm$^{-1}$]   0  0.5  1  1.5  2 Re t(p’,p,x) [fm$^{2}$] \nΘ = 5 ο 2 1.5 1 0.5  0  0.2  0.4  0.6  0.8  1 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1 p’ [fm$^{-1}$]   0  0.5  1  1.5  2  2.5  3 Re t(p’,p,x) [fm$^{2}$] \n-0.01 -0.02 -0.03 -0.04 -0.05  0  0.2  0.4  0.6  0.8  1 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1 p’ [fm$^{-1}$]  -5.0e-02 -4.0e-02 -3.0e-02 -2.0e-02 -1.0e-02 0.0e+00 Im t(p’,p,x) [fm$^{2}$] \n-0.005 -0.01 -0.015  0  0.2  0.4  0.6  0.8  1 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1 p’ [fm$^{-1}$]  -1.6e-02 -1.4e-02 -1.2e-02 -1.0e-02 -8.0e-03 -6.0e-03 -4.0e-03 -2.0e-03 0.0e+00 Im t(p’,p,x) [fm$^{2}$] \n -0.0005 -0.001  0  0.2  0.4  0.6  0.8  1  1.2 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1  1.2 p’ [fm$^{-1}$]  -1.4e-03 -1.2e-03 -1.0e-03 -8.0e-04 -6.0e-04 -4.0e-04 -2.0e-04 0.0e+00 Im t(p’,p,x) [fm$^{2}$] \n -0.0001  -0.0002  -0.0003  -0.0004  -0.0005  0  0.2  0.4  0.6  0.8  1 p [fm$^{-1}$]   0  0.2  0.4  0.6  0.8  1 p’ [fm$^{-1}$]  -5.0e-04 -4.0e-04 -3.0e-04 -2.0e-04 -1.0e-04 0.0e+00 Im t(p’,p,x) [fm$^{2}$] "}]}
+{"image": "doclay/doclay_71397.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Table of Contents\nHEXION INC. CONSOLIDATED STATEMENTS OF COMPREHENSIVE (LOSS) INCOME\nSuccessor Predecessor Year Ended December 31, 2020 July 2, 2019 through December 31, 2019 January 1, 2019 through July 1, 2019 Year Ended December 31, 2018 (In millions) Net (loss) income $ (230) $ (88) $ 2,895  $ (163) Other comprehensive loss, net of tax: Foreign currency translation adjustments (8) (3) (8) (8) Unrealized (loss) gain on cash flow hedge (18) 2  —  —  Loss recognized from pension and postretirement benefits —  —  —  (2) Other comprehensive loss (26) (1) (8) (10) Comprehensive (loss) income (256) (89) 2,887  (173) Comprehensive (income) loss attributable to noncontrolling interest —  (1) (1) 1  Comprehensive (loss) income attributable to Hexion Inc. $ (256) $ (90) $ 2,886  $ (172)\nHexion Inc. |  63  | 2020 Form 10-K\nSee Notes to Consolidated Financial Statements"}]}
+{"image": "doclay/doclay_74557.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "T EN Y EARS OF G ROWTH\nS IGNIFICANT M ILESTONES\n150 200 250 300 350 400 ‘94 ‘95 ‘96 ‘97 ‘98 ‘99 ‘00 ‘01 ‘02 ‘03 ‘04  Proved Oil & Gas Reserves  (BCFE)\nProven and Probable Coal Reserves (Millions of tons) 300 400 500 600 700 800 ‘ 94 ‘ 95  ‘ 96  ‘ 97  ‘ 98 ‘ 99  ‘ 00  ‘ 01  ‘ 02  ‘ 03  ‘ 04 \nCumulative Shareholder Return ($100 invested 1/1/95) 175 300 425 550 675 800 ‘ 94 ‘ 95  ‘ 96  ‘ 97  ‘ 98 ‘ 99  ‘ 00  ‘ 01  ‘ 02  ‘ 03  ‘ 04 \n1\n1996\n1999\n2000\n2001\n2001\n2002\n2003\n2004\n2004\nRestructuring Begins  Penn Virginia gets back coal under  lease to Westmoreland Coal Company. Represents 85% of existing reserves. Purchase new reserves in 1997 and 1998.\nExpansion Outside Appalachia Acquires 23 Bcfe of proved oil and gas reserves in Gwinville field in Mississippi. Additional properties \nreserves in Gwinville field in Mississippi. Additional properties  in 2002 and 2003.\nFocus on CBM Begins Acquires 506,000 acres of oil and  gas rights in central Appalachia. Includes 35 Bcfe of proved reserves  and coalbed methane rights.\nGeographic Diversity in Coal PVR acquires 120MM tons of proven  coal reserves from Peabody Energy  Corp for $125MM of cash and units.\nPenn Virginia Resource is Born Successful IPO of Penn Virginia Resource Partners, LP (PVR). Sells 48% of units, raises over $140MM. Retains 52% of units and 100% of GP.\nPlatform for Growth in Oil & Gas Buys Gulf Coast oil and gas property  with 60 Bcfe of proved and significant probable reserves for $112MM of cash.\nGulf Coast Oil & Gas Expansion Acquires 25% working interest in Kingsville field in South Texas, adding  22 Bcfe of proved oil and gas reserves.\nNew Direction in  Coal Infrastructure PVR acquires 50% interest in coal  handling joint venture with Massey Energy to own coal handling facilities.\nNatural Gas Midstream  Growth Engine for PVR PVR announces acquisition of Cantera  midstream oil and gas \nPVR announces acquisition of Cantera  midstream oil and gas  business for $191MM  of cash.\n= u  -. ~~ m= i\nu\n"}]}
+{"image": "doclay/doclay_70988.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Table of Contents\n2. SIGNIFICANT ACCOUNTING POLICIES (Continued)\nPayment terms\nCustomer deposits and deferred revenue\nResearch and Development\nForeign Currency Translation\nComprehensive Income (Loss)\nEarnings Per Share\n81\nBasic earnings per share is computed based on the weighted average number of shares outstanding during the period, excluding unvested restricted stock. Diluted earnings per share is computed based on the weighted average number of shares outstanding during the period increased by the effect of dilutive employee stock awards, including stock options, restricted stock awards and stock purchase plan contracts, using the treasury stock method.\nComprehensive income (loss) is defined as the change in equity of a business enterprise during a period from transactions and other events and circumstances from non-owner sources. Accumulated other comprehensive income (net of tax) at fiscal 2019 year-end was substantially comprised of accumulated translation adjustments of $(34.4) million and deferred actuarial losses on pension plans of $(2.0) million. Accumulated other comprehensive income (net of tax) at fiscal 2018 year-end was substantially comprised of accumulated translation adjustments of $(1.8) million and deferred actuarial gains on pension plans of $4.6 million.\nThe functional currencies of our foreign subsidiaries are generally their respective local currencies. Accordingly, gains and losses from the translation of the financial statements of the foreign subsidiaries are reported as a separate component of accumulated other comprehensive income (\"OCI\"). Foreign currency transaction gains and losses are included in earnings.\nWe treat third party and government funding of our research and development activity, where we are the primary beneficiary of such work conducted, as a reduction of research and development cost. Research and development reimbursements of $3.8 million, $3.2 million and $2.9 million were offset against research and development costs in fiscal 2019, 2018 and 2017, respectively.\nResearch and development expenses include salaries, contractor and consultant fees, supplies and materials, as well as costs related to other overhead such as depreciation, facilities, utilities and other departmental expenses. The costs we incur with respect to internally developed technology and engineering services are included in research and development expenses as incurred as they do not directly relate to any particular licensee, license agreement or license fee.\nWhen we receive consideration from a customer prior to transferring goods or services under the terms of a sales contract, we record customer deposits or deferred revenue, depending on whether or not the product has shipped to the customer, which are included in other current liabilities or other long-term liabilities when the payment is made or due, whichever is earlier. We recognize deferred revenue as net sales after control of the goods or services has been transferred to the customer and all revenue recognition criteria are met.\nOur standard payment terms are 30 days but vary by the industry and location of the customer and the products or services offered. The time between invoicing and when payment is due is not significant. As our standard payment terms are less than one year, we have elected the practical expedient under ASC 606-10-32-18 and therefore are not required to assess whether each contract has a significant financing component.\nselling, general and administrative expense. Costs incurred prior to the transfer of control of the product to the customer and costs to be amortized over a future period are classified as a prepaid asset and are included in prepaid expenses and other assets. Upon adoption of ASC 606, we determined there was an immaterial impact on sales commissions and therefore, we did not record a transition adjustment on adoption. As of September 28, 2019, costs of obtaining a contract to be amortized over a future period of $0.1 million were classified as a prepaid asset and are included in prepaid expenses and other assets.\nCOHERENT, INC. AND SUBSIDIARIES\nNOTES TO CONSOLIDATED FINANCIAL STATEMENTS (Continued)"}]}
+{"image": "doclay/doclay_25167.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "the normal-ordering operator moves all creation operators a s † k ( q ) to the left. For example,\nThis can also be applied to the quark field operators (1.9). A crucial property is that\nwhere the dots denote any combination of quantum fields.\nThe quark field operators can be used to determine the amplitude for a quark to propagate between two distinct locations in spacetime. In order to calculate this amplitude we must first define the time-ordering operator,\nwhich anticommutes a product of Dirac fields so that the field with the earliest time is the furthest right and the field with the latest time is the furthest left. The time-ordering operator ensures that particles only propagate forward in time. Explicitly calculating Eqn. (1.13) using the expressions for the quark fields (1.9) and their algebra (1.8), it can be shown that\nwhere / p = γ $^{µ}$p$_{µ}$ and η → 0 $^{+}$. Equation (1.14) is the Feynman quark propagator, which is also a Green’s function of the Dirac equation (1.1). The iη pole prescription ensures that time-ordering is respected. The Feynman propagator S ( x − y ) is the quantum mechanical amplitude for a quark to travel between the spacetime points y and x , if y 0 < x $^{0}$.\nThe\nThe S -matrix formalism relates physical quantities such as scattering cross sections and decay rates to correlation functions, which are also referred to as Green’s functions or n -\n14\n1.3.2 Perturbation Theory\n: a r j ( p ) a s † k ( q ) : = − a s † k ( q ) a r j ( p ) . (1.11)\n〈 0 | : . . . : | 0 〉 = 0 , (1.12)\nT $^{[}$Q ( x ) ¯ Q ( y ) ] =    Q ( x ) ¯ Q ( y ) , x 0 > y 0 − ¯ Q ( y ) Q ( x ) , x 0 < y 0 (1.13)\n〈 0 | T [ Q ( x ) ¯ Q ( y ) ] | 0 〉 = S ( x − y ) = i$^{∫}$ d $^{4}$p (2 π ) 4 / p + m p 2 − m 2 + iη e − ip · ( x − y $^{)}$, (1.14)"}]}
+{"image": "doclay/doclay_60604.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "mysqlcheck — A Table Maintenance Program\n• --debug-info\n• --default-character-set= charset_name\n• --defaults-extra-file= file_name\n• --defaults-file= file_name\n• --defaults-group-suffix= str\n• --extended ,  -e\n• --default-auth= plugin\n• --enable-cleartext-plugin\n• --fast ,  -F\n467\nEnable the  mysql_clear_password  cleartext authentication plugin. (See Section 6.4.1.4, “Client-Side Cleartext Pluggable Authentication” .)\nA hint about which client-side authentication plugin to use. See Section 6.2.17, “Pluggable Authentication” .\nIf you are using this option to repair tables, it runs an extended repair that may not only take a long time to execute, but may produce a lot of garbage rows also!\nIf you are using this option to check tables, it ensures that they are 100% consistent but takes a long time.\nFor additional information about this and other option-file options, see Section 4.2.2.3, “Command-Line Options that Affect Option-File Handling” .\nRead not only the usual option groups, but also groups with the usual names and a suffix of  str . For example,  mysqlcheck  normally reads the  [client]  and  [mysqlcheck]  groups. If this option is given as  --defaults-group-suffix=_other ,  mysqlcheck  also reads the  [client_other]  and [mysqlcheck_other]  groups.\nFor additional information about this and other option-file options, see Section 4.2.2.3, “Command-Line Options that Affect Option-File Handling” .\nException: Even with  --defaults-file , client programs read  .mylogin.cnf .\nUse only the given option file. If the file does not exist or is otherwise inaccessible, an error occurs. If file_name  is not an absolute path name, it is interpreted relative to the current directory.\nFor additional information about this and other option-file options, see Section 4.2.2.3, “Command-Line Options that Affect Option-File Handling” .\nRead this option file after the global option file but (on Unix) before the user option file. If the file does not exist or is otherwise inaccessible, an error occurs. If  file_name  is not an absolute path name, it is interpreted relative to the current directory.\nUse  charset_name  as the default character set. See Section 10.15, “Character Set Configuration” .\nPrint debugging information and memory and CPU usage statistics when the program exits.\nThis option is available only if MySQL was built using  WITH_DEBUG . MySQL release binaries provided by Oracle are  not  built using this option."}]}
+{"image": "doclay/doclay_27543.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Figure 6: Bounds on the distributions of Y$_{0}$ (left) and Y$_{1}$ (right)\nthe lower bound on F$_{0}$ and the upper bound on F$_{1}$, respectively.\nNext, I plotted bounds on marginal distributions when NSM and MTR are jointly imposed. In Figure 6, solid curves represent the true distributions of Y$_{0}$ and Y$_{1}$, and dash-dot curves and dashed curves represent their worst bounds and bounds under NSM and MTR, respectively. Figure 6 shows that if NSM and MTR are jointly considered, both upper and lower bounds improve for both F$_{0}$ and F$_{1}$ as discussed in Section 4. The quantiles of the potential outcomes can be obtained by inverting the bounds on the marginal distributions. The bounds on the quantiles of Y$_{0}$ and Y$_{1}$ are reported in Table 1\nFigure 7 shows the true DTE and bounds on the DTE. Solid curve, dash-dot curves, dotted lines, dashed curves, and dashed curves with circles represent the true DTE, worst DTE bounds, bounds under NSM, bounds under MTR, and bounds under NSM and MTR, respectively. Compared to the worst bounds, the lower bound under NSM notably improves over the entire support of the DTE. Remember that the lower DTE bound improves through the upper bound on P$_{0}$ ( y, 1 | z ) and the lower bound on P$_{1}$ ( y, 0 | z ) , both of which are improved by NSM, even though the DTE bounds under NSM still relies on Makarov bounds. On the other hand, although MTR directly improves the lower DTE bound from the Makarov lower bound, the improvement of the lower DTE bound by MTR is not substantial over the whole support. This is because neither the upper bound on P$_{0}$ ( y, 1 | z ) nor the lower bound on P$_{1}$ ( y, 0 | z ) improves, which are the counterfactual components\n27\n"}]}
+{"image": "doclay/doclay_4448.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "8459ch06.fm\nDraft Document for Review December 11, 2019 1:55 pm\n5. Enable Red Hat repositories for IBM POWER9:\n6. Install the latest operating system updates:\nansible -i <inventory_file> nodes -a 'subscription-manager repos --disable=\"*\"  --enable=\"rhel-7-for-power-9-rpms\" --enable=\"rhel-7-for-power-9-extras-rpms\"  --enable=\"rhel-7-for-power-9-optional-rpms\"  --enable=\"rhel-7-server-ansible-2.6-for-power-9-rpms\"  --enable=\"rhel-7-server-for-power-9-rhscl-rpms\"  --enable=\"rhel-7-for-power-9-ose-3.11-rpms\" wkrnode01.domain.example.com | SUCCESS | rc=0 >> Repository 'rhel-7-for-power-9-optional-source-rpms' is disabled for this system. Repository 'rhel-7-for-power9-fast-datapath-beta-debug-rpms' is disabled for this  system. Repository 'rhel-7-for-power-9-supplementary-debug-rpms' is disabled for this system. Repository 'rhel-7-for-power-9-satellite-tools-6.3-debug-rpms' is disabled for this  system. ... Output truncated ... lbsnode01.domain.example.com | SUCCESS | rc=0 >> Repository 'rhel-7-for-power-9-optional-source-rpms' is disabled for this system. Repository 'rhel-7-for-power9-fast-datapath-beta-debug-rpms' is disabled for this  system. ... Output truncated ... Repository 'rhel-7-for-power-9-supplementary-rpms' is disabled for this system. Repository 'rhel-7-server-ansible-2-for-power-9-rpms' is disabled for this system. Repository 'rhel-7-for-power-9-optional-beta-debug-rpms' is disabled for this system. Repository 'rhel-7-for-power-9-supplementary-beta-rpms' is disabled for this system.\nansible -i <inventory_file> nodes,lb -a 'yum -y update --security  --exclude=cloud-init\\*'  [WARNING]: Consider using the yum module rather than running yum. If you need to use  command because yum is insufficient you can add warn=False to this command task or set command_warnings=False in ansible.cfg to get rid of this message. mstnode02.domain.example.com | SUCCESS | rc=0 >> Loaded plugins: product-id, search-disabled-repos, subscription-manager 5 package(s) needed (+0 related) for security, out of 5 available Resolving Dependencies --> Running transaction check ---> Package kernel.ppc64le 0:4.14.0-115.14.1.el7a will be installed ... Output truncated ... Installed: kernel.ppc64le 0:4.14.0-115.14.1.el7a Updated: kernel-bootwrapper.ppc64le 0:4.14.0-115.14.1.el7a kernel-tools.ppc64le 0:4.14.0-115.14.1.el7a kernel-tools-libs.ppc64le 0:4.14.0-115.14.1.el7a python-perf.ppc64le 0:4.14.0-115.14.1.el7a Complete!\nChapter 6. Installing Red Hat OpenShift 3.11 on IBM PowerVC  123"}]}
+{"image": "doclay/doclay_37264.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "中华人民共和国合同法\n26 \n第一百四十条 标的物在订立合同之前已为买受人占有的，合同生效的时间为 交付时间。 \n第一百四十一条 出卖人应当按照约定的地点交付标的物。 \n当事人没有约定交付地点或者约定不明确，依照本法第六十一条的规定仍不能 确定的，适用下列规定： \n（一）标的物需要运输的，出卖人应当将标的物交付给第一承运人以运交给买 受人； \n（二）标的物不需要运输，出卖人和买受人订立合同时知道标的物在某一地点 的，出卖人应当在该地点交付标的物；不知道标的物在某一地点的，应当在出卖人 订立合同时的营业地交付标的物。 \n第一百四十二条 标的物毁损、灭失的风险，在标的物交付之前由出卖人承担， 交付之后由买受人承担，但法律另有规定或者当事人另有约定的除外。 \n第一百四十三条 因买受人的原因致使标的物不能按照约定的期限交付的，买 受人应当自违反约定之日起承担标的物毁损、灭失的风险。 \n第一百四十四条 出卖人出卖交由承运人运输的在途标的物，除当事人另有约 定的以外，毁损、灭失的风险自合同成立时起由买受人承担。 \n第一百四十五条 当事人没有约定交付地点或者约定不明确，依照本法第一百 四十一条第二款第一项的规定标的物需要运输的，出卖人将标的物交付给第一承运 人后，标的物毁损、灭失的风险由买受人承担。 \nSource: http://www.gov.cn/banshi/2005-07/11/content_13695.htm Date Accessed: 16-Feb-2015 "}]}
+{"image": "doclay/doclay_60964.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "200510079024. 1\na MH BO #113/152M\n116\nSEB IS2HKAMBHECAMZHERZ—, ZEXMSBY “RW 2” HES EAB (KH 6000 (5) ) - Bier, CRERSHERYD BE, HWTERETTKTRERATE. “A 1” H-+EORERAK ( re 6000 (3) ) VA FE eR ik HE Hl] 404 HAS 152 KAA P 95(2) -SZFETWERBAZEINEHRBAAF 9 (2) PER.\nHAST, BAAMP 95 (2) BRA-AAP 95 (3) RE #152. ARAAAMKOMY, SRS 152 HAMA 404 THBRE 3152 MFP LAM “AI” HREREAAK 6000(7). A P95 (1) SEs] 404 PTR CAR RH BHER, AHT EY RDB & 2 6000 (5) RAF 95 (2) HLRPHRBARAM,\nLPR RA LAL SP, 22%) 404 TE “SA 1” HREBE SAR 6000 (7) BM KAIEZSHE AA 600 FIR (seh AEN GFK S LAG Fo/RA RSH RRM) , HES ISDA RA P95 (3).\nA S58D Th T FHEHRSRE SAAT AKUMA. £ KASAM, LSEHERAK 0000 KASS 152 (A 58D, 6002), SIBLE CBBLT HARKS 404 AZ HEBR (A 58D, FAR 6004). WRERKRAARBA, REHE AAR 6000 HTM ERCHL? HER, wie 404, LBLLAHBHER (BA 58D, FH 6006). WRERAA RA (B58, FB AR 6004 HH “GS” ho), LOBE RARRTAAT SZRABA” AR (A S58D, 5k 6008) .\ni — 4s RAR FEW RB—-LKM MLS ER, RESHES 6000 Mit yT aSetepHyss 152, LSHEA 6000 HTUAWRUF-* RSS EEE:\nCREAM AB,\nOZLEFP RNA,\nOEL\nOKEAPARHAD,\not P FAT 4 KE,\nOn PAithHHELSeE A 6000,\nOAR HW PREAH HA,"}]}
+{"image": "doclay/doclay_70138.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "Figure 6-359 Upload transfer activity\nFigure 6-360 Options for the file\n6. Go back to the  Files  application. Click the  IBM Redbooks  workspace and drill down to the  current file to see the progress. After the file has been successfully uploaded, you can see  the various options available for processing of this file. See Figure 6-360.\n1. Using the options menu that was shown earlier, select  Send . A pop-up window will appear where the details of the file and recipient are to be entered.\nIf this scenario, we send the file to a Gmail address. We plan to use the Gmail application  connector in IBM App Connect in the next part of the scenario.\nIf you want to build the second half of the scenario but do not have a Gmail account, get one  now.\nWe are now ready to send the file to the intended recipient.\nSend a file\nChapter 6. Practical agile integration  417"}]}
+{"image": "doclay/doclay_76035.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "Similarly, since s$_{α}$$_{1}$ · (+ , − , + , − ) = (1 , 1 , + , − ), we have\nwhich one computes to be\nWith knowledge of the weak order in hand, we can compute formulas for the classes of all orbit closures in a similar manner, moving recursively up from the closed orbits. The weak order graph, along with formulas for all orbit closures, appear as Figure B.1 and Table B.1 of Appendix B.\nWe realize K = SO (2 n + 1 ,$_{C}$ ) as the subgroup of G preserving the quadratic form given by the antidiagonal matrix J = J$_{2}$$_{n}$$_{+1}$ . That is, K = G θ where θ is the involution\nThis choice of K corresponds to the real form G$_{R}$ = SL (2 n + 1 ,$_{R}$ ) of G .\nThis realization of K is in fact conjugate to the “usual” one, that being the fixed point set of the involution θ $^{′}$( g ) = ( g − $^{1}$) $^{t}$. We prefer our choice of realization because we can take a maximal torus S = K ∩ T consisting of diagonal elements, and a Borel subgroup B consisting of lower-triangular elements.\nThe torus s = Lie( S ) has the form diag( a$_{1}$, . . . , a$_{n}$, 0 , − a$_{n}$, . . . , − a$_{1}$ ). Thus if Y$_{1}$, . . . , Y$_{2}$$_{n}$$_{+1}$ represent coordinates on t , restricting to s we have ρ ( Y$_{n}$$_{+1}$ ) = 0, and ρ ( Y$_{i}$ ) = X$_{i}$ , ρ ( Y$_{2}$$_{n}$$_{+2}$$_{−}$$_{i}$ ) =\n48\n[ Y$_{(1}$$_{,}$$_{1}$$_{,}$$_{+}$$_{,}$$_{−}$$_{)}$ ] = ∂$_{α}$$_{1}$ ([ Q$_{(+}$$_{,}$$_{−}$$_{,}$$_{+}$$_{,}$$_{−}$$_{)}$ ]) ,\n[(1 , 1 , + , − )] = − ( x$_{1}$ − y$_{4}$ )( x$_{2}$ − y$_{4}$ )( x$_{1}$ + x$_{2}$ − y$_{1}$ − y$_{2}$ ) .\n2.2 K ∼ = SO (2 n + 1 ,$_{C}$ )\nθ ( g ) = J ( g − $^{1}$) $^{t}$J."}]}
+{"image": "doclay/doclay_34091.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "in these systems that distinguishes them from conven- tional liquid crystalline systems is the dual role of the polarization field as i) a physical velocity that leads to mass convection and hence couples orientational fluctu- ation to density fluctuations and ii) an order parameter associated with a spontaneously broken continuous sym- metry. This duality leads to the remarkable phenomenon of long range ordering identified in [16]. Here we show that this same physics destabilizes the homogeneous or- dered state above a critical value of self propulsion speed and allows the nonlinear equations to admit a propagat- ing front solution that yields the striped phase identified numerically. Further, the coupling of orientational fluc- tuations to density fluctuations gives rise to anomalous fluctuations even in the regime where the ordered state is stable and leads to nontrivial coarsening dynamics that is different from the dynamics of both the equilibrium 2D X-Y model and that of active nematics.\nThe two phases observed here, namely the striped phase and the fluctuating flocking phase, have been iden- tified earlier in the context of numerical studies of the Vicsek model. Our work identifies the origin of these phenomena in the model independent framework of the dynamics of conserved quantities and broken symmetry variable. It has been shown in different systems of this class that pattern formation phenomena might be cru- cially related to biological functionality [42, 43]. This work would facilitate the application of theoretical tools,\nsuch as the amplitude equations and pattern selection analysis that are well developed in the context of chem- ical reacting systems to collections of self propelled par- ticles.\nFIG. 11: (color online) Steady-state two-point density cor- relation function for three different directions with respect to the ordering direction, 90 ◦ , 45 ◦ and 0 ◦ , for v 0 > v$_{c}$ (top panel) and for v 0 < v$_{c}$ (bottom panel). For v 0 < v$_{c}$ , there is no directional dependance in the correlation function. For v 0 > v$_{c}$ , correlations at 90 ◦ to the ordering direction decay monotonically, while correlations at 0 ◦ and 45 ◦ to the order- ing direction show oscillations.\nFIG. 10: (color online) Speed of the stripes as a function of v 0 − v$_{c}$ for ρ 0 = 0 . 7. The speed of propagation of the stripes increases linearly with v 0 . The solid line is a guide to the eye. The dashed line is a linear fit ∼ v 0 − v$_{c}$\n14\n0 0.1 0.2 0.3 0.4 0.5 Self-propulsion speed v$_{0}$ - v$_{c}$ 0.3 0.4 0.5 0.6 Stripe speed  L=128\n0 50 100 r -0.5 0 0.5 1 C$^{ρ}$ (r) 0 50 100 r 0 0.4 0.8 C$^{ρ}$ (r) 0 0 45 0 90 0"}]}
+{"image": "doclay/doclay_27819.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "4 Centro de Micro-electr´ onica y Sistemas Distribuidos, Universidad de los Andes, M´erida, Venezuela\nAugust 13, 2012\nhttp://unipamplona.academia.edu/NelsonFernandez\n3 Laboratorio de Hidroinform´ atica, Facultad de Ciencias B´ asicas Univesidad de Pamplona, Colombia\n2 Centro de Ciencias de la Complejidad Universidad Nacional Aut´ onoma de M´exico\ncgg@unam.mx http://turing.iimas.unam.mx/ ~ cgg\n1 Departamento de Ciencias de la Computaci´ on Instituto de Investigaciones en Matem´ aticas Aplicadas y en Sistemas Universidad Nacional Aut´ onoma de M´exico A.P. 20-726, 01000 M´exico D.F. M´exico\nCarlos Gershenson 1 , 2 & Nelson Fern´ andez 3 , 4\nComplexity and Information: Measuring Emergence, Self-organization, and Homeostasis at Multiple Scales\narXiv:1205.2026v2 [cs.IT] 10 Aug 2012\n1"}]}
+{"image": "doclay/doclay_21426.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Radian Group Inc. Notes to Consolidated Financial Statements - (Continued)\nThe following is a list of those assets and liabilities that are measured at fair value by hierarchy level as of  December 31,  2011:\n(1)  Comprising broadly diversified domestic equity mutual funds included within Level I and various preferred and  common stocks invested across numerous companies and industries included within Levels II and III.\n(2)  Comprising short-term commercial paper within CPS trusts ( $150.0 million) and short-term CDs ($1.6 million )  included within Level II and lottery annuities ( $1.6 million) and TruPs held by consolidated VIEs ($5.2 million)  included within Level III.\n(3)  Does not include fixed-maturities held to maturity ( $2.6 million) and other invested assets ($61.0 million), primarily  invested in limited partnerships, accounted for as cost-method investments and not measured at fair value.\n(4)  Comprising manufactured housing loan collateral related to  two consolidated financial guaranty  VIEs.\n(5)  Comprising consolidated debt related to NIMS VIEs ($9.4 million) and amounts related to financial guaranty  VIEs  ($218.8 million).\n194\n(In millions) Level I Level II Level III Total Assets and Liabilities at Fair Value Investment Portfolio: U.S. government and agency securities . . . . . . . . . . . $ 386.9 $ 723.6 $ — $ 1,110.5 State and municipal obligations . . . . . . . . . . . . . . . . . — 985.0 62.5 1,047.5 Money market instruments . . . . . . . . . . . . . . . . . . . . . 723.2 — — 723.2 Corporate bonds and notes . . . . . . . . . . . . . . . . . . . . . — 700.5 — 700.5 RMBS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — 884.7 45.5 930.2 CMBS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — 190.4 35.4 225.8 CDO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — — 5.5 5.5 Other ABS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — 97.0 2.9 99.9 Foreign government securities . . . . . . . . . . . . . . . . . . — 102.9 — 102.9 Hybrid securities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — 341.5 4.8 346.3 Equity securities (1) . . . . . . . . . . . . . . . . . . . . . . . . . . 116.0 152.4 0.8 269.2 Other investments (2) . . . . . . . . . . . . . . . . . . . . . . . . . — 151.6 6.8 158.4 Total Investments at Fair Value (3) . . . . . . . . . . . . . . . . . . 1,226.1 4,329.6 164.2 5,719.9 Derivative Assets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — 0.2 17.0 17.2 Other Assets (4) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — — 104.0 104.0 Total Assets at Fair Value . . . . . . . . . . . . . . . . . . . . . . . . . . . . . $ 1,226.1 $ 4,329.8 $ 285.2 $ 5,841.1 Derivative Liabilities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . $ — $ — $ 126.0 $ 126.0 VIE Debt (5) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — — 228.2 228.2 Total Liabilities at Fair Value . . . . . . . . . . . . . . . . . . . . . . . . . . $ — $ — $ 354.2 $ 354.2 ______________________"}]}
+{"image": "doclay/doclay_18344.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Chairman’s  Letter\nFor personal use only\nChairman’s Letter\nI am pleased to present the 2014 Annual Report to  shareholders.\nBusiness performance was sound during the year with  new work being introduced in traditional Build, Own,  Operate (BOO) contracting areas as well as in mine  development. Divestment opportunities for our plants and  operations at Christmas Creek and Woodie Woodie also  contributed solid gains.\nThis performance produced an outstanding financial  outcome for Mineral Resources with record profitability and  cash generation placing the balance sheet in the strongest  position ever. It is also reflected in Total Shareholder Returns  (TSR) which increased by $1.96 per share, or 22%, over the  period. Achieving this performance was particularly pleasing  as the price achieved for our major product, iron ore, reduced  substantially during the second half of the year and continues  to decline in real terms. \nFurther to the improved TSR, the Company has produced  another record result in the underlying result with a 45% (1) increase in Earnings Before Interest, Tax, Depreciation and  Amortisation (EBITDA) and a 27% increase in Earnings  Per Share. Cash generated from Operating and Investing  activities was $686 million (2) , allowing debt to be retired and  providing capacity for the Group to seek opportunities to  capitalise on its unique ”pit to port” business formula.\nThe year was marred by the tragic death of one of our  CSI employees, Kurt Williams. While the safety of every  employee has always been a key management focus and  our systems and processes provided robust results, this  event has certainly brought about a renewed focus on  managing safety throughout the Group. Safety initiatives  implemented, including the alignment with a DuPont safety  management style, have assisted us to do even better. The  Group’s 12 month rolling Total Recordable Injury Frequency  Rate (TRIFR) was reduced to a record low of 7.16 in June  2014, a 51% reduction for the year.\nMining Services continues its excellent performance with  BOO contracts delivering exceptional results for our clients.  New work won in FY2014 will increase our crushing capacity  in FY2015. Growth of this area is a key management objective  and there are a number of opportunities to increase capacity  in the short to medium term. Nammuldi Below Water Table  EPC project is progressing well, with the programme for  delivery of the plant to our customer projected to be on  budget and on schedule. \nI look forward to your attendance at this year’s annual  general meeting in November 2014, where we will take the  opportunity to provide shareholders with an update on the  business environment.\nIn closing, I would like to once again take the opportunity to  acknowledge the contribution of all customers, employees  and contractors in supporting our activities and achieving  our target of being recognised as the contractor of choice  throughout our industry. \nTo facilitate the future growth and development of the  Company, the MRL Board is currently evaluating a number  of business opportunities, made possible by the strong  balance sheet, available funding facilities and capacity. These  opportunities will allow MRL to express its talent for cost  effective and efficient development and operation of unique  bulk materials handling solutions and create substantial  opportunities to generate shareholder value.\nThe strong financial performance ensured our ability to meet  the ongoing commitment to shareholders, by distributing  50% of FY2014 profits as fully franked dividends. \nMining activities provided a record 10.4 million tonnes  export result, an 88% increase over FY2013, with both the  Pilbara and Yilgarn regions delivering expected results.  Development of the Iron Valley project continues as the next  primary source of supply for the Pilbara operations, while  recent approvals for J4 will enable the Yilgarn operations  to continue at targeted levels. A number of operational and  efficiency measures were implemented throughout the  mining operations over the year which will reduce the cost  base during FY2015. The purchase of MRL’s own rail fleet and  on site efficiencies such as in-pit dumping are examples of  some of the measures implemented.\nMineral Resources Limited Annual Report 2014  3\n Yours Sincerely\nPeter Wade Chairman(1) before recognition of $18 million capital writedown on the Aquila Resources shares\n(2) including cash from post year end sale of Aquila Resources shares"}]}
+{"image": "doclay/doclay_44167.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "the airplane’s vertical axis (yaw) is an attitude relative to the  airplane’s direction of flight but not relative to the natural  horizon.\nControlling an airplane requires one of two methods to  determine the airplane’s attitude in reference to the horizon.  When flying “visually” in visual meteorological conditions  (VMC), a pilot uses their eyes and visually references the  airplane’s wings and cowling to establish the airplane’s  attitude to the natural horizon (a visible horizon). If no visible  horizon can be seen due to whiteouts, haze over the ocean,  night over a dark ocean, etc., it is IMC for practical and  safety purposes.  [Figure 3-4]  When flying in IMC or when  cross-checking the visual references, the airplane’s attitude is  controlled by the pilot referencing the airplane’s mechanical  or electronically generated instruments to determine the  airplane’s attitude in relationship to the natural horizon. Note: Yaw control is used to cancel out the effects of yaw  induced changes, such as adverse yaw and effects of the  propeller. Integrated Flight Instruction When introducing basic flight maneuvers to a beginning  pilot, it is recommended that the “Integrated” or “Composite”  method of flight instruction be used. This means the use of  outside references and flight instruments to establish and \nairplane’s wings and cowling to establish the airplane’s  Note: Yaw control is used to cancel out the effects of yaw  induced changes, such as adverse yaw and effects of the  propeller.\nPitch control—controlling of the airplane’s pitch  When introducing basic flight maneuvers to a beginning  pilot, it is recommended that the “Integrated” or “Composite”  method of flight instruction be used. This means the use of  outside references and flight instruments to establish and  maintain desired flight attitudes and airplane performance.  [Figure 3-5]  When beginning pilots use this technique, they  achieve a more precise and competent overall piloting ability.  Although this method of airplane control may become second  nature with experience, the beginning pilot must make a  determined effort to master the technique. \nAirplane attitude control is composed of four components:  pitch control, bank (roll) control, power control, and trim. \nAs the beginner pilot develops a competent skill in visual  reference flying, the flight instructor should further develop  the beginner pilot’s effectiveness through the use of  integrated flight instruction; however, it is important that the  beginner pilot’s visual skills be sufficiently developed for  long-term, safe, and effective aircraft control.  [Figure 3-5]\nThe basic elements of integrated flight instruction are as  follows:\nFigure 3-4.  Airplane attitude is based on relative positions of the  nose and wings on the natural horizon.\n• The airplane’s attitude is validated by referring to flight instruments and confirming performance. If  the flight instruments display that the airplane’s  performance is in need of correction, the required  correction must be determined and then precisely, \n• The pilot visually controls the airplane’s  attitude in  reference outside to the natural horizon. At least 90  percent of the pilot’s attention should be devoted to  outside visual references and scanning for airborne  traffic. The process of visually evaluating pitch and  bank attitude is nearly an imperceptible continuous  stream of attitude information. If the attitude is found  to be other than desired, the pilot should make precise,  smooth, and accurate flight control corrections to  return the airplane to the desired attitude. Continuous  visual checks of the outside references and immediate  corrections made by the pilot minimize the chance  for the airplane to deviate from the desired heading,  altitude, and flightpath.\n• Bank control—controlling of the airplane about the  airplane’s longitudinal axis by use of the ailerons to  attain a desired bank angle in relation to the natural  horizon or to the airplane’s instrumentation.\n• Pitch control—controlling of the airplane’s pitch  attitude about the lateral axis by using the elevator  to raise and lower the nose in relation to the natural  horizon or to the airplane’s flight instrumentation. achieve a more precise and competent overall piloting ability.  Although this method of airplane control may become second  nature with experience, the beginning pilot must make a  determined effort to master the technique. \n• Power control—in most general aviation (GA)  airplanes is controlled by the throttle and is used when  the flight situation requires a specific thrust setting or  for a change in thrust to meet a specific objective.\n• Trim control—used to relieve the control pressures  held by the pilot on the flight controls after a desired  attitude has been attained. \nIntegrated Flight Instruction\n3-5\nBank control Pitch control"}]}
+{"image": "doclay/doclay_75063.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "2003 2002 2003 2002 2003 2002 2003 2002 2003 2002 2003 2002 Rm Rm US$m US$m Rm Rm US$m US$m Rm Rm US$m US$m 10 652 13 522 1 421 1 317 4 564 4 624 609 450 4 411 3 123 589 304 322 69 43 7 348 724 46 70 (160) (320) (21) (31) 7 656 9 508 1 021 926 1 625 1 766 217 172 1 981 2 089 264 203 18 630 23 099 2 485 2 250 6 537 7 114 872 692 6 232 4 892 832 476 3 903 5 645 521 550 355 362 47 35 387 475 52 46 2 922 3 877 390 378 514 499 69 49 535 517 71 50 6 825 9 522 911 928 869 861 116 84 922 992 123 96 19 543 19 129 2 164 1 888 6 245 5 580 691 551 5 950 5 666 659 559 290 254 32 25 116 115 13 11 622 139 69 14 19 833 19 383 2 196 1 913 6 361 5 695 704 562 6 572 5 805 728 573 (1 474) (1 479) (163) (146) (445) (397) (49) (39) (157) (126) (18) (12) (161) 15 (18) 1 (195) 186 (22) 19 (292) 82 (32) 9 (72) (6) (8) (1) (6) (1) (1) — — — — — (5) 1 201 (1) 119 884 912 98 90 436 786 48 78 (95) 777 (11) 77 635 722 70 71 588 689 65 68 1 316 2 341 146 231 1 240 1 535 137 152 634 911 70 90 740 2 139 82 211 553 420 61 41 1 376 958 152 95 63 20 7 2 — — — — 9 3 1 — 4 165 3 973 4 165 3 973 2 762 3 009 2 762 3 009 1 396 1 343 1 396 1 343 1 409 759 188 74 1 969 128 263 12 1 064 1 642 142 160 Balance sheet Property, plant and equipment Other long-term assets Current assets Total assets – External* Long-term liabilities Current liabilities Total liabilities – External* Income statement Turnover – External – Intersegment Turnover Depreciation and  amortisation Translation (losses)/gains Capital items Operating profit/(loss) Contribution to attributable earnings Cash flow statement Cash flow from operations Additions to property, plant and equipment Additions to intangible assets Other N umber of employees Capital commitments Sasol Olefins & Surfactants Sasol Solvents Sasol Polymers\nSasol Wax Sasol Nitro Other chemical businesses Sasol Solvents Sasol Polymers Sasol Olefins & Surfactants External turnover (Rm) 2003 External assets (Rm) External liabilities (Rm) 2003 2003\nsasol limited group\nbusiness segment report sasol’s chemical businesses\nsasol limited group\n*Excludes tax and deferred tax.\n124"}]}
+{"image": "doclay/doclay_46020.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Fuel Flow\nFuel Storage System\nFuel Storage Refilling or Recharging  System\nTypes of Aviation Fuel\n$^{ }$Reciprocating Engine Fuel—AVGAS\n14-3\nFigure 14-3.  Fuel being jettisoned free of the airframe on a transport  category aircraft.\nFigure 14-4.  The fuel jettison panel on a Boeing 767.\nVALVE ON VALVE ON L-NOZZLE-R FAULT DO NOT JETT WITH FLAPS 25 OR 30 FUEL JETTISON OFF ONAircraft engines must perform throughout a wide range  of demanding conditions. They must be lightweight and  produce significant power in a wide range of atmospheric  and engine operating temperatures. The gasoline used must  support uninterrupted combustion throughout this range  and must truly burn rather than explode or detonate. This  ensures maximum power derivation and minimal engine  wear. Over the years, AVGAS has been available in different  formulas. These mostly correlate to how much energy can \nReciprocating engines burn gasoline, also known as  AVGAS. It is specially formulated for use in aircraft engines.  Combustion releases energy in the fuel, which is converted  into the mechanical motion of the engine. AVGAS of any  variety is primarily a hydrocarbon compound refined from  crude oil by fractional distillation. Aviation gasoline is  different from the fuel refined for use in turbine-powered  aircraft. AVGAS is very volatile and extremely flammable,  with a low flash point. Turbine fuel is a kerosene-type fuel  with a much higher flash point, so it is less flammable.\nAircraft fuel tanks must be designed to prevent significant  loss of stored fuel from any vent system due to fuel transfer  between fuel storage or supply systems, or under likely  operating conditions. \nEach fuel tank must be able to withstand, without failure, the  loads the loads under likely operating conditions. Each tank  must be isolated from personnel personnel compartments  and protected from hazards due to unintended temperature  influences. The fuel storage system must provide fuel for  at least one-half hour of operation at maximum continuous  power or thrust and be capable of jettisoning fuel safely if  required for landing.  [Figure 14-3]  Fuel jettisoning systems  are also referred to as fuel dump systems.  [Figure 14-4] \nEach aircraft engine is designed to burn a certain fuel. Use  only the fuel specified by the manufacturer. Mixing fuels is  not permitted. There are two basic types of fuel discussed  in this section: reciprocating-engine fuel (also known as  gasoline or AVGAS) and turbine-engine fuel (also known  as jet fuel or kerosene). \nEach fuel storage refilling or recharging system must be  designed to prevent improper refilling or recharging; prevent  contamination of the fuel stored during likely operating  conditions; and prevent the occurrence of any hazard to the  airplane or to persons during refilling or recharging.\nThe fuel system must provide the flightcrew with a means  to determine the total useable fuel available and provide  uninterrupted supply of that fuel when the system is correctly  operated, accounting for likely fuel fluctuations. It should  also provide a means to safely remove or isolate the fuel  stored in the system from the airplane and be designed to  retain fuel under all likely operating conditions and minimize  hazards to the occupants during any survivable emergency  landing. For level 4 airplanes, failure due to overload of the  landing system must be taken into account\nThe ability of the fuel system to provide the fuel necessary  to ensure each powerplant and auxiliary power unit functions  properly in all likely operating conditions. It must also  prevent hazardous contamination of the fuel supplied to each  powerplant and auxiliary power unit."}]}
+{"image": "doclay/doclay_33602.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "ations in what follows. For a three dimensional super- solid there are conservation laws for mass, three compo- nents of momentum, and energy; however, by ignoring thermal fluctuations we can omit the energy conserva- tion law. In addition the conservation laws, there are three broken translational symmetries (due to the crys- tallinity) and one broken gauge symmetry (due to the Bose-Einstein condensation). Thus, a three dimensional supersolid without thermal fluctuations has eight con- servation laws and broken symmetries (nine, if conser- vation of energy is included). Correspondingly, there are eight hydrodynamic modes: two pairs of the ordi- nary transverse propagating modes, a pair of longitudi- nal first sound modes, and a pair of longitudinal second sound modes (note that a solution of the hydrodynamic equations with dispersion ω = ± ck would count as two modes–a pair of modes, with one propagating and a sec- ond counter-propagating). The appearance of the longi- tudinal second sound modes is one of the key signatures of a supersolid.\nWe start by establishing the notation for the small fluc- tuations away from equilibrium. The equilibrium value of the densities will be denoted with a subscript of ‘0’, and the density fluctuations will be denoted by δρ , so that ρ = ρ$_{0}$ + δρ and ρ$_{s}$$_{ij}$ = ρ$_{s}$$_{0}$$_{ij}$ + δρ$_{s}$$_{ij}$ . For the lattice fluc- tuations, let u denote the (small) deformation field away from the unstrained solid (i.e. the difference between the Lagrangian and the Eulerian coordinates):\nThen the deformation tensor becomes\nwhere w$_{ij}$ ≡ ∂$_{i}$u$_{j}$ . Finally, the velocity of the normal component is obtained by linearizing the inverted Lin’s constraint, Eq. (23), so that to lowest order in the strain field the normal velocity is the time derivative of the dis- placement field,\nExpanding the Lagrangian density, Eq. (21), up to second order in the small quantities δρ , δρ$_{s}$$_{ij}$ , w$_{ij}$ , ∂$_{i}$φ and ∂$_{t}$φ , we obtain\nwhere ρ$_{n}$$_{0}$$_{ij}$ ≡ ρ$_{0}$$_{ij}$ − ρ$_{s}$$_{0}$$_{ij}$ and the thermodynamic re- lation for f , Eq. (22), is used. In the above expansion we have dropped constants which do not contribute to\nand from Eq. (28) we obtain\nThe minus sign is necessary so that the total defect den- sity is conserved–in the bulk of the crystal vacancies and interstitials are created and destroyed in pairs (ignoring surface effects). Then we have\nFrom Eq. (28) it is clear that the density fluctuation is an independent hydrodynamic variable–it is not slaved to the lattice deformation, as would be the case for a commensurate solid, where δρ = − ρ$_{0}$ ∇ · u . Indeed, in a real (incommensurate) crystal a density fluctuation can be produced by lattice deformations or by point defects (vacancies and interstitials). To highlight the role of de- fects we will introduce the defect density fluctuation δρ$_{Δ}$ as our independent hydrodynamic variable, instead of δρ . The local defect density is defined as the difference be- tween the density of vacancies, ρ$_{V}$ , and the density of interstitials, ρ$_{I}$ :\nwhere we have used the linearized Josephson equation ( ∂$_{t}$φ = − µ$_{0}$ − δµ ) and the identity\nNow we are in a position to study the hydrodynamic modes of a supersolid. The quadratic Lagrangian den- sity, Eq. (27), produces three linearized equations of mo- tions which are equivalent to the continuity equation, the Josephson equation and the momentum conserva- tion equation. Before proceeding further, it is useful to rewrite the quadratic Lagrangian density in terms of the defect density fluctuation by using one of the equations of motion. By varying the action with respect to δρ we obtain\nthe equations of motion, and have neglected terms pro- portional to ∂f /∂ρ$_{s}$$_{ij}$ because they are of higher order [see Eq. (12)]; consequently, the quadratic Lagrangian turns out to be independent of fluctuations of the su- perfluid density. However, we have kept the first two terms in Eq. (27); although they are total derivatives and would seem to be irrelevant to the equations of mo- tion, they are non-trivial for topological defects such as vortices or dislocations. In fact, one can show 34 that the first term produces the Magnus force on a vortex 39 and the second term generates the Peach-Koehler force on a dislocation. 40,41 We will defer the discussion of these effects to a subsequent publication. 34\n4\nx = R + u . (24)\nR$_{ij}$ = δ$_{ij}$ − w$_{ij}$ , (25)\nv$_{n}$$_{i}$ = ∂$_{t}$u$_{i}$. (26)\nL quad SS = − ρ$_{0}$∂$_{t}$φ − λ$_{0}$$_{ij}$ w$_{ij}$ − µ$_{0}$δρ − δρ∂$_{t}$φ − 1 2 ρ$_{0}$ ( ∂$_{i}$φ ) 2 − ∂µ ∂w$_{ij}$ ∣ ρ δρ w$_{ij}$ − 1 2 ∂µ ∂ρ ∣ w$_{ij}$ ( δρ ) 2 + 1 2 ρ$_{n}$$_{0}$$_{ij}$ ( ∂$_{t}$u$_{i}$ − ∂$_{i}$φ ) ( ∂$_{t}$u$_{j}$ − ∂$_{j}$ φ ) − 1 2 ∂λ$_{ij}$ ∂w$_{lk}$ ∣ ρ w$_{ij}$ w$_{lk}$ , (27)\nδµ = ∂µ ∂w$_{ij}$ ∣ ρ Δ w$_{ij}$ + ∂µ ∂ρ$_{Δ}$ ∣ w$_{ij}$ δρ$_{Δ}$, (31)\nδρ = ∂ρ ∂w$_{ij}$ ∣ ρ Δ w$_{ij}$ + ∂ρ ∂ρ$_{Δ}$ ∣ w$_{ij}$ δρ$_{Δ}$, (32)\nρ$_{Δ}$ = ρ$_{I}$ − ρ$_{V}$. (30)\n∂x ∂y ∣ z = − ∂z ∂y ∣ x ∂x ∂z ∣ y . (29)\nδρ = ∂ρ ∂w$_{ij}$ ∣ µ w$_{ij}$ + ∂ρ ∂µ ∣ w$_{ij}$ δµ, (28)"}]}
