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EP_3500042_B1 (1).png | EP3500042B1 | SYSTEM AND METHOD FOR IMPROVING TRANSMISSION IN WIRELESS NETWORKS | [
"FIG2"
] | [
"FIG2 illustrates a system according to an embodiment of the invention"
] | [
"FIG2 illustrates a system 200 according to an embodiment of the disclosure. The system 200 includes a first network 202 and a second network 206. The first network 202 includes one or more first network devices 204, and the second network includes one or more second network devices 208. In FIG2, the boundary of th... | 11 | 343 | null | H | [
{
"element_identifier": "210",
"terms": [
"overlapping network channels"
]
},
{
"element_identifier": "214",
"terms": [
"have second network channels"
]
},
{
"element_identifier": "202",
"terms": [
"first network"
]
},
{
"element_identifier": "20... | ['9. The method according to any of claims 1 to 8, wherein the threshold is determined based on evaluating min ( T LBT (1 - λ ), π ( ρ ) T LBT ), wherein T LBT is the fixed duration of time, λ is a load of the first network transmitter, and π ( ρ ) is a fraction of transmission opportunities on the channel.', '14. A system for operating a plurality of wireless networks, comprising: at least a first wireless transmitter operable in at least a first wireless network which has overlapping frequency bands with a second wireless network, the first wireless transmitter being configured to: monitor activity in the overlapping frequency bands; determine whether a channel in the overlapping frequency bands is idle for a predefined time period; based on the channel being idle for the predefined time period, determine that the first wireless transmitter has a transmission opportunity on the channel; measure an amount of time until a next frame boundary on the channel; based on the amount of time until the next frame boundary being below a threshold, reserve the channel for a fixed duration of time and transmit data at the next frame boundary; and based on the amount of time until the next frame boundary being above the threshold, skip the transmission opportunity on the channel and wait for a next transmission opportunity.'] | false | [
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EP_3500042_B1 (2).png | EP3500042B1 | SYSTEM AND METHOD FOR IMPROVING TRANSMISSION IN WIRELESS NETWORKS | [
"FIG3"
] | [
"FIG3 is a flow diagram for data transmission according to an embodiment of the invention"
] | [
"FIG3 is a flow diagram 300 for data transmission according to an embodiment of the disclosure. At step 302, the first network device 204 monitors activity in the overlapping frequency bands, for example, in one channel of the overlapping network channels 210. At step 304, the first network device 204 determines wh... | 15 | 94 | flow diagram | H | [
{
"element_identifier": "802",
"terms": [
"IEEE"
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},
{
"element_identifier": "8",
"terms": [
"andFIG."
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},
{
"element_identifier": "301",
"terms": [
"ETSI's EN"
]
},
{
"element_identifier": "18",
"terms": [
"clause"
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{
... | ['8. The method according to any of claims 1 to 7, wherein the threshold is determined based on an activity level in the overlapping frequency bands.', '9. The method according to any of claims 1 to 8, wherein the threshold is determined based on evaluating min ( T LBT (1 - λ ), π ( ρ ) T LBT ), wherein T LBT is the fixed duration of time, λ is a load of the first network transmitter, and π ( ρ ) is a fraction of transmission opportunities on the channel.', '10. The method according to any of claims 1 to 9, wherein the first wireless network is a Long-Term Evolution, LTE, network and the overlapping frequency bands comprises unlicensed National Information Infrastructure, NII, channels.', '14. A system for operating a plurality of wireless networks, comprising: at least a first wireless transmitter operable in at least a first wireless network which has overlapping frequency bands with a second wireless network, the first wireless transmitter being configured to: monitor activity in the overlapping frequency bands; determine whether a channel in the overlapping frequency bands is idle for a predefined time period; based on the channel being idle for the predefined time period, determine that the first wireless transmitter has a transmission opportunity on the channel; measure an amount of time until a next frame boundary on the channel; based on the amount of time until the next frame boundary being below a threshold, reserve the channel for a fixed duration of time and transmit data at the next frame boundary; and based on the amount of time until the next frame boundary being above the threshold, skip the transmission opportunity on the channel and wait for a next transmission opportunity.'] | false | [
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EP_3500042_B1 (6).png | EP3500042B1 | SYSTEM AND METHOD FOR IMPROVING TRANSMISSION IN WIRELESS NETWORKS | [
"FIG7"
] | [
"FIG7 shows exemplary simulation results according to an embodiment of the invention"
] | [
"The obtained results are plotted in FIG7. FIG7 shows individual throughput gain with respect to legacy Wi-Fi when an LBT WN shares the medium with 5 background Wi-Fi WNs, whose offered load increases. It can be seen that 3GPP LAA negatively impacts on Wi-Fi even when lightly loaded. This is more obvious when the f... | 12 | 172 | null | H | [
{
"element_identifier": "300",
"terms": [
"flow diagram"
]
},
{
"element_identifier": "7",
"terms": [
"where in",
"if"
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},
{
"element_identifier": "200",
"terms": [
"system"
]
}
] | ['14. A system for operating a plurality of wireless networks, comprising: at least a first wireless transmitter operable in at least a first wireless network which has overlapping frequency bands with a second wireless network, the first wireless transmitter being configured to: monitor activity in the overlapping frequency bands; determine whether a channel in the overlapping frequency bands is idle for a predefined time period; based on the channel being idle for the predefined time period, determine that the first wireless transmitter has a transmission opportunity on the channel; measure an amount of time until a next frame boundary on the channel; based on the amount of time until the next frame boundary being below a threshold, reserve the channel for a fixed duration of time and transmit data at the next frame boundary; and based on the amount of time until the next frame boundary being above the threshold, skip the transmission opportunity on the channel and wait for a next transmission opportunity.'] | false | [
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EP_3500065_B1 (3).png | EP3500065B1 | INDUCTION HEATING CELLS COMPRISING TENSIONING MEMBERS WITH NON-MAGNETIC METAL CORES | [
"FIG4"
] | [
"FIG4 illustrates an example of arranging multiple tensioning members in a die, in accordance with some examples"
] | [
"In some examples, first tensioning member 130 is a part of first group 137 as, for example, schematically shown in FIG4. All tensioning members 130 of first group 137 are parallel to each other (e.g., extend in X direction). Furthermore, tensioning members 130 of first group 137 may be distributed throughout die i... | 18 | 70 | schematic | B | [
{
"element_identifier": "137",
"terms": [
"first group"
]
},
{
"element_identifier": "126",
"terms": [
"forming surface"
]
},
{
"element_identifier": "120",
"terms": [
"die"
]
},
{
"element_identifier": "130",
"terms": [
"tensioning mem... | ['1. An induction heating cell (100) comprising: a die (120), wherein the die comprises a first side (122) and a second side (124), the die further comprising a forming surface (126); an induction heater (140), wherein at least a portion of the induction heater is disposed adjacent to the forming surface of the die, the induction heater being configured to generate heat using a magnetic field; and a first tensioning member (130), wherein: the first tensioning member extends through the die between and past the first side and the second side of the die and along a first direction (102), the first tensioning member comprises multiple strands (132), each of the multiple strands comprises a non-magnetic metal core (134), a largest cross-sectional dimension of the non-magnetic metal core is less than an induction heating threshold for the magnetic field, and each of the multiple strands is electrically insulated from any other one of the multiple strands.', '10. The induction heating cell according to any of claims 1-9, wherein the first tensioning member is a part of a first group (137) of tensioning members, and wherein the first tensioning members of the first group of tensioning members are parallel to each other.'] | false | [
"126",
"120",
"16",
"120",
"130",
"130",
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"4"
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EP_3500065_B1 (4).png | EP3500065B1 | INDUCTION HEATING CELLS COMPRISING TENSIONING MEMBERS WITH NON-MAGNETIC METAL CORES | [
"FIG5"
] | [
"FIG5 illustrates an example of arranging two sets of tensioning members in a die, in accordance with some examples"
] | [
"In some examples, induction heating cell 100 further comprises second tensioning member 160 extending through die 120 parallel to plane 104 as, for example, shown in FIG5. The direction, along which second tensioning member 160 extends, is referred to as a transverse direction or the Y-direction. The projection of... | 20 | 184 | schematic | B | [
{
"element_identifier": "17",
"terms": [
"supports INTERNATIONAL PAPER CO"
]
},
{
"element_identifier": "5",
"terms": [
"about",
"second side can be"
]
},
{
"element_identifier": "160",
"terms": [
"second tensioning member"
]
},
{
"element_... | ['1. An induction heating cell (100) comprising: a die (120), wherein the die comprises a first side (122) and a second side (124), the die further comprising a forming surface (126); an induction heater (140), wherein at least a portion of the induction heater is disposed adjacent to the forming surface of the die, the induction heater being configured to generate heat using a magnetic field; and a first tensioning member (130), wherein: the first tensioning member extends through the die between and past the first side and the second side of the die and along a first direction (102), the first tensioning member comprises multiple strands (132), each of the multiple strands comprises a non-magnetic metal core (134), a largest cross-sectional dimension of the non-magnetic metal core is less than an induction heating threshold for the magnetic field, and each of the multiple strands is electrically insulated from any other one of the multiple strands.', '9. The induction heating cell according to any of claims 1-8, wherein the non-magnetic metal core has a resistivity of at least about 2.6 × 10 -8 Ohm-meter.'] | false | [
"17",
"104",
"120",
"130",
"5",
"160"
] | |
EP_3500065_B1 (6).png | EP3500065B1 | INDUCTION HEATING CELLS COMPRISING TENSIONING MEMBERS WITH NON-MAGNETIC METAL CORES | [
"FIG8"
] | [
"FIG8 illustrates a block diagram of an example of an aircraft, in accordance with some examples "
] | [
"As shown in FIG8, aircraft 902 produced by illustrative method 900 includes airframe 918 with plurality of systems 920, and interior 922. Examples of high-level systems 920 include one or more of propulsion system 924, electrical system 926, hydraulic system 928, and environmental system 930. Any number of other s... | 17 | 90 | block diagram | B | [
{
"element_identifier": "926",
"terms": [
"electrical system"
]
},
{
"element_identifier": "900",
"terms": [
"method"
]
},
{
"element_identifier": "908",
"terms": [
"manufacturing"
]
},
{
"element_identifier": "904",
"terms": [
"design"... | ['14. A method of operating an induction heating cell of any of claims 1-13, the method comprising: a step of applying heat to a part (190) disposed inside the induction heating cell, wherein: the heat is applied by the induction heater using a magnetic field; and a step of applying pressure to the part disposed over a forming surface of the die, wherein the first tensioning member applies a compressive force to the die while applying the pressure to the part.'] | true | [
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] | |
EP_3500146_B1.png | EP3500146B1 | VACUUM CLEANER NOZZLE HAVING ROTATABLE BRUSH | [
"FIG1",
" FIG3"
] | [
"FIG1 shows a first embodiment of a rotatable brush for use in a vacuum cleaner nozzle in accordance with the invention ",
"FIG3 shows an embodiment of a vacuum cleaner comprising a vacuum cleaner nozzle in accordance with the invention "
] | [
"A first embodiment of a rotatable brush for use in a vacuum cleaner nozzle in accordance with the invention is shown in FIG1. The rotation around an axis A is caused by a motor which is connected to the rotatable brush B by way of gears or pulley that drive a wheel W. The rotatable brush B has a transparent light ... | 39 | 428 | embodiment | A | [] | ['1. A vacuum cleaner nozzle (N) comprising: a rotatable brush (B) comprising a light distribution mechanism for distributing light from the rotatable brush (B); a transparent screen (S) through which a user can see the rotatable brush (B); and a drive unit for rotating the rotatable brush (B); characterized by a sensor for measuring a rotation speed of the rotatable brush (B), and a controller for controlling the light distributed from the rotatable brush (B) in dependence on the rotation speed of the rotatable brush (B).'] | true | [
"97",
"1",
"2",
"3"
] | |
EP_3500158_B1 (2).png | EP3500158B1 | CATHETER WITH VARIABLE RADIUS LOOP AND METHOD OF MANUFACTURE | [
"FIG4"
] | [
"FIG4 is a transverse cross-section taken along line A-A in FIG1 "
] | [
"It is contemplated that the radius of curvature of the loop of distal region 16 may be adjustable, for example to conform to the varying sizes of pulmonary vein ostia of patients of different ages. This additional control may be provided, for example, via the use of an activation wire 26, shown in FIG4, that is ad... | 15 | 163 | transverse cross-sectional view | A | [
{
"element_identifier": "18",
"terms": [
"neck region"
]
},
{
"element_identifier": "28",
"terms": [
"wire"
]
},
{
"element_identifier": "30",
"terms": [
"constraint"
]
},
{
"element_identifier": "26",
"terms": [
"wire"
]
}
] | ['1. A catheter (10) comprising: a catheter body (12) having a proximal region (14), a neck region (18), and a distal region (16) predisposed into at least a partial loop disposed in a plane; a handle (22) joined to the proximal region and including an actuator (24); an activation wire (26) coupled to the actuator (24) and to the distal region (16) such that, when a user actuates the actuator (24), the activation wire (26) is activated to cause the at least a partial loop of the distal region (16) to vary in radius; a shape memory wire (28) extending through the neck region (18) and at least a portion of the distal region (16) and shaping the portion of the distal region (16) into the at least a partial loop; and a tube-shaped constraint (30) within the neck region (18) that prevents nodding of the neck region (18) when the activation wire (26) is activated, characterized in that the activation wire (26) and the shape memory wire (28) are constrained within the constraint (30).'] | false | [
"18",
"28",
"30",
"26",
"11"
] | |
EP_3500171_B1 (2).png | EP3500171B1 | MODEL REGULARIZED MOTION COMPENSATED MEDICAL IMAGE RECONSTRUCTION | [
"FIG3",
" FIG4"
] | [
"FIG3 diagrammatically illustrates an embodiment of masked reconstructed motion phase image ",
"FIG4 illustrates an example in a frontal view and a side view of a visceral cavity model fitted in an image of a subject and the corresponding visceral cavity model in a separate view"
] | [
"With reference to FIG3, an embodiment of masked reconstructed motion phase image 300 is diagrammatically illustrated. The masked reconstructed motion phase image 300 is constructed from a reconstructed motion phase volumetric image 228. The masked reconstructed motion phase image 300 includes the segmented anatomi... | 45 | 263 | embodiment, nan | A | [
{
"element_identifier": "310",
"terms": [
"masked portions"
]
},
{
"element_identifier": "420",
"terms": [
"visceral cavity model"
]
},
{
"element_identifier": "430",
"terms": [
"separate view"
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},
{
"element_identifier": "220",
"terms": [
... | ['1. A medical imaging system (200), comprising: a masking unit (234) configured to construct a mask for each reconstructed volumetric phase image of a plurality of reconstructed volumetric phase images that masks portions of a corresponding image external to an anatomical model fitted to a segmented at least one anatomical structure, wherein the plurality of reconstructed volumetric phase images include a target phase and a plurality of temporal neighboring phases reconstructed from projection data; an image registration unit (238) configured to register the masked reconstructed volumetric phase images; a motion estimator (240) configured to estimate motion between the target phase and the plurality of temporal neighboring phases according to the model based on the registered masked reconstructed volumetric phase images; and a motion compensating reconstructor (244) configured to reconstruct a motion compensated medical image from the projection data using the estimated motion of the registered masked reconstructed volumetric phase images.', '7. The system according to claim 6, wherein the visceral cavity model includes a surface that encloses inner organs of a subject and excludes bones and surrounding tissues.'] | true | [
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"4",
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] | |
EP_3500171_B1 (3).png | EP3500171B1 | MODEL REGULARIZED MOTION COMPENSATED MEDICAL IMAGE RECONSTRUCTION | [
"FIG5"
] | [
"FIG5 flowcharts an embodiment of a method of model regularized motion compensated medical image reconstruction "
] | [
"With reference to FIG5, an embodiment of a method of model regularized motion compensated CT reconstruction is flowcharted. At 500, projection data 212 is received. The projection data 212 can be received directly from the CT scanner 210. The projection data 212 can be received from a storage subsystem, such as th... | 15 | 68 | null | A | [
{
"element_identifier": "100",
"terms": [
"torso"
]
},
{
"element_identifier": "102",
"terms": [
"visceral cavity"
]
},
{
"element_identifier": "104",
"terms": [
"metal object"
]
},
{
"element_identifier": "106",
"terms": [
"streak arti... | ['1. A medical imaging system (200), comprising: a masking unit (234) configured to construct a mask for each reconstructed volumetric phase image of a plurality of reconstructed volumetric phase images that masks portions of a corresponding image external to an anatomical model fitted to a segmented at least one anatomical structure, wherein the plurality of reconstructed volumetric phase images include a target phase and a plurality of temporal neighboring phases reconstructed from projection data; an image registration unit (238) configured to register the masked reconstructed volumetric phase images; a motion estimator (240) configured to estimate motion between the target phase and the plurality of temporal neighboring phases according to the model based on the registered masked reconstructed volumetric phase images; and a motion compensating reconstructor (244) configured to reconstruct a motion compensated medical image from the projection data using the estimated motion of the registered masked reconstructed volumetric phase images.', '3. The system according to either one of claims 1 and 2, further including: a vessel enhancing filter (242) configured to enhance vascular structures in the reconstructed volumetric phase images.', '7. The system according to claim 6, wherein the visceral cavity model includes a surface that encloses inner organs of a subject and excludes bones and surrounding tissues.', '8. The system according to any one claims 1-7, further including: a CT scanner (210) configured to acquire the projection data within a single rotation of an x-ray radiation source about a subject.', '14. A non-transitory computer-readable storage medium carrying software which controls one or more processors (250) to perform the method according to any one of claims 11-'] | false | [
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EP_3500223_B1.png | EP3500223B1 | BACKSTOP AND GEAR-SHIFT ARRANGEMENT FOR A WHEELCHAIR WHEEL | [
"FIG1"
] | [
"FIG1 illustrates schematically a wheelchair with a wheel provided with a backstop arrangement according to the present invention"
] | [
"The present invention relates to a wheelchair and more specifically to the main driving wheels of a wheelchair. An exemplifying wheelchair is depicted in FIG1, wherein a wheelchair 1 essentially comprises a seat 2, a back 3, a foot support 4, and two wheels 5. Each of the two wheels 5 is provided with an outer gri... | 18 | 379 | schematic | A | [
{
"element_identifier": "14",
"terms": [
"space"
]
},
{
"element_identifier": "3",
"terms": [
"back"
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},
{
"element_identifier": "2",
"terms": [
"Canadian patent publication No.",
"seat"
]
},
{
"element_identifier": "5",
"terms": [
... | ['1. A wheel assembly comprising a wheel (5) for a wheelchair (1) and a backstop arrangement (10; 30; 70), the wheel (5) being provided with a wheel hub (11; 31; 71) and a wheel axle (12; 32; 72), the backstop arrangement (10; 30; 70) being configured to selectively engage and disengage, respectively, a backstop function, the backstop arrangement comprising a backstop selector (15; 35; 75) and a backstop member (18; 38; 78), wherein the wheel hub (11; 31; 71) has an inner rotatable circumferential surface (13; 33; 73), which faces the wheel axle (12; 32; 72) and is arranged with a radial space (14; 34; 74) therefrom, and the backstop selector (15; 35; 75) is operatively connected to the backstop member (18; 38; 78), which is radially moveable within the radial space (14; 34; 74), to, upon movement of the backstop selector (15; 35; 75), be selectively engaged with or disengaged from the inner circumferential surface (13; 33; 73), and that the backstop member (18; 38; 78) is configured, when in engagement with the inner circumferential surface (13; 33; 73), to allow the inner circumferential surface (13; 33;73) to rotate in a first direction and to prevent the inner circumferential surface (13; 33; 73) from rotating in a second, opposite direction, wherein the wheel assembly further comprises a gear-shift arrangement, characterized in that the wheel hub (11; 31; 71) is an internal-gear hub (11; 31; 71) comprising a number of internal gears (57, 58); the gear-shift arrangement comprises a shift member (54), which is axially moveable within the internal-gear hub (31) to engage a specific gear of said number of internal gears (57, 58), and wherein the shift member (54) via a connector member (55) is operatively connected to the backstop selector (15; 35; 75 ), such that the backstop selector (15, 35, 75) can be regarded as a gear and backstop selector.'] | false | [
"5",
"3",
"2",
"14"
] | |
EP_3500226_B1 (6).png | EP3500226B1 | SECURED MEDICATION TRANSFER SYSTEM | [
"FIG15"
] | [
"FIG15 is a perspective view of a fourth exemplary vial adaptor coupled to a vial"
] | [
"Referring next to FIG15, a fourth exemplary vial adaptor 400 is shown for use with vial 10. Vial adaptor 400 is similar to the above-described vial adaptor 300, with like reference numerals identifying like elements, except as described below. The illustrative vial adaptor 400 includes a cleaning passageway 430 in... | 15 | 123 | perspective view | A | [
{
"element_identifier": "400",
"terms": [
"vial adaptor"
]
},
{
"element_identifier": "25",
"terms": [
"about"
]
}
] | ['1. A vial adaptor (100) configured for use with a vial (10) containing a medication and a needle assembly (150) having a needle, the vial adaptor comprising: a substantially hollow body (101) configured to couple with the vial, the body including a side wall (102) and an upper wall (108); a needle opening (120) in the body, the needle opening being arranged along an axis and being sized and shaped to receive the needle along the axis to withdraw the medication from the vial; a cleaning passageway (130) in the body, the cleaning passageway having an inlet (131) in the side wall and being sized and shaped to receive a cleaning device to clean the vial; and a shroud (132) extending outward from the body to block needle insertion into the vial through the cleaning passageway, the side wall deviating radially outwardly to follow the path of the shroud wherein the inlet deviates radially outwardly from a lower end (136) of the inlet to an upper end (138) of the inlet.', '4. The vial adaptor of claim 1, wherein the shroud extends from the axis of the needle opening by a distance of about 20 millimeters to about 30 millimeters.'] | false | [
"400",
"15",
"25"
] | |
EP_3500306_B1 (2).png | EP3500306B1 | TRIPLE COMBINATION OF HISTAMINE-3 RECEPTOR INVERSE AGONISTS, ACETYLCHOLINESTERASE INHIBITORS AND NMDA RECEPTOR ANTAGONIST | [
"FIG2"
] | [
"FIG2 depicts the effect of compound 1 in combination with donepezil and memantine on extracellular levels of acetylcholine in medial prefrontal cortex of male Wistar rats"
] | [
"Treatment with donepezil and memantine produced increase in acetylcholine levels to the maximum of 1726 ± 297 % of basal levels. The increase in acetylcholine after combination of compound 1, donepezil and memantine was significantly higher compared to donepezil and memantine combination. Mean maximum increase in ... | 26 | 105 | null | A | [
{
"element_identifier": "1",
"terms": [
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},
{
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"terms": [
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},
{
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},
{
"element_identifier": "0",
"terms"... | ["8. The compound, N-[4-(1-Cyclobutylpiperidin-4-yloxy)phenyl]-2-(morpholin-4-yl)acetamide or a pharmaceutically acceptable salt thereof for use in combination with acetylcholinesterase inhibitor and NMDA receptor antagonist for the treatment of Alzheimer's disease in a patient, and preferably wherein the use is an adjunct treatment for Alzheimer's disease in a patient on stable treatment with acetylcholinesterase inhibitor and NMDA receptor antagonist."] | false | [
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EP_3500306_B1 (3).png | EP3500306B1 | TRIPLE COMBINATION OF HISTAMINE-3 RECEPTOR INVERSE AGONISTS, ACETYLCHOLINESTERASE INHIBITORS AND NMDA RECEPTOR ANTAGONIST | [
"FIG3"
] | [
"FIG3 depicts the effect of compound 2 in combination with donepezil and memantine on extracellular levels of acetylcholine in medial prefrontal cortex of male Wistar rats"
] | [
"Treatment with donepezil and memantine produced increase in acetylcholine levels to the maximum of 1365 ± 249 % of basal levels. The increase in acetylcholine after combination of compound 2, donepezil and memantine was significantly higher compared to donepezil and memantine combination. Mean maximum increase in ... | 26 | 105 | null | A | [
{
"element_identifier": "24",
"terms": [
"wall."
