pierreqi/scilab_code · Datasets at Hugging Face

ed18ff13fd778f1c19ad78f559add2e3f33250e9

1b969fbb81566edd3ef2887c98b61d98b380afd4

/Rez/bivariate-lcmsr-post_mi/bfas_ea_hrz_col_d/~BivLCM-SR-bfas_ea_hrz_col_d-PLin-VLin.tst

25940c1d94a06a5c53729b628bca41819c15f431

[]

no_license

psdlab/life-in-time-values-and-personality

35fbf5bbe4edd54b429a934caf289fbb0edfefee

7f6f8e9a6c24f29faa02ee9baffbe8ae556e227e

refs/heads/master

2020-03-24T22:08:27.964205

2019-03-04T17:03:26

143,070,821

1

0

null

UTF-8

Scilab

false

11,974

tst

~BivLCM-SR-bfas_ea_hrz_col_d-PLin-VLin.tst

THE OPTIMIZATION ALGORITHM HAS CHANGED TO THE EM ALGORITHM. ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 1 2 3 4 5 ________ ________ ________ ________ ________ 1 0.409388D+00 2 -0.616204D-02 0.299466D-02 3 0.426871D-01 -0.630325D-04 0.292608D+00 4 -0.254249D-03 0.370862D-03 -0.498635D-02 0.236375D-02 5 0.112518D-02 0.493353D-04 -0.699495D-03 0.220971D-03 0.454686D-02 6 -0.513462D-04 -0.454020D-05 0.476208D-03 0.153224D-03 0.278489D-03 7 0.208134D-02 0.489330D-04 0.171208D-02 0.251633D-03 0.175288D-02 8 -0.759251D-03 0.425300D-05 0.811737D-03 0.936959D-04 0.458283D-03 9 -0.409457D+00 0.898565D-02 -0.135122D-01 0.763497D-02 0.191444D+00 10 -0.615253D-01 -0.478633D-02 0.949036D-01 0.143155D-01 0.249618D+00 11 -0.105631D+00 0.129875D-01 -0.248333D+00 0.372091D-02 0.781821D-01 12 -0.623743D-01 -0.755724D-02 -0.773963D+00 0.393911D-01 -0.375750D-01 13 0.417322D-01 -0.680010D-04 0.155656D+00 0.205972D-01 0.104447D+00 14 -0.152948D+00 0.208881D-01 -0.470593D+00 0.213722D-01 0.739321D-01 15 -0.383890D+01 0.836305D-02 -0.799248D+00 -0.277419D-01 -0.198138D+00 16 0.461739D-02 -0.125078D-01 -0.154943D-01 -0.241565D-02 0.473013D-03 17 0.431724D-02 -0.580700D-04 0.327140D-02 -0.220328D-03 -0.112798D-02 18 -0.777420D+00 0.179395D-01 -0.435406D+00 -0.312918D-01 -0.416738D-02 19 -0.214267D-01 0.104688D-01 0.164456D+00 0.138537D-02 0.190634D-01 20 -0.371095D+00 0.241518D-01 -0.264973D+01 0.654744D-01 -0.313707D-01 21 -0.178252D-01 -0.123705D-01 -0.237821D+00 -0.592037D-03 -0.170441D-01 22 0.272054D-02 -0.521996D-03 0.406268D-02 -0.362468D-03 -0.119193D-02 23 -0.222275D-01 -0.763460D-04 0.524640D-01 -0.125882D-01 -0.108248D-02 24 0.280218D-02 -0.403305D-03 -0.242026D-02 -0.171056D-03 -0.512860D-03 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 6 7 8 9 10 ________ ________ ________ ________ ________ 6 0.119795D-02 7 0.122526D-02 0.368632D-02 8 0.229872D-03 0.100786D-04 0.291825D-02 9 0.455966D-01 0.120147D+00 0.101177D-01 0.604649D+02 10 0.317266D-01 0.109799D+00 0.348775D-01 0.112290D+02 0.262845D+02 11 0.103533D-01 0.348764D-01 -0.157686D-01 0.163237D+02 0.311358D+01 12 0.104199D-01 -0.443764D-02 -0.898834D-02 0.491689D-01 0.137348D+01 13 0.862721D-01 0.176342D+00 0.233901D-01 0.781539D+01 0.979625D+01 14 0.236620D-01 0.657789D-01 0.198886D+00 0.514303D+01 0.640319D+01 15 -0.711314D-02 -0.944316D-01 0.203575D-01 -0.185277D+02 -0.161401D+02 16 0.184407D-02 0.173584D-02 0.170118D-02 0.962036D+00 0.181179D+00 17 -0.395457D-03 -0.695407D-03 -0.656443D-04 -0.167893D+00 -0.853648D-01 18 -0.270245D-01 -0.600798D-01 -0.144298D-01 -0.159857D+01 0.125412D+01 19 -0.877768D-02 0.104250D-01 0.515068D-02 0.120810D+01 0.950033D+00 20 -0.668514D-02 -0.240952D-01 -0.240256D+00 0.216787D+01 -0.297187D+00 21 0.591866D-02 -0.149353D-01 -0.170023D-02 -0.160796D+01 -0.104522D+01 22 -0.183563D-03 -0.881779D-03 0.125963D-03 -0.376802D-01 -0.823774D-01 23 -0.841447D-03 -0.138449D-02 -0.593914D-02 -0.364269D+00 -0.141634D+00 24 -0.245724D-03 -0.681416D-03 0.102749D-02 -0.957085D-02 -0.407678D-01 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 11 12 13 14 15 ________ ________ ________ ________ ________ 11 0.307203D+02 12 0.898869D+01 0.130525D+03 13 -0.159161D+00 -0.302723D+01 0.175635D+02 14 -0.166491D+01 0.358872D+00 0.863169D+01 0.487043D+02 15 -0.467454D+01 -0.129816D+02 -0.350616D+01 -0.413544D+01 0.484973D+03 16 0.680980D-01 -0.762724D-01 0.306637D+00 0.657733D+00 0.198663D+01 17 -0.560736D-01 0.541811D-01 -0.746639D-01 -0.480344D-01 -0.213164D+01 18 -0.437247D+01 -0.639831D+01 -0.211528D+01 -0.195915D+01 0.969751D+02 19 0.109079D+01 -0.651229D+00 0.786816D+00 -0.154851D+00 0.611628D+00 20 0.583336D+01 -0.242286D+02 -0.555940D+01 -0.208217D+02 0.411196D+02 21 -0.770503D+00 0.507700D+00 -0.123479D+01 0.207476D+00 0.801206D+00 22 -0.621782D-01 0.431495D-01 -0.380228D-01 -0.208804D-02 -0.662993D+00 23 0.162529D+00 0.108794D+01 -0.205958D+00 -0.551104D+00 -0.243601D+00 24 -0.762542D-01 -0.109596D+00 -0.227377D-04 0.999761D-01 -0.258029D+00 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 16 17 18 19 20 ________ ________ ________ ________ ________ 16 0.754127D+00 17 -0.578986D-01 0.244312D-01 18 0.496533D+00 -0.687550D+00 0.198263D+03 19 -0.127639D+00 -0.484531D-02 0.390104D+01 0.435082D+01 20 -0.372500D+00 -0.333749D+00 0.819238D+02 0.141943D+01 0.316057D+03 21 0.148275D+00 0.942259D-02 -0.250241D+01 -0.400826D+01 -0.555798D+00 22 0.299005D-02 0.668604D-02 -0.971626D+00 -0.433470D-01 -0.664958D+00 23 0.515432D-02 0.103553D-01 0.102975D+01 0.539599D-01 0.182909D+01 24 0.115450D-01 0.363881D-02 -0.584332D+00 -0.332400D-01 -0.146923D+01 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 21 22 23 24 ________ ________ ________ ________ 21 0.495329D+01 22 0.126848D-01 0.115705D-01 23 -0.302079D-01 -0.844762D-03 0.623036D+00 24 0.442373D-01 0.627790D-02 -0.569549D-01 0.177306D-01 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 1 2 3 4 5 ________ ________ ________ ________ ________ 1 1.000 2 -0.176 1.000 3 0.123 -0.002 1.000 4 -0.008 0.139 -0.190 1.000 5 0.026 0.013 -0.019 0.067 1.000 6 -0.002 -0.002 0.025 0.091 0.119 7 0.054 0.015 0.052 0.085 0.428 8 -0.022 0.001 0.028 0.036 0.126 9 -0.082 0.021 -0.003 0.020 0.365 10 -0.019 -0.017 0.034 0.057 0.722 11 -0.030 0.043 -0.083 0.014 0.209 12 -0.009 -0.012 -0.125 0.071 -0.049 13 0.016 0.000 0.069 0.101 0.370 14 -0.034 0.055 -0.125 0.063 0.157 15 -0.272 0.007 -0.067 -0.026 -0.133 16 0.008 -0.263 -0.033 -0.057 0.008 17 0.043 -0.007 0.039 -0.029 -0.107 18 -0.086 0.023 -0.057 -0.046 -0.004 19 -0.016 0.092 0.146 0.014 0.136 20 -0.033 0.025 -0.276 0.076 -0.026 21 -0.013 -0.102 -0.198 -0.005 -0.114 22 0.040 -0.089 0.070 -0.069 -0.164 23 -0.044 -0.002 0.123 -0.328 -0.020 24 0.033 -0.055 -0.034 -0.026 -0.057 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 6 7 8 9 10 ________ ________ ________ ________ ________ 6 1.000 7 0.583 1.000 8 0.123 0.003 1.000 9 0.169 0.254 0.024 1.000 10 0.179 0.353 0.126 0.282 1.000 11 0.054 0.104 -0.053 0.379 0.110 12 0.026 -0.006 -0.015 0.001 0.023 13 0.595 0.693 0.103 0.240 0.456 14 0.098 0.155 0.528 0.095 0.179 15 -0.009 -0.071 0.017 -0.108 -0.143 16 0.061 0.033 0.036 0.142 0.041 17 -0.073 -0.073 -0.008 -0.138 -0.107 18 -0.055 -0.070 -0.019 -0.015 0.017 19 -0.122 0.082 0.046 0.074 0.089 20 -0.011 -0.022 -0.250 0.016 -0.003 21 0.077 -0.111 -0.014 -0.093 -0.092 22 -0.049 -0.135 0.022 -0.045 -0.149 23 -0.031 -0.029 -0.139 -0.059 -0.035 24 -0.053 -0.084 0.143 -0.009 -0.060 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 11 12 13 14 15 ________ ________ ________ ________ ________ 11 1.000 12 0.142 1.000 13 -0.007 -0.063 1.000 14 -0.043 0.005 0.295 1.000 15 -0.038 -0.052 -0.038 -0.027 1.000 16 0.014 -0.008 0.084 0.109 0.104 17 -0.065 0.030 -0.114 -0.044 -0.619 18 -0.056 -0.040 -0.036 -0.020 0.313 19 0.094 -0.027 0.090 -0.011 0.013 20 0.059 -0.119 -0.075 -0.168 0.105 21 -0.062 0.020 -0.132 0.013 0.016 22 -0.104 0.035 -0.084 -0.003 -0.280 23 0.037 0.121 -0.062 -0.100 -0.014 24 -0.103 -0.072 0.000 0.108 -0.088 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 16 17 18 19 20 ________ ________ ________ ________ ________ 16 1.000 17 -0.427 1.000 18 0.041 -0.312 1.000 19 -0.070 -0.015 0.133 1.000 20 -0.024 -0.120 0.327 0.038 1.000 21 0.077 0.027 -0.080 -0.863 -0.014 22 0.032 0.398 -0.642 -0.193 -0.348 23 0.008 0.084 0.093 0.033 0.130 24 0.100 0.175 -0.312 -0.120 -0.621 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 21 22 23 24 ________ ________ ________ ________ 21 1.000 22 0.053 1.000 23 -0.017 -0.010 1.000 24 0.149 0.438 -0.542 1.000

26e79c21185d0423a530a855e6c23dbd9e3bce8d

449d555969bfd7befe906877abab098c6e63a0e8

/1151/CH1/EX1.23/example23.sce

1f9497c38bd2a46d0579bd844e21ee7dc593fa3b

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

123

sce

example23.sce

//determine the transfer function printf("z1=(1+R*C*s)/(C*s)\n z2=1/(C*s) \n g=z2/z2 \nTransfer function Eo(s)/Ei(s)=g")

e218ae4173050ea3be4abd8c8ecfc113df9b9ff4

449d555969bfd7befe906877abab098c6e63a0e8

/1673/CH5/EX5.7/5_7.sce

da983684a3f81c79423d1498bd3f0a3e9efc9427

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

515

sce

5_7.sce

//surface fitting by cubic spline //example 5.7 //page 195 clc;clear;close; z=[1 2 9;2 3 10;9 10 17]; deff('y=L0(x)','y=x^3/4-5*x/4+1'); deff('y=L1(x)','y=-x^3/2+3*x/2'); deff('y=L2(x)','y=x^3/4-x/4'); x=0.5;y=0.5; S=0; S=S+L0(x)*(L0(x)*z(1,1)+L1(x)*z(1,2)+L2(x)*z(1,3)); S=S+L1(x)*(L0(x)*z(2,1)+L1(x)*z(2,2)+L2(x)*z(2,3)); S=S+L2(x)*(L0(x)*z(3,1)+L1(x)*z(3,2)+L2(x)*z(3,3)); printf('approximated value of z(0.5 0.5)=%f\n\n',S); printf(' error in the approximated value : %f',(abs(1.25-S)/1.25)*100)

52cf814b52a7863ae1fe6002444fea96db4023b1

449d555969bfd7befe906877abab098c6e63a0e8

/869/CH7/EX7.2/7_2.sce

08ff567e09012f28aa128f4468b09a2cf2ed1cab

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

147

sce

7_2.sce

clc //initialisation of variables Iy= 60 //in^4 A= 25 //sq in x= 10 //in //CALCULATIONS Ia= Iy+ A*x^2 //RESULTS printf ('I= %.f in^4',Ia)

b2dde786d6d5913595cdb6538f5850b4b6b7f1c4

a62e0da056102916ac0fe63d8475e3c4114f86b1

/set7/s_Electronic_Devices_And_Circuits__J._Paul_2045.zip/Electronic_Devices_And_Circuits__J._Paul_2045/CH1/EX1.7/Ex1_7.sce

cb232a41f79f16d907ae74041266ae4bd268943a

[]

no_license

hohiroki/Scilab_TBC

cb11e171e47a6cf15dad6594726c14443b23d512

98e421ab71b2e8be0c70d67cca3ecb53eeef1df6

refs/heads/master

2021-01-18T02:07:29.200029

2016-04-29T07:01:39

null

0

null

UTF-8

Scilab

false

238

sce

Ex1_7.sce

errcatch(-1,"stop");mode(2);//pagenumber 29 example 7 ferlev=0.02;//electron volt q=4;//donor impurity added w=0.025;//electron volt ferlev=-((log(q)-8))/40; disp("fermi = "+string((ferlev))+"electron volt"); exit();

637368e154f345ddb321eb9d761651d051f054fd

449d555969bfd7befe906877abab098c6e63a0e8

/3886/CH6/EX6.13/6_13.sce

cf0b07d40a6772b04711f89931563eb5785ecadb

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

142

sce

6_13.sce

//Effort required D=500 //mm d=200 //mm W=5000 //N eta=0.6 VR=2*D/(D-d) MA=eta*VR P=W/MA //N printf("Required effort=%0.0f N",P)

20a98c9a4d1045507eada6bfb08be7360358acfc

449d555969bfd7befe906877abab098c6e63a0e8

/620/CH20/EX20.5/example20_5.sce

7002a0ad7ce8a8be8381f20a59cee65edf255554

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

119

sce

example20_5.sce

f=10^3; v=10; i=50*10^(-3); x_l=v/i; l=x_l/(2*%pi*f); disp("the inductance of the coil (in mH) is"); disp(l*10^3);

8fe474eb7770643787efa5343a9b7abf8fa9c089

449d555969bfd7befe906877abab098c6e63a0e8

/2741/CH1/EX1.7/7.sce

b527a4c316ed6525caa147e76ebaca2d14e7513e

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

485

sce

7.sce

clc clear //Input data Pt=100;//Pressure of air when the bulb is placed in hot water in cm of Hg P100=109.3;//Pressure of air in a constant volume thermometer at 100 degree centigrade in cm of Hg P0=80;//Pressure of air in a constant volume thermometer at 0 degree centigrade in cm of Hg //Calculations t=((Pt-P0)/(P100-P0))*100;//The temperature of the hot water in degree centigrade //Output data printf('The temperature of the hot water is %3.2f degree centigrade',t)

db0a856086a5c332b17cacf5a9e1f8ec598a9c2c

449d555969bfd7befe906877abab098c6e63a0e8

/416/CH2/EX2.4/exp2_4pp.sce

e3b92131406ed1f8927219ae8f7571584550f6e2

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

739

sce

exp2_4pp.sce

clc disp("example 2.4") printf("\n") printf("the chronological load curve is plotted in fig 1 the durition of loads is as under :") lc=[20*ones(1,5),40*ones(1,4),80*ones(1,9),100*ones(1,4),20*ones(1,2)] ldc=gsort(lc); [mm,nn]=size(ldc) printf("\n") for i=1:nn printf("\t%dW",ldc(i));//arranging accending order end e=sum(ldc) printf("\nthe load duration curve is ploted in 2 the energy produced by plant in 24 hours \n =100x4+80x(13-4)+40(17-13)+20(24-17)=%dMWh \n",e); lff=e/(24*max(ldc)); printf("load factor =1420/2400=%f=%f in persent",lff,lff*100) t=1:1:24 subplot(121); plot2d2(t,lc); xtitle("chronological curve","time","load MW"); subplot(122); plot2d2(t,ldc); xtitle("load duration curve","time","load MW");

6923cbeba908c900d4501b51ae4a92a44450b09d

449d555969bfd7befe906877abab098c6e63a0e8

/135/CH5/EX5.5/EX5.sce

2ffaf877b6ce598f5cae0e4acf249ddddb43d5a4

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

724

sce

EX5.sce

// Example 5.5: VCEQ, ICQ clc, clear VBE=0.7; // in volts betaf=120; // From Fig. 5.15 VCC=20; // in volts VEE=20; // in volts R1=8.2e3; // in ohms R2=2.2e3; // in ohms RC=2.7e3; // in ohms RE=1.8e3; // in ohms // Using Thevnin's theorem to obtain equivalent circuit given in Fig. 5.16(b) RB=R1*R2/(R1+R2); // in ohms // From Fig. 5.16(a) I=(VCC+VEE)/(R1+R2); // in amperes VBB=I*R2-VEE; // in volts // Writing KVL for the base emitter loop and putting Ic= βF*Ib gives IB=(VEE+VBB-VBE)/(RB+(1+betaf)*RE); // in amperes IC=betaf*IB; // in amperes // KVL for the collector loop gives VCE=VCC+VEE-IC*(RC+RE)-IB*RE; // in volts IC=IC*1e3; // in mili-amperes disp(VCE,"VCEQ (V) ="); disp(IC,"ICQ (mA) =");

8e22c1791552f7826edde26ccca49e5e67f09004

449d555969bfd7befe906877abab098c6e63a0e8

/3785/CH1/EX1.2/Ex1_2.sce

a38ac94ba299882d8f1bfa819ec73b2cf9ad84c6

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

517

sce

Ex1_2.sce

// Example 1_2 clc;funcprot(0); // Given data T=98.6;// Temperature in °F p=1.0133*10^5;// Pressure in N/m^2 M=32;// The molecular weight of oxygen R=8.3143*10^3;// Universal gas constant in J/kg.K O=20/100;// The maximum oxygen concentration in oxygenated blood in % // Calculation rho=(p*M)/(R*(273.15+((5/9)*(T-32))));// Density in kg/m^3 rho_O2=O*rho;// The partial density of blood oxygen in kg/m^3 printf("\nThe partial density of oxygen in blood at this concentration is %0.4f kg/m^3",rho_O2);

327692f5e635c236ce3bc84905eda627f0ddf14d

449d555969bfd7befe906877abab098c6e63a0e8

/3821/CH13/EX13.3/Example13_3.sce

3117d467334d9a4c3802cd1c803ff9e73f0b648f

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

535

sce

Example13_3.sce

////Chapter 13 Steam Engines ////Example 13.2 Page No 285 ///Find Mean Effective pressure ///Input data clc; clear; P1=14; //Steam is ssupplied in bar P6=6; //Pressure at the end in bar Pb=1.2; //Pressure at back in bar a=0.1; re=4; //From hyperbolic process b=0.4; ///Calculation //Mean Effective pressure in N/m^2 Pm=P1*((1/re)+((1/re)+a)*log((1+a)/((1+re)+a)))-Pb*((1+b)+(a+b)*log((a+b)/a)); //Output printf('Mean Effective pressure= %f N/m^2 \n',-Pm);

2347591d72339627c5e70f9c544a062d6ce7e7ec

449d555969bfd7befe906877abab098c6e63a0e8

/213/CH11/EX11.12/11_12.sce

d4903266cec90e3420ab2a0a7e041753e005a9e3

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

569

sce

11_12.sce

//To find power transmitted clc //Given: T0=2000 //N mu0=0.3 theta=150*%pi/180 //radians r2=200/1000, d2=2*r2 //m N2=500//rpm //Solution: //Calculating the velocity of the belt v=%pi*d2*N2/60 //m/s //Calculating the tensions in the belt //Initial tension, T0 = (T1+T2)/2, or T1+T2 = 2*T0 //Ratio of the tensions in the belt, log(T1/T2) = mu0*theta, or T1-T2*exp(mu0*theta) = 0 A=[1 1; 1 -exp(mu0*theta)] B=[2*T0; 0] V=A \ B T1=V(1) //N T2=V(2) //N //Calculating the power transmitted P=(T1-T2)*v/1000 //kW //Results: printf("\n\n Power transmitted, P = %.1f kW.\n\n",P)

f7e690f88274cc6d5d2dfd476f0c8b7d44a50a9c

449d555969bfd7befe906877abab098c6e63a0e8

/1757/CH6/EX6.38/EX6_38.sce

205a58f022b7ed0ca18bac2e0c2fdc7bd481f2be

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

459

sce

EX6_38.sce

//Example6_38 // Design high sensitivity current to voltage converter clc; clear; close; R1 = 5*10^3 ; is = 1 ; KR = 0.01/10^9 ; // V / nA // the output voltage of high sensitivity current to voltage converter Vo =-KR*is ; KR = 10*10^6 ; R = 1*10^6 ; //we assume then K = 10 ; //1 + (R2/R1)+(R2/R) = 10 ; // solving above equation we get R2 = 9*((5*10^6)/(10^3+5)) ; disp ('The value of resistance R2 is = '+string(R2)+ ' ohm');

7c96250b1f8408cb125fdc382bd9f7df3c646581

449d555969bfd7befe906877abab098c6e63a0e8

/443/CH20/EX20.3/20_3.sce

3f3bca9c8846cf919294adec7af19e37ad330c23

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

650

sce

20_3.sce

pathname=get_absolute_file_path('20_3.sce') filename=pathname+filesep()+'20_3_data.sci' exec(filename) //Question 20.3 //hydrogen ratio h=(26*1)/(12*12) //Fuel to air ratio far=0.33*(1+h)*((CO2+CO)/N) //Mass flow of air ma=ff/(far*60) //Volume total (in m3/cycle) Vtot=(%pi/4*(d*d)*(2*l)*(cr/(cr-1))) //Scavanger density psc=(ep/(r*t)) //Theoretical mass flow tmf=psc*Vtot*s //Scavanger efficiency nsc=(ma/tmf) //Indicated mean effective pressure (in kN/m2) imep = (nsc*psc)*(cr/(cr-1))*(nith*far*CV) printf("\n\nRESULTS\n\n") printf("\nScavanger efficiency: %f\n",nsc) printf("\nIndicated mean effective pressure %f\n",imep)

4aca2994dcd70f1c7e57ef74d3dd6780e7db1439

449d555969bfd7befe906877abab098c6e63a0e8

/611/CH4/EX4.6/Chap4_Ex6_R1.sce

dac1b2f307317b66e1556eda3bb494b4ed7015fa

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

3,031

sce

Chap4_Ex6_R1.sce

// Y.V.C.Rao ,1997.Chemical Engineering Thermodynamics.Universities Press,Hyderabad,India. //Chapter-4,Example 6,Page 103 //Title:Work done and final temperature //================================================================================================================ clear clc //INPUT W=1;//weight of steam in kg in the piston cylinder assembly X=0.8;//quality of steam (no unit) T1=150;//initial temperature of steam in degree celsius I=5;//current passed in Amperes V=220;//voltage in volts across the resistor t=10;//time for which the current is passed in minutes P1=476;//pressure in kPa obatined from steam tables (corresponding to T1) vf=0.0010908;//specific volume of saturated liquid in m^3/kg obatined from steam tables (corresponding to T1) vg=0.3924;//specific volume of satuarted vapour in m^3/kg obatined from steam tables (corresponding to T1) hf=632.15;//specific enthalpy of saturated liquid in kJ/kg obtained from steam tables (corresponding to T1) hg=2745.4;//specific enthalpy of saturated vapour in kJ/kg obtained from steam tables (corresponding to T1) //CALCULATION V1=(X*vg)+((1-X)*vf);//calculation of specific volume of steam in m^3/kg h1=(X*hg)+((1-X)*hf);//calculation of specific enthalpy of steam in m^3/kg Ws=-V*I*t*60*10^-3;//calculation of electrical work done on the system in kJ h2=h1-Ws;//calculation of the specific enthalpy of steam in the final state in kJ/kg P2=0.476;//Pressure in MPa is held constant during the process T_int1=200;//Temperature in degree celsius obtained from steam tables at P2 taken for interpolation to find V2 and T2 corresponding to P2 T_int2=300;//Temperature in degree celsius obtained from steam tables at P2 taken for interpolation to find V2 and T2 corresponding to P2 V_int1=0.4512;//specific volume in m^3/kg at T_int1 from steam tables at P2 taken for interpolation to find V2 and T2 corresponding to P2 V_int2=0.5544;//specific volume in m^3/kg at T_int2 from steam tables at P2 taken for interpolation to find V2 and T2 corresponding to P2 h_int1=2856.37;//specific enthalpy in kJ/kg at T_int1 obtained from steam tables at P2 taken for interpolation to find V2 and T2 corresponding to P2 h_int2=3065.38;//specific enthalpy in kJ/kg at T_int2 obtained from steam tables at P2 taken for interpolation to find V2 and T2 corresponding to P2 V2=(((h2-h_int1)/(h_int2-h_int1))*(V_int2-V_int1))+V_int1;//specific volume of superheated steam in m^3/kg obtained by interpolation (corresponding to T2 and P2) //Temperature of superheated steam in degree celsius obtained by interpolation (corresponding to T2 and P2) T2=(((h2-h_int1)/(h_int2-h_int1))*(T_int2-T_int1))+T_int1; W=(P1*10^3*(V2-V1)*W)*10^-3;//calculation of work done by steam in kJ using Eq.(4.14) //OUTPUT mprintf('\n The work done by steam= %0.2f kJ \n',W); mprintf('\n The final temperature= %0.2f degree celsius\n',T2); //===============================================END OF PROGRAM===================================================

2d7505d93be30c993b145ae4ea2523c8de4ba44b

449d555969bfd7befe906877abab098c6e63a0e8

/3257/CH12/EX12.5/Ex12_5.sce

c33c10d690cbe3ee4abf57eb653874be13ac9be4

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

562

sce

Ex12_5.sce

// Heat generation in resistance spot welding clc I = 5500 // current in ampere R = 250 // resistance in micro ohm T = 0.15 // time in sec d = 6 // diameter in mm t = 3 // thickness in mm rho = 7850 // density in kg/m^3 E = 1400 // energy required per gram mass printf("\n Example 12.5") Heat = I^2*R*1e-6*T V = %pi/4*d^2*t m = V*rho*1e-6 E_tot = m*E H_r = Heat - E_tot H_per = H_r/Heat*100 printf("\n Amount of heat generated is %d J.", Heat) printf("\n Amount of heat in weld zone is %d J or %d%%.", H_r, H_per) // Answer in book is 196 J

b6d1ca53e49720388bbba35bfed6d0fddac4b182

449d555969bfd7befe906877abab098c6e63a0e8

/3876/CH9/EX9.7/Ex9_7.sce

c1d46499925c2d68d6fce8101a8882f100b31b61

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

195

sce

Ex9_7.sce

//Chapter 9 Ionic Equilibria and Buffer Action clc; clear; //Initialisation of Variables n= 1.31*10**-4 //mole T= 25 //C //CALCULATIONS N= 2*n Ksp= N**2*n //RESULTS mprintf("Ksp = %.1e",Ksp)