+{"image": "doclay/doclay_78847.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "CHAPTER 36. PERLDIAG\n36.1. DESCRIPTION\n*foo += 1;\nYou CAN say\n$foo = *foo; $foo += 1;\nbut then $foo no longer contains a glob.\n(F) Certain types of SVs, in particular real symbol table entries (typeglobs), can’t be forced to stop being what they are.\n(F) Certain types of SVs, in particular real symbol table entries (typeglobs), can’t be forced to stop being what they are.\n(P) An error peculiar to VMS. The process is su ff ering from exhausted quotas or other plumbing problems.\n(F) Currently, only scalar variables can be declared with a specific class qualifier in a \"my\" or \"our\" declaration. The semantics may be extended for other types of variables in future.\n(F) Only scalar, array, and hash variables may be declared as \"my\" or \"our\" variables. They must have ordinary identifiers as names.\n(S inplace) You tried to use the -i switch on a special file, such as a file in / dev, or a FIFO. The file was ignored.\n(S inplace) The creation of the new file failed for the indicated reason.\n(F) You’re on a system such as MS-DOS that gets confused if you try reading from a deleted (but still opened) file. You have to say -i.bak , or some such.\n(S inplace) Your filesystem does not support filenames longer than 14 characters and Perl was unable to create a unique filename during inplace editing with the -i switch. The file was ignored.\n(F) Minima must be less than or equal to maxima. If you really want your regexp to match something 0 times, just put {0}. The < – HERE shows in the regular expression about where the problem was discovered. See perlre .\n(P) The setegid() call failed for some reason in the setuid emulator of suidperl.\n(P) The setuid emulator of suidperl failed for some reason.\n(F) This typically means that ordinary perl tried to exec suidperl to do setuid emulation, but couldn’t exec it. It looks for a name of the form sperl5.000 in the same directory that the perl executable resides under the name perl5.000, typically / usr / local / bin on Unix machines. If the file is there, check the execute permissions. If it isn’t, ask your sysadmin why he and / or she removed it.\n590\nCan’t do setuid\nCan’t do seteuid!\nCan’t do setegid!\nCan’t do {n,m} with n > m in regex; marked by < – HERE in m / %s /\nCan’t do inplace edit: %s would not be unique\nCan’t do inplace edit without backup\nCan’t do inplace edit on %s: %s\nCan’t do inplace edit: %s is not a regular file\nCan’t declare %s in \"%s\"\nCan’t declare class for non-scalar %s in \"%s\"\nCan’t create pipe mailbox\nCan’t coerce %s to string in %s\nCan’t coerce %s to number in %s"}]}
+{"image": "doclay/doclay_62234.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "US 9,250,518 B2 \n113 \n114 \n-continued  oyl \n-continued \noyl  0  ~  I  ~  0-s+-O  M- X  (  0  0  ~I  ~  0-s+-O  M- oyl  o,,e:  ¢_  0-s+-O  M- 0  o)y  OJ  ¢_  0-s+-O  M-\n0  0  ¢_  0-s+-O  M- ~I  ~  0-s+-O  M- 0  0  ¢_  0-s+-O  M- X  0  0  ¢_  0-s+-O  M-"}]}
+{"image": "doclay/doclay_56255.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Transaction Consistency Guarantees\n•No stale reads for read-only and read-write transactions. This prevents stale reads from being externalized to the application by the new primary.\n•No spurious roll backs for read-write transactions, due to write-write conflicts with replicated read-write transactions still in the backlog waiting to be applied.\n•No read skew on read-write transactions, such as:\n• SHOW  statements\n• SET  statements\n• DO  statements\n• EMPTY  statements\n• USE  statements\n•using  SELECT  statements against the  performance_schema  and  sys  databases\n•using  SELECT  statements against the  PROCESSLIST  table from the  infoschema  database\n• SELECT  statements that do not use tables or user defined functions\n• STOP GROUP_REPLICATION  statements\n• SHUTDOWN  statements\n• RESET PERSIST  statements\nA transaction cannot be on-hold forever, and if the time held exceeds  wait_timeout  it returns an ER_GR_HOLD_WAIT_TIMEOUT  error.\nAlthough all writes are held when using  BEFORE_ON_PRIMARY_FAILOVER  consistency level, not all reads are blocked to ensure that you can still inspect the server while it is applying backlog after a promotion took place. This is useful for debugging, monitoring, observability and troubleshooting. Some queries that do not modify data are allowed, such as the following:\nThis ensures that the members all behave in the same way, and that the configuration is persisted after a restart of the member.\nTo guarantee that the group provides the same consistency level regardless of which member is promoted to primary, all members of the group should have  BEFORE_ON_PRIMARY_FAILOVER  (or a higher consistency level) persisted to their configuration. For example, on each member issue:\nTo summarize, when  group_replication_consistency  is set to  BEFORE_ON_PRIMARY_FAILOVER you are choosing to prioritize consistency over availability, because reads and writes are held whenever a new primary is elected. This is the trade-off you have to consider when configuring your group. It should also be remembered that if flow control is working correctly, backlog should be minimal. Note that the higher consistency levels  BEFORE ,  AFTER , and  BEFORE_AND_AFTER  also include the consistency guarantees provided by  BEFORE_ON_PRIMARY_FAILOVER .\nThis query should not cause a conflict but writes outdated values.\n> BEGIN; > SELECT x FROM t1; -- x=1 because x=2 is in the backlog; > INSERT x INTO t2; > COMMIT;\n> SET PERSIST group_replication_consistency=’BEFORE_ON_PRIMARY_FAILOVER’;\n3735"}]}
+{"image": "doclay/doclay_24360.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "The total balance of the reference CMBS tranches in these collateral pools is $6.8 billion.  The underlying loan collateral  pool supporting the CMBS tranches consists of approximately 12,700 loans with a balance of approximately $151.0 billion.  The underlying loan collateral is reasonably well diversified both geographically and by property type.  Approximately 33.6%,  32.6% and 13.6% of the underlying loan collateral was for of fice space, retail space and multi-family property , respectively.  Approximately 14.3% of the underlying loans are due on or before December 31, 2014, and an additional 48.6% and 33.4% of  the underlying loans are due in the years ending December 31, 2015 and 2016, respectively , with the remaining 3.7% due  thereafter. If such underlying loans cannot be refinanced when due and they default, we may be required to pay a principal  claim on our insured CDOs of CMBS, subject to applicable subordination, if the amount recovered upon the foreclosure of the  underlying property, or otherwise, is insufficient to cover the defaulted loan balance and related expenses.\nRMBS. In our insured RMBS transactions, we provide credit protection for the timely payment of principal and interest  when due on one or more tranches of securities backed by pools of residential mortgages of various types (e.g., prime,  Alt-A,  subprime). Included in our RMBS transactions is an aggregate of $132.2 million of net par exposure to 2006 and 2007 vintage  RMBS, all of which has been assumed from our primary insurance customers.  We consider this exposure to be particularly high  risk RMBS exposure due to the historically high default rates and aggregate losses on RMBS originated in those years.  As of  December 31, 2012, 34.8% of our total RMBS net par outstanding remains investment grade (at least BBB), including 39.7% of  our exposure to 2006 and 2007 vintage RMBS.\nCLO. We also have $0.5 billion in exposure as of December 31, 2012, related to three direct CLO transactions. Two of  these transactions are second-to-pay transactions in which we will not be obligated to pay a claim unless both the underlying  obligation defaults and another insurer defaults on its primary insurance obligation to pay such claim.  These second-to-pay  transactions are internally rated  A+ and BB+ and are both scheduled to mature in 2018.  We are in a first-to-pay position with  respect to the remaining direct CLO transaction (representing $8.1 million of exposure), which is internally rated  AAA. In our  CLO transactions, we insure the timely payment of current interest and the ultimate payment of principal on a senior class of  notes whose payment obligations are secured primarily by pools of corporate loans or tranches of CLOs.\nAssumed Reinsurance. We reinsure direct financial guarantees written by other primary financial guaranty insurers or  “ceding companies.” Reinsurance allows a ceding company to write lar ger single risks and larger aggregate risks while  remaining in compliance with the risk limits and capital requirements of applicable state insurance laws, rating agency  guidelines and internal limits. State insurance regulators allow a ceding company to reduce the liabilities appearing on its  balance sheet to the extent of reinsurance coverage obtained from licensed reinsurers or from unlicensed reinsurers meeting  certain solvency and other financial criteria. Similarly , the rating agencies may permit a reduction in both exposures and  liabilities ceded under reinsurance agreements, with the amount of reduction permitted dependent on the financial strength  rating of the insurer and reinsurer .\nAs a result of multiple downgrades of the financial strength ratings of our financial guaranty insurance subsidiaries  beginning in June 2008, all of our financial guaranty reinsurance treaties have been terminated on a “run-of f” basis, meaning  that none of our ceding companies may cede additional business to us under our reinsurance agreements with them.  The  business they previously ceded to us under these agreements remains outstanding until such time as the underlying policy  terminates, the ceding company elects to recapture such business or we mutually agree to a commutation of such risk.  Substantially all of our assumed reinsurance exposure from primary reinsurance customers other than af filiates of Assured and a  significant portion of our assumed reinsurance exposure from  Assured has been recaptured by or commuted with our primary  reinsurance customers.\nOur treaties with our primary reinsurance customers do not permit our reinsurance customers to selectively recapture  business previously ceded to us under their treaties.  While most of our primary reinsurance customers have recaptured or  commuted their reinsurance exposure with us, we continue to have multiple treaties with af filiates of Assured. It is possible  therefore, that one or more af filiates of Assured may choose to recapture business only under those treaties that it perceives as  covering less risky portions of our reinsurance portfolio. If this type of selective recapture occurs, it could potentially leave us  with risk that is more concentrated in troubled asset classes.\n30\n3.  Reinsurance"}]}
+{"image": "doclay/doclay_60019.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "PEP 3129 - Class Decorators The proposal that added class decorators. Function and method decorators were introduced in PEP 318 .\nThe Python Language Reference, Release 3.9.5\nNew in version 3.5.\n8.8 Coroutines\n8.8.1 Coroutine function definition\n8.8.2 The $_{async for}$statement\n103\n8.8. Coroutines\n(continues on next page)\niter =(ITER) iter =type(iter).__aiter__ (iter) running = True while running: try : TARGET = await type(iter).__anext__ (iter) except StopAsyncIteration: running = False else : SUITE else :\nasync for TARGET in ITER: SUITE else : SUITE2\nIs semantically equivalent to:\nThe$_{async for}$statement allows convenient iteration over asynchronous iterables.\nThe following code:\nAn asynchronous iterable provides an$_{__aiter__}$ method that directly returns an asynchronous iterator , which can call asynchronous code in its$_{__anext__}$ method.\n$_{async_for_stmt}$::= \"async\" for_stmt\nasync def func(param1, param2): do_stuff() await some_coroutine()\nAn example of a coroutine function:\nIt is a SyntaxError to use a yield from expression inside the body of a coroutine function.\nFunctions defined with async def syntax are always coroutine functions, even if they do not contain await or $_{async}$keywords.\nExecution of Python coroutines can be suspended and resumed at many points (see coroutine ). Inside the body of a coroutine function,$_{await}$and$_{async}$identifiers become reserved keywords;$_{await}$expressions,$_{async for}$ and$_{async with}$ can only be used in coroutine function bodies.\n$_{async_funcdef}$::= [ decorators ] \"async\" \"def\" funcname \"(\" [ parameter_list ] \")\" [\"->\" expression ] \":\" suite"}]}
+{"image": "doclay/doclay_6009.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "www.conEdison.com Consolidated Edison, Inc. 4 Irving Place  New York, NY 10003 1-212-460-4600"}]}
+{"image": "doclay/doclay_45371.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "pull the control bar in to control pitch. This wing attachment  is different for each manufacturer, but all designs have this  hang point wing attachment so the control bar is always  perpendicular to the longitudinal axis of the aircraft. This  raising and lowering of the nose is the pitch control system  for the WSC aircraft.  [Figures 2-7  and  3-19]\nControl bar movement from side to side controls the roll about  the longitudinal axis. The wing attachment hang point allows  the carriage to roll around the wing keel. Thus, it can also be  looked at from the carriage point of view, when the control  bar is moved side to side, the wing rotates around the wing  keel relative to the carriage.  [Figures 2-31  and  3-19]\nIt would first appear that moving the control bar to one side,  thus shifting weight to the opposite side, could alone bank  the aircraft. It is true that shifting weight to the right would  naturally bank the aircraft to the right and put it into a right  hand turn. However, the weight alone is not enough to provide  adequate roll control for practical fl ight. \nAs weight is moved to one side, the keel is pulled closer to  that side’s leading edge. The actual keel movement is limited  to only 1 to 2 inches each side of center. However, this limited  keel movement is sufficient to warp the wing, changing the  twist side to side (as discussed earlier in the aerodynamics  section) to roll the aircraft  [Figure 2-24]  by changing the  lift side to side. Simply, the shifting of weight from side to  side pulls the keel toward the leading edge on that side and  warps the wing to roll the aircraft. \nBesides the keel shifting relative to the leading edges and  crossbar, overall roll control is adjusted by the designers to  fit the mission of the wing through sail material/stiffness,  leading edge stiffness/flexibility, amount of twist, amount  of travel the keel is allowed, airfoil shape, and the planform  of the wing.  [Figures 3-20  and  3-21]\nThe most common ground adjustable trim system, and typical  of most aircraft, is moving the wing attachment hang point  forward for faster trim speeds and aft for slower trim speeds.  Each manufacturer has different hardware, but the basics of  sliding the carriage wing hang point forward and backward  on the keel is similar for all. As an example, moving the  hang point at the furthest aft position to the furthest forward  position could speed the wing up 20 knots. This in turn  moves the control bar position back to a new “hands off”  trim speed. \nThere are a number of trim systems to relieve the control  pressures for pilots to fly at different “hands off” trim speeds.  Ground adjustable trim allows the pilot to adjust the trim  speed of the wing on the ground and remain at one speed  during flight, while flight adjustable trim systems can change  the trim speed in fl ight. Strap attached to crossbar  that goes around wing keel,  limiting its travel side to side.\nFar Back View Top View\nFigure 3-20.  Shifting weight to the right pulls the keel to the right  (or lets the crossbar shift to the left) and increases twist on the right  side for roll control.\nFigure 3-19.  Hang point wing attachment.\nFigure 3-21.  Crossbar travel limiter.\n Trim Systems\n Roll Control System \n Ground Adjustable Trim Systems \n3-9"}]}
+{"image": "doclay/doclay_22620.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "HYDRO ONE  SENIOR MANAGEMENT\n14\nHYDRO ONE ANNUAL REPORT 2013\nCarmine M arcello President and Chief Executive Officer, Hydro One Inc.\nJoe Ag ostino General Counsel\nLaura Cooke Vice President, Corporate Relations\nJohn Fraser Senior Vice Pr esident, Internal Audit\nPeter Gregg Chief Operating Officer\nJudy McKellar Vice President, People & Culture\nRick Stevens Vice President, Customer Service\nSandy Struthers Chief Administration Officer  and Chief Financial Officer"}]}
+{"image": "doclay/doclay_19407.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Table 3 - Selected Quarterly Financial Data\n(a) Tax-equivalent. See \"Table 1 - Explanation of Non-GAAP Financial Measures\". (b) Efficiency ratio is the result of noninterest expense divided by the sum of noninterest income and tax-equivalent net interest income.\n(a) Tax-equivalent. See \"Table 1 - Explanation of Non-GAAP Financial Measures\". (b) Efficiency ratio is the result of noninterest expense divided by the sum of noninterest income and tax-equivalent net interest income. NM - not meaningful\npage 25\nFinancial Tables\n2011 2010 (Dollars in thousands, except per share  amounts) Fourth Third Second First Fourth Third Second First Income statement Tax-equivalent interest income (a) $ 7,629 8,089 8,438 8,269 8,423 8,819 8,899 9,096 Total interest expense 2,705 2,815 2,941 3,020 3,340 3,632 3,773 3,828 Tax equivalent net interest income (a) 4,924 5,274 5,497 5,249 5,083 5,187 5,126 5,268 Provision for loan losses 650 600 600 600 650 730 750 1,450 Total noninterest income  1,461 1,327 1,300 1,089 131 1,662 2,712 2,213 Total noninterest expense 4,187 4,268 4,308 3,594 3,440 4,171 4,729 3,553 Net earnings before income taxes and  tax-equivalent adjustment 1,548 1,733 1,889 2,144 1,124 1,948 2,359 2,478 Tax-equivalent adjustment 415 429 440 435 441 449 438 437 Income tax (benefit) expense  (32) (63) (8) 160 (195) 255 314 424 Net earnings $ 1,165 1,367 1,457 1,549 878 1,244 1,607 1,617 Per share data: Basic and diluted net earnings  $ 0.32 0.38 0.40 0.43 0.24 0.34 0.44 0.44 Cash dividends declared 0.20 0.20 0.20 0.20 0.195 0.195 0.195 0.195 Weighted average shares outstanding Basic and diluted 3,642,738 3,642,738 3,642,738 3,642,728 3,642,718 3,642,701 3,642,877 3,643,116 Shares outstanding, at period end 3,642,738 3,642,718 3,642,693 3,643,112 Book value  $ 17.96 17.69 16.77 15.87 15.47 16.73 16.21 15.86 Common stock price High $ 19.65 19.70 19.91 20.37 22.00 22.00 21.00 21.95 Low 18.52 19.10 19.40 19.51 19.50 18.08 16.86 17.61 Period-end $ 19.65 19.75 19.56 20.06 20.35 18.80 20.65 To earnings ratio  12.10 x 13.55 14.01 13.49 13.74 15.78 15.41 19.86 To book value 103 % 111 118 123 130 122 116 130 Performance ratios: Return on average equity  7.15 % 8.81 9.90 10.84 5.68 8.31 10.96 11.31 Return on average assets  0.61 0.72 0.75 0.80 0.45 0.64 0.82 0.82 Dividend payout ratio 62.50 % 52.63 50.00 46.51 81.25 57.35 44.32 44.32 Average equity to average assets 8.50 8.12 7.58 7.36 8.00 7.68 7.47 7.30 Asset Quality: Allowance for loan losses as a % of: Loans 1.87 % 1.69 2.07 2.13 2.05 1.91 1.75 1.72 Nonperforming loans  67 60 95 70 65 82 72 60 Nonperforming assets as a % of : Loans and foreclosed properties 4.83 % 4.78 4.57 5.20 5.22 4.42 4.05 4.65 Total assets 2.35 2.39 2.25 2.51 2.61 2.18 1.98 2.28 Nonperforming loans as % of loans 2.80 % 2.80 2.18 3.03 3.16 2.34 2.43 2.87 Net charge-offs as % of average loans 0.08 2.14 0.76 0.45 0.16 0.14 0.76 1.48 Capital Adequacy: Tier 1 risk-based capital ratio 15.40 % 15.25 14.95 14.84 14.57 14.53 14.25 13.76 Total risk-based capital ratio 16.66 16.51 16.20 16.09 15.82 15.78 15.49 15.01 Tier 1 Leverage ratio 8.82 % 8.87 8.65 8.56 8.47 8.39 8.27 8.17 Other financial data: Net interest margin (a) 2.77 % 2.98 3.09 2.98 2.81 2.85 2.82 2.94 Effective income tax rate NM% NM NM 9.36 NM 17.01 16.35 20.77 Efficiency ratio (b) 65.58 % 64.66 63.38 56.71 65.98 60.90 60.33 47.49 Selected period end balances: Securities $ 299,582 283,070 296,443 321,098 315,220 322,118 333,107 333,660 Loans, net of unearned income 370,263 374,788 373,795 368,909 374,215 375,098 376,624 380,619 Allowance for loan losses 6,919 6,340 7,746 7,855 7,676 7,181 6,580 6,546 Total assets 776,218 764,637 779,725 781,557 763,829 777,846 784,124 791,324 Total deposits 619,552 609,070 627,969 631,394 607,127 602,508 605,755 608,588 Long-term debt 85,313 85,317 85,322 85,327 93,331 108,335 113,340 118,345 Total stockholders’ equity 65,416 64,422 61,100 57,801 56,368 60,937 59,042 57,778"}]}
+{"image": "doclay/doclay_19724.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "SElECTEd FINANCIAl dATA\nMarket Price\n8\nFiscal Year ended december 31, 2013  High  Low First Quarter   $ 20.00   $ 18.00 second Quarter  20.49  18.06 third Quarter  22.97  19.38 Fourth Quarter  26.18  21.86 Fiscal Year ended december 31, 2014  High  Low First Quarter   $ 26.60   $ 23.27 second Quarter  27.43  23.12 third Quarter  25.92  21.05 Fourth Quarter  25.45  20.55\nFrom July 8, 1996, until April 18, 2001, the Company’s common stock was listed on the nAsDAQ national Market under the symbol  “UFpt.” since April 19, 2001, the Company’s common stock has been listed on the nAsDAQ Capital Market. the following table sets  forth the range of high and low quotations for the common stock as reported by nAsDAQ for the quarterly periods from January 1,  2013 to December 31, 2014:\nthe following table summarizes our consolidated financial data for the periods presented. you should read the following financial  information together with the information under “Management’s Discussion and Analysis of Financial Condition and Results of  Operations” and our consolidated financial statements and the notes to those financial statements appearing elsewhere in this Report.  the selected statements of operations data for the fiscal years ended December 31, 2014, 2013 and 2012, and the selected balance  sheet data as of December 31, 2014 and 2013, are derived from our audited consolidated financial statements, which are included  elsewhere in this Report. the selected statements of operations data for the years ended December 31, 2011 and 2010, and the balance  sheet data at December 31, 2011 and 2010 are derived from our audited consolidated financial statements not included in this Report. \nYears ended december 31 (in thousands, except per share data) consolidated statement of operations data  2014  2013  2012  2011  2010 net sales   $ 139,307 $ 139,223 $ 130,962 $ 127,244 $ 120,766 Gross profit  36,880 41,014 38,319 36,245 34,616 Operating income 11,561 17,398 16,666 15,716  14,392 net income  7,559 11,276 10,895 10,346 9,247 Diluted earnings per share  1.05 1.59 1.55 1.48 1.37 Weighted average number of diluted shares outstanding  7,175 7,105 7,028 6,999 6,749\nSeLected conSoLidated FinanciaL data\nas of december 31 (in thousands) consolidated balance sheet data  2014  2013  2012 2011  2010 Working capital   $ 56,800 $ 56,398  $ 51,263  $ 48,575 $ 38,267 total assets  113,690 104,908 98,617 79,721 69,478 short-term debt obligations  993 976 1,550 581 654 Long-term debt, excluding current portion  1,873 2,867 8,314 5,639 6,847 total liabilities  18,698 19,318 25,357 17,736 19,251 stockholders’ equity  94,992 85,590 73,260 61,985 50,226"}]}
+{"image": "doclay/doclay_42288.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": " TM 10-1670-287-23&P \n0013 00 \nNOTE \nThe following ripcord pull tests are performed on all MC-4 systems  on a one-time only basis. \n21. Conduct a Slack Checker Inspection Test as indicated in WP 0011 00.\n22. Place parachute in test fixture or anthropometrical device (torso) simulating the 5-to-95 percentile  person or live subject. The device shall hold parachute securely in a position with the mouth of the  ripcord pocket facing down (along the vertical axis). \n20. For reserve mounted AR2s, pull up top pull up cord and remove locking pin. Thread eye of power  cable over top pin of ripcord. Insert top ripcord pin into closing loop (detail A). Axis of ripcord pin will  follow the angled hole in the eye of the power cable (detail B). Center straight portion of ripcord pins  in closing loops and ensure that shoulders of pins remain outside of grommets.\n19. Pull up bottom pull up cord, remove temporary locking pin, and insert bottom ripcord pin into closing  loop.\nDETAIL A  DETAIL B  Power  Cable Eye  Ripcord  Pin  Power  Cable Eye  Ripcord  Pin  Pull-Up  Cord \n0013 00-32 \nChange 2 "}]}
+{"image": "doclay/doclay_37887.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "(4) a user manual; \n(5) implementation  Documentation . \nIV.8.5.3.  The manuals and the  Documentation  shall be in the file format of a word processing  Software  used by the contracting authority and prepared so that they may be published on the contracting  authority’s intranet. \nIV.8.5.4.  The user manuals and the  Documentation  shall be supplied in English, unless otherwise  agreed. \nIV.8.5.5.  The contractor shall update and, if necessary, replace the user manuals and  Documentation  files for the maximum length of the framework contract. \nIV.8.6.1.  Where the specific contract mentions interfaces that need to be observed, the contractor shall  not modify such interfaces without the contracting authority’s written agreement. Such  agreement shall not be unreasonably withheld. \nIV.8.6.2.  Where the  Commissioned software  supplied utilises  Software  from a third party and where that  Software  is updated, the contractor shall adapt the  Commissioned software  in accordance with  terms jointly agreed. \nIV.8.6.3.  The contractor shall ensure that all the  Commissioned software  supplied under the framework  contract is compatible and operates by means of interfaces with all other  Software  specified in  the framework contract. \nPage 38 of 40 \nIV.8.6.  Interfaces and  Compatibility"}]}
+{"image": "doclay/doclay_29978.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "at the middle position of the bilayer distance, will finally be adsorbed to one graphene layer and away from the other layer. The bilayer distance is enlarged for all the investigated adsorption systems. Both N and O atoms are stable at the bridge site, while C atom is stable at the hollow site. Concerning the magnetic property, O-intercalated system is nonmagnetic, while N and C atoms can induce stoner magnetism by introducing extended or quasilocalized states around the Fermi level. Nearly 100% spin polarization is obtained in N-intercalated system and the magnetic moment focuses on the N atom. For C-intercalated system, the magnetic moment distributes on the foreign C atom and certain carbon atoms of the bilayer graphene. Both in N-intercalated and O-intercalated systems, the Fermi level is obviously shift downward, inducing the metallic behavior of the bilayer graphene.\nAcknowledgements: This work was supported by the the Ministry of Sciences and Technology through the 973-Project (No. 2007CB924901), the National Natural Science Foundation of China (Grant Nos. 60221502 and 1067027), the Grand Foundation of Shang- hai Science and Technology (05DJ14003).\n[*] E-mail address: sjgsuda@hotmail.com\n[2] K. S. Novoselov, A. K. Geim, S. V. Morozov, D. Jiang, Y. Zhang, S. V. Dubonos, I. V. Grigorieva, and A. A. Firsov, Science 306 , 666 (2004).\n[3] Y. Zhang, Y. -W. Tan, H. L. Stormer, and P. Kim, Nature 438 , 201 (2005).\n[4] V. P. Gusynin, and S. G. Sharapov, Phys. Rev. Lett. 95 , 146801 (2005).\n[5] X. Wang, Y. Ouyang, X. Li, H. Wang, J. Guo, and H. Dai, Phys. Rev. Lett. 100 , 206803 (2008).\n[6] K. S. Novoselov, A. K. Geim, S. V. Morozov, D. Jiang, M. I. Katsnelson, I. V. Grigorieva, S. V. Dubonos, and A. A. Firsov, Nature 438 , 197 (2005); K. S. Novoselov, D. Jiang, F. Schedin, T. J. Booth, V. V. Khotkevich, S. V. Morozov, and A. K. Geim, Proc. Natl. Acad. Sci. U.S.A. 102 , 10451 (2005); A. K. Geim and K. S. Novoselov, Nature Mater. 6 , 183 (2007).\n[7] H. Min, B. Sahu, S. K. Banerjee, and A. H. MacDonald, Phys. Rev. B 75 , 155115 (2007).\n[8] E. McCann and V. I. Fal’ko, Phys. Rev. Lett. 96 , 086805 (2006); E. McCann, Phys. Rev. B 74 , 161403(R) (2006).\n[9] Y. Mao and J. Zhong, Nanotechnology 19 , 205708 (2008).\n7"}]}
+{"image": "doclay/doclay_6846.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Committedto Grow th\nWe are committed to growth and continue to seek additional expansion opportunities in both the national and international markets. We believe our broad consumer appeal coupled with a high return on investment, will enable us to operate more than 1,000 stores in the U.S.\nThe Children’s Place/babyPLACE combo stores provide an internal growth opportunity for approximately 300 babyPLACE stores. This expansion allows us to increase our square footage and sales without increasing our store count. \nWe are also very excited about our entry into the Canadian market. We plan to open approximately 30 new Canadian stores in 2002, and foresee the potential of operating over 125 stores in Canada.\nIn 2001, we opened 121 new stores and celebrated our 500th store opening. We look forward to becoming the #1 children’s apparel specialty retailer in the United States and Canada.\n"}]}
+{"image": "doclay/doclay_13522.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "10\nAMERICAN ELECTRIC POWER COMPANY, INC.\nHigh-quality service begins with safe, dedicated performance At AEP"}]}
+{"image": "doclay/doclay_22174.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "macquarie.com.au \n2014 Annual Financial Report \nMacquarie Group Limited and its subsidiaries \nThe Board approves (on BRC recommendation)  BRC approves (on behalf of the Board)  Executive Remuneration Policy and Framework Recommendations  GLYPH<150> The  Remuneration Policy , its effectiveness and its compliance  with legal and regulatory requirements  GLYPH<150> The appropriate levels of delegated responsibility to  management for remuneration-related decisions  GLYPH<150> The profit share methodology and any adjustments  Adjustments to the profit share pool as a result of the Non- Executive Directors exercising their discretion  GLYPH<150> Identification of the Designated Executive Director  population, Code Staff population$^{(1)}$, Hong Kong  Covered Staff$^{(1)}$, other persons whose activities may  affect the financial soundness of Macquarie, and senior  risk and financial control staff  GLYPH<150> The profit share pool, calculated in accordance with the  Board-approved methodology  GLYPH<150> The percentage of Executive Directors’ retained profit  share allocated to Macquarie shares and Macquarie- managed fund equity  GLYPH<150> The implementation of the  Remuneration Policy ,  including an annual review of compliance with the  Executive Director minimum shareholding requirements  Executive Remuneration Re commendations  GLYPH<150> Individual remuneration recommendations$^{(2)}$ for:  GLYPH<150> Executive Committee members  Designated Executive Directors  GLYPH<150> Staff covered under specific regulatory requirements  Senior risk and financial control staff GLYPH<150> The total PSU pool available for Executive Committee  members  GLYPH<150> The continued vesting or otherwise of retained profit share  amounts for employees covered under the Malus provisions  GLYPH<150> All individual profit share recommendations for other  Executive Directors  GLYPH<150> The standard number or value of promotion equity  grants to Director-level staff  Non-Executive Director Remuneration GLYPH<150> The remuneration framework for the Non-Executive Directors  of Macquarie and MBL  GLYPH<150> Remuneration recommendations for Non-Executive Director  fees (subject to the maximum aggregate amount being  approved by shareholders)$^{(3)}$ \n(1) Code Staff under the UK Regulators’ Remuneration Code, Covered Staff under the Hong Kong Monetary Authority’s (HKMA) Guideline  on a Sound Remuneration System.  (2) Including base remuneration, profit share and PSUs where applicable, with the proviso that PSU grants to Executive Voting Directors \non a Sound Remuneration System.  (2) Including base remuneration, profit share and PSUs where applicable, with the proviso that PSU grants to Executive Voting Directors  (including the CEO) must be approved by shareholders at the Annual General Meeting.  (3) The Corporations Act 2001 (Cth)(the Act) contains an exception to the general prohibition on voting on a matter in which a Director has \n(including the CEO) must be approved by shareholders at the Annual General Meeting.  (3) The Corporations Act 2001 (Cth)(the Act) contains an exception to the general prohibition on voting on a matter in which a Director has  a material personal interest in respect of a director’s remuneration as a director. \n68 \nDirectors’ Report  –  Remuneration Report  for the financial year ended 31 March 2014  continued "}]}
+{"image": "doclay/doclay_14086.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Franklin Covey 2000 Annual Report\n68 2000 Option Exercises\nDuring the fiscal year ended August 31, 2000, the Com pany did not grant any stock options or stock appreciation rights to the persons named in the preceding Summary Com pensation Table. \nThe following table sets forth the number of shares of  Common Stock acquired during the fiscal year ended August 31, 2000, upon the exercise of stock options, the value r ealized upon such exercise, the number of unexercised stock options held on August 31, 2000, and the aggregate value of suc h options held by the persons named in the Summary Compensation Table. This table reflects options to acquir e shares of Common Stock granted to the named individuals by the Company and by certain affiliates of the Company.  As of August 31, 2000, the Company had not granted any stock appreciation rights to any of the executive officers named below. \nThe Company does not have an employment agreement with any of its named executive officers, other than Robert A. Whitman, the President, Chief Executive Officer and Chairman of the Board.\nIn an effort to develop a compensation agreement that would create a strong link in both pay for performance and shareholder value creation, the Board and Mr. Whitman have directly linked Mr. Whitman’s annual performance award and long-term compensation to measures that create value and increase the price of the Company’s Common Stock. The performance award’s unusual structure differs from normal executive compensation programs in that the annual performance pay is tied to very aggressive growth goals and the long- term compensation is awarded only after most shareholders have benefited from a substantial increase in share price. For example, for fiscal year 2001, Mr. Whitman would receive no performance pay until an approximate 36% increase in EBITDA is achieved and would not receive a full reward unless an 84% increase\nin EBITDA is achieved. Though subsequent years’ performance requirements may not necessarily be that aggressive, the hurdle tied to value creation is expected to be high. The Company’s outside compensation consultants advised the Board that long-term compensation is typically bench-marked by company size and is usually granted at current market price. However,to emphasize pay for performance, the options granted to Mr. Whitman have an unusually conservative vesting schedule and grant price, consistent with Mr. Whitman’s desire that value be created for existing shareholders before he receives long-term compensation rewards. The award provides for no vesting for seven years (and only then if currently employed) of any of the options unless the market price of the Company’s stock price reaches certain levels which would increase shareholders value by approximately 300% to 700% over that time period. The grant price of $14.00 is also well above the current market price. The Board and Mr. Whitman have designed this compensation package with the intent that existing shareholders would benefit prior to Mr. Whitman receiving meaningful compensation. \nEmployment Agreements\n(1) Reflects the difference between the exercise price of the options ex ercised and the market value of the Common Stock on the date of such exercise, as reported by the New York Stock Exchange.\n(2) Reflects the difference between the exercise price of the unexercised options and the market value of the Common Stock on August 31, 2000. The last sale price of the Common Stock on August 31, 2000, as repor ted by the New York Stock Exchange, was $6.625 per share. \nOption/SAR Grants in Last Fiscal Year\nAggregated Option/SAR Exercises in Last Fiscal Year  and Fiscal Year Option/SAR Values\nValue of Unexercised Number of Unexercised In-the-Money Options at Options at August 31, 2000 August 31, 2000(2) Number of Shares Value Acquired on Realized on Name Exercise Exercise(1) Exercisable Unexercisable Exercisable Unexercisable Robert A. Whitman _ $ _ _ _ $ _ $ _ Val John Christensen _ _ 27,825 71,475 34,605 _ Stephen M. R. Covey _ _ 6,250 18,750 _ _ Don J. Johnson _ _ 15,000 5,000 _ _ John R. Harding _ _ 51,834 39,166 _ _"}]}
+{"image": "doclay/doclay_25839.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "A simplification of this filtering algorithm is possible for the case of single-state capture- recapture with one absorbing state. Once an animal is deceased, it is guaranteed to remain in that state thereafter, where X = { “alive” , “dead” } and Y = { “seen” , “not seen” } . In this context we can express the likelihood of a capture history in terms of survival prob- abilities φ$_{t}$ = Pr( X$_{t}$ = “alive” | X$_{t}$$_{−}$$_{1}$ = “alive”) and detection probabilities p$_{t}$ = Pr( Y$_{t}$ = “seen” | X$_{t}$ = “alive”) as\nwhere we numerically assign y$_{t}$ = “seen” as y$_{t}$ = 1 and y$_{t}$ = “not seen” as y$_{t}$ = 0, t$_{final}$ is the time index of the final observed sighting ( i.e. , t$_{final}$ = max { t | y$_{t}$ = 1 } ), χ$_{k}$ = 1, and χ$_{t}$ = 1 − φ$_{t}$ + φ$_{t}$ (1 − p$_{t}$ ) χ$_{t}$$_{+1}$ for t < k (Lebreton et al., 1992). Use of this simplified calculation for single-state capture-recapture will dramatically speed up likelihood evaluations relative to (5), since the likelihood is expressed in closed form.\nThese filtering algorithms numerically integrate over sequences of latent states to directly calculate model likelihoods, removing the need to perform MCMC sampling of these latent variables. However, the MCMC sampling step for each component of θ now requires appli- cation of a filtering algorithm for each observed history y$_{i}$ . Thus, this approach reduces the dimensionality of the MCMC sampling problem, but at the cost of increased computational complexity of each MCMC iteration.\nA further specialized approach arises when there are repeated instances of identical observa- tion histories in the full observed dataset y . That is, multiple distinct individuals exhibited identical observation histories over the k observational periods. Let n ∗ be the number of unique observation histories in the original dataset y . We define a reduced representation ( y $^{∗}$, m$^{∗}$), where y ∗ contains the n ∗ unique histories appearing in y . An accompanying vector\n9\nFiltering MCMC with a reduced representation of the dataset\nL ( θ | y ) =$^{(}$$^{t$_{final}$}$$^{−}$$^{1}$ ∏ t =1 φ$_{t}$$^{)(}$$^{t$_{final}$}$ ∏ t =2 p y$_{t}$ t (1 − p$_{t}$ ) 1 − y$_{t}$ ) χ$_{t}$$_{final}$, (6)"}]}
+{"image": "doclay/doclay_1614.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "some nonnegative integer t and s ∈ [0 , 1]. Then the LHS in (A.4) is 2 . Moreover, since ϕ ( y$_{0}$ ) + ψ ( y$_{1}$ ) > 1, for ( y$_{0}$, y$_{1}$ ) ∈$_{R}$×$_{R}$ s.t. s + t ≤ ϕ ( y$_{0}$ ) < s + t + 1 and − ( s + t − 1) < ψ ( y$_{1}$ ) , by (A.1)\nand thus (A.4) is also satisfied from the following:\nSimilarly, it can be proven that (A.4) is also satisfied for other nontrivial cases. Therefore it concludes that each ( ϕ, ψ ) ∈ Φ$_{c}$ can be written as a continuous convex combination of a continuum of pairs of the form\nProof of Theorem 1 By Lemma A.1, ( ϕ, ψ ) ∈ Φ$_{c}$ can be represented as a continuous convex combi- nation of a continuum of pairs of the form\nSince Φ$_{c}$ is a convex set and J ( ϕ, ψ ) = ∫ ϕdF$_{0}$ + ∫ ψdF$_{1}$ is a linear functional, for all ( ϕ, ψ ) ∈ Φ$_{c}$, there exists s ∈ (0 , 1] such that\n58\nJ ( ∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ϕ,s ) − 1$_{A}$ − k ( ϕ,s ) $^{)}$, ∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ψ,s ) − 1$_{A}$ − k ( ψ,s ) ) ) ≥ J ( ϕ, ψ ) . (A.5)\n∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ϕ,s $_{)}$( y$_{0}$ ) − 1$_{A}$ − k ( ϕ,s $_{)}$( y$_{0}$ ) $^{)}$+ ∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ψ,s $_{)}$( y$_{1}$ ) − 1$_{A}$ − k ( ψ,s $_{)}$( y$_{1}$ ) ≤ 1 { y$_{1}$ − y$_{0}$ < δ } + λ (1 − 1$_{C}$ ( y$_{0}$, y$_{1}$ )) .\n( ∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ϕ,s ) − 1$_{A}$ − k ( ϕ,s ) $^{)}$, ∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ψ,s ) − 1$_{A}$ − k ( ψ,s ) ) ) ,\n( ∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ϕ,s ) − 1$_{A}$ − k ( ϕ,s ) $^{)}$, ∞ ∑ k =0 $^{(}$1$_{A}$ + $_{k}$( ψ,s ) − 1$_{A}$ − k ( ψ,s ) ) ) .\n1 { y$_{1}$ − y$_{0}$ < δ } + λ (1 − 1$_{C}$ ( y$_{0}$, y$_{1}$ )) = ∞ .\n1 < ϕ ( y$_{0}$ ) + ψ ( y$_{1}$ ) ≤ 1 { y$_{1}$ − y$_{0}$ < δ } + λ (1 − 1$_{C}$ ( y$_{0}$, y$_{1}$ )) ,\n■\nwith"}]}
+{"image": "doclay/doclay_62741.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "1111111111111111 IIIIII IIIII 111111111111111 111111111111111 11111 lllll 111111111111111 11111111 \n1111111111111111 IIIIII IIIII 111111111111111 111111111111111 11111 lllll 111111111111111 11111111  US 20140199617Al \nc10) Pub. No.: US 2014/0199617 Al \n(43) Pub. Date:  Jul.  17, 2014 \nc19)  United States  c12)  Patent Application Publication \nTSUBAKI et al. \n(54)  PATTERN-FORMING METHOD, ELECTRON  BEAM-SENSITIVE OR EXTREME  ULTRAVIOLET RADIATION-SENSITIVE  RESIN COMPOSITION, RESIST FILM,  MANUFACTURING METHOD OF  ELECTRONIC DEVICE USING THEM AND  ELECTRONIC DEVICE \n(71)  Applicant:  FUJIFILM CORPORATION,  TOKYO  (JP) \n(72)  Inventors:  Hideaki TSUBAKI,  Shizuoka (JP);  Hiroo TAKIZAWA,  Shizuoka (JP);  Takeshi KAWABATA,  Shizuoka (JP) \n(73)  Assignee:  FUJIFILM CORPORATION,  TOKYO  (JP) \n(21)  Appl. No.:  14/227,444 \n(22)  Filed:  Mar. 27, 2014 \n(63)  Continuation of application No. PCT/JP2012/072285,  filed on Aug. 28, 2012. \n(52)  U.S. Cl.  CPC .  G03F  7120  (2013.01);  G03F  71038  (2013.01)  USPC .............  430/18;  430/296; 430/325; 430/319;  430/270.1; 430/285 .1 \n(51)  Int. Cl. \nG03F  7120  G03F  71038  (2006.01)  (2006.01) \nPublication Classification \n(57)  ABSTRACT \nRelated U.S. Application Data \n(30)  Foreign Application Priority Data \nSep.30,2011  (JP) ................................. 2011-218549 \nA pattern-forming method includes in this order: step (1) of  forming a film with an electron beam-sensitive or extreme  ultraviolet radiation-sensitive resin composition that contains  (A) a resin having an acid-decomposable repeating unit and  capable of decreasing a solubility of the resin (A) in a devel› oper containing an organic solvent by an action of an acid and  (B) a low molecular weight compound capable of generating  an acid upon irradiation with an electron beam or extreme  ultraviolet radiation and decomposing by an action of an acid  to decrease a solubility of the low molecular weight com› pound (B) in an organic solvent; step (2) of exposing the film  with an electron beam or extreme ultraviolet radiation; and  step ( 4) of developing the film with a developer containing an  organic solvent after the exposing to form a negative pattern. "}]}
+{"image": "doclay/doclay_44388.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "TM 10-1670-287-23&P \n0013 00 \n23. Rotate harness/container so that open end of ripcord housing faces down with ripcord cable in a  vertical position. \n24. Secure ripcord handle by hand to prevent ripcord pin withdrawal when weight is applied. \n25. A 20-pound weight attached to the center of the ripcord grip (care shall be exercised not to impose an  impact load) shall readily withdraw ripcord grip from pocket.\n26. When ripcord grip has been removed from pocket, carefully remove the 20-pound weight. \n Change 2 \n0013 00-33 "}]}