]
},
{
"element_identifier": "3",
"terms": [
"compound",
"compounds"
]
},
{
"element_identifier": "10",
"terms": [
"were positioned"
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},
{
"element_identifier": "1",
"terms": [
"co... | ["8. The compound, N-[4-(1-Cyclobutylpiperidin-4-yloxy)phenyl]-2-(morpholin-4-yl)acetamide or a pharmaceutically acceptable salt thereof for use in combination with acetylcholinesterase inhibitor and NMDA receptor antagonist for the treatment of Alzheimer's disease in a patient, and preferably wherein the use is an adjunct treatment for Alzheimer's disease in a patient on stable treatment with acetylcholinesterase inhibitor and NMDA receptor antagonist."] | false | [
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EP_3500306_B1 (4).png | EP3500306B1 | TRIPLE COMBINATION OF HISTAMINE-3 RECEPTOR INVERSE AGONISTS, ACETYLCHOLINESTERASE INHIBITORS AND NMDA RECEPTOR ANTAGONIST | [
"FIG4"
] | [
"FIG4 depicts the effect of compound 3 in combination with donepezil and memantine on extracellular levels of acetylcholine in medial prefrontal cortex of male Wistar rats"
] | [
"Treatment with donepezil and memantine produced increase in acetylcholine levels to the maximum of 1375 ± 461 % of basal levels. The increase in acetylcholine after combination of compound 3, donepezil and memantine was significantly higher compared to donepezil and memantine combination. Mean maximum increase in ... | 26 | 103 | null | A | [
{
"element_identifier": "5",
"terms": [
"patient"
]
},
{
"element_identifier": "10",
"terms": [
"were positioned"
]
}
] | ["7. The combination as claimed in any one of the claim 1 to 6, for use in the treatment of cognitive disorders in a patient, preferably wherein the cognitive disorder is selected from Alzheimer's disease, schizophrenia, Parkinson's disease, Lewy body dementia, vascular dementia, frontotemporal dementia, Down syndrome and Tourette's syndrome."] | false | [
"4000",
"3000",
"2000",
"1000",
"5",
"10",
"40",
"80",
"120",
"160",
"200",
"240",
"2400",
"25"
] | |
EP_3500306_B1 (5).png | EP3500306B1 | TRIPLE COMBINATION OF HISTAMINE-3 RECEPTOR INVERSE AGONISTS, ACETYLCHOLINESTERASE INHIBITORS AND NMDA RECEPTOR ANTAGONIST | [
"FIG5"
] | [
"FIG5 depicts the effect of compound 1 in combination with donepezil and memantine on evoked theta levels in dorsal hippocampus of anesthetized male Wistar rats "
] | [
"Treatment with donepezil and memantine combination produced moderate increase in hippocampal θ power. Compound 1 in combination with donepezil and memantine produced significant increase in θ power levels and peak levels reached up to 167 ± 11 % of pre-dose levels. The effect in triple combination was observed to ... | 25 | 103 | null | A | [
{
"element_identifier": "100",
"terms": [
"about",
"R-α-methylhistamine",
"dialysate basal concentrations with"
]
},
{
"element_identifier": "5",
"terms": [
"patient"
]
},
{
"element_identifier": "60",
"terms": [
"about",
"another"
]
... | ["7. The combination as claimed in any one of the claim 1 to 6, for use in the treatment of cognitive disorders in a patient, preferably wherein the cognitive disorder is selected from Alzheimer's disease, schizophrenia, Parkinson's disease, Lewy body dementia, vascular dementia, frontotemporal dementia, Down syndrome and Tourette's syndrome."] | false | [
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"50",
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"70",
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"100",
"110",
"120",
"100",
"47",
"26"
] | |
EP_3500379_B1 (5).png | EP3500379B1 | PROCESSES FOR RECOVERING SAND AND ACTIVE CLAY FROM FOUNDRY WASTE | [
"FIG9"
] | [
"FIG9 depicts visual results of an evaluation of rinser/shaker tests on a Plant A sand stream using a pre-slurry"
] | [
"FIG9 depicts visual results of an evaluation of rinser/shaker tests on a Plant A sand stream using a pre-slurry. The feed to the rinser/shaker table was a slurry of the sand that was 30% solids. As in the no pre-slurry case, as the sand moves through each rinse, the clay and carbon are removed from the surface of ... | 23 | 89 | null | B | [
{
"element_identifier": "50",
"terms": [
"about"
]
},
{
"element_identifier": "10",
"terms": [
"stream"
]
},
{
"element_identifier": "2",
"terms": [
"stream"
]
},
{
"element_identifier": "1",
"terms": [
"stream",
"Set"
]
},
... | ['1. A method of reclaiming clean sand and active clay from foundry waste comprising: providing dust and sand from a molding process in a foundry, wherein the dust and sand comprise clay including active clay and dead clay; rinsing a slurry comprising the dust and sand to remove clay from the sand and dust, wherein the rinsing comprises rinsing the slurry at least one time, wherein the clay is separated as a first clay slurry; removing additional clay from the rinsed slurry by shaking the rinsed slurry on a shaker table, wherein the additional clay is separated as a second clay slurry, wherein a clean sand slurry is removed from an end of the shaker table; allowing the dead clay to separate as solids from the first and second clay slurry to form an active clay slurry; recycling the active clay slurry to a muller in a foundry; and recycling clean sand from the clean sand slurry to the foundry.'] | false | [
"38"
] | |
EP_3500379_B1 (6).png | EP3500379B1 | PROCESSES FOR RECOVERING SAND AND ACTIVE CLAY FROM FOUNDRY WASTE | [
"FIG10"
] | [
"FIG10 depicts visual results of an evaluation of rinser/shaker tests on a Plant A dust stream with no pre-slurry"
] | [
"FIG10 depicts visual results of an evaluation of rinser/shaker tests on a Plant A dust stream with no pre-slurry. The feed to the rinser/shake table was dry dust feed. Raw dust was used as input to the rinser/shaker and samples were taken and tested after the first, second, third, fourth, and fifth rinse. The raw ... | 23 | 129 | null | B | [
{
"element_identifier": "50",
"terms": [
"about"
]
},
{
"element_identifier": "10",
"terms": [
"stream"
]
},
{
"element_identifier": "2",
"terms": [
"stream"
]
},
{
"element_identifier": "1",
"terms": [
"stream",
"Set"
]
},
... | ['1. A method of reclaiming clean sand and active clay from foundry waste comprising: providing dust and sand from a molding process in a foundry, wherein the dust and sand comprise clay including active clay and dead clay; rinsing a slurry comprising the dust and sand to remove clay from the sand and dust, wherein the rinsing comprises rinsing the slurry at least one time, wherein the clay is separated as a first clay slurry; removing additional clay from the rinsed slurry by shaking the rinsed slurry on a shaker table, wherein the additional clay is separated as a second clay slurry, wherein a clean sand slurry is removed from an end of the shaker table; allowing the dead clay to separate as solids from the first and second clay slurry to form an active clay slurry; recycling the active clay slurry to a muller in a foundry; and recycling clean sand from the clean sand slurry to the foundry.'] | false | [
"39",
"10"
] | |
EP_3500383_B1 (5).png | EP3500383B1 | POWER SKIVING PRESSURE ANGLE CORRECTION WITHOUT TOOL GEOMETRY CHANGE | [
"FIG6"
] | [
"FIG6 shows the reference profile and one involute of a cutting blade before and after a corrective radial shift"
] | [
"FIG6 shows the reference profile 34 and the involute 30 generated by the reference profile 34, respectively by unrolling the virtual cord I*b from the base circle 39. The involute triangle I*b → R*b → (DOtool/2-ΔR) enables the determination of the pressure angle at point 32 with: α+Δα = arccos[Rb* / (DOtool/2-ΔR)]... | 19 | 66 | null | B | [
{
"element_identifier": "35",
"terms": [
"involute"
]
},
{
"element_identifier": "30",
"terms": [
"involute"
]
},
{
"element_identifier": "39",
"terms": [
"base circle"
]
},
{
"element_identifier": "37",
"terms": [
"involute reference l... | ['4. The method of claim 1 wherein changing said initial radial position of said cutting blades comprises shifting the position of each of said plurality of cutting blades in the lengthwise direction thereof.'] | false | [
"36",
"37",
"31",
"35",
"30",
"34",
"33",
"39",
"32",
"2",
"26",
"2",
"15"
] | |
EP_3500422_B1 (1).png | EP3500422B1 | A METHOD FOR MANUFACTURING CONTACT LENSES | [
"FIG2"
] | [
"FIG2 is a flow chart showing a method of manufacturing a contact lens in accordance with a first example method"
] | [
"FIG2 shows a flow chart of an example method of manufacturing a contact lens. In a first step a tubular mold having a diameter corresponding to the diameter of the finished contact lens is assembled 50. To produce the rod a predetermined quantity of liquid lens precursor composition is first poured 52a into the mo... | 20 | 238 | flowchart | B | [
{
"element_identifier": "103",
"terms": [
"mold"
]
},
{
"element_identifier": "2",
"terms": [
"electronic devices"
]
},
{
"element_identifier": "56",
"terms": [
"is removed"
]
},
{
"element_identifier": "104",
"terms": [
"device",
... | ['3. A method according to any previous claim, wherein manufacturing the rod (101) of lens material comprises curing a quantity of liquid lens precursor composition (105) containing an electronic component (104) in a mold (103).', '7. A method according to any previous claim, wherein the electronic component (104) forms part of a curved electronic device.', '8. A method according to claim 4, further comprising a final cure in which the curing process is completed for more than one of the lengths of the rod (101) simultaneously.'] | true | [
"50",
"103",
"105",
"56",
"104",
"104",
"58",
"09",
"62",
"2",
"10"
] | |
EP_3500422_B1.png | EP3500422B1 | A METHOD FOR MANUFACTURING CONTACT LENSES | [
"FIG1"
] | [
"FIG1 is a schematic view of a rod of contact lens material in accordance with a first example embodiment"
] | [
"With reference to the drawings, FIG1 shows a schematic view of a rod 1 of lens material in accordance with a first example embodiment. The rod has a circular cross section and incorporates four electronic devices 2. The electronic devices 2 are spaced equidistantly apart along the longitudinal axis of the rod 1. L... | 19 | 77 | schematic view | B | [
{
"element_identifier": "2",
"terms": [
"electronic devices"
]
},
{
"element_identifier": "1",
"terms": [
"rod"
]
}
] | ['1. A method of manufacturing a contact lens, the method comprising manufacturing a rod (101) of lens material, the rod (101) containing a plurality of electronic components (104) spaced apart along its length, separating the rod (101) into at least one lens blank containing at least one of said electronic components (104), and machining the front and/or back surface of the lens blank to produce a contact lens (110) containing the at least one electronic component (104), CHARACTERISED IN THAT : manufacturing the rod (101) of lens material comprises producing a first length of rod (101a) including a first one of a plurality of electronic components (104) and then producing a second length of the rod (101b), said second length including a second one of the plurality of electronic components (104).'] | false | [
"2",
"1"
] | |
EP_3500497_B1 (2).png | EP3500497B1 | OPEN-WALLED PACK | [
"FIG3"
] | [
"FIG3 is a side view of the pack of FIG1"
] | [
"FIG3 is a view of the pack 100 showing the second wall 108 and first opening 114. The first opening 114 is primarily in the side of the cuboid corresponding to the second wall 108. As shown, the first opening 114 extends from the top 102 of the pack 100 downward to an upper edge 302 of the second wall 108 in a dir... | 10 | 139 | side view | B | [
{
"element_identifier": "306",
"terms": [
"diagonal"
]
},
{
"element_identifier": "304",
"terms": [
"distance"
]
},
{
"element_identifier": "118",
"terms": [
"product",
"products"
]
},
{
"element_identifier": "102",
"terms": [
"to... | ['1. A pack (100) comprising: a unitary blank (400) folded into a rectangular cuboid, the rectangular cuboid defining: a bottom (104); a top (102) approximately parallel to and opposite of the bottom; and four walls (106,108,110,112) approximately perpendicular to and disposed between the top and the bottom, the four walls including a first wall (106), a second wall (108), a third wall (110), and a fourth wall (112), the first wall opposite of the third wall, and the second wall opposite of the fourth wall, wherein the second wall defines a first opening (114) into the interior of the cuboid and the fourth wall defines a second opening (116) into the interior of the cuboid, and characterised in that the first and second openings extend from the first wall to the third wall of the cuboid in a direction parallel to a bottom plane of the cuboid and from the top to an upper edge of the second and fourth walls respectively in a direction normal to the bottom plane of the cuboid and wherein the upper edge of the second and fourth walls is disposed at a height of 50 percent or greater of a distance from the bottom to the top of the cuboid.'] | false | [
"102",
"118",
"306",
"114",
"106",
"110",
"304",
"108",
"14"
] | |
EP_3500497_B1 (6).png | EP3500497B1 | OPEN-WALLED PACK | [
"FIG9"
] | [
"FIG9 is a top view of the pack of FIG1 with the first and second top flap folded over the top"
] | [
"Once the first top flap 432 is folded inward, the second top flap 434 can be folded inward over the first top flap 432. In particular, the second top flap 434 can be folded to an orientation that is perpendicular to the wall panels 406, 408, 410, 412 and covers at least a portion of the products in the pack 100, w... | 21 | 196 | view | B | [
{
"element_identifier": "420",
"terms": [
"wall fold lines"
]
},
{
"element_identifier": "440",
"terms": [
"tab"
]
},
{
"element_identifier": "416",
"terms": [
"top fold line",
"top fold lines"
]
},
{
"element_identifier": "452",
"terms... | ['1. A pack (100) comprising: a unitary blank (400) folded into a rectangular cuboid, the rectangular cuboid defining: a bottom (104); a top (102) approximately parallel to and opposite of the bottom; and four walls (106,108,110,112) approximately perpendicular to and disposed between the top and the bottom, the four walls including a first wall (106), a second wall (108), a third wall (110), and a fourth wall (112), the first wall opposite of the third wall, and the second wall opposite of the fourth wall, wherein the second wall defines a first opening (114) into the interior of the cuboid and the fourth wall defines a second opening (116) into the interior of the cuboid, and characterised in that the first and second openings extend from the first wall to the third wall of the cuboid in a direction parallel to a bottom plane of the cuboid and from the top to an upper edge of the second and fourth walls respectively in a direction normal to the bottom plane of the cuboid and wherein the upper edge of the second and fourth walls is disposed at a height of 50 percent or greater of a distance from the bottom to the top of the cuboid.', '2. The pack of claim 1, wherein the top (102) includes a first top flap (432) and a second top flap (434) disposed over at least a portion of the first top flap, the first top flap integral with a third wall (110) of the cuboid and the second top flap integral with a first wall (106) of the cuboid, wherein the second top flap includes an intermediate panel (436) parallel with the first top flap and defined by a fold with the third wall and by a mid-flap fold (446) with a distal panel (438) of the second top flap, the distal panel of the second top flap disposed over at least a portion of and parallel to the third wall and fastened thereto.', '3. The pack of claim 2, wherein the distal panel (438) of the second top flap (434) defines a tab (440), wherein the third wall (110) of the cuboid defines a slot (442), wherein the distal panel is fastened to the third wall by insertion of the tab into the slot.', '10. The pack of any of claims 2-9, comprising: a line of weakness (452) defined between the tab (440) and a remaining portion of the distal panel (438), the line of weakness configured to break to separate the tab from the remaining portion of the distal panel thereby unfastening the second top flap (434) from the third wall (110).'] | false | [
"112",
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"436",
"438",
"452",
"440",
"106",
"420",
"408",
"422",
"108",
"10",
"104",
"20"
] | |
EP_3500682_B1 (4).png | EP3500682B1 | CLOSED LINEAR DNA PRODUCTION | [
"FIG10A",
" FIG10B"
] | [
"FIG10A shows the linear sequence of introduced stem loop used in Example 1 This also shows the primers used in Example 1 and the binding position in the loop is shown ",
"FIG10B is a photograph of an 0 8% agarose gel of TelN digest of amplified products produced from different priming strategies"
] | [
"Preferably, the central section of the motif or loop includes a sequence for a primer binding site. A primer binding site is a region of a nucleotide sequence where a primer binds or anneals to start replication. The primer specifically anneals to the primer binding site due to the complementary nature of their se... | 53 | 639 | null | C | [
{
"element_identifier": "15",
"terms": [
"priming site",
"ID NO",
"DNA concentrations determined at"
]
},
{
"element_identifier": "3",
"terms": [
"protelomerase recognition sequences",
"Version",
"Table"
]
},
{
"element_identifier": "2",
"t... | ['9. A method as claimed in any preceding claim wherein said template comprises one or more additional protelomerase recognition sequences.'] | true | [
"15",
"1",
"2",
"3",
"3",
"6",
"75"
] | |
EP_3500682_B1 (5).png | EP3500682B1 | CLOSED LINEAR DNA PRODUCTION | [
"FIG11"
] | [
"FIG11 depicts a plasmid map for the vectors used in Example 1 Various components are depicted"
] | [
"Production of stem loop closed linear DNA from a plasmid template. Table 1 below shows the conditions under which plasmid proTLx-K B5X4 eGFP 53SL (see FIG11) was amplified. RCA reactions were setup at room temperature and reagents added in the order indicated. Reactions were carried out in polypropylene tubes and ... | 16 | 147 | null | C | [
{
"element_identifier": "1",
"terms": [
"in Example"
]
},
{
"element_identifier": "2",
"terms": [
"protelomerase recognition sequences",
"Example",
"reaction was then diluted"
]
},
{
"element_identifier": "3",
"terms": [
"protelomerase recognitio... | ['1. A cell-free method of producing closed linear deoxyribose nucleic acid (DNA) molecules comprising: (a) contacting a template comprising linear, double stranded DNA molecule covalently closed at each end by a portion of a protelomerase recognition sequence and comprising at least one stem loop motif with a strand-displacing polymerase under conditions promoting amplification of said template in the presence of at least one primer which is capable of binding specifically to a primer binding site within said stem loop motif; (b) contacting the DNA produced in (a) with at least one protelomerase under conditions promoting production of closed linear DNA.', '9. A method as claimed in any preceding claim wherein said template comprises one or more additional protelomerase recognition sequences.', '11. A linear, double stranded DNA molecule covalently closed at each end by a portion of a protelomerase recognition sequence, wherein the sequence of said linear, double stranded DNA molecule includes at least one stem loop motif, preferably wherein said stem loop motif is as described in any one of claims 2 to'] | false | [
"3500",
"3500",
"3000",
"500",
"3680",
"500",
"3762",
"76",
"11"
] | |
EP_3500867_B1 (1).png | EP3500867B1 | BUILT-IN EYE SCAN FOR ADC-BASED RECEIVER | [
"FIG2"
] | [
"FIG2 is a block diagram depicting the receiver according to an example"
] | [
"The receiver 126 generally includes analog-to-digital converter (ADC) circuitry 104 and eye scan circuitry 106. An example structure of the receiver 126 is described further below with respect to FIG2. The receiver 126 receives an analog signal from the transmission medium 160. The ADC circuitry 104 generates a di... | 12 | 345 | block diagram | G | [
{
"element_identifier": "210",
"terms": [
"clock generator"
]
},
{
"element_identifier": "214",
"terms": [
"CTLE"
]
},
{
"element_identifier": "202",
"terms": [
"front end"
]
},
{
"element_identifier": "216",
"terms": [
"ADCs"
]
}... | ['1. A method of performing an eye-scan in a receiver (126), comprising: generating digital samples from an analog signal input to the receiver (126) based on a sampling clock, the sampling clock phase-shifted with respect to a reference clock based on a phase interpolator, PI, code; equalizing the digital samples based on first equalization parameters of a plurality of equalization parameters of the receiver (126); adapting the plurality of equalization parameters and performing clock recovery based on the digital samples to generate the PI code; performing a plurality of cycles of locking the plurality of equalization parameters, suspending phase detection in the clock recovery, offsetting the PI code by different amounts across the plurality of cycles, collecting an output of the receiver (126), resuming the phase detection in the clock recovery, and unlocking the equalization parameters to perform the eye scan.', '8. A receiver (126), comprising: a front end (202) configured to receive an analog signal; analog-to-digital converter, ADC, circuitry (104) configured to generate digital samples from the analog signal based on a sampling clock; a digital signal processor, DSP (204) configured to equalize the digital samples based on first equalization parameters of a plurality of equalization parameters; a clock recovery circuit (206) configured to perform clock recovery based on the digital samples to generate a phase interpolator, PI, code; a PI (208) configured to generate the sampling clock based on the PI code; an adaptation circuit (205) configured to adapt the plurality of equalization parameters; and an eye scan circuit (106) configured to control a plurality of cycles of locking the plurality of equalization parameters, suspending phase detection in the clock recovery of the clock recovery circuit (206), offsetting the PI code by different amounts across the plurality of cycles, collecting the digital samples, resuming the phase detection in the clock recovery of the clock recovery circuit (206), and unlocking the equalization parameters.'] | false | [
"126",
"106",
"210",
"208",
"206",
"202",
"212",
"104",
"216",
"204",
"218",
"220",
"214",
"205",
"13"
] | |
EP_3500867_B1 (2).png | EP3500867B1 | BUILT-IN EYE SCAN FOR ADC-BASED RECEIVER | [
"FIG3"
] | [
"FIG3 is a block diagram depicting clock recovery and eye scan circuitry according to an example"
] | [
"FIG3 is a block diagram depicting clock recovery and eye scan circuitry according to an example. The clock recovery circuit 206 includes a phase detector 302 and a digital loop filter 330. The eye scan circuitry 106 includes a control circuit 316, a multiplexer 304, and a multiplexer 326. An input of the phase det... | 16 | 130 | block diagram | G | [
{
"element_identifier": "327",
"terms": [
"phase path"
]
},
{
"element_identifier": "310",
"terms": [
"adder"
]
},
{
"element_identifier": "306",
"terms": [
"gain circuit",
"gain circuits"
]
},
{
"element_identifier": "304",
"terms": [
... | ['1. A method of performing an eye-scan in a receiver (126), comprising: generating digital samples from an analog signal input to the receiver (126) based on a sampling clock, the sampling clock phase-shifted with respect to a reference clock based on a phase interpolator, PI, code; equalizing the digital samples based on first equalization parameters of a plurality of equalization parameters of the receiver (126); adapting the plurality of equalization parameters and performing clock recovery based on the digital samples to generate the PI code; performing a plurality of cycles of locking the plurality of equalization parameters, suspending phase detection in the clock recovery, offsetting the PI code by different amounts across the plurality of cycles, collecting an output of the receiver (126), resuming the phase detection in the clock recovery, and unlocking the equalization parameters to perform the eye scan.', '2. The method of claim 1, wherein the step of performing the clock recovery comprises: performing the phase detection based on the digital samples to generate a phase error signal; filtering the phase error signal through a digital loop filter (330) to generate the PI code.', '3. The method of claim 2, wherein the step of suspending the phase detection comprises: disconnecting an output of a phase detector (302) configured to perform the phase detection from an input of the digital loop filter (330).'] | false | [
"327",
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"330",
"304",
"324",
"208",
"326",
"302",
"318",
"310",
"312",
"308",
"320",
"322",
"14",
"328",
"316"
] | |
EP_3500867_B1 (3).png | EP3500867B1 | BUILT-IN EYE SCAN FOR ADC-BASED RECEIVER | [
"FIG4"
] | [
"FIG4 is a flow diagram depicting a method of performing an eye scan in a receiver according to an example"
] | [
"FIG4 is a flow diagram depicting a method 400 of performing an eye scan in a receiver according to an example. The method 400 can be performed by the SerDes 122 described above. The method 400 begins at step 402, where the control circuit 316 selects an initial offset for the PI code to be used during the eye scan... | 20 | 77 | flow diagram | G | [
{
"element_identifier": "420",
"terms": [
"step"
]
},
{
"element_identifier": "416",
"terms": [
"adaptation process. At step"
]
},
{
"element_identifier": "412",
"terms": [
"at step"
]
},
{
"element_identifier": "422",
"terms": [
"step"... | ['1. A method of performing an eye-scan in a receiver (126), comprising: generating digital samples from an analog signal input to the receiver (126) based on a sampling clock, the sampling clock phase-shifted with respect to a reference clock based on a phase interpolator, PI, code; equalizing the digital samples based on first equalization parameters of a plurality of equalization parameters of the receiver (126); adapting the plurality of equalization parameters and performing clock recovery based on the digital samples to generate the PI code; performing a plurality of cycles of locking the plurality of equalization parameters, suspending phase detection in the clock recovery, offsetting the PI code by different amounts across the plurality of cycles, collecting an output of the receiver (126), resuming the phase detection in the clock recovery, and unlocking the equalization parameters to perform the eye scan.', '2. The method of claim 1, wherein the step of performing the clock recovery comprises: performing the phase detection based on the digital samples to generate a phase error signal; filtering the phase error signal through a digital loop filter (330) to generate the PI code.'] | false | [
"400",
"402",
"404",
"406",
"408",
"410",
"412",
"414",
"416",
"418",
"420",
"422",
"4",
"15"
] | |
EP_3500867_B1 (4).png | EP3500867B1 | BUILT-IN EYE SCAN FOR ADC-BASED RECEIVER | [
"FIG5"
] | [
"FIG5 illustrates an example eye plot for a binary non-return-to-zero (NRZ) signal"
] | [
"FIG5 illustrates an example eye plot 500 for a binary NRZ signal. The eye plot 500 is formed from the various digital samples collected during the eye scan cycles described above. The eye plot 500 shows the data eye for a UI 502. During each eye scan cycle, the PI code is offset to scan across an axis 504 represen... | 20 | 128 | plot | G | [