4db1d34c98ec44f561d4e7a1a8ed5dccadc92bdc

449d555969bfd7befe906877abab098c6e63a0e8

/1427/CH18/EX18.32/18_32.sce

e0d705d7869846a6fd7b7109000dcb14b129d414

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

526

sce

18_32.sce

//ques-18.32 //Calculating entropy change when pressure is kept constant and when volume is kept constant clc n=1;//moles of ideal gas Cv=12.471;//calorific volume (in J/K/mol) T1=300; T2=600;//temperature (in K) R=8.314;//in J/K/mol //Pressure is constant Cp=Cv+R;//calorific pressure (in J/K/mol) S_P=2.303*n*Cp*log10(T2/T1); //Volume is constant S_V=2.303*n*Cv*log10(T2/T1); printf("The entropy change when pressure is kept constant is %.3f J/K/mol and when volume is kept constant is %.3f J/K/mol.",S_P,S_V);

ac908fd035538067b932cd084178e0ad36ee0cdd

73d810db141d5005a954ab6b197fb1422ed545e0

/hdls/scripts/Nand.tst

f3a6402262d89097be2664746f0611b5d6e9debd

[]

no_license

vijayakanth89/nand2tetris

29cbe2c57873421a42f56942a7381cee141b760d

61744dfe03c42b67d490518b90a698e8ad78dbb9

refs/heads/master

2021-01-15T21:07:24.667756

2012-11-27T06:09:32

null

0

null

UTF-8

Scilab

false

194

tst

Nand.tst

load Nand.hdl, output-file Nand.out, output-list z; set a 0, set b 0, eval , output; set a 0, set b 1, eval, output; set a 1, set b 0, eval, output; set a 1, set b 1, eval, output;

972ee95511c9ca3a0f2a758e1a343e66586eb416

449d555969bfd7befe906877abab098c6e63a0e8

/2084/CH18/EX18.15w/18_15w.sce

0a9bb66ac2a77a9f47b2249c6334bb7f8893b50f

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

770

sce

18_15w.sce

//developed in windows XP operating system 32bit //platform Scilab 5.4.1 clc;clear; //example 18.15w //calculation of location of the image of an object placed at a distance from the spherical convex surface //given data u=-25; //object distance(in cm) R=20; //radius of curvature of the spherical convex surface(in cm) mu1=1; //refractive index of the medium in which object is kept mu2=1.5; //refractive index of the medium of spherical convex surface //calculation v=mu2/((mu2-mu1)/R+(mu1/u)) //formula for refraction at spherical surface if(v>0) disp(v,'image is formed on the right of the separating surface at a distance(in cm) of'); else disp(-v,'image is formed on the left of the separating surface at a distance(in cm) of'); end

d145aba857db3da42a929a6e095ccfc1bbf24c45

449d555969bfd7befe906877abab098c6e63a0e8

/3683/CH1/EX1.8/Ex1_8.sce

4d58db7462a5130ab454e1908b5ba8d71e3f60ef

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

788

sce

Ex1_8.sce

b=250//width, in mm D=500//overall depth, in mm Ast=4*.785*22^2//four 22 mm dia bars, in sq mm cover=25//in mm d=D-cover//effective depth, in mm l=5//effective span, in m sigma_cbc=5//in MPa sigma_st=190//in MPa m=18.66//modular ratio //to find critical depth of neutral axis Xc=d/(1+sigma_st/(m*sigma_cbc))//in mm //to find actual depth of neutral axis using b(x^2)/2=mAst(d-x), which becomes of the form px^2+qx+r=0 p=b/2 q=m*Ast r=-m*Ast*d x=(-q+sqrt(q^2-4*p*r))/(2*p)//in mm //as x>Xc, beam is over-reinforced Mr=b*sigma_cbc*x/2*(d-x/3)//in N-mm self_weight=25*(b/10^3)*(D/10^3)//in kN/m M=Mr/10^6-self_weight*l^2/8//moment of resistance available for external load, in kN-m W=4*M/l//in kN mprintf("The concentrated load the beam can support at centre=%f kN",W)

c6d9318d1bfd29110fa191b33bce0a328bf44181

449d555969bfd7befe906877abab098c6e63a0e8

/593/CH8/EX8.6/ex8_6.sce

a52e0362b24ef8431f66e0e392145f594b01a8e0

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

2,058

sce

ex8_6.sce

clear; //clc(); // Example 8.6 // Page: 178 printf("Example-8.6 Page no.-178\n\n"); //***Data***// P = 1.00;//[atm] assumed total vapor pressure // In psia unit P1 = 14.7;//[psia] // From the figure 8.12d ( page 176 ) in book, the mole fractions of water in all the three phases and temperature are known and given as x_1_water = 0.65; x_1_butanol = (1-x_1_water); x_2_water = 0.98; x_2_butanol = (1-x_2_water); y_water = 0.73; y_butanol = (1-y_water); T = 92;//[C] // At this temperature we have to estimate the vapor pressure of pure water and n-butanol with the help of Antoine equation // log10(p) = A - B/(T+C) // From Table A.2( page 418), the Antoine equation constants for water are A_w = 7.94917; B_w = 1657.462; C_w = 227.02; // and that for n-butanol are A_b = 7.838; B_b = 1558.190; C_b = 196.881; // Thus vapor pressure of water and n-butanol are respectively p_water = (14.7/760)*10^(A_w - B_w/(T+C_w)); p_butanol = (14.7/760)*10^(A_b - B_b/(T+C_b)); // fugacity of the water and n-butanol are given as // f_i = (y*Y*P)_i // Where Y is the gas phase activity coefficient and its value is 1.00 in ideal gas mixture, so f_water = (y_water*P); f_butanol = (y_butanol*P); // The fugacity will be same in both the phase 1 and 2 // Now, liquid-phase activity coefficients are given by // Y_i = (y_i*P)/(x_i*p_i) // so, Y_water_1 = (y_water*P1)/(x_1_water*p_water); Y_butanol_1 = (y_butanol*P1)/(x_1_butanol*p_butanol); // For phase 2 Y_water_2 = (y_water*P1)/(x_2_water*p_water); Y_butanol_2 = (y_butanol*P1)/(x_2_butanol*p_butanol); printf(" Four activity coefficients and fufacities are shown in the following table:\n\n"); printf("\t Phase \t x_water \t f_water(atm) \t Y_water \t x_butanol \t f_butanol(atm) \t Y_butanol\n\n"); printf(" \t 1 \t %f \t %f \t %f \t %f \t %f \t\t %f \n",x_1_water,f_water,Y_water_1,x_1_butanol,f_butanol,Y_butanol_1); printf(" \t 2 \t %f \t %f \t %0.2f \t\t %f \t %f \t\t %f ",x_2_water,f_water,Y_water_2,x_2_butanol,f_butanol,Y_butanol_2);

309fa36d49a7d9f9104b5c9b42d2fd77425f49b8

9cb37875b74a713c93c09fa50ccc70ac0f71ecdb

/GS/SCENARIO/SparkScenarioDemoChrisDexmart.sce

6b069c250b973221c30d941f43b52cecbda142d8

[]

no_license

jmainpri/move3d-assets

a5b621daaedaaf8784fed0da1e80d029c83f3983

939db49d17a14e052bb58324b70e6112803d3105

refs/heads/master

2021-01-16T17:48:56.669119

2016-02-16T14:04:09

20,237,987

1

0

null

UTF-8

Scilab

false

10,990

sce

SparkScenarioDemoChrisDexmart.sce

#************************************************************ # Scenario of grande_salle # # date : Thu Feb 10 16:21:29 2011 #************************************************************ p3d_sel_desc_name P3D_ENV grande_salle p3d_sel_desc_name P3D_ROBOT MOVING_BOX p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT LOTR_TAPE p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.686214 -4.821133 0.743606 0.377377 0.817115 -16.170211 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT WALLE_TAPE p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.675875 -4.200000 0.784553 2.514918 0.720456 7.271485 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT GREY_K7 p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT GREY_TAPE p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.940678 -4.25503 0.976093 -178.817676 -1.425606 167.776129 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT ACHILE_HUMAN1 p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 4.664451 -4.449941 0.425589 0.000000 0.000000 173.895487 0.000000 0.000000 0.000000 3.621467 -7.239529 0.000000 52.652709 -0.637665 36.385855 0.145466 0.000000 0.000000 0.000000 -90.004310 28.828222 -62.867468 0.002456 0.000000 0.000000 0.000000 0.000000 -106.889961 0.000000 114.089544 0.000000 -7.199583 0.000000 0.000000 -106.889961 0.000000 114.089544 0.000000 -7.199583 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT PR2_ROBOT p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_constraint p3d_lin_rel_dofs 1 14 1 13 2 1.000000 0.000000 0 p3d_constraint p3d_lin_rel_dofs 1 23 1 22 2 1.000000 0.000000 0 p3d_sel_desc_name P3D_ROBOT LOWTABLE p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT CHAIR1 p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT CHAIR2 p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT TRASHBIN p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.893593 -3.677913 0.000000 0.676112 3.971540 180.274972 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT SHELF p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT HRP2TABLE p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.790000 -4.470000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT SIMPLECHAIR p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT IKEA_SHELF p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.517663 -5.371697 0.000000 -0.634174 0.278820 114.578189 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT ACCESSKIT p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.888845 -4.836052 0.749806 0.843583 1.494351 177.276168 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT SPACENAVBOX p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.825299 -4.452245 0.915093 -178.934542 -0.249257 -175.751056 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT PINK_TRASHBIN p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 3.589786 -5.278956 0.828486 -3.641053 -1.372996 128.996745 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT VISBALL_INTERNAL p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_sel_desc_name P3D_ROBOT SAHandRight p3d_set_robot_steering_method Linear p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_constraint p3d_lin_rel_dofs 1 6 1 5 2 1.000000 0.000000 0 p3d_constraint p3d_lin_rel_dofs 1 10 1 9 2 1.000000 0.000000 0 p3d_constraint p3d_lin_rel_dofs 1 14 1 13 2 1.000000 0.000000 0 p3d_constraint p3d_lin_rel_dofs 1 18 1 17 2 1.000000 0.000000 0 p3d_sel_desc_name P3D_ROBOT JIDOKUKA_ROBOT p3d_set_robot_steering_method Multi-Localpath p3d_set_robot_radius 1.000000 p3d_set_robot_current 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 2.820519 -4.541189 0.000000 0.000000 0.000000 -0.467066 -49.988556 -29.982848 85.617377 34.678551 -9.054051 115.398956 5.397184 -35.687301 -11.790036 89.954374 -16.119078 -0.597288 15.473408 15.473408 13.623101 -2.336083 4.408776 4.408776 13.861109 -1.942677 2.867010 2.867010 3.451935 -1.213125 6.269651 6.269651 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_set_robot_goto 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000 p3d_constraint p3d_lin_rel_dofs 1 17 1 16 2 1.000000 0.000000 0 p3d_constraint p3d_lin_rel_dofs 1 21 1 20 2 1.000000 0.000000 0 p3d_constraint p3d_lin_rel_dofs 1 25 1 24 2 1.000000 0.000000 0 p3d_constraint p3d_lin_rel_dofs 1 29 1 28 2 1.000000 0.000000 0 p3d_constraint p3d_lwr_arm_ik 6 5 6 8 9 10 11 1 34 0 2 7 2 p3d_set_cntrt_Tatt 4 -0.438683 0.100912 0.892958 -0.246214 0.897586 0.001049 0.440839 -0.172975 0.043549 0.994895 -0.091037 0.029823 p3d_set_cntrt_Tatt2 4 1.000000 0.000000 0.000000 0.000000 0.000000 1.000000 0.000000 0.000000 0.000000 0.000000 1.000000 -0.105000 p3d_set_object_base_and_arm_constraints 34 1 0 1 4 p3d_set_arm_data 4 8 7 5 6 1 34 p3d_set_camera_pos 2.790519 -4.351189 1.000000 5.000000 -0.700000 0.700000 0.000000 0.000000 1.000000 0.000000

7a07c7677ee9f7fc3947aa0543b08734bfe76352

5d0ddbd6f42843ded4d5ba18966dc130725607d2

/c13.code/uintah/branches/pearls/src/orderAccuracy/test_config_files/Examples/rayGPU.tst

5f89b796ad0468ca536c11797807bfa4a0cf205c

[ "MIT" ]

permissive

alvarodlg/lotsofcoresbook2code

b93ad62e015d205e4f550028ceb54254023021ee

a2dbeb306fa29ae6663ae29b2c4c132608375cf0

refs/heads/master

2020-12-31T03:02:22.579614

2015-09-02T15:23:18

54,509,919

2

1

null

2016-03-22T21:27:56

null

UTF-8

Scilab

false

2,712

tst

rayGPU.tst

<start> <upsFile>RMCRT_test_1L.ups</upsFile> <gnuplot> <script>plotScript.gp</script>s <title>GPU::RMCRT order-of-accuracy \\n 1 timestep (41^3)</title> <ylabel>Error</ylabel> <xlabel># of Rays</xlabel> </gnuplot> <AllTests> <replace_lines> <max_Timesteps>1</max_Timesteps> <randomSeed> true </randomSeed> <resolution> [41,41,41] </resolution> </replace_lines> </AllTests> <Test> <Title>2</Title> <sus_cmd> sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0</postProcess_cmd> <x>2</x> <replace_lines> <nDivQRays> 2 </nDivQRays> </replace_lines> </Test> <Test> <Title>4</Title> <sus_cmd> sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0</postProcess_cmd> <x>4</x> <replace_lines> <nDivQRays> 4 </nDivQRays> </replace_lines> </Test> <Test> <Title>8</Title> <sus_cmd> sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0</postProcess_cmd> <x>8</x> <replace_lines> <nDivQRays> 8 </nDivQRays> </replace_lines> </Test> <Test> <Title>16</Title> <sus_cmd>sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0</postProcess_cmd> <x>16</x> <replace_lines> <nDivQRays> 16 </nDivQRays> </replace_lines> </Test> <Test> <Title>32</Title> <sus_cmd>sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0</postProcess_cmd> <x>32</x> <replace_lines> <nDivQRays> 32 </nDivQRays> </replace_lines> </Test> <Test> <Title>64</Title> <sus_cmd> sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0</postProcess_cmd> <x>64</x> <replace_lines> <nDivQRays> 64 </nDivQRays> </replace_lines> </Test> <Test> <Title>128</Title> <sus_cmd> sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0 -plot true</postProcess_cmd> <x>128</x> <replace_lines> <nDivQRays> 128 </nDivQRays> </replace_lines> </Test> <Test> <Title>256</Title> <sus_cmd> sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0 </postProcess_cmd> <x>256</x> <replace_lines> <nDivQRays> 256 </nDivQRays> </replace_lines> </Test> <Test> <Title>512</Title> <sus_cmd> sus -gpu -nthreads 2 </sus_cmd> <postProcess_cmd>RMCRT_wrapper -bm 1 -L 0 -plot true</postProcess_cmd> <x>512</x> <replace_lines> <nDivQRays> 512 </nDivQRays> </replace_lines> </Test> </start>

8d97536a4af5cdd95876a3478edb2c707f553c44

8217f7986187902617ad1bf89cb789618a90dd0a

/browsable_source/2.1.1/Unix/scilab-2.1.1/macros/util/msqrt.sci

7dd3d2db85cad461728eb6f6177aae1cfe9b6b12

[ "MIT", "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]

permissive

clg55/Scilab-Workbench

4ebc01d2daea5026ad07fbfc53e16d4b29179502

9f8fd29c7f2a98100fa9aed8b58f6768d24a1875

refs/heads/master

2023-05-31T04:06:22.931111

2022-09-13T14:41:51

258,270,193

0

1

null

UTF-8

Scilab

false

507

sci

msqrt.sci

function x=msqrt(a) // msqrt - computes the matrix square root. //%CALLING SEQUENCE // x=msqrt(a) //%PARAMETERS // a : square hermitian matrix // x : square hermitian matrix //%DESCRIPTION // This macro is called by the function sqrt to compute square matrix // square root. //! [m,n]=size(a) if m<>n then error(20,1),end if a<>a' then error('Non hermitian matrix'),end r=and(imag(a)==0) [u,s]=schur(a);s=diag(s) x=u*diag(sqrt(s))*u' if r then if s>=0 then x=real(x) end end //end

3ed7bec6f098dde26792e5ca52a97de30b6dd7ef

449d555969bfd7befe906877abab098c6e63a0e8

/3772/CH4/EX4.11/Ex4_11.sce

2857af64fa44e5fd9ff0dbcda14317797c43ecb5

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

1,459

sce

Ex4_11.sce

// Problem no 4.4.11,Page No.101 clc;clear; close; F_C=5 //KN //Force at C w=2 //KNm //u.d.l on beam L_BC=3 //m //Length of BC L_AB=6 //m //Length of AB L=9 //m //Length of Beam //Calculations //Let R_A & R_B be the reactions at A & B //R_A+R_B=23 //Taking Moment at A //M_A=0=F_C*L-R_B*L_AB+w*L**2*2**-1 R_B=-(-F_C*L-w*L**2*2**-1)*L_AB**-1 R_A=23-R_B //Shear Force Calculations //Shear Force at C V_C1=0 V_C2=-F_C //Shear Force at B V_B=V_C2-w*L_BC**2*2**-1 //Shear Force at A V_A=F_C*L+R_B*L_AB-w*L**2*2**-1 //Pt of contraflexure //Let D be the pt And L_AD=x //V_D=0=R_A+w*L_AD L_AD=R_A*w**-1 x=L_AD //Bending Moment Calculations //Bending Moment at C M_C=0 //Bending Moment at B M_B=-F_C*L_BC-w*L_BC**2*2**-1 //Bending Moment at A M_A=-F_C*L-w*L**2*2**-1+R_B*L_AB //Bending Moment at D L_DC=L-L_AD L_DB=L_DC-L_BC M_D=-R_A*L_AD+w*L_AD**2*2**-1 //Result printf("The Shear Force and Bending Moment Diagrams are the results") //Plotting the Shear Force Diagram subplot(2,1,1) X1=[0,L_BC,L_BC+L_AB,L_BC+L_AB] Y1=[V_C2,V_B,V_A,0] Z1=[0,0,0,0] plot(X1,Y1,X1,Z1) xlabel("Length x in m") ylabel("Shear Force in kN") title("the Shear Force Diagram") //Plotting the Bending Moment Diagram subplot(2,1,2) X2=[0,L_BC,L_BC+L_DB,L_BC+L_AB] Y2=[M_C,M_B,M_D,M_A] Z2=[0,0,0,0] plot(X2,Y2,X2,Z2) xlabel("Length in m") ylabel("Bending Moment in kN.m") title("the Bending Moment Diagram") //The Bending moment in book is incorrect

6f334425399d704800a447e5596dc113569dce71

449d555969bfd7befe906877abab098c6e63a0e8

/2258/CH7/EX7.11/7_11.sce

5600b38ae1a3f02af7798364b7cd3d4724fc0330

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

426

sce

7_11.sce

clc(); clear; // To calculate the conductivity Eg=1.1; //energy gap in eV m=9.109*10^-31; k=1.38*10^-23; T=300; e=1.6*10^-19; h=6.626*10^-34; mew_e=0.48; //electron mobility mew_h=0.013; //hole mobility C=2*(2*%pi*m*k/(h^2))^(3/2); X=2*k*T/e; Y=-Eg/X; A=exp(Y); ni=C*(T^(3/2))*A; sigma=ni*e*(mew_e+mew_h); printf("conductivity in ohm-1 m-1 is"); disp(sigma); //answer given in the book is wrong

872c39128b054b13e2437255bccfdefc1e76589f

449d555969bfd7befe906877abab098c6e63a0e8

/1682/CH11/EX11.2/Exa11_2.sce

50ebc789a564e7930fbbe35786850aa68575e6a9

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

1,222

sce

Exa11_2.sce

//Exa 11.2 clc; clear; close; disp("The method of finding the economic life of the machine witha discounting factor of 20% at zero inflation rate is summarized in table below. From the table it is clear that total annual cost is minimum if the machine is used for 14 years. Hence the economic life of the machine is 14 years."); disp("End of year Op_cost Main_cost Op+Main P/F,i,n PW Cummulative Salvage PW_S TPW A/P,i,n AEM"); i=20;//in per year Cum=0;//initialising Op_cost=40000;//in RS. Main_cost=60000;//in Rs. OpMain=Op_cost+Main_cost;//in Rs. S=400000;//in Rs. for n=1:15 PF=1/((1+i/100)^n); PW=OpMain*PF;//in Rs. Cum=Cum+PW PW_S=PF*S;//in RS. TPW=500000+Cum-PW_S;//in Rs. AP=((i/100)*(1+i/100)^n)/(((1+i/100)^n)-1); AEM=TPW*AP;//in RS disp(" "+string(n)+" "+string(Op_cost)+" "+string(Main_cost)+" "+string(OpMain)+" "+string(PF)+" "+string(PW)+" "+string(Cum)+" "+string(S)+" "+string(PW_S)+" "+string(TPW)+" "+string(AP)+" "+string(AEM)); Op_cost=Op_cost+5000;//in Rs. Main_cost=Main_cost+6000;//in Rs. S=S-50000;//in Rs. end

8190a3f7639044d357e472311d72682a6a939411

449d555969bfd7befe906877abab098c6e63a0e8

/1859/CH7/EX7.20/exa_7_20.sce

c05fb36644047663ef3a10c5f917250dda0ed9b3

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

374

sce

exa_7_20.sce

// Exa 7.20 clc; clear; close; // Given data R2= 1000;//in ohm R3= 10000;// in ohm R4= 2000;//in ohm C4= 1*10^-6;// in F omega= 3000;// radians/sec L1= R2*R3*C4/(1+(omega*C4*R4)^2);// in H disp(L1,"Equivalent inductance of the network in H") R1= R2*R3*R4*omega^2*C4^2/(1+(omega*C4*R4)^2);// in ohm disp(R1*10^-3,"Equivalent resistance of the network in kohm")

69305f5030241a9f1daff4131b078996cb3ca4b5

449d555969bfd7befe906877abab098c6e63a0e8

/509/CH7/EX7.3/7_3.sci

67ba83091cdd7d5381010e5f0f0a9e7cc0e9d1f3

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

783

sci

7_3.sci

//Chapter 7 Example 3// clc clear // useful energy=e1,energy in terms of joules=e// e1=190;// in MeV// e=e1*10^6*1.6*10^-19; printf("\n Energy in terms of joules = %.15f J\n",e); // number of fisions required to produce one joule=n// n=1/e; printf("\n No of fissions required = %.3f \n",n); // number of nuclei burnt during 1 hr per MW of power=n1,percent of neutrons absorbed=p // p=80;// in percent// n1=10^6*n*3600/(p/100); printf("\n Number of nuclei burnt during 1hr per MW of power = %.3f absorption/hr \n",n1); // Mass of U-235 consumed to produce 1MW of power=m,Avagadro number=A// A=6.023*10^23; m=235;// Atomic mass of uranium// m=n1*m/A;// this is for 1MW// m1=m*100// for 100MW// printf("\n Fuel Consumption to produce 100MW = %.4f g/hr\n",m1);

86c3df3fbd3826fdb297d2fa29414475d7acc028

449d555969bfd7befe906877abab098c6e63a0e8

/668/CH4/EX4.3/eg4_3.sce

181835330b042c0e13d4cdf498552b8f4a2922f0

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

795

sce

eg4_3.sce

n = 10^17; p = 10^17; Tn = 10^-7; Tp = 10^-7; Dn = 30; Dp = 10; A = 10^-4; t = 10^-8; V1 = 0.5; V2 = 0.6; E1 = 6.94 * 10^4; E2 = 5.74 * 10^4; np = 2.25*10^3; pn = 2.25*10^3; Ln = 17.32*10^-4; Lp = 10*10^-4; Vbi = 0.817; q = 1.6*10^-19; I0 = q*A*(Dp*pn/Lp + Dn*np/Ln); disp(I0,"prefactor in the ideal diode equation = ") Igr01 = q*ni*A*%pi*kT/(2*t*E1); Igr02 = q*ni*A*%pi*kT/(2*t*E2); disp(Igr01,"prefactor to the recombination-generation current at 0.5V = ") disp(Igr02,"prefactor to the recombination-generation current at 0.6V") I1 = I0*exp(V1/kT)+Igr01*exp(0.5*V1/kT); disp(I1,"Current at 0.5 V = ") I2 = I0*exp(V2/kT)+Igr02*exp(0.5*V2/kT); disp(I2,"Current at 0.6 V = ") n = (log(I2/I1)*kT/(V2-V1))^-1; disp(n,"ideality factor of the diode in the given range =")