+{"image": "doclay/doclay_49840.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "CREATE TABLE Statement\n• ENGINE_ATTRIBUTE  and  SECONDARY_ENGINE_ATTRIBUTE  options (available as of MySQL 8.0.21) are used to specify column attributes for primary and secondary storage engines. The options are reserved for future use.\nPermitted values are a string literal containing a valid  JSON  document or an empty string (’’). Invalid JSON  is rejected.\nENGINE_ATTRIBUTE  and  SECONDARY_ENGINE_ATTRIBUTE  values can be repeated without error. In this case, the last specified value is used.\nENGINE_ATTRIBUTE  and  SECONDARY_ENGINE_ATTRIBUTE  values are not checked by the server, nor are they cleared when the table’s storage engine is changed.\nFor  NDB  tables, it is possible to specify whether the column is stored on disk or in memory by using a  STORAGE  clause.  STORAGE DISK  causes the column to be stored on disk, and  STORAGE MEMORY causes in-memory storage to be used. The  CREATE TABLE  statement used must still include a TABLESPACE  clause:\nCREATE TABLE t1 (c1 INT ENGINE_ATTRIBUTE=’{\" key \":\" value \"}’);\nmysql>  CREATE TABLE t1 ( -> c1 INT STORAGE DISK, -> c2 INT STORAGE MEMORY ->  ) ENGINE NDB; ERROR 1005 (HY000): Can’t create table ’c.t1’ (errno: 140)\nmysql>  CREATE TABLE t1 ( -> c1 INT STORAGE DISK, -> c2 INT STORAGE MEMORY ->  ) TABLESPACE ts_1 ENGINE NDB; Query OK, 0 rows affected (1.06 sec)\n• STORAGE\n• GENERATED ALWAYS\n• CONSTRAINT  symbol\nIndexes, Foreign Keys, and CHECK Constraints\n2548\nThe  CONSTRAINT  symbol  clause may be given to name a constraint. If the clause is not given, or a  symbol  is not included following the  CONSTRAINT  keyword, MySQL automatically generates a constraint name, with the exception noted below. The  symbol  value, if used, must be unique per\nSeveral keywords apply to creation of indexes, foreign keys, and  CHECK  constraints. For general background in addition to the following descriptions, see Section 13.1.15, “CREATE INDEX Statement” , Section 13.1.20.5, “FOREIGN KEY Constraints” , and Section 13.1.20.6, “CHECK Constraints” .\nStored generated columns can be indexed.  InnoDB  supports secondary indexes on virtual generated columns. See Section 13.1.20.9, “Secondary Indexes and Generated Columns” .\nUsed to specify a generated column expression. For information about generated columns, see Section 13.1.20.8, “CREATE TABLE and Generated Columns” .\nThe  STORAGE  clause has no effect on tables using storage engines other than  NDB . The  STORAGE keyword is supported only in the build of  mysqld  that is supplied with NDB Cluster; it is not recognized in any other version of MySQL, where any attempt to use the  STORAGE  keyword causes a syntax error.\nFor  NDB  tables,  STORAGE DEFAULT  is equivalent to  STORAGE MEMORY ."}]}
+{"image": "doclay/doclay_68105.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "1.7 IBM Cloud Paks\nOne key technology contributing to the ability to run software components more efficiently,  with improved lifecycle management, scalability and resilience, is known as containerization.  IBM delivers Kubernetes as part of its IBM Cloud Private offering as well as in its IBM Cloud  Kubernetes Service. IBM is committed to containerization across its enterprise software  portfolio. \nWhile still supporting traditional packaging and deployment models (installing software as  usual on a supported operating system), an increasing number of products are available as  container images. As mentioned, deploying containerized software in a manner suitable for  production requires more than an image. \nIBM Cloud Paks provide enterprise software container images that are pre-packaged in  production-ready configurations that can be quickly and easily deployed to IBM’s container  platforms, with support for resiliency, scalability, and integration with core platform services,  like monitoring or identity management. For customers who don’t want to operate the  software and its underlying infrastructure, in containers or otherwise, IBM also makes many of  its products available as-a-Service, where they are hosted and maintained by IBM in its public  cloud.\nFigure 1-17 shows the three ways IBM software is delivered and consumed as containers.  Not all IBM products are available in all three delivery models.Figure 1-17 IBM software as containers\nIBM Cloud Paks use Helm charts to describe how IBM software should be deployed in a  Kubernetes environment. These resource definitions can be easily customized during  deployment, and upgrades can be easily rolled out or rolled back using the management  interfaces provided by IBM Cloud Private or IBM Cloud Kubernetes Service.\nAn IBM Cloud Pak is more than a simple Helm chart. IBM Cloud Paks accelerate time to  value and improve enterprise readiness at lower cost than containers alone.\n22  IBM Cloud Private System Administrator’s Guide"}]}
+{"image": "doclay/doclay_70643.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "ПРАВИТЕЛЬСТВО РОССИЙСКОЙ ФЕДЕРАЦИИ \nП О С Т А Н О В Л Е Н И Е \nот 27 мая 2021 г. № 801\nМОСКВА \nО внесении изменений в Правила определения новых  инвестиционных проектов, в целях реализации которых средства бюджета субъекта Российской Федерации, высвобождаемые в результате снижения объема погашения  задолженности субъекта Российской Федерации перед Российской Федерацией по бюджетным кредитам, подлежат направлению на осуществление субъектом Российской Федерации бюджетных инвестиций в объекты инфраструктуры Правительство Российской Федерации  п о с т а н о в л я е т :\nУтвердить прилагаемые изменения, которые вносятся в Правила  определения  новых  инвестиционных  проектов,  в  целях  реализации  которых  средства  бюджета  субъекта  Российской  Федерации,  высвобождаемые в результате снижения объема погашения задолженности  субъекта  Российской  Федерации  перед  Российской  Федерацией по  бюджетным  кредитам,  подлежат  направлению  на  осуществление  субъектом  Российской  Федерации  бюджетных  инвестиций  в  объекты  инфраструктуры,  утвержденные  постановлением  Правительства  Российской Федерации 19 октября 2020 г. № 1704 \"Об утверждении  Правил определения новых инвестиционных проектов, в целях реализации  которых  средства  бюджета  субъекта  Российской  Федерации,  высвобождаемые в результате снижения объема погашения задолженности  субъекта  Российской  Федерации  перед  Российской  Федерацией по  бюджетным  кредитам,  подлежат  направлению  на  осуществление"}]}
+{"image": "doclay/doclay_55677.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "✓ Disaster recovery costs:  In theory, the cloud service has  its own disaster recovery capabilities, so there may be  a consequential savings on disaster recovery. However,  you need to clearly understand what your cloud provider’s  disaster recovery capability is. For example, does the  cloud service provider have mirrored sites in case of a  power outage at one data center location? IT management  must determine the level of support the cloud provider  will offer. This can be an added cost from the provider,  or you may seek out a secondary vendor to handle disaster recovery and procedures.\n✓ Data center infrastructure costs:  A whole series of costs — including electricity, floor space, cooling, and  building maintenance — are an integral part of managing  any data center. Because of the large investment in data  centers, moving workloads to a public cloud may not be financially viable if you’re only utilizing as little as 40 percent of the data center’s compute power. (Of course,  you can deploy a private cloud to take advantage of the  underutilized space and the advantages of the cloud.)\n✓ Software maintenance costs:  What’s the annual maintenance cost for the software you may move to a  cloud-based service? The answer can be complicated if  the software license is part of a bundle or if the application  is integrated with other applications. In addition, there’s  the cost of purchasing the software. Is the organization  taking advantage of a “pay-as-you go” licensing model  that allows the user to pay only for what’s used?\n✓ Platform costs:  Some applications run only on specific  operating environments — Windows, Linux, HP-UX, IBM z/OS, AIX, and so on. The annual maintenance costs \n✓ Backup and archive costs:  The actual savings on backup  costs depends on what the backup strategy is when the  application moves into the cloud. The same is true of  archiving. First, you have to understand who’s doing the  backup and archiving. Is backup the responsibility of the  IT organization or is it handled by the service provider?  Will all backup be done in the cloud? If so, do you have  a contingency plan if that cloud service is unavailable  when you need that backup? Will your organization still be  required to back up a percentage of critical data locally?\nCloud Services For Dummies, IBM Limited Edition \n30\nThese materials are the copyright of John Wiley & Sons, Inc. and any  dissemination, distribution, or unauthorized use is strictly prohibited."}]}
+{"image": "doclay/doclay_2921.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "NAVWEPS 00-8OT-80  BASIC AERODYNAMICS \nage relative wind which is different from the  remote free stream wind.  Since the aerody-  namic forces created by the airfoil sections of a  wing depend upon the immediate airstream in  which they operate, consideration must be  given to the effect of the inclined average rela-  tive wind. \nvortex filaments which consist of the tip or  trailing vortices coupled with the bound or  line vortex. The tip vortices are coupled with  the bound vortex when circulation is induced  with lift.  The effect of this vortex system is  to create certain vertical velocity components  in the vicinity of the wing.  The illustration  of these vertical velocities shows that ahead  of the wing the bound vortex induces an up-  wash.  Behind the wing, the coupled action  of the bound vortex and the tip vortices in-  duces a downwash.  With the action of tip  and bound vortices coupled, a final vertical  velocity (220) is imparted to the airstream by  the wing producing lift.  This result is an  inevitable consequence  of a finite wing pro-  ducing lift.  The wing Producing lift applies  the equal and opposite force to the airstream  and deflects it downward. One of the impor-  tant factors in this system is that a downward  velocity is created at the aerodynamic center  (w) which is one half the final downward  velocity imparted to the airstream (2~).  The effect of the vertical velocities in the \nTo create a certain lift coefficient with the  airfoil section, a certain angle must exist be-  tween the airfoil chord line and the avcragc  relative wind.  This angle of attack is a,,, the  section angle of attack.  However, as this lift  is developed on the wing, downwash is in-  curred and the average relative wind is in-  clined.  Thus, the wing must be given some  angle attack greater than the required section  angle of attack to account for the inclination of  the average relative wind.  Since the wing  must be given this additional angle of attack  because  of the induced flow, the angle between  the average reiative wind arid tlie remote fiCC  stream is termed the induced angle of attack,  ai.  From this influence, the wing angle of  attack is the sum of the section and induced  angles of attack. \nvelocity imparted to the airstream (2~).  The effect of the vertical velocities in the  vicinity of the wing is best appreciated when  they are added vectorially to the airstream  velocity.  The remote free stream well ahead  of the wing is unaffected and its direction is  opposite the flight path of the airplane.  ‘ Aft  of the wing, the vertical velocity (2~) adds to  the airstream velocity to produce the down-  wash angle e (epsilon).  At the aerodynamic  center of the wing, the vertical,velocity (w)  adds to the airstream velocity to produce a  downward deflection of the airstream one-half  that of the downwash angle. In other words,  the wing producing lift by the deflection of an  airstream incurs a downward slant co the wind  in the immediate vicinity of the wing.  Hence,  the JeCtionJ  of the wing operate  in an average rela-  tive wind which is inclined downward  one-half  the  final dowraw& angle. This is one important  feature which distinguishes the aerodynamic  properties of a wing from the aerodynamic  properties of an airfoil section.  The induced velocities existing at the aero- \nAnother important influence of the induced  flow is the orientation of the actual lift on a  wing.  Figure 1.30 illustrates the fact that the  lift produced by the wing sections is perpen-  dicular to the average relative wind.  Since  the average relative wind is inclined down-  ward, the section lift is inclined aft, by the  same amount-the  induced angle of attack,  ai.  The lift and drag of a wing must continue  to be referred perpendicular and parallel to the  remote free stream ahead of the wing.  In this  respect, the lift on the wing has a component  of force parallel to the remote free stream.  This component of lift in the drag direction  is the undesirable-but  unavoidable-conse- \na=ul)+a;  where  a= wing angle of attack  OLD=  section angle of attack  OI;= induced angle of attack \nproperties of an airfoil section.  The induced velocities existing at the aero-  dynamic center of a finite wing create an aver- \nINDUCED DRAG \n66 "}]}
+{"image": "doclay/doclay_13185.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "MANAGEMENT’S DISCUSSION & ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS\nINTEREST SENSITIVITY AND DISCLOSURES ABOUT MARKET RISK continued\nResults for the base, rising and falling interest rate scenarios are listed below, based upon the Corporation's rate sensitive assets at December 31, 2002. The net interest income shown represents cumulative net interest income over a 12-month time horizon. Balance sheet assumptions used for the base scenario are the same for the rising and falling simulations.\nBASE RISING FALLING =============================================================================== Net Interest Income (dollars in thousands) $105,138 $113,855 $ 98,793 Variance from base $ 8,717 $ (6,345) Percent of change from base 8.29% (6.03)%\nEARNING ASSETS\nEARNING ASSETS\nEarning assets increased approximately $355 million during 2003. The table below reflects the earning asset mix for the years 2003 and 2002 (at December 31).\nLoans grew by $349.2 million, while investment securities increased by $14.8 million. $298.7 million of the increase in loans and $12.5 million of the increase in investment securities are attributable to the March 1, 2003 acquisition of CNBC Bancorp. Excluding increases related to this acquisition, loans increased by $50.5 million and investments increased by $2.3 million.\nEARNING ASSETS (dollars in millions) December 31, ================================================================================ 2003 2002 -------- -------- Federal funds sold and interest-bearing time deposits $ 40.6 $ 35.0 Securities available for sale ....................... 348.9 332.9 Securities held to maturity ......................... 7.9 9.1 Mortgage loans held for sale ........................ 3.0 21.5 Loans ............................................... 2,353.6 2,004.4 Federal Reserve and Federal Home Loan Bank stock .... 15.5 11.4 -------- -------- Total ........................................... $2,769.5 $2,414.3 ======== ========\n15"}]}
+{"image": "doclay/doclay_33276.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "3\nA. Gilbert-Landau-Lifshitz Equations\nIV. HEATING RATE PER UNIT VOLUME\nB. Landau-Khalatnikov-Tani Equations\nA. Relaxation via Magnetostriction\nThe driving magnetic intensity determines the torque on the magnetic moments according to\nEmploying Eqs.(11) and (17), one finds the equations for magnetic resonance in the Gilbert form\nwherein the Gilbert dimensionless damping tensor α is defined as\nOne may directly solve the Gilbert equations for the driv- ing magnetic intensity according to\n( ) Eqs.(17) and (20) express the magnetic resonance motion in the Landau-Lifshitz form.\nThe driving electric field gives rise to a polarization response according to\nwherein ω$_{p}$ is the plasma frequency. A simple derivation of Eq.(21) may be formulated as follows. In a large vol- ume V , the polarization due to charges { z$_{j}$e } is given by\nIf the driving electric field accelerates the charges accord- ing to\nthen Eq.(21) holds true with the plasma frequency\nwherein n$_{a}$ is the density of charged particles of type a .\nThe polarization resonance equation of motion follows from Eqs.(16) and (21) as 17\nFrom the magnetostriction Eq.(10), it follows that magnetic relaxation gives rise to a strain\nCrystal viscosity is employed to describe, among other things, sound wave attenuation. Our purpose is to de- scribe how heating rates in Eqs.(29) and (30) can be re- lated to the heating rate in Eq.((31)). This allows us to express the transport coefficients τ in terms of the crystal viscosity.\nFinally, the notion of crystal viscosity η$_{ijkl}$ is introduced into elasticity theory 35 via the heating rate per unit vol- ume from rates of change in the strain ∂ e /∂t ; It is\nLet us here consider the heating rate implicit in relax- ation processes. Independently of the details of the mi- croscopic mechanism for generating such heat, the rates of energy dissipation are entirely determined by τ . Ex- plicitly, the heating rates per unit volume for magnetiza- tion and polarization are given, respectively, by\nEq.(28) represents the Landau-Khalatnikov equation for polarized systems.\nIf the decay rates are large on the scale of the the resonant frequencies, then the equation of motion is over damped so that\nThe electric field E induces the polarization P at reso- nant frequencies which are eigenvalues of the tensor Ω for which\nThe decay rates for the polarization oscillations are eigen- values of the tensor Γ for which\n∂ M ∂t = γ M × H$_{d}$ . (17)\n∂ M ∂t = γ M × [ H − ( ∂w ∂ M ) s, σ − ( α γM ) · ∂ M ∂t ] , (18)\nα = ( γM ) τ . (19)\nH$_{d}$ + α · ( N × H$_{d}$ ) = H − ( ∂w ∂ M ) s, σ . (20) Eqs.(17) and (20) express the magnetic resonance motion\n∂ $^{2}$P ∂t 2 = ( ω 2 p 4 π ) E$_{d}$ , (21)\nand\nP = (∑ j z$_{j}$e r$_{j}$ V ) . (22)\nm$_{j}$ ¨ r$_{j}$ = z$_{j}$ e E$_{d}$ , (23)\nω 2 p = 4 πe 2 lim V →∞ [∑ $_{j}$( z 2 $_{j}$/m$_{j}$ ) V ] = 4 πe 2 ∑ a n$_{a}$z 2 a m$_{a}$ , (24)\n( 4 π ω 2 p ) ∂ $^{2}$P ∂t 2 + τ · ∂ P ∂t + ∂w ( P , s, σ ) ∂ P = E . (25)\nΩ 2 = ω 2 p χ − 1 4 π ≡ ω 2 $_{p}$( ϵ − 1 ) − 1 . (26)\nΓ = ω 2 p τ 4 π . (27)\n˙ q$_{M}$ = ∂ M ∂t · τ · ∂ M ∂t , (29)\n˙ q$_{P}$ = ∂ P ∂t · τ · ∂ P ∂t . (30)\n˙ q e = ∂e$_{ij}$ ∂t η$_{ijkl}$ ∂e$_{kl}$ ∂t . (31)\n∂e$_{ij}$ ∂t = 2 M Λ$_{ijkl}$ N$_{k}$ ∂M$_{l}$ ∂t , (32)\nmin j Γ$_{j}$ ≫ max i Ω$_{i}$ implies τ · ∂ P ∂t + ∂w ( P , s, σ ) ∂ P = E . (28)"}]}
+{"image": "doclay/doclay_68297.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Draft Document for Review February 7, 2020 4:43 pm\n8464ch12_Performance.fm\nFigure 12-3 shows the read hit performance numbers.\n0 500 1000 1500 2000 2500 3000 TS7760Tcp1 VEC-T/CSA/XSA R 4.0 (26-DRs/8x8Gb/zEC12) TS7760Tcp0 VEC-T/CSA/XSA R 4.0 (26-DRs/8x8Gb/zEC12) TS7760Tcp1 VEC-T/CSA/XSA R 4.0 (10-DRs/8x8Gb/zEC12) TS7760 VEC/CSA/XSA R 4.0 (10-DRs/8x8Gb/zEC12) TS7720Tcp1 VEB-T/CS9/XS9 R 3.2 (26-DRs/8x8Gb/z10) TS7720Tcp1 VEB-T/CS9/XS9 R 3.2 (10-DRs/8x8Gb/z10) TS7740 V07/CC9/CX9 R 3.2 (3DRs/8x8Gb/z10) TS7720 VEB/CS9/XS9 R 3.2 (10-DRs/8x8Gb/z10) TS7740 V07/CC9/CX9 R 3.1 (3DRs/8x8Gb/z10) TS7720 VEB/CS9*/XS9 R 3.1 (42-DRs/8x8Gb/z10) TS7720 VEB/CS9*/XS9 R 3.1 (26-DRs/8x8Gb/z10) TS7720 VEB/CS9*/XS9 R 3.1 (10-DRs/8x8Gb/z10) TS7720 VEB/CS9/XS9 R 3.1 (10-DRs/8x8Gb/z10) TS7740 V07/CC9/CX9 R 3.1 (3DRs/4x1x8Gb/z10) TS7740 V07/CC9/CX9 R 3.0 (3DRs/4x4Gb/z10) TS7720 VEB/CS9/XS9 R 3.0 (10-DRs/4x4Gb/z10) TS7720 VEB/CS8/XS7 R 2.1 (7DRs/4x4Gb/z10) TS7740 V07/CC8/CX7 R 2.1 (4DRs/4x4Gb/z10) TS7720 VEB/CS8/XS7 R 2.0 (19DRs/4x4Gb/z10) TS7720 VEB/CS8/XS7 R 2.0 (7DRs/4x4Gb/z10) TS7740 V07/CC8/CX7 R 2.0 (4DRs/4x4Gb/z10) TS7720 VEA/CS8/XS7 R 1.7 (19DRs/4x4Gb/z10) TS7720 VEA/CS8/XS7 R 1.7 (7DRs/4x4Gb/z10) TS7740 V06/CC8/CX7 R 1.7 (4DRs/4x4Gb/z10) TS7720 VEA/CS7/XS7 R 1.6 (7DRs/4x4Gb/z10) TS7740 V06/CC7/CX7 R 1.6 (4DRs/4x4Gb/z10) TS7720 VEA/CS7/XS7 R 1.5 (7DRs/4x4Gb/z10) TS7740 V06/CC6/CX6 R 1.5 (4DRs/4x2Gb/z990) TS7740 V06/CC6/CX6 R 1.5 (4DRs/4x2Gb/z900) TS7740 V06/CC6/CX6 R 1.3 (4DRs/4x2Gb/z900) B20 VTS (8xFICON) W/FPA B10 VTS (4xFICON) Host MB/s (Uncompressed) 3 T A N D A L O N E 6 4 3 4 3 2 E A D ( I T 0 E R F O R M A N C E ( I S T O R Y Read Hit\nFigure 12-3 VTS and TS7700 maximum host read hit throughput\nThe numbers that are shown in Figure 12-3 were obtained with 128 concurrent jobs in all  runs, each job uses 32 KiB blocks, and QSAM BUFNO = 20. Before R 3.2, the volume size  was 800 MiB (300 MiB volumes @ 2.66:1 compression). Since R 3.2, the volume size is 2659  MiB (1000 MiB volumes @ 2.66:1 compression).\nFrom a performance aspect, the architecture offers the following important characteristics:\nGLYPH<SM590000> With the selection of IBM Db2fi as the central repository in the TS7700, the TS7700  provides a standard Structured Query Language (SQL) interface to the data, and all data  is stored and managed in one place. Db2 also allows for more control over performance.\nGLYPH<SM590000> The cluster design with virtualization node (vNode) and hierarchical data storage  management node (hnode) provides increased configuration flexibility over the monolithic  design.\nGLYPH<SM590000> The use of Transmission Control Protocol/Internet Protocol (TCP/IP) instead of FICON for  site-to-site communication eliminates the requirement to use channel extenders.\nChapter 12. Performance considerations  705"}]}
+{"image": "doclay/doclay_45612.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Figure 12-26.  Cold front cross-section with surface weather chart depiction and associated METAR. \nStationary Front \nOccluded Front \nWind Shifts \nsteeper frontal slope. Violent weather activity is associated with  cold fronts, and the weather usually occurs along the frontal  boundary, not in advance. However, squall lines can form  during the summer months as far as 200 miles in advance of  a strong cold front. Whereas warm fronts bring low ceilings,  poor visibility, and rain, cold fronts bring sudden storms, gusty  winds, turbulence, and sometimes hail or tornadoes. \nCold fronts are fast approaching with little or no warning,  and they bring about a complete weather change in just a  few hours. The weather clears rapidly after passage and drier  air with unlimited visibilities prevail. Warm fronts, on the  other hand, provide advance warning of their approach and  can take days to pass through a region. \nWind around a high-pressure system rotates clockwise, while  low-pressure winds rotate counter-clockwise. When two  high pressure systems are adjacent, the winds are almost in  direct opposition to each other at the point of contact. Fronts  are the boundaries between two areas of high pressure, and  therefore, wind shifts are continually occurring within a front.  Shifting wind direction is most pronounced in conjunction  with cold fronts. \nWhen the forces of two air masses are relatively equal, the  boundary or front that separates them remains stationary and  influences the local weather for days. This front is called a  stationary front. The weather associated with a stationary  front is typically a mixture that can be found in both warm  and cold fronts. \nAn occluded front occurs when a fast-moving cold front  catches up with a slow-moving warm front. As the occluded  front approaches, warm front weather prevails but is  immediately followed by cold front weather. There are two  types of occluded fronts that can occur, and the temperatures  of the colliding frontal systems play a large part in defining  the type of front and the resulting weather. A cold front  occlusion occurs when a fast moving cold front is colder  than the air ahead of the slow moving warm front. When  this occurs, the cold air replaces the cool air and forces the  warm front aloft into the atmosphere. Typically, the cold  front occlusion creates a mixture of weather found in both  warm and cold fronts, providing the air is relatively stable.  A warm front occlusion occurs when the air ahead of the \n12-21 \nSt. Louis  Indianapolis 200 miles  Columbus  400 miles  Pittsburgh 600 miles  METAR KSTL 1950Z 30018KT 10SM SCT010 08/02 A2979 METAR KIND 1950Z 20024KT 3SM +TSRA OVC010  24/23  A2974  METAR KCMH 1950Z 20012KT 6SM HZ BKN025 25/24 A2983 METAR KPIT 1950Z 20012KT 3SM FU SCT035  24/22  A2989  1011  1008 1005 1005 1008  1011  1011  1011  1014  1014  St. Louis  Indianapolis  Columbus  Pittsburgh  46  42  10  066 10  33  74  071  3  71  77  6  73  75  3  70  35  4  8  12  102  122  10  25  WARM AIR  C O L D A I R  CUMULONIMBUS "}]}
+{"image": "doclay/doclay_74951.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Critical Accounting Policies\nOther Matters\n41\nThe preparation of the Company’s Consolidated Financial Statements requires management to make estimates and assumptions that affect the amounts reported in the financial statements and accompanying notes. Management evaluates these estimates and assump- tions on an ongoing basis. Estimates are based on historical experience, when available, and on various other assumptions that are believed to be reasonable under the circumstances, the results of which form the basis for making judgments about the carrying  values of assets and liabilities that are not readily apparent from other sources. Actual results may differ from these estimates under different assumptions or conditions.\nManagement believes that of its significant accounting policies (see Note 1 to the Consolidated Financial Statements), an under- standing of the following critical accounting policies is important in obtaining an overall understanding of the Consolidated Financial Statements.\nAllowance for Doubtful Accounts: The Company maintains an allowance for doubtful accounts for estimated losses in the collection of accounts receivable. The Company makes estimates regarding the future ability of its customers to make required payments based on historical credit experience and expected future trends. If actual customer financial conditions are less favorable than projected by management, additional accounts receivable write-offs may be necessary, which could unfavorably affect future operating results.\nInventory Reserves: The Company maintains reserves for excess and obsolete inventory resulting from the potential inability to sell its products at prices in excess of current carrying costs. The markets in which the Company operates are highly competitive, with new products and surgical procedures introduced on an ongoing basis. Such marketplace changes may cause some of the Company’s products to become obsolete. The Company makes estimates regarding the future recoverability of the costs of these prod- ucts and records a provision for excess and obsolete inventories based on historical experience, expiration of sterilization dates  and expected future trends. If actual product life cycles, product demand or acceptance of new product introductions are less favor- able than projected by management, additional inventory write-downs may be required, which could unfavorably affect future  operating results.\nIncome Taxes: The Company operates in multiple tax jurisdictions both inside and outside the United States. Accordingly, man- agement must determine the appropriate allocation of income to each of these jurisdictions. Tax audits associated with the alloca- tion of this income and other complex issues may require an extended period of time to resolve and may result in income tax adjustments if changes to the income allocation are required between jurisdictions with different tax rates. Because tax adjustments in certain jurisdictions can be significant, the Company records accruals representing management’s best estimate of the probable resolution of these matters. To the extent additional information becomes available, such accruals are adjusted to reflect the revised estimated probable outcome.\nThe Company distributes its products throughout the world. As a result, the Company’s financial results could be significantly affected by factors such as changes in foreign currency exchange rates or weak economic conditions in foreign markets. The Company’s oper- ating results are primarily exposed to changes in exchange rates among the United States dollar and the Japanese yen and European currencies, in particular the euro and the British pound. When the United States dollar weakens against foreign currencies, the dol- lar value of sales denominated in foreign currencies increases. When the United States dollar strengthens, the opposite situation occurs. The Company manufactures its products in the United States, France, Germany, Ireland, Switzerland, Canada and Puerto Rico and incurs the costs to manufacture in the applicable local currencies. This worldwide deployment of factories serves to partially  mitigate the impact of currency exchange rate changes on the Company’s cost of sales.\nThe Company enters into forward currency exchange contracts to mitigate the impact of currency fluctuations on transactions denominated in nonfunctional currencies, thereby limiting risk to the Company that would otherwise result from changes in exchange rates. These nonfunctional currency exposures principally relate to intercompany receivables and payables arising from inter- company purchases of manufactured products. The periods of the forward currency exchange contracts correspond to the periods of the exposed transactions, with realized gains and losses included in the measurement and recording of transactions denominated in the nonfunctional currencies."}]}
+{"image": "doclay/doclay_48718.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Verordnung über die Berufsausbildung zum Fahrzeuglackierer/zur Fahrzeuglackiererin\nFzgLackAusbV\nAusfertigungsdatum: 03.07.2003\nVollzitat:\n\"Verordnung über die Berufsausbildung zum Fahrzeuglackierer/zur Fahrzeuglackiererin vom 3. Juli 2003 (BGBl. I S. 1083, 1548)\"\n(+++ Textnachweis ab: 1.8.2003 +++)\nDiese Rechtsverordnung ist eine Ausbildungsordnung im Sinne des § 25 der Handwerksordnung und des § 25 des Berufsbildungsgesetzes. Die Ausbildungsordnung und der damit abgestimmte, von der Ständigen Konferenz der Kultusminister der Länder in der Bundesrepublik Deutschland beschlossene Rahmenlehrplan für die Berufsschule werden demächst als Beilage im Bundesanzeiger veröffentlicht.\nAuf Grund des § 25 Abs. 1 in Verbindung mit Abs. 2 Satz 1 des Berufsbildungsgesetzes vom 14. August 1969 (BGBl. I S. 1112), der zuletzt durch Artikel 212 Nr. 2 der Verordnung vom 29. Oktober 2001 (BGBl. I S. 2785) geändert worden ist, und des § 25 Abs. 1 in Verbindung mit Abs. 2 Satz 1 der Handwerksordnung in der Fassung der Bekanntmachung vom 24. September 1998 (BGBl. I S. 3074), von dem Absatz 1 durch Artikel 135 Nr. 3 der Verordnung vom 29. Oktober 2001 (BGBl. I S. 2785) geändert worden ist, jeweils in Verbindung mit § 1 des Zuständigkeitsanpassungsgesetzes vom 16. August 2002 (BGBl. I S. 3165) und dem Organisationserlass vom 22. Oktober 2002 (BGBl. I S. 4206) verordnet das Bundesministerium für Wirtschaft und Arbeit im Einvernehmen mit dem Bundesministerium für Bildung und Forschung:\nDer Ausbildungsberuf Fahrzeuglackierer/Fahrzeuglackiererin wird\nstaatlich anerkannt.\n(1) Die Ausbildung dauert drei Jahre.\n(2) Auszubildende, denen der Besuch eines nach landesrechtlichen Vorschriften eingeführten schulischen Berufsgrundbildungsjahres nach einer Verordnung gemäß § 27a Abs. 1 der Handwerksordnung und § 29 Abs. 1 des Berufsbildungsgesetzes als erstes Jahr der Berufsausbildung anzurechnen ist, beginnen die Berufsausbildung im zweiten Ausbildungsjahr.\n(1) Die Ausbildung im ersten Ausbildungsjahr vermittelt eine berufsfeldbreite Grundbildung, wenn die betriebliche Ausbildung nach dieser Verordnung und die Ausbildung in der Berufsschule nach landesrechtlichen Vorschriften über das Berufsgrundbildungsjahr erfolgen.\n(2) Die in dieser Verordnung genannten Fertigkeiten und Kenntnisse sollen so vermittelt werden, dass die Auszubildenden zur Ausübung einer qualifizierten beruflichen Tätigkeit im Sinne von § 1 Abs. 2 des Berufsbildungsgesetzes befähigt werden, die insbesondere selbständiges Planen, Durchführen und Kontrollieren einschließt. Diese Befähigung ist auch in den Prüfungen nach den §§ 9 und 10 nachzuweisen.\n- Seite 1 von 12 -\n1. gemäß § 25 der Handwerksordnung für die Ausbildung für das Gewerbe Nr. 13, Maler und Lackierer, der Anlage A der Handwerksordnung sowie\n2. gemäß § 25 des Berufsbildungsgesetzes\nFußnote\nEingangsformel \n§ 1 Staatliche Anerkennung der Ausbildungsberufe\n§ 2 Ausbildungsdauer\n§ 3 Berufsfeldbreite Grundbildung und Zielsetzung der Berufsausbildung"}]}
+{"image": "doclay/doclay_31659.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "II. THEORETICAL FRAMEWORK\nThe starting point of the DDRHF theory is an effective Lagrangian density L [21], which contains the degrees of freedom associated with the nucleon field ( ψ ), two isoscalar meson fields ( σ and ω ), two isovector meson fields ( π and ρ ) and the photon field ( A ). Then the effective Hamiltonian H is obtained with the general Legendre transformation. On the level of the mean field approximation, the energy functional E is obtained by taking the expectation of the Hamiltonian H , where both the Hartree (direct) and Fock (exchange) terms are kept. Finally, the Dirac equations, i.e. the equations of motion of nucleons, are obtained via the variation of the energy functional E .\nFor spherical nuclei, the nucleon Dirac spinor can be written as,\nwhere χ 1 $_{2}$( τ$_{a}$ ) is the isospinor, Y l$_{a}$ j$_{a}$m$_{a}$ is the spherical harmonics spinor and Y ˜ l$_{a}$ j$_{a}$$_{m$_{a}$}$(ˆ r ) = − ˆ σ · ˆ r Y l$_{a}$ j$_{a}$$_{m$_{a}$}$(ˆ r ) with ˜ l$_{a}$ = 2 j$_{a}$ − l$_{a}$ . For the negative energy states, the lower component F ( r ) is dominant. The states are labelled by { ˜ n ˜ ljm } with the relation\nin analogy to Ref. [26]. The spin symmetry concerns the near degeneracy of the states (˜ n, ˜ l, j = ˜ l ± 1 / 2). In the following equations, the sub-index will be omitted for simplicity.\nThe radial Dirac equations are the coupled integro-differential ones due to the non-local Fock terms X and Y [18],\nIntroducing the effective local potentials X$_{G}$, X$_{F}$, Y$_{G}$ and Y$_{F}$ by the definitions,\n3\nY ( r ) = G ( r ) Y ( r ) G 2 + F 2 G ( r ) + F ( r ) Y ( r ) G 2 + F 2 F ( r ) ≡ Y$_{G}$ ( r ) G ( r ) + Y$_{F}$ ( r ) F ( r ) , (4b)\nX ( r ) = G ( r ) X ( r ) G 2 + F 2 G ( r ) + F ( r ) X ( r ) G 2 + F 2 F ( r ) ≡ X$_{G}$ ( r ) G ( r ) + X$_{F}$ ( r ) F ( r ) , (4a)\nEF ( r ) = + [ d dr + κ r ] G ( r ) − [ M + Σ$_{S}$( r ) − Σ$_{0}$( r )] F ( r ) + X ( r ) . (3b)\nEG ( r ) = − [ d dr − κ r ] F ( r ) + [ M + Σ$_{S}$( r ) + Σ$_{0}$( r )] G ( r ) + Y ( r ) , (3a)\nn = ˜ n, for κ > 0 , n = ˜ n + 1 , for κ < 0 , (2)\nf$_{α}$ ( r ) = 1 r   iG$_{n}$$_{a}$ ( r ) Y l$_{a}$ j$_{a}$$_{m$_{a}$}$(ˆ r ) − F$_{˜}$ $_{n$_{a}$}$( r ) Y ˜ l$_{a}$ j$_{a}$$_{m$_{a}$}$(ˆ r )   χ 1 $_{2}$( τ$_{a}$ ) , (1)"}]}
+{"image": "doclay/doclay_25431.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "consideration of whether or not the empirical process term represents the dominant error term, or whether the second-order remainder that appears due to the non-linearity of the value parameter represents the dominant error term. In restricted, semiparametric models, we suspect that, depending on the underlying margin, an inefficient estimator of the value may yield a faster rate of regret decay than an efficient estimator. Despite this surprising phenomenon, we continue to advocate the use of first-order efficient value estimators.\nAlex Luedtke gratefully acknowledges the support of the New Development Fund of the Fred Hutchinson Cancer Research Center. Antoine Chambaz acknowledges the support of the French Agence Nationale de la Recherche (ANR), under grant ANR-13-BS01-0005 (project SPADRO) and that this research has been conducted as part of the project Labex MME-DII (ANR11-LBX-0023-01).\n22\nAcknowledgements"}]}
+{"image": "doclay/doclay_77401.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "9-11 \nFigure 9-19.  AN standard fittings. \nAN744 to AN932  Material:  Aluminum alloy .............................................................................................................................................(code D)  Steel ..............................................................................................................................................................(code, absence of letter)  Brass .............................................................................................................................................................(code B)  Aluminum bronze..........................................................................................................................................(code Z–for AN819 sleeve)  Size:  The dash number following the AN number indicates the size of the tubing (or hose) for which the fitting is made in 16ths of an  inch. This size measures the outer diameter of tubing and the inner diameter of hose. Fittings that have pipe threads are coded by  a dash number, indicating the pipe size in 8ths of an inch. The material code letter, as noted above, follows the dash number.  ELBOW AN821  ELBOW AN823  TEE AN825  ELBOW AN822  TEE AN824  TEE AN826  CROSS AN827  UNION AN832  ELBOW AN838  ELBOW AN839  TEE AN804  PLUG AN806  UNION AN815  NUT AN817  NUT AN818  SLEEVE AN819  CAP AN820 NIPPLE AN816  BOLT AN774  BOLT AN775  ELBOW AN776  ELBOW AN777  ELBOW AN778  TEE AN779  PLUG AN814  ADAPTOR AN807  ELBOW AN833  TEE AN834  ELBOW AN837 "}]}
+{"image": "doclay/doclay_40779.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "support for all axis and include a  calibration sphere (sphere accuracy  must be within 1 micron of specified  size) with stand and case.  2.4.25 Machine shall be provided with a tool  laser measurement system, mounted  inside the machine and completely  wired,  in  full-working  state,  for  locating and measuring cutting tools.  2.4.26 Device shall have USB and Ethernet  connections for data transfer.  2.4.27 Device shall have coolant system with  at least 14 bar coolant pumps.  2.5 Tool Balancing Machine  Quantity:1  Manufacturer’s name  Product model/type  Country of Origin  Definition  Device shall be used to determine the  location and amount of imbalance and  to correct the balancing of tool holders  used in CNC machines.  2.5.1 The machine must be able to balance  tool holders vertically; both in static  (single-axis) and dynamic (dual-axis)  balancing sequences.  2.5.2 Body of the balance machine shall be  polymer  concrete  or  cast  mineral  composite to absorb vibrations.  2.5.3 Machine shall have control unit and \nAugust 2020 c4f_annexiitechspeciiitechoffer_en.doc \nPage 36 of 49 "}]}
+{"image": "doclay/doclay_80158.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "81 \n80 \n\"SEC. 236. In the case of industrial life  insurance, the policy shall contain in substance the  following provisions: \n\"(a) A provision that the insured is entitled to a  grace period of four (4) weeks within which the  payment of any premium after the first may be made,  except that where premiums are payable monthly, the  period of grace shall be either one (1) month or thirty  (30) days; and that during the period of grace, the policy  shall continue in full force, but  if  during such grace  period the policy becomes a  claim,  then any overdue  and unpaid premiums may be deducted from any  amount payable under the policy in settlement; \n\"(b) A provision that the policy shall be  incontestable after it has been in force during the  lifetime of the insured for a specified period, not more  than two (2) years from its date of issue, except for  nonpayment of premiums and except for violation of  the conditions of the policy relating to naval or military  service, or services auxiliary thereto, and except as  to  provisions relating to benefits  in  the event of disability  as defined  in  the policy, and those granting additional  insurance specifically against death by accident or by  accidental means, or to additional insurance against  loss of, or loss of use of, specific members of the body; \nII  (c) A provision that the policy shall constitute  the entire contract between the parties, or  if  a copy of  the application is endorsed upon and attached to the  policy when issued, a provision that the policy and  the application therefor shall constitute the entire  contract between the parties, and in the latter case,  a provision that all statements made by the insured  shall, in the absence of fraud, be deemed  representations and not warranties; \n\"(d) A provision that  if  the age of the person  insured, or the age of any person, considered in  determining the premium, or the benefits accruing  under the policy, has been misstated, any amount  payable or benefit accruing under the policy shall be  such as the premium paid would have purchased at  the correct age; \n\"(e) A prOVISIOn that if the policy is a  participating policy, the company shall periodically  ascertain and apportion any divisilile surplus accruing  on the policy under the conditions specified therein; \n\"(f)  A provision that in the event of default in  premium payments after three (3) full years’  premiums have been paid, the policy shall be converted  into a stipulated form of insurance, and that in the  event of default in premium payments after five (5)  full  years’ premiums have  bee~  paid, a specified cash  surrender value shall be av’Eiilable, in lieu of the  stipulated form of insUfailce, at the option of the  policyholder. The net value of such stipulated form of  insurance and the amount’ of such tash value shall  not be less than the reserve on the policy and dividend  additions thereto, if any, at the end of the last  completed policy year for which premiums shall have  been paid (the policy to specify the mortality table,  rate of interest and method of valuation adopted to  compute such reserve), exclusive of any reserve on  disability benefits and,acciaental death benefits, less  I  an amount not to exceed two and one-half percent  (2’>’2%) of the maximum amount insured by the policy  and dividend additions thereto,  if  any, when the issue  age is under ten (10) years, and less an amount not  to exceed two and one-half percent (27’2%) of the  current amount insured by the policy and dividend  additions thereto,  if  any,  if  the issue age is ten (10)  years or older, and less any existing indebtedness to  the company on or secured by the policy; \n\"(g) A provision that the policy may be  surrendered to the company at its home office within  a period of not less than sixty (60) days after the due  date of a premium in default for the specified cash  value:  Provided,  That the insurer may defer payment  for not more than six (6) months after the application  , therefor  is  made;  ’i\\ \n\"(h) A table that shows in figures the  nonforfeiture benefits available under the policy every  year upon default in payment of premiums during at  least the first twenty (20) years of the policy, such "}]}
+{"image": "doclay/doclay_76008.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "We denote by J$_{n}$ the n × n matrix with 1’s on the antidiagonal and 0’s elsewhere, i.e. the matrix ( e$_{i,j}$ ) = δ$_{i,n}$$_{+1}$$_{−}$$_{j}$ . J$_{n,m}$ shall denote the block matrix which has J$_{n}$ in the upper-right block, − J$_{m}$ in the lower-left block, and 0’s elsewhere. That is,\nJ$_{n,m}$ :=    0 J$_{n}$ − J$_{m}$ 0   $_{}$.\nFor any group G with g ∈ G , int( g ) shall denote the inner automorphism “conjugation by g ”.\nWe will use both “one-line” notation and cycle notation for permutations. When giving a permutation in one-line notation, the sequence of values will be listed with no delimiters, while for cycle notation, parentheses and commas will be used. Hopefully this will remove any possibility for confusion on the part of the reader. So, for example, the permutation π ∈ S$_{4}$ which sends 1 to 2, 2 to 3, 3 to 1, and 4 to 4 will be given in one-line notation as 2314 and in cycle notation as (1 , 2 , 3).\nWe shall often have occasion to consider “signed permutations”, which are bijections σ from the set {± 1 , ± 2 . . . , ± n } to itself having the property that\nσ ( − i ) = − σ ( i )\nfor all i . We define the absolute value of such a permutation, denoted | σ | , to be the permu- tation of { 1 , . . . , n } given by\n| σ | ( i ) = | σ ( i ) | .\nSigned permutations will usually be written in one-line notation with bars over some of the numbers to indicate negative values. For instance, the signed permutation σ = 132 is defined by σ (1) = 1, σ (2) = 3, and σ (3) = − 2.\n12"}]}
+{"image": "doclay/doclay_29568.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "polishing.Figure 9: A 5 µ m-wide trench made by damascene process\nUsing this striped pattern, the differences in the spatial resolution with respect to the read out directions are measured. Fig. 10 shows the hit position distribution measured with the pattern, and Fig. 11 shows the their projections onto the horizontal and vertical direction.\nThe spatial resolution is evaluated by fitting. The fitting function is ex- pressed by the sum of an error function and a complementary error function:\nwhere x is the hit position, σ is the spatial resolution, d$_{n}$ is the distance from the initial position of the pattern to the n$_{th}$ stripe, w$_{n}$ is the width of the n$_{th}$ stripe and p$_{1}$ , p$_{2}$ and p$_{3}$ are free fitting parameters. The 12 widest stripes,\n16\nf ( x ) = p$_{1}$ · 12 ∑ n $_{=1}$[ erfc ( $^{x}$− d$_{n}$ √$_{2}$$_{σ}$ + p$_{2}$ ) + erf ( $^{x}$− ( d$_{n}$ + w$_{n}$ ) √$_{2}$$_{σ}$ + p$_{2}$ )] + p$_{3}$, (4)"}]}
