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|
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
b88b2550d69be48f81ede9a13d4da6b13d38310e
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/22/CH2/EX2.7/ch2ex7.sce
|
025d58136ae3df142d67cc907f5c0d89c49313ea
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 558
|
sce
|
ch2ex7.sce
|
//time domain analysis of continuous time systems
//Convolution Integral of input x(t) = (e^-t).u(t)and g(t) =u(t)
clear;
close;
clc;
Max_Limit = 10;
t = -10:0.001:10;
for i=1:length(t)
g(i)=exp(-t(i));
x(i)=exp(-2*t(i));
end
y = convol(x,g)
figure
a=gca();
plot2d(t,g)
xtitle('Impulse Response','t','h(t)');
a.thickness = 2;
figure
a=gca();
plot2d(t,x)
xtitle('Input Response','t','x(t)');
a.thickness = 2;
figure
a=gca();
T=-20:0.001:20;
plot2d(T,y)
xtitle('Output Response','t','y(t)');
a.thickness = 2;
|
d322e6ab6dd9b428bdb1a58f1f208dd3f8eab92c
|
676ffceabdfe022b6381807def2ea401302430ac
|
/solvers/IncNavierStokesSolver/Tests/KovaFlow_3DH1D_P5_20modes_MVM.tst
|
1bc9f844c99f570078a59e642d44efc29fa80666
|
[
"MIT"
] |
permissive
|
mathLab/ITHACA-SEM
|
3adf7a49567040398d758f4ee258276fee80065e
|
065a269e3f18f2fc9d9f4abd9d47abba14d0933b
|
refs/heads/master
| 2022-07-06T23:42:51.869689
| 2022-06-21T13:27:18
| 2022-06-21T13:27:18
| 136,485,665
| 10
| 5
|
MIT
| 2019-05-15T08:31:40
| 2018-06-07T14:01:54
|
Makefile
|
UTF-8
|
Scilab
| false
| false
| 1,047
|
tst
|
KovaFlow_3DH1D_P5_20modes_MVM.tst
|
<?xml version="1.0" encoding="utf-8"?>
<test>
<description>Kovasznay Flow 3D homogeneous 1D, P=5, 20 Fourier modes (MVM)</description>
<executable>IncNavierStokesSolver</executable>
<parameters>KovaFlow_3DH1D_P5_20modes_MVM.xml</parameters>
<files>
<file description="Session File">KovaFlow_3DH1D_P5_20modes_MVM.xml</file>
</files>
<metrics>
<metric type="L2" id="1">
<value variable="u" tolerance="1e-12">1.54682e-06</value>
<value variable="v" tolerance="1e-12">9.50615e-07</value>
<value variable="w" tolerance="1e-12">9.03459e-07</value>
<value variable="p" tolerance="1e-12">2.04388e-05</value>
</metric>
<metric type="Linf" id="2">
<value variable="u" tolerance="1e-12">3.14458e-06</value>
<value variable="v" tolerance="1e-12">2.25387e-06</value>
<value variable="w" tolerance="1e-12">1.8079e-06</value>
<value variable="p" tolerance="1e-12">6.87022e-05</value>
</metric>
</metrics>
</test>
|
7c20216ef3a5b4d596ed7a8fe7c04a164e43ef46
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/14/CH10/EX10.3/example_10_3.sce
|
6b9dad262e40ea3124d4019fdf535e6150ac18bc
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 801
|
sce
|
example_10_3.sce
|
//Chapter 10
//Example 10.3
//Page 259
//thevninloadedfault
clear;clc;
//Given
Pgm = 30e6;
Vgm = 13.2e3;
Xgm = 0.20;
Xl = 0.10;
Pm = 20e6;pfm = 0.8;Vt_m = 12.8e3;
Pbase = Pgm;
Vbase = Vgm;
Vf = Vt_m / Vbase;
Ibase = Pbase / (sqrt(3) * Vbase);
I_L = (Pm / (pfm * sqrt(3) * Vt_m)) * (cos(36.9 * %pi/180) + %i * sin(36.9 * %pi / 180)) / Ibase;
Zth = (%i*(Xgm+Xl) * (%i * Xgm)) / (%i*(Xgm+Xl) + (%i * Xgm));
disp(Zth,'Zth in per unit')
I11_f = Vf / Zth;
disp(I11_f,'Subtransient fault current in per unit')
If_g = I11_f * (%i * Xgm) / (%i*(Xgm+Xl) + (%i * Xgm));
If_m = I11_f * (%i * (Xgm + Xl)) / (%i*(Xgm+Xl) + (%i * Xgm));
I11_g = I_L + If_g ;
disp(I11_g,'Subtransient fault current in generator side in per unit')
I11_m = If_m - I_L ;
disp(I11_m,'Subtransient fault current in motor side in per unit')
|
d6455441dcef7396243ed0441915c32e759f123d
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3875/CH10/EX10.10/Ex10_10.sce
|
58cf3312d7d930993a484927331b0f83066022aa
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 413
|
sce
|
Ex10_10.sce
|
clc;
clear;
W=2.3*1.6*10^-19 //Energy required to remove electron in eV
h=6.63*10^-34 //Plancks constant in J-s
c=3*10^8 //velocity of light in m/s
//calculation
lambda_0=(h*c)/W
printf("\nSince the threshold wavelength is %1.3e,wavelength 680nm is not capable of showing photoelectric effect as threshold wavelength is the longest wavelength",lambda_0)
//The answer provided in the textbook is wrong.