73315cecf0253a56c24f5cd192676d0b6635ee30

449d555969bfd7befe906877abab098c6e63a0e8

/2621/CH4/EX4.7/Ex4_7.sce

266f320962c156bec34617a63b7afaa9e3f65332

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

519

sce

Ex4_7.sce

// Example 4.7 clc; clear; close; format('v',6); // Given data Vin= 10;// in V R= 2.2;// in kΩ R= R*10^3;// in kΩ Ad= 10^5;// differential voltage gain C=1;// in µF C= C*10^-6;// in F T= 1;// in ms T= T*10^-3;// in s I= Vin/R;// in mA V= I*T/C;// output voltage at the end of pulse in mV V= V*10^-3;// in V disp(V,"The output voltage at the end of the pulse in volts is : ") RC_desh= R*C*Ad;// closed-loop time constant in sec. disp(RC_desh,"The closed-loop time constant in seconds : ")

a145796b43921a76408e7448501217720415991a

449d555969bfd7befe906877abab098c6e63a0e8

/1382/CH2/EX2.41/EX_2_41.SCE

bc200ddc954fd6eee8a81a65c98482191403fe76

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

465

sce

EX_2_41.SCE

// Example 2.39.b: Re , S clc; clear; close; Vcc=12;// Colector voltage in volts Beta=50; Vce=2.5;// Collector to emitter voltage in volts Vbe=0.7;// Base to emitter voltage in volts Re= 2.57;// Emitter resistance in killo ohms Rc=4.2;// Collector resistance in killo ohms Ic=14/(Rc+(1+(1/Beta)*Re)); Ib= (6-Vbe-Ic*Re)/Re; DeltaIb= -1;// Change in base Current S= (1+Beta)/(1+Beta); disp(Re,"Resistance in killo ohms") disp(S,"Stability Fcator is")

d7802e9f48f6f9ec88cc9c627bacbebcf7c27846

1bb72df9a084fe4f8c0ec39f778282eb52750801

/test/G14.prev.tst

c3fecb00ed46523f7c9e1b8bf6515d946a612557

[ "Apache-2.0", "LicenseRef-scancode-unknown-license-reference" ]

permissive

gfis/ramath

498adfc7a6d353d4775b33020fdf992628e3fbff

b09b48639ddd4709ffb1c729e33f6a4b9ef676b5

refs/heads/master

2023-08-17T00:10:37.092379

2023-08-04T07:48:00

30,116,803

2

0

null

UTF-8

Scilab

false

2,681

tst

G14.prev.tst

Input: - x^3 + y x^2*y - y^2 mdiv s = - x^2*y + x^3*y: (lts: + x^3*y) / (ltf[0]: + y) = (quot: + x^3), rest 0 mdiv s = x^6 - x^2*y: (lts: - x^2*y) / (ltf[0]: + y) = (quot: - x^2), rest 0 mdiv s = - x^5 + x^6: (lts: + x^6) / (ltf[0]: + y) = (quot: null), rest 0 mdiv s = - x^5 + x^6: (lts: + x^6) / (ltf[1]: - y^2) = (quot: null), rest 0 multipleDivide: - x^2*y + x^3*y = + ( - x^2 + x^3) * ( - x^3 + y) + [Rest = - x^5 + x^6] adding [2] = - x^5 + x^6 mdiv s = - x^2*y + x^3*y: (lts: + x^3*y) / (ltf[0]: + y) = (quot: + x^3), rest 0 mdiv s = x^6 - x^2*y: (lts: - x^2*y) / (ltf[0]: + y) = (quot: - x^2), rest 0 mdiv s = - x^5 + x^6: (lts: + x^6) / (ltf[0]: + y) = (quot: null), rest 0 mdiv s = - x^5 + x^6: (lts: + x^6) / (ltf[1]: - y^2) = (quot: null), rest 0 mdiv s = - x^5 + x^6: (lts: + x^6) / (ltf[2]: + x^6) = (quot: + 1), rest 0 multipleDivide: - x^2*y + x^3*y = + ( - x^2 + x^3) * ( - x^3 + y) + (1) * ( - x^5 + x^6) + [Rest = 0] mdiv s = - x^9 + x^5*y: (lts: + x^5*y) / (ltf[0]: + y) = (quot: + x^5), rest 0 mdiv s = x^8 - x^9: (lts: - x^9) / (ltf[0]: + y) = (quot: null), rest 0 mdiv s = x^8 - x^9: (lts: - x^9) / (ltf[1]: - y^2) = (quot: null), rest 0 mdiv s = x^8 - x^9: (lts: - x^9) / (ltf[2]: + x^6) = (quot: - x^3), rest 0 multipleDivide: - x^9 + x^5*y = + (x^5) * ( - x^3 + y) + ( - x^3) * ( - x^5 + x^6) + [Rest = 0] mdiv s = x^2*y - x^3*y: (lts: - x^3*y) / (ltf[0]: + y) = (quot: - x^3), rest 0 mdiv s = - x^6 + x^2*y: (lts: + x^2*y) / (ltf[0]: + y) = (quot: + x^2), rest 0 mdiv s = x^5 - x^6: (lts: - x^6) / (ltf[0]: + y) = (quot: null), rest 0 mdiv s = x^5 - x^6: (lts: - x^6) / (ltf[1]: - y^2) = (quot: null), rest 0 mdiv s = x^5 - x^6: (lts: - x^6) / (ltf[2]: + x^6) = (quot: - 1), rest 0 multipleDivide: x^2*y - x^3*y = + (x^2 - x^3) * ( - x^3 + y) + ( - 1) * ( - x^5 + x^6) + [Rest = 0] mdiv s = x^8*y - x^5*y^2: (lts: - x^5*y^2) / (ltf[0]: + y) = (quot: - x^5*y), rest 0 multipleDivide: x^8*y - x^5*y^2 = + ( - x^5*y) * ( - x^3 + y) + [Rest = 0] mdiv s = x^9 - x^5*y: (lts: - x^5*y) / (ltf[0]: + y) = (quot: - x^5), rest 0 mdiv s = - x^8 + x^9: (lts: + x^9) / (ltf[0]: + y) = (quot: null), rest 0 mdiv s = - x^8 + x^9: (lts: + x^9) / (ltf[1]: - y^2) = (quot: null), rest 0 mdiv s = - x^8 + x^9: (lts: + x^9) / (ltf[2]: + x^6) = (quot: + x^3), rest 0 multipleDivide: x^9 - x^5*y = + ( - x^5) * ( - x^3 + y) + (x^3) * ( - x^5 + x^6) + [Rest = 0] mdiv s = - x^8*y + x^5*y^2: (lts: + x^5*y^2) / (ltf[0]: + y) = (quot: + x^5*y), rest 0 multipleDivide: - x^8*y + x^5*y^2 = + (x^5*y) * ( - x^3 + y) + [Rest = 0] Groebner Basis: GB: - x^3 + y GB: x^2*y - y^2 GB: - x^5 + x^6

0099a7dc15e0924666eac81f4a67a6f447b5359b

449d555969bfd7befe906877abab098c6e63a0e8

/3886/CH5/EX5.1/5_1.sce

969095d3d32c3ea71e5ec05dcbf29762870dd23b

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

436

sce

5_1.sce

//Value of P //Refer fig. 5.5 (a),(b)&(c) //(a) when P is Horizontal Phor //Consider equilibrium //block A N1=1000 //N F1=0.25*N1 //N T=F1 //N //Block B N2=N1+2000 //N F2=3000/3 //mu*N2 N Phor=F1+F2 //N //(b) when P is inclined (Pinc) //Considering equilibrium of block B //Using law of friction //Pinc*cosd(30)-F1-F2=0 Pinc=1250/(cosd(30)+(0.5/3)) //N printf("\nPhor=%0.2d N\nPinc=%0.2d N",Phor,Pinc)

23d563f9636242f93d4e2b6c61ec71477e5edee6

28593ce1b2f815768f8f91a59f4123b52b1f746f

/common/HR.TA.CommonLibrary/HR.TA.Talent/WireContracts/ContractGenerator.tst

806bfdfc410e6ea2f013095917840c214fd6eec8

[ "LicenseRef-scancode-generic-cla", "MIT" ]

permissive

QPC-database/msrecruit-scheduling-engine

493640cf3d4450948ec44d45b77cfb40f259804b

72336f36cb3c0f68b978794a7127cd3e990b7b15

refs/heads/main

2023-06-19T00:30:31.156716

2021-06-11T11:33:45

383,309,033

1

0

MIT

2021-07-06T01:49:39

null

UTF-8

Scilab

false

5,553

tst

ContractGenerator.tst

//--------------------------------------------------------------------------- // <copyright company="Microsoft Corporation"> // Copyright (c) Microsoft Corporation. All rights reserved. // </copyright> // This file is auto-generated by the HR.TA.Talent/TalentContracts/ContractGenerator.tst script. //--------------------------------------------------------------------------- ${ Template(Settings settings) { settings.OutputFilenameFactory = file => { return $"{file.Name.Replace(".g.cs", ".ts").Replace(".cs", ".ts")}"; }; } string GetClassName(Class c) { return c.Name; } string GetEnumName(Enum e) { return e.Name; } string GetTypeName(Type t) { if (t.IsEnumerable && t.TypeArguments?.Count == 1 && GetTypeName(t.TypeArguments[0]) != t.TypeArguments[0]) { return GetTypeName(t.TypeArguments[0]) + "[]"; } else if (t.IsGeneric && !t.TypeArguments.All(a => a == null || GetTypeName(a) == a.Name)) { return t.OriginalName + "<" + string.Join(", ", t.TypeArguments.Select(GetTypeName)) + ">"; } else if (t.Namespace == "Microsoft.CommonDataService.CommonEntitySets") { return "CommonEntity" + t; } else if (t.Namespace == "Microsoft.CommonDataService" && t == "CountryCode") { return "CommonEntity" + t; } else if (t.Namespace == "Microsoft.CommonDataService" && t.Name == "LargeText") { return "string"; } else if(t.Name =="Json") { return "string"; } return t; } string GetPropertyType(string typeName) { Console.WriteLine(typeName); switch(typeName) { case "IFormFile": return "File"; case "IFormFile[]": return "File[]"; default: return typeName; } } string PrintPropertyWithType(Property p) { string typeName = GetTypeName(p.Type); string attributeValue = p.Attributes?.FirstOrDefault(a => a.Name == "DataMember")?.Value; string attributeValueNameAssignment = attributeValue?.Split(',')?.Select(v => v.Trim())?.FirstOrDefault(v => v.StartsWith("Name = ")); string propertyName = attributeValueNameAssignment?.Substring(8, attributeValueNameAssignment.Length - 9); if (propertyName == null) { propertyName = p.Name; } if (p.Attributes.Any(attribute => attribute.Name == "RelationalField" || attribute.Value.Contains("IsRequired = false"))) { return propertyName + "?: " + GetPropertyType(typeName); } else { return propertyName + ": " + GetPropertyType(typeName); } } }$Classes(c => c.Attributes.Any(a => a.Name == "DataContract") && c.BaseClass == null && c.Name != "AdditionalMetadataValue" && c.Name != "OpenTypeExtension" && c.Name != "CalendarEvent" && c.Name != "CalendarEvents" && c.Name != "AttachmentResponse" && (c.Namespace == "HR.TA.Common.TalentAttract.Contract" || c.Namespace == "HR.TA.Talent.TalentContracts.TeamsIntegration" || c.Namespace == "HR.TA.ScheduleService.Contracts.V1" || c.Namespace == "HR.TA.Talent.TalentContracts.ScheduleService" || c.Namespace == "HR.TA.Talent.TalentContracts.ScheduleService.Conferencing" || c.Namespace == "HR.TA.Talent.TalentContracts.Flighting" || c.Namespace == "HR.TA.Common.Contracts" || c.Namespace == "HR.TA.Talent.TalentContracts.TalentMatch"|| c.Namespace == "HR.TA.Common.TalentEntities.Common" || (c.Namespace == "HR.TA.Common.SchedulingService.Contracts" && c.Name !="EmailTemplate") || (c.Namespace == "HR.TA.Common.Provisioning.Entities.FalconEntities.Attract" && c.Name == "JobApplicationParticipant") || c.Namespace == "HR.TA.Talent.EnumSetModel.SchedulingService" || c.Namespace == "HR.TA.Common.EnvironmentSettings.Contracts" || c.Namespace == "HR.TA.Common.Email.Contracts" || c.Namespace == "HR.TA.Common.Web.Contracts" || c.Namespace == "HR.TA.Talent.TalentContracts.InterviewService" || c.Namespace == "HR.TA.Talent.TalentContracts.QueryStringParameters") || c.Name == "OfferUser" || (c.name == "JobPost" || c.name == "Source" || c.name == "CurrencyCode" || c.name == "JobOfferStatusReason" || c.name == "FlightingContextType" ))[ export interface $GetClassName {$Properties(p => p.Attributes.Any(a => a.Name != "IgnoreDataMember"))[ $PrintPropertyWithType;] } ]$Classes(c => c.Attributes.Any(a => a.Name == "DataContract") && c.BaseClass != null && (c.Namespace == "HR.TA.Common.TalentAttract.Contract" || c.Namespace == "HR.TA.ScheduleService.Contracts.V1" || c.Namespace == "HR.TA.Common.Contracts" || c.Namespace == "HR.TA.Common.Web.Contracts" || c.Namespace == "HR.TA.Talent.TalentContracts.Flighting" || c.Namespace == "HR.TA.Talent.TalentContracts.ScheduleService" || c.Namespace == "HR.TA.Talent.TalentContracts.InterviewService" || c.Namespace == "HR.TA.Talent.TalentContracts.QueryStringParameters") && c.Name != "ThirdPartyJobPost")[ export interface $GetClassName extends $BaseClass {$Properties[ $PrintPropertyWithType;] } ]$Enums(e => e.Attributes.Any(attr => attr.Name == "EnumSet" || attr.Name == "DataContract") )[ export enum $GetEnumName {$Values[ $Name = $Value,] } ]

543b489048ae490c066abc47333620c5cdead1d1

e58ee115056e7db70e0a5c071ab5146400e8e539

/seguidor_referencia_continuo.sce

468e0ec65d04b93e1052fc71fa481f1465a56638

[ "MIT" ]

permissive

mofreitas/algoritmosSistemasControle

7236f5a4020f242a8db69e641c817ad99a8638ef

fb666ab6708554caa8259e1f505f35225d1046c8

refs/heads/master

2020-07-07T20:30:51.712572

2019-08-20T23:47:44

203,469,282

0

null

UTF-8

Scilab

false

1,154

sce

seguidor_referencia_continuo.sce

function[] = sr_c(a, b, c, polos) Aa = zeros(size(c, 'r')+size(a, 'r'), size(c,'c')+1); Aa(1, 2:$) = c; Aa(2:$, 2:$) = a; Ba = [0; b] printf("Matriz Aa -------------------------- \n"); disp(Aa); printf("\nMatriz Ba -------------------------- \n"); disp(Ba); U = zeros(length(Ba), length(Ba)); for i=1:length(Ba), U(:, i) = (Aa^(i-1))*Ba; end printf("\nMatrix U ------------------------ \n"); disp(U); if(rank(U) == length(Ba)) then printf("\nRank cheio \n"); else halt("\nNão tem Rank cheio \n"); end printf("\nPolinomio delta -------------------- \n"); delta = poly(polos, 'A'); disp(delta); qc = zeros(size(Aa, 'r'), size(Aa, 'c')); for i=0:size(Aa, 'r'), qc = qc + (Aa^i)*coeff(delta, i); end printf("\nqc(Aa) ------------------------- \n"); disp(qc); printf("\nU inversa ---------------------- \n"); disp(inv(U)); m = zeros(1, size(qc, 'c')); m($) = 1; ka = -m*inv(U)*qc; printf("\nKa ------------------ \n"); disp(ka); endfunction

bb4df9fedd01481bfd31cac9561ca49c3a1f055e

449d555969bfd7befe906877abab098c6e63a0e8

/551/CH4/EX4.40/40.sce

4690e366e54360ae42011602b51c8f7e3ab5b186

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

215

sce

40.sce

clc p1=6.87; //bar C1=50; //m/s p2=1.37; //bar C2=500; //m/s disp("From steam table corresponding to p1") h1=2850; //kJ/kg h2=h1 - (C2^2-C1^2)/2/1000; disp("Final enthalpy of steam = ") disp(h2) disp("kJ")

273b19079fe42c5bfdbb6c9ca2a4653d8b40068d

417f69e36190edf7e19a030d2bb6aa4f15bb390c

/SMTTests/tests/ok_as.tst

480bd8612f74f535df0066ffe6b1c455784384ed

[]

no_license

IETS3/jSMTLIB

aeaa7ad19be88117c7454d807a944e8581184a66

c724ac63056101bfeeb39cc3f366c8719aa23f7b

refs/heads/master

2020-12-24T12:41:17.664907

2019-01-04T10:47:43

76,446,229

1

0

null

2016-12-14T09:46:41

null

UTF-8

Scilab

false

78

tst

ok_as.tst

; tests resolution of as identifiers ; actually - there are no legal uses yet

eb3a11ce62c9da107d3ff313f967a6b87c1b4c5f

449d555969bfd7befe906877abab098c6e63a0e8

/680/CH2/EX2.11/2_11.sce

9c28db56c2e156a0ad20abd307335aaa4cf994a8

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

415

sce

2_11.sce

//Problem 2.11: //initializing the variables: w= 5000; // in gal C = 50000; // in gal Cs = 45000; // in gal pHmin = 6; pHn = 7; //calculation: CHn = 10^(-1*pHn) CH = 10^(-1*pHmin) X = (C/w)*[CH - Cs*CHn/C] pH = -1*log10(X) printf("\n\nResult\n\n") printf("\n the pH of the most acidic waste shipment is %.2f \n",pH) printf("\n This is the final correct answer, final answer in book is wrong\n")

3947f53b0a4683b5a915677f5d2f22745f8d7543

f8bb2d5287f73944d0ae4a8ddb85a18b420ce288

/Scilab/machine-sliding-mode/jiyukaisou/疑似逆行列.sce

dc1671b42ea12186a730ae007d005f23342aa558

[]

no_license

nishizumi-lab/sample

1a2eb3baf0139e9db99b0c515ac618eb2ed65ad2

fcdf07eb6d5c9ad9c6f5ea539046c334afffe8d2

refs/heads/master

2023-08-22T15:52:04.998574

2023-08-20T04:09:08

248,222,555

8

20

null

2023-02-02T09:03:50

2020-03-18T12:14:34

C

UTF-8

Scilab

false

156

sce

疑似逆行列.sce

A=[2 0 3;0 0 1]; GA=A'*inv(A*A'); Ans=A*GA; disp(A) disp(GA) disp(Ans) //A=[2 0;1 0;1 1]; //GA=inv(A'*A)*A'; //Ans=A*GA; //disp(A) //disp(GA) //disp(Ans)

f6b313cbdb7e851e8ba8c3f770dd12b5fe5ededc

8217f7986187902617ad1bf89cb789618a90dd0a

/browsable_source/2.1.1/Unix/scilab-2.1.1/macros/arma/exar1.sci

ad59391c359eff5d3ca7d54f4873e180c953822c

[ "MIT", "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]

permissive

clg55/Scilab-Workbench

4ebc01d2daea5026ad07fbfc53e16d4b29179502

9f8fd29c7f2a98100fa9aed8b58f6768d24a1875

refs/heads/master

2023-05-31T04:06:22.931111

2022-09-13T14:41:51

258,270,193

0

1

null

UTF-8

Scilab

false

858

sci

exar1.sci

//<z,zd,u,ar>=exar1() //<z,zd,u,ar>=exar1() // // Exemple de processus ARMAX ( K.J. Astrom) // On simule le processus armax caract\'eris\'e par // a=<1,-2.851,2.717,-0.865> // b=<0,1,1,1> // d=<1,0.7,0.2> // exite par un PRBS // z : version sans bruit (d=0) // zd : version bruite // Et on l'identifie avec armax ( comme le bruit est colore // armax doit donner des estimateurs biaises) // Sortie : // z,zd,u,ar, ar est une liste decrivant le processus arma // voir arma et armap //! a=[1,-2.851,2.717,-0.865] b=[0,1,1,1] d=[1,0.7,0.2] ar=armac(a,b,d,1,1,1); write(%io(2),"Simulation du processus ARMAX :"); armap(ar); u=-prbs_a(300,1,int([2.5,5,10,17.5,20,22,27,35]*100/12)); zd=narsimul(a,b,d,1.0,u); z=narsimul(a,b,d,0.0,u); write(%io(2),"Identification ARX (moindre carres):"); [la,lb,sig,resid]=armax(3,3,zd,u,1,1); //end

c6e32324f8ada04ebf8715032858fef06aaafa78

449d555969bfd7befe906877abab098c6e63a0e8

/3472/CH18/EX18.9/Example18_9.sce

4f8584bb6765c3b09793abeb41412c7f4e8bf973

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

2,525

sce

Example18_9.sce

// A Texbook on POWER SYSTEM ENGINEERING // A.Chakrabarti, M.L.Soni, P.V.Gupta, U.S.Bhatnagar // DHANPAT RAI & Co. // SECOND EDITION // PART II : TRANSMISSION AND DISTRIBUTION // CHAPTER 11: LOAD FREQUENCY CONTROL AND LOAD SHARING OF POWER GENERATING SOURCES // EXAMPLE : 11.9 : // Page number 335-336 clear ; clc ; close ; // Clear the work space and console // Given data X = 2.80 // Combined reactance(ohm/phase) load_1 = 7000.0 // Consumer load at station A(kW) PF_1 = 0.9 // Lagging power factor V = 11000.0 // Voltage(V) load_2 = 10000.0 // Load supplied by station B(kW) PF_2 = 0.75 // Lagging power factor // Calculations V_ph = V/3**0.5 // Phase voltage(V) I_1 = load_1*10**3/(3**0.5*V*PF_1)*exp(%i*-acos(PF_1)) // Current at A due to local load(A) I_2 = load_2*10**3/(3**0.5*V*PF_2)*exp(%i*-acos(PF_2)) // Current at B due to local load(A) IA_X = 0.5*(load_1+load_2)*1000/(3**0.5*V) // Current(A) Y_1 = 220.443/V_ph // Solved manually referring textbook X_1 = (1-Y_1**2)**0.5 angle_1 = atand(Y_1/X_1) // Phasor lags by an angle(°) IA_Y = (6849.09119318-V_ph*X_1)/X // Current(A) Y_X = IA_Y/IA_X angle_2 = atand(Y_X) // Angle by which I_A lags behind V_A(°) PF_A = cosd(angle_2) // Power factor of station A angle_3 = acosd(PF_2)+angle_1 // Angle by which I_2 lags V_A(°) I_22 = load_2*10**3/(3**0.5*V*PF_2)*exp(%i*-angle_3*%pi/180) // Current(A) I = 78.7295821622-%i*(IA_Y-177.942225747) // Current(A) I_B = I_22-I // Current(A) angle_4 = abs(phasemag(I_B))-angle_1 // Angle by which I_B lags behind V_B(°) PF_B = cosd(angle_4) // Power factor of station B // Results disp("PART II - EXAMPLE : 11.9 : SOLUTION :-") printf("\nPower factor of station A = %.4f (lagging)", PF_A) printf("\nPower factor of station B = %.4f (lagging)", PF_B) printf("\nPhase angle between two bus bar voltages = %.f° (V_B lagging V_A)", angle_1)

fda53d59ccd2bcf8f06da3c1d63fa77d252007c7

449d555969bfd7befe906877abab098c6e63a0e8

/3363/CH13/EX13.3/Ex13_3.sce

6d9b1542483e69a136639db34ee3d792080cbd39

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

178

sce

Ex13_3.sce

//Example 13.3, page 483 clc m=9.11*10^-31//in kg h=6.63*10^-34//in j-s c=3*10^8//m/s ef=4.72*1.60*10^-19//in J pf=sqrt(2*m*ef) tf=pf/(m*c) printf("\n The angle is %e rad",tf)

6da8fb9ec879154ce80456b727c893d89ad5ae42

449d555969bfd7befe906877abab098c6e63a0e8

/2411/CH7/EX7.16/Ex7_16.sce

882fb61faed5a99abf746f117e3f2fc5926be9d7

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

765

sce

Ex7_16.sce

// Scilab Code Ex7.16: Page-383 (2008) clc; clear; M = 58.5 // Gram atomic mass of NaCl, kg/mole N = 6.023e+026; // Avogadro's number per kmol rho = 2.17e+003; // Density of NaCl, kg/metre-cube m = M/N; // Mass of each NaCl molecule, g V = m/rho; // Volume of each NaCl molecule, metre-cube d = (V/2)^(1/3)/1e-010; // Atomic apacing in the NaCl crystal, angstrom theta = 26; // Bragg's angle, degree n = 2; // Order of diffraction lambda = 2*d*sind(theta)/n; // Wavelength of X rays, m printf("\nThe grating spacing of rock salt = %4.2f angstrom", d); printf("\nThe wavelength of X rays = %4.2f angstrom", lambda); // Result // The grating spacing of rock salt = 2.82 angstrom // The wavelength of X rays = 1.24 angstrom

03fd0dc51147187817a91104636c4af1bc3a2344

8217f7986187902617ad1bf89cb789618a90dd0a

/source/2.5/tests/examples/diophant.man.tst

1c6dc2773939d88660ee4ab41a892f765846ab60

[ "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]

permissive

clg55/Scilab-Workbench

4ebc01d2daea5026ad07fbfc53e16d4b29179502

9f8fd29c7f2a98100fa9aed8b58f6768d24a1875

refs/heads/master

2023-05-31T04:06:22.931111

2022-09-13T14:41:51

258,270,193

0

1

null

UTF-8

Scilab

false

133

tst

diophant.man.tst

clear;lines(0); s=poly(0,'s');p1=(s+3)^2;p2=(1+s); x1=s;x2=(2+s); [x,err]=diophant([p1,p2],p1*x1+p2*x2); p1*x1+p2*x2-p1*x(1)-p2*x(2)

7075cefee7a4124ffad02db7e24902eab3641d95

449d555969bfd7befe906877abab098c6e63a0e8

/257/CH5/EX5.12/example_5_12.sce

f85438faaee7ec9a6a57b46554f57873dddf10e3

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

164

sce

example_5_12.sce

syms G1 G2 G3 G4 G5 G6 G7 G8 a= G8/(1+(G8*G6*G7)) //feedback b=a*G2*G5 c=b/(1+(b*G4*G6)) Y= G3*G1*c //series disp(Y,"C/R = ")

a6a38f7314c38e42f458dd9b87273568ba718978

449d555969bfd7befe906877abab098c6e63a0e8

/1397/CH4/EX4.6/4_6.sce

0638fa15f3a16282362dce8ce4c3ec9c809f4536

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

335

sce

4_6.sce

//clc(); clear; //To determine magnetic force and relative permeability of material I=3000; //magnetisation in amp/m B=0.005; //flux density in weber/m^2 mew0=(4*%pi*10^-7); //mew0 in H/m H=(B/mew0)-I; mewr=(I/H)+1; printf("magnetizing force is %f amp/m",H); printf("relative permeability is %f",mewr);

e517b12de76492c7b7a5fca6501c55100ce62cc3

449d555969bfd7befe906877abab098c6e63a0e8

/1208/CH9/EX9.3/Exa3.sce

f5ee125bed23b9e215cab833eda6f6a99ef5ae22

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

640

sce

Exa3.sce

//Exa3 clc; clear; close; //given data : SQ=100;//in Kgs actualoutput=240000;//in Kgs stdoutput=80;//in Kgs costofmaterial=346500;//in Rupees SQa=(SQ*actualoutput)/stdoutput;//SQa is SQ for actual output SP=1.20;//in Rupees per Kg AQ=315000;// in Kg AP=costofmaterial/AQ;//in Rupees per Kg //(i) MUV MUV=SP*(SQa-AQ);//in rupees //(ii) MPV MPV=AQ*(SP-AP);//in rupees //(iii) MCV MCV=(SQa*SP)-(AQ*AP);//in rupees disp(MUV,"MUV="); disp(MPV,"MPV="); disp(MCV,"MCV="); disp("Note : ") disp("Negative variances indicate adverse value "); disp("Positive variances indicate favourable value ")

8411beffe1e39ec90a5c5f72fed42f332d19970d

449d555969bfd7befe906877abab098c6e63a0e8

/2609/CH9/EX9.5/Ex9_5.sce

402ce6f66724fbe736d4866608473a85eb17cf1a

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

531

sce

Ex9_5.sce

//Ex 9.5 clc; clear; close; format('v',4); f0=1;//kHz(Cutoff frequency) f0dash=1.5;//kHz(Cutoff frequency) disp("Various design parameters are :-"); //For Butterworth filter fH=f0;//kHz fHdash=f0dash;//kHz K=f0/f0dash;//ratio R=3.2;//kohm Rdash=K*R;//kohm disp(Rdash,"Resistance Rdash(kohm)"); disp("Use Rdash=2.2 kohm"); format('v',5); C=0.05;//micro F//Chosen for the design disp(C,"Capacitance(micro F)"); format('v',4); fHdash=1/(2*%pi*Rdash*1000*C*10^-6)/1000;//kHz disp(fHdash,"Cutoff frequency(kHz)");

de7b2d5090b01e4af532f140ca06914cb1e022bb

449d555969bfd7befe906877abab098c6e63a0e8

/2096/CH2/EX2.20/EX_2_20.sce

548a8845dba8ff03f03c636f19b5ce85dc4dd305

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

403

sce

EX_2_20.sce

//Example 2.20//unknown resistance ,capacitance clc; clear; f=2;//frequency in kHz R1=2.8;//in killo ohms C1=4.8;//in micro farads R2=20;//in killo ohms R4=80;//in killo ohms R3=((R4/R2)*(R1*10^3+(1/((2*%pi*f*10^3)^2*(C1*10^-6)^2*R1*10^3))));// C3=(1/((2*%pi*f*10^3)^2*C1*10^-6*R1*10^3*R3));//capaciatnce disp(R3*10^-3,"unknown resistance in killo ohms") disp(C3*10^12,"CAPACITANCE IN PICO FARAD IS")

296471a889f2cc6df379cf9c29e7ff1197d6b0da

a8592d34f144b71794ebf30f1c2a1b5faf0b053c

/ODE/scilab/ode_hamming.sce

b13223306f3fe03cde202db821c21fc59e0af9fb

[]

no_license

f-fathurrahman/ffr-MetodeNumerik

ee9a6a7153b174b1ba3d714fe61ccbd1cb1dd327

e3a9da224c0fd5b32e671708e890018a3c4104c4

refs/heads/master

2023-07-19T22:29:38.810143

2023-07-07T10:02:34

107,272,110

2

null

UTF-8

Scilab

false

960

sce

ode_hamming.sce

function [t,y] = ode_hamming(f,tspan,y0,N,KC) // Hamming method to solve vector d.e. y’(t) = f(t,y(t)) // for tspan = [t0,tf] and with the initial value y0 and N time steps // using the modifier based on the error estimate depending on KC = 1/0 if ~exists("KC", "local") KC = 1 end if ~exists("N","local") N = 100 end if ~exists("tspan","local") y0 = 0 end y0 = y0(:)' h = (tspan(2) - tspan(1))/N tspan0 = tspan(1) + [0 3]*h [t,y] = ode_RK4(f,tspan0,y0,3) t = [t(1:3)' t(4):h:tspan(2)]' for k = 2:4 F(k-1,:) = f(t(k),y(k,:)) end p = y(4,:) c = y(4,:) h34 = h/3*4 KC11 = KC*112/121 KC91 = KC*9/121 h312 = 3*h*[-1 2 1] for k = 4:N p1 = y(k - 3,:) + h34*(2*(F(1,:) + F(3,:)) - F(2,:)) m1 = p1 + KC11*(c-p) c1 = (-y(k-2,:) + 9*y(k,:) + h312*[F(2:3,:); f(t(k + 1),m1)])/8 y(k+1,:) = c1 - KC91*(c1 - p1) p = p1 c = c1 F = [F(2:3,:); f(t(k+1),y(k+1,:))] end endfunction