+{"image": "doclay/doclay_72555.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "4.25 Restatement Agreement, dated as of September 14, 2018, by and among the Company, CB International Finance S.à r.l., certain of the Company’s subsidiaries as guarantors, Bank of America, N.A., as Administrative Agent, and the Lenders party thereto, including the Eighth Amended and Restated Credit Agreement dated as of September 14, 2018, by and among the Company, CB International Financing S.à r.l., Bank of America, N.A., as Administrative Agent, and the Lenders party thereto (filed as Exhibit 4.1 to the Company’s Current Report on Form 8-K dated September 14, 2018, filed September 19, 2018 and incorporated herein by reference). 4.26 Term Loan Credit Agreement, dated as of September 14, 2018, by and among the Company, Bank of America, N.A., as Administrative Agent, and the Lenders party thereto (filed as Exhibit 4.2 to the Company’s Current Report on Form 8-K dated September 14, 2018, filed September 19, 2018 and incorporated herein by reference). 10.1 Constellation Brands, Inc. Long-Term Stock Incentive Plan, amended and restated as of July 18, 2017 (filed as Exhibit 10.4 to the Company’s Current Report on Form 8-K dated July 18, 2017, filed July 20, 2017 and incorporated herein by reference).  * 10.2 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 1, 2008 and before April 6, 2009) (filed as Exhibit 10.1 to the Company’s Quarterly Report on Form 10-Q for the fiscal quarter ended August 31, 2008 and incorporated herein by reference).  *# 10.3 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 6, 2009 and before April 5, 2010) (filed as Exhibit 99.1 to the Company’s Current Report on Form 8-K dated April 6, 2009, filed April 9, 2009 and incorporated herein by reference).  *# 10.4 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 5, 2010 and before April 3, 2012) (filed as Exhibit 99.1 to the Company’s Current Report on Form 8-K, dated April 5, 2010, filed April 9, 2010 and incorporated herein by reference).  *# 10.5 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 3, 2012 and before April 28, 2014) (filed as Exhibit 99.1 to the Company’s Current Report on Form 8-K dated April 3, 2012, filed April 5, 2012 and incorporated herein by reference).  *# 10.6 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 28, 2014 and before April 25, 2016) (filed as Exhibit 10.1 to the Company’s Current Report on Form 8-K dated April 28, 2014, filed May 1, 2014 and incorporated herein by reference).  *# 10.7 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 25, 2016 and before April 21, 2017) (filed as Exhibit 10.1 to the Company’s Current Report on Form 8-K dated April 25, 2016, filed April 28, 2016 and incorporated herein by reference).  * 10.8 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 21, 2017 and before April 23, 2018) (filed as Exhibit 10.1 to the Company’s Current Report on Form 8-K dated April 21, 2017, filed April 25, 2017 and incorporated herein by reference).  * 10.9 Form of Terms and Conditions Memorandum for Employees with respect to grants of options to purchase Class 1 Stock pursuant to the Company’s Long-Term Stock Incentive Plan (grants on or after April 23, 2018) ( filed as Exhibit 10.1 to the Company’s Current Report on Form 8-K dated April 23, 2018, filed April 26, 2018 and incorporated herein by reference).  * 10.10 Form of Restricted Stock Unit Agreement with respect to the Company’s Long-Term Stock Incentive Plan (grants on or after April 26, 2013 and before April 28, 2014) (filed as Exhibit 10.2 to the Company’s Current Report on Form 8-K dated April 26, 2013, filed May 1, 2013 and incorporated herein by reference).  *# 10.11 Form of Restricted Stock Unit Agreement with respect to the Company’s Long-Term Stock Incentive Plan (grants on or after April 28, 2014 and before April 28, 2015) (filed as Exhibit 10.2 to the Company’s Current Report on Form 8-K dated April 28, 2014, filed May 1, 2014 and incorporated herein by reference).  * # 10.12 Form of Restricted Stock Unit Agreement with respect to Company’s Long-Term Stock Incentive Plan (awards on or after April 28, 2015 and before April 25, 2016) (filed as Exhibit 10.1 to the Company’s Current Report on Form 8-K dated April 28, 2015, filed May 1, 2015 and incorporated herein by reference).  * 10.13 Form of Restricted Stock Unit Agreement with respect to the Company’s Long-Term Stock Incentive Plan (awards on or after April 25, 2016 and before April 21, 2017) (filed as Exhibit 10.2 to the Company’s Current Report on Form 8-K dated April 25, 2016, filed April 28, 2016 and incorporated herein by reference).  *\n119\nTable of Contents"}]}
+{"image": "doclay/doclay_44905.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Extinguishing Agents and Portable Fire  Extinguishers\nInert Cold Gases\nHalogenated Hydrocarbons\nDry Powders\nWater\n17-10\nFigure 17-10.  Hand held fire extinguisher requirement for transport  aircraft.\nClass A type fires are best controlled with water by cooling  the material below its ignition temperature and soaking the  material to prevent re-ignition.\nClass A, B, or C fires can be controlled by dry chemical  extinguishing agents. The only all purpose (Class A, B, C  rating) dry chemical powder extinguishers contain mono- ammonium phosphate. All other dry chemical powders  have a Class B, C U.S – UL fire rating only. Dry powder  chemical extinguishers best control class A, B, and C fire  but their use is limited due to residual residue and clean up  after deployment.\nNOTE: While Halons are still in service and are appropriate  agents for these classes of fires, the production of these \nTwo types of Halons are employed in aviation: Halon  1301(CBrF$_{3}$) a total flooding agent, and Halon 1211  (CBrClF$_{2}$) a streaming agent. Class A, B, or C fires are  appropriately controlled with Halons. However, do not use  Halons on a class D fire. Halon agents may react vigorously  with the burning metal. \nFor over 45 years, halogenated hydrocarbons (Halons) have  been practically the only fire extinguishing agents used in civil  transport aircraft. However, Halon is an ozone depleting and  global warming chemical, and its production has been banned  by international agreement. Although Halon usage has been  banned in some parts of the world, aviation has been granted  an exemption because of its unique operational and fire safety  requirements. Halon has been the fire extinguishing agent  of choice in civil aviation because it is extremely effective  on a per unit weight basis over a wide range of aircraft  environmental conditions. It is a clean agent (no residue),  electrically nonconducting, and has relatively low toxicity. \nThere must be at least one hand held, portable fire  extinguisher for use in the pilot compartment that is located  within easy access of the pilot while seated. There must be at  least one hand held fire extinguisher located conveniently in  the passenger compartment of each airplane accommodating  more than 6 and less than 30 passengers. Each extinguisher  for use in a personnel compartment must be designed to  minimize the hazard of toxic gas concentrations. The number  of portable, hand held fire extinguishers for transport aircraft  is shown in  Figure 17-10.\nozone depleting agents has been restricted. Although not  required, consider replacing Halon extinguishers with  Halon replacement extinguishers when discharged. Halon  replacement agents found to be compliant to date include the  halocarbons HCFC Blend B, HFC-227ea, and HFC-236fa.\nCarbon dioxide (CO$_{2}$) is an effective extinguishing agent. It  is most often used in fire extinguishers that are available on  the ramp to fight fires on the exterior of the aircraft, such as  engine or APU fires. CO$_{2}$ has been used for many years to  extinguish flammable fluid fires and fires involving electrical  equipment. It is noncombustible and does not react with most  substances. It provides its own pressure for discharge from  the storage vessel, except in extremely cold climates where  a booster charge of nitrogen may be added to winterize the  system. Normally, CO$_{2}$ is a gas, but it is easily liquefied by  compression and cooling. After liquification, CO$_{2 }$remains in  a closed container as both liquid and gas. When CO$_{2}$ is then  discharged to the atmosphere, most of the liquid expands to  gas. Heat absorbed by the gas during vaporization cools the  remaining liquid to –110 °F, and it becomes a finely divided  white solid, dry ice snow.\nCarbon dioxide is about 1½ times as heavy as air, which  gives it the ability to replace air above burning surfaces and  maintain a smothering atmosphere. CO$_{2}$ is effective as an  extinguishing agent primarily because it dilutes the air and  reduces the oxygen content so that combustion is no longer  supported. Under certain conditions, some cooling effect  is also realized. CO$_{2}$ is considered only mildly toxic, but  it can cause unconsciousness and death by suffocation if  the victim is allowed to breathe CO$_{2}$ in fire extinguishing  concentrations for 20 to 30 minutes. CO$_{2}$ is not effective as an  extinguishing agent on fires involving chemicals containing  their own oxygen supply, such as cellulose nitrate (used in  some aircraft paints). Also, fires involving magnesium and  titanium cannot be extinguished by CO$_{2}$.\n7 through 30 31 through 60 61 through 200 201 through 300 301 through 400 401 through 500 501 through 600 601 through 700 1 2 3 4 5 6 7 8 Passenger capacity No. of extinguishers"}]}
+{"image": "doclay/doclay_22085.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "notes to the Consolidated Financial Statements (cont’d)\nAs at January 1, 2011 Financial asset  Financial  Items  Total at fair value through  Loans and  liabilities at  accounted for  carrying (Amounts in $000s) profit and loss  receivables amortized cost  as hedges  amount Cash and cash equivalents  $   598 $   – $   – $   – $   598  Accounts receivable   –  50,452  –  –  50,452  Other financial assets   –  –  –  890  890  Bank loans   –  –  42,725  –  42,725  Accounts payable and accrued liabilities   –  –  60,065  –  60,065  Provisions   –  –  550  –  550  Other financial liabilities   –  –  –  2,334  2,334  Other long-term financial liabilities   –  –  –  207  207  Long-term debt   –  –  48,338  –  48,338 \nAs at January 3, 2010 Financial asset  Financial  Items  Total at fair value through  Loans and  liabilities at  accounted for  carrying (Amounts in $000s) profit and loss  receivables amortized cost  as hedges  amount Cash and cash equivalents  $   1,953 $   – $   – $   – $   1,953  Accounts receivable   –  57,963  –  –  57,963  Other financial assets   –  –  –  1,590  1,590  Bank loans   –  –  23,051  –  23,051  Accounts payable and accrued liabilities   –  –  49,905  –  49,905  Provisions   –  –  1,423  –  1,423  Other financial liabilities   –  –  –  3,989  3,989  Other long-term financial liabilities   –  –  –  928  928  Long-term debt   –  –  54,502  –  54,502 \nintereSt rateS uSed for determining fair value\nThe interest rates used to discount the estimated cash flows, when applicable, are based on the government yield curve at the  reporting date plus an adequate credit spread and were as follows:\nDecember 31, 2011 January 1, 2011  January 3, 2010 Bank loans  3.10% 2.27%  1.56% Long-term debt  7.00% 2.30%  4.08% Capital lease obligations  5.90% 5.62%  5.66%\nIn the fifty two-week period ended December 31, 2011, the Company expensed $127 thousand and $306 thousand (January 1, 2011: $457 thousand and $165 thousand) of short-term and long-term interest, respectively, relating to interest that was calculated using  the effective interest rate method relating to its transaction fees and its borrowings. \nThe Company systematically enters into foreign exchange contracts, with maturities of 15 months or less, to hedge future cash  outflows for the purchase of raw materials. The Company uses hedge accounting to account for these foreign exchange contracts. \nAt period-end, the Company had the following total foreign exchange forward single rate contracts outstanding:\namortized coSt impact on intereSt expenSe\nforward exchange contractS\n December 31, 2011 Sell  Receive CAD$  US$ Forward rate  $ 5,327,982  $ 5,294,465\n95\nAnnuAl RepoRt 2011"}]}
+{"image": "doclay/doclay_79224.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "CHAPTER 122. README.SOLARIS\n122.4. RUN CONFIGURE.\nThe transitional compilation environment exports all the explicit 64-bit functions (xxx64()) and types in addition to all the regular functions (xxx()) and types. Both xxx() and xxx64() functions are available to the program source. A 32-bit application must use the xxx64() functions in order to access large files. See the lf64(5) manual page for a complete listing of the 64-bit transitional interfaces.\nThe transitional compilation environment is obtained with the following compiler and linker flags:\nSecond is the \"large file compilation environment\", described in lfcompile(5). According to the man page,\nEach interface named xxx() that needs to access 64-bit entities to access large files maps to a xxx64() call in the resulting binary. All relevant data types are defined to be of correct size (for example, off_t has a typedef definition for a 64-bit entity).\nAn application compiled in this environment is able to use the xxx() source interfaces to access both large and small files, rather than having to explicitly utilize the transitional xxx64() interface calls to access large files.\nTwo exceptions are fseek() and ftell(). 32-bit applications should use fseeko(3C) and ftello(3C). These will get automatically mapped to fseeko64() and ftello64().\nThe large file compilation environment is obtained with\nBy default, perl uses the large file compilation environment and relies on Solaris to do the underlying mapping of interfaces.\nTo compile a 64-bit application on an UltraSparc with a recent Sun Compiler, you need to use the flag \"-xarch = v9\". getconf(1) will tell you this, e.g.\n1624\n$ getconf -a | grep v9 XBS5_LP64_OFF64_CFLAGS: -xarch=v9 XBS5_LP64_OFF64_LDFLAGS: -xarch=v9 XBS5_LP64_OFF64_LINTFLAGS: -xarch=v9 XBS5_LPBIG_OFFBIG_CFLAGS: -xarch=v9 XBS5_LPBIG_OFFBIG_LDFLAGS: -xarch=v9 XBS5_LPBIG_OFFBIG_LINTFLAGS: -xarch=v9 _XBS5_LP64_OFF64_CFLAGS: -xarch=v9 _XBS5_LP64_OFF64_LDFLAGS: -xarch=v9 _XBS5_LP64_OFF64_LINTFLAGS: -xarch=v9 _XBS5_LPBIG_OFFBIG_CFLAGS: -xarch=v9 _XBS5_LPBIG_OFFBIG_LDFLAGS: -xarch=v9 _XBS5_LPBIG_OFFBIG_LINTFLAGS: -xarch=v9\ngetconf LFS_CFLAGS -D_LARGEFILE_SOURCE -D_FILE_OFFSET_BITS=64 getconf LFS_LDFLAGS # nothing special needed getconf LFS_LIBS # nothing special needed\ngetconf LFS64_CFLAGS -D_LARGEFILE64_SOURCE getconf LFS64_LDFLAG # nothing special needed getconf LFS64_LIBS # nothing special needed\nBuilding an LP64 perl"}]}
+{"image": "doclay/doclay_77010.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "CONTENTS \nPART 1 ABOUT ENISA .................................................................................................................. 4 PART 2 TERMS OF REFERENCE (LOT 1) .................................................................................... 5 I. SCOPE OF THIS TENDER....................................................................................................................... 5 1. BACKGROUND INFORMATION ............................................................................................................ 6 2. PROJECTS PROPOSED FOR 2020....................................................................................................... 6 3. AREAS OF EXPERTISE ......................................................................................................................... 7 4. DESCRIPTION OF TASKS & SERVICES TO BE PROVIDED .............................................................. 7 5. POOL OF EXPERTS AND EXPERT PROFILES.................................................................................... 8 5.1 Junior Expert profile.................................................................................................................................... 8  5.2 Senior Expert profile ................................................................................................................................... 9  6. CONTENT AND PRESENTATION OF THE TECHNICAL OFFER ...................................................... 10 7. CONTENT AND PRESENTATION OF THE FINANCIAL OFFER (LOT 1) .......................................... 10 8. TENDER RESULT AND ESTIMATED CONTRACT VALUES (LOT 1)................................................ 11 9. DATA PROTECTION AND TRANSPARENCY..................................................................................... 11 10. MARKING OF SUBMITTED DOCUMENTS........................................................................................ 12 11. PRICE .................................................................................................................................................. 12 12. PRICE REVISION ................................................................................................................................ 12 13. COSTS INVOLVED IN PREPARING AND SUBMITTING A TENDER .............................................. 12 14. PERIOD OF VALIDITY OF THE TENDER .......................................................................................... 12 15. PROTOCOL ON PRIVILEGES & IMMUNITIES OF THE EUROPEAN UNION ................................. 12 16. PAYMENT ARRANGEMENTS............................................................................................................ 12 17. CONTRACTUAL DETAILS ................................................................................................................. 13 18. PROVISION OF SERVICES - Re-opening of Competition .............................................................. 14 PART 3 TENDER SPECIFICATIONS (LOT 1) ................................................................................ 15 1. INFORMATION ON TENDERING ......................................................................................................... 15 2. STRUCTURE AND CONTENT OF THE TENDER................................................................................ 16 3. ASSESSMENT AND AWARD OF THE CONTRACT ........................................................................... 20 3.1 EXCLUSION CRITERIA ...................................................................................................................... 20  3.2 SELECTION CRITERIA ...................................................................................................................... 21  3.3 AWARD CRITERIA ............................................................................................................................. 23 \npage 2 of 25 \nF-COD-20-T03:  LOT 1  - Development of Material for Exercises, Challenges and Trainings"}]}
+{"image": "doclay/doclay_46171.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "GROUP 06 HARNESS/CONTAINER \n0071 00\nTM 10-1670-287-23&P \nFigure 7. Harness/Container (Sheet 1 of 2) \nChange 1 \n0071 00-1\n4 4 7 8 1 1 4 1 1 5 6 7 8 5 6 7 8 12 15 4 16 5 6 14 13 17 2 3 2 9 10 11 18"}]}
+{"image": "doclay/doclay_12850.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "between the required accounting for sale-leaseback transactions and the required accounting for certain lease modifications that have economic effects that are similar to sale-leaseback transactions. This statement also amends  other existing authoritative pronouncements to make various technical corrections, clarify meanings, or describe their applicability under changed conditions. SFAS No. 145 does not currently impact ADTRAN.\nIn July 2002, the Financial Accounting Standards Board issued SFAS No. 146, Accounting for Costs Associated with  Exit or Disposal Activities, which is effective for disposal or exit activities that are initiated after December 31, 2002. This statement addresses financial accounting and reporting for costs associated with exit or disposal activities and nullifies Emerging Issues Task Force Issue No. 94-3, Liability Recognition for Certain Employee Termination Benefits and Other Costs to Exit an Activity (Including Certain Costs Incurred in a Restructuring) . The statement requires that a liability for  a cost associated with an exit or disposal activity shall be recognized and measured initially at its fair value in the period in which liability is incurred, except for liabilities for one-time termination benefits that are incurred over time. In the unusual circumstance in which fair value cannot be reasonably estimated, the liability shall be recognized initially  in the period in which fair value can be reasonably estimated. The impact of SFAS No. 146 on ADTRAN’s financial  statements is not expected to be material.\nIn December 2002, the Financial Accounting Standards Board issued SFAS No. 148, Accounting for Stock-Based Compensation – Transition and Disclosure – an Amendment of FAS 123 , which is effective for financial statements for  fiscal years ending after December 15, 2002. This Statement amends FASB Statement No. 123, Accounting for Stock- Based Compensation , to provide alternative methods of transition for a voluntary change to the fair value-based method of accounting for stock-based employee compensation. In addition, this Statement amends the disclosure requirements of Statement 123 to require prominent disclosures in both annual and interim financial statements about the method  of accounting for stock-based employee compensation and the effect of the method used on reported results. The  disclosure requirements of SFAS No. 148 have been included in Note 7 to the consolidated financial statements.\nADTRAN classifies its securities as either available-for-sale or held-to-maturity. At December 31, 2002 and 2001, ADTRAN held the following securities, recorded at either fair value or amortized cost, which approximates fair value.\n2 Investments\nDecember 31, 2002 $_{Cost or}$) $_{Gross}$) $_{Gross}$) $_{Amortized Cost}$) $_{Unrealized Gains}$) $_{Unrealized Losses}$) $_{Fair Values}$) Available-for-sale securities Restricted money market funds $50,000,000) $50,000,000) Municipal bonds and fixed income mutual funds 103,849,011) $2,072,966) ($237,488) 105,684,488) Marketable equity securities 22,669,021) 3,831,397) (1,099,930) 25,400,488) Other equity securities 910,674) 910,674) Total available-for-sale securities $177,428,706 ) $5,904,363 ) ($1,337,418) $181,995,651 ) Held-to-maturity securities Municipal bonds and other  government fixed income securities $13,678,847) $13,678,847) Other debt securities 403,695) 403,695) Total held-to-maturity securities $14,082,542 ) $14,082,542 )\n27 Financial Results"}]}
+{"image": "doclay/doclay_12809.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Letter to the Shareholders \n2004 was an outstanding year for Southern Peru Cop- per Corporation (SPCC). In addition to the substantial  rise in the price of metals produced by the Company,  SPCC’s output and sales reached unprecedented levels.  The production of copper, molybdenum, and silver in- creased 6.06%, 17.79%, and 6.0%, respectively, as  compared to 2003. Company products sold (copper,  molybdenum, silver) also increased 115%.\nPrice hikes were outstanding during 2004 as compared  to the previous year. Average price of products was:  copper, $1.30 per pound, that is, 60% higher than in  2003; molybdenum, $16.21 per pound, a 300% in- crease; silver, $6.68 per ounce, as compared to $4.87  in 2003. \nWith respect to 2004 production, mined copper totaled  876 million pounds in 2004. Higher copper output at  SPCC resulted mainly from expanded production at the  Toquepala mine and higher treated volumes after pro- cessing capacity increased at the concentration plant.  The Toquepala concentration plant produced 580,111  tons of concentrate, a new production record. Further- more, Toquepala mine also produced more molybdenum:  output increased from 4,153 tons to 6,004 tons. This \nSOUTHERN PERU COPPER CORPORATION 6.\ngrowth also resulted from higher mined ore grades and  recoveries in 2004.\nto estimates, the pre-feasibility study will continue dur- ing 2005. \nGreater output at Cuajone mine in 2004 also resulted  from higher ore grades in 2004 and improved recovery  in grinding that resulted in 752,941 tons of concentrate,  also an unprecedented production level. SX/EW cop- per output decreased 12.4 million pounds due to lower  grades in the pregnant leaching solutions (PLS). The  smelter also attained a new record by smelting 1,213,030  tons of concentrate.\nNet income was an outstanding item in 2004: it reached  $597 million, or 400% higher than in 2003. Operating  cash cost per pound of copper decreased from $0.399  to $0.046 due mainly to high price of molybdenum, a  by-product of copper mining.\nAt present, SPCC has mining operations in Peru, Mexico  and Chile, with beds to be explored that might increase  the Company’s reserves and future profile. SPCC also  maintained its prospecting program in all of Peru, mainly  in the south, focusing in the finding of copper and gold  resources. With respect to Los Chancas project, the drill- ing program was maintained during 2004 and, according \nSPCC continued its globalization efforts during 2004. The  Board of Directors appointed a special committee to ana- lyze the proposal to acquire Minera Mexico, a subsidiary \nAlso in 2004, as part of the Environmental Compliance  and Management Program agreed with the government  of Peru, SPCC began to upgrade the Ilo smelter. The up- graded smelter will use Australian Isasmelt technology to  process 1.2 million tons of copper annually, with anodes  as the final product instead of the blister bars produced at  present. Sulfur capture will be of the order of 95%, well  over the standards required by environmental regulations  in force. The smelter upgrading is the largest environ- mental project undertaken by our Company in Peru, and  once it is completed, it will mean the conclusion of SPCC’s  environmental commitments in the country.\nSouthern Peru launched major projects in 2004, such as  the one related with the Leaching Dums Project, where  conveyor belts will be replaced with haulage trucks to  transport minerals at the Toquepala mine. Construction  works are scheduled to conclude in June 2005. \nof Americas Mining Corporation (AMC), the holding of  Grupo Mexico engaged in mining operations. After eight  months of comprehensive work, the Special Committee  of Disinterested Directors advised the Board to accept  the offer. The proposal was approved by a majority of  the Board and, once authorized by the relevant regulat- ing authorities, the shareholders will vote on the matter  during the first quarter of 2005.\nSouthern Peru foresees the investment projects it carries  out will further consolidate its position among the main  producers of metals worldwide, therefore signaling a  positive economic return for our shareholders, a contri- bution for the relevant countries and their communities,  and a benefit for SPCC workers. \nOn behalf of Southern Peru’s Board of Directors, we want  to express our gratitude to the workers and employees  for their effort and dedication, to our clients for their  trust and loyalty, and to you, our shareholders, for your  long-term support.\nSOUTHERN PERU COPPER CORPORATION 7.\nOSCAR GONZÁLEZ ROCHA President and Chief Executive Officer\nGERMÁN LARREA MOTA-VELASCO Chairman of the Board"}]}
+{"image": "doclay/doclay_18367.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "IOOF  | Annual Report 2012\n* The opening balance has been adjusted for 37,500 options that were reassessed as vested during the reporting period. The options outstanding at 30 June 2012 have an exercise price in the range of $2.98 to $9.99 and a weighted average contractual life of 2.8 years. The weighted average share price at the date of exercise for share options exercised during the year ended 30 June 2012 was $5.58 (2011: $6.84).\nSeries - Recipient Exercise  price Opening  balance as  at 1 July  2011* Granted Forfeited or  Lapsed Exercised Closing  balance as  at 30 June  2012 Vested Options 2008-8 - Senior Management 3.15 112 , 5 0 0 - - (112 , 5 0 0 ) - - 2009-01 - Senior Management 2.98 53,619  - - - 53,619  53,619  2009-02 - Senior Management 3.73 26,809  - - - 26,809  26,809  2009-04 - Senior Management 5.52 134,0 48  - - (134,0 48) - - 2009-7 - Executives 9.36 147, 452 - - - 147, 452 147, 452 2009-8 - Senior Staff 9.36 191,670  - (6,702) - 184,968  184,968  2009-9 - Managing Director 9.99 134,0 48  - - - 134,0 48  134,0 48  2009-15 - Former CEO 9.89 675,000  - (675,000) - - - 2009-16 - Managing Director 5.20 316,624  - - - 316,624  - 2009-20 - Senior Management 5.68 150,000  - - - 150,000  56,250  2010-02 - Senior Management 7. 4 0 150,000  - - - 150,000  37, 5 0 0 2010-03 - Executives 7. 01 500,000  - - - 500,000  - 2010-04 - Executives 6.14 1,925,000  - - - 1,925,000  - 2010-05 - Managing Director 6.93 300,000  - - - 300,000  - 2012-02 - Managing Director 6.81 - 300,000  - - 300,000  - 2012-05 - DKN Replacement  7. 50 - 409,854  (10,620) - 399,234  - 4,816,770  709,854  (692,322) (246,548) 4,587,754  640,646  Performance rights 2007-5 - Senior Management $nil 3,750  - - (3,750) - - 2008-1 - Senior Management $nil 41,614  - - (41,614) - - 2008-2 - Senior Management $nil 21,717  - - (21,717) - - 2008-6 - Other Key Stakeholders $nil 83,600  - - (83,600) - - 2008-7 - Senior Management $nil 7, 5 0 0 - - (1,250) 6,250  - 2009-14 - Managing Director $nil 150,000  - - - 150,000  - 2009-17 - Senior Management $nil 32,970  - - - 32,970  - 2009-18 - Other Key Stakeholders $nil 116 , 313 - (24,973) - 91,340  91,340  2010-01 - Senior Management $nil 8,750  - - (1,250) 7, 5 0 0 - 2010-06 - Managing Director $nil 150,000  - - - 150,000  - 2012-01 - Managing Director $nil - 150,000  - - 150,000  - 2012-04 - Executives $nil - 371,250  - - 371,250  - 616,214  521,250  (24,973) (153,181) 959,310  91,340  Deferred shares 2010-07 - Managing Director $nil 48,238  - - ( 24 ,119) 24 ,119 - 2012-03 - Managing Director $nil 31,694  - - - 31,694  - 2012-06 - Managing Director $nil - 35,977  - - 35,977  - 79,932  35,977  - ( 24 ,119) 91,790  - 5,512,916  1,267,081  (717,295) (423,848) 5,638,854  731,986 \npage 107\nDisclosure of share-based payment programmes"}]}
+{"image": "doclay/doclay_71511.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Table of Contents\nEL PASO ELECTRIC COMPANY NOTES TO FINANCIAL STATEMENTS\nTexas Energy Efficiency Cost Recovery Factor (\"EECRF\").  On May 1, 2017, the Company filed its annual application with the PUCT, which was assigned PUCT Docket No. 47125, to establish its EECRF for 2018. In addition to projected energy efficiency costs for 2018 and a reconciliation of collections to prior year actual costs, the Company requested approval of an incentive bonus for the 2016 energy efficiency program results in accordance with PUCT rules. Interim rates were approved effective January 1, 2018. The Company, the PUCT Staff and the City of El Paso reached an agreement that includes an incentive bonus of $0.8 million. The agreement was filed on January 25, 2018, and was approved by the PUCT on February 15, 2018.\nOn May 1, 2018, the Company filed its annual application with the PUCT, which was assigned PUCT Docket No. 48332, to establish its EECRF for 2019. In addition to projected energy efficiency costs for 2019 and a reconciliation of collections to actual costs for the prior year, the Company requested approval of a $1.0 million incentive bonus for the 2017 energy efficiency program results in accordance with PUCT rules. Instead of convening a live hearing on the merits of this case, the parties agreed to enter into the record the pre-filed testimony of the parties and certain other exhibits and then file briefs on the contested issues. The ALJ issued a proposal for final decision on November 15, 2018, including the Company's fully requested incentive bonus. On January 17, 2019, the PUCT issued a final order approving a modified bonus amount of $0.9 million.\nOn May 1, 2019, the Company filed its annual application with the PUCT, which was assigned PUCT Docket No. 49496, to establish its EECRF for 2020. In addition to projected energy efficiency costs for 2020 and a reconciliation of collections to actual costs for the prior year, the Company requested approval of a $0.8 million incentive bonus for the 2018 energy efficiency program results in accordance with PUCT rules. On July 1, 2019, the Company requested, and received approval for, a suspension of the procedural schedule in order to pursue settlement of the case. On July 12, 2019, the Company informed the ALJ in the case that all parties had agreed in principle on terms for settlement. On August 14, 2019, the Company filed an unopposed settlement agreement and proposed order which resolved all issues in the proceeding, including the requested incentive bonus. The case was remanded on August 16, 2019, to the PUCT for a final order approving the settlement agreement and the Company's EECRF rates. On November 14, 2019, the PUCT issued an order approving the filed settlement.\nFuel and Purchased Power Costs.  The Company's actual fuel costs, including purchased power energy costs, net of the cost of off-system sales and related shared margins, are recovered from customers through a fixed fuel factor. The PUCT has adopted a fuel cost recovery rule (\"Texas Fuel Rule\") that allows the Company to seek periodic adjustments to its fixed fuel factor. The Company can seek to revise its fixed fuel factor based upon the approved formula at least four months after its last revision except in the month of December. The Texas Fuel Rule requires the Company to request to refund fuel costs in any month when the over-recovery balance exceeds a threshold material amount and it expects fuel costs to continue to be materially over-recovered. The Texas Fuel Rule also permits the Company to seek to surcharge fuel under-recoveries in any month the balance exceeds a threshold material amount and it expects fuel cost recovery to continue to be materially under-recovered. Fuel over- and under- recoveries are considered material when they exceed 4% of the previous twelve months' fuel costs. All such fuel revenue and expense activities are subject to periodic final review by the PUCT in periodic fuel reconciliation proceedings.\nOn October 13, 2017, the Company filed a request with the PUCT, which was assigned PUCT Docket No. 47692, to decrease the Texas fixed fuel factor by approximately 19% to reflect decreased fuel expenses primarily related to a decrease in the price of natural gas used to generate power. The decrease in the Texas fixed fuel factor became effective beginning with the November 2017 billing month.\nOn April 13, 2018, the Company filed a request with the PUCT, which was assigned PUCT Docket No. 48264, to decrease the Texas fixed fuel factor by approximately 29% to reflect decreased fuel expenses primarily related to a decrease in the price of natural gas used to generate power. On April 25, 2018, the Company's proposed fuel factors were approved on an interim basis effective for the first billing cycle of the May 2018 billing month. The revised factor was approved by the PUCT and the docket closed on May 22, 2018.\nOn October 15, 2018, the Company filed a request with the PUCT, which was assigned PUCT Docket No. 48781, to decrease the Texas fixed fuel factor by approximately 6.99% to reflect decreased fuel expenses primarily related to a decrease in the price of natural gas used to generate power. On October 25, 2018, the Company's fixed fuel factor was approved on an interim basis effective for the first billing cycle of the November 2018 billing month. The revised factor was approved by the PUCT and the docket closed on November 19, 2018.\nOn April 29, 2019, the Company filed a petition with the PUCT, which was assigned PUCT Docket No. 49482, requesting authority to implement, beginning on June 1, 2019, a four-month, interim fuel refund of $19.4 million in fuel cost over-recoveries, including interest, for the period from April 2016 through March 2019. On May 30, 2019, the Company's fuel refund credit was approved on an interim basis. The Company implemented the fuel refund in customer bills beginning June 1, 2019. On September\n65"}]}
+{"image": "doclay/doclay_3642.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "iSeries Advanced Series\nS544-5349-02\nAdvanced Function Printing Utilities for iSeries: User’s Guide\nIBM"}]}
+{"image": "doclay/doclay_10627.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Bank distribution partnerships also represent an opportunity to extend our reach and the partnership with Caja de Ahorros del Mediterráneo, one of the largest savings banks in Spain,  is an important development. We will continue to develop distribution partnerships in those markets where it makes strategic sense to do so.\nI am also pleased to report increased authority of AEGON’s common shareholders as a result of the modernization of AEGON’s corporate governance. In addition, the recent introduction of the Dutch Corporate Governance Code is an important step forward in improving the accountability of companies registered in the Netherlands. AEGON is committed to the highest standards of transparency and we welcome the adoption of the principles of the code.\nAlthough the continued low interest rate environment and weak US dollar are not helpful,  it will not change the direction of our business. Rising bond yields, combined with lower bond defaults and the upward momentum of equity markets, as well as growth in the United States economy, are significant factors that are beginning to have a positive impact on our business. AEGON has a leading position in an industry that is demonstrating real evidence of recovery after an unprecedented period of challenges in the financial markets. With focused execution  of our growth strategy, we look to 2004 as a year in which AEGON will create value for all stakeholders.\nThank you for your support and interest in AEGON. I hope our 2003 annual report proves to be a valuable resource for you.\nYours sincerely,\nAEGON GROUP ANNUAL REPORT 2003 7\nDonald J. Shepard Chairman of the Executive Board\nDonald J. Shepard CAD,"}]}
+{"image": "doclay/doclay_39632.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "4_Vol3_d4.3_Section 4 General Requirements_en_GIR_rev6 \n40 of 40\nConstruction of Giresun Wastewater Treatment Plant  Tender Dossier Volume 3 Employer’s Requirements  Section 04: General Requirements for the Execution and Completion of the Works \ntest values with the required maximum or minimum values shall be summarised in a table extended  according to EN 12255-15. \nFailure to pass the verification of mechanical equipment performance \n1. For exceeding the required maximum pressure loss over the diffuser grids:\n2. Too low SSOTE:\nIf the test results reveal that the pressure loss over the complete diffuser-arrangement or individual  sections (incl. potential build-in check valve) exceeds the required maximum values at maximum  duty conditions, the Contractor shall preferably redesign the diffuser system, replace the diffusers,  or increase the number of diffusers or on any other way remedy the defect.\nIf the test results reveal that the required minimum SSOTE over the complete diffuser-arrangement  or individual sections is less than the required values, the Contractor shall preferably redesign the  diffuser system, replace the diffusers, or increase the number of diffusers or on any other way  remedy the defect. "}]}
+{"image": "doclay/doclay_30892.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "Yukawa-type interaction obtained in Ref. [53] from the Casimir-less experiment (the short- dashed line) and the constraints obtained in Ref. [24] from the torsion pendulum experiment of Ref. [23] (the long-dashed line). The latter constraints will be discussed in more detail in the next section. As can be seen in Fig. 4, the constraints following from the measurement of the gradient of the Casimir pressure between two parallel plates are not as strong as the constraints obtained from previously performed experiments.\nThe experimental configuration of two parallel plates has some potentialities to obtain stronger constraints on the parameters of the Yukawa-type interaction. One evident resource is connected with the increase of precision [i.e.,with the decrease of Δ$_{i}$( ν $^{2}$− ν 2 $_{0}$)]. Furthermore, the replacement of Cr, as the material of metal coating, with an Au layer of the same thickness would lead to stronger constraints shown in Fig. 4 by the grey line marked 1. Moreover, the increase of thicknesses of the metal coating up to Δ$_{Au}$ = 500 nm would lead to even stronger constraints shown in Fig. 4 by the grey line marked 2. This line presents constraints of the same strength as those obtained in Ref. [53] from the Casimir- less experiment. Thus, the configuration of two parallel plates can be further used for obtaining constraints on the Yukawa-type interaction. As to the possibility of replacing a plane plate with a corrugated one, this does not lead to significantly stronger constraints in the experiment with parallel plates because of much larger separation distances between the test bodies.\nMeasurements of the Casimir-Polder force between an atom and a plate (cavity wall) and the measure of their agreement with theory provides additional opportunities for constraining the Yukawa-type corrections to Newtonian gravity. Up to now no strongest constraints have been obtained in this way, but to a large extent the potentialities of this field remain unexplored. Here, we obtain constraints on the parameters of the Yukawa-type interaction using the measurement data of dynamic experiment demonstrating the thermal Casimir- Polder force between $^{87}$Rb atoms and a SiO$_{2}$ plate [39]. Rubidium atoms belonged to a Bose-Einstein condensate which was produced in a magnetic trap with frequencies equal to ω$_{0}$$_{z}$ = 1438 . 85 rad/s and ω$_{0}$$_{l}$ = 40 . 21 rad/s in the perpendicular and longitudinal directions to\n15\nVI. CONSTRAINTS FROM THE MEASUREMENT OF THERMAL CASIMIR-POLDER FORCE"}]}
+{"image": "doclay/doclay_56309.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "CROCHETING PROJECT\n4-H EXPERIENTAL LEARNING MODEL\nYou will learn to: • Tie a slip knot\nPotential Projects or Exhibits: • Pot holder\n2\nReflect  - How do you feel about your project? What part of the experiences was the most challenging or easiest?\nReflect  - How do you feel about your project? What part of the experiences was the most challenging or easiest?\nApply  - Using the skills listed above you will practice and complete a project.\nDo  - What did you do?\nThe purpose of the 4-H program is to help youth learn technical skills and life  skills that will improve their lives. Technical skills relate to the subject matter,  while life skills are those abilities used in every facet of our lives. Life skills  developed through these 4-H activity guide projects include: planning and  organizing, decision making, learning to learn, wise use of resources.You will learn to: • Tie a slip knot • Chain \n• Tie a slip knot • Chain  • Single crochet\n• Chain  • Single crochet • Double crochet\n• Single crochet • Double crochet • Half double crochet\n• Double crochet • Half double crochet • Treble crochet\n• Half double crochet • Treble crochet • Increase and decrease stitches\n• Treble crochet • Increase and decrease stitches • Recognize stitches and know the difference\n• Increase and decrease stitches • Recognize stitches and know the difference between stitch and space • Slip a stitch\nbetween stitch and space • Slip a stitch • Attach yarn and change colors\n• Slip a stitch • Attach yarn and change colors • Fasten off\n• Attach yarn and change colors • Fasten off • Count stitches and rows\n• Fasten off • Count stitches and rows • Join seams\n• Count stitches and rows • Join seams • Learn abbreviations used in pattern directions\n• Join seams • Learn abbreviations used in pattern directions • Read and follow pattern directions\n• Learn abbreviations used in pattern directions • Read and follow pattern directions\nPotential Projects or Exhibits: • Pot holder • Slippers\n• Pot holder • Slippers • Dishcloth\n• Slippers • Dishcloth • Purse, baby bassinette purse\n• Dishcloth • Purse, baby bassinette purse • Hat, scarf, or mittens\n• Purse, baby bassinette purse • Hat, scarf, or mittens • Small afghan for a baby or a lap blanket\n• Hat, scarf, or mittens • Small afghan for a baby or a lap blanket • Crocheted edge patterns\n• Small afghan for a baby or a lap blanket • Crocheted edge patterns • Any other crochet items from patterns found in books, Internet, etc.\n• Crocheted edge patterns • Any other crochet items from patterns found in books, Internet, etc."}]}
+{"image": "doclay/doclay_41590.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "B\nAlcohol...........................................................................8-2 Alternate pressure application......................................7-32 Alternating current (AC) introduction ...........................9-9 Definitions ..................................................................9-9 Cycle .....................................................................9-10 Effective..................................................................9-9 Frequency .............................................................9-10 Instantaneous ..........................................................9-9 Peak.........................................................................9-9 Period ....................................................................9-11 Phase relationships................................................9-11 Values of AC ..........................................................9-9 Wavelength ...........................................................9-11 Alternator drive............................................................9-42 Alternator voltage regulators .......................................9-40 Altimeter and static system inspections.......................2-62 Aluminum alloys..........................................................4-30 Aluminum soldering ....................................................5-21 Aluminum welding ......................................................5-18 Amorphous thermoplastics ............................................7-8 Amphibious aircraft .....................................................1-36 Angle adapters .............................................................4-16 Angle of attack...............................................................2-6 Angle of incidence .........................................................2-5 Annual and 100-hour inspections ...................... 2-60, 2-63 Anti-chafe tape...............................................................3-5 Antiservo tabs ..............................................................1-34 Antitorque pedals .........................................................2-30 Antitorque system ........................................................1-45 Application of cement..................................................7-56 Applying the finish ......................................................8-11 Applying the glue/adhesive..........................................6-11 Approval of repair........................................................4-94 Aramid (kevlar®) fiber-reinforced plastics .................7-52 Arc welding procedures ...............................................5-25 Argon .............................................................................5-7 Assessment of damage.................................................4-92 Atmosphere ....................................................................2-2 Atmospheric pressure.....................................................2-2 Audible sonic testing (coin tapping) ............................7-16 Autoclave .....................................................................7-23 Autogyro ......................................................................2-17 Automated tap test .......................................................7-16 Automatic center punch .................................................4-6 Autorotation .................................................................2-27 Auxiliary control surfaces............................................1-28 Auxiliary lift devices....................................................2-12 Axes of an aircraft..........................................................2-9\nBalance panels .............................................................1-33 Balsa wood...................................................................7-13 Band saw......................................................................4-11 Bar folding machine.....................................................4-21 Base measurement .......................................................4-59 Bead weld.....................................................................5-28 Bearing...........................................................................4-3 Bell stabilizer bar system .............................................2-30 Belt drive clutch...........................................................2-36 Bend allowance (BA)...................................................4-59 Bending .........................................................................,1-7 Bending a U-channel....................................................4-61 Bend radius ..................................................................4-59 Bend tangent line (BL).................................................4-59 Benzene..........................................................................8-2 Bernoulli’s Principle ......................................................2-4 Bias ................................................................................3-3 Bidirectional (fabric)......................................................7-3 Biplane assembly and rigging......................................2-55 Bismaleimides (BMI).....................................................7-8 Blanket method ............................................................3-12 Bleeder ply ...................................................................7-21 Bleedout technique.......................................................7-29 Bleriot, Louis .................................................................1-3 Blind bolts.......................................................... 4-53, 7-48 Blind fasteners .............................................................7-47 Nnonstructural ..........................................................4-56 Blind rivets...................................................................4-47 Blushing .......................................................................8-13 Bolt and bushing holes.................................................6-19 Bolted repairs ...............................................................7-44 Bonded flush patch repairs...........................................7-37 Boron..............................................................................7-6 Boundary layer...............................................................2-7 Box and pan brake (finger brake) ................................4-22 Box beam ........................................................... 1-12, 1-13 Brazing and soldering ..................................................5-19 Breather material..........................................................7-21 Brinelling .....................................................................4-90 Brushing.........................................................................8-5 Bucking bar..................................................................4-36 Bumping.......................................................................4-58 Burnishing....................................................................4-90 Burr ..............................................................................4-90 Burring tool..................................................................4-14 Butt joints.....................................................................5-30 Buttock line..................................................................1-39\n I-2"}]}