|
981efc34729eab83ce816f98706d7a3500124f5f
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3710/CH5/EX5.4/Ex5_4.sce
|
dadcd54b7d873cfe6d3eb1a73c6bd07b1f0501fd
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 340
|
sce
|
Ex5_4.sce
|
//Example 5.4, Page Number 205
//The Function fpround(dependency) is used to round a floating point number x to n decimal places
clc;
n2=3.6 //Refractive Index for GaAs
n1=1 //Refractive Index for Air
//From Fresnels Equation
R=((n2-n1)/(n2+n1))**2
R=fpround(R,2)
mprintf("The Reflectance at a GaAs/Air Interface is %0.2f",R);
|
5592deb99f1bd0fdb072e4a3ec492028266f5903
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1892/CH3/EX3.11/Example3_11.sce
|
83f6e75f8ebacdadcf79ab8a250a45c940f68896
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 305
|
sce
|
Example3_11.sce
|
// Example 3.11
clear; clc; close;
format('v',6);
// Given data
Beta=1.8;//in dcegree
revolution=10;//no. of revolution
//Calculations
resolution=360/Beta;//in steps/rev
steps=resolution*revolution;//no. of steps in 10 evolution
disp("No. of steps = "+string(steps)+" should be encoded.");
|
26adaed27bd81061007b92cd7a2bb68420dda74f
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/213/CH10/EX10.18/10_18.sce
|
32f001d14822916923db0b04decfc658884cc472
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 809
|
sce
|
10_18.sce
|
//To find power lost in friction
clc
//Given:
D=200/1000,R=D/2 //m
W=30*1000 //N
alpha=120/2 //degrees
mu=0.025
N=140 //rpm
//Solution:
//Calculating the angular speed of the shaft
omega=2*%pi*N/60 //rad/s
//Power lost in friction assuming uniform pressure:
//Calculating the total frictional torque
T=2/3*mu*W*R*(1/sind(alpha)) //N-m
//Calculating the power lost in friction
P1=T*omega //Power lost in friction, W
//Power lost in friction assuming uniform wear:
//Calculating the total frictional torque
T=1/2*mu*W*R*(1/sind(alpha)) //N-m
//Calculating the power lost in friction
P2=T*omega //Power lost in friction, W
//Resluts:
printf("\n\n Power lost in friction assuming uniform pressure, P = %d W.\n",P1)
printf(" Power lost in friction assuming uniform wear, P = %.1f W.\n\n",P2)
|
b2cf337d5b671e4359028b5a486c34463ec1b33c
|
43ee35e120afa343a967b8a7034a973f0a481a4d
|
/60002190045_SS_EXP_4.sce
|
f948eb38249b5968f3083bb80b5c065f3cdedfa9
|
[] |
no_license
|
hrushilp/60002190045_SSPRACS
|
8c43d955139c09e5e3d0a3d0d041fb053c94cb88
|
07887fd3a92d3d599b993fb5585b63d569836d67
|
refs/heads/main
| 2023-01-20T06:23:31.575304
| 2020-11-25T18:52:42
| 2020-11-25T18:52:42
| 316,027,450
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 394
|
sce
|
60002190045_SS_EXP_4.sce
|
//PRACTICAL-4-Z-TRANSFORM
clc;
//find the z transform of a simple sequence
function[za]=ztransfer(seq,n)
z=poly(0,'z','r')
za=seq*(1/z)^n'
endfunction
// -6 to 2
x1=[2 -1 3 2 1 0 2 3 -1]
n= -6:2
zz=ztransfer(x1,n)
//Roc of the above sequence
//INVERSE Z TRANSFORM
z=%z;
num=3*z^2+2*z+1;
den=z^2-3*z + 2;
h=ldiv(num,den,16);
disp(h,"First sixteen terms of the series")
|
a90e5e11c79573bc202d7c1552f6307719544b84
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3809/CH17/EX17.1/EX17_1.sce