95b8c8d54ef35ff80a3fca561acac8175cb205bc

449d555969bfd7befe906877abab098c6e63a0e8

/1883/CH5/EX5.3.9/Example5_9.sce

2d342504db524d86340c85d5edd24404acac9d87

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

1,099

sce

Example5_9.sce

//Chapter-5,Example5_3_9,pg 5-10 V=3000 //Potential difference wavelength=12.27/sqrt(V) //The de Broglie wavelength of an electron accelerated through a potential diff. of 'V' printf("\nThe de Broglie wavelength of an electron accelerated through a potential diff. of V is %.3f A.\n",wavelength) h=6.63*10^-34 //Plancks constant p=h/(wavelength*10^-10) //as the de Broglie wavelength of an electron is (wavelength=h/p) printf("\nThe momentum of an electron is\n") disp(p) printf("kg-meter/sec\n") wave_no=1/(wavelength*10^-10) //wave number printf("\nThe wave number = %.f/m\n",wave_no) d=2.04 //distance between planes n=1 //For first ordet reflection angle=asind(n*wavelength/(2*d)) //By Bragg's law '2dsin(angle)=n*wavelength' printf("\nThe Bragg angle = %.3f Degree\n",angle)

4c1d99a8b1d21ccc61d7b38486f81ce135c3ead5

127061b879bebda7ce03f6910c80d0702ad1a713

/bin/PIL_read_mat.sci

e2a914427e10fcb3e6b066a40a85e7c9e9f4effe

[]

no_license

pipidog/PiLib-Scilab

961df791bb59b9a16b3a32288f54316c6954f128

125ffa71b0752bfdcef922a0b898263e726db533

refs/heads/master

2021-01-18T20:30:43.364412

2017-08-17T00:58:50

100,546,695

0

1

null

UTF-8

Scilab

false

3,348

sci

PIL_read_mat.sci

// **** Purpose **** // This is a read function of the standard output format of my library // This format also consistent with my Fortran output format // **** Variables **** // [fid]: 1x1, integer // <= your file ID // [read_range]: 2x2, integer, default: read all data // <= specify the range you want to read,ex:[3,10;7,12] // [A]: NxM, integer, real or complex // => you read data // **** Version **** // 02/07/2014 First Built // 06/05/2014 auto read data type, no type input needed anymore // 06/07/2014 add sparse and string matrix (separated by '#') format // 04/26/2015 read row numbers // **** Comment **** // 1. illustration // Helpful to pass and receive data with Fortran. It makes Scilab and // Fortran well-integrated. function [A]=PIL_read_mat(fid,read_range) // determin starting point and size while meof(fid)==0 read_data=mgetl(fid,1); if length(grep(read_data,['PiLib Variable']))~=0 then mgetl(fid,1); mgetstr(6,fid); order=mfscanf(1,fid,'%4d'); mgetstr(8,fid); A_size(1)=mfscanf(1,fid,'%6d'); mgetstr(1,fid); A_size(2)=mfscanf(1,fid,'%6d'); mgetstr(8,fid); data_type=mfscanf(1,fid,'%s'); if data_type=='STRING' then mgetl(fid,2); else mgetl(fid,4); end break; end end [lhs,rhs]=argn(); if rhs==1 then read_range=[1,A_size(1);1,A_size(2)]; end r_size=read_range(1,2)-read_range(1,1)+1; c_size=read_range(2,2)-read_range(2,1)+1; tot_column=A_size(2); A=zeros(r_size,c_size); mgetl(fid,read_range(1,1)-1); select data_type case 'INTEGER' for n=1:r_size mfscanf(1,fid,'%6d'); mfscanf(read_range(2,1)-1,fid,'%d ') A(n,:)=(mfscanf(c_size,fid,'%d '))'; if read_range(2,2)< tot_column then mgetl(fid,1); end end case 'REAL' for n=1:r_size mfscanf(1,fid,'%6d'); mfscanf(read_range(2,1)-1,fid,'%f ') A(n,:)=(mfscanf(c_size,fid,'%f '))'; if read_range(2,2)< tot_column then mgetl(fid,1); end end A=A*10^(order); case 'COMPLEX' A=zeros(r_size,c_size); B=zeros(r_size,c_size*2); for n=1:r_size mfscanf(1,fid,'%6d'); mfscanf(2*(read_range(2,1)-1),fid,'%f ') B(n,:)=(mfscanf(2*c_size,fid,'%f '))'; if read_range(2,2)< tot_column then mgetl(fid,1); end end for n=1:c_size A(:,n)=B(:,2*n-1)+%i*B(:,2*n) end A=A*10^(order); case 'SPARSE' if rhs~=1 then disp('Warning: PIL_read_mat, sparse format cannot assign read range!'); end A=mfscanf(A_size(1),fid,'%f %f %f %f') A(:,1:2)=round(A(:,1:2)); A(:,3)=A(:,3)+%i*A(:,4); A=A(:,1:3); A(:,3)=A(:,3)*10^(order); A=sparse(PIL_sparse(A,'sparse','all')); case 'STRING' A=emptystr(A_size(1),A_size(2)); for n=1:A_size(1) A(n,:)=PIL_str_split(mgetl(fid,1)); end A=A(read_range(1,1):read_range(1,2),read_range(2,1):read_range(2,2)); end endfunction

0d9636cc32832ff9a8d6cf7028ece079861ba9e7

449d555969bfd7befe906877abab098c6e63a0e8

/2045/CH8/EX8.6/Ex8_6.sce

86f93ec2ad4bfecab97b19ee93de3c344ce1fd6c

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

449

sce

Ex8_6.sce

//pagenumber 405 example 6 clear vds=14;//volt idq=3*10^-3;//ampere vdd=20;//volt g=2*10^-2; rd=50*10^3;//ohm vgs=-1.5;//volt w=(vdd-vds)/idq; r1=-vgs/idq; r2=w-r1; inpres=1/(1-(0.8*((r1)/(r1+r2)))); volgai=(r1+r2)/(r1+r2+(1/(g))); disp("r1 = "+string((r1))+"ohm"); disp("effective input resistance = "+string((inpres))+"r3ohm"); disp("r2 = "+string((r2))+"ohm"); disp("voltage gain = "+string((volgai))+"av`");

81def396e92909cef52e580d4cd9e502a95ffe8e

449d555969bfd7befe906877abab098c6e63a0e8

/3890/CH2/EX2.1/Ex2_1.sce

3755bf30df93086e5715e32e8f43d2465aaab585

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

877

sce

Ex2_1.sce

//Electric machines and power systems by Syed A Nasar //Publisher:TataMcgraw Hill //Year: 2002 ; Edition - 7 //Example 2.1 //Scilab Version : 6.0.0 ; OS : Windows clc; clear; a1=5*10^-4;a2=10*10^-4; //area of cross sections in m^2 l1=24*10^-2;l2=8*10^-2; //mean length in m ur=500; //relative permiability of the material u0=4*3.14*10^-7 //permiabiity of free space u=ur*u0; //permiablity in H/m r1=l1/(u*a1); //reluctance of material with lenght l1 r2=l2/(u*a2); //reluctance of material with lenght l2 r_a=r1/2+r2; //net reluctance of a 200 turn coilin H^-1 r_b=r1*r2/(r1+r2)+r1; //net reluctance of 100 turn coil in H^-1 printf('the net reluctance of 200 turn coil is %2f in H^-1\n',r_a) printf('the net reluctance of 100 turn coil is %2f in H^-1\n',r_b)

280b517410d42c110eea41ae2bf7c210568f6184

e176c804d3e82d065a9c9635dad92da21c1483a9

/missions/X1/mission_x1.sce

bd7e1ac381a7bc8800a50aded14172d194f9fbde

[ "MIT" ]

permissive

Exia-Aix-2016/ExoLife

38f7d5e54a1fd26333f19d99a8b63f0d64cc4c4c

a88d4bc3b852f8a85b6c8cc0979ced29fb28b751

refs/heads/master

2021-09-07T01:47:04.742247

2018-02-15T11:57:47

120,471,380

1

0

null

UTF-8

Scilab

false

315

sce

mission_x1.sce

getd ('../../libs/'); //CHARGEMENT DE l'IMAGE load('Asellus_Secundus.sod'); scf(0); title("Images Originale"); display_gray(asellus_secundus); result = real(ifft(asellus_secundus)); result = uint8(result); scf(10); title("Images Result"); display_gray(result); imwrite(to_native_img(result), 'img/result.png');

209d785786e2b77af432e31d9ff7c3ac5f4bbfb8

449d555969bfd7befe906877abab098c6e63a0e8

/1580/CH7/EX7.4/Ch07Ex4.sce

561c849da115dbecdf45b07e91982ad38db44874

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

431

sce

Ch07Ex4.sce

// Scilab Code Ex7.4: Page-7.26 (2004) clc;clear; N = 3e+28; // Number density, atoms per metrecube eo = 8.854e-12; //Permittivity of the free space, farad per metre alpha = 10e-40; // Electrical polarization, farad metresquare er = 1+(N*alpha/eo); // Dielectric constant of the material printf("\nDielectric constant of the material = %3.3f ", er); // Result // Dielectric constant of the material = 4.388

508fb7779275909b2b9104dc97bd12d1ec20118c

b24d354cfcd174c92760535d8b71e22ced005d81

/Signal Processing functions/stepz.sci

5f4c4c6daf42ae297a586fa3a713f68d6f47f017

[]

no_license

shreniknambiar/FOSSEE-Signal-Processing-Toolbox

57ad8e2a71d64f95c4ccfd131e00095cf2b9c6f8

143cf61eff31240870dc0c4f61e32818a4482365

refs/heads/master

2021-01-01T18:25:34.435606

2017-07-25T18:23:47

98,334,322

0

null

2017-07-25T17:48:00

2017-07-25T17:47:59

null

UTF-8

Scilab

false

2,323

sci

stepz.sci

function [h,t] = stepz(b,varargin) if(argn(2)<1 | argn(2)>4) then error("Input arguments should lie between 1 and 4"); end if(argn(1) ~=2) then error("Outpu argument should be 2"); end flag= true; if(size(b)> [1 1]) then if(size(b,2) ~= 6) then error(" SOS must be k by 6 matrix"); end flag = false; if argn(2)>1 then n= varargin(1); else n=[]; end if argn(2)>2 then fs = varargin(2); else fs=1; end if( type(n) ~=8) then error("n must be of type double"); end if(type(fs) ~= 8) then error("fs must be of type double"); end if (type(b) ~=8) then error(" "); end end if flag then if(argn(2)>1) a= varargin(1); if (size(a)> [1 1]) then error(" a has wrong input size"); end else a=1; end if(argn(2)>2) then n= varargin(2); else n=[]; end if(argn(2)>3) then fs= varargin(3); else fs=1; end if(type(n) ~=8) then error(" n must be of type double"); end if(type(fs) ~=8) then error(" fs must be of type double"); end if( type(b) ~=8 & type(a)~= 8) then error("b and a should be of type double"); end end t=0; N=[]; if (argn(2)<2) then if flag n =impzlength(b,a); else n= impzlength(b); end elseif(length(n)>1) N= round(n); n =max(N)+1; M= min(min(N),0); end t1 = (t:(n-1))'/fs; x = ones(size(t1)); if flag s= filter(b,a,x); else s= sfilter(b,x); end if ~isempty(N) then s= s(N-m+1); t1= t1(N-m+1); end endfunction

14a32fea78e82f70352635e8daa2cfa2e8fc22d5

449d555969bfd7befe906877abab098c6e63a0e8

/1592/CH7/EX7.7/Example_7_7.sce

1a302133c1231e2e64c67992368261dcc7bc0007

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

874

sce

Example_7_7.sce

//Scilab Code for Example 7.7 of Signals and systems by //P.Ramakrishna Rao clc; clear x y1 y y2 q t n; clear; //y(t)=n*x(n) disp('y(n) depends only upon present inputs'); disp('(i) Hence the system is Dynamic'); x1=[1,3,5,3,2,5,3,9];//random variable x2=[2,4,6,4,2,4,2,1]; for n=1:4 y1(1,n)=n*x1(n); y2(1,n)=n*x2(n); end b1=2; b2=3; x=b1*x1+b2*x2; disp(x,'The input to the system is:'); for n=1:4 q(1,n)=n*x(n); end disp(q,'This input gives the output:'); y=b1*y1+b2*y2; disp(y,'For the system to be linear the output should be:'); disp('(ii) Hence the system is linear'); disp('For a delay (n0) of 2 seconds'); disp('At n=3 seconds:'); t=3; a=x(1,n-2); b=y(1,n-2); c=2*x(1,n-2); disp(a,'x(n-n0):'); disp(b,'is not equal to y(n-n0):'); disp(c,'while (n-n0)*x(n-n0):'); disp('(iii) Hence the system is Time variant');

4d21c745453313dee8cf00965cb8cdae7c858ef5

1c0a381442e787465dcbfc8eb1ae5192c322ab86

/scilab/examples/gpio.sci

aa758998ae42556f5731195d7f730cce0bd710be

[ "MIT" ]

permissive

sfuxy/stDAQ

1ea87f0dd2ee49812e52208b6bb26cba78b90b1a

bdef5de7c806612feae0b2669b9abfb9f90b7955

refs/heads/main

2023-08-11T13:54:01.531127

2021-09-01T14:59:14

382,806,217

1

null

UTF-8

Scilab

false

193

sci

gpio.sci

// Example for stdaq_toggle_gpio() as from the Reference Manual in docs/refman stdaq_open("COM0"); tags = 100; for i=1:tags stdaq_toggle_gpio(0); sleep(1); end stdaq_close();

3c5cf972c692cf9b69e6f829582663a3cee838bd

449d555969bfd7befe906877abab098c6e63a0e8

/1052/CH24/EX24.1/241.sce

172c0e4d577e73d5b403e982f83deb0e7afeb3aa

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

1,248

sce

241.sce

clc; //Example 24.1 //page no 350 printf("Example 24.1 page no 350\n\n"); //glass sphere are settling in water at 20 deg C //the slurry contains 60 wt% solids // start by assuming a basis of 100 kg of slurry m_f=40//mass of fluid,kg rho_f=998//density of water,kg/m^3 V_f=m_f/rho_f//volume of the fluid,m^3 m_s=60//mass of solid,kg rho_p=2467//density of glass,kg/m^3 V_s=m_s/rho_p//volume of glass,m^3 V = V_f + V_s//total volume,m^3 v_frac_f = V_f/V//volume fraction for the fluid particles printf("\n volume fraction fluid particles v_frac_f =%f ",v_frac_f); v_frac_p=1-v_frac_f//volume fraction for the glass particles printf("\n volume fraction for the glass particles v_frac_p=%f ",v_frac_p); rho_m=round(v_frac_f*rho_f + v_frac_p*rho_p)//bulk density of slurry printf("\n bulk density of slurry rho_m=%f kg/m^3 ",rho_m); b=10^(1.82*(1-v_frac_f))//dimensionless correction factor g=9.807//gravitational acc.,m/s^2 D_p=0.0001554//diameter of particle,m meu_f=0.001//viscosity of fluid v_t = g*D_p^2*(rho_p-rho_f)*v_frac_f^2/(18*meu_f*b)//terminal velocity printf("\n terminal velocity v_t=%f m/s",v_t); meu_m = meu_f*b//effective mixture viscosity printf("\n effective mixture viscosity meu_m=%f kg/m.s",meu_m);

9d65e9dd6c066351752c045bc667351ad12340eb

449d555969bfd7befe906877abab098c6e63a0e8

/116/CH5/EX5.2/exa5_2.sce

91fc8d0cf2c3c2ab2d440737d273c78c47dff264

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

591

sce

exa5_2.sce

//Example 5.2 //Page 253 //Refer to figure 5.19 on page 252 N=80//Number of links Nc=24//Number of control words Nb1=7//Number of bits per control word Nb2=5//Number of bits per control word disp('The number of crosspoints in the space stage is') Nx=N^2 disp('The total number of memory bits for the space stage control store is') Nbx=N*Nc*Nb1 disp('The total number of memory bits for the time stage is') Nbt=(N*Nc*8)+(N*Nc*Nb2) disp('Thus the implementation complexity is ') Cmplx=Nx+[(Nbx+Nbt)/100] //Result //Complexity is 6784 equivalent crosspoint.

893d022775e60640a1a1b00a8f35823294843010

449d555969bfd7befe906877abab098c6e63a0e8

/620/CH3/EX3.15/example3_15.sce

7f1c33cfa5cb377c630fdf1896c6fbeb9a40631d

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

236

sce

example3_15.sce

disp("Part a"); r=100; p=2; i=sqrt(p/r); disp("the maximum current (in mA) that the resistor can handle is"); disp(i*10^3); disp("Part b"); p1=50*10^(-3); v=40; r1=(v^2)/p1; disp("the resistance (in kΩ) is"); disp(r1*10^(-3));

f2ba2cfc71f2895ae82a315a8e2f2114b255ce21

6e51f2fdd036612dc2b51c405904fed97d2ae8b0

/src/test_server_2_b.tst

12231b0bc38b91bd5582408c35143c9d47cb8ba2

[ "MIT", "Zlib", "BSD-3-Clause", "OML" ]

permissive

joe-nano/ciyam

92c6ccb58029a1b2a641a7e00417ab524cb9f957

a92c296b911b29620a7bb3b758eb55339e040219

refs/heads/master

2022-04-16T14:39:55.822434

2020-03-27T06:39:13

null

0

null

UTF-8

Scilab

false

1,580

tst

test_server_2_b.tst

> module_load Meta > object_create Meta User 1 > object_execute 1 set "Description \"Test Description\"" okay > object_validate 1 Error: Password must not be empty. > object_execute 1 set "Password \"Test Password\"" okay > object_validate 1 Error: User Id must not be empty. > object_execute 1 set "User_Id \"Test User_Id\"" okay > object_validate 1 > object_execute 1 get Description Test Description > object_execute 1 get User_Id Test User_Id > object_execute 1 get Password Test Password > object_variable 1 test1 "first value" > object_variable 1 test2 "second value" > object_variable 1 test1 first value > object_variable 1 test2 second value > object_create Meta Workgroup 2 > object_create Meta User 3 > object_create Meta Application 4 > object_create Meta Workgroup 5 > object_execute 4 set "Name \"Test App Name\"" okay > object_variable 4 test_var "One" > object_execute 4 Test_Proc_1 One Test App Name > object_variable 4 test_var "Two" > session_variable test_var "Here" > object_execute 4 "Test_Proc_2 \"Is Over\"" Two Test App Name Is Over Here > session_variable test_var "Found" > object_execute 4 "Test_Proc_2 \"Is Soon\"" Two Test App Name Is Soon Found > session_list -min 5* session_list <none> <unknown> 5:5 0:0 28 > object_list 1 Meta User 2 Meta Workgroup 3 Meta User 4 Meta Application 5 Meta Workgroup > object_destroy 1 > object_list 2 Meta Workgroup 3 Meta User 4 Meta Application 5 Meta Workgroup > object_destroy 2 > object_destroy 3 > object_destroy 4 > object_destroy 5 > object_list > module_unload Meta >

c9d5a9f36262986bbee3f4f58c46fa5dd03478a2

449d555969bfd7befe906877abab098c6e63a0e8

/1994/CH10/EX10.10/Example10_10.sce

bad9cb97c9e93c425583ecf6d0d723a3ff8b301b

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

395

sce

Example10_10.sce

//Chapter-10,Example10_10,pg10_36 R2=0.04 X2=0.2 //for Tm=Tst, sm=1 R21=X2 Rex=R2-R21 //for Tst=Tm/2........(1) //Tst=k*(E2^2)*R21/((R21^2)+(X2^2))......(2)with added resistance //from (1) and (2) //(R21^2)-0.8*R21+0.04=0 a=1 b=-0.8 c=0.04 R21=(-b-sqrt((b^2)-4*a*c))/(2*a)//neglecting higher value Rex=R21-R2 printf("external resistance\n") printf("Rex=%.4f ohm per phase",Rex)

5e1fc2053f34775af46400469fa3dd94d4916a1c

449d555969bfd7befe906877abab098c6e63a0e8

/2891/CH4/EX4.5/Ex4_5.sce

db4324a8bdc39721b30d95013331275a52c27856

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

796

sce

Ex4_5.sce

//Exa 4.5 clc; clear; close; // given : N=100 // no. of elements Lm=poly(0,'Lm') // defining Lm as lambda d=0.5*Lm l=N*d // array length B.W.F.N = 114.6 /(l/Lm) // beam width in degrees B.W.F.N=horner(B.W.F.N,1) disp(B.W.F.N ,"null-to-null beamwidth in degrees:") H.P.B.W = B.W.F.N/2 // half power beam width in degrees disp(H.P.B.W ,"half power beamwidth in degrees:") D1=2*(l/Lm) // directivity of broad side array D1=horner(D1,1) D2=4*(l/Lm) // directivity of end fire array D2=horner(D2,1) disp(D1,"directivity of broad side array:") disp(D2,"directivity of end fire array:") // note : answer in the book is mis-printed,the HPBW is not 11.46 it should be 1.146 degrees. // note: misprint in second step of part a in book correct is l=N*d=100*0.5*lambda=50*lambda

61ca811dab0b817cc3f0adaa26dd1e997ed04f8a

fdc5047b7bf8122bad1e621df236b0481226c36e

/exemplos/xls-link-0.5.0-src/tests/unit_tests/xls_IsExcelRunning.tst

bca702cd8be1905d2f04f246f5674727030aa4fc

[]

no_license

jpbevila/virtualHartSci

aea3c6ba23d054670eb193f441ea7de982b531cc

a3f5be6041d230bd9f0fd67e5d7efa71f41cfca5

refs/heads/main

2023-07-26T23:05:28.044194

2021-09-09T11:50:59

null

0

null

UTF-8

Scilab

false

568

tst

xls_IsExcelRunning.tst

// ==================================================================== // Allan CORNET // DIGITEO 2008 - 2010 // ==================================================================== // <-- CLI SHELL MODE --> // ==================================================================== ierr = execstr('xls_IsExcelRunning(1)','errcatch'); assert_checkfalse(ierr == 0); assert_checkfalse(xls_IsExcelRunning()); r = xls_NewExcel(); assert_checktrue(r); assert_checktrue(xls_IsExcelRunning()); r = xls_Quit(); assert_checktrue(r); assert_checkfalse(xls_IsExcelRunning());

41dcb6f72e6e5e26e3e3857d2a10a6f8bf67ec93

002b6230874dea6e4d76defafc1ae293b5744918

/solvers/APESolver/Tests/Pulse.tst

ba046e3c29f82882c714911d9ed115d373f5c9ab

[ "MIT" ]

permissive

SCOREC/nektar

f3cf3c44106ac7a2dd678366bb53861e2db67a11

add6f04b55fad6ab29d08b5b27eefd9bfec60be3

refs/heads/master

2021-01-22T23:16:16.440068

2015-02-27T17:26:09

30,382,914

6

7

null

UTF-8

Scilab

false

816

tst

Pulse.tst

<?xml version="1.0" encoding="utf-8"?> <test> <description>2D pulse with base flow, P=5</description> <executable>APESolver</executable> <parameters>Pulse.xml</parameters> <files> <file description="Session File">Pulse.xml</file> </files> <metrics> <metric type="L2" id="1"> <value variable="p" tolerance="1e-12">10.9756</value> <value variable="u" tolerance="1e-12">0.00258633</value> <value variable="v" tolerance="1e-12">0.00258633</value> </metric> <metric type="Linf" id="2"> <value variable="p" tolerance="1e-12">98.1507</value> <value variable="u" tolerance="1e-12">0.0194736</value> <value variable="v" tolerance="1e-12">0.0194736</value> </metric> </metrics> </test>

86bed6ef20c56856c44fe18ebfbec57b4583d9bf

449d555969bfd7befe906877abab098c6e63a0e8

/3594/CH15/EX15.1/Ex15_1.sce

e983bc7c9af1cdef71310675892c9783684df350

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

580

sce

Ex15_1.sce

//to find the frequencies of the free longitudinal, transverse and torsional vibrations clc //given W=.3*2240//lb l=36//in D=3//in k=15//in A=%pi*(D/2)^2 E=30*10^6//youngs modulus C=12*10^6 g=32.2//ft/s^2 d=W*l/(A*E) Fl=187.8/(d)^(1/2) I=%pi*(d/2)^4 d1=W*(l^3)*64/(3*E*%pi*(3^4)) Ft=187.8/(d1)^(1/2) j=%pi*3^4/32 q=C*j/l Ftor=(1/(2*%pi))*(q*g*12/(W*k^2))^(1/2) F1=Ftor*60 printf("\na) Frequency of Longitudinal vibrations = %.f per min\nb) Frequency of the transverse vibrations = %.f per min\nc) Frequency of the torsional vibration = %.f per min",Fl,Ft,F1)

c7e35f38721a7c6393eb566d17cfee426d41afa8

449d555969bfd7befe906877abab098c6e63a0e8

/2141/CH13/EX13.2/Ex13_2.sce

a3e3cf9ce85d3117bd05ce8c29d11925960aa890

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

656

sce

Ex13_2.sce

clc //initialisation of variables Pn=19.71//lbf/in^2 Po=4.36 //lbf/in^2 y=14.7//lbm x=2.37/3.52//lbf/in^2 X=3.37//lbf/in^2 Pc=492//lbf/in^2 T=126.2//K t=80//K Tc=154.8//k Pcb=736//lbf/in^2 FB=0.965//lbf/in^2 Tr=t/T//lbf/in^2 Pr=Pn/Pc//lbf/in^2 fA=0.95 //lbf/in^2 fB=fA*Pn//lbf/in^2 PrA=y/Pc//lbf/in^2 FA=0.96//lbf/in^2 Fa1=FA*y//lbf/in^2 TrB=t/Tc//lbf/in^2 Pr1=Po/Pcb//lbf/in^2 fB1=0.99*4.36//lbf/in^2 XA1=0.681//lbf/in^2 //CALCULATIONS Xa=Pn/y//lbf/in^2 Xb=Po/y//lbf/in^2 YA=Xa*x//lbf/in^2 FBv=FB*y//lbf/in^2 //RESULTS printf('the raoults rule=% f lbf/in^2',YA) printf('the ideal solution in both phase=% flbf/in^2',FBv)

a1e03e3a283d1a5e2cf683158b03f5e2ba67fa0a

449d555969bfd7befe906877abab098c6e63a0e8

/1931/CH11/EX11.4/4.sce

2cc86f715a57f4718ba66d675acb20e5b9b2961c

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

607

sce

4.sce

clc clear //INPUT DATA d=5*10^28//density of silicon atom in atoms/m^3 nd=2.5*10^7//donor concentration in 1 atom per si atom T=300//Temperature in K Eg=1.1*1.6*10^-19//Eg for silicon in eV kb=1.38*10^-23//Boltzmann's Constant in m^2 Kg s^-2 k^-1 m=9.11*10^-31//mass of electon in Kg h=6.625*10^-34//plank's constant in m^2 Kg/sec //CALCULATION Nd=(d/nd)//The donor concentration in atoms/m^3 Ef=((Eg/2)+(kb*T*(log(Nd/(2*((2*3.14*m*kb*T)/h^2)^(3/2))))))/10^-20//The position of fermi level at 300K in Joule*10^-20 //OUTPUT printf('The position of fermi level is %3.4f*10^-20 Joule',Ef)