+{"image": "doclay/doclay_42400.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Insight \nAcquiring Knowledge \nMemorization \nUnderstanding \nUnderstanding develops when learners begin to organize known facts and steps into coherent groups that come together to form an  understanding of how a thing or a process works. For example, after learning to adjust the mixture control in cruise flight, Beverly  learns that combustion requires a certain mixture of fuel and air, and that air becomes less dense as altitude increases. \nA more experienced pilot can answer the altimeter question because she or he understands the ramifications of the question.  Understanding, or the ability to notice similarities and make associations between the facts and procedural steps learned, is an  important next stage in the knowledge acquisition process. At this stage, the learner begins to organize knowledge in useful ways and  a collection of memorized facts gives way to understanding. \nThe limitations of memorization become apparent when a learner is asked to solve a problem or provide an explanation of something  that is not covered by the newly acquired knowledge. For example, when asked whether she would rather have the altimeter  mistakenly set too high or too low when flying in mountainous terrain, Beverly may not have an answer. \nMemorizing facts and steps has an advantage: it allows learners to get started quickly. For example, as soon as Beverly memorizes the  purpose of the knob on the altimeter and the procedure for obtaining the current barometric pressure, she is able to properly configure  the instrument for flight. \nA learner’s first attempt to acquire knowledge about a new topic amounts to memorizing facts about steps in a procedure. For$_{ }$ example, when Beverly is learning to use an altimeter, she may have memorized that the knob on the instrument is used to dial the  current barometric pressure and that this number should be obtained from the recorded broadcast and set prior to flight. \nFigure 3-6  shows the three phases of knowledge, a progression of how learners acquire knowledge. Some practical considerations  about learning new knowledge and instructor actions that help learners acquire knowledge are summarized. \nPart of an aviation instructor’s job is helping learners acquire knowledge. In this context, knowledge refers to information that  humans are consciously aware of and can articulate. For example, knowledge of the fuel capacity of a particular aircraft,  understanding how an internal combustion engine works, and the ability to determine the weight and balance of an aircraft are  examples of knowledge. \nAs perceptions increase in number, the learner develops insight by assembling them into larger blocks. As a result, learning becomes  more meaningful and more permanent. Forgetting is less of a problem when there are more anchor points for tying insights together.  It is a major responsibility of the instructor to organize demonstrations and explanations, and to direct practice so that the learner has  better opportunities to understand the interrelationship of the many kinds of experiences that have been perceived. Pointing out the  relationships as they occur, providing a secure and nonthreatening environment in which to learn, and helping the learner acquire and  maintain a favorable self-concept are key steps in fostering the development of insight. \nInsight almost always occurs eventually, whether or not instruction is provided. For this reason, it is possible for a person to become  an electrician by trial and error, just as one may become a lawyer by reading law. Instruction, however, speeds this learning process  by teaching the relationship of perceptions as they occur, thus promoting the development of the learner’s insight. \nTrue learning requires an understanding of how each factor may affect all of the others and, at the same time, knowledge of how a  change in any one of them may affect all of the others. This mental relating and grouping of associated perceptions is called insight. \nFor example, during straight-and-level flight in an aircraft with a fixed-pitch propeller, the revolutions per minute (rpm) increase  when the throttle is opened and decrease when it is closed. On the other hand, rpm changes can also result from changes in aircraft  pitch attitude without changes in power setting. Obviously, engine speed, power setting, airspeed, and aircraft attitude are all related. \nInsight involves the grouping of perceptions into meaningful wholes. Creating insight is one of the instructor’s major responsibilities.  To ensure that this occurs, it is essential to keep each learner constantly receptive to new experiences and to help them understand  how each piece relates to all other pieces of the total pattern of the task. \n3-9 "}]}
+{"image": "doclay/doclay_15453.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "See accompanying “Notes to Consolidated Financial Statements.” \nCentury Bancorp, Inc. AR ’12 Year Ended December 31,  2012  2011 2010 (dollars in thousands) CASH FLOWS FROM OPERATING ACTIVITIES: Net income $ 19,039 $ 16,693  $ 13,574 Adjustments to reconcile net income to net cash provided by operating activities: Mortgage loans originated for sale (20,149) (22,664) — Proceeds from mortgage loans sold 14,457 19,697 — Gain on sales of mortgage loans held for sale (297) (422) — Gain on sale of loans — (238) — Gain on sale of fixed assets (1) — (7) Net gains on sales of securities (1,843) (1,940) (1,851) Provision for loan losses 4,150 4,550 5,575 Deferred tax benefit (2,104) (953) (1,546) Net depreciation and amortization 6,445 5,558 4,955 Decrease (increase) in accrued interest receivable 211 579 (795) Decrease in prepaid FDIC assessments 1,562 1,794 2,629 (Gain) loss on sales of other real estate owned (1) 8 (127) Write down of other real estate owned — 117 — Increase in other assets (3,113) (4,456) (1,417) Increase (decrease) in other liabilities 1,070 503 (849) Net cash provided by operating activities 19,426 18,826 20,141 CASH FLOWS FROM INVESTING ACTIVITIES: Proceeds from maturities of short-term investments 38,397 121,106   131,762 Purchase of short-term investments (37,413) (25,539)   (227,162) Proceeds from redemption of Federal Home Loan Bank of Boston stock 385 — — Proceeds from calls/maturities of securities available-for-sale 532,734 722,403   610,975 Proceeds from sales of securities available-for-sale 294,881 75,615 41,251 Purchase of securities available-for-sale (998,955)  (1,140,194)  (914,944) Proceeds from calls/maturities of securities held-to-maturity 88,628 119,315   154,445 Purchase of securities held-to-maturity (185,346) (68,863)   (167,442) Proceeds from sales of loans — 4,000 — Net increase in loans (123,183) (82,793) (33,315) Proceeds from sales of other real estate owned 1,584 802 555 Proceeds from sales of fixed assets 1 — 13 Capital expenditures (4,300) (2,692) (2,281) Net cash used in investing activities (392,587) (276,840)   (406,143) CASH FLOWS FROM FINANCING ACTIVITIES: Net (decrease) increase in time deposit accounts (13,518) 16,241   124,622 Net increase in demand, savings, money market and NOW deposits 334,007 206,320 75,414 Net proceeds from the exercise of stock options 304 52 150 Cash dividends (2,186) (2,180) (2,173) Net increase (decrease) in securities sold under agreements to repurchase 48,070 34,770 (10,195) Net (decrease) increase in other borrowed funds (48,999) 22,025 (11,906) Net cash provided by financing activities 317,678 277,228   175,912 Net (decrease) increase in cash and cash equivalents (55,483) 19,214   (210,090) Cash and cash equivalents at beginning of year 207,766 188,552   398,642 Cash and cash equivalents at end of year  $ 152,283 $ 207,766  $ 188,552 SUPPLEMENTAL DISCLOSURES OF CASH FLOW INFORMATION: Cash paid during the year for: Interest $ 19,597 $ 22,799  $ 24,930 Income taxes 3,348 3,109 3,580 Change in unrealized gains on securities available-for-sale, net of taxes  $ 4,011 $ 4,726 $ (536) Pension liability adjustment, net of taxes  (1,839) (3,667) 1,259 Transfer of loans to other real estate owned 400 2,110 428\nCentury Bancorp, Inc. AR ’12 Consolidated Statements of Cash Flows\n22"}]}
+{"image": "doclay/doclay_11919.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "As the Corporation continues to grow, an appropriate capital structure will be maintained in order to access capital markets at the lowest possible cost. The capital structure of Fortis is presented in the following table.\nIn September 2001, Fortis Properties acquired a portfolio of properties including TD Place, in downtown St. John’s, Newfoundland and Labrador, for $8.3 million. During 2001, Fortis Properties sold the Centennial Building in Halifax,\nNova Scotia for proceeds of $11.5 million and realized an after-tax gain of $2.6 million. The Corporation received $5.5 million in proceeds and realized an after-tax gain of $0.5 million on the sale of the assets and liabilities of Fortis Trust.\nCapital expenditures excluding acquisitions,  by operating segment, are presented in the following table.\nThe Corporation paid $28.0 million in Common Share dividends in 2001, or $1.87 per Common Share, compared to $25.7 million, or $1.84 per Common Share, in 2000. Fortis has increased its dividends per Common Share every year since its inception in 1987. The dividend payout ratio declined to 52.1 per cent in 2001 from 67.6 per cent in 2000.\nThe Corporation received $7.1 million in 2001 for Common Shares issued through its Dividend Reinvestment Plan, Consumer Share Purchase Plan, Employee Share Purchase Plan, Executive Stock Option Plan and Director Stock Option Plan compared to $4.9 million in the prior year.  The $2.2 million increase over 2000 results predominantly from exercise of stock options in 2001.\nNewfoundland Power’s capital expenditures focused on improving the reliability of the electricity system throughout the province of Newfoundland and Labrador. Maritime Electric’s capital expenditures focused on initiatives to strengthen its energy delivery system to meet increased load. Belize Electricity’s capital expenditures predominately pertain to the Power III Project, which is designed to extend electrical services to 13,000 new customers by 2003. Fortis Properties’ capital expenditures were mainly associated with construction of the $15 million Four Points by Sheraton Halifax hotel in Halifax, Nova Scotia.\nThe primary business risks for Fortis are related to regulation, energy prices, weather, foreign exchange,\nIn January 2001, Fortis acquired a 95 per cent interest in BECOL for an aggregate purchase price of $103.1 million. In September 2001, the Corporation, through Newfoundland Power and another subsidiary, closed a transaction to purchase poles and related infrastructure from Aliant Telecom for an aggregate purchase price of $46 million. \nInvesting Activities: Cash used in investing activities totalled $239.7 million in 2001 compared to $240.7 million in 2000. Fortis invested $103.0 million in acquiring new business interests and $149.5 million in capital expenditures during 2001.\nBusiness Risk Management\nCapital Structure 2001 2000 ($ millions) % ($ millions) % Total Debt, Net of Cash  882.3 63.9 706.2 60.4 Preferred Shares 50.0 3.6 50.0 4.3 Common Shareholders' Equity 448.9 32.5 412.1 35.3 Total 1,381.2 100.0 1,168.3 100.0\nexcluding acquisitions ($ millions) 2001 2000 Newfoundland Power 48.1 43.7 Maritime Electric 14.6 12.6 Belize Electricity 27.6 21.0 Canadian Niagara Power 3.5 3.4 Fortis Properties 16.8 16.9 Other 4.7 0.5 Total 115.3 98.1\nCapital Expenditures, excluding acquisitions\nFORTIS Inc. 2OO1 Annual Report\n38\nTSE:FTS"}]}
+{"image": "doclay/doclay_76091.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "Theorem 4.1 also implies the presence of an unpredictable point and a trajectory in the dynamics of (4.1).\nNext, as an example of a semi-flow, consider the following space of infinite sequences [12],\nwith the metric\nwhere s = ( s 0 s 1 s 2 . . . ) , s = ( s 0 s 1 s 2 . . . ) ∈ Σ 2 . The shift map σ : Σ 2 → Σ 2 is defined as σ ( s 0 s 1 s 2 . . . ) = ( s 1 s 2 s 3 . . . ) . As in the case of the space of bi-infinite sequences, the metric space Σ 2 is compact and the map σ is continuous [12, 13].\nLet us take into account the sequence\nwhich is constructed by successively listing all blocks of 0 ’s and 1 ’s of length n, then length n + 1 , etc.\nThis sequence is non-periodic and its trajectory T ( s $^{∗}$) = { σ $^{n}$( s $^{∗}$) : n = 0 , 1 , 2 , . . . } is dense in Σ 2 [12]. Note that the number of all blocks of length n in s ∗ is 2 $^{n}$. Based upon the construction of s $^{∗}$, there exists a sequence { t$_{n}$ } satisfying t$_{n}$ ≥ ∑ n j =1 j 2 $^{j}$, n ∈ N , such that s ∗ i = σ t n ( s $^{∗}$)$_{i}$ for each i = 0 , 1 , 2 , . . . , n.\nClearly, t$_{n}$ → ∞ as n → ∞ and d [ σ t n ( s $^{∗}$) , s $^{∗}$] ≤ 1 / 2 n so that σ t n ( s $^{∗}$) → s ∗ as n → ∞ . Hence, s ∗ is stable P $^{+}$. In a very similar way to the bi-infinite sequences, one can show the existence of a sequence { τ$_{n}$ } , τ$_{n}$ → ∞ as n → ∞ , such that d [ σ t $_{n}$+ τ n ( s $^{∗}$) , σ τ n ( s $^{∗}$)] ≥ 1 for each n ∈ N . Thus, s ∗ is an unpredictable point in Σ 2 .\nIt was shown in [16] that the logistic map x$_{n}$ +1 = µx$_{n}$ (1 − x$_{n}$ ) possesses an invariant Cantor set Λ ⊂ [0 , 1] , and the map on Λ is topologically conjugate to σ on Σ 2 for µ > 4 . Therefore, the map with µ > 4 possesses an unpredictable point and a trajectory in accordance with Theorem 4.1.\nEmphasizing the ingredients of Devaney [12] and Li-Yorke [4] chaos, one can see that the definitions of chaos have been considered by means of sets of motions, but not through a single motion description. This is the first time in the literature that we initiate chaos by a single function. Thus, the line, equilibrium, periodic function, quasi-periodic function, almost periodic function, recurrent function, Poisson stable motion is prolonged with the new element - unpredictable motion. This supplement to the line creates the possibility of other functions behind the known ones.\n5 Conclusions\n7\ns ∗ = ( 0 1 ︸︷︷︸ 1 $_{blocks}$| 00 01 10 11 ︸ ︷︷ ︸ 2 blocks | 000 001 010 011 . . . ︸ ︷︷ ︸ 3 blocks | . . . ) ,\nΣ 2 = { s = ( s 0 s 1 s 2 . . . ) : s$_{j}$ = 0 or 1 for each j }\nd [ s, s ] = ∞ ∑ k =0 | s$_{k}$ − s$_{k}$ | 2 k ,"}]}
+{"image": "doclay/doclay_13625.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "The following table presents the impact to net income and EPS of goodwill amortization for the year ended December 31, 2001:\nAt December 31, 2002 and 2001, the company’s total short-term debt outstanding was $21.1 billion and $31.6 billion, respec- tively, with weighted average interest rates of 1.7% and 3.0%, respectively. At December 31, 2002 and 2001, $8.7 billion and $17.1 billion, respectively, of short-term debt outstanding was hedged by interest rate swaps. The year-end weighted average effective interest rates were 2.4% and 4.6% for 2002 and 2001, respectively. The company generally paid fixed rates of interest under the terms of interest rate swaps. Unused lines of credit to support commercial paper borrowings were approximately $10.0 billion and $10.4 billion at December 31, 2002 and 2001, respectively.\n(a) For floating rate debt issuances, the stated and effective interest rates were based on the respective rates at December 31, 2002 and 2001; these rates are not an indication of future interest rates.\n(b) Weighted average rates were determined where appropriate.\nI 68 AXP I NOTES TO CONSOLIDATED FINANCIAL STATEMENTS\nDecember 31, (Dollars in millions) 2002 2001 Year-End Year-End Year-End Effective Year-End Effective Notional Stated Interest Notional Stated Interest Outstanding Amount of Rate on Rate with Maturity of Outstanding Amount of Rate on Rate with Maturity of Balance Swaps Debt (a,b) Swaps (a,b) Swaps Balance Swaps Debt (a,b) Swaps (a,b) Swaps Notes due November 20, 2007 $ 744 — 3.75% — — — — — — — Notes due September 12, 2006 1,003 — 5.50% — — $ 1,000 — 5.50% — — Notes due November 1, 2005 498 — 6.88% — — 497 — 6.88% — — Notes due December 16, 2004 500 $ 500 6.50% 5.92% various — — — — — Notes due June 23, 2004 500 — 6.75% — — 500 — 6.75% — — Notes due December 17, 2003 1,306 1,306 6.50% 5.92% various — — — — — Notes due April 8, 2003 510 510 6.50% 5.92% various — — — — — Notes due May 15, 2003 1,000 — 5.90% — — 1,000 — 5.90% — — Notes due February 14, 2003 600 600 6.50% 5.92% various — — — — — Floating Rate Notes due June 15, 2006 1,000 — 1.43% — — — — — — — Floating Rate Notes due January 15, 2005 750 — 1.45% — — — — — — — Floating Rate Notes due October 15, 2004 750 — 1.47% — — 750 — 1.88% — — Floating Rate Notes due  September 15, 2003 950 — 1.53% — — 950 — 1.88% — — Other Fixed Senior Notes due 2002– 2002 – 2005 4,547 3,734 6.52% 5.90% various 1,465 $ 544 6.73% 6.67%  2012 Other Floating Senior Notes due 2002 – 2005 601 250 1.72% 1.60% 2005 515 400 1.88% 1.88% 2002 Other Fixed Rate Notes due 2002 – 2007 142 — 6.73% — — 149 — 6.53% — — Other Floating Rate Notes due 2003– 2002 – 2008 551 232 4.10% 2.98% various 748 181 3.28% 3.17% 2004 Subordinated Fixed Rate Notes due 2003 – 2004 153 — 6.90% — — 153 — 6.90% — — Subordinated Floating Rate Notes due 2004 – 2006 203 — 1.71% — — 61 — 1.88% — — Total $ 16,308 $ 7,132 4.93% $ 7,788 $ 1,125 4.73%\n(Millions, except per share amounts) Net Income Basic EPS Diluted EPS Reported $ 1,311 $ 0.99 $ 0.98 Add back: Goodwill amortization (after-tax) $ 82 $ 0.06 $ 0.06 Adjusted $ 1,393 $ 1.05 $ 1.04\nShort-Term Debt\nLong-Term Debt\nNote 6 SHORT- AND LONG-TERM DEBT AND BORROWING AGREEMENTS"}]}
+{"image": "doclay/doclay_25844.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "as the base increases. This is a finite size effect, because for large scales most values are not represented in short strings, so their probability is considered as zero. In very long strings, however, this effect is less noticeable, so long random strings have a high entropy for different scales ( I$_{b}$ ≈ 1), as shown in Table 2.\nTable 1: Example of a 32-bit string. Grouping b bits, it can be scaled to different bases.\nb base string I$_{b}$ 1 2 0 0 0 0 1 0 0 0 1 0 1 0 0 0 0 1 1 1 0 0 1 0 0 0 1 1 0 0 1 0 0 0 0.89603821 2 4 0 0 2 0 2 2 0 1 3 0 2 0 3 0 2 0 0.8246987 4 16 0 8 10 1 12 8 12 8 0.5389098 8 256 8 161 200 200 0.1875\nTable 2: Example of I$_{b}$ for a long pseudorandom string at different scales.\nb base length I$_{b}$ 1 2 2 20 0.9999998 2 4 2 19 0.9999997 4 16 2 18 0.9999956 8 256 2 17 0.9998395\nE , S , C , and H for different scales can be obtained converting binary strings to higher bases and normalizing their information with Eq. 10. The behavior is similar for all except H , since the Hamming distance measures the percentage of different symbols between strings. For binary strings ( b = 1), uncorrelated strings have a Hamming distance d ≈ 0 . 5, since the probability of having the same symbol in each position is 0.5. For base 4 strings ( b = 2), this will be halved to d ≈ 0 . 25, because the probability of having the same symbol is each position is also halved to 0.25. Thus, the lowest expected H (uncorrelated states) will decrease with increasing b in the form of 1 2 $_{b}$.\nSince I can change drastically depending on the scale at which it is observed (e.g. a string 10101010 has I$_{1}$ = 1 but I$_{2}$ = 0, since the string in base 4 becomes 2222), all the proposed measures can also have drastic changes with a change of scale.\n12"}]}
+{"image": "doclay/doclay_53373.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "UCI CYCLING REGULATIONS \nFor all para-cycling TR competitions, the maximum shall be two teams for any given  structure (national team, trade team...). A third team may be registered for each structure  only if it is an all women’s team. Looking at the following table, the total of points for the  three TR participants must be a maximum of nine (9) points including an athlete with a  maximum scoring value of two (2) points. At the  World Championships : The titles belong  to athletes that compose the team. \nSport Class and Gender  Points  H5 men  4  H4 men  4  H3 men  3  H2 men  2  H1 men  1  H5 women  3  H4 women  3  H3 women  2  H2 women  1  H1 women  1 \n(text modified on 01.02.11; 01.10.12; 01.02.14; 11.02.20) \n16.7.013  The Team manager must give the names and sport classes that make up their team as  well as the order in which the athletes will be placed in the relay. The order needs to be  provided to the president of the commissaires panel at the latest 1 hour after the end of  the last event involving H division athletes. This start order may not be altered  subsequently. \nIf the team relay is the first race involving athletes from Division H, The order needs to  be provided to the president of the commissaires panel at the latest 1 hour after the team  managers meeting. \n(text modified on 01.01.11; 01.10.11; 01.01.16) \n16.7.014  The first wave of athletes will start all together and compete like in a regular road race.  As soon as an athlete from a team completes his lap and passes in front of his  teammates, the next athlete will start his lap. \nIt is the responsibility of the team managers to give the start to their riders when the relay  is passed to another athlete. A commissaire will supervise the relay zone and in case of  a false start, a penalty of 10 seconds will be added directly to the results and the team  manager will be informed by the Commissaire during the race. \nA false start consists of an athlete who takes the relay of his teammate before he crosses  the relay line. Helping a rider to start by pushing or pulling his handcycle will also be  considered as a false start. A false start done more than 3 seconds before the teammate  crosses the relay line will automatically result in the disqualification of the team. \nE0121 \nPARA-CYCLING \n53 "}]}
+{"image": "doclay/doclay_53809.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "mysqldump Tips\n7.4.5 mysqldump Tips\n7.4.5.1 Making a Copy of a Database\n7.4.5.2 Copy a Database from one Server to Another\n7.4.5.3 Dumping Stored Programs\nSeveral options control how  mysqldump  handles stored programs (stored procedures and functions, triggers, and events):\nYou can specify a different database name in this case, so omitting  --databases  from the  mysqldump command enables you to dump data from one database and load it into another.\nshell>  mysqladmin create db1 shell>  mysql db1 < dump.sql\nshell>  mysqldump db1 > dump.sql\nshell>  mysql < dump.sql\nshell>  mysqldump --databases db1 > dump.sql\n1625\n• --events : Dump Event Scheduler events\n• --routines : Dump stored procedures and functions\nAlternatively, you can omit  --databases  from the  mysqldump  command. Then you need to create the database on Server 2 (if necessary) and specify it as the default database when you reload the dump file.\nOn Server 1:\nOn Server 2:\nUse of  --databases  with the  mysqldump  command line causes the dump file to include  CREATE DATABASE  and  USE  statements that create the database if it does exist and make it the default database for the reloaded data.\nOn Server 2:\nCopy the dump file from Server 1 to Server 2.\nOn Server 1:\nDo not use  --databases  on the  mysqldump  command line because that causes  USE db1  to be included in the dump file, which overrides the effect of naming  db2  on the  mysql  command line.\nshell>  mysqldump db1 > dump.sql shell>  mysqladmin create db2 shell>  mysql db2 < dump.sql\n•How to make a copy a database\n•How to copy a database from one server to another\n•How to dump stored programs (stored procedures and functions, triggers, and events)\n•How to dump definitions and data separately\nThis section surveys techniques that enable you to use  mysqldump  to solve specific problems:"}]}
+{"image": "doclay/doclay_74866.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "\nreaching new frontiers\nWith our strong South African roots dating back to our company’s formation in 1950, we at Sasol are advancing a focused growth programme in Southern Africa and around the world. Through our oil, gas and chemical interests, our company currently has exploration, production and sales operations in 23 countries.\nWe continue to reach new frontiers – not only geographically, but also through our employees’ commitment to advancing competitive technologies and business-optimisation strategies. Core to this drive are our shared values, which emphasise customer focus, winning with people, excellence in all we do, continuous improvement and integrity.\nOur values provide a robust framework for pursuing our vision and delivering solid results for our stakeholders around the globe . . .\nin 2003 and beyond . . .\n1"}]}
+{"image": "doclay/doclay_24745.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "2.1 General Relativity\n9\nWe can rearrange Eq. (2.11) slightly so that all four spacetime coordinates have the same scale factor, by defining a Conformal Time variable\nThe line element now becomes\nLet us now assume that the content of the Universe is analogous to a perfect fluid , which is a fluid that has no shear stress, no viscosity and which does not conduct heat. It can be described entirely by its energy density ρ and its isotropic pressure P . In the local rest frame, the Energy- Momentum tensor becomes simply\nWe have not yet employed GR in the discussion regarding our FLRW Universe. All we have assumed so far is a uniformly expanding/contracting homogeneous and isotropic Universe, which has a content that can be de- scribed as a perfect fluid. We now take the “00” (“ tt ”) component of the\nT$_{µν}$ =    $^{ρ}$ 0 0 0 0 P 0 0 0 0 P 0 0 0 0 P    \nds 2 = a $^{2}$( η ) ( − dη 2 + dx 2 + dy 2 + dz 2 ) (2.13)\ndη = dt a (2.12)"}]}
+{"image": "doclay/doclay_43015.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "AIM\n8/15/19  1/30/20\nFIG 7 − 1 − 8 Key to Decode an ASOS/AWOS (METAR) Observation (Back) \nMeteorology\n7 − 1 − 29\n"}]}
+{"image": "doclay/doclay_27410.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "4.3 Quark mass versus meson mass, showing the massless pion when m$_{q}$ = 0. We plot the square root of the quark mass to demonstrate the linear relationship. . . . . . . . . . . . . . . 69 4.4 A plot of m$_{ρ}$ vs m 2 π in the Constable-Myers background on the left. Lattice data [1] (preliminary, quenched and at finite spacing) for the same quantity is also shown on the right. . . 71 5.1 Experimentally, the ρ mesons follow very closely the relation- ship m 2 n ∼ n . The dots are the physical values . . . . . . . . 81 7.1 The mass squared of the n lightest ρ meson excitations for different values of the UV cutoff. The dots represent the experimental values. . . . . . . . . . . . . . . . . . . . . . . 100 7.2 The decay constant F 1 / 2 ρ for different ρ excitations, plotted for varying UV cutoffs . . . . . . . . . . . . . . . . . . . . . 102 8.1 Hadronization . . . . . . . . . . . . . . . . . . . . . . . . . . 108 8.2 A re-enactment of a single e $^{+}$e − collision detected at CERN 108 8.3 The normalised holographic hadron basis functions for the π 0 stack (left) and the ρ meson stack (right) . . . . . . . . . . . 114\nvi"}]}
+{"image": "doclay/doclay_79862.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "US 2020/0159120 Al \n57 \nMay 21, 2020 \n-continued \n-continued "}]}
+{"image": "doclay/doclay_44470.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Direct cranking electric starter.......................................5-2 Direct cranking electric starting system for large  reciprocating engines..................................................5-3 Motor assembly ......................................................5-3 Starter motor ...........................................................5-3 Direct cranking electric starting system for small  aircraft ........................................................................5-7 Discharge nozzle............................................................2-7 Divided-entrance duct..................................................3-19 Duplex fuel nozzle .......................................................2-46 Durability .......................................................................1-3 Dynamic dampers ........................................................1-10\nCarburetor types.............................................................2-9 Float-type carburetor ..................................................2-9 Pressure-type carburetor.............................................2-9 Checking ignition induction vibrator systems .............4-30 Checking the internal timing of a magneto..................4-25 Circuit protection devices ............................................4-68 Combustion drain valves..............................................2-47 Combustion section......................................................1-44 Compactness ..................................................................1-3 Complete fuel system...................................................2-33 Compression ratio ........................................................1-29 Compressor inlet screens .............................................3-20 Compressors.................................................................1-40 Axial-flow compressor .............................................1-41 Rotor .....................................................................1-42 Disk-type rotor...................................................1-42 Drum-type rotor.................................................1-42 Stator.....................................................................1-41 Centrifugal-flow compressors ..................................1-40 Compressor manifold.................................. 1-40, 1-41 Diffuser ....................................................... 1-40, 1-41 Impeller.................................................................1-40 Compressor section......................................................1-39 Conductor insulation....................................................4-49 Dielectric strength ....................................................4-50 Insulation resistance .................................................4-50 Conduit.........................................................................4-67 Connecting rods ...........................................................1-10 Connecting terminal lugs to terminal blocks ...............4-62 Connector identification...............................................4-65 Connectors ...................................................................4-65 Continental/TCM fuel-injection system ......................2-25 Continuous ignition......................................................4-40 Controlling or monitoring the electrical load...............4-67 Convergent-divergent exhaust nozzle..........................3-28 Convergent exhaust nozzle ..........................................3-28 Copper wire terminals..................................................4-59 Crankshaft balance.......................................................1-10 Crankshafts ....................................................................1-8 Crimping tools .............................................................4-60 Cutting wire and cable .................................................4-58 Cylinder barrels............................................................1-16 Cylinder heads .............................................................1-15 Cylinder numbering .....................................................1-16 Cylinders ......................................................................1-14\nDensity altitude ..............................................................3-6 Dielectric inspection ....................................................4-38 Differential pressure controller ....................................3-14 Diffuser ........................................................................1-44\nFactors affecting selection of conductor material........4-47 Factors affecting the selection of wire size..................4-47 FADEC for an auxiliary power unit.............................2-37 FADEC fuel control propulsion engine .......................2-39 FADEC fuel control systems .......................................2-37 FADEC system description..........................................4-12\nEconomizer system ......................................................2-14 EEC system..................................................................2-37 Efficiencies ..................................................................1-35 E-gap ............................................................................4-25 Electrical equipment installation..................................4-67 Electrical load limits ....................................................4-67 Electrical wiring installation ........................................4-51 Electric starting systems and starter generator  starting system .............................................................5-10 Electronic control unit (ECU)............................ 4-13, 4-14 Emergency splicing repairs..........................................4-61 Engine fuel system components...................................2-43 Engine noise supression...............................................3-31 Engines...........................................................................1-4 Inline engines .............................................................1-4 Opposed engines.........................................................1-4 O-type engines............................................................1-4 Radial engines ............................................................1-5 V-type engines............................................................1-5 Exhaust leak .................................................................3-25 Exhaust manifold and stack failures ............................3-25 Exhaust section ............................................................1-52 Exhaust cone.............................................................1-52 Exhaust nozzle..........................................................1-53 Insulation blanket .....................................................1-53 Tailpipe.....................................................................1-53 Exhaust system inspection ...........................................3-24 Exhaust system repairs.................................................3-26 Exhaust systems with turbocharger .............................3-26\nE\nF\nD\n I-2"}]}
+{"image": "doclay/doclay_29164.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "= n ∏ j =1 ( 2 πm$_{j}$ β ) 3 / 2 1 (2 π ) 3 ∫ d $^{3}$x exp [ − m$_{0}$ β x 2 2 ] = n ∏ j =1 ( 2 πm$_{j}$ β ) 3 / 2 / ( 2 πm$_{0}$ β ) 3 / 2 , (A9)\nf trans l ( β ) = − 1 β [ ln ( V$_{n}$ ( m$_{N}$A$_{l}$ 2 π ℏ $^{2}$β ) 3 / 2 ) − ln ( N$_{l}$ !) N$_{l}$ ] , (A11)\nF$_{n}$ ( β ) = k ∑ l =1 N$_{l}$ ( f ∗ l ( β ) + f trans l ( β ) − B$_{l}$ − E$_{cl}$ ) − ( f trans 0 ( β ) − E$_{c}$$_{0}$ ) , (A12)\nω$_{n}$ = 1 2 πi ∫ c + i ∞ c − i ∞ dβ exp [ − β ( F$_{n}$ ( β ) − E$_{0}$ )] , (A13)\nE$_{0}$ = ε$_{0}$ − B$_{0}$ . (A14)\nCombining the factors resulting from the momentum integrals with those due to the fragment multiplicities, we define the translational Helmholtz free energies as\nwhere we recognize that m$_{l}$ = m$_{N}$A$_{l}$ and m$_{0}$ = m$_{N}$A$_{0}$ , with m$_{N}$ the nucleon mass. We can then define the total Helmholtz free energy as\nwhere we have replaced the sum over the fragments with a sum over distinct fragments times their multiplicities, and write the density of final states as\nwhere we have defined\nUp to this point, we have made several definitions but no approximations. This expression is exactly equivalent to that of Eq. (9).\n[1] E. Fermi, Prog. Theor. Phys. 5 (1950) 570.\n[2] E. Fermi, Phys. Rev. 81 (1951) 683.\n[3] J. J. Lord, J. Fainberg, and M. Schein, Phys. Rev. 80 (1950) 970.\n16\n∑ ω$_{n}$ = k ∏ l =1 1 N$_{l}$ ! 1 2 πi ∫ c + i ∞ c − i ∞ dβ n ∏ j $_{=1}$( V$_{n}$ ( m$_{j}$ 2 π ℏ $^{2}$β ) 3 / 2 ) / ( V$_{n}$ ( m$_{0}$ 2 π ℏ $^{2}$β ) 3 / 2 ) (A10) × exp [ β ( ε$_{0}$ − B$_{0}$ − E$_{c}$$_{0}$ − n ∑ j =1 ( f ∗ j ( β ) − B$_{j}$ − E$_{cj}$ ) )] .\nwhere m$_{0}$ = ∑ n j $_{=1}$m$_{j}$ . We rewrite the full integral as k ∏ 1 1 ∫ c + i ∞ n ∏ $_{=1}$( ( m$_{j}$ )"}]}
+{"image": "doclay/doclay_250.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "\n2004 Annual Report 11\nbringing better packaging to your pantry\nhassle-free holiday cooking\nLight, convenient shape, easy to open – these are just a few reasons why our new  Tetra Recart packaging is such a great solution for our  Hormel and Stagg lines of chili. The cartons also make our delicious chili easier to ship, stack, store, and eat. We have received great acceptance with the nationwide distribution of  Stagg chili.\nCount on Hormel Foods to end holiday anxiety! Home cooks across America were calmer this year with the introduction of our new  Jennie-O Turkey Store Oven Ready Turkey – a top-quality turkey that goes directly from freezer to oven for a flawless holiday celebration in about three and one-half hours. Even a  novice cook can create a juicy, tender holiday turkey with confidence."}]}
+{"image": "doclay/doclay_19299.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "52\nannual report 2012  kAThMANdu\n13 INTANGIBLE ASSETS\nGroup  Goodwill nZ$’000 Brand nZ$’000 Software nZ$’000 total nZ$’000 As at 31 July 2010 Cost or valuation 76,677 165,285 3,065 245,027 Accumulated amortisation  (1,271) - (1,931) (3,202) Closing net book value 75,406 165,285 1,134 241,825 Year ended 31 July 2011 Opening net book value 75,406 165,285 1,134 241,825 Additions - - 676 676 Amortisation - - (862) (862) Exchange differences - 2,023 23 2,046 Closing net book value 75,406 167,308 971 243,685 As at 31 July 2011 Cost or valuation 76,677 167,308 3,764 247,749 Accumulated amortisation  (1,271) - (2,793) (4,064) Closing net book value 75,406 167,308 971 243,685 Year ended 31 July 2012 Opening net book value 75,406 167,308 971 243,685 Additions - - 3,985 3,985 Disposals - - (9) (9) Amortisation - - (1,599) (1,599) Exchange differences - 3,018 12 3,030 Closing net book value 75,406 170,326 3,360 249,092 As at 31 July 2012 Cost or valuation 76,677 170,326 7,801 254,804 Accumulated amortisation  (1,271) - (4,441) (5,712) Closing net book value 75,406 170,326 3,360 249,092\nImpairment tests for goodwill and brand\nthe aggregate carrying amounts of goodwill and brand allocated to each unit are as follows:\nGroup GooDWILL BrAnD 2012 nZ$’000 2011 nZ$’000 2012 nZ$’000 2011 nZ$’000 New Zealand 28,654 28,654 51,000 51,000 Australia 46,752 46,752 119,326 116,308 75,406 75,406 170,326 167,308"}]}
+{"image": "doclay/doclay_13821.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "First BanCorp.> 2001\nThe Island of Puerto Rico is a U.S. Commonwealth with a pop- ulation of 3.8 million, located in the Caribbean approximately 1,600 miles southeast of New York. Puerto Rico enjoyed solid economic growth over most of the 1990’s. Real GNP grew by 3.1% in the 2000 fiscal year, according to the most recent offi- cial data available. Economists project a slowdown to less than 2% during fiscal 2001 and a small decline in fiscal 2002 due to the U.S. recession.\nPuerto Rico’s economic performance is a natural result of its increasing integration into the U.S. economy. Puerto Ricans are U.S. citizens and serve in the United States armed forces, and the Island has several large U.S. military bases.The Island uses U.S. currency and forms part of the U.S. financial system. Federal courts enforce U.S. laws here. Since Puerto Rico falls within the U.S. for purposes of customs and migration, there is full mobility of funds, people and goods between Puerto Rico and the U.S. mainland. Puerto Rico banks are subject to the same Federal laws, regulations and supervision as other financial institutions in the rest of the U.S.The Federal Deposit Insurance Corporation insures the deposits of Puerto Rico chartered commercial banks, including FirstBank, the banking subsidiary of First BanCorp.\nOne Economy 1\n0 15"}]}
+{"image": "doclay/doclay_27802.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "177\nBibliography\n[322] O. Aharony, S. S. Gubser, J. M. Maldacena, H. Ooguri, and Y. Oz, Large N field theories, string theory and gravity , Phys. Rept. 323 , 183 (2000) [hep-th/9905111]. x, 54, 57, 59, 60, 65\n[323] J. Polchinski, Lectures on D-branes (1996) [hep-th/9611050]. x, 58, 59\n[324] M. B. Green, J. H. Schwarz, and E. Witten, Superstring theory , vol. 1 (Cambridge University Press, 1987). x, 59\n[325] R. G. Leigh, Dirac-Born-Infeld Action from Dirichlet Sigma Model , Mod. Phys. Lett. A4 , 2767 (1989). 59\n[326] N. Seiberg and E. Witten, Monopoles, duality and chiral symmetry breaking in N=2 supersymmetric QCD , Nucl. Phys. B431 , 484 (1994) [hep-th/9408099]. 60\n[327] M. Dine and N. Seiberg, Comments on higher derivative operators in some SUSY field theories , Phys. Lett. B409 , 239 (1997) [hep-th/ 9705057]. 60\n[328] M. R. Douglas, D. N. Kabat, P. Pouliot, and S. H. Shenker, D-branes and short distances in string theory , Nucl. Phys. B485 , 85 (1997) [hep-th/ 9608024]. 60\n[329] I. R. Klebanov, World-volume approach to absorption by non-dilatonic branes , Nucl. Phys. B496 , 231 (1997) [hep-th/9702076]. 61\n[330] I. R. Klebanov, TASI lectures: Introduction to the AdS/CFT correspon- dence (2000) [hep-th/0009139]. 66\n[331] C. V. Johnson, D-branes (Cambridge University Press, 2003). 66\n[332] S. S. Gubser, I. R. Klebanov, and A. W. Peet, Entropy and Temperature of Black 3-Branes , Phys. Rev. D54 , 3915 (1996) [hep-th/9602135]. 66, 70, 120\n[333] P. Kovtun, D. T. Son, and A. O. Starinets, Holography and hy- drodynamics: Diffusion on stretched horizons , JHEP 10 , 064 (2003) [hep-th/0309213]. 68"}]}
+{"image": "doclay/doclay_30187.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "longitudinal momentum fractions, we have made them explicit in the above formula. For a complete analysis, the above three terms have to be taken into account. The first term in the above equation, the contribution from the twist-three parton distributions φ (3) $_{i/A}$( x, x $^{′}$) from the polarized nucleon have been calculated in Refs. [17–19]. The second term from the twist- three effect in the unpolarized nucleon φ (3) $_{j/B}$( x, x $^{′}$) is found very small in the forward region of the polarized nucleon where the largest asymmetry has been found experimentally [28]. The third term is least known in the literature, which we will focus in this paper. There have been attempts to formulate this part of contribution [29]. However, a universality argument for the Collins fragmentation function [30, 31] would indicate that the contribution calcu- lated in Ref. [29] vanishes. This universality has also been extended to pp collisions [32]. Large azimuthal asymmetries coming from this Collins effect have been observed in semi- inclusive hadron production in deep inelastic scattering and di-hadron production in e $^{+}$e − annihilation processes by the HERMES [33] and COMPASS [34], and BELLE collabora- tions [35], respectively. In a recent publication, two of us have re-examined the twist-three fragmentation contribution to the single spin asymmetry [23]. In particular, we have identi- fied the twist-three fragmentation function corresponding to the TMD Collins fragmentation function, and shown that the TMD and collinear factorization approaches are consistent in the intermediate transverse momentum region in the SIDIS process. In this paper, we will extend this formalism to the twist-three fragmentation function contribution to the above process of (1), the single spin asymmetries in inclusive hadron production in p $^{↑}$p scattering.\nThe twist-three fragmentation function which corresponds to the universal Collins TMD fragmentation function, is defined as 1\n∫ In the above definition Eq. (3), we have set the hadron momentum in the ˆ z direction. The index α is in the transverse direction perpendicular to the hadron momentum direction, and\nˆ H ( z ) = z 2 2 ∫ dξ − 2 π e ik $^{+}$ξ − 1 2 { Tr σ α $^{+}$〈 0 | [ iD α T + ∫ + ∞ ξ − dζ $^{−}$gF α $^{+}$( ζ $^{−}$) ] ψ ( ξ ) | P$_{h}$X 〉 × 〈 P$_{h}$X | ¯ ψ (0) | 0 〉 + h.c. } , (3) k + = P + h /z . This function can also be written as the transverse momentum moment\nˆ H ( z ) = ∫ d $^{2}$p$_{T}$ | ⃗ p$_{T}$ | 2 2 M$_{h}$ H ⊥ 1 ( z, p 2 $_{T}$) . (4) In the above definition Eq. (3), we have set the hadron momentum in the ˆ z direction. The\n} where k + = P + h /z . This function can also be written as the transverse momentum moment of the Collins fragmentation function H ⊥ 1 ( z, p 2 $_{T}$),\n1 In the definition of ˆ H ( z ) in Ref. [23], a factor of 1 / 2 missed.\n4"}]}