|
b5621881774dffc2c343c4d1f13d1543ec7a60c6
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 607
|
sce
|
EX17_1.sce
|
//Chapter 17, Example 17.1
clc
//Initialisation
rd=100*10**3 //resistance in ohm
gm=2*10**-3 //in seimens
RD=2*10**3 //resistance in ohm
RG=10**6 //resistance in ohm
//Calculation
ro=((rd*RD)/(rd+RD)) //Input Resistance
v=-gm*ro //Small Signal Voltage Gain
ri=RG //Input Resistance
//Results
printf("Small Signal Voltage Gain = %.1f \n",v)
printf("Input Resistance, ri = %d MOhm \n",ri/10**6)
printf("Ouput Resistance, ro = %d kOhm \n",round(ro/10**3))
|
6f29b0af8493a69aa062bcebf39c81e69e3695f3
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2708/CH16/EX16.3/ex_16_3.sce
|
d198f9c551cd12db81bb3512885ac7b08dbe6399
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 365
|
sce
|
ex_16_3.sce
|
//Example 16.3 //frequency & energy of photon
clc;
clear;
//given data :
lamda=4D-7;// de-Broglie wavelength in m
c=3D8;// speed of light in m/s
h=6.62D-34;// plank's constant in joules-sec
v=c/lamda;// frequency of photon in Hz
E=h*v;// energy in joules
E=E/1.6D-19;// Energy in eV
disp(v,"frequency of photon in Hz")
disp(E,"Energy of Photon in eV")
|
1d6348e51cac8975c9ccc5fd23174123fce13a70
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2132/CH7/EX7.6/Example7_6.sce
|
63dffe9e7c670c07244f88b7ba0ecd11095059a2
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 316
|
sce
|
Example7_6.sce
|
////Example 7.6
clc;
clear;
close;
format('v',6);
//Given data :
D=20/100;//meter
v=3;//m/s
v1=0.01*10^-3;//m^2/sec
Re=D*v/v1;//Reynolds number
f=0.002+0.09/Re^0.3;//coeff. of friction
L=5;//meter
g=9.81;//gravity constanty
hf=4*f*L*v^2/D/2/g;//meter
disp(hf,"Head lost due to friction in meter : ");
|
81a0931a0cbeb333873314c3928a8c8de055763c
|
8627886261b3eddf8440c0b470cd9ee25c762d97
|
/сайлаб/7_lab_rabota.sce
|
6f666159307537f85cf399ae1e96b4a94259899d
|
[] |
no_license
|
timurzotov/pvis
|
ba75cf86fae91b6adc8dd3fe9cd2672eea561cca
|
d60e8e241d6ce0ad3a9b2a75c8771f92a9b039ba
|
refs/heads/master
| 2020-09-08T07:59:31.719500
| 2019-11-11T21:14:13
| 2019-11-11T21:14:13
| 221,070,925
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 769
|
sce
|
7_lab_rabota.sce
|
clc
disp('******Задание №7*******')
disp('-----------№1----------')
function [s,p]=f1(n)
s=0;
p=1;
for i=1:n
s=s+i;
p=p*i;
end
disp(p,'p=',s,'s=')
endfunction
funcprot(0);
f1(5);
disp('-----------№2----------')
function y=f(n)
disp (' x y')
for x=2:n
y=sin(x);
disp ([x,y])
end
endfunction
f(7);
disp('-----------№3----------')
function [ks,s]=f(n,a,h,b)
ks=0;
s=0;
x=a;
for i=1:n
y=cos(x);
if y>b then ks=ks+1, s=y+s;
end
x=x+h;
end
disp(s,'Сумма=')
disp(ks,'Количество слагаемых=')
endfunction
f(10,0,0.3,-0.1);
|
3fb3559713ad1e092aa594cd585f3c247d30a56d
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/479/CH3/EX3.13/Example_3_13.sce
|
ff466298f62026a2d5d946cb454716667b4f719d
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,153
|
sce
|
Example_3_13.sce
|
//Chemical Engineering Thermodynamics
//Chapter 3
//First Law of Thermodynamics
//Example 3.13
clear;
clc;
//Given
//Q=W=delPE=delKE=0;