49097c06f85e5864925b2217d075f77777f6a561

449d555969bfd7befe906877abab098c6e63a0e8

/1499/CH5/EX5.37/s37.sce

b5d050f1b58dd6b5b5b94128c31ab3e7eb0cef2c

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

188

sce

s37.sce

s=%s; syms K H=syslin('c',K*(1+2*s)/(s*(s+1)*(s^2+s+1))) nyquist(H) show_margins(H,'nyquist') mtlb_axis([-1 1 -5 1]) gm=g_margin(H) // gain margin pm=p_margin(H) // phase margin

ab2c40ba3f49eef95d071bd5c69cf22829af6da3

449d555969bfd7befe906877abab098c6e63a0e8

/1109/CH5/EX5.2/5_2.sce

e155e846dc5a579d988461e8069e7a4887727bf7

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

514

sce

5_2.sce

clear; clc; R=10.15;L=3.93*(10^-3);G=0.29*(10^-6);C=0.008*(10^-6);w=5000;r=7.3;l=246*(10^-3); s=7.88; Rc=R+(r/s); Lc=L+(l/s); al=((Rc/2)*sqrt(C/Lc))+((G/2)*sqrt(Lc/C)); printf("-a = %f neper/km\n",round(al*10000)/10000); b=w*(sqrt(Lc*C)); printf("-b = %f radians/km\n",round(b*10^4)/10^4); lo=2*%pi/b; //lo=lambda printf("-lo = %f km\n",round(lo*100)/100); Vp=(w/b)*10^-4; printf("-Vp = %f * 10^4 km/sec\n",round(Vp*100)/100); Zo=(sqrt(Lc/C))*10^-3; printf("-Zo = %f * 10^3 ohms",fix(Zo*100)/100);

48506637e09ec55ea71631e90def3c3cc833d865

6227c5ef4e1c5d72cdebd6eac81f82161dda7e17

/digi_dc_dc/Scilab/AuxiliaryFunctions/CycleSpec.sci

6b4b276144b81a35b7f3c17bdc7c43233f67f718

[]

no_license

maxsimmonds1337/Scilab

b4e8a03a9fbeda4d8f6e51e07d205bcf51addce8

b413659e2b697565c24ad440d158f5bd28203570

refs/heads/master

2022-11-04T23:17:50.045864

2020-06-13T20:35:24

272,081,285

0

null

UTF-8

Scilab

false

446

sci

CycleSpec.sci

function Linespec=CycleSpec(n) // n : from 0 to N Linestyle =['-';'--';':';'-.'] Linecolor = ['r';'g';'b';'c';'m';'k'] Linemarker =['';'+';'o';'*';'.';'x';'s';'d';'^';'v';'>';'<';'p'] i = modulo(n,size(Linecolor,'*'))+1 j = modulo(floor(n/size(Linecolor,'*')),size(Linestyle,'*'))+1 k = modulo(floor(n/size(Linecolor,'*')/size(Linestyle,'*')),size(Linemarker,'*'))+1 Linespec = Linestyle(j)+Linecolor(i)+Linemarker(k) endfunction

1f63f641f41332e4059e78396aba6c2a087eea7f

449d555969bfd7befe906877abab098c6e63a0e8

/1092/CH9/EX9.17/Example9_17.sce

d0fb0539ff20a6cb646a1b38c8bd8857fafaf7bf

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

2,724

sce

Example9_17.sce

// Electric Machinery and Transformers // Irving L kosow // Prentice Hall of India // 2nd editiom // Chapter 9: POLYPHASE INDUCTION (ASYNCHRONOUS) DYNAMOS // Example 9-17 clear; clc; close; // Clear the work space and console. // Given data // three-phase SCIM V_o = 220 ; // Rated voltage in volt P = 4 ; // Number of poles in SCIM P_o = 10 ; // Rated power in hp f = 60 ; // Frequency in Hz(assume,not given) T_o = 30 ; // Rated torque in lb-ft S_r = 1710 ; // Rated rotor speed in rpm V_n1 = 242 ; // Impressed stator voltage in volt(case a) V_n2 = 198 ; // Impressed stator voltage in volt(case b) // Calculations S = (120*f)/P ; // Speed in rpm of the rotating magnetic field // case a : Impressed stator voltage = 242 V s_o = (S - S_r)/S ; // Rated slip T_n1 = T_o * (V_n1/V_o)^2 ; // New torque in lb-ft s_n1 = s_o * (T_o/T_n1); // New slip S_rn1 = S*(1 - s_n1); // case b : Impressed stator voltage = 198 V T_n2 = T_o * (V_n2/V_o)^2 ; // New torque in lb-ft s_n2 = s_o * (T_o/T_n2); // New slip S_rn2 = S*(1 - s_n2); // case c // Subscript a in percent_slip and percent_speed indicates part a percent_slip_a = (s_o - s_n1)/s_o * 100 ; // Percent change in slip in part(a) percent_speed_a = (S_rn1 - S_r)/S_r * 100; // Percent change in speed in part(a) // case d // Subscript b in percent_slip and percent_speed indicates part b percent_slip_b = (s_n2 - s_o)/s_o * 100 ; // Percent change in slip in part(b) percent_speed_b = (S_r - S_rn2)/S_r * 100; // Percent change in speed in part(b) // Display the results disp("Example 9-17 Solution : "); printf(" \n a: Rated slip :\n s = %.2f\n",s_o); printf(" \n For impressed stator voltage = %d V \n ",V_n1); printf(" \n New torque :\n T_n = %.1f lb-ft \n ",T_n1); printf(" \n New slip :\n s_n = %f \n ",s_n1); printf(" \n New rotor speed :\n S_r = %f rpm \n",S_rn1); printf(" \n b: For impressed stator voltage = %d V \n ",V_n2); printf(" \n New torque :\n T_n = %.1f lb-ft \n ",T_n2); printf(" \n New slip :\n s_n = %f \n ",s_n2); printf(" \n New rotor speed :\n S_r = %f rpm \n",S_rn2); printf(" \n c: Percent change in slip in part(a)"); printf(" \n = %.1f percent decrease.\n",percent_slip_a); printf(" \n Percent change in speed in part(a)"); printf(" \n = %.2f percent increase \n",percent_speed_a); printf(" \n d: Percent change in slip in part(b)"); printf(" \n = %.2f percent increase.\n",percent_slip_b); printf(" \n Percent change in speed in part(b)"); printf(" \n = %.2f percent decrease\n",percent_speed_b); printf(" \n SLIGHT VARIATIONS IN PERCENT CHANGE IN SLIP AND SPEED ARE DUE TO"); printf(" \n NON-APPROXIMATION OF NEW SLIPS AND NEW SPEEDS CALCULATED IN SCILAB.")

a692f4019f9cbb8101ac0d77ece1c21a185f9a1c

6a22b7e73dc2ff6c089b727d0a3858241846f8df

/Systems/esh-spring-2015.git/eshtests/milestone.tst

566b675f9699a6c2fe480b4a4c905d567a0dab2d

[ "MIT" ]

permissive

mikefeneley/school

fe48ee989ac83d4836ce93538cbe51496f709abe

5156f4537ca76782e7ad6df3c5ffe7b9fb5038da

refs/heads/master

2021-06-10T01:52:21.148937

2016-12-23T12:39:32

72,551,482

1

0

null

UTF-8

Scilab

false

40

tst

milestone.tst

= Milestone 30 milestone/foreground.py

296413c0a5ad9c923e070fd7ff229babdf6c0549

449d555969bfd7befe906877abab098c6e63a0e8

/2399/CH4/EX4.13.1/Example_4_13_1.sce

0087101ced810dfc0835ed0e08fc013df3604922

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

489

sce

Example_4_13_1.sce

// Example 4.13.1 clc; clear; lamda=1550d-9; lamda0=1.3d-6; s0=0.095; Dt=lamda*s0/4*(1-(lamda0/lamda)^4); //computing material dispersion Dt=Dt*10^9; printf("\nMaterial dispersion at 1550 nm is %.1f ps/nm/km",Dt); printf("\n\nNOTE - Slight deviation in the answer because of printig mistake\nIn problem they have given lamda0 as 1300 nanometer \nbut while solving they have taken it as 1330 nanometer"); //answer in the book 15.6 ps/nm/km, deviaton due to printing mistake.

fef44ce3f61455edee4048e5572104b416f4f22a

b29e9715ab76b6f89609c32edd36f81a0dcf6a39

/ketpicscifiles6/Closepar.sci

64b93e1af2f4f62d40f497cdadb1a9a7ef79d3b6

[]

no_license

ketpic/ketcindy-scilab-support

e1646488aa840f86c198818ea518c24a66b71f81

3df21192d25809ce980cd036a5ef9f97b53aa918

refs/heads/master

2021-05-11T11:40:49.725978

2018-01-16T14:02:21

117,643,554

1

0

null

UTF-8

Scilab

false

245

sci

Closepar.sci

// 08.05.31 function Closepar() global Wfile FID S='\end{minipage}' if Wfile=='default' mprintf('%s\n','%'); mprintf('%s',S); else mfprintf(FID,'%s\n','%'); mfprintf(FID,'%s',S); end Closephr(); endfunction

a41bb10c314cd89b6232046cdb34c683ecfb677d

ed81f401dcd2ce0399cec3a99b6e5851e62e74ca

/data/github.com/arktools/arktoolbox/d347996e3543e6fb7aeee2febfc36b9be9a57d8d/arktoolbox-scicos/scicos/arktoolbox/navigationEquations.sci

7067619cee03f96f97dd8c59f65ece2b08a41e9c

[ "MIT" ]

permissive

smola/language-dataset

9e2a35340d48b497cd9820fa2673bb5d482a13f7

4d1827d1018b922e03a48a5de5cb921a6762dda3

refs/heads/master

2023-03-10T12:42:04.396308

2022-07-15T18:05:05

143,737,125

18

3

MIT

2023-03-06T05:01:14

2018-08-06T14:05:52

Python

UTF-8

Scilab

false

3,158

sci

navigationEquations.sci

function [x,y,typ]=navigationEquations(job,arg1,arg2) // // insDynamics.sci // // USAGE: // // input 1: (body velocity) // [1] U (distance/s) // [2] V (distance/s) // [3] W (distance/s) // // input 2: (attitude) // [1] phi (rad) // [2] theta (rad) // [3] psi (rad) // // output 1: (navigation frame velocities) // [1] vN, north velocity (distance/s) // [2] vE, east velocity (distance/s) // [3] vD, down velocity (distance/s) // // AUTHOR: // // Copyright (C) James Goppert 2011 // // This file is free software: you can redistribute it and/or modify it // under the terms of the GNU General Public License as published by the // Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This file is distributed in the hope that it will be useful, but // WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. // See the GNU General Public License for more details. // // You should have received a copy of the GNU General Public License along // with this program. If not, see <http://www.gnu.org/licenses/>. // mode(-1); x=[];y=[];typ=[]; select job case 'plot' then standard_draw(arg1) case 'getinputs' then [x,y,typ]=standard_inputs(arg1) case 'getoutputs' then [x,y,typ]=standard_outputs(arg1) case 'getorigin' then [x,y]=standard_origin(arg1) case 'set' then x=arg1; graphics=arg1.graphics;exprs=graphics.exprs; model=arg1.model; //while %t do //labels=[.. //'Omega (rad/s)';.. //'Re (unit distance)';.. //'state mode: full(0), attitude(1), velocity position(2)']; //[ok,Omega,Re,stateMode,exprs]=.. //getvalue('Set Planet Parameters',labels,.. //list('vec',1,'vec',1,'vec',1),exprs); //if ~ok then break,end //graphics.exprs=exprs; //// set sizes based on mode //if stateMode==0 then //nOut=10; //nIn=[6;1;10] //elseif stateMode==1 then //nOut=4; //nIn=[3;1;4] //elseif stateMode==2 then //nOut=6; //nIn=[3;1;6] //else //disp('invalid mode in insDynamics block'); //error('invalid mode in insDynamics block'); //end //model.out=[nOut]; //model.in=[nIn]; //[model,graphics,ok]=check_io(model,graphics,nIn,nOut,[],[]) //if ok then //model.rpar=[Omega,Re]; //model.ipar=stateMode; //graphics.exprs=exprs; //x.graphics=graphics; //x.model=model; //break //end //end case 'define' then // set model properties model=scicos_model(); model.sim=list('sci_navigationEquations',4); nOut=3; nIn=[3;3] model.in=nIn; model.out=nOut; model.blocktype='c'; model.dep_ut=[%t %f]; exprs=[]; // gpsIns parameters //Omega = 7.292115e-5; //Re=6378137; //stateMode=0; // full state //model.rpar=[Omega,Re]; //model.ipar=stateMode; // initialize strings for gui //exprs=[.. //strcat(sci2exp(Omega)),.. //strcat(sci2exp(Re)),.. //strcat(sci2exp(stateMode))]; // setup icon gr_i=['xstringb(orig(1),orig(2),[''navigation'';''equations''],sz(1),sz(2),''fill'');'] x=standard_define([5 2],model,exprs,gr_i) end endfunction // vim:ts=4:sw=4

894438ac044d4c1427040c54e6db13726c988d39

1573c4954e822b3538692bce853eb35e55f1bb3b

/DSP Functions/allpasslp2mb/test_10.sce

7d44d7c574cea90bc5cf54c7648b8f31c4a96cc5

[]

no_license

shreniknambiar/FOSSEE-DSP-Toolbox

1f498499c1bb18b626b77ff037905e51eee9b601

aec8e1cea8d49e75686743bb5b7d814d3ca38801

refs/heads/master

2020-12-10T03:28:37.484363

2017-06-27T17:47:15

95,582,974

1

0

null

UTF-8

Scilab

false

215

sce

test_10.sce

// Test # 10 : For 1 output argument exec('./allpasslp2mb.sci',-1); [n]=allpasslp2mb(0.3,[0.434,.731]); disp(n); // //Scilab Output //n=- 0.5915977 - 0.4567161 - 1. // //Matlab Output //n= -0.5916 -0.4567 -1.0000

9fdf6ab637b50025e205c4fafeaad9dc5f9c87fa

5900f4bae371f44e90fa8de76d746cc470223e04

/src/special_functions.sci

36d3c0263bae25e237a9032ba26f1b4f37c62acf

[]

no_license

olgerd27/union__gte_reducer_oil

6400148e100224e0c59c4ca807afa5de07ffcb09

be994038b218ba7cac13b59faf2391a8e2bdd861

refs/heads/master

2021-01-10T20:21:06.558271

2014-10-01T06:56:23

null

0

null

UTF-8

Scilab

false

17,638

sci

special_functions.sci

// SPECIAL FUNCTIONS function [reg_all, dtm_all] = calcSteadyPoints() //***************************************************************** // Function for calculating the steady mode points values * // IN: all initial data is the global variables * // OUT: reg_all - the regime parameter steady mode points values * // dtm_all - the 'dt' parameters steady mode points values * //***************************************************************** // Arrays for storing steady mode points values reg_all = []; dtm_all = []; // MAIN CYCLE for fileIndex = 1 : size(filesArchive, 'r') // Deleting results that was obtained in the previous main cycle iteration clear reg_steady; clear tm_steady; clear dtm_steady; clear arrayNumber_steady; // READING an archive file params = readParametersData(path_archives, sep, filesArchive(fileIndex), '.' + ext_archive, params); // Getting the parameters arrays with reduction to a normal atmospheric condition // This parameters is take out of the if-else, because name of its index variable for the both diagnostic systems is equal reg = params(index_reg).data; // the regime parameter values tm = params(index_tm).data; if diag_sys == GTE_OIL t0 = mean(params(index_t0).data, 'c'); alpha = sqrt(288 ./ (t0 + 273)); // alpha coefficient for reductions parameters to normal atmospheric conditions Gt = params(index_Gt).data; reg = reg * 10.2; // there are p2 parameter values with conversion its from MPa to kg/cm2 n2 = params(index_n2).data .* alpha; // reduction to normal conditions end // Splitting parameters arrays to sectors with defining the average values and strange steadyIndex = 0; // kk - is the coefficient for correct definition the iterations quantity and correct shifting buffer with length "sectorShift" // along the full length of archive kk = ceil(sectorLength / sectorShift); arrSize = length(reg); for j = kk : int(arrSize / sectorShift) from = sectorShift * (j - 1) + 1; to = sectorShift * j; arrayNumber = j * sectorShift; // split arrays, calc strange or average values of parameters and define steady mode isSteadyMode = %F; if diag_sys == GTE_OIL Gt_strange = strange(Gt(to - sectorLength + 1 : to)); // there are splitting and strange value calculation n2_avrg = median(n2(from : to)); Gt_avrg = median(Gt(from : to)); isSteadyMode = (Gt_strange <= UGt_strange) & (n2_avrg > Un2_xx) & (Gt_avrg > 0); // define steady mode else reg_strange = strange(reg(to - sectorLength + 1 : to)); reg_avrg = median(reg(from : to)); isSteadyMode = (reg_strange <= Ungv_strange) & (reg_avrg > Ungv_min); // define steady mode end // Processing the steady modes of GTE's work points values if isSteadyMode steadyIndex = steadyIndex + 1; if diag_sys == GTE_OIL reg_steady(steadyIndex) = median(reg(from : to)); else reg_steady(steadyIndex) = reg_avrg; // already calculated end //-------------------------------------------------------------------------------------------------------- // calculate the 'tm' values in steady mode of work modelFrom = arrayNumber - modelLength + 1; modelTo = arrayNumber; xModel = [modelFrom : modelTo]'; yModel = tm(modelFrom : modelTo, :); forecastTo = to + forecastInterval; // the argument-value for forecasting // printf("modelFrom = %i, modelTo = %i\n", modelFrom, modelTo); // printf("sizes: xModel = [%i, %i], yModel = [%i, %i]\n", .. // size(xModel, 'r'), size(xModel, 'c'), size(yModel, 'r'), size(yModel, 'c')); // abort; tm_steady(steadyIndex, :) = linearForecastValues(xModel, yModel, forecastTo)'; // old version // for t = 1 : count_tmParams // tm_steady(steadyIndex, t) = median(tm(from : to, t)); // end //-------------------------------------------------------------------------------------------------------- arrayNumber_steady(steadyIndex) = arrayNumber; end end // Check if in the current archive doesn't exist the steady mode points if steadyIndex == 0 printf("[ERROR]: Steady mode points not found: archive #%i = %s, sectorLength = %i, sectorShift = %i\n", .. fileIndex, filesArchive(fileIndex), sectorLength, sectorShift); printf("Continue? (1 - yes, 2 - no)\n"); key = scanf("%i"); if key == 1 continue; else scf(1); xgrid; title('Steady mode points not found. ' + params(index_reg).name + ' = f(time)', 'fontsize', 4); plot2d(reg); e = gce(); e.children.thickness = 2; printf("--------------------------------------------------------------------------------------------------------\n\n"); abort; end end // Define temperature drop of oil for t = 1 : count_dtmParams dtm_steady(:, t) = tm_steady(:, t + 1) - tm_steady(:, index_in); end // Check existence the "bad", invalid points, that is far from others points ind_invalidValues = find(dtm_steady > Udtm_valid_max | dtm_steady < Udtm_valid_min); count_invalidPoints = length(ind_invalidValues); if count_invalidPoints [cols_invalid_dt, rows_invalid] = calcInvalidValuePos(ind_invalidValues, size(reg_steady, 'r')); rows_invalid_u = unique(rows_invalid); str_archiveNumberName = 'archive #' + string(fileIndex) + ': ' + filesArchive(fileIndex)'; printf("[ERROR]: There was found %i invalid steady mode point(s) in the %s\n", count_invalidPoints, str_archiveNumberName); for i = 1 : count_invalidPoints printf("\tpoint #%i: parameter = ''%s'', number = %i\n", i, dt_names(cols_invalid_dt(i)), rows_invalid(i)); end printf("Continue with deleting invalid points? (1 - yes, 2 - no)\n"); key = scanf("%i"); if key == 1 // delete rows with invalid point(-s) for getting arrays with only valid points reg_steady(rows_invalid_u, :) = []; dtm_steady(rows_invalid_u, :) = []; else plotInvalidArchive( reg, tm, reg_steady, tm_steady, arrayNumber_steady, .. cols_invalid_dt, rows_invalid, rows_invalid_u, .. index_in, params(index_reg).name, t_names, .. str_archiveNumberName, colors ); printf("--------------------------------------------------------------------------------------------------------\n\n"); abort; end end // Save the values of the steady mode points over all archives for further processing out of the main cycle reg_all = [reg_all; reg_steady]; dtm_all = [dtm_all; dtm_steady]; printf("[INFO]: Archive #%i: ""%s"", points quantity = %i\n", fileIndex, filesArchive(fileIndex), steadyIndex); end endfunction function forc_y = linearForecastValues(xArr, yArr, forc_x) //********************************************************************************************** // Calculation the forecast value Y for given model and argument value X (linear forecasting) * // IN: xArr - array values of model * // yArr - array values of model * // forc_x - the x-argument value * // OUT: forc_y - the forecasted value * //********************************************************************************************** Ncols = size(yArr, 'c'); power = 1; forc_y(Ncols) = 0; for i = 1 : Ncols coefs = coeffs_trend_n(xArr, yArr(:, i), power); for j = 1 : power + 1 forc_y(i) = forc_y(i) + coefs(j) * forc_x .^ (power + 1 - j); end end endfunction // The power (N) defining function N = p2ToPower(p2, count, p2_characs, N_characs) //***************************************************************************************** // Define the GTE's power values (Ngte) with yhe help of the characteristics Ngte = f(p2) * // IN: p2 - the array with the p2 parameter values * // count - the "p2" array size * // p2_characs - the x-values (p2) of the characteristics for defining powers * // N_characs - the x-values (Ngte) of the characteristics for defining powers * // OUT: N - the array with the result Ngte parameter values * //***************************************************************************************** for i = 1 : count N(i) = interExtraPolation(p2_characs, N_characs, p2(i)); end endfunction function N = ngvToPower(ngv, N_nom, ngv_nom) //********************************************************************************************* // Define the power on the outlet reduction shaft (Nred) with the help of the reducer outlet * // shaft rotation speed (ngv) and the theoretical cubic dependence Nred and ngv. * // IN: ngv - array of the reducer outlet shaft rotation speeds values * // N_nom - the value of Ngte parameter on the nominal works regime * // ngv_nom - the value of ngv on the nominal works regime * // OUT: N - array of the powers on the reducer outlet shaft * //********************************************************************************************* power_N_ngv = 3; a = (N_nom / ngv_nom ^ power_N_ngv); N = a * ngv ^ power_N_ngv; endfunction function [invalidCols, invalidRows] = calcInvalidValuePos(indexes, count_rows) //***************************************************************************************** // Calculate the positions (rows, cols) of the parameters arrays rows with invalid data * // IN: indexes - array of indexes with invalid values of parameters * // count_rows - the rows quantity in parameters arrays * // OUT: invalidRows - the array of the parameters arrays rows numbers with invalid values * // invalidCols - the array of the parameters arrays cols numbers with invalid values * //***************************************************************************************** invalidCols = ceil(indexes / count_rows); invalidRows = indexes - int(indexes / count_rows) * count_rows; lastValuesInCols = find(invalidRows == 0); if length(lastValuesInCols) invalidRows(lastValuesInCols) = count_rows; end endfunction // GRAPHS PLOT function plotResults(x_points, y_points, x_polyn, y_polyn, .. count_pars, plotInSameWin, x_names, y_name, strDateTime) //************************************************************ // //************************************************************ // define the size of graphs square matrix if plotInSameWin size_graphsSquareMatrix = 2; else size_graphsSquareMatrix = 1; end graphsOnWin = size_graphsSquareMatrix * size_graphsSquareMatrix; // plotting str_y_name = ' = f(' + y_name + ')'; oneWin_parNames = ''; sep_win_par_names = ', '; number_winFirst = max(winsid()) + 1; it_par = 1; // iterator of plotted parameters it_win = 1; // iterator of plot windows it_graph = 1; // iterator of the graphs on a one plot window while (it_par <= count_pars) strTitle = x_names(it_par) + str_y_name; oneWin_parNames = oneWin_parNames + x_names(it_par) + sep_win_par_names; // for the windows names hWin = scf(number_winFirst + it_win); subplot(size_graphsSquareMatrix, size_graphsSquareMatrix, it_graph); plot2d(x_points, y_points(:, it_par), -9); xgrid; title(strTitle + ', ' + strDateTime, 'fontsize', 4); // Plot the approximate line plot2d(x_polyn, y_polyn(:, it_par), 15); e = gce(); e.children.thickness = 2; // Plot the approximate lines points plot2d(x_polyn, y_polyn(:, it_par), -14); if (it_graph == graphsOnWin) | (it_par == count_pars) // forming the windows names oneWin_parNames = part(oneWin_parNames, [1 : length(oneWin_parNames) - length(sep_win_par_names)]); hWin.figure_name = '[' + oneWin_parNames + ']' + str_y_name; oneWin_parNames = ''; hWin.figure_size = [1000 700]; hWin.figure_position = [50 50]; // increase the iterators values it_win = it_win + 1; it_graph = 1; else it_graph = it_graph + 1; end it_par = it_par + 1; end endfunction function plotInvalidArchive( reg, tm, reg_steady, tm_steady, arrayNumber_steady, .. cols_invalid_dt, rows_invalid, rows_invalid_u, .. index_in, reg_name, t_names, .. str_archiveNumberName, colors ) //************************************************************************************************************* // Function for plotting archive parameters with the invalid steady mode points. * // IN: reg - the regime parameter time series * // tm - the temperature parameters time series * // reg_steady - the regime parameter steady mode points * // tm_steady - the temperature parameter steady mode points * // arrayNumber_steady - the steady mode points of array numbers * // cols_invalid_dt - the number(-s) of columns with invalid point(-s) value(-s) (if use 'dt' parameter) * // rows_invalid - the number(-s) of rows with invalid point(-s) value(-s) * // rows_invalid_u - the unique values from the 'rows_invalid' arrays * // index_in - the number of the index temperature at the entry * // reg_name - the name of the regime parameter * // t_names - the array of the temperatures names * // str_archiveNumberName - the string of union information about number and name archive * // colors - the colors indexes arrays * // OUT: --- * //************************************************************************************************************* // define the valid steady mode points reg_steady_valid = reg_steady; reg_steady_valid(rows_invalid_u, :) = []; tm_steady_valid = tm_steady; tm_steady_valid(rows_invalid_u, :) = []; arrayNumber_steady_valid = arrayNumber_steady; arrayNumber_steady_valid(rows_invalid_u, :) = []; // Initial data for plotting x_time = [0 : length(reg) - 1]; // X-value for plotting kRegScale = 0.1; // scaled coefficient for plotting 'reg' parameter in same window as 'tm' parameters type_validPoints = -3; // type of the marker for plotting the valid points type_invalidPoints = -9; // type of the marker for plotting the invalid points legend_str = []; cols_invalid_t = cols_invalid_dt + 1; // conversion columns number from 'dt' parameter to 'tm' cols_invalid_t_u = unique(cols_invalid_t); // numbers of the parameters with invalid steady mode points count_invalidParams = length(cols_invalid_t_u); // quantity of the parameters with invalid steady mode points // plot window settings windowNumber = max(winsid()) + 1; strTitle = 'Invalid points, ' + str_archiveNumberName; hPlot = scf(windowNumber); xgrid; hPlot.figure_name = strTitle; title(strTitle, 'fontsize', 4); // plot parameters time series graphs plot2d(x_time, reg * kRegScale, colors(1)); e = gce(); e.children.thickness = 2; legend_str = [legend_str; reg_name]; plot2d(x_time, tm(:, index_in), colors(2)); e = gce(); e.children.thickness = 2; legend_str = [legend_str; t_names(index_in)]; for i = 1 : count_invalidParams plot2d(x_time, tm(:, cols_invalid_t_u(i)), colors(i + 2)); e = gce(); e.children.thickness = 2; legend_str = [legend_str; t_names(cols_invalid_t_u(i))]; end legend(hPlot, legend_str, 1); // plot invalid steady mode points plot2d(arrayNumber_steady(rows_invalid_u), reg_steady(rows_invalid_u) * kRegScale, type_invalidPoints); plot2d(arrayNumber_steady(rows_invalid_u), tm_steady(rows_invalid_u, index_in), type_invalidPoints); for i = 1 : count_invalidPoints plot2d(arrayNumber_steady(rows_invalid(i)), tm_steady(rows_invalid(i), cols_invalid_t(i)), type_invalidPoints); end // plot valid steady mode points if length(reg_steady_valid) ~= 0 plot2d(arrayNumber_steady_valid, reg_steady_valid * kRegScale, type_validPoints); plot2d(arrayNumber_steady_valid, tm_steady_valid(:, index_in), type_validPoints); for i = 1 : count_invalidParams plot2d(arrayNumber_steady_valid, tm_steady_valid(:, cols_invalid_t_u(i)), type_validPoints); end else printf("[INFO]: None steady mode, founded in current archive, is valid\n"); end endfunction