+{"image": "doclay/doclay_1470.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "UNITED STATES SECURITIES AND EXCHANGE COMMISSION Washington, D.C. 20549\nFORM 10-K\n(Mark One)\nTRANSITION REPORT PURSUANT TO SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934 For the transition period from ___________ to___________\nCommission file number 001-15059\nor\nNORDSTROM, INC. (Exact name of registrant as specified in its charter)\nNORDSTROM, INC. (Exact name of registrant as specified in its charter)\nWashington (State or other jurisdiction of\nWashington (State or other jurisdiction of incorporation or organization)\n1617 Sixth Avenue, Seattle, Washington (Address of principal executive offices)\n1617 Sixth Avenue, Seattle, Washington (Address of principal executive offices)\n(Address of principal executive offices) (Zip Code) Registrant’s telephone number, including area code  206-628-2111\nSecurities registered pursuant to Section 12(b) of the Act:\n91-0515058 (I.R.S. Employer\n91-0515058 (I.R.S. Employer Identification No.)\n98101 (Zip Code)\n98101 (Zip Code) 206-628-2111\nCommon stock, without par value New York Stock Exchange Securities registered pursuant to Section 12(g) of the Act:  None\nTitle of each class Common stock, without par value\nTitle of each class Common stock, without par value\nName of each exchange on which registered New York Stock Exchange\nName of each exchange on which registered New York Stock Exchange None\nIndicate by check mark if the registrant is a well-known seasoned issuer, as defined in Rule 405 of the Securities Act. YES   NO \nIndicate by check mark if the registrant is not required to file reports pursuant to Section 13 or Section 15(d) of the Act. YES   NO \nIndicate by check mark whether the registrant (1) has filed all reports required to be filed by Section 13 or 15(d) of the Securities Exchange  Act of 1934 during the preceding 12 months (or for such shorter period that the registrant was required to file such reports), and (2) has been  subject to such filing requirements for the past 90 days. YES   NO \nAct of 1934 during the preceding 12 months (or for such shorter period that the registrant was required to file such reports), and (2) has been  subject to such filing requirements for the past 90 days. YES   NO \nIndicate by check mark whether the registrant has submitted electronically and posted on its corporate Website, if any, every Interactive Data  File required to be submitted and posted pursuant to Rule 405 of Regulation S-T during the preceding 12 months (or for such shorter period  that the registrant was required to submit and post such files). YES   NO \nIndicate by check mark if disclosure of delinquent filers pursuant to Item 405 of Regulation S-K is not contained herein, and will not be  contained, to the best of registrant’s knowledge, in definitive proxy or information statements incorporated by reference in Part III of this Form  10-K or any amendment to this Form 10-K. \nIndicate by check mark whether the registrant is a large accelerated filer, an accelerated filer, a non-accelerated filer, or a smaller reporting  company. See the definitions of “large accelerated filer,” “accelerated filer” and “smaller reporting company” in Rule 12b-2 of the Exchange  Act.\nLarge accelerated filer  Non-accelerated filer \nDOCUMENTS INCORPORATED BY REFERENCE Portions of the Proxy Statement for the 2015 Annual Meeting of Shareholders scheduled to be held on May 5, 2015 are incorporated into \nLarge accelerated filer  Non-accelerated filer   (Do not check if a smaller reporting company)\nAccelerated filer  Smaller reporting company \nAccelerated filer  Smaller reporting company \nIndicate by check mark whether the registrant is a shell company (as defined in Rule 12b-2 of the Act). YES   NO \nAs of August 1, 2014 the aggregate market value of the Registrant’s voting and non-voting stock held by non-affiliates of the Registrant was  approximately $10.6 billion using the closing sales price on that day of $68.95. On March 2, 2015, 190,405,729 shares of common stock  were outstanding.\nDOCUMENTS INCORPORATED BY REFERENCE Portions of the Proxy Statement for the 2015 Annual Meeting of Shareholders scheduled to be held on May 5, 2015 are incorporated into  Part III.\nNordstrom, Inc. and subsidiaries 1\nANNUAL REPORT PURSUANT TO SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934 For the fiscal year ended January 31, 2015 \nANNUAL REPORT PURSUANT TO SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934 For the fiscal year ended January 31, 2015 "}]}
+{"image": "doclay/doclay_53644.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "InnoDB System Variables\nInnoDB  tries to flush data from the buffer pool so that the percentage of dirty pages does not exceed this value.\nThe  innodb_max_dirty_pages_pct  setting establishes a target for flushing activity. It does not affect the rate of flushing. For information about managing the rate of flushing, see Section 15.8.3.5, “Configuring Buffer Pool Flushing” .\nFor related information, see Section 15.8.3.5, “Configuring Buffer Pool Flushing” . For general I/O tuning advice, see Section 8.5.8, “Optimizing InnoDB Disk I/O” .\nDefines a low water mark representing the percentage of dirty pages at which preflushing is enabled to control the dirty page ratio. A value of 0 disables the pre-flushing behavior entirely. The configured value should always be lower than the  innodb_max_dirty_pages_pct  value. For more information, see Section 15.8.3.5, “Configuring Buffer Pool Flushing” .\nDefines the desired maximum purge lag. If this value is exceeded, a delay is imposed on  INSERT , UPDATE , and  DELETE  operations to allow time for purge to catch up. The default value is 0, which means there is no maximum purge lag and no delay.\nFor more information, see Section 15.8.9, “Purge Configuration” .\n3264\n• innodb_max_dirty_pages_pct_lwm\nMaximum Value 99.99\nCommand-Line Format --innodb-max-dirty-pages-pct-lwm=# System Variable innodb_max_dirty_pages_pct_lwm Scope Global Dynamic Yes SET_VAR  Hint Applies No Type Numeric Default Value 10 Minimum Value 0 Maximum Value 99.99\nCommand-Line Format --innodb-max-purge-lag=# System Variable innodb_max_purge_lag Scope Global Dynamic Yes SET_VAR  Hint Applies No Type Integer Default Value 0 Minimum Value 0 Maximum Value 4294967295\n• innodb_max_purge_lag"}]}
+{"image": "doclay/doclay_64840.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "US 2020/0246423 Al \n73 \nAug. 6, 2020 \nTABLE 57 \nTABLE 59 \nTABLE 60 \nTABLE 58 \nConcentration, pH, and Osmolality \n[0418]  The aflibercept concentration (mg/mL), pH, and  osmolality (mOSm) of the Block E formulations were  evaluated at tO. Results are reported in Table 59 below. \n[0419]  The stability of the Block E formulations was  evaluated by measuring the amount of non-degraded afliber› cept present in the formulation at time  O  (tO) and after being  subjected to storage conditions. Size Exclusion Chromatog› raphy was conducted on the formulations and the percentage  of protein present in the main peak (non-degraded afliber› cept) in each formulation is reported in Table 60-63 below. \nSize Exclusion Chromatography \n[0417]  This example describes experiments to evaluate  buffer-free aflibercept formulations that have a stabilizer  other than sucrose (Block E). The design mirrored Block D,  except all of these compositions include 0.03% PS 20. This  will allow for a direct and detailed examination of the  importance PS 20 (and co-solvents in general) for their  impact on storage stability. Table 58, below, shows an  exemplary set of such formulations. \n[0416]  It  is further contemplated that in the formulations  of Block D, phosphate could be used instead of histidine  buffer.  It  is also contemplated that CaC1$_{2 }$ could be used  instead of, or in addition to, MgC1$_{2}$ . \n[0415]  The aflibercept formulations of Block Dare physi› cally and chemically stable. \nDiscussion \nExample 6-Buffer-Free Aflibercept Formulations  with Alternative Stabilizers \nic!EF results for Block D formulations after storage for four weeks at 5°  C.  Rel. Area (%) Smoothing (Grou12)  Formulation Block  2  3  4  5  6  7  8  9  D-1  4.6 6.8 7.4  11.4  13.9  15.2  14.5  11.6  8.5  D-2  4.5 6.2 7.8  12.1  14.6  14.9  14.2  11.6  8.0  D-3  4.5 6.1  7.7  11.9  14.2  14.8  14.5  11.6  8.5  D-4  4.3 6.6 7.3  12.4  14.0  15.5  14.1  11.5  8.5  D-5  4.8 6.3 7.3  12.5  13.9  14.7  14.9  11.6  8.2  D-6  4.2 7.1  6.9  11.6  14.8  15.0  14.2  11.8  8.1  D-7  4.4 6.3  8.0  12.0  14.3  14.8  14.7  11.6  8.0  D-8  3.9 6.5 7.2  12.1  15.1  15.0  14.1  11.2  8.3  D-9  4.2 6.7 7.3  12.1  14.3  15.7  14.1  11.8  8.0  D-10  4.4 6.1  8.0  11.9  14.4  15.6  14.0  11.9  7.8  D-11  4.8 6.8 7.4  12.3  13.8  15.7  14.1  11.6  7.9  D-12  5.0 6.5  6.7  12.4  14.7  15.4  14.1  11.9  7.8  Eylea  4.5 6.2 7.8  12.1  14.6  14.9  14.2  11.6  8.0  10  11  12  3.9 1.8 0.4  3.8 1.8 0.5  3.6 1.9 0.7  3.6 1.8 0.5  3.5 1.9 0.5  3.5 1.9 0.9  3.6  1.7  0.5  3.7 2.1  0.8  3.7 1.6 0.4  3.8 1.6 0.4  3.6 1.6 0.3  3.5 1.6 0.4  3.8 1.6 0.6 \nForm  Final Concentration  Final Osmolality  No.  (mg/mL)  Final pH  (mOsm/Kg)  E-1  38.33  6.23  274  E-2  37.88  6.21  303  E-3  39.55  6.25  284  E-4  40.06  6.27  242  E-5  37.91  6.14  295  E-6  39.63  6.11  271  E-7  39.31  6.22  287  E-8  39.85  6.12  290  E-9  39.57  6.44  276  E-10  42.04  6.57  297  E-11  39.71  6.95  276  E-12  40.42  6.94  302 \nAll formulations include 0.03% PS 20.  Form  Gly  Arg  Pro  NaCl  MgC1$_{2 }$ Dextran  No.  aflibercept pH (mM) (mM) (mM) (mM)  (mM)  (%)  E-1  40 mg/ml  6.2  270  0  0  0  0  0  E-2  40 mg/ml  6.2  0  0  270  0  0  0  E-3  40 mg/ml  6.2  0  25  0  125  0  0  E-4  40 mg/ml  6.2  0  50  0  75  0  0  E-5  40 mg/ml  6.2  0  0  0  150  0  E-6  40 mg/ml  6.2  0  0  0  0  100  0  E-7  40 mg/ml  6.2  270  0  0  0  0  E-8  40 mg/ml  6.2  0  0  0  40  75  0  E-9  40 mg/ml  6.5  270  0  0  0  0  0  E-10  40 mg/ml  6.5  0  0  270  0  0  0  E-11  40 mg/ml 7.0  270  0  0  0  0  0  E-12  40 mg/ml 7.0  0  0  270  0  0  0 \nSEC results for Block E formulations at T - 0  Form  Rel. Area(%),  Rel. Area (%),  Rel. Area (% ),  No.  Before Main Peak  Main Peak  After Main Peak  E-1  1.11  98.89  0  E-2  1.14  98.86  0  E-3  1.14  98.86  0  E-4  1.14  98.86  0  E-5  1.18  98.82  0  E-6  1.43  98.57  0  E-7  1.15  98.85  0  E-8  1.09  98.91  0  E-9  1.13  98.87  0  E-10  1.19  98.81  0  E-11  1.29  98.71  0  E-12  1.36  98.64  0 "}]}
+{"image": "doclay/doclay_60505.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "STANDARDS SECTION XVIII - TOURNAMENT STANDARDS OF PERFORMANCE\ne. Microphones\ni.  Center and Show Courts with five (5) camera coverage or above A minimum of twelve (12) audio microphones.\nii.  Outside Court Coverage with less than five (5) camera coverage A minimum of six (6) audio microphones.\nf.  On-Court Coaching\ni.  Two (2) wireless microphones for each Match on the World Feed.\nii.  An audio assistant must liaise with each player’s coach no less than  fifteen (15) minutes prior to the start of each televised Match in order  to prepare the coach’s microphone before the start of play.\niii. A discreet boom microphone may be added to the player bench  area.\niv.  When a player is being coached, a hand held camera may approach  the player and coach, but the camera must not get closer than six (6)  feet (1.83 meters) to their conversation and the camera framing must  be discreet. \na. Access\ni.  Each Tournament shall grant free access to personnel of the WTA  (and its designees) and shall provide the WTA (and its designees)  with such passes or tickets as are required for such access.\n(See Section XVIII.D for additional provisions concerning On-Court  Coaching.) \nEach Tournament must comply with the following requirements:\n4.  Tournament Facilities\nii.  At no cost to the WTA (or its designees), each Tournament shall  provide the WTA (and its properly credentialed designees) with  access to the player areas, and the site at which awards are to be  made. \n391"}]}
+{"image": "doclay/doclay_55523.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "sys Schema Views\nThe total number of occurrences of the stage event for the user.\nThe total wait time of timed occurrences of the stage event for the user.\nThe average wait time per timed occurrence of the stage event for the user.\nThese views summarize overall statement statistics, grouped by user. By default, rows are sorted by descending total latency.\nThe  user_summary_by_statement_latency  and  x$user_summary_by_statement_latency views have these columns:\nThe client user name. Rows for which the  USER  column in the underlying Performance Schema table is NULL  are assumed to be for background threads and are reported with a host name of  background .\nThe total number of statements for the user.\nThe total wait time of timed statements for the user.\nThe maximum single wait time of timed statements for the user.\nThe total time waiting for locks by timed statements for the user.\nThe total number of rows returned by statements for the user.\nThe total number of rows read from storage engines by statements for the user.\nThe total number of rows affected by statements for the user.\nThe total number of full table scans by statements for the user.\n28.4.3.46 The user_summary_by_statement_type and x$user_summary_by_statement_type Views\n5178\n• full_scans\n• rows_affected\n• rows_examined\n• rows_sent\n• lock_latency\n• max_latency\n• total_latency\n• total\n• user\n• avg_latency\n• total_latency\n28.4.3.45 The user_summary_by_statement_latency and x $user_summary_by_statement_latency Views"}]}
+{"image": "doclay/doclay_24868.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "S1 Proof of Lemma 3.6\nAssume that { X$_{j}$, j ≥ 1 } follows the LMSV model. Define\nLemma 3.6 states that\nin D ([ −∞ , ∞ ] × [0 , 1])\nProof of Lemma 3.6. In order to prove Lemma 3.6 we have to verify tightness in D ([ −∞ , ∞ ] × [0 , 1]). For this we quote Theorem 3.1 in Ivanoff (1983).\nTheorem S1.1. Let ( X$_{n}$, F $_{n}$, P$_{n}$ ) be a sequence of probability spaces such that X$_{n}$ is a random element of D ([0 , 1] × [0 , 1]) for each n , and the process X$_{n}$ ( x, t ) is adapted to a complete, right continuous filtration F $_{n}$( x, t ) ⊆ F $_{n}$. If X$_{n}$ ( x, t ) is tight for each ( x, t ) ∈ [0 , 1] × [0 , 1] and if for all δ$_{n}$ ↘ 0 and each canonical 1-stopping time S$_{n}$ and each canonical 2-stopping time T$_{n}$\nthen X$_{n}$ is tight in D ([0 , 1] × [0 , 1]) .\nIn the following we will show that the conditions of the theorem hold for X$_{n}$ ( x, t ) := n − 1 / $^{2}$M$_{n}$ ◦ H , where H : [0 , 1] × [0 , 1] −→ [ −∞ , ∞ ] × [0 , 1] with H ( x, t ) = ( h ( x ) , t ) for some increasing isomorphism h : [0 , 1] −→ [ −∞ , ∞ ]. Then, Lemma 3.6 immediately follows from an application of Theorem S1.1. Indeed, due to Lemma 3.5, n − 1 / $^{2}$M$_{n}$ ◦ H ( x, t ) is tight for each ( x, t ) ∈ [0 , 1] × [0 , 1].\n35\nM$_{n}$ ( x, t ) := ⌊ nt ⌋ ∑ j =1 ( $^{1}${ ψ ( X$_{j}$ ) ≤ x } − E ( $^{1}${ ψ ( X$_{j}$ ) ≤ x } | F j − 1 )) .\n1 √$_{n}$ M$_{n}$ ( x, t ) = O $_{P}$(1)\nsup 0 ≤ t ≤ $_{1}$| X$_{n}$ ( S$_{n}$ + δ$_{n}$, t ) − X$_{n}$ ( S$_{n}$, t ) | P −→ 0 , as n → ∞ , (S1.1)\nsup 0 ≤ x ≤ $_{1}$| X$_{n}$ ( x, T$_{n}$ + δ$_{n}$ ) − X$_{n}$ ( x, T$_{n}$ ) | P −→ 0 , as n → ∞ , (S1.2)"}]}
+{"image": "doclay/doclay_66649.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "( x ) Burial of dead.  — To prohibit the burial of the dead within the centers of population of the municipality and provide for their burial in such proper place and in such manner as the council may determine, subject to the provisions of the general law re gulating burial grounds and cemeteries and governing funerals and the disposal of the dead. AEcIaH\n(y) Slaughterhouses and markets . — To establish or authorize the establishment of slaughterhouses and markets, and inspect and regulate the use of the same; to provide for and regulate the keeping, preparation, and sale of meat, fruits, poultry, milk, fish , vegetables, and all other provisions or articles of food offered for sale.\n( z ) Enforcement of health laws and regulations . — To enforce health laws and regulations, and by ordinance to provide fines and penalties for violations of such regulations; to adopt such other measures to prevent the introduction and spread of disease as m ay, from time to time, be deemed desirable or necessary. SIaHDA\n( aa ) Nuisances . — To declare, prevent, and abate nuisances.\n( bb ) Cockfighting . — To regulate and license or prohibit cockfighting and the keeping or training of fighting cocks, and to close cockpits subject to the provisions and restrictions of general law. IAEcCT\n( cc ) Ringing of bells . — To regulate and restrain the ringing of bells and the making of loud or unusual noises.\n( dd ) Police . — To establish, maintain, and regulate a police force subject to the provisions of section two thousand five hundred and eighty hereof, and the provisions of general law.\n( ee ) Prison . — To establish, maintain, and regulate a municipal prison.\n(ff) Cruelty to animals . — To prohibit and provide for the punishment of cruelty to animals.\n( gg ) Disorderly houses, and so forth . — To suppress or regulate houses of ill fame and other disorderly houses; to prohibit the printing, sale, or exhibition of immoral pictures, books, or publications of any description. SDHacT\n( hh ) Gambling, riots, and breaches of the peace . — To prevent and\nCopyright 2012 CD Technologies Asia, Inc. and Accesslaw, Inc. Philippine Law Encyclopedia 2011\n836"}]}
+{"image": "doclay/doclay_69033.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Draft Document for Review December 5, 2019 4:33 pm\n8456ch_ConfigGUI.fm\n2. Click the Create Pool Pair tab as shown in Figure 11-41. The Create Pool Pair window  opens. \n3. Specify the pool pair parameters, as shown in Figure 11-42:\n– Storage type : Ensure that  Open Systems (FB)  is selected.\n– Name prefix : Add the pool pair name prefix. A suffix ID sequence number is added  during the creation process.\nNote:  You can automatically assign arrays when creating a pool pair. The arrays are  created with the default raid type, RAID 6. To configure other supported raid types,  select the  Custom  option on the Create Pool Pair dialog, or assign arrays manually to  an existing storage pool from the  Unassigned Arrays . RAID level 5 would need an RPQ,  but it is not recommended. For more information, see “Creating Fixed Block (FB) Pools:  Custom” on page 300.\nFigure 11-41 Create Pool Pair tab\nFigure 11-42 Create FB pool pair and assign arrays \nChapter 11. DS8900F Storage Management GUI  299"}]}
+{"image": "doclay/doclay_59964.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "Replication Channels\nFrom MySQL 8.0, multi-source replicas can be configured with replication filters on specific replication channels. Channel specific replication filters can be used when the same database or table is present on multiple sources, and you only need the replica to replicate it from one source. For GTID-based replication, if the same transaction might arrive from multiple sources (such as in a diamond topology), you must ensure the filtering setup is the same on all channels. For more information, see Section 17.2.5.4, “Replication Channel Based Filters” .\nTo provide compatibility with previous versions, the MySQL server automatically creates on startup a default channel whose name is the empty string ( \"\" ). This channel is always present; it cannot be created or destroyed by the user. If no other channels (having nonempty names) have been created, replication statements act on the default channel only, so that all replication statements from older replicas function as expected (see Section 17.2.2.2, “Compatibility with Previous Replication Statements” . Statements applying to replication channels as described in this section can be used only when there is at least one named channel.\nTo enable MySQL replication operations to act on individual replication channels, use the  FOR CHANNEL channel  clause with the following replication statements:\nAn additional  channel  parameter is introduced for the following function:\nThe following statements are disallowed for the  group_replication_recovery  channel:\nThe following statements are disallowed for the  group_replication_applier  channel:\nFLUSH RELAY LOGS  is now permitted for the  group_replication_applier  channel, but if the request is received while a transaction is being applied, the request is performed after the transaction ends. The requester must wait while the transaction is completed and the rotation takes place. This behavior prevents transactions from being split, which is not permitted for Group Replication.\n3593\n• SHOW REPLICA | SLAVE STATUS\n• STOP REPLICA | SLAVE\n• START REPLICA | SLAVE\n• STOP REPLICA | SLAVE\n• START REPLICA | SLAVE\n• MASTER_POS_WAIT()\n• RESET REPLICA | SLAVE\n• SHOW REPLICA | SLAVE STATUS\n• FLUSH RELAY LOGS\n• SHOW RELAYLOG EVENTS\n• STOP REPLICA | SLAVE\n• START REPLICA | SLAVE\n• CHANGE MASTER TO\n• CHANGE REPLICATION SOURCE TO\n17.2.2.1 Commands for Operations on a Single Channel"}]}
+{"image": "doclay/doclay_57777.jpg", "conversations": [{"from": "human", "value": "<image>\nRead and extract all visible text in this image, following the natural reading order."}, {"from": "gpt", "value": "54 | Driver’s Manual\n• Three or more alcohol or drug related  driving convictions in the 25 year look back  period plus at least one other serious driving  offense during that period. A serious driving  offense includes: a fatal crash, a driving-re- lated penal law conviction, an accumulation  of 20 or more points assessed for driving  violations within the 25 year look back peri- od or having two or more driving convictions  during the 25 year look back period each  worth five points or more.\n• Delayed Re-Licensing, Driving Restrictions,  & Interlocks for Other Drivers with Repeated  Alcohol- or Drug-Related Driving Convic- tions:  For those drivers seeking reinstatement  of a license after revocation who have three or  four alcohol- or drug-related driving convic- tions but no serious driving offense in the 25  year look back period, DMV will:\n• Deny their applications for five years beyond  their statutory revocation period if the appli- cant’s license was revoked for an alcohol- or  drug-related offense; or two additional years  if the applicant’s license was revoked for a reason other than an alcohol or drug related offense;\n• Restore the applicant’s license after that  additional period as a “restricted” license  limiting the applicant’s driving to, for exam- ple, travel to and from work or medical visits; and\n• Require an interlock device on the vehicle  driven by the applicant for five years from  the date of the interlock device installation.\n• End the Reduction of Mandatory Suspension  or Revocation Periods:  Previously, repeat  drunk drivers whose licenses had been re- voked or suspended could get their full driving  privileges back in as little as seven weeks by  completing DMV’s Impaired Driver Program.  DMV’s new regulations will ensure that those  drivers cannot regain their driving privileges  until their full term of suspension or revocation  has ended.\nZero Tolerance for Drivers Under Age 21\nIllegal Purchase of Beverages Containing Alcohol\nOpen Container Law\nThe legal purchase and possession age for  beverages containing alcohol in New York State  is 21. Under the state’s “zero tolerance” law, it  is a violation for a person under 21 to drive with  any BAC that can be measured (.02 to .07). After  a finding of violation is determined at a DMV  hearing, the driver license will be suspended for  six months. The driver then must pay a $100 sus- pension termination fee and a $125 civil penalty  to be re-licensed. For a second Zero Tolerance  violation, the driver license will be revoked for  at least one year or until the driver reaches 21,  whichever is longer.\nWhen you use a driver license or Non-Driver ID  card as proof of age to illegally purchase bever- ages that contain alcohol, state law requires the  suspension of your driver license or privilege to  apply for a license.\nIt is a traffic infraction for a driver or passenger  in a motor vehicle on a public highway, street or  road to drink a beverage containing alcohol or to  have a beverage containing alcohol. The penalty  for a first conviction is a fine up to $150, a man- datory surcharge, a crime victim assistance fee,  and possible imprisonment of 15 days. Additional  offenses within 18 months bring higher penalties.  The law exempts passengers in vehicles like  stretch limousines and other vehicles that display  a commerce certificate or permit issued by the  U.S. Department of Transportation or the NYS  Department of Transportation."}]}
+{"image": "doclay/doclay_23782.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract all text from this image, reading from top to bottom and left to right."}, {"from": "gpt", "value": "Bancorp offers a variety of products designed to attract and retain customers, with the primary focus on building and expanding relationships. At December 31, 2010, deposits totaled $520.3 million. During 2010, deposits decreased  by $20.3 million (3.7%). The 2010 change in deposits was comprised of the following: certificates of deposit decreased by $28.4 million (12.5%), checking accounts decreased  by $3.0 million (2.1%), money market deposit accounts (MMDA’s) increased by $2.9 million (2.6%), while savings accounts increased by $8.2 million (14.5%). During 2010, as a result of carrying excess liquidity, management imple- mented a strategy that allowed for the reduction in higher cost certificates of deposit. The increase in MMDA and savings balances is a result of customer preferences for liquid investments in the current low interest rate environment. \nequivalents were from loan sales and repayments, maturities and sales of securities, FHLB advances, and cash from  operating activities. The primary uses of cash and cash  equivalents were loan originations, purchase of securities, expenditures for premises and equipment, decrease in deposits, FHLB advance repayments and the payment of common stock dividends. During 2010, cash from operating activities totaled $14.5 million, compared to $1.2 million for 2009. The 2010 increase in cash provided by operating activities was a result of higher net income, having prepaid three years of FDIC assessments in 2009, and ACH prefunding liabilities. Cash inflows from investing activities totaled $19.9 million during 2010, compared to $3.3 million during 2009. The change for the current year was related to a decrease in loan balances, maturities and pay downs of AFS securities, and foreclosed real estate sales. Loan sales totaled $41.4 million for 2010, compared to $60.0 million in 2009. Net cash outflows from financing activities totaled $36.7 million in 2010, compared to net cash outflows of $2.7 million in 2009. The change during 2010 was primarily due to a decrease in deposits. Deposits decreased by $20.3 million during 2010, compared to an increase of $12.4 million for 2009. FHLB advances decreased by $9.0 million during 2010 compared to an $8.0 million increase during 2009. The lower deposit growth and reduction in advance balances was a result of lower funding requirements during 2010. The Bancorp paid dividends on common stock of $2.2 million and $3.4 million during 2010 and 2009, respectively. During 2010, the Bancorp’s Board of Directors reduced dividends to build capital and preserve long-term capital strength.\nThe Bancorp’s borrowed funds are primarily comprised of repurchase agreements and FHLB advances that are used to fund asset growth not supported by deposit generation.  At December 31, 2010, borrowed funds totaled $48.6 million compared to $63.0 million at December 31, 2009,  a decrease of $14.4 million (22.9%). During 2010,  management repaid borrowed funds with excess liquidity. Retail repurchase agreements totaled $16.1 million at December 31, 2010, compared to $15.9 million at December 31, 2009, an increase of $0.2 million (1.2%). FHLB advances totaled $29.0 million, decreasing $9.0 million or 23.7%. In addition, the Bancorp’s FHLB line  of credit carried a balance of $3.2 million at December 31, 2010, compared to $8.5 million at December 31, 2009. Other short-term borrowings totaled $296 thousand at December 31, 2010, compared to $664 thousand at December 31, 2009.\nDuring the third quarter of 2010, the Bancorp opened its twelfth full service banking center in Saint John, Indiana. The new $2.1 million state-of-the-art facility did not have a material impact on operations during 2010. It is expected that the new banking center will provide opportunities to expand market share for the Bancorp’s products and services. \nThe Bancorp’s primary goal for funds and liquidity  management is to ensure that at all times it can meet the cash demands of its depositors and its loan customers.  A secondary purpose of funds management is profit  management. Because profit and liquidity are often conflicting objectives, management will maximize the Bank’s net interest margin by making adequate, but not excessive, liquidity provisions. Furthermore, funds are managed so that future profits will not be significantly impacted as funding costs increase. \nChanges in the liquidity position result from operating, investing and financing activities. Cash flows from operating activities are generally the cash effects of transactions and other events that enter into the determination of net income. The primary investing activities include loan originations, loan repayments, investments in interest bearing balances in financial institutions, dividend receipts and the purchase and maturity of investment securities. Financing activities focus almost entirely on the generation of customer deposits. In addition, the Bancorp utilizes borrowings (i.e., repurchase agreements, FHLB advances and federal funds purchased)  as a source of funds.\nManagement strongly believes that safety and soundness is enhanced by maintaining a high level of capital. Stockholders' equity totaled $56.1 million at December 31, 2010, compared to $53.1 million at December 31, 2009, an increase of $3 million (5.7%). The increase was a result of $5.2 million in net income for 2010. Additional items increasing stockholders' equity were $151 thousand from the sale of treasury stock, and $36 thousand from stock-based compensation plans. Decreasing stockholders' equity were $314 thousand from the change in the valuation of available- for-sale securities, the Bancorp’s declaration of $2.0 million in cash dividends, and $8 thousand from the change in net unrealized items from the Bank’s postretirement plans.  At December 31, 2010, book value per share was $19.84 compared to $18.83 for 2009.\nThe Bancorp is subject to risk-based capital guidelines adopted by the Board of Governors of the Federal Reserve System (the FRB), and the Bank is subject to risk-based capital guidelines adopted by the FDIC. As applied to the Bancorp and the Bank, the FRB and FDIC capital require- ments are substantially the same. These regulations divide capital into two tiers. The first tier (Tier 1) includes common equity, certain non-cumulative perpetual preferred\nDuring 2010, cash and cash equivalents decreased  $2.3 million compared to a increase of $1.9 million for 2009. During 2010, the primary sources of cash and cash\n15\nLiquidity and Capital Resources"}]}
+{"image": "doclay/doclay_45856.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "APPENDIX D - Atmospheric Dispersion Modeling \nAPPENDIX D$_{ }$\nD.1  Overview \nD.2  Dispersion Modeling Data \nD.2.1  Model Identification and Options \n70  EPA, Preferred/Recommended Models, http://www.epa.gov/scram001/dispersion_prefrec.htm.  71  The term  building downwash  describes the effect that wind flowing over or around a structure(s) has on plumes \nEPA, Preferred/Recommended Models, http://www.epa.gov/scram001/dispersion_prefrec.htm.  71  The term  building downwash  describes the effect that wind flowing over or around a structure(s) has on plumes  released from nearby sources (such as stacks). Essentially, structure(s) create a cavity of recirculating winds in  the area near the structure(s), and these cavities cause increased vertical dispersion of plumes emitted from \n74$_{ }$\nAERMOD is typically executed using the regulatory default options (e.g., stack- tip downwash,  buoyancy-induced dispersion, and final plume rise), default wind speed profile categories,  default potential temperature gradients, and no pollutant decay. AERMOD also has the capability  to account for building downwash effects$^{71 }$and to employ gas or particle deposition or wet/dry  depletion of the plume. 72 \nThe model predicts both short - (i.e., 1-, 3, 8, 24- hour) and long -term (i.e., annual) average  concentrations (in microgram per cubic meter or µg/m $^{3}$) at each receptor. These concentrations  may be presented as plot files and receptor files providing the results for both tabular graphical display. \nAERMOD is a steady-state Gaussian dispersion model recommended by the EPA for short-range  (i.e., up to 50 kilometers) dispersion of air pollutant emissions from point, area, line, volumes sources over simple, intermediate, and complex terrain. 70  As such, AERMOD serves as  dispersion modeling component for the FAA’s EDMS/AEDT. \nThese concepts and elements are discussed individually in the following sections. \nThe fundamental concepts and elements of air dispersion modeling include the following: \nThis appendix discusses the methodology, typical input data, and endpoints associated  with  atmospheric dispersion modeling of airport-related sources.  Section 7.1  ( Atmospheric Dispersion  Modeling for Airports ) discusses the available guidance for preparing and reporting the results of  dispersion modeling for FAA projects/actions. \n• Model identification and options  Emission source release characteristics \nModel identification and options  • Emission source release characteristics  Meteorological data \nEmission source release characteristics  • Meteorological data  Spatial allocation \nMeteorological data  • Spatial allocation  Temporal profiles \nSpatial allocation  • Temporal profiles  Topography data \nTemporal profiles  • Topography data  Building downwash \nTopography data  • Building downwash  Receptor locations \nBuilding downwash  • Receptor locations  NO$_{x }$to NO$_{2 }$conversion \nReceptor locations  • NO$_{x }$to NO$_{2 }$conversion  Background concentrations \nNO$_{x }$to NO$_{2 }$conversion  • Background concentrations "}]}
+{"image": "doclay/doclay_1884.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "TABLE VIII: Lorentzian-fit parameters of HEOR strength distributions in the Sn isotopes, as extracted from MDA. The results from TAMU work, where available, are provided for compari- son [19, 21].\na ( m 1 /m 0 ) ratios.\nmeasurements of the ISGMR in the Pb isotopes, using background-free inelastic spectra with high-energy α beams, would be worthwhile to fully examine this possibility.\nThe incompressibility of a nucleus, K$_{A}$ , may be expressed as:\nHere, c ≈ -1[84], and K$_{Coul}$ is essentially model independent (in the sense that the deviations from one theoretical model to another are quite small), so that the associated term can be calculated for a given isotope. Thus, for a series of isotopes, the difference K$_{A}$ − K$_{Coul}$Z $^{2}$A − 4 / 3 may be approximated to have a quadratic relationship with the asymmetry parameter, of the type y = A + Bx $^{2}$, with K$_{τ}$ being the coefficient, B, of the quadratic term. It has been established previously [85, 86] that direct fits to the Eq. 8 do not provide good constraints on the value of K$_{∞}$. However, this expression is being used here not to obtain a value for K$_{∞}$, but, rather, only to demonstrate the approximately quadratic relationship between K$_{A}$ and the asymmetry parameter.\nFrom such an analysis of the ISGMR data in the Sn isotopes, we have obtained a value of\n22\nK$_{A}$ ∼ K$_{vol}$ (1 + cA − 1 / $^{3}$) + K$_{τ}$ (( N − Z ) /A ) 2 + K$_{Coul}$Z $^{2}$A − 4 / 3 (8)\nTarget E$_{HEOR}$ (MeV) Γ (MeV) Reference $^{112}$Sn 22 . 7 ± 0 . 7 7 . 2 ± 1 . 9 This work 20 . 63 +0 . 30 − 0 28 3 . 21 +0 . 30 − 0 28 TAMU a $^{114}$Sn 22 . 7 ± 0 . 7 7 . 2 ± 2 . 1 This work $^{116}$Sn 22 . 3 ± 0 . 6 7 . 6 ± 1 . 7 This work 23 . 3 ± 0 . 8 10 . 9 ± 0 . 6 TAMU $^{118}$Sn 22 . 1 ± 0 . 6 5 . 9 ± 1 . 5 This work $^{120}$Sn 22 . 3 ± 0 . 6 7 . 5 ± 1 . 8 This work $^{122}$Sn 22 . 1 ± 0 . 6 5 . 6 ± 1 . 5 This work $^{124}$Sn 22 . 1 ± 0 . 5 8 . 1 ± 1 . 5 This work 19 . 12 +0 . 26 − 0 26 3 . 30 +0 . 17 − 0 05 TAMU a"}]}
+{"image": "doclay/doclay_60812.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "13\n200510003630. 5\na HR OEIYIM\nFARR TGA, ARB PO BEARMRTARAN -EcItwiH FEHA-EZTWRE TERM, TEE -AREHAR-AKEE neh. totL—R, —ZidKit BALA HARARE RA DEBT ARH PCI BIR P 9 ARIE 4E IN, HEIZ PCIE FR PCI FE TH HS RE PCI IEREMNE, BERAHANANER FAHRT MHZ RASA BRIE\nVA EPIRA RAR IKE, ARAR BAF AP PT KAY IgE Ry, Sir, HARRARUWY BSA."}]}
+{"image": "doclay/doclay_4166.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "2 \nUS 7,851,130 B2 \n1 \ndecomposable resin), and chemical amplification resist com› positions comprising acid generators are effectively used as  the main components. \nIn connection with these positive resists for electron  beams, X-rays or EUV rays, some resist compositions con› taining phenolic acid-decomposable resin are known (e.g.,  JP-A-2002-323768 (The term \"JP-A\" as used herein refers to  an \"unexamined published Japanese patent application\".),  JP-A-6-41221, Japanese Patent No. 3173368, JP-A-2000- 122291, JP-A-2001-114825, and JP-A-2001-206917). \nAs the resist suitable for lithographic process using elec- tron beams, X-rays or EUV rays, chemical amplification  resists utilizing acid catalytic reaction are mainly used from  the viewpoint of the enhancement of sensitivity, and in posi› tive resists, phenolic polymers having properties that are  insoluble or hardly soluble in an alkali developing solution  but become soluble in an alkali developing solution by the  action of an acid (hereinafter referred to as phenolic acid-\nFurther, when EUV is used as the light source, since wave› lengths of the lights belong to the extreme ultraviolet region  having high energy, there is a problem of contrast reduction  due to concentration of photochemical reaction such as the  tendency to be negative attributable to EUV rays and the like.  In lithography using X-rays or EUV rays, it is also an impor› tant object to reconcile high sensitivity and high resolution,  and the resolution of this problem is indispensable. \nIn particular, electron beam lithography is taken as the  pattern forming technique of the next generation or the next of  the next generation, so that resists of high sensitivity and high  resolution are required. The increase in sensitivity is very  important object in view of shortening of the processing time  of wafers, but in positive resists for electron beams, pursuit of  increment of sensitivity is accompanied by not only reduction  of resolution but also deterioration ofline edge roughness, so  that the development of a resist satisfying these characteris› tics at the same time is strongly desired. Here, line edge  roughness means that the edge of the interface between the  line pattern of a resist and a substrate irregularly changes in  perpendicular direction to the line direction attributable to the  characteristics of the resist, and the edge looks unevenly when  it is observed from right above. This unevenness is transferred  to the substrate by etching processing with the resist as a mask  and deteriorates electric characteristic and results in the  reduction of yield. In particular, line edge roughness is an  extremely important object to be solved in a hyperfine region  of 0.25 µm  or less. High sensitivity, high resolution, a good  pattern form and good line edge roughness are in relationship  of trade-off, and how to satisfy these factors at the same time  is a very important object. \nIn the manufacturing process of semiconductor devices  such as IC and LSI, fine processing by lithography using  photoresist compositions has been conventionally carried  out. In recent years, with the increment of integration of  integrated circuits, ultrafine pattern formation of the levels of  a sub-micron and quarter-micron has come to be required.  Under such a circumstance, the exposure wavelengths show a  tendency to be shortening, such as from g-ray to i-ray, further  to KrF excimer laser beam. Further, lithography using elec› tron beams, X-rays or EUV rays in addition to excimer laser  beams has been developed nowadays. \nThe present invention relates to a photosensitive composi› tion preferably used in super-microlithography processes  such as the manufacture of super LSI and high capacity  microchips, and other photo-publication processes. More  specifically, the invention relates to a positive photoresist  capable of forming a highly refined pattern with electron  beams, X-rays or EUV rays, and a resist composition suitable  for fine processing of semiconductor devices using electron  beams, X-rays or EUV rays (wavelength: 13 nm or so). \nFurther, when light sources such as electron beams, X-rays  and EUV are used, exposure is carried out under a vacuum, so  that compounds having a low boiling point such as solvents  and resist materials decomposed by high energy are volatil› ized to thereby contaminate the exposure apparatus, i.e., out- gassing is a serious problem. In recent years, various investi› gations are in progress on the reduction of outgassing, and a  variety of trials are suggested, e.g., restraint of volatilization  of low molecular weight compounds by forming a top coat  layer (e.g., refer to EP 1480078), and addition of a radical  trapping agent capable of inhibiting decomposition of a poly› mer (e.g., refer to U.S. Pat. No. 6,680,157). Some contriv› ances of outgassing are also required in connection with acid  generators. \nIn addition, contrivances such as linking of a benzene ring  oftriphenyl sulfonium (JP-A-2003-149800), and addition of  a base capable of decomposing and becoming a neutral com› pound by actinic radiation exposure (Japanese Patent No.  3549592) have been tried. \nHowever, it is the present situation that high sensitivity,  high resolution, good line edge roughness and low outgassing  in a hyperfine region cannot be satisfied at the same time with  any of these combinations. \nAn object of the invention is to solve the problems of the  improving technique of performances in fine processing of  semiconductor devices using high energy rays, X-rays, elec› tron beams or EUV rays, and another object is to provide a  photosensitive composition capable of satisfying high sensi› tivity, high resolution, good line edge roughness and low  outgassing at the same time. \nAs a result of eager examinations, the present inventors  have found that the above objects of the invention can be  achieved surprisingly with a photosensitive composition con› taining specific compound (A). \nThat is, the invention can be achieved by the following  constitutions. \n(1) A photosensitive composition comprising: \n(A) a compound represented by the following formula  (I): \nSUMMARY OF THE INVENTION \n1.  Field of the Invention \n2. Description of the Related Art \nBACKGROUND OF THE INVENTION \nPHOTOSENSITIVE COMPOSITION,  COMPOUND FOR USE IN THE  PHOTOSENSITIVE COMPOSITION, AND  PATTERN-FORMING METHOD USING THE  PHOTOSENSITIVE COMPOSITION \n(I) \nwherein R$^{1 }$to R$^{13 }$each independently represents a hydro› gen atom or a substituent; "}]}
+{"image": "doclay/doclay_46584.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "design is necessary to obtain the best results from these two  conflicting conditions. \nIn comparison, the rectangular wing has a tendency to stall  first at the wing root and provides adequate stall warning,  adequate aileron effectiveness, and is usually quite stable.  It is, therefore, favored in the design of low cost, low speed  airplanes. \nThe second means of changing the planform is by tapering  (decreasing the length of chord from the root to the tip of the  wing). In general, tapering causes a decrease in drag (most  effective at high speeds) and an increase in lift. There is also  a structural benefit due to a saving in weight of the wing. \nIf an aircraft were viewed in straight-and-level flight from the  front  [Figure 5-34],  and if the forces acting on the aircraft  could be seen, lift and weight would be apparent: two forces.  If the aircraft were in a bank it would be apparent that lift  did not act directly opposite to the weight, rather it now acts  in the direction of the bank. A basic truth about turns is that  when the aircraft banks, lift acts inward toward the center of  the turn, perpendicular to the lateral axis as well as upward. \nMost training and general aviation type airplanes are operated  at high coefficients of lift, and therefore require comparatively  high aspect ratios. Airplanes that are developed to operate at  very high speeds demand greater aerodynamic cleanness and  greater strength, which require low aspect ratios. Very low  aspect ratios result in high wing loadings and high stall speeds.  When sweepback is combined with low aspect ratio, it results  in flying qualities very different from a more conventional  high aspect ratio airplane configuration. Such airplanes  require very precise and professional flying techniques,  especially at slow speeds, while airplanes with a high aspect  ratio are usually more forgiving of improper pilot techniques. \nThe elliptical wing is the ideal subsonic planform since it  provides for a minimum of induced drag for a given aspect  ratio, though as we shall see, its stall characteristics in  some respects are inferior to the rectangular wing. It is also  comparatively difficult to construct. The tapered airfoil is  desirable from the standpoint of weight and stiffness, but  again is not as efficient aerodynamically as the elliptical  wing. In order to preserve the aerodynamic efficiency of the  elliptical wing, rectangular and tapered wings are sometimes  tailored through use of wing twist and variation in airfoil  sections until they provide as nearly as possible the elliptical  wing’s lift distribution. While it is true that the elliptical  wing provides the best coefficients of lift before reaching an  incipient stall, it gives little advance warning of a complete  stall, and lateral control may be difficult because of poor  aileron effectiveness. \nNewton’s First Law of Motion, the Law of Inertia, states that  an object at rest or moving in a straight line remains at rest  or continues to move in a straight line until acted on by some  other force. An aircraft, like any moving object, requires a  sideward force to make it turn. In a normal turn, this force  is supplied by banking the aircraft so that lift is exerted  inward, as well as upward. The force of lift during a turn is  separated into two components at right angles to each other.  One component, which acts vertically and opposite to the  weight (gravity), is called the “vertical component of lift.”  The other, which acts horizontally toward the center of the  turn, is called the “horizontal component of lift” or centripetal  force. The horizontal component of lift is the force that  pulls the aircraft from a straight flight path to make it turn.  Centrifugal force is the “equal and opposite reaction” of the  aircraft to the change in direction and acts equal and opposite  to the horizontal component of lift. This explains why, in a  correctly executed turn, the force that turns the aircraft is  not supplied by the rudder. The rudder is used to correct any  deviation between the straight track of the nose and tail of the  aircraft into the relative wind. A good turn is one in which the \nFigure 5-34.  Forces during normal, coordinated turn at constant altitude. \n5-22 \nLevel flight  Medium banked turn  Steeply banked turn  Centrifugal force  Horizontal  component  Vertical component  Resultant load Centrifugal force  Horizontal  component  Vertical component  Resultant load  Lift Total lift Total lift  Weight Weight Weight \nAerodynamic Forces in Flight Maneuvers \nForces in Turns "}]}