{
"element_identifier": "504",
"terms": [
"axis"
]
},
{
"element_identifier": "500",
"terms": [
"eye plot"
]
},
{
"element_identifier": "502",
"terms": [
"UI"
]
}
] | ['7. The method of any of claims 1-6, wherein the plurality of cycles are performed until the PI code has been updated to cover at least one unit interval, UI, of the analog signal.'] | false | [
"500",
"502",
"5",
"504",
"16"
] | |
EP_3500867_B1.png | EP3500867B1 | BUILT-IN EYE SCAN FOR ADC-BASED RECEIVER | [
"FIG1"
] | [
"FIG1 is a block diagram depicting an example of a serial communication system"
] | [
"FIG1 is a block diagram depicting an example of a serial communication system 100. The serial communication system 100 comprises a transmitter 112 coupled to a receiver 126 over transmission medium 160. The transmitter 112 can be part of a serializer-deserializer (SerDes) 116. The receiver 126 can be part of a Ser... | 13 | 346 | block diagram | G | [
{
"element_identifier": "122",
"terms": [
"SerDes"
]
},
{
"element_identifier": "160",
"terms": [
"transmission medium"
]
},
{
"element_identifier": "128",
"terms": [
"circuitry"
]
},
{
"element_identifier": "116",
"terms": [
"SerDes"
... | ['1. A method of performing an eye-scan in a receiver (126), comprising: generating digital samples from an analog signal input to the receiver (126) based on a sampling clock, the sampling clock phase-shifted with respect to a reference clock based on a phase interpolator, PI, code; equalizing the digital samples based on first equalization parameters of a plurality of equalization parameters of the receiver (126); adapting the plurality of equalization parameters and performing clock recovery based on the digital samples to generate the PI code; performing a plurality of cycles of locking the plurality of equalization parameters, suspending phase detection in the clock recovery, offsetting the PI code by different amounts across the plurality of cycles, collecting an output of the receiver (126), resuming the phase detection in the clock recovery, and unlocking the equalization parameters to perform the eye scan.', '8. A receiver (126), comprising: a front end (202) configured to receive an analog signal; analog-to-digital converter, ADC, circuitry (104) configured to generate digital samples from the analog signal based on a sampling clock; a digital signal processor, DSP (204) configured to equalize the digital samples based on first equalization parameters of a plurality of equalization parameters; a clock recovery circuit (206) configured to perform clock recovery based on the digital samples to generate a phase interpolator, PI, code; a PI (208) configured to generate the sampling clock based on the PI code; an adaptation circuit (205) configured to adapt the plurality of equalization parameters; and an eye scan circuit (106) configured to control a plurality of cycles of locking the plurality of equalization parameters, suspending phase detection in the clock recovery of the clock recovery circuit (206), offsetting the PI code by different amounts across the plurality of cycles, collecting the digital samples, resuming the phase detection in the clock recovery of the clock recovery circuit (206), and unlocking the equalization parameters.'] | false | [
"100",
"116",
"112",
"122",
"126",
"104",
"106",
"128",
"160",
"110",
"120",
"12"
] | |
EP_3500908_B1 (4).png | EP3500908B1 | SUPPORTING AN AUGMENTED-REALITY SOFTWARE APPLICATION | [
"FIG8"
] | [
"FIG8 shows another embodiment of the processing means comprised in the computing device for supporting an AR software application"
] | [
"In FIG8 an alternative embodiment 800 of processing means 125 is illustrated. Similar to processing means 700, processing means 800 comprises one or more interfaces 801 (\"I/O\" in FIG8) for controlling and/or receiving information from other components comprised in computing device 120/500/600, such as camera 121... | 19 | 325 | embodiment | G | [
{
"element_identifier": "801",
"terms": [
"interfaces"
]
},
{
"element_identifier": "704",
"terms": [
"computer-executable instructions"
]
},
{
"element_identifier": "701",
"terms": [
"interfaces"
]
},
{
"element_identifier": "802",
"terms": ... | ['1. A computing device (120; 500; 600) for supporting an Augmented-Reality, AR, software application, the computing device comprising processing means (125) being operative to: for each one of at least two candidate physical locations (131, 132; 231, 232) for placing a current virtual object (104; 204), where the current virtual object appears to be placed when overlaid onto a video sequence capturing a physical scene (100; 200) in the surroundings of a user (110) of the AR software application: determine an expected physical location to which the user moves, or where the user remains, in response to displaying (123; 223) the physical scene and the overlaid current virtual object to the user, and evaluate a value of an attribute which is related to a performance of a wireless connection utilized by the AR software application, and which is spatially dependent in the surroundings of the user, at the expected physical location, and select the physical location for placing the current virtual object from the at least two candidate physical locations based on a superior performance of the wireless connection for the selected physical location.', '17. A computer program (704) comprising computer-executable instructions for causing a device to perform the method according to claim 16, when the computer-executable instructions are executed on a processing unit (702) comprised in the device.'] | true | [
"7",
"700",
"704",
"701",
"8",
"800",
"802",
"801",
"21"
] | |
EP_3500923_B1 (1).png | EP3500923B1 | COLLECTING ENTROPY FROM DIVERSE SOURCES | [
"FIG2"
] | [
"FIG2 illustrates foiling an eavesdropper in accordance with an embodiment"
] | [
"FIG2 illustrates foiling an eavesdropper in a typical use case. Entropy source 202 is compromised by a determined entity. For example, the manufacturer of a hardware-based entropy generator 202 may have conceded data to a government that shows that the entropy generator is slightly skewed. The government may be ab... | 10 | 70 | null | G | [
{
"element_identifier": "210",
"terms": [
"timers"
]
},
{
"element_identifier": "202",
"terms": [
"source",
"entropy generator"
]
},
{
"element_identifier": "242",
"terms": [
"PRNG"
]
},
{
"element_identifier": "262",
"terms": [
"... | ['1. A method for generating entropy in a computing device, the method comprising: setting a repeating first timer for a first frequency; setting a repeating second timer for a second frequency; collecting a predetermined number of first bits from a first entropy source at the first frequency, the predetermined number based on an amount of entropy per bit attributable to the first entropy source; presenting the first bits to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source at the second frequency, the specified number based on an amount of entropy per bit attributable to the second entropy source; and presenting the second bits to the pseudo-random number generator, whereby the first and second bits can be used to seed the pseudo-random number generator.', '14. A method for seeding entropy in a pseudo-random number generator, the method comprising: setting asynchronous timers of different frequencies; collecting a predetermined number of first bits from a first entropy source according to a first timer of the asynchronous timers; calculating a Hamming distance between successive collected first bits; accepting the first bits into a first accumulation buffer based on the Hamming distance exceeding a minimum; summing Hamming distances between successive collections of first bits into an accumulated value of entropy attributed to contents of the first accumulation buffer; presenting contents of the first accumulation buffer to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source according to a second timer of the asynchronous timers; accepting the second bits into a second accumulation buffer, the second accumulation buffer having a different size than a size of the first accumulation buffer; and presenting contents of the second accumulation buffer to the pseudo-random number generator.'] | false | [
"200",
"202",
"204",
"210",
"242",
"208",
"260",
"258",
"256",
"254",
"262",
"47"
] | |
EP_3500923_B1 (2).png | EP3500923B1 | COLLECTING ENTROPY FROM DIVERSE SOURCES | [
"FIG3"
] | [
"FIG3 is a sequence diagram in accordance with an embodiment"
] | [
"FIG3 is a sequence diagram for system 300 with time running from top to bottom. At a first time, source 302 supplies entropy 318a to entropy collector 306. That entropy is forwarded as seed 336a immediately to PRNG 342. At periodic time intervals following, at frequency 308, entropies 318b, 318c, 318d, 318e, 318f,... | 10 | 99 | sequence diagram | G | [
{
"element_identifier": "310",
"terms": [
"at frequency",
"frequencies",
"frequency"
]
},
{
"element_identifier": "338",
"terms": [
"seed"
]
},
{
"element_identifier": "334",
"terms": [
"accumulation buffer"
]
},
{
"element_identifier... | ['1. A method for generating entropy in a computing device, the method comprising: setting a repeating first timer for a first frequency; setting a repeating second timer for a second frequency; collecting a predetermined number of first bits from a first entropy source at the first frequency, the predetermined number based on an amount of entropy per bit attributable to the first entropy source; presenting the first bits to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source at the second frequency, the specified number based on an amount of entropy per bit attributable to the second entropy source; and presenting the second bits to the pseudo-random number generator, whereby the first and second bits can be used to seed the pseudo-random number generator.', '8. The method of claim 1 further comprising: accepting the first bits into an accumulation buffer upon the collecting; and presenting the first bits from the accumulation buffer to the pseudo-random number generator upon the accumulation buffer becoming full, thereby providing a greater amount of sudden entropy than in a single collection of first bits.'] | false | [
"300",
"30",
"334",
"308",
"3189",
"34",
"310",
"334",
"348",
"334",
"334",
"338",
"334",
"48"
] | |
EP_3500923_B1 (3).png | EP3500923B1 | COLLECTING ENTROPY FROM DIVERSE SOURCES | [
"FIG4"
] | [
"FIG4 is a timing diagram with two entropy source sampling frequencies in accordance with an embodiment"
] | [
"FIG4 is a timing diagram with two entropy source sampling frequencies in accordance with an embodiment. A representation of first timer 408 is shown at the top of the figure. Every leading edge or downward edge represents a timer event. Nominally, first timer 408 fires at every vertical line. In the figure, the pu... | 16 | 92 | diagram | G | [
{
"element_identifier": "4",
"terms": [
"required"
]
},
{
"element_identifier": "414",
"terms": [
"random jitter"
]
},
{
"element_identifier": "410",
"terms": [
"second timer"
]
},
{
"element_identifier": "408",
"terms": [
"first timer"... | ['1. A method for generating entropy in a computing device, the method comprising: setting a repeating first timer for a first frequency; setting a repeating second timer for a second frequency; collecting a predetermined number of first bits from a first entropy source at the first frequency, the predetermined number based on an amount of entropy per bit attributable to the first entropy source; presenting the first bits to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source at the second frequency, the specified number based on an amount of entropy per bit attributable to the second entropy source; and presenting the second bits to the pseudo-random number generator, whereby the first and second bits can be used to seed the pseudo-random number generator.'] | false | [
"414",
"408",
"49",
"410",
"4"
] | |
EP_3500923_B1 (4).png | EP3500923B1 | COLLECTING ENTROPY FROM DIVERSE SOURCES | [
"FIG5"
] | [
"FIG5 is a flowchart illustrating a process in accordance with an embodiment"
] | [
"FIG5 is a flowchart illustrating process 500 in accordance with an embodiment. The process can be implemented by computer by executing instructions in a processor or otherwise. In operation 501, a repeating time for a first frequency is set. In operation 502, a repeating second timer for a second frequency is set,... | 12 | 237 | flowchart | G | [
{
"element_identifier": "32",
"terms": [
"OpenSSL reads"
]
},
{
"element_identifier": "256",
"terms": [
"decryption key"
]
},
{
"element_identifier": "1",
"terms": [
"OpenSSL version"
]
},
{
"element_identifier": "0",
"terms": [
">"
... | ['1. A method for generating entropy in a computing device, the method comprising: setting a repeating first timer for a first frequency; setting a repeating second timer for a second frequency; collecting a predetermined number of first bits from a first entropy source at the first frequency, the predetermined number based on an amount of entropy per bit attributable to the first entropy source; presenting the first bits to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source at the second frequency, the specified number based on an amount of entropy per bit attributable to the second entropy source; and presenting the second bits to the pseudo-random number generator, whereby the first and second bits can be used to seed the pseudo-random number generator.', '3. The method of claim 2 wherein the adjusting of the first frequency is based on an output from the pseudo-random number generator.', '14. A method for seeding entropy in a pseudo-random number generator, the method comprising: setting asynchronous timers of different frequencies; collecting a predetermined number of first bits from a first entropy source according to a first timer of the asynchronous timers; calculating a Hamming distance between successive collected first bits; accepting the first bits into a first accumulation buffer based on the Hamming distance exceeding a minimum; summing Hamming distances between successive collections of first bits into an accumulated value of entropy attributed to contents of the first accumulation buffer; presenting contents of the first accumulation buffer to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source according to a second timer of the asynchronous timers; accepting the second bits into a second accumulation buffer, the second accumulation buffer having a different size than a size of the first accumulation buffer; and presenting contents of the second accumulation buffer to the pseudo-random number generator.'] | false | [
"500",
"501",
"502",
"503",
"505",
"504",
"506",
"507",
"50"
] | |
EP_3500923_B1 (5).png | EP3500923B1 | COLLECTING ENTROPY FROM DIVERSE SOURCES | [
"FIG6"
] | [
"FIG6 is a flowchart illustrating a process in accordance with an embodiment"
] | [
"FIG6 is a flowchart illustrating process 600 in accordance with an embodiment. The process can be implemented by computer by executing instructions in a processor or otherwise. In operation 601, asynchronous timers of different frequencies from one another that are not, in this case, harmonics of each other are se... | 12 | 249 | flowchart | G | [
{
"element_identifier": "32",
"terms": [
"OpenSSL reads"
]
},
{
"element_identifier": "256",
"terms": [
"decryption key"
]
},
{
"element_identifier": "1",
"terms": [
"OpenSSL version"
]
},
{
"element_identifier": "0",
"terms": [
">"
... | ['1. A method for generating entropy in a computing device, the method comprising: setting a repeating first timer for a first frequency; setting a repeating second timer for a second frequency; collecting a predetermined number of first bits from a first entropy source at the first frequency, the predetermined number based on an amount of entropy per bit attributable to the first entropy source; presenting the first bits to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source at the second frequency, the specified number based on an amount of entropy per bit attributable to the second entropy source; and presenting the second bits to the pseudo-random number generator, whereby the first and second bits can be used to seed the pseudo-random number generator.', '3. The method of claim 2 wherein the adjusting of the first frequency is based on an output from the pseudo-random number generator.', '14. A method for seeding entropy in a pseudo-random number generator, the method comprising: setting asynchronous timers of different frequencies; collecting a predetermined number of first bits from a first entropy source according to a first timer of the asynchronous timers; calculating a Hamming distance between successive collected first bits; accepting the first bits into a first accumulation buffer based on the Hamming distance exceeding a minimum; summing Hamming distances between successive collections of first bits into an accumulated value of entropy attributed to contents of the first accumulation buffer; presenting contents of the first accumulation buffer to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source according to a second timer of the asynchronous timers; accepting the second bits into a second accumulation buffer, the second accumulation buffer having a different size than a size of the first accumulation buffer; and presenting contents of the second accumulation buffer to the pseudo-random number generator.'] | false | [
"009",
"01",
"601",
"602",
"603",
"604",
"605",
"8",
"606",
"607",
"608",
"609",
"6",
"51"
] | |
EP_3500923_B1 (6).png | EP3500923B1 | COLLECTING ENTROPY FROM DIVERSE SOURCES | [
"FIG7"
] | [
"FIG7 illustrates an exemplary computer system, in which various embodiments of the present invention may be implemented "
] | [
"FIG7 illustrates an exemplary computer system 700, in which various embodiments of the present invention may be implemented. The system 700 may be used to implement any of the computer systems described above. As shown in the figure, computer system 700 includes a processing unit 704 that communicates with a numbe... | 18 | 109 | null | G | [
{
"element_identifier": "32",
"terms": [
"OpenSSL reads"
]
},
{
"element_identifier": "256",
"terms": [
"decryption key"
]
},
{
"element_identifier": "1",
"terms": [
"OpenSSL version"
]
},
{
"element_identifier": "0",
"terms": [
">"
... | ['1. A method for generating entropy in a computing device, the method comprising: setting a repeating first timer for a first frequency; setting a repeating second timer for a second frequency; collecting a predetermined number of first bits from a first entropy source at the first frequency, the predetermined number based on an amount of entropy per bit attributable to the first entropy source; presenting the first bits to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source at the second frequency, the specified number based on an amount of entropy per bit attributable to the second entropy source; and presenting the second bits to the pseudo-random number generator, whereby the first and second bits can be used to seed the pseudo-random number generator.', '3. The method of claim 2 wherein the adjusting of the first frequency is based on an output from the pseudo-random number generator.', '14. A method for seeding entropy in a pseudo-random number generator, the method comprising: setting asynchronous timers of different frequencies; collecting a predetermined number of first bits from a first entropy source according to a first timer of the asynchronous timers; calculating a Hamming distance between successive collected first bits; accepting the first bits into a first accumulation buffer based on the Hamming distance exceeding a minimum; summing Hamming distances between successive collections of first bits into an accumulated value of entropy attributed to contents of the first accumulation buffer; presenting contents of the first accumulation buffer to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source according to a second timer of the asynchronous timers; accepting the second bits into a second accumulation buffer, the second accumulation buffer having a different size than a size of the first accumulation buffer; and presenting contents of the second accumulation buffer to the pseudo-random number generator.'] | false | [
"704",
"734",
"700",
"732",
"706",
"708",
"702",
"724",
"52",
"720",
"722",
"710",
"712",
"714",
"716",
"718",
"726",
"728",
"730"
] | |
EP_3500923_B1.png | EP3500923B1 | COLLECTING ENTROPY FROM DIVERSE SOURCES | [
"FIG1"
] | [
"FIG1 illustrates an entropy module in accordance with an embodiment"
] | [
"FIG1 illustrates an entropy module in system 100. In entropy module 106, timers 108 and 110 are set up to periodically poll, or otherwise collect or gather, entropy (i.e., random bits or as otherwise known in the art) from first entropy source 102 or second entropy source 104, respectively. The frequencies of poll... | 10 | 94 | null | G | [
{
"element_identifier": "142",
"terms": [
"PRNG"
]
},
{
"element_identifier": "104",
"terms": [
"second entropy source"
]
},
{
"element_identifier": "118",
"terms": [
"entropy"
]
},
{
"element_identifier": "112",
"terms": [
"timer"
... | ['1. A method for generating entropy in a computing device, the method comprising: setting a repeating first timer for a first frequency; setting a repeating second timer for a second frequency; collecting a predetermined number of first bits from a first entropy source at the first frequency, the predetermined number based on an amount of entropy per bit attributable to the first entropy source; presenting the first bits to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source at the second frequency, the specified number based on an amount of entropy per bit attributable to the second entropy source; and presenting the second bits to the pseudo-random number generator, whereby the first and second bits can be used to seed the pseudo-random number generator.', '3. The method of claim 2 wherein the adjusting of the first frequency is based on an output from the pseudo-random number generator.', '14. A method for seeding entropy in a pseudo-random number generator, the method comprising: setting asynchronous timers of different frequencies; collecting a predetermined number of first bits from a first entropy source according to a first timer of the asynchronous timers; calculating a Hamming distance between successive collected first bits; accepting the first bits into a first accumulation buffer based on the Hamming distance exceeding a minimum; summing Hamming distances between successive collections of first bits into an accumulated value of entropy attributed to contents of the first accumulation buffer; presenting contents of the first accumulation buffer to a pseudo-random number generator; gathering a specified number of second bits from a second entropy source according to a second timer of the asynchronous timers; accepting the second bits into a second accumulation buffer, the second accumulation buffer having a different size than a size of the first accumulation buffer; and presenting contents of the second accumulation buffer to the pseudo-random number generator.'] | false | [
"100",
"118",
"102",
"108",
"26",
"118",
"130",
"114",
"112",
"106",
"140",
"142",
"150",
"144",
"146",
"148",
"16",
"128",
"110",
"238",
"120",
"46",
"120",
"104",
"138",
"334",
"132"
] | |
EP_3500965_B1 (3).png | EP3500965B1 | SPEED CONTROL FOR A FULL STOP OF AN AUTONOMOUS DRIVING VEHICLE | [
"FIG6"
] | [
"FIG6 is a flow diagram illustrating a process of making a full stop of an autonomous vehicle according to a comparative example suitable for understanding the invention"
] | [
"FIG6 is a flow diagram illustrating a process of making a full stop of an autonomous vehicle according to a comparative example suitable for understanding the invention. Process 600 may be performed by processing logic which may include software, hardware, or a combination thereof. For example, process 600 may be ... | 27 | 198 | flow diagram | B | [
{
"element_identifier": "10",
"terms": [
"given stop location.DE",
"move"
]
},
{
"element_identifier": "2",
"terms": [
"second vehicle.EP"
]
},
{
"element_identifier": "100",
"terms": [
"network configuration"
]
},
{
"element_identifier": "... | ['3. The method of claim 2, wherein the first deceleration rate (A) is determined based on the following formula: A = k ∗ V 2 /2S, wherein k is a constant, V represents the current speed (V C ), and S represents the distance (S) between the first location and the second location, preferably, the constant k is approximately 1.', '14. A data processing system, comprising: a processor (1501); and a memory (1503) coupled to the processor (1501) to store instructions, which when executed by the processor (1501), cause the processor (1501) to perform operations of operating an autonomous vehicle (101), the operations including rece iving (601) a request to decelerate an autonomous vehicle from a first location and to stop at a second location, determining (602) a first zone (501) and a second zone (503) within a distance (S) from the first location to the second location, determining a third zone (502) between the first zone (501) and the second zone (503), decelerating (603) the autonomous vehicle (101) based on a first deceleration rate from a current speed (V C ) to a predetermined speed (Vi) during the first zone (501), maintaining the predetermined speed (Vi) of the autonomous vehicle (101) as a relatively constant speed within the third zone (502), and decelerating (604) the autonomous vehicle (101) based on a second deceleration rate from the predetermined speed (Vi) to a stop during the second zone (503), wherein the first deceleration rate and the second deceleration rate are different.'] | false | [
"009",
"601",
"602",
"3",
"603",
"604",
"20"
] | |
EP_3500968_B1 (1).png | EP3500968B1 | METHOD AND APPARATUS TO SECURE AND PROTECT DATA-CENTERS AND GENERALIZED UTILITY-BASED CLOUD COMPUTING ENVIRONMENTS FROM UNINVITED GUESTS IN THE FORM OF BOTH HARDWARE AND SOFTWARE | [
"FIG2"
] | [
"FIG2 is a block diagram illustrating a node that is executing a virtual agent, according to some embodiments"
] | [
"FIG2 is a block diagram illustrating a node that is executing a virtual agent, according to some embodiments. The node 130 includes hardware resources 140 such as computing hardware 210, storage hardware 220, and networking hardware 230. The node 130 executes a hypervisor 150 or VMM that allows a virtual agent 160... | 19 | 317 | block diagram | G | [
{
"element_identifier": "230",
"terms": [
"networking hardware"
]
},
{
"element_identifier": "160",
"terms": [
"virtual agent",
"virtual agents"
]
},
{
"element_identifier": "130",
"terms": [
"node",
"nodes"
]
},
{