5ea62c6b69576d0d47a6489edf926a2b01cb0db6

e0fcb1aede35832965ea980460a3a2bdade5adee

/task1.sce

8f0b8885bbe5c05f6fdac503b6ede468e4ca680b

[]

no_license

fatawesome/dsp-ass4

e06bcae70f93bb54b439bb0abb6d48e77e26fd86

2cfcb0d8be06e91231d12ff10648542ed76c0e1d

refs/heads/master

2022-04-19T04:29:57.088781

2020-04-15T19:14:03

256,013,336

0

null

UTF-8

Scilab

false

6,388

sce

task1.sce

clear() clf() // Read signal //[s, Fs, _] = wavread("signal_with_low_freq_noise_2.wav") load("signal_with_noise_and_filtered.sod"); // Take the first channel s = signal_with_noise(1, :) // Plot //plot(s) //xlabel("Time, n", 'fontsize', 2) //ylabel("Amplitude", 'fontsize', 2) //title("Signal with noise in time domain", 'fontsize', 3) //xs2png(0, "signal_with_noise_time.png") // Plot spectrum // calculate frequencies //s_len = length(s) //frequencies = (0:s_len-1)/s_len * Fs; // //// plot // //plot2d("nl", frequencies, abs(fft(s)), color("blue")) //xlabel("Frequency component, n", 'fontsize', 2) //ylabel("Freq. Amplitude", 'fontsize', 2) //title("Signal with noise in frequency domain", 'fontsize', 3) //xs2png(0, "signal_with_noise_freq.png") // N: integer length of FIR filter // cutoff: fraction of Fs, at which frequencies are stopped // stop_value: the value for frequencies in the stop band // (after cutoff frequency) // return: frequency representation of an ideal // low pass FIR filter of length N+1 if N is even // or N if N is odd function H = ideal_lowpass(N, cutoff, stop_value) N = (N - modulo(N, 2)) / 2 cutoff = floor(2 * N * cutoff) H = ones(1, N) * stop_value H(1, 1:cutoff) = 1 printf("%d, %d\n", N, cutoff) // need to make N odd H = [1. H flipdim(H, 2)] endfunction function H = highpass(N, cutoff, stop_value) N = (N - modulo(N, 2)) / 2 cutoff = floor(2 * N * cutoff) H = ones(1, N) H(1, 1:cutoff) = stop_value printf("%d, %d\n", N, cutoff) // need to make N odd H = [1. H flipdim(H, 2)] endfunction function H = task1_filter(N, cutoff_low, cutoff_high, stop_low, stop_high) N = (N - modulo(N, 2)) / 2 cutoff_low = floor(2 * N * cutoff_low) cutoff_high = floor(2 * N * cutoff_high) printf("%d, %d, %d\n", N, cutoff_low, cutoff_high) H = ones(1, N) H(1, 1:cutoff_high) = stop_high H(1, cutoff_low:N) = stop_low H(1, 1:30) = 0 // need to make N odd H = [1. H flipdim(H, 2)] endfunction function sv = shift(v,n) if (size(v,'r')<>1 & size(v,'c')<>1) then error("1st argument must be column vector or row vector") end if size(v,'r')<>1 then v = shift(v',n) sv = v' else n = modulo(n,size(v,'c')) sv = v($-n+1:$) sv = [sv v(1:$-n)] end endfunction H_l = ideal_lowpass(256, 0.15, 0.); h_len = length(H_l) frequencies = (0:h_len-1)/h_len * Fs; // Compute impulse response // project into temporal domain // imaginary part should be close to 0 h_l = real(ifft(H_l)) mid = floor(h_len / 2) //h_l_shifted = [h_l(:, mid + 1:h_len), h_l(:, 1:mid)] h_l_shifted = shift(h_l, int(h_len / 2)) h_l_windowed = h_l_shifted .* window('kr', length(h_l), 8) disp(h_l_windowed) //plot2d('nn', 0:length(h_l_windowed)-1, h_l_windowed, color("blue")) //xlabel("Time, n", 'fontsize', 2) //ylabel("Amplitude", 'fontsize', 2) //title("Impulse response of ideal low-pass filter", 'fontsize', 3) //xs2png(gcf(), "ideal_lowpass_time.png") ////plot2d("nl", frequencies, abs(fft(h_l_windowed)), color("blue")) ////xlabel("Frequency, Nz", 'fontsize', 2) ////ylabel("Freq amplitude", 'fontsize', 2) ////title("Frequency response of the final FIR filter", 'fontsize', 3) ////xs2png(gcf(), "frequency_response_final_fir_filter.png") H_h = highpass(256, 0.001, 0.); h_len = length(H_l) frequencies = (0:h_len-1)/h_len * Fs; h_h = real(ifft(H_h)) mid = floor(h_len / 2) h_h_shifted = shift(h_h, int(h_len / 2)) h_h_windowed = h_h_shifted .* window('kr', length(h_h), 8) task1_fir = task1_filter(8192, 0.15, 30 / 44100, 0., 0.) task1_fir_len = length(task1_fir) frequencies = (0:task1_fir_len-1)/task1_fir_len * Fs; // квадтратный график //plot2d("nn", frequencies, task1_fir, color("blue")) //xlabel("Frequency, Hz", 'fontsize', 2) //ylabel("Freq amplitude", 'fontsize', 2) //title("Frequency response of band-pass task1 filter", 'fontsize', 3) //xs2png(0, "task1-band-pass-freq.png") task1_fir = real(ifft(task1_fir)) task1_fir_shifted = shift(task1_fir, int(task1_fir_len / 2)) task1_fir_windowed = task1_fir_shifted .* window('kr', length(task1_fir_shifted), 8) //plot2d('nl', frequencies, abs(fft(task1_fir_windowed)), color("blue")) //xlabel("Time, n", 'fontsize', 2) //ylabel("Amplitude", 'fontsize', 2) //title("Impulse response of ideal low-pass filter", 'fontsize', 3) //xs2png(gcf(), "ideal_lowpass_time.png") //zopa = convol(h_h_windowed, convol(h_l_windowed, s)) //savewave('task1-piped-filter.wav', zopa, 44100) //zopa = convol(ffilt("bp", 256, 9000, 10000), s) zopa = convol(task1_fir_windowed, s) savewave('task1-combined-filter.wav', zopa, 44100) frequencies = (0:length(zopa)-1)/length(zopa) * Fs; //plot2d("nl", frequencies, abs(fft(zopa)), color("blue")) //xlabel("Frequency, Nz", 'fontsize', 2) //ylabel("Freq amplitude", 'fontsize', 2) //title("Frequency response of the final FIR filter", 'fontsize', 3) //xs2png(gcf(), "frequency_response_final_fir_filter.png") //-------------- h_len = length(task1_fir); //frequencies = (0:h_len-1)/h_len * Fs; //plot2d("nn", frequencies, task1_fir, color("blue")); //xlabel("Frequency, Hz", 'fontsize', 2); //ylabel("Freq amplitude", 'fontsize', 2); //title("Frequency response of ideal low-pass filter", 'fontsize', 3); //h_l = real(ifft(task1_fir)); //plot2d('nn', 0:length(h_l)-1, h_l, color("blue")); //xlabel("Time, n", 'fontsize', 2); //ylabel("Amplitude", 'fontsize', 2); //title("Impulse response of ideal low-pass filter", 'fontsize', 3); task1_fir_shifted = shift(task1_fir, int(task1_fir_len / 2)) //plot2d('nn', 0:length(task1_fir_shifted)-1, task1_fir_shifted , color("blue")); //xlabel("Time, n", 'fontsize', 2); //ylabel("Amplitude", 'fontsize', 2); //title("Impulse response of shifted task1 band-pass filter", 'fontsize', 3); task1_fir_windowed = task1_fir_shifted .* window('kr', length(task1_fir_shifted), 8) plot2d('nn', 0:length(task1_fir_windowed)-1, task1_fir_windowed, color("blue")); xlabel("Time, n", 'fontsize', 2); ylabel("Amplitude", 'fontsize', 2); title("Impulse response of shiffted task1 filter after window", 'fontsize', 3); //frequencies = (0:task1_fir_len-1)/task1_fir_len * Fs; //plot2d("nl", frequencies, abs(fft(task1_fir_windowed)), color("blue")); //xlabel("Frequency, Hz", 'fontsize', 2); //ylabel("Freq amplitude", 'fontsize', 2); //title("Frequency response of the final FIR filter", 'fontsize', 3);

53eb30c634f88e778184172f4e83a097e8319a5a

0812f3bb6f3cc038b570df68ccee4275da04b11f

/models/complexity_1000/Applied_Thermodynamics_and_Engineering/CH3/EX3.12/3_12.sce

64f33b51cebad47548b50a4a06e2b01d5166227d

[]

no_license

apelttom/20-semester_PhD_thesis

edc0b55580bae9d364599932cd73cf32509f4b7a

ff28b115fcf5e121525e08021fa0c02b54a8e143

refs/heads/master

2018-12-26T22:03:38.510422

2018-12-14T20:04:11

106,552,276

0

null

UTF-8

Scilab

false

170

sce

3_12.sce

clc; p=15;//bar V=6;//m^3; R=0.287; T=313.5; y=1.4 m=p*V/(R*T); p2=12;//bar T2=T/[(p/p2)^((y-1)/y)]; m2=p2*V*10^5/(R*T2*10^3); disp("mass of air left"); disp("kg",m2)

6e4a85b22da1e7add4622aa0ce372f663e26da8a

598546b56588670efcd591e67deb3578f52ddddc

/btests/3.0.tst

10440399259061d2ef00ee3ec9c83590af617906

[]

no_license

natindo/techpark-HM1

6ae5da7cca55a5306f33fedd9ab4021a0d897cc2

e9a4f25d32b0e802d1749ec2f5d1a250b6e1b2f4

refs/heads/master

2023-08-25T14:35:18.304147

2021-10-13T18:51:42

416,403,554

0

null

UTF-8

Scilab

false

19

tst

3.0.tst

KEYS="3 0" OUT="0"

c187ac0d53a6834c7efed5cf121ddbb6b31575ef

449d555969bfd7befe906877abab098c6e63a0e8

/3809/CH18/EX18.11/EX18_11.sce

041e93433aef5dbc5d380f5dccce6ba1ee5d39cc

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

1,166

sce

EX18_11.sce

//Chapter 18, Example 18.11 clc //Initialisation VCC=10 //voltage R2=3*10**3 //resistance in ohm R1=7*10**3 //resistance in ohm RE=10**3 //resistance in ohm RC=3*10**3 //resistance in ohm VBE=0.7 //base emitter voltage av=1 //small sg voltage gain RE2=2*10**3 //resistance in ohm RC2=4*10**3 //resistance in ohm //Calculation VB=VCC*(R2/(R1+R2)) //Quiescent base voltage VE=VB-VBE //Quiescent emitter voltage IE=VE/RE //Quiescent emitter current VC1=VCC-(IE*RC) //Quiescent collector voltage VB2=VC1 //bias voltage VE2=VB2-VBE //emitter voltage IC2=VE2/RE2 //collector current in ampere VC2=VCC-(IC2*RC2) //collector voltage Av=(-RC/RE)*(-RC2/RE2) //overall gain //Results printf("Quiescent output voltage = %.1f V\n",VC2) printf("Overall Voltage Gain = %d",Av)

39c576933b5f85fe274df351d59ac2e4d2059ce7

449d555969bfd7befe906877abab098c6e63a0e8

/1358/CH1/EX1.9/Example19.sci

d52dbc1295a48253de21c43811ef5e3450bd9caa

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

321

sci

Example19.sci

// Display mode mode(0); // Display warning for floating point exception ieee(1); clear; clc; disp("Turbomachinery Design and Theory,Rama S. R. Gorla and Aijaz A. Khan, Chapter 1, Example 9") //Theoritical Question //Kinetic Energy Equation disp("The Kinetic Energy => k V^2 m ") disp("Where k is a constant")

23722516e694b97e03d16f065b4968291414b004

1b969fbb81566edd3ef2887c98b61d98b380afd4

/Rez/bivariate-lcmsr-post_mi/bfas_co_mvi/~BivLCM-SR-bfas_co_mvi-PLin-VLin.tst

d2dd3f6fffe94855354b776e6003f4ed817f1029

[]

no_license

psdlab/life-in-time-values-and-personality

35fbf5bbe4edd54b429a934caf289fbb0edfefee

7f6f8e9a6c24f29faa02ee9baffbe8ae556e227e

refs/heads/master

2020-03-24T22:08:27.964205

2019-03-04T17:03:26

143,070,821

1

0

null

UTF-8

Scilab

false

11,974

tst

~BivLCM-SR-bfas_co_mvi-PLin-VLin.tst

THE OPTIMIZATION ALGORITHM HAS CHANGED TO THE EM ALGORITHM. ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 1 2 3 4 5 ________ ________ ________ ________ ________ 1 0.290441D+00 2 -0.372267D-02 0.226500D-02 3 -0.265857D-01 0.819752D-03 0.668766D-01 4 0.109980D-02 -0.157259D-03 -0.917013D-03 0.528079D-03 5 0.972053D-03 -0.147599D-03 0.667574D-03 -0.364507D-04 0.301503D-02 6 0.382113D-02 -0.240700D-03 -0.549058D-03 -0.761004D-04 0.485677D-03 7 0.116811D-02 -0.467766D-04 -0.129531D-03 -0.140203D-04 0.107122D-03 8 0.659314D-03 -0.416526D-04 -0.478288D-03 0.851651D-05 0.967195D-04 9 -0.175268D+00 0.113078D-01 0.221050D-01 0.352719D-02 0.761298D-01 10 -0.307256D-01 -0.106188D-01 0.247719D-01 -0.423632D-02 0.135310D+00 11 0.791797D-02 -0.620835D-02 0.161845D-01 -0.211235D-02 -0.518074D-02 12 0.333306D-01 0.751640D-03 -0.540128D-01 0.558869D-02 0.451946D-02 13 0.102314D+00 -0.384237D-02 -0.278662D-01 0.244258D-03 -0.940048D-03 14 -0.153699D-01 0.112323D-02 0.126005D-02 0.148880D-03 -0.233880D-02 15 -0.154745D+01 -0.254005D-01 0.281063D+00 -0.237445D-02 -0.974499D-01 16 -0.330023D-01 -0.624592D-03 -0.542829D-04 0.945640D-03 -0.700363D-03 17 0.886740D-02 0.155792D-03 -0.685701D-03 -0.653348D-04 -0.392506D-03 18 0.387214D+00 0.740428D-02 -0.127130D+00 -0.853851D-03 -0.310704D-01 19 -0.556903D-02 0.173724D-02 0.874015D-02 0.594249D-03 -0.136141D-02 20 -0.706710D-01 0.532013D-02 0.151740D+00 -0.157581D-02 0.145264D-01 21 0.660887D-02 -0.644323D-03 -0.153817D-01 -0.443630D-03 0.141786D-02 22 -0.199885D-02 -0.116646D-03 0.941142D-03 -0.529868D-05 0.970230D-04 23 -0.117486D-02 -0.261937D-04 0.327902D-02 -0.415404D-03 0.160615D-03 24 0.134404D-03 -0.534258D-04 -0.122164D-02 -0.762035D-05 -0.107895D-03 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 6 7 8 9 10 ________ ________ ________ ________ ________ 6 0.587088D-02 7 0.628469D-03 0.351955D-03 8 0.215659D-03 0.886286D-04 0.227283D-02 9 -0.377291D-01 -0.653602D-02 0.462253D-02 0.290928D+02 10 0.319513D-01 0.124992D-02 0.702365D-02 0.199891D+01 0.158861D+02 11 0.331890D-01 0.714307D-02 0.240450D-02 -0.191144D+01 -0.121396D+00 12 0.153342D-01 -0.382095D-04 0.229506D-01 0.321232D+00 0.710234D+00 13 0.444806D-01 0.103784D-01 0.444284D-02 -0.459946D+00 0.340078D+00 14 -0.485385D-03 0.421857D-03 0.231088D-01 -0.431532D-01 0.173160D+00 15 0.147552D-01 -0.879467D-02 -0.172754D-02 -0.771755D+00 -0.675326D+01 16 0.887718D-03 -0.729301D-03 -0.173135D-02 0.439440D+00 -0.331487D-01 17 -0.133259D-03 0.111039D-03 0.115351D-03 -0.971960D-01 -0.407533D-01 18 -0.424439D-01 -0.606863D-02 -0.122426D-01 -0.101868D+01 -0.111460D+01 19 -0.903880D-02 0.155338D-02 -0.854134D-03 0.537421D+00 -0.266156D+00 20 -0.115066D-01 -0.489705D-02 -0.147468D-01 0.242114D+00 0.120047D+00 21 0.897226D-02 -0.150690D-02 0.158069D-02 -0.693913D+00 0.233568D+00 22 -0.178591D-03 -0.528042D-04 -0.333768D-04 0.230469D-01 0.608621D-02 23 0.837313D-03 0.541321D-04 0.859691D-04 0.168881D-01 0.554238D-02 24 -0.355603D-04 0.925624D-05 -0.979919D-04 -0.274947D-02 -0.379066D-02 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 11 12 13 14 15 ________ ________ ________ ________ ________ 11 0.440321D+01 12 -0.438575D+00 0.317982D+01 13 -0.129632D+00 0.251029D+00 0.144929D+01 14 0.677970D-01 0.141960D+00 0.950810D-01 0.998319D+00 15 0.159621D+01 0.201020D+00 -0.537497D+00 0.631648D-01 0.198608D+03 16 -0.531780D-01 0.103170D-01 0.127128D-02 0.199284D-02 0.162788D+01 17 0.101062D-01 0.600060D-03 0.231214D-02 0.288805D-02 -0.991553D+00 18 0.620747D-02 -0.109603D+01 -0.487924D+00 -0.177666D+00 -0.207643D+02 19 0.915710D-01 -0.333197D+00 -0.592279D-01 -0.616271D-03 -0.145051D+01 20 -0.618755D+00 0.858303D-01 -0.309993D+00 -0.344987D+00 -0.101467D+00 21 -0.486043D-01 0.331455D+00 0.273266D-01 0.130421D-02 0.129096D+01 22 -0.876349D-02 0.524166D-02 -0.592195D-03 -0.403886D-03 0.103050D+00 23 0.105260D-02 -0.143297D-01 0.966131D-02 0.670105D-02 -0.897720D-01 24 0.346907D-02 -0.208914D-02 -0.377711D-03 -0.176880D-02 0.435602D-02 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 16 17 18 19 20 ________ ________ ________ ________ ________ 16 0.344639D+00 17 -0.271971D-01 0.119945D-01 18 -0.211417D+00 0.110616D+00 0.268634D+02 19 -0.635215D-01 0.882656D-02 0.616472D+00 0.687268D+00 20 0.152434D-01 -0.175071D-01 -0.147442D+01 -0.119793D+00 0.124258D+02 21 0.104993D-01 -0.465197D-02 -0.264040D+00 -0.641458D+00 0.362026D-01 22 0.279146D-02 -0.110744D-02 -0.135237D+00 -0.457699D-02 0.785933D-02 23 0.875119D-03 -0.237200D-03 0.309319D-02 -0.143530D-02 0.115668D+00 24 -0.441335D-03 0.151073D-03 0.385323D-02 0.639370D-03 -0.613221D-01 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 21 22 23 24 ________ ________ ________ ________ 21 0.785531D+00 22 -0.385509D-02 0.160628D-02 23 -0.106314D-01 0.710048D-03 0.210837D-01 24 0.133637D-02 -0.599631D-04 -0.195651D-02 0.673761D-03 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 1 2 3 4 5 ________ ________ ________ ________ ________ 1 1.000 2 -0.145 1.000 3 -0.191 0.067 1.000 4 0.089 -0.144 -0.154 1.000 5 0.033 -0.056 0.047 -0.029 1.000 6 0.093 -0.066 -0.028 -0.043 0.115 7 0.116 -0.052 -0.027 -0.033 0.104 8 0.026 -0.018 -0.039 0.008 0.037 9 -0.060 0.044 0.016 0.028 0.257 10 -0.014 -0.056 0.024 -0.046 0.618 11 0.007 -0.062 0.030 -0.044 -0.045 12 0.035 0.009 -0.117 0.136 0.046 13 0.158 -0.067 -0.090 0.009 -0.014 14 -0.029 0.024 0.005 0.006 -0.043 15 -0.204 -0.038 0.077 -0.007 -0.126 16 -0.104 -0.022 0.000 0.070 -0.022 17 0.150 0.030 -0.024 -0.026 -0.065 18 0.139 0.030 -0.095 -0.007 -0.109 19 -0.012 0.044 0.041 0.031 -0.030 20 -0.037 0.032 0.166 -0.019 0.075 21 0.014 -0.015 -0.067 -0.022 0.029 22 -0.093 -0.061 0.091 -0.006 0.044 23 -0.015 -0.004 0.087 -0.124 0.020 24 0.010 -0.043 -0.182 -0.013 -0.076 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 6 7 8 9 10 ________ ________ ________ ________ ________ 6 1.000 7 0.437 1.000 8 0.059 0.099 1.000 9 -0.091 -0.065 0.018 1.000 10 0.105 0.017 0.037 0.093 1.000 11 0.206 0.181 0.024 -0.169 -0.015 12 0.112 -0.001 0.270 0.033 0.100 13 0.482 0.460 0.077 -0.071 0.071 14 -0.006 0.023 0.485 -0.008 0.043 15 0.014 -0.033 -0.003 -0.010 -0.120 16 0.020 -0.066 -0.062 0.139 -0.014 17 -0.016 0.054 0.022 -0.165 -0.093 18 -0.107 -0.062 -0.050 -0.036 -0.054 19 -0.142 0.100 -0.022 0.120 -0.081 20 -0.043 -0.074 -0.088 0.013 0.009 21 0.132 -0.091 0.037 -0.145 0.066 22 -0.058 -0.070 -0.017 0.107 0.038 23 0.075 0.020 0.012 0.022 0.010 24 -0.018 0.019 -0.079 -0.020 -0.037 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 11 12 13 14 15 ________ ________ ________ ________ ________ 11 1.000 12 -0.117 1.000 13 -0.051 0.117 1.000 14 0.032 0.080 0.079 1.000 15 0.054 0.008 -0.032 0.004 1.000 16 -0.043 0.010 0.002 0.003 0.197 17 0.044 0.003 0.018 0.026 -0.642 18 0.001 -0.119 -0.078 -0.034 -0.284 19 0.053 -0.225 -0.059 -0.001 -0.124 20 -0.084 0.014 -0.073 -0.098 -0.002 21 -0.026 0.210 0.026 0.001 0.103 22 -0.104 0.073 -0.012 -0.010 0.182 23 0.003 -0.055 0.055 0.046 -0.044 24 0.064 -0.045 -0.012 -0.068 0.012 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 16 17 18 19 20 ________ ________ ________ ________ ________ 16 1.000 17 -0.423 1.000 18 -0.069 0.195 1.000 19 -0.131 0.097 0.143 1.000 20 0.007 -0.045 -0.081 -0.041 1.000 21 0.020 -0.048 -0.057 -0.873 0.012 22 0.119 -0.252 -0.651 -0.138 0.056 23 0.010 -0.015 0.004 -0.012 0.226 24 -0.029 0.053 0.029 0.030 -0.670 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 21 22 23 24 ________ ________ ________ ________ 21 1.000 22 -0.109 1.000 23 -0.083 0.122 1.000 24 0.058 -0.058 -0.519 1.000

1c8fdc34e1d373e7a68df1937a1b6b4aa64dc3a2

b26cbe6bc3e201f030705aaf9eb82da94def231f

/tests/Morisita_RP-027.tst

862410e908c0c1ec64a787be24ee6d84e3b03d5b

[]

no_license

RP-pbm/Recurrence-plot

f86c5cd85460661b01a609f8f4281d2cda6b4e07

b5da95f9b30c1a924a002102219bf0a2ad47df2c

refs/heads/master

2022-07-24T12:11:34.163543

2022-07-09T19:32:43

92,934,698

0

null

UTF-8

Scilab

false

31

tst

Morisita_RP-027.tst

../inputs/pops-21x2-sqrt-02.ssv

1fb51bd1b57cc7c4e45ce688bd7b24894afefaee

8217f7986187902617ad1bf89cb789618a90dd0a

/browsable_source/2.5/Unix-Windows/scilab-2.5/tests/examples/eqiir.man.tst

0a8fbabbcc3ba9918f9f846c0756f3769b6d19c9

[ "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]

permissive

clg55/Scilab-Workbench

4ebc01d2daea5026ad07fbfc53e16d4b29179502

9f8fd29c7f2a98100fa9aed8b58f6768d24a1875

refs/heads/master

2023-05-31T04:06:22.931111

2022-09-13T14:41:51

258,270,193

0

1

null

UTF-8

Scilab

false

146

tst

eqiir.man.tst

clear;lines(0); [cells,fact,zzeros,zpoles]=... eqiir('lp','ellip',[2*%pi/10,4*%pi/10],0.02,0.001) transfer=fact*poly(zzeros,'z')/poly(zpoles,'z')

8e0a223ba7ea5404945aeb105a033af499ec9880

449d555969bfd7befe906877abab098c6e63a0e8

/3557/CH20/EX20.4/Ex20_4.sce

b2d908ec2ad15e340c27768924e34aee88092e0f

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

173

sce

Ex20_4.sce

//Example20.4// Ek=(-7112);//eV //the innermost electron orbital shell El=(-708);//ev //the innermost electron next shell Eka=abs(Ek-El) mprintf("Eka = %i eV",Eka)

ceb1ee947f561cb5b4db392a8418709f5f8af3bf

449d555969bfd7befe906877abab098c6e63a0e8

/1979/CH9/EX9.9/Ex9_9.sce

13b06996a69a0bcad720b77a959e622d74ea638e

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

675

sce

Ex9_9.sce

//chapter-9 page 412 example 9.9 //============================================================================== clc; clear; //For an IMPATT diode Lp=0.5*10^(-9);//Inductance in Henry Cj=0.5*10^(-12);//Capacitance in Farad Ip=0.8;//RF peak current in A Rl=2;//Load Resistance in ohms Vbd=100;//Breakdown Voltage in V Ib=0.1;//dc Bias current in A //CALCULATION f=(1/(2*(%pi)*sqrt(Lp*Cj)))/10^9;//Resonant Frequency in GHz n=((Rl*Ip^2)/(2*Vbd*Ib))*100;//Efficiency in Percentage //OUTPUT mprintf('\nResonant Frequency is f=%2.0f GHz \nEfficiency is n=%1.1f percentage',f,n); //=========================END OF PROGRAM===============================

317f661fb2bbca05cf91e7a0f34ebde3ab2f8c93

449d555969bfd7befe906877abab098c6e63a0e8

/3751/CH16/EX16.9/Ex16_9.sce

b1562f85b5489669159686609a794891967fb01e

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

1,091

sce

Ex16_9.sce

//Fluid Systems - By Shiv Kumar //Chapter 16- Hydraulic Power and Its Transmissions //Example 16.9 //To Deternmine the Diameter of the ram. clc clear //Given Data:- d=125; //Diameter of Pipe, mm l=2; //Lenght of Pipe, km P=35; //Power Transmitted, kW W=1250; //Load on ram, kN loss_per=3; //Percentage of Power Loss due to friction f_dash=0.04; //Pipe Friction Factor //Data Used:- rho=1000; //Density of Water, kg/m^3 g=9.81; //Acceleration due to gravity, m/s^2 //Computations:- Delta_P=loss_per/100*P*1000; //Power Loss due to friction , W //By Darcy's Formula, hf_by_V2=f_dash*(l*1000)/(2*g*d/1000); //hf/V^2 QbyV=(%pi/4)*(d/1000)^2; //Q/V V=( Delta_P/(rho*g*QbyV*hf_by_V2))^(1/3); //m/s Q=QbyV*V; //m^3/s p=P*1000/Q; //N/m^2 D=sqrt(W*1000/(p*%pi/4))*1000; //mm //Result:- printf("The Diameter of ram, D=%.2f mm",D) //The answer vary due to round off error