//M2=0; no exit stream
Ti = 288;//initial temperature in K
H = 7*Ti;//enthalpy of air in Kcal/Kgmole
Ei = 5*Ti;// initial internal energy of air in Kcal/Kgmole
//Ef=5*Tf;Final internal energy of air in Kcal/Kgmole
Pi = 0.3;//initial pressure in atm
V = 0.57;//volume of the tank in m^3
R = 848;//gas constant in mKgf/Kg mole K
Pf = 1;//final prssure in atm
//To calculate the final weight and the final temperature of the air in the tank
Mi = (Pi*V*1.03*10^4)/(R*Ti);//initial quantity of air in tank in Kg mole
//Tf=(Pf*V*1.033*10^4)/(Mf*R)..(a) final temperature,Mf=final quantity of air in tank in Kg mole
//M1=Mf-Mi..(b) M1 is mass of steam added in Kg mole
//H*M1=(Ef*Mf)-(Ei*Mi)
//H*M1=((5*Pf*V*1.033*10^4)/(Tf*R))*Tf-(Ei*Mi)...(c)
A = [1 -1;0 -H];
B = [Mi;((Ei*Mi)-((5*Pf*V*1.03*10^4)/R))];
x = A\B;
Mf = x(1);
mprintf('The final weight of air in the tank is%f Kg',Mf);
Tf = (Pf*V*1.03*10^4)/(Mf*R);
mprintf('\n The final temperature of air in the tank is %f K',Tf);
//end
|
7447bcd9e162666d32953a8a9067a974ae28a60b
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/24/CH13/EX13.2/Example13_2.sce
|
c81e89600694d5a719eaca15033ca6b4e784557a
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 532
|
sce
|
Example13_2.sce
|
//Given that
L = 12 // in meter
m = 45 //in kg
h = 9.3 //in meter
M = 72 //in kg
g = 9.8 //in m/s^2
//Sample Problem 13-2
printf("**Sample Problem 13-2**\n")
//From the figure
N2 = (M+m)*g
A = asin(h/L)
//Balancing torque from the bottom point of the ladder
N1 = (m*g*L/3*cos(A)+M*g*L/2*cos(A))/(L*sin(A))
f = N1
printf("The normal force from the wall is equal to %fN\n", N1)
printf("The normal force from the pavement is equal to %fN\n", N2)
printf("The frictional force from the pavement is equal to %fN", f)
|
67617e107c30fb4c59de5df70e59e726cd07d0f1
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3637/CH4/EX4.4/Ex4_4.sce
|
e201bfd63dffeefa87b9bc89ababd4015289855c
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 320
|
sce
|
Ex4_4.sce
|
//problem 4 pagenumber 4.39
//given
n=12;format(6);
r=8e-3;//volt
z='011101110001';
//determine output voltage
vof=r*(2^n-1);res=r/vof;
v0=r*base2dec(z,2);
disp('Output voltage = '+string(v0)+' volt');
disp('Fullscale Output Voltage = '+string(vof)+' volt');
disp('Resolution = '+string(res*1e2)+' percent');
|
0c63909e119c025dd921af182d93036aaaf1eb9f
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3137/CH1/EX1.17/Ex1_17.sce
|
aab0c32a3e7e80908dab49eb73cc7cd3dfcfebbd
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 248
|
sce
|
Ex1_17.sce
|
Px=2.85 //ft
Py=4.67 //ft
Pz=-8.09 //ft
Qx=28.3 //lb
Qy=44.6 //lb
Qz=53.3 //lb
//Calculations
X=(Py*Qz-Pz*Qy) //N.m
Y=(Pz*Qx-Px*Qz) //N.m
Z=(Px*Qy-Py*Qx) //N.m
//Result
clc
printf('The cross product is:%fi%fj%fk lb-ft',X,Y,Z) //lb-ft
|
801bf76c3821417171311d6db200d1882cdaa3f4
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1862/CH8/EX8.5/C8P5.sce
|
19844b9ce498b87c518b0947f8f0c01f9efcdc95
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,724
|
sce
|
C8P5.sce
|
clear
clc
//to find linesr or tangential speed of a point on a rim
//to find tangential acceleration of a point on a rim