"element_identifier... | ['1. A method implemented by a network device communicatively coupled to a datacenter to detect a presence of unauthorized software and hardware in the datacenter, the method comprising: initiating (310) deployment of a virtual agent on a node in the datacenter, wherein the virtual agent is to perform a security scan of the node and store results of the security scan in a memory allocated to the virtual agent at the node, and wherein the results of the security scan are to be encrypted by the virtual agent using a data encryption key; and initiating (320) migration of the virtual agent to a preconfigured location that has a data decryption key for decrypting the results of the security scan, wherein the results of the security scan are to be extracted from the virtual agent and decrypted at the preconfigured location using the data decryption key.', '6. The method of claim 1, wherein the virtual agent includes a hardware access key that provides the virtual agent with permission to access one or more hardware resources of the node.', '8. The method of claim 1, wherein the security scan includes a scan of any one of a Basic Input/Output System (BIOS), a Unified Extensible Firmware Interface (UEFI), a System Center Configuration Manager or Systems Management Server (SCCM/SMS), and hypervisor installed on the node.'] | false | [
"130",
"160",
"240",
"250",
"260",
"165",
"150",
"140",
"210",
"220",
"270",
"230",
"2",
"13"
] | |
EP_3500968_B1 (2).png | EP3500968B1 | METHOD AND APPARATUS TO SECURE AND PROTECT DATA-CENTERS AND GENERALIZED UTILITY-BASED CLOUD COMPUTING ENVIRONMENTS FROM UNINVITED GUESTS IN THE FORM OF BOTH HARDWARE AND SOFTWARE | [
"FIG3"
] | [
"FIG3 is a flow diagram of a process for detecting unauthorized software and hardware in a datacenter using a virtual agent, according to some embodiments"
] | [
"FIG3 is a flow diagram of a process for detecting unauthorized software and hardware in a datacenter using a virtual agent, according to some embodiments. In one embodiment, the process may be implemented by a network device 100 (e.g., cloud orchestration component 110 of network device 100) that is communicativel... | 26 | 135 | flow diagram | G | [
{
"element_identifier": "2",
"terms": [
"Layer"
]
},
{
"element_identifier": "120",
"terms": [
"datacenter"
]
},
{
"element_identifier": "130",
"terms": [
"node",
"nodes"
]
},
{
"element_identifier": "140",
"terms": [
"hardware re... | ['4. The method of claim 3, wherein the corrective action includes any one of migrating a tenant on the node to another node in the datacenter, installing a honeypot, decommissioning of the node, moving a tenant off the node, reinstalling an image on the node, and deploying another virtual agent in the datacenter.', '6. The method of claim 1, wherein the virtual agent includes a hardware access key that provides the virtual agent with permission to access one or more hardware resources of the node.', '8. The method of claim 1, wherein the security scan includes a scan of any one of a Basic Input/Output System (BIOS), a Unified Extensible Firmware Interface (UEFI), a System Center Configuration Manager or Systems Management Server (SCCM/SMS), and hypervisor installed on the node.', '12. A network device (100) configured to detect a presence of unauthorized software and hardware in a datacenter, the network device comprising: a set of one or more processors (410); and a non-transitory machine-readable storage medium (430) having stored therein a cloud orchestration component (110), which when executed by the set of one or more processors, causes the network device to initiate deployment of a virtual agent on a node in the datacenter, wherein the virtual agent is to perform a security scan of the node and store results of the security scan in a memory allocated to the virtual agent at the node, and wherein the results of the security scan are to be encrypted by the virtual agent using a data encryption key and initiate migration of the virtual agent to a preconfigured location that has a data decryption key for decrypting the results of the security scan, wherein the results of the security scan are to be extracted from the virtual agent and decrypted at the preconfigured location using the data decryption key.'] | false | [
"14"
] | |
EP_3500968_B1 (3).png | EP3500968B1 | METHOD AND APPARATUS TO SECURE AND PROTECT DATA-CENTERS AND GENERALIZED UTILITY-BASED CLOUD COMPUTING ENVIRONMENTS FROM UNINVITED GUESTS IN THE FORM OF BOTH HARDWARE AND SOFTWARE | [
"FIG4"
] | [
"FIG4 is block diagram of a network device that can implement the detection of the presence of unauthorized software and hardware in a datacenter using a virtual agent, according to some embodiments "
] | [
"FIG4 is block diagram of a network device that can implement the detection of the presence of unauthorized software and hardware in a datacenter using a virtual agent, according to some embodiments. The network device 100 includes a set of one or more processor(s) 410, which may be general purpose and/or a special... | 33 | 170 | block diagram | G | [
{
"element_identifier": "430",
"terms": [
"machine readable storage medium"
]
},
{
"element_identifier": "100",
"terms": [
"network device"
]
},
{
"element_identifier": "110",
"terms": [
"cloud orchestration component"
]
}
] | ['12. A network device (100) configured to detect a presence of unauthorized software and hardware in a datacenter, the network device comprising: a set of one or more processors (410); and a non-transitory machine-readable storage medium (430) having stored therein a cloud orchestration component (110), which when executed by the set of one or more processors, causes the network device to initiate deployment of a virtual agent on a node in the datacenter, wherein the virtual agent is to perform a security scan of the node and store results of the security scan in a memory allocated to the virtual agent at the node, and wherein the results of the security scan are to be encrypted by the virtual agent using a data encryption key and initiate migration of the virtual agent to a preconfigured location that has a data decryption key for decrypting the results of the security scan, wherein the results of the security scan are to be extracted from the virtual agent and decrypted at the preconfigured location using the data decryption key.'] | false | [
"100",
"410",
"420",
"430",
"110",
"4",
"15"
] | |
EP_3500968_B1.png | EP3500968B1 | METHOD AND APPARATUS TO SECURE AND PROTECT DATA-CENTERS AND GENERALIZED UTILITY-BASED CLOUD COMPUTING ENVIRONMENTS FROM UNINVITED GUESTS IN THE FORM OF BOTH HARDWARE AND SOFTWARE | [
"FIG1"
] | [
"FIG1 is a block diagram of a datacenter in which a virtual agent can be deployed, according to some embodiments"
] | [
"FIG1 is a block diagram of a datacenter in which a virtual agent can be deployed, according to some embodiments. As shown, the datacenter 120 includes nodes 130A-D. Each node 130 may be an electronic device or network device that includes hardware resources such as computing hardware (e.g., processors), storage ha... | 21 | 164 | block diagram | G | [
{
"element_identifier": "160",
"terms": [
"virtual agent",
"virtual agents"
]
},
{
"element_identifier": "120",
"terms": [
"datacenter"
]
},
{
"element_identifier": "100",
"terms": [
"network device"
]
},
{
"element_identifier": "115",
... | ['4. The method of claim 3, wherein the corrective action includes any one of migrating a tenant on the node to another node in the datacenter, installing a honeypot, decommissioning of the node, moving a tenant off the node, reinstalling an image on the node, and deploying another virtual agent in the datacenter.', '6. The method of claim 1, wherein the virtual agent includes a hardware access key that provides the virtual agent with permission to access one or more hardware resources of the node.', '8. The method of claim 1, wherein the security scan includes a scan of any one of a Basic Input/Output System (BIOS), a Unified Extensible Firmware Interface (UEFI), a System Center Configuration Manager or Systems Management Server (SCCM/SMS), and hypervisor installed on the node.', '12. A network device (100) configured to detect a presence of unauthorized software and hardware in a datacenter, the network device comprising: a set of one or more processors (410); and a non-transitory machine-readable storage medium (430) having stored therein a cloud orchestration component (110), which when executed by the set of one or more processors, causes the network device to initiate deployment of a virtual agent on a node in the datacenter, wherein the virtual agent is to perform a security scan of the node and store results of the security scan in a memory allocated to the virtual agent at the node, and wherein the results of the security scan are to be encrypted by the virtual agent using a data encryption key and initiate migration of the virtual agent to a preconfigured location that has a data decryption key for decrypting the results of the security scan, wherein the results of the security scan are to be extracted from the virtual agent and decrypted at the preconfigured location using the data decryption key.'] | false | [
"100",
"115",
"110",
"4",
"160",
"165",
"150",
"140",
"120",
"1",
"12"
] | |
EP_3500986_B1 (3).png | EP3500986B1 | METHOD AND SYSTEM FOR ESTIMATING THE MASS OF A STOCKPILE | [
"FIG5a"
] | [
"FIG5a is a table of data showing the force upon a layer influences the density, while FIG5b charts data from FIG5a"
] | [
"A representative sample of material was taken and placed in a cylindrical test cell having calibrated dimensions. Details are shown in the table of FIG5a. The volume of the cylindrical test cell was 3244cm3 and the surface area of the internal footprint was 181cm2. The mass of the wheat sample was 2707.05g. The in... | 22 | 323 | table | G | [
{
"element_identifier": "7",
"terms": [
"andFigure"
]
},
{
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"terms": [
"datum"
]
},
{
"element_identifier": "2",
"terms": [
"surface"
]
},
{
"element_identifier": "6",
"terms": [
"surface"
]
},
{
"e... | ['1. A method of estimating the mass of material in a stockpile, the method including: obtaining an upper surface profile of said stockpile; the method being characterised by : defining a plurality of layers in the stockpile based on the upper surface profile, wherein each layer is defined to extend parallel to the upper surface profile, and estimating the volume of each defined layer; obtaining density characteristics of the stockpile material; estimating the density of each defined layer according to the density characteristics of the stockpile material; and calculating, using the estimated volume and estimated density of each defined layer, the mass of the stockpile.'] | false | [
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... | |
EP_3500986_B1 (5).png | EP3500986B1 | METHOD AND SYSTEM FOR ESTIMATING THE MASS OF A STOCKPILE | [
"FIG6a"
] | [
"FIG6a is a table of data showing the recorded mass of a number of stockpiles against estimated (and actual) mass values, while FIG6b charts data from FIG6a"
] | [
"FIG6a tabulates a real-world scenario in which the mass of material in a number of bunkers (column P) was to be audited for a client. The stock volume (column Q) and a density, referred to as the \"bulk density\" (column R) were provided by the client for each bunker and used to estimate the mass (column S) using ... | 30 | 75 | table | G | [
{
"element_identifier": "2",
"terms": [
"surface"
]
},
{
"element_identifier": "4",
"terms": [
"datum"
]
},
{
"element_identifier": "6",
"terms": [
"surface"
]
},
{
"element_identifier": "1m",
"terms": [
"each layer's depth was"
]
... | ['2. The method of claim 1, wherein each layer extends parallel to the upper surface profile and has a boundary, configured equidistant, in a vertical direction, from the upper surface profile.', '11. A system for estimating the mass of material in a stockpile, the system including: apparatus operable to obtaining an upper surface profile of said stockpile; the system being characterised by : a controller, configured to define a plurality of layers in the stockpile based on the upper surface profile, wherein each layer is defined to extend parallel to the upper surface profile, and estimate the volume of each defined layer; obtain density characteristics of the stockpile material; estimate the density of each defined layer, according to the density characteristics of the stockpile material; and calculate, using the estimated volume and density of each defined layer, the mass of the stockpile.', '12. A computer readable storage medium storing one or more programs, said programs having instructions, which when executed by an electronic device or system, perform a method according to any of claims 1 to'] | false | [
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EP_3501017_B1 (1).png | EP3501017B1 | MOTION SENSOR WITH ANTIMASK PROTECTION | [
"FIG2"
] | [
"FIG2 is a block diagram of a controller for the motion detector of FIG1 according to one embodiment"
] | [
"FIG2 is a block diagram of the microcontroller 125 of the motion detector 100 according to one embodiment. The microcontroller 125 includes a plurality of electrical and electronic components that provide power, operational control, and protection to the components and modules within the microcontroller 125. The m... | 18 | 117 | block diagram | G | [
{
"element_identifier": "6262661",
"terms": [
"A1. US"
]
},
{
"element_identifier": "100",
"terms": [
"motion detector"
]
},
{
"element_identifier": "105",
"terms": [
"transmission circuit"
]
},
{
"element_identifier": "110",
"terms": [
... | ['1. A motion detector (100) with antimasking capability, the motion detector (100) comprising: an antenna (131, 135); a dual-channel reception circuit (110, 115), the dual-channel reception circuit (110, 115) configured to receive a reflected radio frequency (RF) signal; and an electronic processor (205) electrically connected to the dual-channel reception circuit (110, 115) and configured to receive a first signal from a first channel (110) of the dual-channel reception circuit (110, 115) indicative of motion at a first range, receive a second signal from a second channel (115) of the dual-channel reception circuit (110, 115) indicative of motion at a second range, at least a portion of the second range being shorter than the first range, and generate a notification based on the first signal and the second signal, wherein the electronic processor (205) is configured to generate the notification by generating a trouble notification indicative of a masking attempt when the second signal indicates motion at the second range, and wherein the electronic processor (205) is configured to generate the trouble notification when the second signal is greater than a first threshold, characterized in that the electronic processor (205) is configured to adjust the first threshold to a lesser value when the first signal is indicative of motion at the first range.', '7. The motion detector (100) according to Claim 1, wherein the dual-channel reception circuit (110, 115) is controlled by a time gate circuit (120) such that the first channel (110) and the second channel (115) each receive control signals from the time gate circuit (120) simultaneously.'] | false | [
"125",
"305",
"310",
"11",
"315",
"2"
] | |
EP_3501017_B1 (2).png | EP3501017B1 | MOTION SENSOR WITH ANTIMASK PROTECTION | [
"FIG3"
] | [
"FIG3 is a timing diagram for controlling operation of the motion detector of FIG1 according to one embodiment"
] | [
"FIG3 illustrates one example of control signals for the transmission circuit 105, the first reception circuit 110, and the second reception circuit 115. The time gate circuit 120 is configured to generate multiple control signals including the transmission control signal 191 to control the shape generator 130, the... | 18 | 371 | diagram | G | [
{
"element_identifier": "6262661",
"terms": [
"A1. US"
]
},
{
"element_identifier": "100",
"terms": [
"motion detector"
]
},
{
"element_identifier": "105",
"terms": [
"transmission circuit"
]
},
{
"element_identifier": "110",
"terms": [
... | ['1. A motion detector (100) with antimasking capability, the motion detector (100) comprising: an antenna (131, 135); a dual-channel reception circuit (110, 115), the dual-channel reception circuit (110, 115) configured to receive a reflected radio frequency (RF) signal; and an electronic processor (205) electrically connected to the dual-channel reception circuit (110, 115) and configured to receive a first signal from a first channel (110) of the dual-channel reception circuit (110, 115) indicative of motion at a first range, receive a second signal from a second channel (115) of the dual-channel reception circuit (110, 115) indicative of motion at a second range, at least a portion of the second range being shorter than the first range, and generate a notification based on the first signal and the second signal, wherein the electronic processor (205) is configured to generate the notification by generating a trouble notification indicative of a masking attempt when the second signal indicates motion at the second range, and wherein the electronic processor (205) is configured to generate the trouble notification when the second signal is greater than a first threshold, characterized in that the electronic processor (205) is configured to adjust the first threshold to a lesser value when the first signal is indicative of motion at the first range.', '7. The motion detector (100) according to Claim 1, wherein the dual-channel reception circuit (110, 115) is controlled by a time gate circuit (120) such that the first channel (110) and the second channel (115) each receive control signals from the time gate circuit (120) simultaneously.'] | false | [
"191",
"192",
"193",
"12",
"194",
"195",
"1000",
"3"
] | |
EP_3501017_B1.png | EP3501017B1 | MOTION SENSOR WITH ANTIMASK PROTECTION | [
"FIG1"
] | [
"FIG1 is a block diagram of motion detector with dual-channel reception and antimasking according to one embodiment"
] | [
"FIG1 illustrates an example of a motion detector 100 with antimask protection. In the example illustrated, the motion detector 100 includes a radio frequency (RF) transmission circuit 105, a first reception circuit 110 (i.e., a first channel), and a second reception circuit 115 (i.e., a second channel). A time gat... | 19 | 172 | block diagram | G | [
{
"element_identifier": "160",
"terms": [
"second amplifier"
]
},
{
"element_identifier": "1",
"terms": [
"m"
]
},
{
"element_identifier": "193",
"terms": [
"control signal"
]
},
{
"element_identifier": "115",
"terms": [
"reception circ... | ['1. A motion detector (100) with antimasking capability, the motion detector (100) comprising: an antenna (131, 135); a dual-channel reception circuit (110, 115), the dual-channel reception circuit (110, 115) configured to receive a reflected radio frequency (RF) signal; and an electronic processor (205) electrically connected to the dual-channel reception circuit (110, 115) and configured to receive a first signal from a first channel (110) of the dual-channel reception circuit (110, 115) indicative of motion at a first range, receive a second signal from a second channel (115) of the dual-channel reception circuit (110, 115) indicative of motion at a second range, at least a portion of the second range being shorter than the first range, and generate a notification based on the first signal and the second signal, wherein the electronic processor (205) is configured to generate the notification by generating a trouble notification indicative of a masking attempt when the second signal indicates motion at the second range, and wherein the electronic processor (205) is configured to generate the trouble notification when the second signal is greater than a first threshold, characterized in that the electronic processor (205) is configured to adjust the first threshold to a lesser value when the first signal is indicative of motion at the first range.', '7. The motion detector (100) according to Claim 1, wherein the dual-channel reception circuit (110, 115) is controlled by a time gate circuit (120) such that the first channel (110) and the second channel (115) each receive control signals from the time gate circuit (120) simultaneously.'] | false | [
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"10",
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] | |
EP_3501024_B1 (1).png | EP3501024B1 | SYSTEMS, APPARATUSES, AND METHODS FOR SPEAKER VERIFICATION USING ARTIFICIAL NEURAL NETWORKS | [
"FIG2"
] | [
"FIG2 illustrates the training of an ANN based speaker verification system according to some embodiments"
] | [
"FIG2 illustrates a speaker verification system 200, according to some embodiments, in which there currently exists K enrolled speaker. As shown in FIG2, the example speaker verification system 200 includes K 2-class ANNs - - i.e., one for each of the K enrolled speakers. More specifically, FIG2 illustrates the tra... | 15 | 282 | null | G | [
{
"element_identifier": "200",
"terms": [
"system"
]
}
] | ['7. A computer system (700), which comprises at least one computer apparatus (702), adapted to: obtain (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; select (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; input (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtain (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; compare (610) the posterior probability to a predetermined threshold value; and determine (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.'] | false | [
"200",
"16"
] | |
EP_3501024_B1 (2).png | EP3501024B1 | SYSTEMS, APPARATUSES, AND METHODS FOR SPEAKER VERIFICATION USING ARTIFICIAL NEURAL NETWORKS | [
"FIG3"
] | [
"FIG3 illustrates an ANN based speaker verification system according to some embodiments"
] | [
"FIG3 illustrates a speaker verification process for system 200 in some embodiments. In the embodiment shown in FIG3, a feature vector xU, which was generated based on an utterance from an unknown speaker, is input into each of the K ANNs. Each of the K ANNs then uses xU to produce a posterior probability (PP) indi... | 12 | 182 | null | G | [
{
"element_identifier": "10",
"terms": [
"vol."
]
},
{
"element_identifier": "100",
"terms": [
"ANN"
]
},
{
"element_identifier": "800",
"terms": [
"apparatus"
]
},
{
"element_identifier": "900",
"terms": [
"apparatus"
]
},
{
... | ['1. A method (600) for speaker verification, comprising: obtaining (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; selecting (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; inputting (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtaining (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; comparing (610) the posterior probability to a predetermined threshold value; and determining (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '6. A method (400) for producing a set of trained artificial neural networks, ANNs, for use in determining the identity of an unknown speaker, comprising: obtaining (402) a feature vector, x1, created using an utterance made by a first speaker; obtaining (404) a feature vector, x_UBM, generated using a universal background model, UBM; training (406) a first two-class ANN using as inputs x1 and x_UBM to produce a first trained ANN; associating (408) the first trained ANN with the first speaker; obtaining (410) a feature vector, x2, created using an utterance made by a second speaker; training (412) a second two-class ANN using as inputs x2 and x_UBM to produce a second trained ANN; and associating (414) the second trained ANN with the second speaker.', '7. A computer system (700), which comprises at least one computer apparatus (702), adapted to: obtain (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; select (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; input (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtain (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; compare (610) the posterior probability to a predetermined threshold value; and determine (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '14. A computer program comprising instructions that, when executed on at least one processor, cause the at least one processor to carry out the method according to any one of claims 1-'] | false | [
"3",
"17"
] | |
EP_3501024_B1 (3).png | EP3501024B1 | SYSTEMS, APPARATUSES, AND METHODS FOR SPEAKER VERIFICATION USING ARTIFICIAL NEURAL NETWORKS | [
"FIG5"
] | [
"FIG5 is a flowchart illustrating a process according to some embodiments"
] | [
"FIG5 is a flow chart illustrating a process 500, according to some embodiments, for determining the identity of an unknown speaker. Process 500 may begin with step 502, in which a feature vector (xU) is obtained, wherein xU was created using an utterance made by the unknown speaker. In step 504, xU is inputted int... | 11 | 329 | flowchart | G | [
{
"element_identifier": "10",
"terms": [
"vol."
]
},
{
"element_identifier": "100",
"terms": [
"ANN"
]
},
{
"element_identifier": "800",
"terms": [
"apparatus"
]
},
{
"element_identifier": "900",
"terms": [
"apparatus"
]
},
{
... | ['1. A method (600) for speaker verification, comprising: obtaining (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; selecting (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; inputting (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtaining (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; comparing (610) the posterior probability to a predetermined threshold value; and determining (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '6. A method (400) for producing a set of trained artificial neural networks, ANNs, for use in determining the identity of an unknown speaker, comprising: obtaining (402) a feature vector, x1, created using an utterance made by a first speaker; obtaining (404) a feature vector, x_UBM, generated using a universal background model, UBM; training (406) a first two-class ANN using as inputs x1 and x_UBM to produce a first trained ANN; associating (408) the first trained ANN with the first speaker; obtaining (410) a feature vector, x2, created using an utterance made by a second speaker; training (412) a second two-class ANN using as inputs x2 and x_UBM to produce a second trained ANN; and associating (414) the second trained ANN with the second speaker.', '7. A computer system (700), which comprises at least one computer apparatus (702), adapted to: obtain (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; select (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; input (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtain (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; compare (610) the posterior probability to a predetermined threshold value; and determine (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '14. A computer program comprising instructions that, when executed on at least one processor, cause the at least one processor to carry out the method according to any one of claims 1-'] | false | [
"500",
"502",
"504",
"506",
"507",
"3",
"510",
"508",
"4",
"5",
"19"
] | |
EP_3501024_B1 (4).png | EP3501024B1 | SYSTEMS, APPARATUSES, AND METHODS FOR SPEAKER VERIFICATION USING ARTIFICIAL NEURAL NETWORKS | [
"FIG6"
] | [
"FIG6 is a flowchart illustrating a process according to some embodiments"
] | [
"FIG6 is a flow chart illustrating a process 600, according to some embodiments, for speaker verification. Process 600 may begin with step 602, in which a feature vector (xU) is obtained, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person. In step 604, an ANN spec... | 11 | 223 | flowchart | G | [
{
"element_identifier": "10",
"terms": [
"vol."