079c74c3ea60affbcf682e2284cd17e8a4265844

449d555969bfd7befe906877abab098c6e63a0e8

/1964/CH14/EX14.3/ex14_3.sce

8e30f1fc21fa19ab253250f17fba13e15dc8b032

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

626

sce

ex14_3.sce

//Chapter-14, Example 14.3, Page 458 //============================================================================= clc clear //INPUT DATA A=50;//gain of inverting amplifier Vid=20*10^-3;//voltage in V SR=0.5;//slewrate in V/us----->SR=(2*%pi*f*Vm)/(10^6) //CALCULATIONS Vm=A*(Vid);//maximum output voltage in V fmax=(SR*10^6)/(2*%pi*Vm);//frequency in hz mprintf("thus maximum frequency of the input for which undistorted output is obtained is %g hz",fmax); //=================================END OF PROGRAM=======================================================================================================

c9911d08d7fcfebe7eec93ee431a88bf6d59ec75

e04f3a1f9e98fd043a65910a1d4e52bdfff0d6e4

/New LSTMAttn Model/.data/form-split/GOLD-TEST/mao.tst

cff93607341061772ad578c201b51b37f06dd22d

[]

no_license

davidgu13/Lemma-vs-Form-Splits

c154f1c0c7b84ba5b325b17507012d41b9ad5cfe

3cce087f756420523f5a14234d02482452a7bfa5

refs/heads/master

2023-08-01T16:15:52.417307

2021-09-14T20:19:28

395,023,433

3

0

null

UTF-8

Scilab

false

825

tst

mao.tst

mahara mahara V;ACT tahi tahia V;PASS mahara maharatia V;PASS whāngai whāngai V;ACT momotu motukia V;PASS hiki hiki V;ACT mutu mutua V;PASS aroha aroha V;ACT mihi mihi V;ACT tomo tomokia V;PASS kī kī V;ACT ako ako V;ACT pātai pātaitia V;PASS tūtaki tūtakitia V;PASS motu motukia V;PASS eke eke V;ACT hora hora V;ACT tuhituhi tuhituhi V;ACT oho ohokia V;PASS manaaki manaakitia V;PASS rongo rongo V;ACT hemo hemo V;ACT parai parai V;ACT keri keria V;PASS ruruku rurukutia V;PASS hoe hoea V;PASS tunu tunua V;PASS pā pā V;ACT ruku rukuhia V;PASS titiro tirohia V;PASS kau kau V;ACT tupu tupuria V;PASS kutētē kutētētia V;PASS pīrangi pīrangi V;ACT hiahia hiahiatia V;PASS pī pīhia V;PASS tahu tahuna V;PASS hīkoi hīkoitia V;PASS hono hono V;ACT hamu hamua V;PASS paki paki V;ACT wareware warewaretia V;PASS

ec6a66f56b05604a5dc96958152cca136b6def8b

f542bc49c4d04b47d19c88e7c89d5db60922e34e

/PresentationFiles_Subjects/CONT/GF38CPK/ATWM1_Working_Memory_MEG_GF38CPK_Session1/ATWM1_Working_Memory_MEG_Salient_Uncued_Run1.sce

fc0fa5b3a2ad434559bbc67f165b95c70e93022e

[]

no_license

atwm1/Presentation

65c674180f731f050aad33beefffb9ba0caa6688

9732a004ca091b184b670c56c55f538ff6600c08

refs/heads/master

2020-04-15T14:04:41.900640

2020-02-14T16:10:11

56,771,016

0

1

null

UTF-8

Scilab

false

48,405

sce

ATWM1_Working_Memory_MEG_Salient_Uncued_Run1.sce

# ATWM1 MEG Experiment scenario = "ATWM1_Working_Memory_MEG_salient_uncued_run1"; #scenario_type = fMRI; # Fuer Scanner #scenario_type = fMRI_emulation; # Zum Testen scenario_type = trials; # for MEG #scan_period = 2000; # TR #pulses_per_scan = 1; #pulse_code = 1; pulse_width=6; default_monitor_sounds = false; active_buttons = 2; response_matching = simple_matching; button_codes = 10, 20; default_font_size = 36; default_font = "Arial"; default_background_color = 0 ,0 ,0 ; write_codes=true; # for MEG only begin; #Picture definitions box { height = 382; width = 382; color = 0, 0, 0;} frame1; box { height = 369; width = 369; color = 255, 255, 255;} frame2; box { height = 30; width = 4; color = 0, 0, 0;} fix1; box { height = 4; width = 30; color = 0, 0, 0;} fix2; box { height = 30; width = 4; color = 255, 0, 0;} fix3; box { height = 4; width = 30; color = 255, 0, 0;} fix4; box { height = 369; width = 369; color = 42, 42, 42;} background; TEMPLATE "StimuliDeclaration.tem" {}; trial { sound sound_incorrect; time = 0; duration = 1; } wrong; trial { sound sound_correct; time = 0; duration = 1; } right; trial { sound sound_no_response; time = 0; duration = 1; } miss; # Start of experiment (MEG only) - sync with CTF software trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; } expStart; time = 0; duration = 1000; code = "ExpStart"; port_code = 80; }; # baselinePre (at the beginning of the session) trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; }default; time = 0; duration = 10000; #mri_pulse = 1; code = "BaselinePre"; port_code = 91; }; TEMPLATE "ATWM1_Working_Memory_MEG.tem" { trigger_encoding trigger_retrieval cue_time preparation_time encoding_time single_stimulus_presentation_time delay_time retrieval_time intertrial_interval alerting_cross stim_enc1 stim_enc2 stim_enc3 stim_enc4 stim_enc_alt1 stim_enc_alt2 stim_enc_alt3 stim_enc_alt4 trial_code stim_retr1 stim_retr2 stim_retr3 stim_retr4 stim_cue1 stim_cue2 stim_cue3 stim_cue4 fixationcross_cued retr_code the_target_button posX1 posY1 posX2 posY2 posX3 posY3 posX4 posY4; 42 62 292 292 399 125 1892 2992 1892 fixation_cross gabor_018 gabor_035 gabor_058 gabor_102 gabor_018 gabor_035_alt gabor_058_alt gabor_102 "1_1_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_1900_gabor_patch_orientation_018_035_058_102_target_position_2_3_retrieval_position_2" gabor_circ gabor_035_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_1_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_035_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2192 2992 2292 fixation_cross gabor_175 gabor_019 gabor_109 gabor_129 gabor_175_alt gabor_019 gabor_109_alt gabor_129 "1_2_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2200_3000_2300_gabor_patch_orientation_175_019_109_129_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_109_framed gabor_circ blank blank blank blank fixation_cross_white "1_2_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_109_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1742 2992 2492 fixation_cross gabor_075 gabor_117 gabor_003 gabor_051 gabor_075 gabor_117_alt gabor_003 gabor_051_alt "1_3_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2500_gabor_patch_orientation_075_117_003_051_target_position_2_4_retrieval_position_2" gabor_circ gabor_117_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_3_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_117_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2092 2992 2292 fixation_cross gabor_174 gabor_134 gabor_007 gabor_048 gabor_174_alt gabor_134_alt gabor_007 gabor_048 "1_4_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2100_3000_2300_gabor_patch_orientation_174_134_007_048_target_position_1_2_retrieval_position_2" gabor_circ gabor_085_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_4_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_085_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1992 2992 2192 fixation_cross gabor_090 gabor_049 gabor_113 gabor_004 gabor_090_alt gabor_049 gabor_113_alt gabor_004 "1_5_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_2200_gabor_patch_orientation_090_049_113_004_target_position_1_3_retrieval_position_1" gabor_139_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_5_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_139_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2242 2992 2392 fixation_cross gabor_027 gabor_115 gabor_002 gabor_092 gabor_027 gabor_115_alt gabor_002_alt gabor_092 "1_6_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2400_gabor_patch_orientation_027_115_002_092_target_position_2_3_retrieval_position_2" gabor_circ gabor_115_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_6_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_115_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1892 2992 1892 fixation_cross gabor_073 gabor_111 gabor_041 gabor_096 gabor_073 gabor_111_alt gabor_041_alt gabor_096 "1_7_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_1900_gabor_patch_orientation_073_111_041_096_target_position_2_3_retrieval_position_2" gabor_circ gabor_157_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_7_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_157_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 2092 2992 2142 fixation_cross gabor_109 gabor_151 gabor_071 gabor_040 gabor_109 gabor_151_alt gabor_071_alt gabor_040 "1_8_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_300_300_399_2100_3000_2150_gabor_patch_orientation_109_151_071_040_target_position_2_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_090_framed blank blank blank blank fixation_cross_white "1_8_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_090_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2042 2992 2142 fixation_cross gabor_078 gabor_155 gabor_099 gabor_042 gabor_078 gabor_155_alt gabor_099_alt gabor_042 "1_9_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2150_gabor_patch_orientation_078_155_099_042_target_position_2_3_retrieval_position_2" gabor_circ gabor_020_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_9_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_020_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1792 2992 2242 fixation_cross gabor_022 gabor_167 gabor_096 gabor_079 gabor_022 gabor_167 gabor_096_alt gabor_079_alt "1_10_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2250_gabor_patch_orientation_022_167_096_079_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_096_framed gabor_circ blank blank blank blank fixation_cross_white "1_10_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_096_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 1942 2992 1942 fixation_cross gabor_041 gabor_056 gabor_179 gabor_026 gabor_041_alt gabor_056 gabor_179 gabor_026_alt "1_11_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_300_300_399_1950_3000_1950_gabor_patch_orientation_041_056_179_026_target_position_1_4_retrieval_position_2" gabor_circ gabor_056_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_11_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_056_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2142 2992 2042 fixation_cross gabor_133 gabor_164 gabor_009 gabor_027 gabor_133 gabor_164 gabor_009_alt gabor_027_alt "1_12_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2050_gabor_patch_orientation_133_164_009_027_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_055_framed gabor_circ blank blank blank blank fixation_cross_white "1_12_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_055_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1842 2992 2542 fixation_cross gabor_168 gabor_062 gabor_027 gabor_046 gabor_168_alt gabor_062_alt gabor_027 gabor_046 "1_13_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2550_gabor_patch_orientation_168_062_027_046_target_position_1_2_retrieval_position_2" gabor_circ gabor_062_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_13_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_062_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1892 2992 1992 fixation_cross gabor_128 gabor_162 gabor_084 gabor_056 gabor_128 gabor_162_alt gabor_084 gabor_056_alt "1_14_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2000_gabor_patch_orientation_128_162_084_056_target_position_2_4_retrieval_position_2" gabor_circ gabor_022_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_14_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_022_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1942 2992 2092 fixation_cross gabor_089 gabor_006 gabor_170 gabor_040 gabor_089 gabor_006_alt gabor_170_alt gabor_040 "1_15_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_2100_gabor_patch_orientation_089_006_170_040_target_position_2_3_retrieval_position_2" gabor_circ gabor_146_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_15_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_146_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1992 2992 2142 fixation_cross gabor_097 gabor_072 gabor_126 gabor_054 gabor_097 gabor_072 gabor_126_alt gabor_054_alt "1_16_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2150_gabor_patch_orientation_097_072_126_054_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_054_framed blank blank blank blank fixation_cross_white "1_16_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_054_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2042 2992 2192 fixation_cross gabor_007 gabor_049 gabor_087 gabor_164 gabor_007 gabor_049 gabor_087_alt gabor_164_alt "1_17_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_2200_gabor_patch_orientation_007_049_087_164_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_087_framed gabor_circ blank blank blank blank fixation_cross_white "1_17_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_087_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 2142 2992 2142 fixation_cross gabor_005 gabor_021 gabor_131 gabor_047 gabor_005_alt gabor_021_alt gabor_131 gabor_047 "1_18_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_300_300_399_2150_3000_2150_gabor_patch_orientation_005_021_131_047_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_131_framed gabor_circ blank blank blank blank fixation_cross_white "1_18_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_131_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1942 2992 1892 fixation_cross gabor_134 gabor_047 gabor_021 gabor_154 gabor_134_alt gabor_047 gabor_021_alt gabor_154 "1_19_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_1900_gabor_patch_orientation_134_047_021_154_target_position_1_3_retrieval_position_1" gabor_134_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_19_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_134_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2142 2992 2592 fixation_cross gabor_002 gabor_122 gabor_180 gabor_057 gabor_002_alt gabor_122_alt gabor_180 gabor_057 "1_20_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2600_gabor_patch_orientation_002_122_180_057_target_position_1_2_retrieval_position_2" gabor_circ gabor_074_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_20_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_074_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1892 2992 2042 fixation_cross gabor_095 gabor_172 gabor_156 gabor_035 gabor_095_alt gabor_172 gabor_156_alt gabor_035 "1_21_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2050_gabor_patch_orientation_095_172_156_035_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_156_framed gabor_circ blank blank blank blank fixation_cross_white "1_21_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_156_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1842 2992 1892 fixation_cross gabor_025 gabor_047 gabor_171 gabor_111 gabor_025 gabor_047_alt gabor_171_alt gabor_111 "1_22_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_1900_gabor_patch_orientation_025_047_171_111_target_position_2_3_retrieval_position_2" gabor_circ gabor_001_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_22_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_001_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1842 2992 1992 fixation_cross gabor_140 gabor_064 gabor_025 gabor_092 gabor_140 gabor_064 gabor_025_alt gabor_092_alt "1_23_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_300_300_399_1850_3000_2000_gabor_patch_orientation_140_064_025_092_target_position_3_4_retrieval_position_1" gabor_005_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_23_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_005_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2042 2992 2342 fixation_cross gabor_039 gabor_161 gabor_178 gabor_023 gabor_039 gabor_161 gabor_178_alt gabor_023_alt "1_24_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2350_gabor_patch_orientation_039_161_178_023_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_129_framed gabor_circ blank blank blank blank fixation_cross_white "1_24_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_129_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1992 2992 2192 fixation_cross gabor_054 gabor_023 gabor_087 gabor_038 gabor_054 gabor_023_alt gabor_087 gabor_038_alt "1_25_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2200_gabor_patch_orientation_054_023_087_038_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_038_framed blank blank blank blank fixation_cross_white "1_25_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_038_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1742 2992 2092 fixation_cross gabor_054 gabor_006 gabor_113 gabor_035 gabor_054 gabor_006_alt gabor_113_alt gabor_035 "1_26_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2100_gabor_patch_orientation_054_006_113_035_target_position_2_3_retrieval_position_2" gabor_circ gabor_144_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_26_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_144_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 2192 2992 1992 fixation_cross gabor_030 gabor_088 gabor_172 gabor_066 gabor_030_alt gabor_088 gabor_172_alt gabor_066 "1_27_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_300_300_399_2200_3000_2000_gabor_patch_orientation_030_088_172_066_target_position_1_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_115_framed blank blank blank blank fixation_cross_white "1_27_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_115_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1792 2992 2392 fixation_cross gabor_083 gabor_063 gabor_100 gabor_023 gabor_083 gabor_063 gabor_100_alt gabor_023_alt "1_28_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2400_gabor_patch_orientation_083_063_100_023_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_145_framed gabor_circ blank blank blank blank fixation_cross_white "1_28_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_145_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1792 2992 2492 fixation_cross gabor_095 gabor_154 gabor_122 gabor_074 gabor_095_alt gabor_154_alt gabor_122 gabor_074 "1_29_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2500_gabor_patch_orientation_095_154_122_074_target_position_1_2_retrieval_position_1" gabor_047_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_29_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_047_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2042 2992 1892 fixation_cross gabor_032 gabor_138 gabor_108 gabor_051 gabor_032 gabor_138 gabor_108_alt gabor_051_alt "1_30_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_1900_gabor_patch_orientation_032_138_108_051_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_002_framed blank blank blank blank fixation_cross_white "1_30_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_002_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1842 2992 2242 fixation_cross gabor_175 gabor_039 gabor_012 gabor_102 gabor_175_alt gabor_039 gabor_012_alt gabor_102 "1_31_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2250_gabor_patch_orientation_175_039_012_102_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_057_framed gabor_circ blank blank blank blank fixation_cross_white "1_31_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_057_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1992 2992 2542 fixation_cross gabor_061 gabor_011 gabor_045 gabor_119 gabor_061_alt gabor_011 gabor_045_alt gabor_119 "1_32_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2550_gabor_patch_orientation_061_011_045_119_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_045_framed gabor_circ blank blank blank blank fixation_cross_white "1_32_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_045_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 1942 2992 2492 fixation_cross gabor_094 gabor_158 gabor_077 gabor_010 gabor_094 gabor_158_alt gabor_077 gabor_010_alt "1_33_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_300_300_399_1950_3000_2500_gabor_patch_orientation_094_158_077_010_target_position_2_4_retrieval_position_3" gabor_circ gabor_circ gabor_077_framed gabor_circ blank blank blank blank fixation_cross_white "1_33_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_077_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2142 2992 2342 fixation_cross gabor_152 gabor_002 gabor_071 gabor_130 gabor_152_alt gabor_002 gabor_071_alt gabor_130 "1_34_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_2350_gabor_patch_orientation_152_002_071_130_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_071_framed gabor_circ blank blank blank blank fixation_cross_white "1_34_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_071_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1842 2992 2042 fixation_cross gabor_019 gabor_105 gabor_146 gabor_039 gabor_019_alt gabor_105 gabor_146_alt gabor_039 "1_35_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2050_gabor_patch_orientation_019_105_146_039_target_position_1_3_retrieval_position_1" gabor_019_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_35_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_019_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1992 2992 2092 fixation_cross gabor_002 gabor_088 gabor_128 gabor_055 gabor_002 gabor_088_alt gabor_128 gabor_055_alt "1_36_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_300_300_399_2000_3000_2100_gabor_patch_orientation_002_088_128_055_target_position_2_4_retrieval_position_3" gabor_circ gabor_circ gabor_177_framed gabor_circ blank blank blank blank fixation_cross_white "1_36_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_177_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1742 2992 1992 fixation_cross gabor_177 gabor_131 gabor_072 gabor_003 gabor_177 gabor_131 gabor_072_alt gabor_003_alt "1_37_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2000_gabor_patch_orientation_177_131_072_003_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_003_framed blank blank blank blank fixation_cross_white "1_37_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_003_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2192 2992 2542 fixation_cross gabor_113 gabor_180 gabor_005 gabor_146 gabor_113 gabor_180_alt gabor_005_alt gabor_146 "1_38_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2550_gabor_patch_orientation_113_180_005_146_target_position_2_3_retrieval_position_2" gabor_circ gabor_040_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_38_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_040_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1792 2992 1942 fixation_cross gabor_178 gabor_091 gabor_065 gabor_127 gabor_178 gabor_091_alt gabor_065 gabor_127_alt "1_39_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_300_300_399_1800_3000_1950_gabor_patch_orientation_178_091_065_127_target_position_2_4_retrieval_position_1" gabor_038_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_39_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_038_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1842 2992 2592 fixation_cross gabor_167 gabor_013 gabor_142 gabor_054 gabor_167_alt gabor_013 gabor_142_alt gabor_054 "1_40_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2600_gabor_patch_orientation_167_013_142_054_target_position_1_3_retrieval_position_1" gabor_167_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_40_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_167_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2142 2992 2092 fixation_cross gabor_005 gabor_072 gabor_110 gabor_090 gabor_005_alt gabor_072 gabor_110 gabor_090_alt "1_41_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2100_gabor_patch_orientation_005_072_110_090_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_139_framed blank blank blank blank fixation_cross_white "1_41_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_139_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1892 2992 2242 fixation_cross gabor_139 gabor_058 gabor_168 gabor_014 gabor_139 gabor_058 gabor_168_alt gabor_014_alt "1_42_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2250_gabor_patch_orientation_139_058_168_014_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_032_framed gabor_circ blank blank blank blank fixation_cross_white "1_42_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_032_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1742 2992 2592 fixation_cross gabor_141 gabor_122 gabor_173 gabor_061 gabor_141_alt gabor_122 gabor_173_alt gabor_061 "1_43_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2600_gabor_patch_orientation_141_122_173_061_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_173_framed gabor_circ blank blank blank blank fixation_cross_white "1_43_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_173_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2092 2992 2292 fixation_cross gabor_065 gabor_047 gabor_031 gabor_112 gabor_065 gabor_047_alt gabor_031_alt gabor_112 "1_44_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2300_gabor_patch_orientation_065_047_031_112_target_position_2_3_retrieval_position_2" gabor_circ gabor_047_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_44_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_047_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 1742 2992 2192 fixation_cross gabor_106 gabor_054 gabor_023 gabor_071 gabor_106_alt gabor_054_alt gabor_023 gabor_071 "1_45_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_300_300_399_1750_3000_2200_gabor_patch_orientation_106_054_023_071_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_023_framed gabor_circ blank blank blank blank fixation_cross_white "1_45_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_023_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2242 2992 2192 fixation_cross gabor_168 gabor_079 gabor_113 gabor_098 gabor_168_alt gabor_079 gabor_113 gabor_098_alt "1_46_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2200_gabor_patch_orientation_168_079_113_098_target_position_1_4_retrieval_position_1" gabor_168_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_46_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_168_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1842 2992 2242 fixation_cross gabor_015 gabor_105 gabor_175 gabor_133 gabor_015_alt gabor_105_alt gabor_175 gabor_133 "1_47_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2250_gabor_patch_orientation_015_105_175_133_target_position_1_2_retrieval_position_2" gabor_circ gabor_055_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_47_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_055_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2242 2992 2092 fixation_cross gabor_019 gabor_046 gabor_133 gabor_165 gabor_019 gabor_046_alt gabor_133 gabor_165_alt "1_48_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2100_gabor_patch_orientation_019_046_133_165_target_position_2_4_retrieval_position_2" gabor_circ gabor_093_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_48_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_093_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2092 2992 2242 fixation_cross gabor_004 gabor_082 gabor_136 gabor_160 gabor_004_alt gabor_082 gabor_136_alt gabor_160 "1_49_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2250_gabor_patch_orientation_004_082_136_160_target_position_1_3_retrieval_position_1" gabor_004_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_49_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_004_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 2042 2992 1942 fixation_cross gabor_138 gabor_176 gabor_157 gabor_091 gabor_138_alt gabor_176 gabor_157 gabor_091_alt "1_50_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_300_300_399_2050_3000_1950_gabor_patch_orientation_138_176_157_091_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_157_framed gabor_circ blank blank blank blank fixation_cross_white "1_50_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_157_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2192 2992 2292 fixation_cross gabor_003 gabor_161 gabor_071 gabor_049 gabor_003_alt gabor_161_alt gabor_071 gabor_049 "1_51_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2200_3000_2300_gabor_patch_orientation_003_161_071_049_target_position_1_2_retrieval_position_2" gabor_circ gabor_161_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_51_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_161_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2092 2992 1942 fixation_cross gabor_169 gabor_003 gabor_116 gabor_031 gabor_169_alt gabor_003_alt gabor_116 gabor_031 "1_52_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_1950_gabor_patch_orientation_169_003_116_031_target_position_1_2_retrieval_position_2" gabor_circ gabor_003_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_52_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_003_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1992 2992 2342 fixation_cross gabor_066 gabor_138 gabor_101 gabor_154 gabor_066_alt gabor_138 gabor_101_alt gabor_154 "1_53_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_2350_gabor_patch_orientation_066_138_101_154_target_position_1_3_retrieval_position_1" gabor_018_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_53_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_018_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2242 2992 2542 fixation_cross gabor_132 gabor_024 gabor_042 gabor_069 gabor_132 gabor_024 gabor_042_alt gabor_069_alt "1_54_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2550_gabor_patch_orientation_132_024_042_069_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_042_framed gabor_circ blank blank blank blank fixation_cross_white "1_54_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_042_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2192 2992 2442 fixation_cross gabor_038 gabor_083 gabor_018 gabor_098 gabor_038_alt gabor_083_alt gabor_018 gabor_098 "1_55_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2450_gabor_patch_orientation_038_083_018_098_target_position_1_2_retrieval_position_1" gabor_173_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_55_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_173_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1942 2992 2042 fixation_cross gabor_130 gabor_157 gabor_016 gabor_101 gabor_130_alt gabor_157 gabor_016_alt gabor_101 "1_56_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_300_300_399_1950_3000_2050_gabor_patch_orientation_130_157_016_101_target_position_1_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_051_framed blank blank blank blank fixation_cross_white "1_56_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_051_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1742 2992 2442 fixation_cross gabor_107 gabor_089 gabor_024 gabor_147 gabor_107_alt gabor_089 gabor_024 gabor_147_alt "1_57_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2450_gabor_patch_orientation_107_089_024_147_target_position_1_4_retrieval_position_1" gabor_061_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_57_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_061_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1892 2992 2442 fixation_cross gabor_133 gabor_111 gabor_178 gabor_026 gabor_133_alt gabor_111_alt gabor_178 gabor_026 "1_58_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2450_gabor_patch_orientation_133_111_178_026_target_position_1_2_retrieval_position_2" gabor_circ gabor_064_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_58_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_064_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 1942 2992 2292 fixation_cross gabor_177 gabor_115 gabor_137 gabor_008 gabor_177 gabor_115 gabor_137_alt gabor_008_alt "1_59_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_300_300_399_1950_3000_2300_gabor_patch_orientation_177_115_137_008_target_position_3_4_retrieval_position_2" gabor_circ gabor_115_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_59_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_115_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2092 2992 2592 fixation_cross gabor_080 gabor_143 gabor_122 gabor_057 gabor_080 gabor_143 gabor_122_alt gabor_057_alt "1_60_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2600_gabor_patch_orientation_080_143_122_057_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_122_framed gabor_circ blank blank blank blank fixation_cross_white "1_60_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_122_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2142 2992 2392 fixation_cross gabor_076 gabor_024 gabor_107 gabor_056 gabor_076_alt gabor_024_alt gabor_107 gabor_056 "1_61_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2400_gabor_patch_orientation_076_024_107_056_target_position_1_2_retrieval_position_2" gabor_circ gabor_163_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_61_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_163_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2242 2992 2342 fixation_cross gabor_022 gabor_039 gabor_162 gabor_110 gabor_022 gabor_039_alt gabor_162 gabor_110_alt "1_62_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2350_gabor_patch_orientation_022_039_162_110_target_position_2_4_retrieval_position_2" gabor_circ gabor_039_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_62_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_039_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1792 2992 1942 fixation_cross gabor_031 gabor_005 gabor_090 gabor_071 gabor_031_alt gabor_005 gabor_090_alt gabor_071 "1_63_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_1950_gabor_patch_orientation_031_005_090_071_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_090_framed gabor_circ blank blank blank blank fixation_cross_white "1_63_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_090_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1742 2992 2342 fixation_cross gabor_147 gabor_103 gabor_020 gabor_129 gabor_147 gabor_103_alt gabor_020_alt gabor_129 "1_64_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2350_gabor_patch_orientation_147_103_020_129_target_position_2_3_retrieval_position_2" gabor_circ gabor_057_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_64_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_057_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1792 2992 1992 fixation_cross gabor_013 gabor_045 gabor_153 gabor_133 gabor_013 gabor_045_alt gabor_153_alt gabor_133 "1_65_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2000_gabor_patch_orientation_013_045_153_133_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_103_framed gabor_circ blank blank blank blank fixation_cross_white "1_65_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_103_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2192 2992 2392 fixation_cross gabor_171 gabor_127 gabor_083 gabor_143 gabor_171 gabor_127 gabor_083_alt gabor_143_alt "1_66_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_2200_3000_2400_gabor_patch_orientation_171_127_083_143_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_083_framed gabor_circ blank blank blank blank fixation_cross_white "1_66_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_083_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 2042 2992 2042 fixation_cross gabor_048 gabor_090 gabor_112 gabor_170 gabor_048 gabor_090 gabor_112_alt gabor_170_alt "1_67_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_300_300_399_2050_3000_2050_gabor_patch_orientation_048_090_112_170_target_position_3_4_retrieval_position_1" gabor_048_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_67_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_048_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1792 2992 2142 fixation_cross gabor_162 gabor_004 gabor_036 gabor_090 gabor_162_alt gabor_004 gabor_036 gabor_090_alt "1_68_Encoding_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2150_gabor_patch_orientation_162_004_036_090_target_position_1_4_retrieval_position_1" gabor_162_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_68_Retrieval_Working_Memory_MEG_P4_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_162_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1892 2992 2442 fixation_cross gabor_029 gabor_115 gabor_084 gabor_140 gabor_029 gabor_115 gabor_084_alt gabor_140_alt "1_69_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_300_300_399_1900_3000_2450_gabor_patch_orientation_029_115_084_140_target_position_3_4_retrieval_position_2" gabor_circ gabor_165_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_69_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_165_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2242 2992 2492 fixation_cross gabor_171 gabor_015 gabor_053 gabor_034 gabor_171_alt gabor_015 gabor_053 gabor_034_alt "1_70_Encoding_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2500_gabor_patch_orientation_171_015_053_034_target_position_1_4_retrieval_position_1" gabor_123_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_70_Retrieval_Working_Memory_MEG_P4_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_123_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; }; # baselinePost (at the end of the session) trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; }; time = 0; duration = 5000; code = "BaselinePost"; port_code = 92; };

d774cdd6d376e798d1e5f36999b94ae42368c6f3

8217f7986187902617ad1bf89cb789618a90dd0a

/browsable_source/2.4/Unix-Windows/scilab-2.4/macros/percent/%p_d_r.sci

840c56d9f852e41937d80590614155a51a137dfe

[ "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]

permissive

clg55/Scilab-Workbench

4ebc01d2daea5026ad07fbfc53e16d4b29179502

9f8fd29c7f2a98100fa9aed8b58f6768d24a1875

refs/heads/master

2023-05-31T04:06:22.931111

2022-09-13T14:41:51

258,270,193

0

1

null

UTF-8

Scilab

false

137

sci

%p_d_r.sci

function r=%p_d_r(p,r) // r=%p_d_r(p,r) <=> r= p./r polynomial./rational // Copyright INRIA [n,d]=r(2:3) r(2)=d.*p;r(3)=n.*ones(p);