//to find radial acceleration of a point on a rim
// GIVEN:
//refer to problem 8-3 from page no. 165
//refer to the figure 8-7 from page no. 165
//radius of grindstone for first case
r1 = 0.24//in meters
//radius of grindstone for second case
r2 = 0.12//in meters
//initial angular speed of grindstone
w = 8.6//in rad/s
//constant angular acceleration of grindstone
a = 3.2//in rad/s^2
//time interval
t = 2.7//in seconds
// SOLUTION:
//using kinematic equation of motion for rotational motion
//for r1 = 0.24m
//linesr or tangential speed of a point on a rim
vT = w*r1//in m/s
//tangential acceleration of a point on a rim
aT = a*r1//in m/s^2
//radial acceleration of a point on a rim
aR = w^2*r1//in m/s^2
//for r1 = 0.12m
//linesr or tangential speed of a point on a rim
v_T = w*r2//in m/s
//tangential acceleration of a point on a rim
a_T = a*r2//in m/s^2
//radial acceleration of a point on a rim
a_R = w^2*r2//in m/s^2
aR = round(aR)
printf ("\n\n Linesr or tangential speed of a point on a rim for r1 = 0.24m vT = \n\n %.1f m/s",vT);
printf ("\n\n Tangential acceleration of a point on a rim for r1 = 0.24m aT = \n\n %.2f m/s^2",aT);
printf ("\n\n Radial acceleration of a point on a rim for r1 = 0.24m aR = \n\n %2i m/s^2",aR);
printf ("\n\n Linesr or tangential speed of a point on a rim for r1 v_T = 0.12m v_T = \n\n %.1f m/s",v_T);
printf ("\n\n Tangential acceleration of a point on a rim for r1 = 0.12m a_T = \n\n %.2f m/s^2",a_T);
printf ("\n\n Radial acceleration of a point on a rim for r1 = 0.12m a_R = \n\n %.1f m/s^2",a_R);
|
a56a0aa8b20ddf75751c86611272c11488cc75e6
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/181/CH5/EX5.1/example5_1.sce
|
c6d5c3914257d325f5f1d5a688b7e535a4943813
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,559
|
sce
|
example5_1.sce
|
// Calculate BJT parameters using beta gain
// Basic Electronics
// By Debashis De
// First Edition, 2010
// Dorling Kindersley Pvt. Ltd. India
// Example 5-1 in page 235
clear; clc; close;
// Part 1
// Given Data
beta_bjt=100; // Beta Gain of BJT
Vcc=10; // DC voltage across Collector in V
Rb=100000; // Base Resistance of BJT in ohm
Rc=2000; // Collector Resistance of BJT in ohm
Vbe=0.7; // Base-Emitter voltage of BJT
// Calculations
Ib=(Vcc-Vbe)/((beta_bjt*Rc)+Rc+Rb);
Ic=beta_bjt*Ib;
Vce=Vcc-(Ib+Ic)*Rc;
printf("Part 1 \n");
printf("(a)The value of Base Current in the BJT circuit is %0.3e A \n",Ib);
printf("(b)The value of Collector Current in the BJT circuit is %0.3e A \n",Ic);
printf("(c)The value of Collector-Emitter voltage in the circuit is %0.3f V \n",Vce);
// Part 2
// Given Data
Vce2=7; // Collector-Emitter voltage of BJT
Vcc=10; // DC voltage across Collector in V
Rc=2000; // Collector Resistance of BJT in ohm
Vbe=0.7; // Base-Emitter voltage of BJT
Rc2=2000; // Collector Resistance of BJT in ohm
// Calculations
constant=(Vcc-Vce2)/Rc;
Ib2=constant/101;
Ic2=100*Ib2;
Rb2=(Vcc-Vbe-(Rc2*constant))/Ib2;
printf("\nPart 2 \n");
printf("(a)The value of the Base Resistance of the Circuit is %0.3e ohm \n ",Rb2);
// Results
// Circuit 1: Value of Base Current of circuit = 0.031 mA