]
},
{
"element_identifier": "100",
"terms": [
"ANN"
]
},
{
"element_identifier": "800",
"terms": [
"apparatus"
]
},
{
"element_identifier": "900",
"terms": [
"apparatus"
]
},
{
... | ['1. A method (600) for speaker verification, comprising: obtaining (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; selecting (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; inputting (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtaining (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; comparing (610) the posterior probability to a predetermined threshold value; and determining (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '6. A method (400) for producing a set of trained artificial neural networks, ANNs, for use in determining the identity of an unknown speaker, comprising: obtaining (402) a feature vector, x1, created using an utterance made by a first speaker; obtaining (404) a feature vector, x_UBM, generated using a universal background model, UBM; training (406) a first two-class ANN using as inputs x1 and x_UBM to produce a first trained ANN; associating (408) the first trained ANN with the first speaker; obtaining (410) a feature vector, x2, created using an utterance made by a second speaker; training (412) a second two-class ANN using as inputs x2 and x_UBM to produce a second trained ANN; and associating (414) the second trained ANN with the second speaker.', '7. A computer system (700), which comprises at least one computer apparatus (702), adapted to: obtain (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; select (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; input (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtain (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; compare (610) the posterior probability to a predetermined threshold value; and determine (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '14. A computer program comprising instructions that, when executed on at least one processor, cause the at least one processor to carry out the method according to any one of claims 1-'] | false | [
"600",
"602",
"604",
"606",
"4",
"608",
"610",
"612",
"6",
"20"
] | |
EP_3501024_B1 (5).png | EP3501024B1 | SYSTEMS, APPARATUSES, AND METHODS FOR SPEAKER VERIFICATION USING ARTIFICIAL NEURAL NETWORKS | [
"FIG7"
] | [
"FIG7 is a block diagram of a computer system according to some embodiments"
] | [
"FIG7 is a block diagram of a computer system 700 that can be configured to perform the processes described above. As described below, computer system 700 may consist of a single computer apparatus 702 or set of computer apparatuses (i.e., computer system 700 may be a cloud computing system).",
"As shown in FIG7,... | 13 | 227 | block diagram | G | [
{
"element_identifier": "755",
"terms": [
"processors"
]
},
{
"element_identifier": "705",
"terms": [
"network interface"
]
},
{
"element_identifier": "708",
"terms": [
"data storage system"
]
},
{
"element_identifier": "702",
"terms": [
... | ['7. A computer system (700), which comprises at least one computer apparatus (702), adapted to: obtain (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; select (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; input (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtain (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; compare (610) the posterior probability to a predetermined threshold value; and determine (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '14. A computer program comprising instructions that, when executed on at least one processor, cause the at least one processor to carry out the method according to any one of claims 1-'] | false | [
"700",
"708",
"702",
"755",
"741",
"743",
"744",
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"7",
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] | |
EP_3501024_B1 (6).png | EP3501024B1 | SYSTEMS, APPARATUSES, AND METHODS FOR SPEAKER VERIFICATION USING ARTIFICIAL NEURAL NETWORKS | [
"FIG8"
] | [
"FIG8 illustrates an apparatus 800 for speaker verification according to some embodiments"
] | [
"FIG8 illustrates an apparatus 800 for speaker verification according to some embodiments. Apparatus 800 includes means for obtaining 802 a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; means for selecting 804 from a set of artificial neu... | 12 | 202 | null | G | [
{
"element_identifier": "812",
"terms": [
"determining"
]
},
{
"element_identifier": "810",
"terms": [
"comparing"
]
},
{
"element_identifier": "804",
"terms": [
"selecting"
]
},
{
"element_identifier": "802",
"terms": [
"obtaining"
... | ['1. A method (600) for speaker verification, comprising: obtaining (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; selecting (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; inputting (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtaining (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; comparing (610) the posterior probability to a predetermined threshold value; and determining (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.', '7. A computer system (700), which comprises at least one computer apparatus (702), adapted to: obtain (602) a feature vector, xU, wherein xU was created using an utterance made by an unknown speaker who claims to be a certain person; select (604) from a set of artificial neural networks, ANNs, an ANN specifically associated with the certain person, wherein the selected ANN specifically associated with the certain person was trained using only a feature vector created using an utterance made by the certain person and a feature vector, x_UBM, generated using a universal background model, UBM; input (606) xU into the selected ANN, wherein the selected ANN is configured such that in response to xU being input the selected ANN produces a posterior probability; obtain (608) the posterior probability produced by the selected ANN as a result of inputting xU into the selected ANN; compare (610) the posterior probability to a predetermined threshold value; and determine (612) whether the unknown speaker is the certain person based on the comparison of the posterior probability to the predetermined threshold value.'] | false | [
"800",
"802",
"804",
"806",
"808",
"810",
"812",
"8",
"22"
] | |
EP_3501039_B1 (2).png | EP3501039B1 | SUBSTRATE NOISE ISOLATION STRUCTURES FOR SEMICONDUCTOR DEVICES | [
"FIG3A"
] | [
"FIG3A is a plan view depicting a substrate noise isolation structure according to an example"
] | [
"FIG3A is a plan view depicting the substrate noise isolation structure 105 according to an example. In the example of FIG3A, the substrate noise isolation structure 105 includes two guard structures 106-1 and 106-2. Each guard structure 106 comprises discontinuous pairs 108 of n+ and p+ diffusion regions along the... | 15 | 153 | plan view | H | [
{
"element_identifier": "30",
"terms": [
"be"
]
},
{
"element_identifier": "100",
"terms": [
"semiconductor device"
]
},
{
"element_identifier": "101",
"terms": [
"semiconductor substrate"
]
},
{
"element_identifier": "102",
"terms": [
... | ['3. The semiconductor device of claim 2, wherein the first guard structure (106-1) is a first guard ring (506-1) formed around the first circuit (102), the first guard ring (506-1) including first and second sides formed by respective first and second sets of the first discontinuous n+ and p+ diffusions (108-1) and second and third sides formed by respective first and second portions of the first continuous diffusion.', '11. A method of manufacturing a semiconductor device, comprising: forming a first circuit (102) and a second circuit (104) in a semiconductor substrate (101); forming a first guard structure (106-1) in the semiconductor substrate (101) between the first circuit (102) and the second circuit (104), the first guard structure (106-1) including first discontinuous pairs of n+ and p+ diffusions (108-1) disposed along a first axis; and forming a second guard structure (106-2) in the semiconductor substrate (101) between the first circuit (102) and the second circuit (104), the second guard structure (106-2) including second discontinuous pairs of n+ and p+ diffusions (108-2) disposed along the first axis, the second discontinuous pairs of n+ and p+ diffusions (108-2) being staggered with respect to the first discontinuous pairs of n+ and p+ diffusions (108-1) such that gaps between the first discontinuous pairs of n+ and p+ diffusions (108-1) are not aligned with gaps between the second discontinuous pairs of n+ and p+ diffusions (108-2) along a second axis perpendicular to the first axis.'] | true | [
"108",
"14"
] | |
EP_3501080_B1 (1).png | EP3501080B1 | REACTIVE POWER PRODUCTION OF WIND TURBINE GENERATORS WITHIN WIND WAKE ZONE | [
"FIG2"
] | [
"FIG2 illustrates a wind power plant and associated controller, according to one or more embodiments"
] | [
"FIG2 illustrates a wind power plant and associated controller, according to one or more embodiments. In general, a wind power plant may also be referred to as a wind farm or wind park. The wind power plant (WPP) 200 comprises a plurality of wind turbine generators (WTGs) 100-1, 100-2, ..., 100-n (generically refer... | 16 | 138 | null | F | [
{
"element_identifier": "235",
"terms": [
"module"
]
},
{
"element_identifier": "225",
"terms": [
"memory"
]
},
{
"element_identifier": "230",
"terms": [
"wake zone determination module"
]
},
{
"element_identifier": "280",
"terms": [
"p... | ['1. A method of controlling power production of a wind power plant (WPP, 200) comprising a plurality of wind turbine generators (WTG, 100, 100-n), the method comprising: defining, based on received wind information (240, 245), a wind wake zone (232) comprising a group of first wind turbine generators of the plurality of wind turbine generators; and increasing a reactive power production of at least one of the first wind turbine generators of the wind wake zone, wherein a reactive power production is increased for at least two of the one or more first wind turbine generators, wherein an amount of reactive power increase of the at least two of the one or more first wind turbine generators is based on relative active power ratings of the at least two of the one or more first wind turbine generators, so that at least two of the one or more first wind turbine generators disposed within the wind wake zone are controlled to provide a relatively greater reactive power than wind turbine generators outside the wind wake zone (232).'] | false | [
"200",
"280",
"215",
"220",
"225",
"230",
"232",
"210",
"205",
"100",
"15",
"235",
"240",
"250",
"255",
"260",
"265",
"245",
"2"
] | |
EP_3501080_B1 (4).png | EP3501080B1 | REACTIVE POWER PRODUCTION OF WIND TURBINE GENERATORS WITHIN WIND WAKE ZONE | [
"FIG6"
] | [
"FIG6 illustrates a wind wake zone corresponding to a wind turbine generator, according to one or more embodiments"
] | [
"FIG6 illustrates a wind wake zone corresponding to a wind turbine generator, according to one or more embodiments. The arrangement 600 illustrates a two-dimensional, top-down view of a plurality of WTGs 100-1, 100-2, 100-3 of a wind power plant. Arrow 605 indicates a current wind direction as measured by one or mo... | 19 | 99 | null | F | [
{
"element_identifier": "605",
"terms": [
"Arrow"
]
},
{
"element_identifier": "100",
"terms": [
"WTGs"
]
},
{
"element_identifier": "705",
"terms": [
"group"
]
},
{
"element_identifier": "600",
"terms": [
"each provide",
"collect... | ['1. A method of controlling power production of a wind power plant (WPP, 200) comprising a plurality of wind turbine generators (WTG, 100, 100-n), the method comprising: defining, based on received wind information (240, 245), a wind wake zone (232) comprising a group of first wind turbine generators of the plurality of wind turbine generators; and increasing a reactive power production of at least one of the first wind turbine generators of the wind wake zone, wherein a reactive power production is increased for at least two of the one or more first wind turbine generators, wherein an amount of reactive power increase of the at least two of the one or more first wind turbine generators is based on relative active power ratings of the at least two of the one or more first wind turbine generators, so that at least two of the one or more first wind turbine generators disposed within the wind wake zone are controlled to provide a relatively greater reactive power than wind turbine generators outside the wind wake zone (232).'] | false | [
"600",
"605",
"615",
"232",
"6",
"700",
"232",
"705",
"100",
"605",
"100",
"18"
] | |
EP_3501080_B1.png | EP3501080B1 | REACTIVE POWER PRODUCTION OF WIND TURBINE GENERATORS WITHIN WIND WAKE ZONE | [
"FIG1"
] | [
"FIG1 illustrates a diagrammatic view of a horizontal-axis wind turbine, according to one or more embodiments"
] | [
"FIG1 illustrates a diagrammatic view of a horizontal-axis wind turbine (WTG) 100. The wind turbine 100 typically includes a tower 102 and a nacelle 104 located at the top of the tower 102. A wind turbine rotor 106 may be connected with the nacelle 104 through a low speed shaft extending out of the nacelle 104. As ... | 19 | 201 | diagrammatic view | F | [
{
"element_identifier": "7",
"terms": [
"vol."
]
},
{
"element_identifier": "3",
"terms": [
"no.",
"patent documents EP"
]
},
{
"element_identifier": "2016",
"terms": [
"July"
]
},
{
"element_identifier": "2014",
"terms": [
"Octob... | ['1. A method of controlling power production of a wind power plant (WPP, 200) comprising a plurality of wind turbine generators (WTG, 100, 100-n), the method comprising: defining, based on received wind information (240, 245), a wind wake zone (232) comprising a group of first wind turbine generators of the plurality of wind turbine generators; and increasing a reactive power production of at least one of the first wind turbine generators of the wind wake zone, wherein a reactive power production is increased for at least two of the one or more first wind turbine generators, wherein an amount of reactive power increase of the at least two of the one or more first wind turbine generators is based on relative active power ratings of the at least two of the one or more first wind turbine generators, so that at least two of the one or more first wind turbine generators disposed within the wind wake zone are controlled to provide a relatively greater reactive power than wind turbine generators outside the wind wake zone (232).', '7. A computer program product comprising a non-transitory computer-readable storage medium containing code which, when executed by one or more processors, performs an operation for controlling power production of a wind power plant (WPP, 200) comprising a plurality of wind turbine generators (WTG, 100, 100n), the operation comprising: defining, based on received wind information (240, 245), a wind wake zone (232) comprising a group of first wind turbine generators of the plurality of wind turbine generators; and increasing a reactive power production of at least one of the one or more first wind turbine generators of the wind wake zone, wherein a reactive power production is increased for at least two of the one or more first wind turbine generators, wherein an amount of reactive power increase of the at least two of the one or more first wind turbine generators is based on relative active power ratings of the at least two of the one or more first wind turbine generators, so that at least two of the one or more first wind turbine generators disposed within the wind wake zone are controlled to provide a relatively greater reactive power than wind turbine generators outside the wind wake zone (232).'] | false | [
"114",
"116",
"110",
"120",
"112",
"118",
"104",
"108",
"106",
"108",
"102",
"100",
"1",
"14"
] | |
EP_3501110_B1 (4).png | EP3501110B1 | CENTER FREQUENCY AND Q TUNING OF BIQUAD FILTER BY AMPLITUDE-LIMITED OSCILLATION-BASED CALIBRATION | [
"FIG6B"
] | [
"FIG6B is a schematic diagram of the biquad filter of FIG6A with oscillation switches added, in accordance with certain aspects of the present disclosure"
] | [
"Certain aspects of the present disclosure provide techniques and apparatus for calibrating a tunable active filter without sweeping the frequency across the entire bandwidth and without determining a bandwidth (e.g., the -3 dB bandwidth) for each center frequency using a frequency sweep. Rather, to calibrate the v... | 25 | 175 | schematic diagram | H | [
{
"element_identifier": "605",
"terms": [
"includes differential amplifiers"
]
},
{
"element_identifier": "630",
"terms": [
"control signal"
]
},
{
"element_identifier": "626",
"terms": [
"switches",
"switch"
]
},
{
"element_identifier": "6... | ['1. A filter circuit (900) comprising: a tunable active filter (624) comprising at least one amplifier (603, 605) and a first feedback path coupled between an input and an output of the at least one amplifier, the first feedback path comprising at least one switch (626, 628); and an amplitude limiter (902) coupled to the tunable active filter and comprising at least one transistor (904, 906) disposed in a second feedback path coupled between the input and the output of the at least one amplifier; and wherein: the at least one transistor of the amplitude limiter comprises an n-channel metal-oxide semiconductor, NMOS, transistor (906) and a p-channel metal-oxide semiconductor, PMOS, transistor (904); a drain of the NMOS transistor is coupled to a drain of the PMOS transistor; and a source of the NMOS transistor is coupled to a source of the PMOS transistor.'] | false | [
"626",
"603",
"605",
"628",
"630",
"26"
] | |
EP_3501110_B1 (6).png | EP3501110B1 | CENTER FREQUENCY AND Q TUNING OF BIQUAD FILTER BY AMPLITUDE-LIMITED OSCILLATION-BASED CALIBRATION | [
"FIG8"
] | [
"FIG8 is a flow diagram of example operations for calibrating a quality factor for a tunable active filter at different center frequencies, in accordance with certain aspects of the present disclosure"
] | [
"Once the initial center frequency (fn) has been calibrated by adjusting the programmable component in the tunable active filter, the Q associated with this center frequency may be initially tuned using an STG and an FFT engine to determine the bandwidth (e.g., the -3 dB bandwidth) for one of the center frequencies... | 32 | 280 | flow diagram | H | [
{
"element_identifier": "1",
"terms": [
"1xRTT",
"transmit/receive data via different",
">"
]
},
{
"element_identifier": "1x",
"terms": [
"simply"
]
},
{
"element_identifier": "802",
"terms": [
"at block"
]
},
{
"element_identifier": ... | ['1. A filter circuit (900) comprising: a tunable active filter (624) comprising at least one amplifier (603, 605) and a first feedback path coupled between an input and an output of the at least one amplifier, the first feedback path comprising at least one switch (626, 628); and an amplitude limiter (902) coupled to the tunable active filter and comprising at least one transistor (904, 906) disposed in a second feedback path coupled between the input and the output of the at least one amplifier; and wherein: the at least one transistor of the amplitude limiter comprises an n-channel metal-oxide semiconductor, NMOS, transistor (906) and a p-channel metal-oxide semiconductor, PMOS, transistor (904); a drain of the NMOS transistor is coupled to a drain of the PMOS transistor; and a source of the NMOS transistor is coupled to a source of the PMOS transistor.', '3. The filter circuit of claim 1, wherein the amplitude limiter further comprises a biasing circuit coupled to a gate of the NMOS transistor and to a gate of the PMOS transistor, the biasing circuit being configured to generate a first bias voltage for biasing the gate of the NMOS transistor and a second bias voltage for biasing the gate of the PMOS transistor.', '4. The filter circuit of claim 3, wherein the biasing circuit comprises: a buffer circuit having an input configured to receive a common-mode voltage of the filter circuit; a first current source and a first resistive element connected in series, coupled to an output of the buffer circuit, and configured to generate the first bias voltage; and a second current source and a second resistive element connected in series, coupled to the output of the buffer circuit, and configured to generate the second bias voltage.', '15. The filter circuit of claim 1, or the method of claim 9, wherein the tunable active filter comprises a Tow-Thomas biquad filter.'] | false | [
"800",
"802",
"2",
"806",
"0",
"2",
"8"
] | |
EP_3501113_B1 (2).png | EP3501113B1 | DECLARING QUASI CO-LOCATION AMONG MULTIPLE ANTENNA PORTS | [
"FIG3"
] | [
"FIG3 is a diagram illustrating an example of an evolved Node B (eNB) and user equipment (UE) in an access network"
] | [
"FIG3 is a block diagram of an eNB 310 in communication with a UE 350 in an access network. In the DL, IP packets from the EPC 160 may be provided to a controller/processor 375. The controller/processor 375 implements layer 3 and layer 2 functionality. Layer 3 includes a radio resource control (RRC) layer, and laye... | 25 | 291 | diagram | H | [
{
"element_identifier": "310",
"terms": [
"eNB"
]
},
{
"element_identifier": "375",
"terms": [
"controller/processor"
]
},
{
"element_identifier": "374",
"terms": [
"channel estimator"
]
},
{
"element_identifier": "350",
"terms": [
"UE"... | ['1. A method (600) of wireless communication by a base station, comprising: determining (602) a set of antenna ports at the base station that are quasi co-located, QCL, wherein the determination is based on one or more of an angle of arrival at the base station, angle of departure from the base station, and a beam width for each antenna port of the set of antenna ports; transmitting (604) QCL information to a user equipment, UE, indicating that the set of antenna ports are determined to be QCL; and characterized by further comprising: receiving (606) feedback from the UE indicating whether the set of antenna ports at the base station are QCL.'] | false | [
"310",
"316",
"375",
"376",
"350",
"352",
"35",
"356",
"358",
"352",
"354",
"368",
"360",
"320",
"318",
"359",
"374",
"370",
"23",
"318"
] | |
EP_3501113_B1 (6).png | EP3501113B1 | DECLARING QUASI CO-LOCATION AMONG MULTIPLE ANTENNA PORTS | [
"FIG8"
] | [
"FIG8 is a conceptual data flow diagram illustrating the data flow between different means/components in an exemplary apparatus"
] | [
"FIG8 is a conceptual data flow diagram 800 illustrating the data flow between different means/components in an exemplary apparatus 802. The apparatus may be a base station (e.g., the mmW base station 180). The apparatus includes a reception component 804, a measuring component 806, a QCL component 808, and a trans... | 20 | 64 | conceptual data flow diagram | H | [
{
"element_identifier": "100",
"terms": [
"access network"
]
},
{
"element_identifier": "102",
"terms": [
"base stations",
"base station"
]
},
{
"element_identifier": "104",
"terms": [
"UEs"
]
},
{
"element_identifier": "160",
"terms": ... | ['1. A method (600) of wireless communication by a base station, comprising: determining (602) a set of antenna ports at the base station that are quasi co-located, QCL, wherein the determination is based on one or more of an angle of arrival at the base station, angle of departure from the base station, and a beam width for each antenna port of the set of antenna ports; transmitting (604) QCL information to a user equipment, UE, indicating that the set of antenna ports are determined to be QCL; and characterized by further comprising: receiving (606) feedback from the UE indicating whether the set of antenna ports at the base station are QCL.', '6. The method of claim 1, further comprising: receiving (612) reference signals from the UE via the set of antenna ports; and determining (614) whether the set of antenna ports are QCL for reception based on the received reference signals.', '10. The method of claim 8, wherein only the angle of departure is used to determine (602) that the set of antenna ports are QCL if transmit beamforming is considered.'] | false | [
"800",
"802",
"804",
"806",
"808",
"30",
"810",
"850",
"8"
] | |
EP_3501114_B1 (2).png | EP3501114B1 | CODEBOOK INCLUDING PHASE ROTATION BETWEEN LAYERS | [
"FIG3"
] | [
"FIG3 is a diagram of an example of sparse code multiple access (SCMA) encoding in accordance with some aspects of the disclosure"
] | [
"FIG3 illustrates an example multi-dimensional codebook 302 for a (4, 6, 2) coding scheme. In this example, there are six inputs 303A, 303B, 303C, 303D, 303E, 303F, each of which corresponds to an SCMA layer. The inputs could be from different sources (e.g., UEs) or a single source.",
"In the example illustrated ... | 24 | 145 | diagram | H | [
{
"element_identifier": "5",
"terms": [
"layers"
]
},
{
"element_identifier": "306",
"terms": [
"are two non-active tones"
]
},
{
"element_identifier": "302",
"terms": [
"example multi-dimensional codebook"
]
},
{
"element_identifier": "308",
... | ['1. A method of communication employing codebooks, wherein each codebook defines, for each layer of a plurality of layers, a mapping between input bits and multi-dimensional constellation points; the method comprising: generating (1502) a plurality of symbol error patterns by running a decoder process for each of a plurality of permutations of constellation points between nonzero entities for at least one encoder layer; identifying (1504), for each of the symbol error patterns, a corresponding bit mapping that results in a lowest bit error; defining (1506) a plurality of initial codebooks based on each permutation and each corresponding bit mapping; and identifying (1508) a final codebook by running a receiver process for each initial codebook and selecting one of the initial codebooks with a highest performance.'] | false | [
"302",
"5",
"3",
"306",
"308",
"28"
] | |
EP_3501122_B1 (3).png | EP3501122B1 | METHODS AND APPARATUSES FOR BEAM INFORMATION FOR INDEPENDENT LINKS | [
"FIG28"
] | [
"FIG28 is a block diagram illustrating an example hardware implementation for an apparatus (e g , an electronic device) that can support communication in accordance with some aspects of the disclosure"
] | [
"FIG28 illustrates a block diagram of an example hardware implementation of an apparatus 2800 configured to communicate according to one or more aspects of the disclosure. The apparatus 2800 could embody or be implemented within a UE, a TRP, a gNB, a base station (BS), or some other type of device that supports wir... | 33 | 309 | block diagram | H | [
{
"element_identifier": "2818",
"terms": [
"may maintain link information"
]
},
{
"element_identifier": "2804",
"terms": [
"storage medium"
]
},
{
"element_identifier": "2816",
"terms": [
"receiver"
]
},
{
"element_identifier": "2834",
"terms... | ['1. A method (2400) of communication for a multi-link multi-beam communications apparatus, the method comprising: communicating (2402) data via a first wireless communication link (1208); and communicating (2404) beam information for a second wireless communication link (1210) via the first wireless communication link (1208), wherein the beam information comprises a designated time for a beam switch.', '9. The method of claim 8, wherein error processing of the first transport blocks is independent of error processing of the second transport blocks.', '12. The method of claim 1, further comprising: sending the beam information to another apparatus that is configured to communicate via the second wireless communication link.'] | false | [
"2812",
"2800",
"2802",
"2816",
"2804",
"2838",
"2840",
"281",
"2820",
"2822",
"282",
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"2830",
"2832",
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"2836",
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"2846",
"2848",
"2850",
"2852",
"2854",
"2806",
"2808",
"2818",
"28",
"78"
] | |
EP_3501145_B1 (2).png | EP3501145B1 | FAST ACCESS TELECOMMUNICATION TUNNEL CLONING | [
"FIG3"
] | [
"FIG3 illustrates example protocol layers in a Tunneled Services Control Function tunneling configuration for encapsulating media traffic according to an embodiment"
] | [
"In a tunneling configuration, encapsulated (i.e., in a packet/frame) media is typically communicated according to the real-time transport protocol (\"RTP\" as provided, for example, in IETF RFC 3550). In a TSCF tunneling configuration, RTC (e.g., speech, video, etc.) may be subject to two levels of transport: one ... | 21 | 230 | null | H | [
{
"element_identifier": "2",
"terms": [
"EP"
]
},
{
"element_identifier": "10",
"terms": [
"system"
]
},
{
"element_identifier": "80",
"terms": [
"receiving device"
]
},
{
"element_identifier": "200",
"terms": [
"VPN client"
]
},
... | ['2. The method of claim 1, wherein the main tunnel and the cloned tunnel are established according to a tunneled services control function "TSCF" standard; or wherein the main tunnel terminates at a first interface associated with a first server and the cloned tunnel terminates at a second interface associated with a second server that is different than the first server, and optionally wherein the cloned tunnel is established without the use of TSCF service messages.', '7. A computer readable medium having instructions stored thereon that, when executed by a processor, cause the processor to transmit encapsulated media during a telecommunication session, the transmitting comprising: establishing (502) a main tunnel between a tunneling client and a tunneling server using a first socket, the main tunnel comprising a corresponding tunnel identifier and Internet Protocol "IP" address; traversing (504) the encapsulated media over the main tunnel during the telecommunication session; determining (506) that a cloned tunnel is needed for the telecommunication session; establishing (508) a cloned tunnel between the tunneling client and the tunneling server using a second socket that has been marked as a cloned tunnel candidate, wherein the cloned tunnel comprises the corresponding tunnel identifier and IP address of the main tunnel; and traversing (510) the encapsulated media over the cloned tunnel instead of the main tunnel during the telecommunication session.', '13. A user equipment device (102) comprising: an application (104); and a tunneling client (106); the tunneling client configured to establish a main tunnel (108) between a tunneling client and a tunneling server (116) using a first socket, the main tunnel comprising a corresponding tunnel identifier and Internet Protocol "IP" address; the tunneling client configured to traverse the encapsulated media over the main tunnel during the telecommunication session; the application configured to determining that a cloned tunnel is needed for the telecommunication session; the tunneling client configured to establish a cloned tunnel (109) between the tunneling client and the tunneling server using a second socket that has been marked as a cloned tunnel candidate, wherein the cloned tunnel comprises the corresponding tunnel identifier and IP address of the main tunnel; and the tunneling client configured to traverse the encapsulated media over the cloned tunnel instead of the main tunnel during the telecommunication session.'] | false | [
"300",
"3",
"17"
] | |
EP_3501145_B1 (3).png | EP3501145B1 | FAST ACCESS TELECOMMUNICATION TUNNEL CLONING | [
"FIG4"
] | [
"FIG4 includes network elements such as a tunneling client in communication with an application, and a tunneling server in communication with a service provider network, as described herein with reference to FIG1"
] | [
"FIG4 is an example message sequence diagram 400, including the sequence of messages exchanged between application 104, tunneling client 106 and tunneling server 116 of FIG1, for fast access tunnel cloning according to some embodiments. FIG4 includes network elements such as tunneling client 106 in communication wi... | 34 | 255 | null | H | [
{
"element_identifier": "420",
"terms": [
"tsc_socket API at"
]
},
{
"element_identifier": "122",
"terms": [
"service provider network"
]
},
{
"element_identifier": "407",
"terms": [
"at"
]
},
{
"element_identifier": "423",
"terms": [
"... | ['1. A method of transmitting encapsulated media during a telecommunication session, the method comprising: establishing (502) a main tunnel between a tunneling client and a tunneling server using a first socket, the main tunnel comprising a corresponding tunnel identifier and Internet Protocol "IP" address; traversing (504) the encapsulated media over the main tunnel during the telecommunication session; determining (506) that a cloned tunnel is needed for the telecommunication session; establishing (508) a cloned tunnel between the tunneling client and the tunneling server using a second socket that has been marked as a cloned tunnel candidate, wherein the cloned tunnel comprises the corresponding tunnel identifier and IP address of the main tunnel; and traversing (510) the encapsulated media over the cloned tunnel instead of the main tunnel during the telecommunication session.', '2. The method of claim 1, wherein the main tunnel and the cloned tunnel are established according to a tunneled services control function "TSCF" standard; or wherein the main tunnel terminates at a first interface associated with a first server and the cloned tunnel terminates at a second interface associated with a second server that is different than the first server, and optionally wherein the cloned tunnel is established without the use of TSCF service messages.'] | false | [
"400",
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"411",
"415",
"42",
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EP_3501149_B1 (1).png | EP3501149B1 | FILTERED MULTI-CARRIER COMMUNICATIONS | [
"FIG4"
] | [
"FIG4 is a simplified flowchart of a method of filter design for a multi-carrier communication system, according to embodiments of the invention"
] | [
"Reference is now made to FIG4, which is a simplified flowchart of a method of filter design for a multi-carrier communication system, according to embodiments of the invention. Optionally the filter design method is performed using an electronic design automation system."