73db4ae5676fb8ffac9759fec0e9ae06a340d250

449d555969bfd7befe906877abab098c6e63a0e8

/1754/CH3/EX3.11/Exa3_11.sce

ed6d0a254370417555a0cae0a58838e108cafc5e

[]

no_license

FOSSEE/Scilab-TBC-Uploads

948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1

7bc77cb1ed33745c720952c92b3b2747c5cbf2df

refs/heads/master

2020-04-09T02:43:26.499817

2018-02-03T05:31:52

37,975,407

3

12

null

UTF-8

Scilab

false

428

sce

Exa3_11.sce

//Exa 3.11 clc; clear; close; //Given data : Po_dc=10;//in watt Po_ac=3.5;//in watt //Part (i) : ETAcollector=Po_ac/Po_dc;//unitless ETAcollector=ETAcollector*100;//collector efficiency in % disp(ETAcollector,"Collector Efficiency(in %) : "); //Part (ii) disp(Po_dc,"Zero signal condition represents maximum power loss. Therefore, all the 10 W power is dissipated by it. Hence Powe Rating of transistor in Watt : ")

236a9b2b41220e4314e1ca44605fbde4f96db884

25ec4bae7c1d991a8b4f36a96650a07061417648

/Exemplos/exemplo07SegueFaixa/pistaAngulada.sce

796c87e6d1c04aa35617f23c28b95fb169557a68

[]

no_license

OtacilioNeto/EV3MicroPythonExamples

716f76e4179d98157577d68b116a33a078aed085

037af9585402fe294d3c82d3b7d88cb49bc26bcf

refs/heads/master

2023-06-08T19:34:49.916922

2023-06-02T13:24:10

226,492,496

0

null

UTF-8

Scilab

false

25,104

sce

pistaAngulada.sce

// Red Green Blue Red Green Blue pistaAngulada = [ 28 40 59 29.26 43.23 60.58; 28 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 41.88 60.58; 28 40 60 30.34 43.23 59.11; 28 40 59 30.34 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 29.26 43.23 60.58; 29 40 60 30.34 43.23 59.11; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 29 40 60 30.34 43.23 60.58; 28 40 60 30.34 41.88 60.58; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 59.11; 28 40 60 30.34 41.88 59.11; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 60.58; 28 40 60 30.34 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 41.88 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 28 40 59 29.26 43.23 60.58; 28 40 60 30.34 43.23 59.11; 28 40 59 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 60.58; 28 40 60 30.34 43.23 60.58; 29 40 60 30.34 41.88 60.58; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 29.26 41.88 59.11; 29 40 60 29.26 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 29.26 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 28 40 60 30.34 43.23 59.11; 28 40 60 30.34 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 40 59 29.26 43.23 60.58; 28 40 60 30.34 43.23 59.11; 28 40 59 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 59 29.26 43.23 60.58; 29 41 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 41 60 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 40 59 29.26 43.23 60.58; 28 40 60 30.34 43.23 59.11; 28 40 59 29.26 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 41 60 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 60.58; 28 40 60 30.34 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 60.58; 28 40 60 30.34 41.88 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 41 60 30.34 41.88 60.58; 28 40 59 30.34 41.88 60.58; 29 40 60 30.34 41.88 60.58; 29 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 60.58; 28 40 60 29.26 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 28 40 59 29.26 43.23 60.58; 29 40 60 30.34 43.23 59.11; 28 40 59 29.26 41.88 59.11; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 41.88 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 59 30.34 41.88 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 41 60 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 40 59 30.34 43.23 60.58; 28 40 60 30.34 43.23 59.11; 28 40 59 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 40 60 29.26 43.23 60.58; 28 40 60 30.34 43.23 59.11; 28 40 59 29.26 41.88 59.11; 29 40 60 29.26 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 29 40 60 30.34 43.23 62.04; 28 40 60 30.34 43.23 60.58; 29 40 60 30.34 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 41.88 60.58; 29 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 60.58; 28 40 60 30.34 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 60.58; 29 40 59 29.26 43.23 60.58; 28 40 60 30.34 43.23 59.11; 28 40 60 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 41.88 60.58; 29 40 60 30.34 41.88 60.58; 28 40 59 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 59 29.26 43.23 60.58; 29 40 60 30.34 43.23 59.11; 28 40 59 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 59 29.26 41.88 60.58; 29 41 60 30.34 43.23 59.11; 28 40 60 30.34 41.88 59.11; 29 41 60 30.34 41.88 59.11; 29 40 60 30.34 41.88 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 41 60 29.26 41.88 59.11; 29 40 59 29.26 43.23 60.58; 28 40 60 30.34 43.23 59.11; 28 40 59 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 59 29.26 43.23 60.58; 29 40 60 30.34 43.23 59.11; 28 40 60 29.26 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 40 59 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 28 40 59 29.26 41.88 59.11; 29 40 59 30.34 41.88 60.58; 28 40 60 30.34 43.23 59.11; 29 40 60 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 60.58; 29 40 59 29.26 43.23 60.58; 29 40 60 30.34 43.23 59.11; 28 40 59 29.26 41.88 59.11; 29 40 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 43.23 59.11; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 29.26 41.88 59.11; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 62.04; 29 41 60 30.34 41.88 60.58; 29 41 60 30.34 43.23 62.04; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 62.04; 29 41 60 30.34 43.23 62.04; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 60.58; 29 41 60 30.34 43.23 62.04; 29 41 60 30.34 43.23 60.58; 29 40 60 30.34 41.88 60.58; 27 38 56 29.26 41.88 59.11; 26 36 53 27.1 39.16 54.7; 25 36 53 27.1 39.16 54.7; 26 38 55 28.18 40.52 59.11; 27 38 56 29.26 40.52 59.11; 27 38 55 29.26 41.88 59.11; 26 37 54 29.26 41.88 60.58; 27 38 55 29.26 40.52 59.11; 26 37 54 28.18 39.16 56.17; 26 37 53 28.18 40.52 57.64; 26 37 54 29.26 40.52 57.64; 26 37 54 28.18 40.52 56.17; 26 37 54 28.18 40.52 54.7; 26 37 54 28.18 39.16 54.7; 26 37 54 26.02 37.81 53.23; 26 37 54 26.02 37.81 51.77; 26 37 55 27.1 37.81 54.7; 27 38 56 28.18 40.52 57.64; 27 37 56 28.18 40.52 57.64; 27 38 57 28.18 40.52 57.64; 27 38 56 28.18 39.16 56.17; 27 37 56 27.1 39.16 54.7; 27 38 57 27.1 40.52 54.7; 27 38 56 27.1 39.16 56.17; 28 38 58 27.1 40.52 57.64; 28 39 59 27.1 39.16 54.7; 28 39 59 27.1 39.16 53.23; 28 39 59 27.1 40.52 56.17; 28 39 58 27.1 39.16 56.17; 27 38 56 27.1 39.16 54.7; 27 38 56 23.86 36.45 42.96; 28 38 58 13.05 24.24 16.53; 30 40 62 2.24 6.61 6.25; 31 42 63 5.48 6.61 12.12; 32 43 65 7.65 9.32 19.46; 31 42 64 6.57 7.96 13.59; 31 41 63 3.32 6.61 6.25; 31 41 62 3.32 6.61 6.25; 30 40 61 6.57 12.03 7.72; 30 40 62 13.05 22.88 19.46; 30 40 62 18.45 31.02 34.15; 27 36 58 26.02 39.16 53.23; 20 28 46 29.26 40.52 57.64; 19 25 41 29.26 40.52 57.64; 20 27 45 29.26 40.52 59.11; 25 34 55 28.18 41.88 57.64; 29 39 62 26.02 39.16 51.77; 30 40 62 21.7 35.09 44.42; 31 42 64 17.37 29.67 34.15; 31 42 63 14.13 25.6 26.8; 31 42 63 13.05 22.88 22.4; 31 42 64 10.89 20.17 19.46; 33 44 66 13.05 22.88 22.4; 32 43 66 15.21 25.6 29.74; 31 42 64 20.62 32.38 42.96; 29 40 61 26.02 39.16 53.23; 24 35 51 28.18 40.52 57.64; 20 28 40 30.34 40.52 59.11; 20 28 40 29.26 40.52 57.64; 22 31 44 30.34 41.88 60.58; 24 34 50 31.42 43.23 62.04; 24 34 51 31.42 43.23 62.04; 26 36 54 29.26 41.88 60.58; 27 37 56 28.18 40.52 57.64; 27 38 58 24.94 37.81 51.77; 28 39 59 24.94 37.81 51.77; 28 38 59 23.86 36.45 50.3; 29 40 61 24.94 37.81 51.77; 30 41 62 26.02 37.81 53.23; 28 39 59 24.94 37.81 51.77; 28 38 59 26.02 37.81 53.23; 28 38 59 26.02 37.81 54.7; 28 39 59 27.1 39.16 54.7; 29 40 60 28.18 40.52 57.64; 29 40 60 28.18 40.52 59.11; 28 38 58 28.18 40.52 59.11; 27 38 56 28.18 41.88 59.11; 22 33 37 28.18 40.52 59.11; 14 22 17 28.18 40.52 59.11; 6 10 5 30.34 41.88 62.04; 3 7 5 32.51 43.23 63.51; 3 6 7 33.59 45.94 66.45; 3 6 6 33.59 44.59 64.98; 3 7 5 32.51 44.59 63.51; 10 15 12 31.42 43.23 63.51; 16 25 24 30.34 40.52 60.58; 24 35 45 27.1 39.16 59.11; 29 40 59 22.78 35.09 51.77; 29 40 60 18.45 29.67 42.96; 30 40 61 17.37 28.31 41.49; 29 40 60 21.7 32.38 47.36; 28 39 57 24.94 36.45 53.23; 25 36 48 27.1 39.16 59.11; 22 32 40 28.18 39.16 59.11; 17 25 28 31.42 41.88 60.58; 15 22 24 31.42 43.23 62.04; 14 20 20 31.42 43.23 62.04; 13 18 20 31.42 43.23 62.04; 18 25 29 32.51 43.23 62.04; 24 34 47 30.34 43.23 62.04; 28 39 58 27.1 39.16 57.64; 29 40 61 24.94 37.81 53.23; 29 40 61 22.78 35.09 48.83; 29 40 60 24.94 36.45 51.77; 28 38 57 27.1 39.16 56.17; 27 38 56 28.18 40.52 57.64; 25 36 51 29.26 40.52 59.11; 22 32 44 29.26 40.52 59.11; 22 31 42 30.34 41.88 60.58; 21 30 40 31.42 43.23 60.58; 21 29 40 31.42 43.23 62.04; 21 30 40 30.34 41.88 60.58; 22 31 42 30.34 43.23 62.04; 24 35 50 31.42 43.23 62.04; 27 38 56 30.34 43.23 60.58; 28 39 60 28.18 40.52 57.64; 29 40 60 26.02 37.81 53.23; 29 40 62 24.94 37.81 51.77; 29 40 61 24.94 36.45 51.77; 29 40 61 26.02 37.81 51.77; 29 41 61 26.02 39.16 53.23; 29 40 61 27.1 39.16 54.7; 29 41 61 27.1 39.16 54.7; 29 40 60 27.1 40.52 56.17; 28 40 59 28.18 40.52 59.11; 27 39 58 29.26 40.52 59.11; 27 38 56 29.26 41.88 60.58; 26 37 55 28.18 40.52 57.64; 27 38 55 30.34 41.88 59.11; 26 36 50 30.34 41.88 60.58; 23 34 44 30.34 41.88 60.58; 19 28 29 30.34 41.88 60.58; 9 14 10 31.42 43.23 60.58; 4 8 4 32.51 43.23 63.51; 3 7 5 33.59 44.59 64.98; 3 7 4 33.59 44.59 64.98; 4 8 5 32.51 44.59 63.51; 9 14 11 31.42 43.23 62.04; 15 22 23 30.34 41.88 60.58; 24 35 47 30.34 41.88 60.58; 28 40 58 27.1 39.16 56.17; 30 40 60 21.7 32.38 45.89; 30 40 61 19.54 31.02 42.96; 30 40 61 19.54 31.02 44.42; 29 40 59 23.86 35.09 51.77; 27 39 55 28.18 40.52 59.11; 23 34 44 29.26 40.52 60.58; 19 28 31 31.42 43.23 62.04; 14 20 20 31.42 43.23 62.04; 13 18 18 31.42 43.23 62.04; 10 15 14 32.51 43.23 63.51; 12 17 16 31.42 43.23 62.04; 18 26 27 32.51 44.59 63.51; 23 34 44 30.34 43.23 62.04; 28 40 58 27.1 39.16 57.64; 30 40 61 23.86 36.45 50.3; 30 40 61 20.62 32.38 44.42; 29 40 60 21.7 33.74 47.36; 28 39 55 24.94 37.81 53.23; 25 37 49 28.18 40.52 59.11; 19 29 30 30.34 41.88 60.58; 14 21 19 31.42 41.88 60.58; 7 12 9 31.42 43.23 62.04; 4 8 4 32.51 43.23 63.51; 5 9 5 32.51 44.59 64.98; 8 13 10 31.42 43.23 62.04; 16 24 22 30.34 41.88 60.58; 24 35 44 27.1 39.16 57.64; 27 38 54 22.78 33.74 48.83; 28 38 56 18.45 29.67 42.96; 30 41 61 20.62 31.02 45.89; 29 40 58 22.78 35.09 50.3; 27 38 52 23.86 35.09 51.77; 25 36 45 26.02 37.81 54.7; 19 29 29 28.18 39.16 57.64; 16 24 22 30.34 41.88 60.58; 10 16 13 31.42 41.88 62.04; 6 11 6 31.42 41.88 62.04; 7 12 7 32.51 44.59 64.98; 13 20 17 32.51 43.23 63.51; 22 32 37 30.34 41.88 62.04; 27 39 54 24.94 36.45 53.23; 29 40 60 19.54 31.02 44.42; 30 40 60 17.37 28.31 38.55; 29 40 60 18.45 29.67 42.96; 28 39 55 22.78 33.74 50.3; 23 34 41 27.1 37.81 56.17; 18 27 25 28.18 39.16 59.11; 12 18 15 30.34 41.88 60.58; 6 10 6 31.42 41.88 62.04; 4 7 4 31.42 43.23 62.04; 6 10 6 31.42 43.23 62.04; 14 22 19 31.42 41.88 62.04; 24 35 42 27.1 39.16 57.64; 28 39 54 20.62 32.38 47.36; 30 40 60 18.45 28.31 42.96; 29 40 59 17.37 26.95 38.55; 28 39 57 20.62 31.02 45.89; 26 38 50 23.86 35.09 53.23; 22 33 37 26.02 37.81 54.7; 18 28 27 28.18 39.16 59.11; 14 22 18 30.34 40.52 59.11; 11 17 13 30.34 41.88 60.58; 9 14 10 31.42 43.23 62.04; 14 22 18 31.42 43.23 62.04; 23 34 40 26.02 36.45 54.7; 28 39 56 17.37 28.31 41.49; 28 38 58 15.21 24.24 35.61; 29 40 59 16.29 25.6 38.55; 28 40 57 19.54 31.02 44.42; 28 39 53 22.78 33.74 48.83; 24 35 43 23.86 35.09 51.77; 21 31 33 27.1 39.16 57.64; 17 26 24 28.18 39.16 57.64; 14 21 18 28.18 39.16 57.64; 13 19 16 30.34 40.52 59.11; 11 17 13 30.34 40.52 59.11; 18 27 26 30.34 41.88 60.58; 28 38 52 23.86 35.09 51.77; 29 39 58 18.45 28.31 42.96; 29 39 59 16.29 25.6 37.08; 29 39 59 16.29 25.6 37.08; 28 38 54 20.62 31.02 45.89; 25 36 43 24.94 36.45 53.23; 20 30 30 28.18 39.16 59.11; 13 21 15 30.34 41.88 60.58; 10 16 10 31.42 41.88 60.58; 8 13 9 31.42 43.23 62.04; 8 13 8 31.42 43.23 62.04; 13 20 15 30.34 41.88 62.04; 24 36 41 26.02 37.81 56.17; 29 38 56 17.37 28.31 41.49; 29 39 59 14.13 22.88 34.15; 29 39 59 13.05 21.53 32.68; 29 39 59 15.21 24.24 35.61; 28 39 55 19.54 29.67 44.42; 25 36 44 22.78 33.74 50.3; 22 32 33 27.1 37.81 57.64; 16 26 21 29.26 40.52 60.58; 13 21 15 29.26 40.52 59.11; 13 19 15 29.26 40.52 59.11; 12 18 13 29.26 40.52 59.11; 16 24 19 29.26 40.52 60.58; 22 33 33 26.02 37.81 56.17; 29 40 55 18.45 29.67 44.42; 29 40 59 14.13 21.53 32.68; 30 40 60 14.13 22.88 35.61; 30 41 59 17.37 26.95 40.02; 28 40 53 19.54 31.02 45.89; 27 38 50 20.62 31.02 47.36; 24 35 40 22.78 33.74 51.77; 21 31 32 26.02 37.81 57.64; 18 27 25 27.1 37.81 56.17; 16 25 21 28.18 39.16 57.64; 15 22 19 29.26 40.52 59.11; 13 20 17 29.26 40.52 59.11; 14 22 18 30.34 40.52 59.11; 18 28 25 28.18 39.16 59.11; 26 37 45 23.86 35.09 51.77; 29 40 56 18.45 28.31 42.96; 28 39 56 17.37 26.95 40.02; 29 40 55 18.45 28.31 42.96; 27 38 50 22.78 33.74 50.3; 20 30 30 26.02 37.81 57.64; 17 26 25 28.18 39.16 57.64; 13 19 17 30.34 41.88 60.58; 10 16 13 31.42 41.88 60.58; 10 14 11 31.42 41.88 60.58; 11 17 15 32.51 43.23 62.04; 18 26 26 30.34 40.52 60.58; 27 38 51 24.94 36.45 53.23; 29 40 60 17.37 26.95 38.55; 30 39 60 15.21 24.24 35.61; 30 40 60 19.54 31.02 45.89; 28 39 56 22.78 33.74 48.83; 26 36 49 27.1 39.16 57.64; 21 30 37 29.26 40.52 59.11; 19 27 32 30.34 40.52 59.11; 18 26 30 30.34 40.52 59.11; 19 26 33 30.34 40.52 59.11; 18 25 32 30.34 41.88 59.11; 20 28 39 30.34 40.52 59.11; 25 35 52 31.42 41.88 60.58; 26 37 56 28.18 40.52 56.17; 28 39 60 26.02 37.81 51.77; 29 39 60 21.7 33.74 41.49; 30 40 61 18.45 31.02 35.61; 30 41 61 16.29 26.95 29.74; 30 40 61 13.05 22.88 22.4; 31 42 63 10.89 20.17 17.99; 32 43 64 11.97 21.53 19.46; 31 42 64 15.21 25.6 26.8; 31 41 63 19.54 31.02 37.08; 28 39 60 24.94 37.81 48.83; 25 35 54 26.02 39.16 53.23; 23 32 51 27.1 39.16 53.23; 25 34 53 27.1 39.16 53.23; 27 37 58 24.94 37.81 50.3; 28 38 60 22.78 35.09 44.42; 30 40 61 19.54 31.02 38.55; 31 41 62 16.29 28.31 31.21; 31 41 62 14.13 24.24 25.34; 31 41 63 13.05 24.24 22.4; 31 42 63 14.13 24.24 25.34; 31 42 63 16.29 28.31 29.74; 31 42 64 20.62 32.38 38.55; 29 40 62 22.78 35.09 47.36; 28 38 59 24.94 37.81 50.3; 27 37 58 26.02 37.81 51.77; 28 38 60 24.94 36.45 50.3; 30 40 62 22.78 35.09 45.89; 31 41 63 19.54 32.38 37.08; 32 42 64 14.13 24.24 22.4; 32 43 65 10.89 20.17 17.99; 32 44 65 9.81 18.82 16.53; 32 43 65 11.97 21.53 19.46; 32 43 65 18.45 31.02 34.15; 30 41 63 23.86 36.45 45.89; 26 36 55 27.1 40.52 53.23; 22 30 49 28.18 40.52 56.17; 23 31 50 27.1 39.16 53.23; 27 37 58 22.78 35.09 41.49; 30 41 63 15.21 26.95 25.34; 31 42 63 9.81 18.82 13.59; 32 42 64 6.57 12.03 7.72; 32 43 65 5.48 10.68 6.25; 32 43 64 6.57 12.03 7.72; 32 42 64 9.81 17.46 12.12; 31 41 63 15.21 26.95 25.34; 27 37 59 22.78 35.09 44.42; 21 27 47 29.26 41.88 57.64; 16 21 36 29.26 40.52 57.64; 16 20 36 29.26 40.52 59.11; 18 23 41 29.26 40.52 57.64; 24 32 53 27.1 39.16 51.77; 26 36 58 23.86 37.81 47.36; 29 39 61 20.62 33.74 37.08; 30 40 62 16.29 28.31 26.8; 31 41 63 13.05 24.24 20.93; 31 42 63 13.05 24.24 19.46; 30 40 61 10.89 20.17 15.06; 32 43 65 11.97 21.53 17.99; 32 43 65 14.13 25.6 20.93; 29 40 63 22.78 36.45 44.42; 21 28 48 28.18 40.52 56.17; 17 22 38 29.26 40.52 59.11; 21 28 48 29.26 41.88 57.64; 25 34 55 27.1 40.52 54.7; 27 36 58 26.02 37.81 50.3; 28 38 61 21.7 33.74 42.96; 31 41 63 18.45 31.02 34.15; 31 42 64 15.21 26.95 28.27; 32 42 64 13.05 22.88 22.4; 32 43 64 10.89 18.82 16.53; 32 43 65 9.81 17.46 15.06; 33 44 66 11.97 22.88 20.93; 32 43 65 14.13 25.6 26.8; 31 42 63 23.86 36.45 47.36; 27 37 57 27.1 39.16 54.7; 21 29 44 29.26 40.52 57.64; 19 26 40 29.26 40.52 57.64; 21 28 44 29.26 40.52 57.64; 25 35 53 28.18 40.52 54.7; 27 38 58 27.1 40.52 54.7; 28 39 60 23.86 36.45 47.36; 30 41 62 20.62 32.38 40.02; 31 42 63 17.37 29.67 32.68; 31 42 63 15.21 25.6 26.8; 31 42 62 10.89 20.17 17.99; 31 41 62 8.73 16.1 10.65; 32 44 65 9.81 17.46 13.59; 32 43 65 11.97 21.53 17.99; 32 43 65 24.94 39.16 48.83; 25 35 54 29.26 41.88 57.64; 19 26 41 31.42 41.88 60.58; 19 25 40 30.34 41.88 60.58; 22 31 49 30.34 43.23 60.58; 26 35 56 29.26 41.88 57.64; 29 39 61 24.94 39.16 50.3; 29 40 61 22.78 35.09 42.96; 31 41 62 15.21 26.95 26.8; 32 42 64 11.97 22.88 19.46; 31 42 63 7.65 14.75 10.65; 32 43 64 6.57 12.03 9.18; 33 45 67 10.89 20.17 19.46; 32 43 65 18.45 31.02 35.61; 30 41 63 26.02 39.16 53.23; 26 37 56 30.34 43.23 60.58; 21 30 45 29.26 40.52 57.64; 21 29 44 31.42 43.23 60.58; 23 31 48 30.34 41.88 59.11; 26 37 55 30.34 43.23 59.11; 28 39 60 28.18 40.52 56.17; 29 40 61 26.02 37.81 51.77; 31 42 63 23.86 36.45 48.83; 31 42 62 21.7 35.09 44.42; 32 42 64 20.62 33.74 42.96; 32 43 64 19.54 32.38 41.49; 31 41 61 19.54 31.02 38.55; 32 42 64 19.54 32.38 41.49; 33 44 65 23.86 37.81 50.3; 32 43 64 27.1 40.52 57.64; 29 40 60 29.26 41.88 59.11; 25 36 52 30.34 41.88 60.58; 24 35 49 30.34 43.23 60.58; 24 34 49 30.34 41.88 60.58; 25 35 50 31.42 43.23 62.04; 25 36 51 32.51 44.59 63.51; 26 36 52 32.51 44.59 63.51; 26 36 51 32.51 44.59 63.51; 25 36 51 31.42 44.59 62.04; 27 37 54 31.42 43.23 62.04; 28 40 59 31.42 43.23 60.58; 30 41 61 31.42 44.59 62.04; 29 41 60 30.34 43.23 62.04; 29 40 60 30.34 43.23 60.58; 30 41 62 30.34 43.23 59.11; 29 41 61 29.26 41.88 60.58; 29 40 60 29.26 41.88 59.11; 28 40 58 27.1 40.52 51.77; 26 37 54 2.24 6.61 6.25; 28 38 60 9.81 12.03 28.27; 33 44 67 29.26 39.16 64.98; 35 47 71 34.67 47.3 69.39; 34 46 70 33.59 45.94 64.98; 31 42 62 31.42 41.88 60.58; 31 42 63 31.42 41.88 60.58; 31 41 62 30.34 40.52 59.11; 34 45 67 33.59 44.59 64.98; 35 46 68 33.59 47.3 67.92; 32 43 66 32.51 44.59 63.51; 34 45 68 33.59 45.94 66.45; 32 43 65 32.51 44.59 63.51; 31 42 63 31.42 43.23 60.58; 33 44 66 32.51 43.23 63.51; 33 44 66 32.51 44.59 63.51; 34 45 68 33.59 45.94 66.45; 34 45 68 34.67 45.94 64.98; 34 45 67 33.59 45.94 64.98; 33 44 67 33.59 44.59 64.98; 34 46 68 33.59 45.94 64.98; 34 45 68 34.67 45.94 64.98; 35 47 70 34.67 47.3 67.92; 32 44 64 33.59 45.94 64.98; 30 44 64 31.42 44.59 63.51; 26 38 56 26.02 39.16 53.23; 24 35 53 22.78 33.74 48.83; 21 30 49 22.78 31.02 47.36; 13 16 29 13.05 16.1 26.8; 9 9 18 9.81 12.03 20.93; 2 2 8 4.4 2.54 6.25; 1 1 1 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; 0 0 0 2.24 2.54 6.25; ];