// Circuit 1: Value of Collector Current of circuit = 3.1 mA
// Circuit 1: Value of Collector-Emitter voltage of BJT circuit = 3.779 V
// Circuit 2: Value of BAse Resistance required = 424.24 K-ohm
|
0a738b45cb1ddb25da0b564b9b1455cd165f2ae6
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2444/CH6/EX6.8/ex6_8.sce
|
44b968a6d740586314aafc456be3f0b43b8ffdf6
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 299
|
sce
|
ex6_8.sce
|
// Exa 6.8
clc;
clear;
close;
format('v',6)
// Given data
A = 600;// unit less
Af = 50;// unit less
// Af = A/(1+(A*Beta));
Beta = ((A/Af)-1)/A;// unit less
//P = Vf/Vout = Beta*100;
P = Beta*100;// percentage of output voltage in %
disp(P,"The percentage of output voltage in % is");
|
e673bf44e3e4e36c1d4b0053d85f9fd948e1c204
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/770/CH15/EX15.19/15_19.sce
|
0354e6af17ecd5171cbc85bb4dd0c2a1a6d48fe7
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 2,787
|
sce
|
15_19.sce
|
clear;
clc;
//Example - 15.19
//Page number - 541
printf("Example - 15.19 and Page number - 541\n\n");
//Given
T = 45;//[C] - Temperature
x_1 = [0.0455,0.0940,0.1829,0.2909,0.3980,0.5069,0.5458,0.5946,0.7206,0.8145,0.8972,0.9573];
y_1 = [0.1056,0.1818,0.2783,0.3607,0.4274,0.4885,0.5098,0.5375,0.6157,0.6913,0.7869,0.8916];
P = [31.957,33.553,35.285,36.457,36.996,37.068,36.978,36.778,35.792,34.372,32.331,30.038];
// Pressure value for which x_1 = y_1 = 0, corresponds to P_2_sat,therefore
P_2_sat = 29.819;//[kPa]
// Pressure value for which x_1 = y_1 = 1, corresponds to P_1_sat,therefore
P_1_sat = 27.778;//[kPa]
x_2 = zeros(1,12);
y_2 = zeros(1,12);
Y1 = zeros(1,12);
Y2 = zeros(1,12);
alpha_12 = zeros(1,12);
GE_RT = zeros(1,12);
x1x2_GE_RT = zeros(1,12);
printf(" x_1 \t\t y_1 \t P \t\t Y1 \t\tY2 \t alpha_12 \t G_E/RT \t x1*x2/(G_E/RT)\n\n");
for i=1:12;
x_2(1,i) = 1 - x_1(i);
y_2(1,i) = 1 - y_1(i);
Y1(1,i) = (y_1(i)*P(i))/(x_1(i)*P_1_sat);
Y2(1,i) = (y_2(i)*P(i))/(x_2(i)*P_2_sat);
alpha_12(1,i) = (y_1(i)/x_1(i))/(y_2(i)/x_2(i));
GE_RT(1,i) = x_1(i)*log(Y1(i)) + x_2(i)*log(Y2(i));// G_E/(R*T)
x1x2_GE_RT(1,i) = (x_1(i)*x_2(i))/GE_RT(i);
printf(" %f\t %f\t %f \t %f \t %f \t %f\t %f \t%f\n\n",x_1(i),y_1(i),P(i),Y1(i),Y2(i),alpha_12(i),GE_RT(i),x1x2_GE_RT(i));
end
[M,N,sig]=reglin(x_1,x1x2_GE_RT);
// Linear regression between x_1 and x_1*x_2/(G_E/R*T) gives intercept = N and slope = M
// Now let us assume the system to follow van Laar activity coefficient model.
// x_1*x_2/(G_E/(R*T)) = x_1/B + x_2/A = x_1/B + (1 - x_1)/A = 1/A + (1/B - 1/A)*x_1 = N + M*x_1
// 1/A = N
A = 1/N;
// (1/B - 1/A) = M
B = 1/(M + 1/A);
printf("\n\n")
printf(" The value of van Laar parameters are, A = %f and B = %f \n\n",A,B);
Y1_infinity = exp(A);
Y2_infinity = exp(B);
// Azeotrope is formed when maxima ( or mainina) in pressure is observed and relative volatility becomes 1.
// This is the case for x_1 between 0.2980 and 0.5458.
// The ezeotropr os maximum pressure (and thus minimum boiling) because at azeotrope the system pressure is greater than vapour pressure of pure components.
// Now let us calculate the azeotrope composition.