] | 25 | 47 | simplified flowchart | H | [
{
"element_identifier": "55",
"terms": [
"vol."
]
},
{
"element_identifier": "10",
"terms": [
"no."
]
},
{
"element_identifier": "2007",
"terms": [
"Oct"
]
},
{
"element_identifier": "78",
"terms": [
"vol."
]
},
{
"element_i... | ['3. An apparatus for processing data symbols in a multi-carrier transmitter, comprising: a transmit pulse shaper (110), adapted to filter a plurality of data pulses with respective transmit pulse shaping filters, each of said data pulses being associated with a respective carrier; a transmit sub-band filter (120) associated with said transmit pulse shaper (110), adapted to perform sub-band filtering of said pulse-shaped data pulses, wherein said sub-band filter (120) and at least one of said transmit pulse shaping filters are jointly designed according to the method of any one of claims 1-2 to optimize the first and the second specified performance measures.', '4. An apparatus for processing the pulse-shaped and sub-band filtered multi-carrier signal in a multi-carrier receiver, comprising: a receive sub-band filter (310), adapted to sub-band filter a received signal; and a receive pulse shaper (320) associated with said receive sub-band filter (310), adapted to pulse-shape carriers in said sub-band filtered signal with respective receive pulse shaping filters, wherein said sub-band filter (310) and at least one of said receive pulse shaping filters are jointly designed according to the method of any one of claims 1-2 to optimize the first and the second specified performance measures.'] | false | [
"400",
"16"
] | |
EP_3501149_B1.png | EP3501149B1 | FILTERED MULTI-CARRIER COMMUNICATIONS | [
"FIG2",
" FIG3"
] | [
"FIG2 is a simplified block diagram of an apparatus for processing data symbols in a multi-carrier transmitter according to an exemplary embodiment of the invention ",
"FIG3 is a simplified block diagram of an apparatus for processing data symbols in a multi-carrier receiver, according to embodiments of the inven... | [
"Reference is now made to FIG2, which is a simplified block diagram of an apparatus for processing data symbols in a multi-carrier transmitter, according to an exemplary embodiment of the invention.",
"The pulse shaping operation is applied on the time-domain OFDM data symbol generated by IFFT 210. In the exempla... | 53 | 164 | simplified block diagram | H | [
{
"element_identifier": "210",
"terms": [
"IFFT"
]
},
{
"element_identifier": "230",
"terms": [
"P/S"
]
},
{
"element_identifier": "310",
"terms": [
"receive sub-band filter"
]
},
{
"element_identifier": "220",
"terms": [
"then undergo ... | ['3. An apparatus for processing data symbols in a multi-carrier transmitter, comprising: a transmit pulse shaper (110), adapted to filter a plurality of data pulses with respective transmit pulse shaping filters, each of said data pulses being associated with a respective carrier; a transmit sub-band filter (120) associated with said transmit pulse shaper (110), adapted to perform sub-band filtering of said pulse-shaped data pulses, wherein said sub-band filter (120) and at least one of said transmit pulse shaping filters are jointly designed according to the method of any one of claims 1-2 to optimize the first and the second specified performance measures.', '4. An apparatus for processing the pulse-shaped and sub-band filtered multi-carrier signal in a multi-carrier receiver, comprising: a receive sub-band filter (310), adapted to sub-band filter a received signal; and a receive pulse shaper (320) associated with said receive sub-band filter (310), adapted to pulse-shape carriers in said sub-band filtered signal with respective receive pulse shaping filters, wherein said sub-band filter (310) and at least one of said receive pulse shaping filters are jointly designed according to the method of any one of claims 1-2 to optimize the first and the second specified performance measures.'] | true | [
"001",
"110",
"120",
"210",
"220",
"230",
"240",
"2",
"300",
"310",
"320",
"15"
] | |
EP_3501161_B1 (5).png | EP3501161B1 | METHODS AND APPARATUS FOR PROVIDING IMPROVED VISUAL AND OPTIONALLY TACTILE FEATURES ON A SUBSTRATE | [
"FIG10"
] | [
"FIG10 is a perspective view of an alternative composite substrate with respective first and second substrates thereof in a separated configuration, and including tactile features"
] | [
"Reference is now made to FIG10, which is a perspective view an alternative composite substrate 100-3 with respective first and second substrates 110-1, 110-2 thereof in a separated configuration. In accordance with one or more further aspects, the above-noted effect of gradual variation from dominance to subordina... | 26 | 106 | perspective view | G | [
{
"element_identifier": "222",
"terms": [
"one tactile element"
]
},
{
"element_identifier": "10",
"terms": [
"about"
]
}
] | ['1. An apparatus, comprising: a substrate comprising a first major surface (102), a second major surface (104) opposite the first major surface, and at least one edge surface (106) extending between the first and second major surfaces, the substrate comprising an at least partially transparent material; at least one visual element (210) disposed on the second major surface of the substrate and/or within the substrate such that the at least one visual element may be viewed through the first major surface; and at least one tactile element (212) disposed on the first major surface of the substrate, the at least one tactile element comprising one or more surface roughness portions, wherein at least some of the one or more surface roughness portions of the tactile element are positioned on the first major surface of the substrate in a complimentary fashion with respect to at least some of the one or more visual portions of the visual element to modify the visual effect of the visual element as viewed through the first major surface of the substrate wherein a majority of the total surface area of the first major surface of the substrate comprises a first surface roughness; and the one or more surface roughness portions of the tactile element cover a minority of the total surface area of the first major surface and comprise at least some portions that are of a second surface roughness, which is different from the first surface roughness.'] | false | [
"10",
"222",
"24"
] | |
EP_3501161_B1.png | EP3501161B1 | METHODS AND APPARATUS FOR PROVIDING IMPROVED VISUAL AND OPTIONALLY TACTILE FEATURES ON A SUBSTRATE | [
"FIG1"
] | [
"FIG1 includes a top view and a perspective view of a substrate having both visual and tactile features"
] | [
"With reference to the drawings wherein like numerals indicate like elements there is shown in FIG1 a substrate 100-1 in accordance with one or more embodiments of this disclosure.",
"As can be seen in the illustration of FIG1, at least some of the one or more surface roughness portions (and/or small surface elem... | 18 | 242 | null | G | [
{
"element_identifier": "106",
"terms": [
"one edge surface"
]
},
{
"element_identifier": "102",
"terms": [
"first major surface"
]
},
{
"element_identifier": "104",
"terms": [
"surface"
]
},
{
"element_identifier": "1",
"terms": [
"Ep"... | ['1. An apparatus, comprising: a substrate comprising a first major surface (102), a second major surface (104) opposite the first major surface, and at least one edge surface (106) extending between the first and second major surfaces, the substrate comprising an at least partially transparent material; at least one visual element (210) disposed on the second major surface of the substrate and/or within the substrate such that the at least one visual element may be viewed through the first major surface; and at least one tactile element (212) disposed on the first major surface of the substrate, the at least one tactile element comprising one or more surface roughness portions, wherein at least some of the one or more surface roughness portions of the tactile element are positioned on the first major surface of the substrate in a complimentary fashion with respect to at least some of the one or more visual portions of the visual element to modify the visual effect of the visual element as viewed through the first major surface of the substrate wherein a majority of the total surface area of the first major surface of the substrate comprises a first surface roughness; and the one or more surface roughness portions of the tactile element cover a minority of the total surface area of the first major surface and comprise at least some portions that are of a second surface roughness, which is different from the first surface roughness.'] | false | [
"1",
"102",
"106",
"104",
"18"
] | |
EP_3501177_B1 (1).png | EP3501177B1 | ELECTRONIC APPARATUS AND METHOD OF OPERATING THE SAME | [
"FIG3"
] | [
"FIG3 is a block diagram illustrating a configuration of the electronic apparatus according to various embodiments"
] | [
"FIG3 is a block diagram illustrating a configuration of the electronic apparatus according to various embodiments.",
"Referring to FIG3, the electronic apparatus 100 according to various embodiments may further include a video processor 180, an audio processor 115, an audio output interface 125, a power supply 1... | 16 | 301 | block diagram | G | [
{
"element_identifier": "160",
"terms": [
"power supply"
]
},
{
"element_identifier": "174",
"terms": [
"port"
]
},
{
"element_identifier": "126",
"terms": [
"speaker"
]
},
{
"element_identifier": "153",
"terms": [
"Ethernet interface"
... | ['1. An electronic apparatus (100) comprising: a display (120); and a controller (110) electrically connected to the display, and a storage that stores a lookup table for a flat display including aspect ratio information of the display and an angle of view which matches the aspect ratio information, wherein based on a type of the display being flat, the controller is configured to: identify aspect ratio information of the display, determine an angle of view of a 360 degree image to be displayed on the display based on the identified aspect ratio information of the display, using the lookup table, and control the display to display a region of the 360 degree image based on the determined angle of view.', '6. The electronic apparatus (100) of claim 1, further comprising a camera (132), wherein the controller (110) is further configured to control to display the 360 degree image on the display (120) based on data generated by the camera.'] | false | [
"126",
"127",
"128",
"120",
"15",
"25",
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"190",
"110",
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"182",
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"174",
"25"
] | |
EP_3501177_B1 (2).png | EP3501177B1 | ELECTRONIC APPARATUS AND METHOD OF OPERATING THE SAME | [
"FIG4"
] | [
"FIG4 is a flowchart for describing a method of displaying an image in the electronic apparatus according to various embodiments"
] | [
"FIG4 is a flowchart for describing a method of displaying an image in the electronic apparatus according to various embodiments.",
"Referring again to FIG4, in operation 430, the electronic apparatus 100 may determine a region which will be displayed (or an angle of view) among images which will be reproduced on... | 20 | 79 | flowchart | G | [
{
"element_identifier": "360",
"terms": [
"spherical"
]
},
{
"element_identifier": "100",
"terms": [
"electronic apparatus"
]
},
{
"element_identifier": "10",
"terms": [
"degree image"
]
},
{
"element_identifier": "20",
"terms": [
"degr... | ['1. An electronic apparatus (100) comprising: a display (120); and a controller (110) electrically connected to the display, and a storage that stores a lookup table for a flat display including aspect ratio information of the display and an angle of view which matches the aspect ratio information, wherein based on a type of the display being flat, the controller is configured to: identify aspect ratio information of the display, determine an angle of view of a 360 degree image to be displayed on the display based on the identified aspect ratio information of the display, using the lookup table, and control the display to display a region of the 360 degree image based on the determined angle of view.', '6. The electronic apparatus (100) of claim 1, further comprising a camera (132), wherein the controller (110) is further configured to control to display the 360 degree image on the display (120) based on data generated by the camera.'] | true | [
"410",
"420",
"430",
"440",
"450",
"510",
"520",
"530",
"26"
] | |
EP_3501199_B1 (1).png | EP3501199B1 | CONTROLLING DIRECTIONAL COMMUNICATION EQUIPMENT | [
"FIG2"
] | [
"FIG2 is a table of example antenna beamwidth and sensing sensitivity combinations, according to embodiments"
] | [
"In some embodiments, the jointly selected antenna beamwidth 150 and sensing sensitivity may be a predefined beamwidth and sensitivity combination. FIG2 illustrates an example table comprising a plurality of predefined beamwidth and sensitivity combinations from which the communication device 110 jointly selects an... | 16 | 424 | table | H | [
{
"element_identifier": "120",
"terms": [
"remote device",
"remote devices"
]
},
{
"element_identifier": "120a",
"terms": [
"remote device",
"remote devices"
]
},
{
"element_identifier": "100",
"terms": [
"example wireless communication system"
... | ['1. A method (300) of controlling directional communication equipment (730), implemented by a communication device (110), the method (300) being characterized by : determining (310) a distance (140a, 140b) for which an antenna lobe (160a, 160b) extends from the communication device (110) for directionally sensing spectral conditions; jointly selecting (320) an antenna beamwidth (150a, 150b) and sensing sensitivity with which to directionally sense the spectral conditions based on the distance (140a, 140b).', '8. The method of claim 7, further comprising: transmitting in a direction of a remote device (120) responsive to the spectral energy level being below the energy threshold; changing one or both of the selected antenna beamwidth (150a, 150b) and sensing sensitivity based on a determination of whether or not the transmission was successfully received by the remote device (120).'] | false | [
"2",
"12"
] | |
EP_3501199_B1 (2).png | EP3501199B1 | CONTROLLING DIRECTIONAL COMMUNICATION EQUIPMENT | [
"FIG3"
] | [
"FIG3 is a flow diagram illustrating an example method according to embodiments"
] | [
"In view of the above, FIG3 illustrates an example method 300 of controlling directional communication equipment, implemented by a communication device 110. The method 300 comprises determining a distance 140 for directionally sensing spectral conditions (step 310), and jointly selecting an antenna beamwidth 150 an... | 12 | 71 | flow diagram | H | [
{
"element_identifier": "300",
"terms": [
"method",
"methods"
]
}
] | ['1. A method (300) of controlling directional communication equipment (730), implemented by a communication device (110), the method (300) being characterized by : determining (310) a distance (140a, 140b) for which an antenna lobe (160a, 160b) extends from the communication device (110) for directionally sensing spectral conditions; jointly selecting (320) an antenna beamwidth (150a, 150b) and sensing sensitivity with which to directionally sense the spectral conditions based on the distance (140a, 140b).'] | false | [
"300",
"310",
"320",
"3",
"13"
] | |
EP_3501199_B1 (3).png | EP3501199B1 | CONTROLLING DIRECTIONAL COMMUNICATION EQUIPMENT | [
"FIG4"
] | [
"FIG4 is a flow diagram illustrating a more detailed example method according to embodiments"
] | [
"FIG4 illustrates a more detailed method 400 of controlling directional communication equipment, implemented by a communication device 110. The method 400 comprises determining a distance 140 (step 410) and a carrier frequency (step 420) for directionally sensing spectral conditions. The method 400 further comprise... | 14 | 122 | flow diagram | H | [
{
"element_identifier": "400",
"terms": [
"method"
]
},
{
"element_identifier": "150",
"terms": [
"antenna beamwidth"
]
}
] | ['1. A method (300) of controlling directional communication equipment (730), implemented by a communication device (110), the method (300) being characterized by : determining (310) a distance (140a, 140b) for which an antenna lobe (160a, 160b) extends from the communication device (110) for directionally sensing spectral conditions; jointly selecting (320) an antenna beamwidth (150a, 150b) and sensing sensitivity with which to directionally sense the spectral conditions based on the distance (140a, 140b).'] | false | [
"410",
"420",
"400",
"430",
"440",
"85",
"150",
"460",
"470",
"475",
"490",
"4",
"14"
] | |
EP_3501199_B1 (4).png | EP3501199B1 | CONTROLLING DIRECTIONAL COMMUNICATION EQUIPMENT | [
"FIG5"
] | [
"FIG5 is a block diagram illustrating example hardware configured according to embodiments"
] | [
"Yet other embodiments of the present disclosure include the computing device 110 implemented according to the hardware illustrated in FIG5. The example hardware of FIG5 comprises processing circuitry 710, memory circuitry 720, and interface circuitry 730. The processing circuitry 710 is communicatively coupled to ... | 12 | 345 | block diagram | H | [
{
"element_identifier": "760",
"terms": [
"control software"
]
},
{
"element_identifier": "710",
"terms": [
"processing circuitry"
]
},
{
"element_identifier": "750",
"terms": [
"input circuitry"
]
},
{
"element_identifier": "740",
"terms": [... | ['1. A method (300) of controlling directional communication equipment (730), implemented by a communication device (110), the method (300) being characterized by : determining (310) a distance (140a, 140b) for which an antenna lobe (160a, 160b) extends from the communication device (110) for directionally sensing spectral conditions; jointly selecting (320) an antenna beamwidth (150a, 150b) and sensing sensitivity with which to directionally sense the spectral conditions based on the distance (140a, 140b).'] | false | [
"110",
"720",
"760",
"710",
"740",
"750",
"730",
"5",
"15"
] | |
EP_3501199_B1 (5).png | EP3501199B1 | CONTROLLING DIRECTIONAL COMMUNICATION EQUIPMENT | [
"FIG6"
] | [
"FIG6 is a block diagram illustrating a plurality of physical units comprised in processing circuitry of a communication device according to embodiments"
] | [
"Other embodiments of the present disclosure include the example processing circuitry 710 of the computing device 110 as illustrated in FIG6. The processing circuitry 710 comprises a plurality of communicatively coupled physical units. In particular, the processing circuitry 710 comprises a determining unit 805 con... | 22 | 89 | block diagram | H | [
{
"element_identifier": "120",
"terms": [
"remote device",
"remote devices"
]
},
{
"element_identifier": "120a",
"terms": [
"remote device",
"remote devices"
]
},
{
"element_identifier": "100",
"terms": [
"example wireless communication system"
... | ['1. A method (300) of controlling directional communication equipment (730), implemented by a communication device (110), the method (300) being characterized by : determining (310) a distance (140a, 140b) for which an antenna lobe (160a, 160b) extends from the communication device (110) for directionally sensing spectral conditions; jointly selecting (320) an antenna beamwidth (150a, 150b) and sensing sensitivity with which to directionally sense the spectral conditions based on the distance (140a, 140b).', '8. The method of claim 7, further comprising: transmitting in a direction of a remote device (120) responsive to the spectral energy level being below the energy threshold; changing one or both of the selected antenna beamwidth (150a, 150b) and sensing sensitivity based on a determination of whether or not the transmission was successfully received by the remote device (120).'] | false | [
"710",
"805",
"810",
"6",
"16"
] | |
EP_3501199_B1 (6).png | EP3501199B1 | CONTROLLING DIRECTIONAL COMMUNICATION EQUIPMENT | [
"FIG7"
] | [
"FIG7 is a block diagram illustrating a plurality of software modules comprised in control software for controlling a programmable communication device according to embodiments "
] | [
"Other embodiments of the present disclosure include the example control software 760 of computing device 710, as illustrated in FIG7. The control software 760 of FIG7 comprises a plurality of software modules. In particular, this control software 760 comprises a determining module 905 configured to determine a dis... | 24 | 88 | block diagram | H | [
{
"element_identifier": "120",
"terms": [
"remote device",
"remote devices"
]
},
{
"element_identifier": "120a",
"terms": [
"remote device",
"remote devices"
]
},
{
"element_identifier": "100",
"terms": [
"example wireless communication system"
... | ['1. A method (300) of controlling directional communication equipment (730), implemented by a communication device (110), the method (300) being characterized by : determining (310) a distance (140a, 140b) for which an antenna lobe (160a, 160b) extends from the communication device (110) for directionally sensing spectral conditions; jointly selecting (320) an antenna beamwidth (150a, 150b) and sensing sensitivity with which to directionally sense the spectral conditions based on the distance (140a, 140b).', '8. The method of claim 7, further comprising: transmitting in a direction of a remote device (120) responsive to the spectral energy level being below the energy threshold; changing one or both of the selected antenna beamwidth (150a, 150b) and sensing sensitivity based on a determination of whether or not the transmission was successfully received by the remote device (120).'] | false | [
"760",
"905",
"910",
"7",
"17"
] | |
EP_3501206_B1 (6).png | EP3501206B1 | RISK AWARE VALIDITY ASSESSMENT OF SYSTEM INFORMATION | [
"FIG7"
] | [
"FIG7 shows a flowchart for schematically illustrating a method performed by an access node according to an embodiment of the invention"
] | [
"FIG7 shows a flowchart for illustrating a method of controlling radio transmissions in a wireless communication network. The method of FIG7 may be utilized for implementing the illustrated concepts in an access node of the wireless communication network, such as one of the above-mentioned access nodes 110. If a pr... | 21 | 107 | flowchart | H | [
{
"element_identifier": "1",
"terms": [
"class"
]
},
{
"element_identifier": "2",
"terms": [
"class"
]
},
{
"element_identifier": "3",
"terms": [
"Type"
]
},
{
"element_identifier": "9",
"terms": [
"System Information Block Type"
]
... | ['1. A method of controlling access to a wireless communication network, the method comprising: a radio device (10; 600; 900) acquiring (510) system information from the wireless communication network, the system information comprising parameters for controlling access of the radio device (10; 600; 900) to the wireless communication network and being organized in at least two classes differing with respect to a risk level associated with accessing the wireless communication network based on one or more parameters of the class; the radio device (10; 600; 900) receiving (520) validation information which enables the radio device (10; 600; 900) to determine, individually for at least one of the classes, validity of the system information as previously acquired by the radio device (10 ; 600; 900); and depending on the validity and the risk level associated with at least one of the classes, the radio device (10; 600; 900) determining (530) whether to access the wireless communication network based on the system information as previously acquired by the radio device (10; 600; 900), wherein the risk level of each class is based on a probability that a problem is caused by accessing the wireless communication network based on one or more parameters of the class or on a severeness level of a problem caused by accessing the wireless communication network based on one or more parameters of the class.', '4. The method according to any one of the preceding claims, comprising: the radio device (10; 600; 900) receiving an identifier (220) from the wireless communication network; and based on the identifier (220), the radio device (10; 600; 900) acquiring the system information, wherein the radio device (10; 600; 900) receives the validation information in conjunction with a transmission of the identifier (220), wherein the radio device (10; 600; 900) receives the system information in an access information table (210) and utilizes the identifier (220) to acquire the system information by identifying, in the access information table, at least one entry including the system. wherein the identifier (220) corresponds to a signature sequence utilized by the radio device (10; 600; 900) to synchronize with an access node (110; 800; 1000) of the wireless communication network.'] | false | [
"710",
"720",
"33",
"7"
] | |
EP_3501217_B1 (1).png | EP3501217B1 | SUPPORTING OR PERFORMING DISTRIBUTION OF A PAGING MESSAGE | [
"FIG4A",
" FIG4B"
] | [
"FIG4A is a first example of a list with network nodes supporting a requested RANA, in accordance with embodiments herein ",
"FIG4B is a second example of a list with network nodes supporting three requested RANAs, in accordance with embodiments herein"
] | [
"FIG4A is a table illustrating a first example of the above-mentioned list of network nodes sent by the wireless device 200 to the first network node 208 in action 306 or action 2:4. In this example, the first network node 208 has requested information about which network nodes support RANA 1. It is thus shown that... | 42 | 307 | nan, schematic | H | [