+{"image": "doclay/doclay_13847.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "ALLIANZ GROUP 28\nWe maintain the continuity of our dividend policy and propose to our shareholders at the Annual General Meeting to distribute a dividend of 1.50 euros per share for 2003, unchanged from last year. Due to the higher number of Allianz shares, the divi- dend payout will increase 47 percent to 551 million euros.\nIn a voluntary public offer, we invited the holders of Allianz profit participation certificates to exchange their certificates for Allianz shares. This offer was designed to restructure our capi- tal. The exchange was completed in January and ended with a satisfactory acceptance ratio of 86 percent. We issued a total of 6.1 million shares from treasury stock to holders of profit par- ticipation certificates. Additional information on the exchange of profit participation certificates is provided on pages 139 and 140 of this Annual Report. Following this offer, the terms for the certificates still outstanding remain in force. We do not intend to issue a call for their redemption as of December 31, 2006.\nThe higher free float and the capital increase also led to a rise of the number of shareholders, from 510,000 to over 570,000. Trading volumes went up as well. On an average day, approxi- mately 3.9 million Allianz shares are bought and sold through the electronic trading system Xetra. That put the trading vol- ume of our share in second position among the thirty DAX stocks.\nSince the end of 2000, Allianz shares have also been traded on the New York Stock Exchange in the form of American Depositary Receipts (ADR). Ten ADRs are the equivalent of one Allianz share. \nThe free float percentage of our share continued to rise in 2003, from 71 percent in the previous year to the current 83 percent. The increase is mainly attributable to Munich Re, which reduced its stake in Allianz from about 20 percent to close to 12 percent. This makes Allianz one of the largest publicly held corporations in Europe. A higher free float percentage raises the liquidity of our share and upgrades its weighting in most major indexes. Up-to-date information on our shareholder structure is available on the Internet at www.allianzgroup.com/investor-relations.\nFree float now over 83 percent\nPublic offer to holders of profit participation certifi- cates \nShareholder structure on December 31, 2003 Free float: 83 %, Long-term investments: 17 % Private investors Investment companies Other institutional investors Munich Re Treasury shares 17 (13) % 22 (16) % 5 (9) % 12 (20) % 44 (42) % Source: Allianz AG share register\nRegional distribution of share ownership on December 31, 2003 58 (68) % 32 (25) % 9 (6) % 1 (1) % Germany Asia-Pacific Region, Africa Rest of Europe North and South America Source: Allianz AG share register\nTotal dividend and dividend per share 0 0.3 0.6 0.9 1.2 1.5 1.8 100 0 200 300 400 500 600 1999 1.25 307 2000 1.50 367 2001 1.50 364 2002 1.50 374 2003 1.50 551 Total dividend in  ¤mn Dividend per share in  ¤\nHigher dividend payout"}]}
+{"image": "doclay/doclay_69084.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "In the Certificate Viewer, which is shown in Figure 11, click the Details tab and select the root  2. certificate.\nClick Export at the lower left of the Certificate Viewer window (Figure 11). 3.\nSave the file with a  .crt  or  .pem  extension, then close the Certificate Viewer and Security exception  4. windows. Open the Firefox Options menu, as shown in Figure 12.\nFigure 11. Firefox Certificate Viewer\nFigure 12. Selecting the Firefox Options menu\nConfiguring your browser for trusted HTTPS connections to IBM Content Navigator and Box\n8\nFigure 11. Firefox Certificate Viewer\nFigure 12. Selecting the Firefox Options menu"}]}
+{"image": "doclay/doclay_35514.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "0 0.2 0.4 0.6 0.8 1 0 0.2 0.4 0.6 0.8 1 0 0.1 0.2 0.3 0.4 0.5 0.2 0.4 0.6 0.8 1 0 0.1 0.2 0.3 0.4 0.5 0.2 0.4 0.6 0.8 1 p$_{k}$ −theory P ( k,k’ )−theory Numerical simulation  on original network (a) Facebook Oklahoma (b) AS Internet (c) PGP Network (d) Power Grid µ ρ\n4\nedge [23] has smaller absolute values for the networks shown in panels (a) and (d) (0.074, with the mean 0.063 over 100 Facebook networks, and 0.0035, respectively) than it does for the networks in (b) and (c) ( − 0 . 2 and 0.24, respectively).\n(We use K to denote this maximal value of k .) For Fig. 2(a) and (b), we obtain K$_{P}$$_{(}$$_{k,k}$ ′ $_{)}$/K$_{num}$ ≈ 0 . 916 and K$_{P}$$_{(}$$_{k,k}$ ′ $_{)}$/K$_{num}$ ≈ 0 . 826, respectively. The corresponding values for Fig. 2(c) and (d) are K$_{P}$$_{(}$$_{k,k}$ ′ $_{)}$/K$_{num}$ ≈ 0 . 516 and K$_{P}$$_{(}$$_{k,k}$ ′ $_{)}$/K$_{num}$ ≈ 0 . 368.\nWatts [36] introduced a simple model for the spread of cultural fads. It allows one to examine how a small initial fraction of early adopters can lead to a global cas- cade of adoption via a social network. The p$_{k}$ -theory and P ( k, k $^{′}$)-theory for the average cascade size are given, re- spectively, in Ref. [37] and Ref. [35]. In Fig. 3, we com- pare these theories with numerical simulations on popu- lations with Gaussian threshold distributions of mean µ and variance σ 2 = 0 . 04. The cascade size shows a sharp transition as µ is increased. As with the other processes that we discussed above, the position of this transition is accurately captured by the theory for the Facebook and AS Internet networks but not for the other examples.\nFigures 2, 3, and 4 show similar comparisons of analyt- ical results versus numerical simulations for other well- studied processes on networks. In Fig. 2, we plot the k -core sizes of the networks. The k -core is the largest subgraph whose nodes all have degree at least k . The p$_{k}$ -theory for k -core sizes is given in Ref. [34] and the P ( k, k $^{′}$)-theory is given by Eq. (32) of Ref. [35]. As shown in Fig. 2(a,b), we again find very good agree- ment of P ( k, k $^{′}$)-theory with numerical calculations on the AS Internet and Facebook networks and less accu- rate results for the other example networks. This can be quantified by comparing the actual (numerical) result for the highest value of k for which the k -core size is nonzero to the value that is predicted by P ( k, k $^{′}$)-theory.\nFIG. 3: (Color online) Watts’ threshold model, with threshold mean µ and variance σ 2 = 0 . 04 for the networks from Fig. 1. We use the seed fraction ρ$_{0}$ = 0 because the nodes with negative thresholds immediately turn on and act as initial seeds. In other words, the effective seed fraction is given by the cumulative distribution of thresholds at zero: [ 1 + erf ($_{−}$ µ/ ( $_{σ}$√$_{2}$ ))] / 2.\nB. k -Cores\nC. Watts’ Threshold Model"}]}
+{"image": "doclay/doclay_37579.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "In the table below the minimum service level requirements (SLRs) listed are accompanied by a penalty scheme to be activated in case of  breaches of the agreed minimum requirements / service levels. While the table reports the minimum required performance (column C), the  contractor has the opportunity to propose better values (in the column F).\nDepending on the proposal provided (column F) the tenderer can get additional award points (see column H for calculation details) up to a  maximum award score value (column G). \nThe maximum awarding score achievable with the proposed service level requirement values is equal to  60 points . \nThe reference calendar for the calculation of the working days (including the business hours for a working day) will be agreed at the kick- off meeting after signature of the framework contract. \nDuring a grace period of 2 months, following the signature of the framework contract, the penalties will not be applied. \n27 \nID  A)  Performance  area  B)  Performance  indicator  name  C) Minimum required  performance  D) Measuring and follow up E) Penalty F) Performance  proposed by the  contractor G)  Award  score  H) Resulting score SLR-1  All  Time to sign  the order  form  (OF)/specific  contract (SC)  The contractor must sign  an OF/SC within 5 wdays  (working days)  from  EFSA’s  email  request.  At the end of each year of the FWC  implementation, EFSA and the Contractor  (separately) will count the number of days of delay  which occurred in the given year. EFSA will inform the contractor of the penalty sum. The contractor will deduct the penalty sum, if any,  from any upcoming invoice to be issued.  50  € for each  day of delay  Insert here your  proposal as a  value between 1 and 5 15  Award score  (G)  x Best proposed  performance /  Contractor  proposed  performance  (F)  SLR-2  All  Time to reply  to an order  form/specific  contract  The contractor must reply  with an offer within 5 wdays from  EFSA’s  email  request.  At the end of each year of the FWC  implementation, EFSA and the Contractor  (separately) will count the number of days of delay  which occurred in the given year. EFSA will inform the contractor of the penalty sum  10 working days before the yearly meeting. The contractor will deduct the penalty sum, if any,  from any upcoming invoice to be issued.  50  € for each  day of delay  Insert here your  proposal as a  value between 1 and 5 15  Award score  (G)  x Best proposed  performance /  Contractor  proposed  performance  (F) "}]}
+{"image": "doclay/doclay_12388.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "36\nConsolidated Statements of Cash Flows\nThe accompanying notes are an integral part of these statements. \nYear ended June 30  (in thousands) 2002 2001 2000 Operating Activities Net (loss) income $ (211,908) $ 53,288 $ 51,710  Adjustments for non-cash items: Depreciation 70,825 73,163 75,194 Amortization 2,804 24,134 26,452 Loss on divestitures 3,522 5,781 – Restructuring and asset impairment charges 12,712 4,325 6,378 Cumulative effect of change in accounting principles,  net of tax 250,406 599 – Loss on early extinguishment of debt, net of tax – – 267 Other 2,485 12,362 11,472 Changes in certain assets and liabilities,  net of effects of acquisition and divestitures: Accounts receivable 33,603 9,620 (17,257) Proceeds from accounts receivable securitization 2,200 5,200 6,500 Inventories 40,251 19,894 14,331 Accounts payable and accrued liabilities (29,033) (827) 44,968 Other (22,707) (19,983) 1,192 Net cash flow from operating activities 155,160 187,556 221,207  Investing Activities  Purchases of property, plant and equipment (44,040) (59,929) (50,663)  Disposals of property, plant and equipment 10,905 4,227 8,109  Divestitures, net of cash 3,309 729 –  Purchase of subsidiary stock (1,161) (47,505) – Acquisition of business assets (5,385) – – Investment in affiliates (5,770) – – Other (1,129) (26) (531) Net cash flow used for investing activities (43,271) (102,504) (43,085) Financing Activities  Net (decrease) increase in notes payable (4,778) 4,038 (18,491)  Net decrease in revolving and other lines of credit (84,151) (78,905) (15,100)  Term debt borrowings 549,950 1,216 378  Term debt repayments (677,563) (2,941) (129,810)  Net proceeds from issuance of capital stock 120,584 – – Dividend reinvestment and employee benefit and stock plans 23,269 22,854 11,276 Purchase of treasury stock (12,417) (16,494) –  Cash dividends paid to shareowners (21,426) (21,056) (20,570) Financing fees (10,448) – – Other (1,268) (949) (1,018)  Net cash flow used for financing activities (118,248) (92,237) (173,335) Effect of exchange rate changes on cash and equivalents 3,804 (2,198) 128  Cash and Equivalents Net (decrease) increase in cash and equivalents (2,555) (9,383) 4,915  Cash and equivalents, beginning of year 12,940 22,323 17,408  Cash and equivalents, end of year $ 10,385 $ 12,940 $ 22,323  Supplemental Disclosures  Interest paid (net of amount capitalized) $ 33,861 $ 51,480 $ 55,000  Income taxes paid 31,949 36,608 17,092 Contribution of stock to employee benefit plans 9,405 13,364 9,170 Notes received from sale of subsidiaries 4,587 5,809 –"}]}
+{"image": "doclay/doclay_17320.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "Consolidated Statements of Earnings\nGENERAL MILLS, INC. AND SUBSIDIARIES\n47\nAnnual Report 2010\n(In Millions, Except per Share Data) 2010 2009 2008 Fiscal Year ........................................................................................ ............................................................................................................................................................................................................................................................................................................................................................................................ Net sales $14,796.5 $14,691.3 $13,652.1 Cost of sales 8,922.9 9,457.8 8,778.3 Selling, general, and administrative expenses 3,236.1 2,951.8 2,623.6 Divestitures (gain), net — (84.9) — Restructuring, impairment, and other exit costs 31.4 41.6 21.0 ............................................................................................................................................................................................................................................................................................................................................................................................ Operating profit 2,606.1 2,325.0 2,229.2 Interest, net 401.6 382.8 399.7 ............................................................................................................................................................................................................................................................................................................................................................................................ Earnings before income taxes and after-tax earnings from joint ventures 2,204.5 1,942.2 1,829.5 Income taxes 771.2 720.4 622.2 After-tax earnings from joint ventures 101.7 91.9 110.8 ............................................................................................................................................................................................................................................................................................................................................................................................ Net earnings, including earnings attributable to noncontrolling interests 1,535.0 1,313.7 1,318.1 Net earnings attributable to noncontrolling interests 4.5 9.3 23.4 ............................................................................................................................................................................................................................................................................................................................................................................................ Net earnings attributable to General Mills $ 1,530.5 $ 1,304.4 $ 1,294.7 Earnings per share – basic $ 2.32 $ 1.96 $ 1.93 Earnings per share – diluted $ 2.24 $ 1.90 $ 1.85 Dividends per share $ 0.96 $ 0.86 $ 0.78\nSee accompanying notes to consolidated financial statements."}]}
+{"image": "doclay/doclay_52275.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Installing Python Modules, Release 3.9.5\nC.3.6 UUencode and UUdecode functions\nC.3.7 XML Remote Procedure Calls\nC.3. Licenses and Acknowledgements for Incorporated Software\n33\nThe$_{uu}$module contains the following notice:\nCopyright 1994 by Lance Ellinghouse Cathedral City, California Republic, United States of America.\nAll Rights Reserved\nPermission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Lance Ellinghouse not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission.\nLANCE ELLINGHOUSE DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL LANCE ELLINGHOUSE CENTRUM BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.\nModified by Jack Jansen, CWI, July 1995:\nThe$_{xmlrpc.client}$ module contains the following notice:\nThe XML-RPC client interface is\nCopyright (c) 1999-2002 by Secret Labs AB\nCopyright (c) 1999-2002 by Fredrik Lundh\nBy obtaining, using, and/or copying this software and/or its associated documentation, you agree that you have read, understood, and will comply with the following terms and conditions:\nPermission to use, copy, modify, and distribute this software and its associated documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appears in all copies, and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Secret Labs AB or the author not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission.\nSECRET LABS AB AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANT- ABILITY AND FITNESS. IN NO EVENT SHALL SECRET LABS AB OR THE AUTHOR BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.\n- Use binascii module to do the actual line-by-line conversion between ascii and binary. This results in a 1000-fold speedup. The C version is still 5 times faster, though.\n- Arguments more compliant with Python standard"}]}
+{"image": "doclay/doclay_59686.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Verifying Package Integrity Using MD5 Checksums or GnuPG\nWJp79oBIWwnW/84RbxutRoEwSar/TLwVRkcZyRXeJTapbnLGnQ/lDO1o1d7+Vbjd q/Sg/cKHHf7NthCwkQNsCnHL0f51gZCJASIEEAECAAwFAkqoEAAFAwASdQAACgkQ lxC4m8pXrXwE/Af/XD4R/A5R6Ir/nCvKwCTKJmalajssuAcLEa2pMnFZYO/8rzLO +Gp8p0qFH9C4LFwA0NvR5q6X/swuROf4zxljSvNcdlQVaAfJ2ZDEgJ5GXzsPplrv SAI9jS3LL7fSWDZgKuUe0a4qx7A0NgyGMUYGhP+QlRFa8vWEBI9fANd/0mMqAeBV qQyOH0X1FiW1Ca2Jn4NKfuMy9GEvRddVIbB1LvoNVtXPNzeeKMyNb9Jdx1MFWssy COBP2DayJKTmjvqPEc/YOjOowoN5sJ/jn4mVSTvvlTooLiReSs6GSCAjMVxN7eYS /Oyq6Iu1JDcJvmB8N2WixAZtAVgF8OA7CWXKVYkBIgQQAQIADAUCSrnHiQUDABJ1 AAAKCRCXELibyletfPChB/9uECti1dZeNuFsd0/RuGyRUVlrrhJE6WCcOrLO9par rPbewbKBmjSzB0MygJXGvcC06mPNuquJ7/WpxKsFmfg4vJBPlADFKtgRUy9BLzjC eotWchPHFBVW9ftPbaQViSUu7d89NLjDDM5xrh80puDIApxoQLDoIrh3T1kpZx56 jSWv0gelFUMbXAzmqkJSyL4Xdh1aqzgUbREd7Xf2ICzuh0sV6V7c/AwWtjWEGEsA HZaiQDywZwbC18GwrMLiAzGWb/AScFDQRCZKJDjL+Ql8YT6z+ZMVr8gb7CIU5PKY dhiIf2UVTQwLAoW7lNRCQQAqcGjK3IMIz7SO/yk4HmVUiQEiBBABAgAMBQJK3gjG BQMAEnUAAAoJEJcQuJvKV618jkEH+wb0Zv9z7xQgpLMowVuBFQVu8/z7P5ASumyB PUO3+0JVxSHBhlCKQK7n11m1fhuGt2fCxXhSU6LzXj36rsKRY53lGZ9QhvqFUtQH 3Xb2IQLIJC4UKjG2jSSCdcuA/x98bwp2v7O03rn7ndCS16CwXnRV3geQoNipRKMS DajKPpZv1RiZm8pMKqEb8WSw352xWoOcxuffjlsOEwvJ85SEGCAZ9tmIlkZOc7Ai QONDvii9b8AYhQ60RIQC0HP2ASSmK0V92VeFPxHmAygdDQgZNVtbVxgnnt7oTNEu VRXNY+z4OfBArp7R+cTsvijDRZY4kML1n22hUybwoxUEvjqZV2+JASIEEAECAAwF AkrvOlQFAwASdQAACgkQlxC4m8pXrXxrPAgArXiNgZirNuBhfNCXlkzkCHLx5wnV e4SmTpbWzTwWw7+qk7d4l9hlWtdImISORINzo7f4ShSUzJX2GciNaXhaHRo7+y5O Zbu82jQb09aQQj/nibKYuqxqUrobTEm+DuYz3JUQZm2PsPcHLS8mX9cxvrJUncPG nXEV0DRaq71SGWDprtkvBbp6i38aY3sIhYgz8wM5m1szKDtjywmBYcFehIdozt9z hm7wZshzRWQX1+Rf/pIsnk+OzBIa34crSemTnacbV/B7278z2XAyziPNFuqz0xu+ iltOmYmayfNWAmumuw9NcuwWMlth6Mc2HLrpo0ZBheJ6iuDMPsHnwqdB/4kBIgQQ AQIADAUCSwBd2gUDABJ1AAAKCRCXELibyletfP6tB/4m1w0BtlkJgtS6E+B/ns14 z4A4PGors+n+MYm05qzvi+EnDF/sytCmVcKeimrtvDcfoDtKAFFvJjcYXfnJdGWm Pu0SJMRL5KKCirAKwZmU/saxOgoB5QLNw+DHPteJ3w9GmWlGxIqG1r15WC5duzBC y3FsnjJYG3jaLnHOO9yXXb5h0kUTORfUKdvAr1gxF2KoatZWqGoaPPnHoqb88rjt zk8I7gDqoXnzh8wLxa0ZYvfTC/McxdWTrwXLft+krmMQ18iIZEne2hvVLNJVuluU oiWLeHA8iNCQ4W4WTdLc1mCnCjGTMX/MN41uLH0C9Ka4R6wEaqj4lPDk1B/1TV+Q iQEiBBABAgAMBQJLEYGrBQMAEnUAAAoJEJcQuJvKV618naIH/2t9aH5mBTKBN6fU qhrf79vIsjtI/QNS5qisBISZMX3/1/0Gu6WnxkPSfdCUJMWCjMcnVj7KU2wxTHHG VpAStd9r2afUNxRyqZwzwyytktuZok0XngAEDYDDBS3ssu2R4uWLCsC2ysXEqO/5 tI5YrTWJZrfeIphTaYP5hxrMujvqy3kEwKKbiMz91cDeiLS+YCBcalj5n/1dMYf7 8U8C6ieurxAg/L8h6x25VM4Ilx4MmG2T8QGtkkUXd+Fd/KYWmf0LE5LLPknf0Hhw oVslPXeinp4FsHK/5wzviv4YZpzuTqs9NlKcMsa4IuuPOB0FDf0pn+OFQbEg9QwY 2gCozK+JASIEEAECAAwFAksjTdQFAwASdQAACgkQlxC4m8pXrXwlogf/XBGbXRVX LMaRN4SczOjwT3/tUCriTkb3v+zKjRG90zFhYAccjn7w+7jKQicjq6quQG1EH2X4 /Su6ps1lDLqGHHhiJW3ZhxQScLZmhdAYsh2qG4GP/UW3QjXG7c61t+H3olvWg2cr wqCxxFZAgkAAkr9xcHWFZJEQeXoob6cCZObaUnHSANdmC6s5lUxXYa2bmL7Q3UB4 4KCzDvAfbPZKJOw9k0qb3lc11zx+vGdyZFbm4R0+3LPp/vT0b3GlSbbF9lU1GOXh VaphrgFFa76dmjfHCkPplXAkK1VSIU/aPGAefduTFMdlSZpdMtJ5AULjGcszBDlR pLlPxvqVa0ZpgIkBIgQQAQIADAUCSycmkgUDABJ1AAAKCRCXELibyletfHlNCACp 1YespiHfQt2alcscE5zgfETEHHic8Ai6pNkU9HT4TeWcFHEDe5QqfYcpjLrQvBXS kSvxEittbyRdv+e+j5Z+HyHjiG8nAQBL6qy9eHqQE4+d7gYs6DTk7sG9ZMYphREb ltzD+F4hVCQdLT8LNr0eVFN7ehqECScDaCG8/Qyti+l/0M902/Yn+mz0ilOiUdWJ 9x6LPaIINtb1gsYDEylLjwGIZmI0r5Kh9wYoV4vnNezFbxO1uRiW0B7iaPjIEsbt OOKp7wx2aX+DM3N9F3BtaIY8XnzcnomNm83SNsgmgrZljpQltUnNqIhNM8DupQ+I WOV5gtl6pTC7CgeVTVyRiQEiBBABAgAMBQJLOGXuBQMAEnUAAAoJEJcQuJvKV618 ll4IAKJ9mm4jb0c8fe9+uDI8eCJRbzNbVXm8zWzpA8GUtQAakwxoKv332QP1Wa1P odni/e3EMhsSREOZJJv79YqGxGRBTE9Kb/VjM34nas4XSnXKW28XWhKyIw+XwQAi nY2swFHh+83Htr/mwTdJfS2aEYl2zboBvd/JZCdhOGU2GH737S/3uEczoKkfVQ/w OTM8X1xWwlYWqx23k/DsGcuDs9lA2g7Mx7DSqBtVjaTkn9h0zATzXLDkmP4SAUVj cZ83WDpFre5WnizZjdXlBMM5OCexp5WpmzyHLTnaBFK4jEmnsk5C2Rnoyp8Ivz6g Ecg1tRbEXijRw++d2TFYlJwLKtiJASIEEAECAAwFAktKMicFAwASdQAACgkQlxC4 m8pXrXxqHQgAuYY5scKrh0m/GS9EYnyC9494lOlO6iytU0CpE6oBC31M3hfX/Dbj UbcS5szZNU+2CPYo4ujQLZ7suN7+tTjG6pZFfMevajT9+jsL+NPMF8RLdLOVYmbl TmSQGNO+XGEYaKYH5oZIeIW5AKCgi2ozkdFlBBLAx7Kqo/FyybhkURFEcvEyVmgf 3KLV7IIiX/fYLfoCMCJ/Lcm9/llSFB1n8Nvg66Xd533DKoHjueD3jyaNAVlo2mq/ sIAv++kntvOiB3GDK5pfwHZ78WWiCpsWZpE5gzAnzJ1Y0WEigRo0PVLu3cLO0jLG 23d+H/CbfZ8rkajHJeCDQF7YVmP0t0nYpYkBIgQQAQIADAUCS1v+ZgUDABJ1AAAK CRCXELibyletfNS/CACqt2TkB86mjqM+cJ74+dWBvJ2aFuURuxzm95i9Q/W/hU08 2iMbC3+0k2oD8CrTOe61P+3oRyLjv/UEDUNzLncNe2YsA9JeV+4hvPwH5Vp3Om13 089fCKZUbqslXNKkHiWYU+zAaZJXEuGRmRz0HbQIeAMOWF4oa226uo1e4ws1Jhc+ F3E/ApCRyFBqBUdL05hapQLditYpsBjIdiBGpjzidMLE2wX2W4ZpAdN0U6BIyIqR\n104"}]}
+{"image": "doclay/doclay_35831.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "\nFIG. 5: (Color online) Spin collinearity P [Eq. (19)] at h = 0 for b = 0 . 1 , showing the onset of nematic order at T Q ≈ 0 . 13 . P is measured for the farthest spin pair along the 〈 110 〉 chains in the py- rochlore lattice in each system size ranging from L = 4 to L = 16 , and averaged over the 〈 110 〉 chains running in different directions.\n7FIG. 4: (Color online) (a) Illustration of collinear E –symmetry ne- matic state at h = 0 , showing loop–like coordination of parallel spins associated with the “ice” manifold. (b) Four–sublattice lo ng range order with E symmetry induced by FM J$_{3}$ . (c) Canted nematic state with partial magnetization under applied field.\nof the tetrahedral symmetry group T $_{d}$, defined in Sec. II B, and that local fluctuations of order λ local E take on their maximal value λ local E = 16 / 3 . This concludes our survey of symmetry breaking for T = 0 ,\nE This concludes our survey of symmetry breaking for T = 0 , but it leaves open the question, what happens at finite tem- perature? By analogy with ordered systems where “order from disorder” is effective, thermal fluctuations might be e x- pected to select a single configuration from the “ice” mani- fold, and so restore N´eel order. To address this question, we have performed extensive Monte Carlo simulations using a local–update Metropolis algorithm to sample spin configura - tions. We typically perform 10 6 MC samplings for measure- ments after 10 5 steps for thermalization. We have checked the convergence of the results by comparing those for different initial spin configurations. In particular, to minimize thehys- teresis associated with first order transitions, we used mix ed initial conditions in which different parts of the system are assigned different ordered or disordered states$^{32}$. Where the acceptance rate in MC updates becomes extremely slow, we used the exchange MC method$^{33}$, to avoid local spin-freezing at low temperatures. Results are divided into five bins to es- timate statistical errors by variance of average values in the bins. The system sizes in the present work are up to L = 16 , where L is the linear dimension of the system measured in the cubic units shown in Fig. 1, i.e., the total number of spins N is given by 16 L $^{3}$. We show the results for b = 0 . 1 and b = 0 . 6 , case by case, both of which exhibit qualitatively the same behavior.\nIn the absence of applied magnetic field, the spin collinear- ity P ( r ) grows sharply below a transition temperature T$_{Q}$ ≈ b , as illustrated in Fig. 5. As expected, for T → 0 , P ( r ) → 1 , implying that all spins have a single common axis. The nematic order parameter Q [Eq. (18)] is plotted in Fig. 6(a), together with the heat capacity in Fig. 6(b) for a range of system sizes from L = 4 to L = 16 . Here the heat capacity is calculated by the fluctuation of internal energyas\ndictated by this effective electrodynamics. This power–la w decay of spin correlations is a signal property of the “ice” manifold. However it should not be taken to imply that “up” and “down” spins are entirely uncorrelated. Within each uudd tetrahedron, each spin has twice as many AF aligned neigh- bors as FM aligned ones, and the net correlation on nearest neighbor bonds is\nLocally, order is well formed. More formally, we can state that these uudd tetrahedra belong to the two–dimensional E irrep\nC$_{v}$ = 〈H $^{2}$〉 − 〈H〉2 T $^{2}$N . (31)\n〈 S$_{i}$ . · S$_{j}$ 〉 n . n . = − 1 3 . (30)"}]}
+{"image": "doclay/doclay_67782.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Draft Document for Review February 7, 2020 3:15 pm\n8464ch09_Oper.fm\n– Expires: The expiration status of the feature license. The following values are possible:\nGLYPH<129> Day/Date: The day and date on which  the feature license is set to expire.\nGLYPH<129> Never: The feature is permanently active and never expires.\nGLYPH<129> One-time use: The feature can be used once and has not yet been used.\nGLYPH<SM590000> Copy Policy Override: Select this option to back up the settings to override local copy and  I/O policies.\nGLYPH<SM590000> SNMP: Select this option to back up the settings for SNMP.\nGLYPH<SM590000> Write Protect Mode Categories: Select this option to back up the settings for write protect  mode categories.\nImportant:  If the user navigates away from this window while the backup is in progress,  the backup operation is stopped and the operation must be restarted. \nTo back up cluster settings, select any of the previous settings and then, click  Download . A  window opens to show that the backup is in progress.\nWhen the backup operation is complete, the backup file  ts7700_cluster< cluster ID >.xmi  is  created. This file is an XML Meta Interchange file. The user is prompted to open the backup  file or save it to a directory. Save the file. When prompted to open or save the file to a  directory, save the file without changing the  .xmi  file extension or the file contents. \nAny changes to the file contents or extension can cause the restore operation to fail. The user  can modify the file name before saving it if the user wants to retain this backup file after  subsequent backup operations.\nNote:  If the user chooses to open the file, do not use Microsoft Excel to view or save it.  Microsoft Excel changes the encoding of an XML Meta Interchange file, and the changed  file is corrupted when used during a restore operation.\nThe following settings are not available for backup or recovery:\nGLYPH<SM590000> User accounts\nGLYPH<SM590000> Security policies\nGLYPH<SM590000> Grid identification policies\nGLYPH<SM590000> Cluster identification policies\nGLYPH<SM590000> Grid communication encryption (SDT)\nGLYPH<SM590000> SSL certificates\nRecord these settings in a safe place and recover them manually, if necessary.\nFor more information about backup settings, see IBM Knowledge Center.\nRestore Settings window \nUse this window to restore the settings from a TS7700 cluster to a recovered or new cluster.\nNote:  Backup and restore functions are not supported between clusters that are operating  at different code levels. Only clusters that are operating at the same code level as the  current cluster can be selected from the Current Cluster Selected graphic. Clusters that are  operating at different code levels are visible (but not available) in the graphic.\nFor more information about Backup and Restore settings reference, see Table 9-11 on  page 498. \nChapter 9. Configuring and operating the IBM TS7700  501"}]}
+{"image": "doclay/doclay_49679.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "７． 石油 給湯機 7. Oil-fired  Water  Heaters  １ 日本産業規格Ｓ３０３１（２００９）石油燃焼機器の試験方法 通則（以下「ＪＩＳ試験通則」という。）６．１．１に定める温度 条件を満たした試験室（以下「ＪＩＳ試験室」という。）におい て、ＪＩＳ試験通則６．７に定める燃焼排ガス中の一酸化炭素の二 酸化炭素に対する比（ＣＯ／ＣＯ２）の測定方法（以下「石油燃焼 機器のＣＯ／ＣＯ２の測定方法」という。）による測定を行つたと き、測定値が０．０１以下であること。 1 When, in a testing laboratory that meets the temperature  conditions specified in JIS S3031 (2009) General Rules for Test  Methods of Oil Burning Appliances (hereinafter referred to as  the \"General Rules for JIS Tests\") 6.1.1 (such laboratory is  hereinafter referred to as a \"JIS Laboratory\"), measurement is  taken by the method for measuring the ratio of carbon monoxide  to carbon dioxide (CO/CO2) in the combustion exhaust gas as  specified in the General Rules for JIS Tests 6.7 (hereinafter  referred to as the \"CO/CO2 Measuring Method for Oil-fired  Water Heaters\"), the measurement value is no more than 0.01.  ２ ＪＩＳ試験室において、ＪＩＳ試験通則６．１、６．２の ｅ）、ｆ）及びｉ）に定める各部の温度上昇試験を行つたとき、次 に掲げる条件に適合すること。 2 When a temperature rise test is conducted for each part as  specified in the General Rules for JIS Tests 6.1 and 6.2 e), f),  and i) in a JIS Laboratory, the results meet the following  conditions.  （１） 機器下面及び周辺の木台の表面温度と室温との差が６５度 以下であること。 (1) The difference between the room temperature and the  surface temperature of the wooden stand below and around the  heater is no more than 65 degrees.  （２） 機器上面、側面（背面を含む。）及び前面の木壁の表面温 度と室温との差が６５度以下であること。 (2) The difference between the room temperature and the  surface temperature of the wooden walls above, at the sides  (including at the back), and in front of the heater is no more  than 65 degrees.  （３） 機器本体と一体の油タンクにあつては、油タンクの表面温 度と室温との差が２５度以下であること。 (3) Where the oil tank is combined with the heater body, the  difference between the room temperature and the surface  temperature of the oil tank is no more than 25 degrees.  （４） 油温と室温との差が２５度以下であること。 (4) The difference between the room temperature and the oil  temperature is no more than 25 degrees. \n58 "}]}
+{"image": "doclay/doclay_53626.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "CREATE TABLE Statement\nin the  COLUMNS  clause and a set of column values in each  PARTITION ... VALUES LESS THAN ( value_list )  partition definition clause. (In the simplest case, this set consists of a single column.) The maximum number of columns that can be referenced in the  column_list  and  value_list  is 16.\nThe  column_list  used in the  COLUMNS  clause may contain only names of columns; each column in the list must be one of the following MySQL data types: the integer types; the string types; and time or date column types. Columns using  BLOB ,  TEXT ,  SET ,  ENUM ,  BIT , or spatial data types are not permitted; columns that use floating-point number types are also not permitted. You also may not use functions or arithmetic expressions in the  COLUMNS  clause.\nThe  VALUES LESS THAN  clause used in a partition definition must specify a literal value for each column that appears in the  COLUMNS()  clause; that is, the list of values used for each  VALUES LESS THAN  clause must contain the same number of values as there are columns listed in the  COLUMNS clause. An attempt to use more or fewer values in a  VALUES LESS THAN  clause than there are in the COLUMNS  clause causes the statement to fail with the error  Inconsistency in usage of column lists for partitioning... . You cannot use  NULL  for any value appearing in  VALUES LESS THAN . It is possible to use  MAXVALUE  more than once for a given column other than the first, as shown in this example:\nEach value used in a  VALUES LESS THAN  value list must match the type of the corresponding column exactly; no conversion is made. For example, you cannot use the string  ’1’  for a value that matches a column that uses an integer type (you must use the numeral  1  instead), nor can you use the numeral  1 for a value that matches a column that uses a string type (in such a case, you must use a quoted string: ’1’ ).\nFor more information, see Section 24.2.1, “RANGE Partitioning” , and Section 24.4, “Partition Pruning” .\nThis is useful when assigning partitions based on a table column with a restricted set of possible values, such as a state or country code. In such a case, all rows pertaining to a certain state or country can be assigned to a single partition, or a partition can be reserved for a certain set of states or countries. It is similar to  RANGE , except that only  VALUES IN  may be used to specify permissible values for each partition.\nVALUES IN  is used with a list of values to be matched. For instance, you could create a partitioning scheme such as the following:\nCREATE TABLE rc ( a INT NOT NULL, b INT NOT NULL ) PARTITION BY RANGE COLUMNS(a,b) ( PARTITION p0 VALUES LESS THAN (10,5), PARTITION p1 VALUES LESS THAN (20,10), PARTITION p2 VALUES LESS THAN (50,MAXVALUE), PARTITION p3 VALUES LESS THAN (65,MAXVALUE), PARTITION p4 VALUES LESS THAN (MAXVALUE,MAXVALUE) );\nCREATE TABLE client_firms ( id INT, name VARCHAR(35) ) PARTITION BY LIST (id) ( PARTITION r0 VALUES IN (1, 5, 9, 13, 17, 21), PARTITION r1 VALUES IN (2, 6, 10, 14, 18, 22), PARTITION r2 VALUES IN (3, 7, 11, 15, 19, 23), PARTITION r3 VALUES IN (4, 8, 12, 16, 20, 24)\n2564\n• LIST( expr )"}]}
+{"image": "doclay/doclay_9928.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "notes to  consolidated  financial  statements\nTyson Foods, Inc. 2002 annual report\np 40\nIncluded in current debt are short-term notes payable totaling $37 million and $18 million at September 28, 2002, and September 29, 2001, respectively.\nThe Company has fully and unconditionally guaranteed $541 million of senior notes issued by IBP, a wholly-owned subsidiary  of the Company.\nThe following condensed consolidating financial information is provided for the Company, as guarantor, and for IBP, as issuer,  as an alternative to providing separate financial statements for the issuer.\nFinancial results of the live swine operations, as well as interest expense related to the IBP acquisition are included in the Tyson amounts.\nCondensed Consolidating Statement of Income for the year ended September 28, 2002\nin millions Tyson IBP Adjustments Consolidated Sales $7,848 $15,563 $(44) $23,367 Cost of Sales 6,900 14,694 (44) 21,550 948 869 – 1,817 Operating Expenses: Selling, general and administrative 509 368 877 Other charges 26 27 53 Operating Income 413 474 887 Interest and Other Expense 243 51 294 Income Before Income Taxes and Minority Interest 170 423 593 Provision for Income Taxes 53 157 210 Minority Interest – Net Income $ 117 $ 266 $ – $ 383\nin millions Tyson IBP Adjustments Consolidated Sales $7,520 $ 3,048 $ (5) $10,563 Cost of Sales 6,764 2,901 (5) 9,660 756 147 – 903 Selling, General and Administrative 510 77 587 Operating Income 246 70 316 Interest and Other Expense 135 16 151 Income Before Income Taxes and Minority Interest 111 54 165 Provision for Income Taxes 40 18 58 Minority Interest 1 18 19 Net Income $ 70 $ 18 $ – $ 88\nCondensed Consolidating Statement of Income for the year ended September 29, 2001"}]}
+{"image": "doclay/doclay_69985.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Draft Document for Review September 23, 2019 1:36 am\n8860ch02.fm\n2.8.6 Defining Network\nOpen Systems Adapter (OSA)\nShared Memory Communications - RDMA\nThis section provides planning considerations for deploying the network-related features:\nGLYPH<SM590000> OSA features\nGLYPH<SM590000> Shared Memory Communications (SMC-R and SMC-D) features:\n– SMC - RDMA over Converged Ethernet (RoCE) Express features (SMC-R)\n– SMC - Direct Memory Access over Internal Shared Memory (SMC-D)\nGLYPH<SM590000> HiperSockets\nGLYPH<SM590000> Copper-based Ethernet (1000 Mbps)\nGLYPH<SM590000> Fiber-based Gigabit Ethernet (GbE), Short Wave (SX), and Long Wave (LX) \nGLYPH<SM590000> Fiber-based 10-Gigabit Ethernet Short Reach (SR) and Long Reach (LR)\nThe OSA Express features are installed in an IBM z15 server PCIe+ I/O drawer. The features  are available as different types and support several networking protocols. Depending on the  types of OSAs installed in the z15, the CPC supports attachment with the following  characteristics:\nBased on the intended use, the operating modes must be defined with channel type and  device address. For configuration details, see  Chapter 6, “Configuring network features”  on page 129  and the  OSA-Express Implementation Guide , SG24-5948.\nStarting with Driver Level 22 (HMC 2.13.0), HMC has been enhanced to take advantage of  the Open Systems Adapter/Support Facility (OSA/SF) function for the OSA-Express6S,  OSA-Express5S, and OSA-Express4S features. Either OSA/SF on the HMC or the OSA/SF  in the operating system component can be used for the OSA-Express4S features. For the  OSA-Express7S, OSA-Express6S and OSA-Express5S features, OSA/SF on the HMC is  required. The OSA/SF is used primarily for these purposes:\nSee 6.3, “Customizing OSA-Express using OSA Ad vanced facilities” on  page 133 for details  about the use of OSA/SF on the HMC.\nNote:  OSA-Express6S 1000Base-T adapter (FC 0426) is the last generation of OSA  1000Base-T adapters to support connections operating at 100Mbps link speed.  OSA-Express7S 1000Base-T (FC 0466) supports only 1000Mbps duplex link speed only.\nThe 10GbE RoCE Express (FC #0411), the 10GbE RoCE Express2 (FC #0412), the 10GbE  RoCE Express2.1 (FC #0432), the 25GbE RoCE Express2 (FC 0430) and the 25GbE RoCE  Express2.1 (FC 0450) features are designed to help reduce CPU consumption for  applications that use the TCP/IP stack without requiring application changes. Using the RoCE \nGLYPH<SM590000> Manage all OSA ports.\nGLYPH<SM590000> Configure all OSA non-QDIO ports.\nGLYPH<SM590000> Configure local MAC addresses.\nGLYPH<SM590000> Display registered IPv4 addresses (in use and not in use). It is supported on IBM Z  platform for QDIO ports.\nGLYPH<SM590000> Display registered IPv4 or IPv6 Virtual MAC and VLAN ID associated with all OSA  Ethernet features configured as QDIO Layer 2.\nGLYPH<SM590000> Provide status information about an OSA port and its shared or exclusive use state.\nChapter 2. Planning considerations for CPC in PR/SM mode  23"}]}
+{"image": "doclay/doclay_4178.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "220 \nUS 9,423,690 B2 \n-continued \n(D-11) \n(D-12) \n0  o)l_)(/  o;n1 \no,,lo~  \"’\"’ \no,,lo~  \"’\"’ \no,,lo~  \"’\"’ \no,,lo~  \"’\"’ \n(D-18) \nGN,,l)(/  ’\"’’ \n0  G)l)(~  ’\"’  u \nGN,,lO~  ’\"•’’ \" \nGN,,lOf>  ’\"’’ "}]}
+{"image": "doclay/doclay_57582.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "Spatial Operator Functions\n12.17.8 Spatial Operator Functions\nOpenGIS proposes a number of functions that can produce geometries. They are designed to implement spatial operators. These functions support all argument type combinations except those that are inapplicable according to the Open Geospatial Consortium specification.\nMySQL also implements certain functions that are extensions to OpenGIS, as noted in the function descriptions. In addition, Section 12.17.7, “Geometry Property Functions” , discusses several functions that construct new geometries from existing ones. See that section for descriptions of these functions:\n• ST_Envelope( g )\n• ST_EndPoint( ls )\n• ST_StartPoint( ls )\n• ST_PointN( ls ,  N )\n• ST_ExteriorRing( poly )\n• ST_InteriorRingN( poly ,  N )\n• ST_GeometryN( gc ,  N )\nUnless otherwise specified, functions in this section handle their geometry arguments as follows:\n•If any argument is  NULL , the return value is  NULL .\n•If any geometry argument is not a syntactically well-formed geometry, an  ER_GIS_INVALID_DATA  error occurs.\n•If any geometry argument is a syntactically well-formed geometry in an undefined spatial reference system (SRS), an  ER_SRS_NOT_FOUND  error occurs.\n•For functions that take multiple geometry arguments, if those arguments are not in the same SRS, an ER_GIS_DIFFERENT_SRIDS  error occurs.\n•If any geometry argument has an SRID value for a geographic SRS and the function does not handle geographic geometries, an  ER_NOT_IMPLEMENTED_FOR_GEOGRAPHIC_SRS  error occurs.\n•For geographic SRS geometry arguments, if any argument has a longitude or latitude that is out of range, an error occurs:\n• If a longitude value is not in the range ( − 180, 180], an ER_GEOMETRY_PARAM_LONGITUDE_OUT_OF_RANGE  error occurs ( ER_LONGITUDE_OUT_OF_RANGE prior to MySQL 8.0.12).\n• If a latitude value is not in the range [ − 90, 90], an  ER_GEOMETRY_PARAM_LATITUDE_OUT_OF_RANGE error occurs ( ER_LATITUDE_OUT_OF_RANGE  prior to MySQL 8.0.12).\nRanges shown are in degrees. If an SRS uses another unit, the range uses the corresponding values in its unit. The exact range limits deviate slightly due to floating-point arithmetic.\n•Otherwise, the return value is non- NULL .\n• ST_Buffer( g ,  d  [,  strategy1  [,  strategy2  [,  strategy3 ]]])\nThese spatial operator functions are available:\n2317"}]}
+{"image": "doclay/doclay_62527.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "Feb.28,2019 \n13 \nUS 2019/0064665 Al \n[0103]  Under the action of acid, a polymer comprising  recurring units of formula (a) is decomposed to generate  carboxylic acid, turning to be alkali soluble. \n[0104]  The acid labile group  XA  may be selected from a  variety of such groups. Examples of the acid labile group  include groups of the following formulae (Ll) to (L4),  tertiary alkyl groups of 4 to 20 carbon atoms, preferably 4  to 15 carbon atoms, trialkylsilyl groups in which each alkyl  moiety has 1 to 6 carbon atoms, and oxoalkyl groups of 4 to  20 carbon atoms. \n[0105]  In formula (Ll), RLoi and  RL $^{02 }$each are hydrogen  or a straight, branched or cyclic alky 1 group of 1 to 18 carbon  atoms, preferably 1 to 10 carbon atoms. Exemplary alkyl  groups include methyl, ethyl, propyl, isopropyl, n-butyl,  s-butyl, t-butyl, cyclopentyl, cyclohexyl, 2-ethylhexyl, n-oc› tyl, norbomyl, tricyclodecanyl, tetracyclododecanyl, and  adamantyl. \n[0106]  RL $^{03 }$is a monovalent hydrocarbon group of 1 to 18  carbon atoms, preferably 1 to 10 carbon atoms, which may  contain a heteroatom such as oxygen, examples of which  include unsubstituted straight, branched or cyclic alkyl  groups and substituted forms of such alkyl groups in which  some hydrogen atoms are replaced by hydroxyl, alkoxy, oxo,  amino, alkylamino or the like, or in which at least one  carbon atom is replaced by a heteroatom such as oxygen. \n-continued  H  RA  H  H  H \n(Ll)  RLOI  I  L03  ----C-OR  I  RL02 \n(L2)  0  II  ----(CH2)x-C-OR 104 \n(L3) \n(L4) \n(++)  i  ’j=o  0  q_o  o  I  0  0  XA "}]}
+{"image": "doclay/doclay_18836.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "PRESIDENT’S MESSAGE \n1 \nThe Path Forward \nWithout question, 2013 was the busiest and most interesting year that we have had in the five years that we have been a  public company. The year was marked by the largest achievements in our history and it was also marked by the first  failure of a partner’s business in our history. While that is the nature of the business we are in, any company would be  foolish not to learn and grow from both its successes and its failures. \nWith the way that Alaris contributes capital to a private company and the criteria it uses to make its decisions (preferred  cash distributions, low percentage of the businesses economics, businesses with low levels of debt and capital expenditure  requirements, the use of collars on our distributions to reduce cash flow volatility) an awful lot has to go wrong for us not  to receive a distribution from one of our partners. For our partners at SHS, everything went wrong. Looking back, the key  issue that was very different than any other situation that we have ever gone into, and any situation that we will go into  going forward, was the lack of management continuity and a misalignment of interests. Any situation where you have a  management/ownership group that has not displayed a long track record of performance with the specific assets that  provide us our cash flow provides too many unknown variables. Too many of those unknowns were out of the control of  SHS’s management team, making any correction to the situation all but impossible.\nWhile the outcome on SHS was bitterly disappointing, it certainly drove home many of the key parts of our business model  that we set out upon founding the business over ten years ago. First among those is diversification. Over the course of  time, no matter how low risk your investment structure is, there will be business risks that pop up from time to time. While  we have partnered with tremendous companies over the years that has given us an enviable track record, building a  diversified revenue stream is still the best way to reduce risk. That certainly paid off in this case as the SHS distribution  represented just 3% of our revenue. So even with an outright failure of SHS’s business, our payout ratio was not materially  impacted and remained right at our target of 80% of our distributable cash flow. Our objective has always been to have  no revenue stream represent more than 10% of total revenue and given our continuing growth expectations, we believe  that we should hit that target within two years. Today, our largest revenue stream is approximately 17% of total revenue. \nThe rest of 2013 was the best performance that we have ever had. Coming off of 2012’s record year of $90 million of  capital deployed, Alaris deployed over $170 million in 2013. We added four new partners as well as helping to fund growth  in some of our existing partners. The fact that we have now completed more than 20 follow-on transactions with current  partners is a testament to the long-term sustainability of our offering to private companies. Our partners are successful,  profitable businesses with many options for capital. The fact that they continue to choose Alaris as their capital partner is  an excellent reference for future partners.\nNearly doubling our next busiest year not only led to our sixth and seventh consecutive dividend increases in 2013, it also  necessitated an expansion of our staffing levels to increase our capacity to both add new partners as well as monitor our  current ones. Even with these staffing additions, our total corporate costs are now only 8% of our total revenue. In adding  Amanda Frazer and Mike Ervin, two valued members of third party service providers that have worked with Alaris for years,  we have significantly enhanced our team and feel that we can double the current size of our company again with the team  we have in place today.\nSince the start of 2009, the total return that Alaris has provided its shareholders is approaching 400% (share appreciation  plus reinvestment of dividends paid). Even at a larger size, Alaris was able to post per share EBITDA growth of more than  30% for a second consecutive year. The delivery of a low volatility distributable cash flow stream, in combination with  sustainable growth, has made Alaris very unique in the public markets. While growing at the same pace becomes harder  and harder as we’ve become larger, the exposure that our company has received in a huge market continues to grow. In  2013, Alaris added our largest partner, Sequel Youth and Family Services. Sequel is a very successful and well-known  company in its industry in the United States and was sought after by many private equity firms. Having companies like "}]}