// At azeotrope, Y1*P1_sat = Y2*P2_sat
// log(Y1/Y2) = log(P_2_sat/P_1_sat)
// From van Laar model we get
// log(P_2_sat/P_1_sat) = (A*B^(2)*2*x_2^(2))/(A*x_1 + B*x_2)^(2) + (B*A^(2)*2*x_1^(2))/(A*x_1 + B*x_2)^(2)
// Solving the above equation
deff('[y]=f(x_1)','y= log(P_2_sat/P_1_sat) - (A*B^(2)*(1-x_1)^(2))/(A*x_1 + B*(1-x_1))^(2) + (B*A^(2)*x_1^(2))/(A*x_1 + B*(1-x_1))^(2)');
x_1 = fsolve(0.1,f);
printf(" The azeotrope composition is given by x_1 = y_1 = %f\n",x_1);
|
5bfe3eed883fc6ec09c75c254050894d62b1c4cb
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1427/CH16/EX16.22/16_22.sce
|
64eecd04694b7cea14929bc6dfb119e46af66e09
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 265
|
sce
|
16_22.sce
|
//ques-16.22
//Determining order of the reaction
clc
r1=0.76; r2=1.07;//rate of reaction (in torr/s)
x1=5; x2=20;//percentage of decomposition
a1=1-(x1/100); a2=1-(x2/100);
n=log10(r2/r1)/log10(a1/a2);//order
printf("The order of the reaction is %.0f.",n);
|
5914cf61c76bab3064afb34c955e859b35404ced
|
be58a32d59591a9c6a9685b435d245984bdd44c0
|
/.env.tst
|
75d91297d3b591599770fd372412400f9c1a6848
|
[] |
no_license
|
yifan1002/soldier
|
3e26c34265efb2e1473814ebdf035696f3dc8cc7
|
bb8c8e524a0c941179572659341ab6c755727255
|
refs/heads/master
| 2023-01-14T11:12:45.431008
| 2019-12-20T10:07:56
| 2019-12-20T10:07:56
| 224,424,041
| 0
| 0
| null | 2023-01-05T01:49:42
| 2019-11-27T12:17:53
|
Vue
|
UTF-8
|
Scilab
| false
| false
| 71
|
tst
|
.env.tst
|
MODE_ENV = 'production'
VUE_APP_CURRENTMODE = 'test'
outputDir = 'test'
|
4577a0d9549b1ce8277b156e1b84f27423a75963
|
e6d5f1d801a3fe887b5dc04b8cc0a9eabc1fd432
|
/Semana_4/act4.sce
|
d0637ef14fb81cd71cc9a4bc7b30092ee7208fad
|
[] |
no_license
|
lordjuacs/MateIII
|
70def332063e56eb10fb47678a7e6130dc0dca63
|
164c53b61c9e35e565121f77ba2c578680a3ab56
|
refs/heads/master
| 2021-05-24T15:56:01.078904
| 2020-07-27T19:57:34
| 2020-07-27T19:57:34
| 253,643,962
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,190
|
sce
|
act4.sce
|
//Actividad 4
//Origen --> O(0;0;0)
//P2 --> (-1;1;-1)
//R3 --> R3
//Rotación alrededor de la recta que pasa por O y P2
//P1(1;-1;-1) se convierte en P3(-1;-1;1)
clc
disp("MATE III - SEMANA 4")
disp("GRUPO 2")
disp("Actividad 4")
O = [0 0 0]'
P2 = [-1 1 -1]'
V = [P2(1)-O(1);P2(2)-O(2);P2(3)-O(3)]
Vuni = V/((sum(V.^2))^0.5)
disp(Vuni, "Vector unitario")
//Puntos a transformar
P1 = [1 -1 -1]'
P0 = [1 1 1]'
P2 = [-1 1 -1]'
P3 = [-1 -1 1]'
//Ángulo teta
angulo = (2*%pi/3)
//Matriz de coeficientes de la transformación
R = [cos(angulo)+(Vuni(1)^2)*(1-cos(angulo)), Vuni(1)*Vuni(2)*(1-cos(angulo))-Vuni(3)*sin(angulo), Vuni(1)*Vuni(3)*(1-cos(angulo))+Vuni(2)*sin(angulo); Vuni(2)*Vuni(1)*(1-cos(angulo))+Vuni(3)*sin(angulo),cos(angulo)+(Vuni(2)^2)*(1-cos(angulo)), Vuni(2)*Vuni(3)*(1-cos(angulo))-Vuni(1)*sin(angulo); Vuni(3)*Vuni(1)*(1-cos(angulo))-Vuni(2)*sin(angulo), Vuni(3)*Vuni(2)*(1-cos(angulo))+Vuni(1)*sin(angulo), cos(angulo)+(Vuni(3)^2)*(1-cos(angulo))]
disp(R, "Matriz de coeficientes")
disp(P0, "P0")
disp(R*P0, "P0 Transformado")
disp(P1, "P1")
disp(R*P1, "P1 Transformado")
disp(P2, "P2")
disp(R*P2, "P2 Transformado")
disp(P3, "P3")
disp(R*P3, "P3 Transformado")
|
efa372dd14bbf4afd15ac2faf08168c9d2572e87
|
b24d354cfcd174c92760535d8b71e22ced005d81
|
/DSP functions/zpklp2xn/test_6.sce
|
9b2caa3d90176d05b041499174cb434c0e28f75c
|
[] |
no_license
|