{
"element_identifier": "306",
"terms": [
"action"
]
},
{
"element_identifier": "11",
"terms": [
"network nodes"
]
},
{
"element_identifier": "1",
"terms": [
"RANA"
]
},
{
"element_identifier": "304",
"terms": [
"action"
]
},
{
... | ['1. A method performed by a wireless device (200) for supporting distribution of paging messages within a Radio Access Network Area, RANA, of a wireless network, the method comprising: - collecting (300) RANA related information from network nodes (202, 204, 206) visited by the wireless device (200), the RANA related information indicating which RANAs are supported by the respective network nodes, - extracting (304) from the collected RANA related information, a list of network nodes that support a RANA, and - sending (306) the extracted list of network nodes to a first network node (208) to enable said distribution of paging messages by the first network node (208) within the RANA.'] | true | [
"300",
"302",
"304",
"306",
"3",
"1",
"11",
"12",
"13",
"1",
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"3",
"11",
"21",
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"12",
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"13",
"23",
"33",
"1",
"2",
"3",
"15"
] | |
EP_3501217_B1 (3).png | EP3501217B1 | SUPPORTING OR PERFORMING DISTRIBUTION OF A PAGING MESSAGE | [
"FIG6"
] | [
"FIG6 is a block diagram illustrating a wireless device and a first network node in more detail, according to further possible embodiments "
] | [
"The block diagram in FIG6 illustrates a detailed but non-limiting example of how a wireless device 600 and a first network node 602, respectively, may be structured to bring about the above-described solution and embodiments thereof. In this figure, the wireless device 600 and the first network node 602 may be con... | 23 | 226 | block diagram | H | [
{
"element_identifier": "606",
"terms": [
"network nodes"
]
},
{
"element_identifier": "2",
"terms": [
"RANA"
]
},
{
"element_identifier": "600",
"terms": [
"wireless device"
]
},
{
"element_identifier": "604",
"terms": [
"wireless netw... | ['1. A method performed by a wireless device (200) for supporting distribution of paging messages within a Radio Access Network Area, RANA, of a wireless network, the method comprising: - collecting (300) RANA related information from network nodes (202, 204, 206) visited by the wireless device (200), the RANA related information indicating which RANAs are supported by the respective network nodes, - extracting (304) from the collected RANA related information, a list of network nodes that support a RANA, and - sending (306) the extracted list of network nodes to a first network node (208) to enable said distribution of paging messages by the first network node (208) within the RANA.'] | false | [
"604",
"2",
"606",
"600",
"602",
"6",
"17"
] | |
EP_3501259_B1 (1).png | EP3501259B1 | RETURN PAN FOR AN AGRICULTURAL COMBINE | [
"FIG2"
] | [
"FIG2 is a perspective top view of the return pan of FIG1"
] | [
"In FIG2, the return pan 116 is shown in greater detail. The return pan has a floor 134, a rear wall 136, and two side walls 138, 140. The return pan 116 has an exit 142 from which grain leaves the return pan 116. The floor 134 is divided into four separate sections that extend longitudinally and guide the dirty gr... | 12 | 146 | perspective view | A | [
{
"element_identifier": "166",
"terms": [
"auger flights"
]
},
{
"element_identifier": "172",
"terms": [
"supports bearings"
]
},
{
"element_identifier": "164",
"terms": [
"inner end. Auger shaft"
]
},
{
"element_identifier": "142",
"terms": ... | ['1. A return pan (116) for an agricultural combine for harvesting crops in an agricultural field and having a direction of travel through the field, wherein the return pan (116) comprises: a textured floor (134) configured to push grain toward an exit (142) of the return pan (116) when the return pan (116) is oscillated in a fore-and-aft direction, a first auger (146) and a second auger (148) that extend across the exit (142) of the textured floor (134) generally perpendicular to the fore-and-aft direction, and a first motor (150) coupled to the first auger (146) to drive the first auger (146) in rotation; characterized in that the return pan (116) comprises a second motor (152) coupled to the second auger (148) to drive the second auger (148) in rotation.', '2. The return pan (116) of claim 1, further comprising two side walls (138, 140) and a rear wall (136) fixed to the textured floor (134) and extending upward from the textured floor (134).'] | false | [
"116",
"136",
"144",
"134",
"140",
"144",
"144",
"174",
"178",
"168",
"148",
"182",
"164",
"176",
"142",
"138",
"172",
"162",
"166",
"146",
"120",
"180",
"170"
] | |
EP_3501259_B1.png | EP3501259B1 | RETURN PAN FOR AN AGRICULTURAL COMBINE | [
"FIG1"
] | [
"FIG1 is a side view of a threshing, separating, and cleaning mechanism in accordance with the present invention"
] | [
"In FIG1 a threshing, separating, and cleaning mechanism 100 for an agricultural combine is shown. Mechanism 100 includes a rotor 102 disposed inside a cage 104. A forward portion of rotor 102 functions to thresh the crop material. A rear portion of rotor 102 functions to separate material other than grain from the... | 20 | 61 | side view | A | [
{
"element_identifier": "122",
"terms": [
"chaffer"
]
},
{
"element_identifier": "128",
"terms": [
"floor"
]
},
{
"element_identifier": "116",
"terms": [
"return pan"
]
},
{
"element_identifier": "130",
"terms": [
"trough"
]
},
... | ['1. A return pan (116) for an agricultural combine for harvesting crops in an agricultural field and having a direction of travel through the field, wherein the return pan (116) comprises: a textured floor (134) configured to push grain toward an exit (142) of the return pan (116) when the return pan (116) is oscillated in a fore-and-aft direction, a first auger (146) and a second auger (148) that extend across the exit (142) of the textured floor (134) generally perpendicular to the fore-and-aft direction, and a first motor (150) coupled to the first auger (146) to drive the first auger (146) in rotation; characterized in that the return pan (116) comprises a second motor (152) coupled to the second auger (148) to drive the second auger (148) in rotation.', '10. A separating and cleaning mechanism (100) for an agricultural combine comprising a rotor (102) and concave (106) arrangement for separating grain from plant residue and/or a residue beater rotor (110) and associated grating (114); a return pan (116) according to one of the preceding claims disposed underneath the rotor (102) and concave (106) arrangement and/or below the residue beater rotor (110) and the grating (114) to receive threshed and separated grain from the rotor (102) and concave (106) arrangement and/or from the grating (114) and a cleaning shoe including at least a cleaning fan (126) and a sieve (122) or chaffer (124) disposed underneath the return pan (116) to receive the threshed and separated grain from the return pan (116) and to further clean the threshed and separated grain.'] | false | [
"100",
"102",
"104",
"108",
"110",
"112",
"114",
"106",
"8",
"106",
"120",
"118",
"116",
"122",
"124",
"128",
"126",
"132",
"130",
"1"
] | |
EP_3501307_B1 (1).png | EP3501307B1 | ELECTRONIC CIGARETTE AND CONTROL METHOD THEREFOR | [
"FIG2",
" FIG3",
" FIG4"
] | [
"FIG2 is a schematic block diagram of functional modules of a first electronic cigarette according to a second embodiment of the present invention ",
"FIG3 is a schematic block diagram of functional modules of a second electronic cigarette according to the second embodiment of the present invention ",
"FIG4 is ... | [
"FIG2 is a schematic diagram of functional modules of an electronic cigarette 200 according to a second embodiment of the present invention. As shown in FIG2, the electronic cigarette 200 includes a microprocessor 201, a battery module 202, a heating element 203, and a sensing module 204. ",
"Optionally, as shown... | 69 | 390 | schematic block diagram | A | [
{
"element_identifier": "201",
"terms": [
"microprocessor"
]
},
{
"element_identifier": "202",
"terms": [
"battery module"
]
},
{
"element_identifier": "203",
"terms": [
"heating element"
]
},
{
"element_identifier": "206",
"terms": [
"... | ['1. An electronic cigarette, comprising a microprocessor (101, 201), a battery module (102, 202) and a heating element (103, 203), the microprocessor (101, 201) being electrically connected to the battery module (102, 202), the battery module (102, 202) being electrically connected to the heating element (103, 203) and supplying power to the heating element (103, 203) with a first output parameter, a sensing module (109, 204), connected to the microprocessor (101, 201) and disposed in a smoke outlet passage (108) of the electronic cigarette, for detecting the concentration of an analyte and sending the concentration of the analyte to the microprocessor (101, 201); characterized in that the analyte comprises one or more of fine particles, smoke tar, carbon monoxide, nicotine, formaldehyde, acetaldehyde, acrolein, and glyoxal; wherein the sensing module (109, 204) comprises one or more of a PM2.5 sensor, a tar sensor, a carbon monoxide sensor, a semiconductor sensor, and an electrochemical sensor; wherein the microprocessor (101, 201) stores a preset threshold, the microprocessor (101, 201) is configured to receive the concentration of the analyte detected by the sensing module (109, 204), and further configured to determine the relationship between the concentration of the analyte and the preset threshold; when the concentration of the analyte is higher than or equal to the preset threshold, the microprocessor (101, 201) controls the battery module (102, 202) to supply power to the heating element (103, 203) with a second output parameter, wherein the second output parameter is smaller than the first output parameter.', '4. The electronic cigarette according to claim 1 , wherein the electronic cigarette further comprises a timer (206), wherein: the timer (206) is configured for calculating time T1 and sending T1 to the microprocessor (101, 201), wherein T1 is the time during which the battery module (102, 202) supplies power to the heating element (103, 203) with the first output parameter; the microprocessor (101, 201) stores a first preset time, the microprocessor (101, 201) is further configured to control the sensing module (109, 204) to detect the concentration of the analyte when T1 reaches the first preset time.'] | true | [
"203",
"202",
"200",
"201",
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"200",
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"205",
"201",
"3",
"203",
"202",
"204",
"200",
"206",
"201",
"4",
"204",
"15"
] | |
EP_3501307_B1 (2).png | EP3501307B1 | ELECTRONIC CIGARETTE AND CONTROL METHOD THEREFOR | [
"FIG5"
] | [
"FIG5 is a flow chart of steps of a control method for an electronic cigarette according to a third embodiment of the present invention"
] | [
"FIG5 is a flow chart of steps of a control method for an electronic cigarette according to a third embodiment of the present invention. As shown in FIG5, the method includes:Step S501, the microprocessor controls the battery module of the electronic cigarette to supply power to the heating element with the first o... | 24 | 60 | flowchart | A | [
{
"element_identifier": "100",
"terms": [
"electronic cigarette"
]
},
{
"element_identifier": "10",
"terms": [
"housing"
]
},
{
"element_identifier": "20",
"terms": [
"mouthpiece"
]
},
{
"element_identifier": "102",
"terms": [
"battery ... | ['1. An electronic cigarette, comprising a microprocessor (101, 201), a battery module (102, 202) and a heating element (103, 203), the microprocessor (101, 201) being electrically connected to the battery module (102, 202), the battery module (102, 202) being electrically connected to the heating element (103, 203) and supplying power to the heating element (103, 203) with a first output parameter, a sensing module (109, 204), connected to the microprocessor (101, 201) and disposed in a smoke outlet passage (108) of the electronic cigarette, for detecting the concentration of an analyte and sending the concentration of the analyte to the microprocessor (101, 201); characterized in that the analyte comprises one or more of fine particles, smoke tar, carbon monoxide, nicotine, formaldehyde, acetaldehyde, acrolein, and glyoxal; wherein the sensing module (109, 204) comprises one or more of a PM2.5 sensor, a tar sensor, a carbon monoxide sensor, a semiconductor sensor, and an electrochemical sensor; wherein the microprocessor (101, 201) stores a preset threshold, the microprocessor (101, 201) is configured to receive the concentration of the analyte detected by the sensing module (109, 204), and further configured to determine the relationship between the concentration of the analyte and the preset threshold; when the concentration of the analyte is higher than or equal to the preset threshold, the microprocessor (101, 201) controls the battery module (102, 202) to supply power to the heating element (103, 203) with a second output parameter, wherein the second output parameter is smaller than the first output parameter.', '4. The electronic cigarette according to claim 1 , wherein the electronic cigarette further comprises a timer (206), wherein: the timer (206) is configured for calculating time T1 and sending T1 to the microprocessor (101, 201), wherein T1 is the time during which the battery module (102, 202) supplies power to the heating element (103, 203) with the first output parameter; the microprocessor (101, 201) stores a first preset time, the microprocessor (101, 201) is further configured to control the sensing module (109, 204) to detect the concentration of the analyte when T1 reaches the first preset time.'] | false | [
"5",
"16"
] | |
EP_3501307_B1 (3).png | EP3501307B1 | ELECTRONIC CIGARETTE AND CONTROL METHOD THEREFOR | [
"FIG6"
] | [
"FIG6 is a flow chart of steps of another control method for an electronic cigarette according to the third embodiment of the present invention"
] | [
"Optionally, referring to FIG6, FIG6 is a flow chart of another control method for an electronic cigarette according to an embodiment of the present invention. As shown in FIG6, the step S504 may further include controlling a reminder device on the electronic cigarette to issue an alarm, in order to remind the user... | 24 | 77 | flowchart | A | [
{
"element_identifier": "100",
"terms": [
"electronic cigarette"
]
},
{
"element_identifier": "10",
"terms": [
"housing"
]
},
{
"element_identifier": "20",
"terms": [
"mouthpiece"
]
},
{
"element_identifier": "102",
"terms": [
"battery ... | ['1. An electronic cigarette, comprising a microprocessor (101, 201), a battery module (102, 202) and a heating element (103, 203), the microprocessor (101, 201) being electrically connected to the battery module (102, 202), the battery module (102, 202) being electrically connected to the heating element (103, 203) and supplying power to the heating element (103, 203) with a first output parameter, a sensing module (109, 204), connected to the microprocessor (101, 201) and disposed in a smoke outlet passage (108) of the electronic cigarette, for detecting the concentration of an analyte and sending the concentration of the analyte to the microprocessor (101, 201); characterized in that the analyte comprises one or more of fine particles, smoke tar, carbon monoxide, nicotine, formaldehyde, acetaldehyde, acrolein, and glyoxal; wherein the sensing module (109, 204) comprises one or more of a PM2.5 sensor, a tar sensor, a carbon monoxide sensor, a semiconductor sensor, and an electrochemical sensor; wherein the microprocessor (101, 201) stores a preset threshold, the microprocessor (101, 201) is configured to receive the concentration of the analyte detected by the sensing module (109, 204), and further configured to determine the relationship between the concentration of the analyte and the preset threshold; when the concentration of the analyte is higher than or equal to the preset threshold, the microprocessor (101, 201) controls the battery module (102, 202) to supply power to the heating element (103, 203) with a second output parameter, wherein the second output parameter is smaller than the first output parameter.', '4. The electronic cigarette according to claim 1 , wherein the electronic cigarette further comprises a timer (206), wherein: the timer (206) is configured for calculating time T1 and sending T1 to the microprocessor (101, 201), wherein T1 is the time during which the battery module (102, 202) supplies power to the heating element (103, 203) with the first output parameter; the microprocessor (101, 201) stores a first preset time, the microprocessor (101, 201) is further configured to control the sensing module (109, 204) to detect the concentration of the analyte when T1 reaches the first preset time.'] | false | [
"6",
"17"
] | |
EP_3501307_B1.png | EP3501307B1 | ELECTRONIC CIGARETTE AND CONTROL METHOD THEREFOR | [
"FIG1"
] | [
"FIG1 is a schematic structural diagram of an electronic cigarette according to a first embodiment of the present invention"
] | [
"Referring to FIG1, a structural diagram of an electronic cigarette 100 according to a first embodiment of the present invention is shown. The electronic cigarette 100 includes a housing 10, a mouthpiece 20 disposed at one end of the housing 10, a battery module 102 received in the housing 10, a heating element 103... | 19 | 130 | schematic structural diagram | A | [
{
"element_identifier": "103",
"terms": [
"heating element"
]
},
{
"element_identifier": "100",
"terms": [
"electronic cigarette"
]
},
{
"element_identifier": "20",
"terms": [
"mouthpiece"
]
},
{
"element_identifier": "104",
"terms": [
... | ['1. An electronic cigarette, comprising a microprocessor (101, 201), a battery module (102, 202) and a heating element (103, 203), the microprocessor (101, 201) being electrically connected to the battery module (102, 202), the battery module (102, 202) being electrically connected to the heating element (103, 203) and supplying power to the heating element (103, 203) with a first output parameter, a sensing module (109, 204), connected to the microprocessor (101, 201) and disposed in a smoke outlet passage (108) of the electronic cigarette, for detecting the concentration of an analyte and sending the concentration of the analyte to the microprocessor (101, 201); characterized in that the analyte comprises one or more of fine particles, smoke tar, carbon monoxide, nicotine, formaldehyde, acetaldehyde, acrolein, and glyoxal; wherein the sensing module (109, 204) comprises one or more of a PM2.5 sensor, a tar sensor, a carbon monoxide sensor, a semiconductor sensor, and an electrochemical sensor; wherein the microprocessor (101, 201) stores a preset threshold, the microprocessor (101, 201) is configured to receive the concentration of the analyte detected by the sensing module (109, 204), and further configured to determine the relationship between the concentration of the analyte and the preset threshold; when the concentration of the analyte is higher than or equal to the preset threshold, the microprocessor (101, 201) controls the battery module (102, 202) to supply power to the heating element (103, 203) with a second output parameter, wherein the second output parameter is smaller than the first output parameter.'] | false | [
"100",
"20",
"103",
"105",
"107",
"104",
"106",
"101",
"10",
"102",
"1",
"14"
] | |
EP_3501333_B1 (2).png | EP3501333B1 | ORAL CARE IMPLEMENT | [
"FIG3"
] | [
"FIG3 shows a diagram of a flow chart for molding the handle of the oral care implement according to the present disclosure"
] | [
"FIG3 shows a diagram of a flow chart illustrating the steps of making a handle 12 or a portion of a handle of the oral care implement 10 according to the present disclosure. An amorphous thermoplastic resin, optionally comprising glass fibers, is provided at 100. Aluminum oxide, boron nitride or aluminum silicate ... | 22 | 167 | diagram | A | [
{
"element_identifier": "19",
"terms": [
"distal end"
]
},
{
"element_identifier": "160",
"terms": [
"implement/handle is shown at"
]
},
{
"element_identifier": "130",
"terms": [
"At",
"about"
]
},
{
"element_identifier": "100",
"terms"... | ['1. An oral care implement (10, 300, 310) having an overall length extension (15, 720) extending between a proximal end (17) and a distal end (19, 760), the distal end (19, 760) being opposite the proximal end (17), the oral care implement (10, 300, 310) comprising a head (14) at the proximal end (17) and a handle (12, 600, 610), the handle (12, 600, 610) being at least partially made from a material having a density being higher than the density of the material of the head (14), the oral care implement (10, 300, 310) having a center of gravity (500, 510) located at a distance (740) measured from the distal end (19, 760), wherein the ratio of said distance (740) to the overall length extension (15, 720) of the oral care implement (10, 300, 310) is from about 0.30 to about 0.45, preferably from about 0.35 to about 0.42, further preferably from about 0.38 to about 0.41, characterized in that the material of the handle (12, 600 , 610) comprises a magnetic and/or ferromagnetic material comprising from about 13 weight percent to about 30 weight percent of an amorphous thermoplastic resin; from about 3 weight percent to about 25 weight percent of aluminium oxide, boron nitride or aluminium silicate; and from about 45 weight percent to about 67 weight percent of iron oxide.'] | false | [
"100",
"110",
"120",
"130",
"140",
"150",
"160",
"3",
"19"
] | |
EP_3501333_B1 (6).png | EP3501333B1 | ORAL CARE IMPLEMENT | [
"FIG10"
] | [
"FIG10 shows a side view of an example embodiment of an oral care implement according to the present disclosure "
] | [
"In contrast to the toothbrushes of the state of the art having a lightweight handle, toothbrush 310 according to the present disclosure has a center of gravity 510 being located below the axis of rotation 515 when the brush is loaded with about 1.4 g of toothpaste and placed on a substantially planer/flat surface ... | 19 | 132 | side view | A | [
{
"element_identifier": "1",
"terms": [
"about"
]
},
{
"element_identifier": "1000",
"terms": [
"toothbrush"
]
},
{
"element_identifier": "11",
"terms": [
"front side"
]
},
{
"element_identifier": "400",
"terms": [
"toothpaste"
]
... | ['1. An oral care implement (10, 300, 310) having an overall length extension (15, 720) extending between a proximal end (17) and a distal end (19, 760), the distal end (19, 760) being opposite the proximal end (17), the oral care implement (10, 300, 310) comprising a head (14) at the proximal end (17) and a handle (12, 600, 610), the handle (12, 600, 610) being at least partially made from a material having a density being higher than the density of the material of the head (14), the oral care implement (10, 300, 310) having a center of gravity (500, 510) located at a distance (740) measured from the distal end (19, 760), wherein the ratio of said distance (740) to the overall length extension (15, 720) of the oral care implement (10, 300, 310) is from about 0.30 to about 0.45, preferably from about 0.35 to about 0.42, further preferably from about 0.38 to about 0.41, characterized in that the material of the handle (12, 600 , 610) comprises a magnetic and/or ferromagnetic material comprising from about 13 weight percent to about 30 weight percent of an amorphous thermoplastic resin; from about 3 weight percent to about 25 weight percent of aluminium oxide, boron nitride or aluminium silicate; and from about 45 weight percent to about 67 weight percent of iron oxide.', '3. The oral care implement (10, 300, 310) of any of the preceding claims, wherein the oral care implement (10, 300, 310) has a front side (11) and a back side (13) opposite the front side (11), and the head (14) has at least one cleaning element (21) extending from the front side (11), and the handle (12, 600, 610) has a cross-sectional area extending substantially perpendicular to the overall length extension (15, 720) of the oral care implement (10, 300, 310), the cross-sectional area has a height extension (23) extending between the front side (11) and the back side (13), and the oral care implement (10, 300, 310) has an axis of rotation (515) when the oral care implement (10, 300, 310) is placed with the back side (13) on a surface (517), and the center of gravity (500, 510) is below the axis of rotation (515) and closer to the back side (13) than to the front side (11) when measured along the height extension (23) of the handle (12, 600, 610).'] | true | [
"1000",
"400",
"1100",
"1300",
"1200",
"8",
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"400",
"1100",
"1010",
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"610",
"13",
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"720",
"517",
"14",
"10",
"23"
] | |
EP_3501334_B1 (1).png | EP3501334B1 | ORAL CARE IMPLEMENT | [
"FIG2"
] | [
"FIG2 shows a perspective view of an example embodiment of a kit comprising the oral care implement according to the present disclosure, and a magnetic holder at which the oral care implement is magnetically attached"
] | [
"The material of which the handle 12 is at least partially made possesses magnetic and/or ferromagnetic properties. FIG2 shows a kit 22 comprising a manual toothbrush 10 with handle 12 to which head 14 is attached, and a magnetic holder 24 onto which toothbrush 10 is magnetically attached."