+{"image": "doclay/doclay_55149.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "mysqlslap — A Load Emulation Client\nOption Name Description Introduced Deprecated --defaults-extra-file Read named option file in addition to usual option files --defaults-file Read only named option file --defaults-group-suffix Option group suffix value --delimiter Delimiter to use in SQL statements --detach Detach (close and reopen) each connection after each N statements --enable-cleartext-plugin Enable cleartext authentication plugin --engine Storage engine to use for creating the table --get-server-public-key Request RSA public key from server --help Display help message and exit --host Host on which MySQL server is located --iterations Number of times to run the tests --login-path Read login path options from .mylogin.cnf --no-defaults Read no option files --no-drop Do not drop any schema created during the test run --number-char-cols Number of VARCHAR columns to use if --auto- generate-sql is specified --number-int-cols Number of INT columns to use if --auto-generate- sql is specified --number-of-queries Limit each client to approximately this number of queries --only-print Do not connect to databases. mysqlslap only prints what it would have done --password Password to use when connecting to server\n542"}]}
+{"image": "doclay/doclay_42592.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Defining Elements  of Risk Management Chapter 1\nIntroduction\nRisk management, a formalized way of dealing with hazards,  is the logical process of weighing the potential costs of risks  against the possible benefits of allowing those risks to stand  uncontrolled. In order to better understand risk management,  the terms “hazard” and “risk” need to be understood. "}]}
+{"image": "doclay/doclay_7658.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract and digitize all visible text in this image, preserving the layout order."}, {"from": "gpt", "value": "Income Taxes\nNon-Interest Expense\nMANAGED CONSUMER LOAN PORTFOLIO\n26\nNon-interest expense for the year ended December 31, 2001, increased $910.4 million, or 29%, to $4.1 billion from $3.1 billion for the year ended December 31, 2000. Contributing to the increase in non-interest expense were marketing expenses, which increased $176.8 million, or 20%, to $1.1 billion in 2001, from $906.1 million in 2000. The increase in marketing expenses during 2001 reflected the Company’s continued identification of and investments in opportunities for growth, as well as its marketing extension into television advertisements. Salaries and associate benefits increased $368.7 million, or 36%, to $1.4 billion in 2001, from $1.0 billion in 2000, as the Company added approximately 2,400 net new associates to its staffing levels to manage the growth in the Company’s accounts. All other non-interest expenses increased $364.8 million, or 30%, to $1.6 billion for the year ended December 31, 2001, from $1.2 billion in 2000. The increase in other non-interest expenses was primarily composed of increased depreciation expense due to premises and equipment growth, increased collections costs as a result of increased collection and recovery efforts, and non-recurring expenses such as the write-off of an investment in an ancillary business as well as costs associated with the mailing of amendments to customer account agreements. The increase was also driven by the 39% increase in average accounts.\nmillion, or 36%, to $1.4 billion in 2001. The decrease in the salaries and associate benefit growth rate as well as a decrease in marketing expenses of $12.4 million compared to 2001, was the result of the Company’s efforts to slow loan growth to more historical levels. All other non-interest expenses increased $374.1 million, or 24%, to $2.0 billion for the year ended December 31, 2002, from $1.6 billion in 2001. This increase was the result of a 23% increase in the average number of accounts as compared to the prior year and $110.0 million of one-time charges incurred in 2002. Of the $110.0 million: $38.8 million related to unused facility capacity, early termination of facility leases, and the accelerated depreciation of fixed assets; $14.5 million related to the accelerated vesting of restricted stock issued in connection with the PeopleFirst, Inc. (“PeopleFirst”) acquisition; and $12.5 million related to the realignment of certain aspects of its European operations. The remaining amounts related to investment company valuation adjustments, increases in associate related costs and accruals for contingent liabilities. \nThe Company’s income tax rate was 38% for the years ended December 31, 2002, 2001 and 2000, respectively. The effective rate includes both state and federal income tax components.\nThe Company’s managed consumer loan portfolio is comprised of reported and off-balance sheet loans. Off-balance sheet loans are those which have been securitized and accounted for as sales in accordance with SFAS 140, and are not assets of the Company. \nThe Company analyzes its financial performance on a managed consumer loan portfolio basis. Managed consumer loan data adds back the effect of off- balance sheet consumer loans. The managed consumer loan portfolio includes securitized loans for which the Company has retained significant risks and rewards.\nNon-interest expense for the year ended December 31, 2002, increased $527.6 million, or 13%, to $4.6 billion from $4.1 billion for the year ended December 31, 2001. Contributing to the increase was salaries and associate benefits, which increased $165.8 million, or 12%, to $1.6 billion in 2002, from an increase of $368.7\nMARKETING INVESTMENT ($ in millions) 1,071 2002 2001 1,083 2000 906"}]}
+{"image": "doclay/doclay_4358.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "The outer layer may be substantially uniform in thickness. The outer layer may comprise about 10%, about 15%, about 16%, about 17%, about 18%, about 19%, about 20%, about 2 1%, about 22%, about 23%, about 24%, about 25% or about 30% of the hybrid/composite capsule.\nIn various embodiments, the outer layer is physically deposited on the inner layer. In various embodiments, the hybrid/composite shell does not comprise a polyelectrolyte such as a poly(allylamine hydrochloride) (PAH). Accordingly, the hybrid/composite shell may be substantially inert e.g. does not react with an encapsulated active.\nThe hybrid/composite capsule may be substantially spherical in shape. The hybrid/composite capsule may be micron- or submicron-sized. In various embodiments, the hybrid/composite capsule has a size/diameter/particle size/particle size distribution/average particle size in the range of from about 100 nm to about 100 pm, from about 500 nm to about 100 pm, from about 1 pm to about 100 pm, 10 pm to about 100 pm, from about 20 pm to about 100 pm, from about 30 pm to about 100 pm, from about 40 pm to about 100 pm, from about 50 pm to about 100 pm, from about 60 pm to about 100 pm, from about 70 pm to about 100 pm, no less than about 70 pm, no less than about 60 pm, no less than about 50 pm or no less than about 40 pm.\nIn various embodiments, the hybrid/composite capsule comprises one or more actives loaded in a core of the capsule that is encapsulated by the shell of the primary capsule. For example, the hybrid/composite capsule may be loaded with one or more cargoes selected from the following: oil, silicone oil, active including sensitive active (e.g. sensitive to free radical reactions), aroma, aroma oil, flavour, fragrance, perfume, drug, therapeutic, cosmetic, skin care substance, consumer care substance, combinations or mixtures or derivatives thereof. In various embodiments, the hybrid/composite shell is substantially inert e.g. does not react with an encapsulated active."}]}
+{"image": "doclay/doclay_38180.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe the text content of this image systematically, going from top to bottom."}, {"from": "gpt", "value": "APPENDIX B  General Terms  and Conditions \nThe Bank may at any time terminate the Framework Agreement and any Contract by giving the Service  Provider one month's written notice. \nThe Bank may terminate the Framework Agreement and any Contract immediately by notice in writing to the  Service Provider if: \nThe Service Provider may at any time terminate the Framework Agreement and any Contract by giving the  Bank three months' written notice. \nConflict of interest is a situation where the impartial and objective performance of the Contract by the Service  Provider is compromised for reasons involving:\nThe Service Provider shall ensure to take all the necessary measures to prevent any situation of conflict of  interest and to notify the Bank in writing as soon as possible of any situation or potential situation that could \nVersion dated 26-03-2021 \n7 \n§ 18. Conflict of interest \nc)  previous or ongoing professional activities affect Service Provider’s capacity to perform the Contract  to an appropriate quality standard.\nb) any involvement with the Bank or any third party related to the subject matter of the Contract; \na) family, emotional life, political or national affinity, economic interest;\n(x)  the Agreement or a Contract should not have been awarded to the Service Provider in view of a serious  infringement of the obligations under the EU Treaties and of Directive 2014/24/EU that has been  declared by the Court of Justice of the European Union in a procedure pursuant to Article 258 of the  Treaty on the Functioning of the European Union.\n(ix)  the Service Provider had, at the time of the award of the Agreement or of a Contract, been in one of  the situations referred to in Article 57(1) of Directive 2014/24/EU and should therefore have been  excluded from that procurement procedure; or \n(viii)  the Service Provider, or any member of the Service Provider’s Personnel, has engaged in Prohibited  Conduct within the meaning of the Anti-Fraud Policy referred to in point (v) of §9 of these General  Terms and Conditions; \n(vii)  the Service Provider does not comply with the applicable data protection obligations resulting from  Regulation (EU) 2016/679; \n(vi)  the Service Provider is in breach of the data protection obligations resulting from paragraph B of Annex  II hereto;\nc)  the appointment of a liquidator, receiver, administrator, administrative receiver, regulatory official,  compulsory manager or similar officer in respect of the Service Provider. \nb) a composition, assignment or arrangement with any creditor of the Service Provider; or \na) the suspension of payments, a moratorium of any indebtedness, the winding-up, dissolution,  administration or reorganisation of the Service Provider; \n(v)  any corporate action, legal proceedings or other procedure is taken in any jurisdiction in relation to: \n(iv)  the Service Provider has ceased or has resolved to cease to carry on the whole or any substantial part  of its business or activities, or a change to the Service Provider’s legal, financial, technical or  organisational or ownership situation leads to the transfer of all of the Service Provider’s rights and  obligations to a third party by way of universal succession and said third party is ineligible according  to the Bank’s procurement policies;\n(iii)  the Service Provider, or a member of the Service Provider’s Personnel, is in a situation of conflict or  potential conflict of interest, as defined in § 18 of these General Terms and Conditions; \n(ii)  the Service Provider, or a member of the Service Provider’s Personnel, has been engaged in conduct  bringing the Bank into disrepute, including a Sanction Event; \n(i)  the Service Provider is in material breach of any of its obligations under the Framework Agreement  and any Contract; "}]}
+{"image": "doclay/doclay_25956.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform optical character recognition on this image, capturing all text elements."}, {"from": "gpt", "value": "The discreteness of the optimized input distribution is proved in the following. According to Properties (b) and (c), lower bound L ( · ) is maximized by a first-order Markov process, the transition probability distribution of which P$_{X}$$_{2}$$_{|}$$_{X}$$_{1}$ can be expressed as\nwhere b$_{i}$ = 1$_{{}$$_{x}$$_{i}$$_{̸}$$_{=0}$$_{}}$ P$_{X}$ = µ$_{X}$ and P$_{X}$$_{2}$$_{|}$$_{X}$$_{1}$ = µ$_{X}$$_{2}$$_{|}$$_{X}$$_{1}$ . Then the maximum of L ( µ ) can be achieved by the follow optimization\nSince given any q$_{0}$ ≥ q > 0 , I$_{X}$ ( q$_{0}$ ) − I$_{B}$ ( q$_{0}$ ) can be maximized by the maximum of I$_{X}$ ( q$_{0}$ ) and the minimum of I$_{B}$ ( q$_{0}$ ) respectively, the maximization of (119) must be achieved by P$_{X}$ , which maximizes I ( X ; Y ) for given q$_{0}$ . Therefore given q$_{0}$ , the maximization in (120) is similar to the problem in Theorem 1. The difference to Theorem 1 is that in (120) the distribution P$_{X}$ satisfies P$_{X}$ (0) = q$_{0}$ ≥ q , however in Theorem 1 the distribution P$_{X}$ satisfies P$_{X}$ (0) ≥ q . Define\nwhere µ is the marginal input distribution of the first-order Markov process. We can establish the following lemma.\nLemma 7: Λ$_{0}$( γ, q$_{0}$ ) is compact in the topological space P .\nΛ$_{0}$( γ, q$_{0}$ ) = $^{{}$µ : µ ( { 0 } ) = q$_{0}$, E$_{µ}$ $^{{}$X 2 $^{}}$≤ γ } (124)\nsubject to I$_{X}$ ( q$_{0}$ ) = maximize P$_{X}$ I ( X ; Y ) (120)\nI$_{B}$ ( q$_{0}$ ) = minimize P ( B$_{2}$ | B$_{1}$ ) I ( B$_{1}$ ; B$_{2}$ ) (121)\nP$_{X}$ (0) = P$_{B}$$_{1}$ (0) = P$_{B}$$_{2}$ (0) = q$_{0}$ (122)\nq$_{0}$ − 2 cq$_{0}$P$_{B}$$_{2}$$_{|}$$_{B}$$_{1}$ (1 | 0) ≥ q. (123)\nmaximize q$_{0}$ I$_{X}$ ( q$_{0}$ ) − I$_{B}$ ( q$_{0}$ ) (119)\nP$_{X}$$_{2}$$_{|}$$_{X}$$_{1}$ ( x$_{2}$ | x$_{1}$ ) = P$_{B}$$_{2}$$_{|}$$_{B}$$_{1}$ ( b$_{2}$ | b$_{1}$ ) P$_{X}$ ( x$_{2}$ ) P$_{B}$$_{2}$ ( b$_{2}$ ) (118)\n24"}]}
+{"image": "doclay/doclay_71426.jpg", "conversations": [{"from": "human", "value": "<image>\nIdentify and transcribe every piece of text visible in this image."}, {"from": "gpt", "value": "Table of Contents\nHEXION INC. CONSOLIDATED STATEMENTS OF DEFICIT\n51\nSee Notes to Consolidated Financial Statements\n(In millions) Common Stock Paid-in Capital Treasury Stock Accumulated Other Comprehensive Income (Loss) Accumulated Deficit Total Hexion Inc. Deficit Non- controlling Interest Total Balance at December 31, 2015 $ 1 $ 526 $ (296 ) $ (15 ) $ (2,692 ) $ (2,476 ) $ (1 ) $ (2,477 ) Net loss — — — — (38) (38) — (38) Other comprehensive loss — — — (24 ) — (24 ) — (24 ) Balance at December 31, 2016 1 526 (296) (39) (2,730) (2,538) (1) (2,539) Net loss — — — — (234 ) (234 ) — (234 ) Other comprehensive income — — — 31 — 31 — 31 Balance at December 31, 2017 1 526 (296 ) (8 ) (2,964 ) (2,741 ) (1 ) (2,742 ) Net loss — — — — (162) (162) (1) (163) Other comprehensive loss — — — (10 ) — (10 ) — (10 ) Impact of change in accounting policy — — — — 1 1 — 1 Balance at December 31, 2018 $ 1 $ 526 $ (296 ) $ (18 ) $ (3,125 ) $ (2,912 ) $ (2 ) $ (2,914 )"}]}
+{"image": "doclay/doclay_10814.jpg", "conversations": [{"from": "human", "value": "<image>\nExtract the textual content from this image in reading order."}, {"from": "gpt", "value": "MANAGEMENT ’ S DISCUSSION AND ANALYSIS\nOther Iroquois Expansion Projects\nIroquois/Portland Ownership Changes\nPortland Rate Application\nNorthern Development\nNorthwinds Pipeline\n2001 ANNUAL REPORT \n25\nIn September 2001, TransCanada and National Fuel Gas Supply Corporation announced the formation of a strategic partnership to evaluate the feasibility of developing a new natural gas pipeline project (Northwinds Pipeline) to provide transportation service from Dawn, Ontario to the Ellisburg-Leidy area in Pennsylvania. The partnership is currently evaluating market sup- port for the project.\nAll costs incurred to date related to northern development have been expensed as incurred.\nTransCanada spent considerable time in 2001 gathering input from producers with natural gas reserves in the WCSB and the two Arctic basins on options for moving northern gas once it reaches Alberta. As a result of these discussions, TransCanada has developed a comprehensive plan that provides flexibility and choice for all producers to move their natural gas. This plan ensures costs are effectively managed by using existing infrastructure where possible and by expanding in increments based on the volumes to be shipped. The company continues to refine and discuss this plan.\nIn November 2001, TransCanada was one of ten companies, known as the ANGTS Group, to sign a Memorandum of Understanding to begin developing an initial commercial transportation proposal relating to northern slope gas production in Alaska. The group is pursuing development of the Alaska Natural Gas Transportation System, also known as the Alaska Highway project. The ANGTS Group completed the initial proposal in 2001 and is discussing details on this complex project and potential commercial arrangements with Alaska North Slope producers.\nTransCanada actively continues to pursue pipeline opportunities to move both Mackenzie Delta and Alaska North Slope natural gas to markets throughout North America. TransCanada worked with key stakeholders in 2001 to promote a stand-alone Mackenzie Valley pipeline project. The Mackenzie Delta producers have indicated they would prefer to use TransCanada’s existing Alberta System for gas to be transported to markets.\nPortland filed a Rate Application with the FERC in October 2001. Portland will be operating under a FERC approved interim toll commencing April 1, 2002, until a final toll is determined.\nIn May 2001, TransCanada purchased an additional 5.96 per cent interest in Iroquois, bringing its total interest to 40.96 per cent. In June 2001, TransCanada purchased an additional 11.88 per cent interest in Portland, bringing its total interest to 33.29 per cent. TransCanada holds the largest ownership interest in both Iroquois and Portland.\nThree applications were filed with the FERC in the fourth quarter of 2001, which if approved would see total capital additions of US$148 million to the pipeline system occurring between 2003 and 2005.\nTuscarora operates a 369 kilometre pipeline system transporting gas from Malin, Oregon to Reno, Nevada with delivery points in north- eastern California. TransCanada owns an aggregate 17.4 per cent interest in T uscarora, of which 16.4 per cent is held through TransCanada’ interest in TC PipeLines, LP.\nPortland operates  a 471 kilometre pipeline which  connects with TQM near Pittsburgh,  New Hampshire and  has delivery points in Massachusetts. TransCanada increased its interest in Portland to 33.29 per cent  in 2001.\nFoothills Pipe Lines  Ltd. (Foothills) carries natural gas for export from central Alberta to the U.S. border to  serve marketsin the U.S. Midwest, Pacific Northwest and California. Tr ansCanada owns 50 per cent of Foothills, 69.5 per cent of Foothills (Sask.), 74.5 per cent of Foothills (Alta.) and 74.5 per cent of Foothills (South B.C.). Together these pipelines systems  total 1,040 kilometres in length.\nFOOTHILLS\nPORTLAND \nTUSCARORA "}]}
+{"image": "doclay/doclay_42312.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "Acknowledgments\nPlane Sense  was produced by the Federal Aviation Administration (FAA) with the assistance of The Wicks  Group, PLLC. The FAA wishes to acknowledge the providers of the following images used in this handbook:\nSkycatcher used on the cover and in chapter 6, courtesy of Cessna Aircraft Corporation\nCirrus SR20-1 used on the cover and in chapter 1, courtesy of Cirrus Design\nEclipse 500 used on the cover, courtesy of Eclipse Aviation Corporation\nThe FAA would also like to extend its appreciation to several aviation industry organizations that provided  assistance and input in the preparation of this handbook, including: \nGeneral Aviation Manufacturers Association (GAMA) \nAircraft Owners and Pilots Association (AOPA)\nExperimental Aircraft Association (EAA)\nv"}]}
+{"image": "doclay/doclay_20363.jpg", "conversations": [{"from": "human", "value": "<image>\nRead through this image and extract all text content systematically."}, {"from": "gpt", "value": "represented the premium paid in the tender offer, the write-off of the remaining discount and unamortized fees, and the settlement of related swaps. We issued commercial paper to fund the repurchase.\nDuring fiscal 2010, we repaid $88 million of long-term bank debt held by wholly owned foreign subsidiaries.\nIn January 2009, we issued $1.2 billion aggregate principal amount of 5.65 percent notes due 2019. In August 2008, we issued $700 million aggregate principal amount of 5.25 percent notes due 2013. The proceeds of these notes were used to repay a portion of our outstanding commercial paper. Interest on these notes is payable semi-annually in arrears. These notes may be redeemed at our option at any time for a specified make-whole amount. These notes are senior unsecured, unsubordinated obli- gations that include a change of control repurchase provision.\nIn June 2010, subsequent to our fiscal 2010 year-end, we issued $500.0 million aggregate principal amount of 5.4 percent notes due 2040. The significant terms of these notes are similar to our previously issued notes.\nreceived insurance proceeds of $41 million in fiscal 2009 from the settlement with the insurance carrier covering the loss at our La Salteña pasta manufacturing facility in Argentina. These pro- ceeds offset the capital expenditures required to replace the manufacturing facility that was destroyed by fire in fiscal 2008.\nWe expect capital expenditures to increase to approximately $700 million in fiscal 2011, including initiatives that will: increase manufacturing capacity for cereals and Yoplait yogurt; continue HMM initiatives throughout the supply chain; and expand Inter- national production capacity for Wanchai Ferry and Ha ¨agen-Dazs products.\nOn October 15, 2007, we settled the forward contract estab- lished with Lehman Brothers in October 2004 in conjunction with the issuance by Lehman Brothers of $750 million of notes that were mandatorily exchangeable for shares of our common stock. In settlement of that forward contract, we issued 29 million shares of our common stock and received $750 million in cash from Lehman Brothers. We used the cash to reduce outstanding commercial paper balances.\nOn August 7, 2007, we repurchased for a net amount of $843 mil- lion all of the outstanding Series B-1 Interests in GMC as part of a required remarketing of those interests. The purchase price reflected the Series B-1 Interests’ original capital account balance of $835 million and $8 million of capital account appreciation attributable and paid to the third-party holder of the Series B-1 Interests. The capital appreciation paid to the third-party holder of the Series B-1 Interests was recorded as a reduction to retained earnings, a component of stockholders’ equity, on our Consolidated Balance Sheets, and reduced net earnings available to common stockholders in our basic and diluted EPS calculations.\nNet cash used by financing activities increased by $99 million in fiscal 2010.\nIn May 2010, we paid $437 million to repurchase in a cash tender offer $400 million of our previously issued debt. We repurchased $221 million of our 6.0 percent notes due 2012 and $179 million of our 5.65 percent notes due 2012. As a result of the repurchase, we recorded interest expense of $40 million which\nIn April 2007, we issued $1.15 billion of floating rate convertible senior notes. In April 2008, holders of $1.14 billion of those notes tendered them to us for repurchase. In April 2009, we\nGeneral Mills\n32\nCash Flows from Financing Activities\nIn Millions 2010 2009 2008 Fiscal Year ..................................................................................... ......................................................................................................................................................................................... Change in notes payable $ 235.8 $(1,390.5) $ 946.6 Issuance of long-term debt — 1,850.0 1,450.0 Payment of long-term debt (906.9) (370.3) (1,623.4) Settlement of Lehman Brothers forward purchase contract — — 750.0 Repurchase of Series B-1 limited membership interests in GMC — — (843.0) Repurchase of General Mills Capital, Inc. preferred stock — — (150.0) Proceeds from sale of Class A limited membership interests in GMC — — 92.3 Proceeds from common stock issued on exercised options 388.8 305.2 191.4 Tax benefit on exercised options 114.0 89.1 55.7 Purchases of common stock for treasury (691.8) (1,296.4) (1,432.4) Dividends paid (643.7) (579.5) (529.7) Other, net — (12.1) (0.5) ......................................................................................................................................................................................... Net cash used by financing activities $(1,503.8) $(1,404.5) $(1,093.0)"}]}
+{"image": "doclay/doclay_5265.jpg", "conversations": [{"from": "human", "value": "<image>\nOCR this image section by section, from top to bottom, and left to right."}, {"from": "gpt", "value": "Notes to Consolidated Financial Statements\n43\nFranklin Covey 2000 Annual Report\nThe weighted average interest rate on outstanding current line of credit debt at August 31, 2000 and 1999 was 8.6 percent and 7.8 percent, respectively. The weighted average interest rate on the long-term credit facility was 8.7 percent as of August 31, 2000.\nThe line of credit agreements require the Company to maintain certain financial ratios and working capital levels. At August 31, 2000, the Company was in compli- ance with the terms of the line of credit agreements.  The Company’s line of credit agreements expire on December 1, 2001.\nCommitment fees associated with the lines of credit were $0.7 million during fiscal 2000.\nLong-term debt was comprised of the following (in thousands):\nAUGUST 31,\nLong-Term Debt\nAUGUST 31,\nAs a result of restructuring and impaired asset charges, the Company was not in compliance with certain terms of the $85.0 million senior unsecured notes payable at August 31, 1999. The Company did not obtain a waiver on the terms of the debt covenants, and during October 1999, the Company retired the $85.0 million notes payable at par plus accrued interest. The Company utilized existing cash and its expanded long-term line of credit to retire the notes payable. Accordingly, the $85.0 million notes payable were reported as a component of the current portion of long-term debt in the accompanying fiscal 1999 consolidated balance sheet.\nFuture maturities of long-term debt at August 31, 2000 were as follows (in thousands):\nYEAR ENDING AUGUST 31,\nAUGUST 31, 2000 1999 Note payable in annual installments  of $3,000 plus interest at 8%  through December 2001, unsecured $ 6,000 $0,0000 Note payable in quarterly installments  of $574 including interest at 5.0%  through April 2001, unsecured 1,679 3,822 Mortgage payable in monthly  installments of $18 including  interest at 8.5% through  August 2016, secured by real estate 1,619 1,697 Note payable on demand,  plus interest at 8.0%, unsecured 1,396 1,481 Mortgage payable in monthly  installments of $14 CDN, including  interest at 7.2% through January 2015,  secured by real estate 997 Note payable to bank, payable in  monthly installments of $20, including  interest at 7.8% through August 2004,  secured by equipment 802 976 Mortgage payable in monthly  installments of $8 including interest  at 9.9% through October 2014,  secured by real estate 688 710 Note payable to bank, payable in  monthly installments of $23, plus  interest at prime plus .5% payable  through September 2002, secured  by real estate 587 869\n2000 1999 Senior unsecured notes payable with  interest at 6.6% due semi-annually,  paid in full $0,0000 $ 85,000 Note payable to a Japanese bank for  YEN 60,000, payable in quarterly  installments of YEN 20,000,  paid in full 548 Other mortgages and notes, payable  in monthly installments, interest  ranging from 2.0% to 8.8%, due at  various dates through 2002,  secured by equipment 230 531 13,998 95,634 Less current portion (6,873) (90,010) Long-term debt, less current portion $ 7,125 $ 5,624\nAUGUST 31, 2001 $ 6,873 2002 3,697 2003 419 2004 386 2005 209 Thereafter 2,414 $13,998"}]}
+{"image": "doclay/doclay_38611.jpg", "conversations": [{"from": "human", "value": "<image>\nConvert all text in this image to digital format, reading sequentially from top to bottom."}, {"from": "gpt", "value": "For the contractor  For the contracting authority  Name:  Name:  Title:  Title:  Signature:  Signature:  Date:  Date:  Endorsed for financing by the European Union Name:  Title:  Signature:  Date:\nElectronically signed on 31/08/2020 21:13 (UTC+02) in accordance with article 4.2 (Validity of electronic documents) of Commission Decision 2004/563\nAugust 2020 c4c_contract_en.doc \nPage 4 of 4 "}]}
+{"image": "doclay/doclay_11939.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "NOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS 133\n12/31/2003 12/31/2002 ¤ mn ¤ mn Loans to banks 4,439 5,213 Loans to customers *) 120,851 148,530 Total lending volume 125,290 153,743 Less loan loss allowance 5,725 6,967 Lending volume after loan loss allowance 119,565 146,776\n12/31/2003 12/31/2002 ¤ mn ¤ mn Corporate customers 136,360 123,082 Public authorities 3,270 2,989 Private customers 69,054 68,572 Loans and advances to customers 208,684 194,643 Less loan loss allowance 5,425 6,559 Loans and advances to customers, net  of loan loss allowance 203,259 188,084\n12/31/2003 12/31/2002 ¤ mn ¤ mn Loans 120,717 148,253 Reverse repos 63,296 39,002 Other advances 24,671 7,388 Total 208,684 194,643\nThe overall volume of risk provisions includes allowances for loan losses deducted from loans and advances to banks and customers in the amount of  ¤ 5,725 (2002: 6,967) mn and provisions for contin- gent liabilities included in other accrued liabilities in the amount of ¤ 549 (2002: 633) mn.\nLoans and advances due within 1 year total  ¤ 131,471 (2002: 106,603) mn, those due after more than 1 year total  ¤ 77,213 (2002: 88,040) mn.\nLoans and advances to customers include amounts receivable under finance leases at their net investment value totaling  ¤ 933 (2002: 1,104) mn. The corresponding gross investment value of these leases amounts to  ¤ 1,030 (2002: 1,224) mn, the associated unreal- ized finance income is  ¤ 97 (2002: 120) mn. The residual values of the entire leasing portfolio were fully insured, both in the reporting year and in the preceding year. Lease payments received have been recognized as income in the amount of  ¤ 80 (2002: 141) mn. The al- lowance for uncollectable lease payments amounted to  ¤ 42 (2002: 4) mn at the balance sheet date. The total amounts receivable under leasing arrangements include  ¤ 114 (2002: 122) mn due within 1 year, ¤ 450 (2002: 714) mn due within 1 to 5 years, and  ¤ 466 (2002: 388) mn due after more than 5 years.\nIn contrast to the reporting of loans and advances, lending volume does not include reverse repos or other advances. However, this item does comprise loans extended on bills of exchange which, in turn, are not reported under loans and advances to customers or loans and advances to banks.\n$^{*) }$Including bills of exchange amounting to ¤ 134 (2002: 277) mn, unless these are included under loans and advances to banks or customers\nAllowance for loan losses\nLoans and advances to customers\nLending volume\nLoans and advances to customers by customer category (before loan loss allowance) are as follows:\nLoans and advances to customers by type of loan  (before loan loss allowance) are as follows:"}]}
+{"image": "doclay/doclay_35014.jpg", "conversations": [{"from": "human", "value": "<image>\nScan and convert all text elements in this image to machine-readable format."}, {"from": "gpt", "value": "12\n[51] Wahlén, E., \"A Hamiltonian formulation of water waves with constant vorticity,\" Lett. Math. Phys. 79 : 303\n[26] Kartashova, E., \"Wave resonances in systems with dis- crete spectra,\" AMS Transl. 2 , 95 (1998).\n[50] Verheest, F., \"Integrability of restricted multiple three- wave interactions. II. Coupling constants with ratios 1 and 2,\" J. Math. Phys. 29 : 2197 (1988).\n[49] Verheest, F., \"Proof of integrability for five-wave interac- tions in a case with unequal coupling constants,\" Phys. A: Math. Gen. 21 : L545 (1988).\n[48] Varvaruca, E., \"On some properties of traveling water waves with vorticity,\" SIAM J. Math. Anal. 39 : 1686 (2008).\n[47] Treumann, R., and Baumjohann, W., Advanced Space Plasma Physics (Imperial College Press, London, 2001).\n[25] Kartashova, E., \"Weakly nonlinear theory of finite-size effects in resonators,\" Phys. Rev. Lett. 72 : 2013 (1994).\n[24] Kartashova, E., \"On properties of weakly nonlinear wave interactions in resonators,\" Physica D , 54 : 125 (1991).\n[23] Henry, D., \"Particle trajectories in linear periodic cap- illary and capillary-gravity water waves,\" Philos. Trans. R. Soc. London A 365 , 2241 (2007).\n[22] Hasselmann, K., \"A criterion for nonlinear wave stabil- ity,\" J. Fluid Mech. 30 , 737 (1967).\n[21] Groves, M., and Wahlén, E., \"Small-amplitude Stokes and solitary gravity water waves with an arbitrary dis- tribution of vorticity,\" Physica D 237 , 1530 (2008).\n[46] Tanaka, M., and Yokoyama, N., \"Effects of discretization of the spectrum in water-wave turbulence,\" Fluid Dyn. Res. 34 , 199 (2004).\n[45] Stiassnie, M., and Shemer, L., \"On the interactions of four water waves,\" Wave motion 41 : 307 (2005).\n[20] Falcon, C., Falcon, E., Bortolozzo, U., and Fauve, S., \"Capillary wave turbulence on a spherical fluid surface in low gravity,\" EPL 86 , 14002 (2009).\n[19] Ganshin, A.N, Efimov, V.B., Kolmakov, G.V., Mezhov- Deglin, L.P., and McClintock, P.V.E., \"Observation of an Inverse Energy Cascade in Developed Acoustic Turbu- lence in Superfluid Helium,\" Phys. Rev. Lett. 101 , 065303 (2008).\n[44] Snouck, D., Westra, M.-T., and van der Water, W., \"Turbulent parametric surface waves,\" Phys. Fluids 21 : 025102 (2009).\n[43] Sajjadi, S., \"Vorticity generated by pure capillary waves,\" J. Fluid Mech. 459 : 277 (2002).\n[18] Ehrnström, M., and Villari, G., \"Linear water waves with vorticity: rotational features and particle paths,\" J. Dif- ferential Equations 244 , 1888 (2008).\n[17] Denissenko, P., Lukaschuk, S., and Nazarenko, S., \"Grav- ity surface wave turbulence in a laboratory flume,\" Phys. Rev. Lett. 99 , 014501 (2007).\n[42] Ritz, Ch. P., and Powers, E.J., \"Estimation of nonlinear transfer functions for fully developed turbulence,\" Phys- ica D 20 : 320 (1986).\n[41] Rinberg, D., Cherepanov, V., and Steinberg, V., \"Uni- versal broadening of frequency spectra in parametrically driven systems,\" Phys. Rev. Lett. 78 : 4383 (1997).\n[40] Punzmann, H., Shats, M.C., and Xia, H., \"Phase ran- domization of three-wave interactions in capillary waves,\" Phys. Rev. Lett. 103 : 064502 (2009).\n[16] Da Silva, A.F.T., and Peregrine, D.H., \"Steep, steady surface waves on water of finite depth with constant vor- ticity,\" J. Fluid Mech. 195 , 281 (1988).\n[15] Constantin, A., and Strauss, W., \"Pressure beneath a Stokes wave,\" Comm. Pure Appl. Math. , in print, DOI: 10.1002/cpa.20299 (2010).\n[39] Pushkarev, A.N., and Zakharov, V.E., \"Turbulence of capillary waves - theory and numerical simulation,\" Phys- ica D 135 : 98 (1999).\n[14] Constantin, A., and Strauss, W., \"Rotational steady wa- ter waves near stagnation,\" Philos. Trans. Roy. Soc. Lon- don A 365 , 2227 (2007).\n[13] Constantin, A., and Strauss, W., \"Stability properties of steady water waves with vorticity,\" Comm. Pure Appl. Math. 60 , 911 (2007).\n[38] Pushkarev, A.N., \"On the Kolmogorov and frozen turbu- lence in numerical simulation of capillary waves,\" Eur. J. Mech. - B/Fluids 18 (3): 345 (1999).\n[37] Perlin, M., and Schultz, W.M., \"Capillary effects on sur- face waves,\" Annu. Rev. Fluid. Mech. 32 : 241 (2000).\n[36] Newell, A., and Zakharov, V.E., \"Rough sea foam,\" Phys. Rev. Lett. 69 : 1149 (1992).\n[35] Manley, J.M., and Rowe, H.E., \"Some general properties of non-linear elements - Part 1. General energy relations,\" Proc. Inst. Rad. 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+{"image": "doclay/doclay_71973.jpg", "conversations": [{"from": "human", "value": "<image>\nCapture all textual information in this image using optical character recognition."}, {"from": "gpt", "value": "(c) First quarter of fiscal 2019 net income was impacted by restructuring, integration and other expenses of $11.5 million after tax, and a discrete income tax expense of $8.2 million. Second quarter results were impacted by restructuring, integration and other expenses of $46.6 million after tax and a discrete income tax expense of $16.7 million. Third quarter results were impacted by restructuring, integration and other expenses of $2.6 million after tax and a discrete income tax expense of $4.1 million. Fourth quarter results were impacted by restructuring, integration and other expenses of $20.7 million after tax, a goodwill impairment expense of $118.8 million after tax and a discrete income tax benefit of $20.9 million.\n● Sales adjusted for certain items that impact the year-over-year analysis, which includes the impact of certain acquisitions by adjusting Avnet’s prior periods to include the sales of acquired businesses, as if the acquisitions had occurred at the beginning of the earliest period presented. In addition, the prior year sales are adjusted for divestitures by adjusting Avnet’s prior periods to exclude the sales of divested businesses as if the divestitures had occurred at the beginning of the earliest period presented. Sales taking into account these adjustments are referred to as “organic sales.”\n● Operating income excluding (i) restructuring, integration and other expenses (see Restructuring, Integration and Other Expenses in this MD&A), (ii) goodwill and intangible asset impairment expenses, and (iii) amortization of acquired intangible assets and other is referred to as “adjusted operating income.” The reconciliation of operating income to adjusted operating income is presented in the following table:\nFor an understanding of Avnet and the significant factors that influenced the Company’s performance during the past three fiscal years, the following discussion should be read in conjunction with the description of the business appearing in Item 1 of this Report and the consolidated financial statements, including the related notes and schedule, and other information appearing in Item 8 of this Report. The Company operates on a “52/53 week” fiscal year. Fiscal years 2020, 2019 and 2018 all contain 52 weeks.\nThere are references to the impact of foreign currency translation in the discussion of the Company’s results of operations. When the U.S. Dollar strengthens and the stronger exchange rates of the current year are used to translate the results of operations of Avnet’s subsidiaries denominated in foreign currencies, the resulting impact is a decrease in U.S. Dollars of reported results. Conversely, when the U.S. Dollar weakens and the weaker exchange rates of the current year are used to translate the results of operations of Avnet’s subsidiaries denominated in foreign currencies, the resulting impact is an increase in U.S. Dollars of reported results. In the discussion that follows, results excluding this impact, primarily for subsidiaries in EMEA and Asia, are referred to as “constant currency.”\nIn addition to disclosing financial results that are determined in accordance with generally accepted accounting principles in the U.S. (“GAAP”), the Company also discloses certain non-GAAP financial information, including:\nYears Ended June 27, June 29, June 30, 2020 2019 2018 (Thousands) Operating (loss) income $  (4,628) $  365,911 $  209,218 Restructuring, integration and other expenses  81,870  108,144  145,125 Goodwill and intangible asset impairment expenses  144,092  137,396  181,440 Amortization of acquired intangible assets and other  81,555  84,257  91,923 Adjusted operating income $  302,889 $  695,708 $  627,706\n22\nItem 7.  Management’s Discussion and Analysis of Financial Condition and Results of Operations"}]}
+{"image": "doclay/doclay_74391.jpg", "conversations": [{"from": "human", "value": "<image>\nDigitize all text present in this image, maintaining the original structure."}, {"from": "gpt", "value": "\nPlease see pages 189 and 190 for a list of significant subsidiaries and incorporated joint ventures of Sasol Limited.\nNote:\n11\nSasol Technology Sasol Technology is our business partner in the fields of research and development, technology and innovation, engineering and project management. The company fulfils a strategic role by helping Sasol businesses worldwide to pursue growth and continuous improvement opportunities and to promote competitive advantage through appropriate technology solutions and services. Sasol Synfuels  International Sasol Synfuels International (SSI) develops and implements international ventures based on the integrated, three-step Sasol Slurry Phase Distillate (SPD™) process for GTL conversion. SSI also explores, for international beneficiation, opportunities based on coal and other hydrocarbon sources that could entail the use of competitive Sasol Fischer-Tropsch synthesis technology. Sasol Petroleum International Sasol Petroleum International (SPI) develops and manages our international upstream interests in oil and gas exploration and production from offices at London and Johannesburg. These interests are concentrated in Mozambique, South Africa, Gabon, Nigeria and Equatorial Guinea. SPI is developing Mozambique’s Temane and Pande fields in preparation for the production of natural gas in 2004. It is also producing oil off the coast of Gabon. Sasol Financing Sasol Financing is responsible for managing group cash and liquidity, in-house banking, domestic and international financing arrangements, foreign exchange, treasury risk and general treasury matters.\nSasol Nitro Sasol Nitro manufactures and markets ammonia, nitric acid and ammonium nitrate-based products, including commercial explosives, fertilisers and related chemicals, as well as specialised blasting accessories, at Sasolburg, Secunda, Bronkhorstspruit and other sites. It manufactures phosphoric acid at Phalaborwa and a phosphate detergent at Meyerton, and markets on behalf of other businesses their production of sulphur and speciality gases. Other chemical businesses Includes Sasol Infrachem, Merisol and African Amines. Sasol Wax Sasol Wax operates wax manufacturing, blending and marketing operations in South Africa, Germany, the Netherlands, the United Kingdom, Austria, Norway, the USA and China. The division also has marketing and sales operations in France, Denmark, Malaysia, Australia and Venezuela. External turnover 3 810 Operating profit 253 Rm External turnover 4 663 Operating profit 149 Rm"}]}
+{"image": "doclay/doclay_31578.jpg", "conversations": [{"from": "human", "value": "<image>\nPerform complete text extraction from this image, section by section."}, {"from": "gpt", "value": "\nFigure 4: Main graph: Spectral noise density of a 0.4N/m cantilever measured with a digital lock-in amplifier. For this noise measurement, no external excitation was applied to the cantilever and the motion of the cantilever was measured using the beam-deflection technique. The larger (red) points correspond to experimental noise data, the solid line to a fit assuming a constant offset and a Lorenz function (see main text) and the smaller (pink) points show the error between this fit and the measured data points. Inset: Log-Log plot of the total noise as a function of bandwidth for a noise measurement centered at the peak of the main noise curve. For small bandwidth, the frequency noise shows the typical 1 /a$_{os}$ behavior (slope -1 in the Log-Log plot). However, for high bandwidth ( bw > ν$_{0}$/Q , with Q quality factor) the total noise saturates.\n22"}]}
+{"image": "doclay/doclay_68697.jpg", "conversations": [{"from": "human", "value": "<image>\nTranscribe every readable text element from this image."}, {"from": "gpt", "value": "4.6.3 Viewing the local port mask\n4.7 Other administrative procedures\n4.7.1 Removing a node from a clustered system\nTo view the local port mask for the system, use the  lssystem  command, as shown in  Example 4-2.\nThis section describes other administrative procedures.\nIn the GUI go to  Monitoring →  System  and complete the following steps to remove a node:\nFigure 4-47 Displaying node details138  Implementing the IBM System Storage SAN Volume Controller with IBM Spectrum Virtualize V8.2.1\nExample 4-2 Viewing the local port mask\nIBM_Storwize:ITSO:superuser>lssystem id 000001003D600126 name ITSO location local partnership ... ... local_fc_port_mask 0000000000000000000000000000000000000000000000000000000000001111 partner_fc_port_mask 1111111111111111111111111111111111111111111111111111111111111111 ...\n1. Click on the right arrow in the representation of the node that you want to remove, as  shown in Figure 4-47. "}]}