] | 36 | 51 | perspective view | A | [
{
"element_identifier": "24",
"terms": [
"magnetic holder"
]
},
{
"element_identifier": "17",
"terms": [
"about"
]
},
{
"element_identifier": "14",
"terms": [
"head"
]
},
{
"element_identifier": "12",
"terms": [
"handle"
]
},
{
... | ['1. An oral care implement (10, 300, 310) comprising a head (14) and a handle (12, 600, 610), the head (14) being repeatedly attachable to and detachable from the handle (12, 600, 610), the head (14) being at least partially made from a material having a density from about 0.5 g/cm 3 to about 1.2 g/cm 3 , and the handle (12) being at least partially made from a material having a density from about 2.1 g/cm 3 to about 3.1 g/cm 3 , wherein the material of the head (14) is a non-magnetic and/or non-ferromagnetic material, preferably polypropylene; and the material of the handle (12, 600, 610) comprises a magnetic and/or ferromagnetic material and the magnetic and/or ferromagnetic material of the handle (12, 600, 610) comprises from about 13 weight percent to about 30 weight percent of an amorphous thermoplastic resin; from about 3 weight percent to about 25 weight percent of aluminium oxide, boron nitride or aluminium silicate; and from about 45 weight percent to about 67 weight percent of iron oxide.', '6. A kit (22) comprising the oral care implement (10, 300, 310) of any of the preceding claims and a magnetic holder (24) for attaching and holding the oral care implement (10, 300, 310).'] | false | [
"22",
"14",
"10",
"16",
"24",
"12",
"2",
"17"
] | |
EP_3501334_B1 (2).png | EP3501334B1 | ORAL CARE IMPLEMENT | [
"FIG3"
] | [
"FIG3 shows a diagram of a flow chart for molding the handle of the oral care implement according to the present disclosure"
] | [
"FIG3 shows a diagram of a flow chart illustrating the steps of making a handle 12 or a portion of a handle of the oral care implement 10 according to the present disclosure. An amorphous thermoplastic resin, optionally comprising glass fibers, is provided at 100. Aluminum oxide, boron nitride or aluminum silicate ... | 22 | 167 | diagram | A | [
{
"element_identifier": "160",
"terms": [
"article is shown at"
]
},
{
"element_identifier": "130",
"terms": [
"At",
"about"
]
},
{
"element_identifier": "18",
"terms": [
"metal layer"
]
},
{
"element_identifier": "100",
"terms": [
... | ['1. An oral care implement (10, 300, 310) comprising a head (14) and a handle (12, 600, 610), the head (14) being repeatedly attachable to and detachable from the handle (12, 600, 610), the head (14) being at least partially made from a material having a density from about 0.5 g/cm 3 to about 1.2 g/cm 3 , and the handle (12) being at least partially made from a material having a density from about 2.1 g/cm 3 to about 3.1 g/cm 3 , wherein the material of the head (14) is a non-magnetic and/or non-ferromagnetic material, preferably polypropylene; and the material of the handle (12, 600, 610) comprises a magnetic and/or ferromagnetic material and the magnetic and/or ferromagnetic material of the handle (12, 600, 610) comprises from about 13 weight percent to about 30 weight percent of an amorphous thermoplastic resin; from about 3 weight percent to about 25 weight percent of aluminium oxide, boron nitride or aluminium silicate; and from about 45 weight percent to about 67 weight percent of iron oxide.'] | false | [
"100",
"110",
"120",
"130",
"140",
"150",
"160",
"3",
"18"
] | |
EP_3501335_B1 (1).png | EP3501335B1 | ORAL CARE IMPLEMENT | [
"FIG2"
] | [
"FIG2 shows a perspective view of an example embodiment of a kit comprising the oral care implement according to the present disclosure, and a magnetic holder at which the oral care implement is magnetically attached"
] | [
"The material of which the handle 12 is at least partially made possesses magnetic and/or ferromagnetic properties. FIG2 shows a kit 22 comprising a manual toothbrush 10 with handle 12 to which head 14 is attached, and a magnetic holder 24 onto which toothbrush 10 is magnetically attached."
] | 36 | 51 | perspective view | A | [
{
"element_identifier": "24",
"terms": [
"magnetic holder"
]
},
{
"element_identifier": "14",
"terms": [
"head"
]
},
{
"element_identifier": "12",
"terms": [
"handle"
]
},
{
"element_identifier": "22",
"terms": [
"kit"
]
},
{
... | ['1. An oral care implement (10) comprising a head (14) and a handle (12), the head (14) being repeatedly attachable to and detachable from the handle (12), the head (14) being made from a non-magnetic and/or non-ferromagnetic material, and the handle (12) being made at least partially made from a magnetic and/or ferromagnetic material, characterized in that the magnetic and/or ferromagnetic material comprises from about 13 weight percent to about 30 weight percent of an amorphous thermoplastic resin; from about 3 weight percent to about 25 weight percent of aluminum oxide, boron nitride or aluminum silicate; and from about 45 weight percent to about 67 weight percent of iron oxide.', '5. The oral care implement (10) of any of the preceding claims, wherein the handle (14) comprises a thumb rest (16) being made from thermoplastic elastomer material and/or from polypropylene material.', '8. A kit (22) comprising the oral care implement (10) of any of the preceding claims and a magnetic holder (24) for attaching and holding the oral care implement (10).'] | false | [
"22",
"14",
"16",
"24",
"12",
"2",
"14"
] | |
EP_3501335_B1 (2).png | EP3501335B1 | ORAL CARE IMPLEMENT | [
"FIG3"
] | [
"FIG3 shows a diagram of a flow chart for molding the handle of the oral care implement according to the present disclosure "
] | [
"FIG3 shows a diagram of a flow chart illustrating the steps of making a handle 12 or a portion of a handle of the oral care implement 10 according to the present disclosure. An amorphous thermoplastic resin, optionally comprising glass fibers, is provided at 100. Aluminum oxide, boron nitride or aluminum silicate ... | 22 | 163 | diagram | A | [
{
"element_identifier": "160",
"terms": [
"handle is shown at"
]
},
{
"element_identifier": "130",
"terms": [
"At"
]
},
{
"element_identifier": "100",
"terms": [
"is provided at"
]
},
{
"element_identifier": "110",
"terms": [
"silicate ... | ['1. An oral care implement (10) comprising a head (14) and a handle (12), the head (14) being repeatedly attachable to and detachable from the handle (12), the head (14) being made from a non-magnetic and/or non-ferromagnetic material, and the handle (12) being made at least partially made from a magnetic and/or ferromagnetic material, characterized in that the magnetic and/or ferromagnetic material comprises from about 13 weight percent to about 30 weight percent of an amorphous thermoplastic resin; from about 3 weight percent to about 25 weight percent of aluminum oxide, boron nitride or aluminum silicate; and from about 45 weight percent to about 67 weight percent of iron oxide.'] | false | [
"100",
"110",
"120",
"130",
"140",
"150",
"160",
"3",
"15"
] | |
EP_3501346_B1 (1).png | EP3501346B1 | PORTION DISPENSER FOR DISPENSING PORTIONED BEVERAGE ITEMS | [
"FIG4"
] | [
"FIG4 is an enlarged view of FIG3 showing the interface between the exchangeable cartridge and the portion dispenser in the extended position of the piston"
] | [
"The tubular surface 13 of the dispenser is arranged for coupling with the tubular member 7 of the exchangeable cartridge such that the cartridge is held in a substantial vertical arrangement thereby allowing the discharge of the beverage items by gravity in the dispenser. The receiving portion 5 may further compri... | 25 | 254 | enlarged view | A | [
{
"element_identifier": "5",
"terms": [
"receiving portion"
]
},
{
"element_identifier": "20",
"terms": [
"piston housing"
]
},
{
"element_identifier": "40",
"terms": [
"control unit"
]
},
{
"element_identifier": "29",
"terms": [
"spind... | ['1. Portion dispenser (2) for dispensing beverage items (8) from an exchangeable cartridge (3) comprising: a frame (4) with a receiving portion (5) for receiving the exchangeable cartridge, a discharge opening (6) next to the receiving portion (5) and sized for allowing a beverage item to be individually discharged by gravity from the exchangeable cartridge, a piston assembly (16) comprising a piston (19) and a piston housing (20) in which the piston is arranged for moving therein, wherein the piston (19) is arranged for providing a discharge chamber (23) for discharge of at least one beverage item therein and for transporting to a dispensing area (17) and, wherein the piston assembly (16) is arranged for sealingly connecting with the exchangeable cartridge (3) and comprises means for opening the exchangeable cartridge to allow the discharge of the beverage item in the discharge chamber and for re-closing the exchangeable cartridge.', '5. Portion dispenser according to claim 4, wherein the terminal portion (24) of the piston (19) forms at least a part of a keying member (25) arranged for complementarily fitting with a locking member (26) of the closure cap (14) to be removed from the tubular storage member (7) of the exchangeable cartridge.', '6. Portion dispenser according to any one of claims 1 to 5, wherein the piston assembly (16) is mounted moveable relative to the frame (4) so as to move the discharge chamber (23) between a discharge position in which the piston (19) is situated in axial relationship with the discharge opening (6) and a dispensing position in which the piston (19) is situated in axial relationship with a dispensing opening (18) of the frame.', '7. Portion dispenser according to claim 6, wherein the piston assembly (16) comprises a shutter (36) arranged for sealingly closing the discharge opening (18) as the piston housing (20) moves the piston to the dispensing area (17).', '8. Portion dispenser according to any one of claims 1 or 7, wherein the opening and re-closing means comprise a piston actuator (27) arranged for driving the piston (19) in a reciprocal axial path, most preferably a combined axial and rotational path.', '11. Portion dispenser system (1) according to claim 10, wherein the exchangeable cartridge (3) comprises: a tubular storage member (7) comprising an interior for accommodating a plurality of portioned beverage ingredient items (8) (also referred as "beverage items") comprising a closed end (9) and an open end (10) comprising an exit opening (11) having a size preferably configured for allowing the dispensing of a single beverage item at a time, wherein the tubular storage member (7) comprises an attachment portion (12) at or next to the exit opening (11) and connectable to at least one tubular surface (13) of the receiving portion (5) and, a closure cap (14) adapted to connect to the tubular storage member (7) at the open end (10) of the tubular storage member in a removable and sealable manner through a removable complementary connection (15) of the tubular storage member and closure cap.'] | true | [
"16",
"19",
"25",
"20",
"29",
"28",
"27",
"31",
"89",
"40",
"30",
"24",
"13",
"21",
"14",
"15",
"33",
"25",
"20",
"19",
"16",
"5",
"18",
"29",
"26",
"36",
"17"
] | |
EP_3501346_B1 (3).png | EP3501346B1 | PORTION DISPENSER FOR DISPENSING PORTIONED BEVERAGE ITEMS | [
"FIG11"
] | [
"FIG11 is an enlarged cross-section view of FIG7"
] | [
"The support surface of the closure cap (i.e. the surface supporting the beverage item for dispensing it through the housing as shown in FIG11) is also designed to match the surface of the shutter so that the amount of air that can enter in the cartridge is kept as low as possible. Preferably, the support surface o... | 10 | 72 | cross-sectional view | A | [
{
"element_identifier": "19",
"terms": [
"piston"
]
},
{
"element_identifier": "12",
"terms": [
"attachment portion"
]
},
{
"element_identifier": "11",
"terms": [
"exit opening"
]
},
{
"element_identifier": "18",
"terms": [
"dispensing ... | ['1. Portion dispenser (2) for dispensing beverage items (8) from an exchangeable cartridge (3) comprising: a frame (4) with a receiving portion (5) for receiving the exchangeable cartridge, a discharge opening (6) next to the receiving portion (5) and sized for allowing a beverage item to be individually discharged by gravity from the exchangeable cartridge, a piston assembly (16) comprising a piston (19) and a piston housing (20) in which the piston is arranged for moving therein, wherein the piston (19) is arranged for providing a discharge chamber (23) for discharge of at least one beverage item therein and for transporting to a dispensing area (17) and, wherein the piston assembly (16) is arranged for sealingly connecting with the exchangeable cartridge (3) and comprises means for opening the exchangeable cartridge to allow the discharge of the beverage item in the discharge chamber and for re-closing the exchangeable cartridge.', '6. Portion dispenser according to any one of claims 1 to 5, wherein the piston assembly (16) is mounted moveable relative to the frame (4) so as to move the discharge chamber (23) between a discharge position in which the piston (19) is situated in axial relationship with the discharge opening (6) and a dispensing position in which the piston (19) is situated in axial relationship with a dispensing opening (18) of the frame.', '7. Portion dispenser according to claim 6, wherein the piston assembly (16) comprises a shutter (36) arranged for sealingly closing the discharge opening (18) as the piston housing (20) moves the piston to the dispensing area (17).', '11. Portion dispenser system (1) according to claim 10, wherein the exchangeable cartridge (3) comprises: a tubular storage member (7) comprising an interior for accommodating a plurality of portioned beverage ingredient items (8) (also referred as "beverage items") comprising a closed end (9) and an open end (10) comprising an exit opening (11) having a size preferably configured for allowing the dispensing of a single beverage item at a time, wherein the tubular storage member (7) comprises an attachment portion (12) at or next to the exit opening (11) and connectable to at least one tubular surface (13) of the receiving portion (5) and, a closure cap (14) adapted to connect to the tubular storage member (7) at the open end (10) of the tubular storage member in a removable and sealable manner through a removable complementary connection (15) of the tubular storage member and closure cap.'] | true | [
"18",
"37",
"19",
"11",
"36",
"12",
"21"
] | |
EP_3501346_B1.png | EP3501346B1 | PORTION DISPENSER FOR DISPENSING PORTIONED BEVERAGE ITEMS | [
"FIG2"
] | [
"FIG2 shows a side view of an exchangeable cartridge of the invention"
] | [
"As illustrated in FIG2, the exchangeable cartridge 3 comprises a tubular storage member 7 for storing beverage items 8 such as compacted balls of beverage ingredients. The beverage ingredients can comprise or be roast and ground coffee. The tubular storage member is preferably arranged to accommodate a pile of bev... | 12 | 258 | side view | A | [
{
"element_identifier": "8",
"terms": [
"storing beverage items",
"selected beverage item"
]
},
{
"element_identifier": "14",
"terms": [
"cap"
]
},
{
"element_identifier": "12",
"terms": [
"attachment portion"
]
},
{
"element_identifier": "... | ['1. Portion dispenser (2) for dispensing beverage items (8) from an exchangeable cartridge (3) comprising: a frame (4) with a receiving portion (5) for receiving the exchangeable cartridge, a discharge opening (6) next to the receiving portion (5) and sized for allowing a beverage item to be individually discharged by gravity from the exchangeable cartridge, a piston assembly (16) comprising a piston (19) and a piston housing (20) in which the piston is arranged for moving therein, wherein the piston (19) is arranged for providing a discharge chamber (23) for discharge of at least one beverage item therein and for transporting to a dispensing area (17) and, wherein the piston assembly (16) is arranged for sealingly connecting with the exchangeable cartridge (3) and comprises means for opening the exchangeable cartridge to allow the discharge of the beverage item in the discharge chamber and for re-closing the exchangeable cartridge.', '4. Portion dispenser according to claims 2 or 3, wherein the piston (19) comprises a terminal portion (24) arranged for connecting to a closure cap (14) removably attached to a tubular storage member (7) of the exchangeable cartridge (3) so that the piston (19) moves between the retracted position and the extended position with the closure cap (14) connected thereto.', '6. Portion dispenser according to any one of claims 1 to 5, wherein the piston assembly (16) is mounted moveable relative to the frame (4) so as to move the discharge chamber (23) between a discharge position in which the piston (19) is situated in axial relationship with the discharge opening (6) and a dispensing position in which the piston (19) is situated in axial relationship with a dispensing opening (18) of the frame.', '11. Portion dispenser system (1) according to claim 10, wherein the exchangeable cartridge (3) comprises: a tubular storage member (7) comprising an interior for accommodating a plurality of portioned beverage ingredient items (8) (also referred as "beverage items") comprising a closed end (9) and an open end (10) comprising an exit opening (11) having a size preferably configured for allowing the dispensing of a single beverage item at a time, wherein the tubular storage member (7) comprises an attachment portion (12) at or next to the exit opening (11) and connectable to at least one tubular surface (13) of the receiving portion (5) and, a closure cap (14) adapted to connect to the tubular storage member (7) at the open end (10) of the tubular storage member in a removable and sealable manner through a removable complementary connection (15) of the tubular storage member and closure cap.'] | false | [
"8",
"18",
"89",
"40",
"8",
"22",
"11",
"10",
"14",
"12",
"16"
] | |
EP_3501359_B1 (5).png | EP3501359B1 | PAPER PRODUCTS DISPENSER | [
"FIG13",
" FIG14"
] | [
"FIG13 is a side cross-section view of the dispenser container ",
"FIG14 is a detailed view of the shaped side support, which can be inserted into one of the side housings of the dispenser container, wherein sheets containing information and/or advertising messages can be placed"
] | [
"As can be seen, instead, in FIG13, also the housings 19a, 19b, 19c have correspondingly respective raised elements 20,21 arranged in a convergent manner, so as to constitute a guide for the insertion of the respective shaped panels 22a, 22b, 22c. ",
"Each one of the shaped panels 22a, 22b, 22c, observed in plan ... | 48 | 93 | detailed view, side cross-sectional view | A | [
{
"element_identifier": "14",
"terms": [
"first member"
]
},
{
"element_identifier": "20",
"terms": [
"raised elements"
]
},
{
"element_identifier": "16",
"terms": [
"first seat"
]
},
{
"element_identifier": "15",
"terms": [
"second mem... | ['1. A dispenser (1) for paper products comprising at least one container (2), provided with an internal volume (3) and at least one opening (4) which allows access to said internal volume (3), and at least one drawer (5), housed in said internal volume (3), comprising at least one compartment (7) for housing paper products (P), and at least one window (6a) through which the user can manually withdraw paper products (P), said drawer (5) being selectively removable through said opening (4), so as to allow for feeding/refilling paper products (P) as they are withdrawn by users, characterised in that it comprises magnetic retention means (13) of said drawer (5) inside said container (2).', '2. A dispenser (1) according to claim 1, wherein said magnetic retention means (13) comprise a first member (14) fixed to said container (2), and a second member (15) fixed to said drawer (5), said first member (14) and second member (15) being subjected to a mutual magnetic attraction force when they are close to each other.', '5. A dispenser (1) according to any one of claims 2 to 4, wherein said first member (14) is engaged in a respective first seat (16) provided in the bottom wall (2e) of said container (2) opposed to said opening (4), or in one of the side walls (2a, 2b, 2c, 2d) of said container (2) at, or in the immediate vicinity of, said bottom wall (2e).'] | true | [
"21",
"20",
"13",
"20",
"14",
"15",
"16"
] | |
EP_3501398_B1.png | EP3501398B1 | ENT BONE DISTANCE COLOR CODED FACE MAPS | [
"FIG1"
] | [
"FIG1 is a schematic diagram of a surface registration system, according to an embodiment of the present invention"
] | [
"FIG1 is a schematic diagram of a surface registration system 10, according to an embodiment of the present invention. System 10 is used to register a magnetic tracking system 12 with an image, herein by way of example assumed to comprise a computerized tomography (CT) image, of a subject 14. Tracking system 12 is ... | 19 | 336 | schematic diagram | A | [
{
"element_identifier": "40",
"terms": [
"bed"
]
},
{
"element_identifier": "42",
"terms": [
"frame"
]
},
{
"element_identifier": "52",
"terms": [
"skin"
]
},
{
"element_identifier": "43",
"terms": [
"with cable"
]
},
{
"ele... | ['2. An apparatus comprising: a display device; and a processor, which is configured to receive a computerized tomography (CT) image comprising voxels of a body part of a subject, to segment the image so as to identify a surface of a skin and a surface of a bone in the image, to measure respective minimum distances to the bone from a plurality of points on the surface of the skin, and to render an image of the surface of the skin on the display device while visually coding the rendered image so as to indicate the respective minimum distances.', '13. The method according to claim 1 or the apparatus according to claim 2, wherein the body part comprises a head.'] | false | [
"50",
"30",
"32",
"34",
"38",
"1",
"35",
"12",
"43",
"14",
"40",
"36",
"42",
"48",
"36",
"18",
"52",
"16",
"26",
"24",
"28",
"1"
] | |
EP_3501438_B1 (3).png | EP3501438B1 | HEADLESS COMPRESSION SCREW DRIVER SYSTEM | [
"FIG10"
] | [
"FIG10 is a cross-sectional view of the headless compression screw driver system"
] | [
"The tubular body 42 also defines a transverse bore 48 configured to receive the lock button 50. The lock button 50 has a body 52 which defines a through passage 53 which is sized and configured such that the guide portion 32 of the shaft 22 passes therethrough. A locking portion 54 of the lock button body 52 exten... | 14 | 275 | cross-sectional view | A | [
{
"element_identifier": "40",
"terms": [
"drive selection member"
]
},
{
"element_identifier": "76",
"terms": [
"threads"
]
},
{
"element_identifier": "42",
"terms": [
"tubular body"
]
},
{
"element_identifier": "29",
"terms": [
"bore"
... | ['1. A compression screw driver system (10) comprising: a drive member (20) including a shaft (22) extending from a proximal end (21) to a distal end (23) with a drive tip (26) defined on the distal end; a drive selection member (40) positioned about the shaft (22) and secured thereto such that the drive selection member (40) rotates with the shaft (22) and is axially moveable along the shaft (22) between an engagement position and a disengaged position, a distal portion of the drive selection member (40) defining a first engagement structure (59); and a compression sleeve (70) having a tubular body (72) extending from a proximal end (71) to a distal end (73) with a through passage (75) therethrough is positioned over the distal end of the shaft (22) with threads (76) within the through passage threadably engaging threads (36) on the shaft (22), the proximal end of the compression sleeve (70) defines a second engagement structure (79) which complements the first engagement structure and the distal end of the compression sleeve (70) defines a contact surface (81), wherein in the engagement position the first and second engagement structures are engaged and the compression sleeve (70) rotates with the drive member (20) and in the disengaged position the first and second engagement structures are disengaged and the compression sleeve (70) remains stationary while the drive member (20) rotates.', '3. The system of claim 1, wherein the drive selection member (40) includes one or more pairs of axial slots (46) and a connection pin (30) extends through the shaft (22) and into the axial slots (46) to define the axial range of motion of the drive selection member (40).', '4. The system of claim 1, wherein a spring (51) within the drive selection member (40) biases the drive selection member (40) toward the engagement position.', '5. The system of claim 1, wherein a lock button (50) extends into the drive selection member (40) and is configured to engage a notch (34) in the shaft (22) when the drive selection member (40) is in the disengaged position such that the lock button (50) maintains the drive selection member (40) in the disengaged position.', '7. The system of claim 1, wherein the first and second engagement structures are in the form of radial teeth.', '11. The system of claim 1, wherein the shaft (22) includes a guide portion (32) with a non-circular configuration which complements a non-circular portion of a through passage of the drive selection member (40).'] | true | [
"40",
"28",
"46",
"70",
"36",
"76",
"80",
"75",
"74",
"32",
"31",
"54",
"58",
"34",
"59",
"56",
"79",
"10",
"29",
"46",
"42",
"57",
"59",
"70",
"47",
"32",
"22",
"79",
"11",
"12"
] | |
EP_3501454_B1 (2).png | EP3501454B1 | EVERTING TRANSCATHETER VALVE | [
"FIG2"
] | [
"FIG2 is a representation of the embodiment of the two piece valve of FIG1A unrolled to a flat orientation"
] | [
"As shown in FIG2, the three posts 131 extend away from body frame when in the non-everted configuration.",
"The leaflet frame 130 is elastically compressible to obtain a relatively small diameter to accommodate percutaneous transcatheter mounting and delivery. In accordance with an embodiment as shown in FIG2, t... | 19 | 272 | embodiment | A | [
{
"element_identifier": "122",
"terms": [
"apertures"
]
},
{
"element_identifier": "160",
"terms": [
"film"
]
},
{
"element_identifier": "142",
"terms": [
"leaflet free edge",
"leaflet free edges"
]
},
{
"element_identifier": "136",
"te... | ['1. A transcatheter valve comprising: a multi-part frame comprising a leaflet frame and a body frame, wherein the body frame is located coaxially, laterally adjacent to and spaced apart from the leaflet frame in a non-everted configuration, a plurality of leaflets, and a film which is coupled to the body frame and the leaflet frame and said film couples the body frame to the leaflet frame across at least a fold region, said valve having a collapsed configuration and an expanded configuration and operable to fold along a generally circumferential line in the fold region to provide an everted configuration.', '3. The transcatheter valve of claim 1 or claim 2 wherein said valve has a pre-deployed configuration wherein said plurality of leaflets are carried by the leaflet frame which is external to the body frame and said leaflet frame is operable to be everted into the body frame by rotating about the fold region to present said plurality of leaflets inside said body frame in a post-deployed configuration.', '5. The transcatheter valve of any of the proceeding claims wherein the leaflet frame has a generally annular shape defining a plurality of U-shaped portions each defining a base and a plurality of posts.'] | false | [
"100",
"122",
"19",
"2",
"160",
"142",
"160",
"140",
"132",
"136",
"135",
"133",
"137",
"133",
"135",
"160",
"140",
"134",
"131",
"130",
"132",
"142"
] |
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