shreniknambiar/FOSSEE-Signal-Processing-Toolbox
|
57ad8e2a71d64f95c4ccfd131e00095cf2b9c6f8
|
143cf61eff31240870dc0c4f61e32818a4482365
|
refs/heads/master
| 2021-01-01T18:25:34.435606
| 2017-07-25T18:23:47
| 2017-07-25T18:23:47
| 98,334,322
| 0
| 0
| null | 2017-07-25T17:48:00
| 2017-07-25T17:47:59
| null |
UTF-8
|
Scilab
| false
| false
| 309
|
sce
|
test_6.sce
|
// Test # 6 : Range test for Input Argument #4 or Input Argument #5
exec('./zpklp2xn.sci',-1);
[z,p,k,n,d]=zpklp2xn(0.2,1,4,[2 0.9],[4,0.7]);
//!--error 10000
//Wo must be in normalised and ascending form
//at line 56 of function zpklp2xn called by :
//[z,p,k,n,d]=zpklp2xn(0.2,1,4,[5 0.9],[0.4,0.7]);
|
342098d1db849c1e1eb8dd9306e4f92840d7bc3d
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/503/CH7/EX7.60/ch7_60.sci
|
5253ebcab58b4815816bccc3d55470ab20f355a7
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 660
|
sci
|
ch7_60.sci
|
//to determine load torque and motor eff,armature current for max motor eff and ots value
clc;
V=250;
Ia=35;
Ra=.5;
Ea=V-Ia*Ra;
Poutg=Ea*Ia;
Prot=500;
Pout_net=Poutg-Prot;
n=1250;
w=2*%pi*n/60;
T_L=Pout_net/w;disp(T_L,'load torque(Nm)');
Rf=250;
If=V/Rf;
I_L=If+Ia;
Pin=I_L*V;
eff=Pout_net*100/Pin;disp(eff,'efficiency(%)');
Pk=Prot+V*If;
Ia=sqrt(Pk/Ra);disp(Ia,'armature current(A)');
Tloss=2*Pk;
I_L=If+Ia;
Pin=I_L*V;
eff_max=1-(Tloss/Pin);disp(eff_max*100,'max efficiency(%)');
Ea1=V-Ia*Ra;
n1=n*Ea1/Ea;disp(n1,'speed(rpm)');
w=2*%pi*n1/60;
Poutg=Ea1*Ia;
Pout_net=Poutg-Prot;
T_L=Pout_net/w;disp(T_L,'load torque(Nm)');
|
dc5c5c0616db18a5b2702929151821866fa5b122
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/50/CH5/EX5.17/ex_5_17.sce
|
f0e6d0b6f98a1f74d7bc11826e6fc5ff1d920e37
|
[] |
no_license
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FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 776
|
sce
|
ex_5_17.sce
|
// example 5.17
// caption: gauss-legendre method
// I= integral 2*x/(1+x^4) in the range [1,2];
// first we need ti transform the interval [1,2 ] to [-1,1], since gauss-legendre three point method is applicable in the range[-1,1],
// let t=ax+b;
// solving for a,b from the two ranges, we get a=1/2; b=3/2; x=(t+3)/2;
// hence I=integral 2*x/(1+x^4) in the range [0,1]= integral 8*(t+3)/16+(t+3)^4 in the range [-1,1];
deff('[y]=f(t)','y=8*(t+3)/(16+(t+3)^4) ');
// 1) since , from gauss legendre one point rule;
I1=2*f(0)
// 2) since , from gauss legendre two point rule;
I2=f(-1/sqrt(3))+f(1/sqrt(3))
// 3) since , from gauss legendre three point rule;
I=(1/9)*(5*f(-sqrt(3/5))+8*f(0)+5*f(sqrt(3/5)))
// we know , exact solution is 0.5404;
|
491e2104acc72648230fe9ca70f26128f44ecbcc
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3784/CH1/EX1.6/Ex1_6.sce
|
9360fe65ce764c823bf086f33d57afde96412e65
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,617
|
sce
|
Ex1_6.sce
|
clc
// Variable Initialization
Vm=200 //Supply Voltage in Volts
N=1000 //speed of motor in RPM
I=13 //Motor current in Ampere
Ra=3 //Armature circuit resistance in Ohm
L=100e-3 //Armature circuit Inductance in mH
V=230 //Ac Source voltage in Volts
f=50 //source Frequency in Hz
a=30
aa=(30*%pi)/180 //in rad/sec
N2=400
//Solution
P=atand((2*%pi*f*L)/Ra) // In Degree
Cot_P=1/(tand(P))
A=exp(-%pi*Cot_P)
B=exp((-aa)*Cot_P)
Z=sqrt((Ra^(2))+((2*%pi*f*L)^2)) //Impedance In Ohm
Eb=Vm-(I*Ra) //back emf in Volts
w=(2*%pi*N)/60 //Angular Speed in rad/sec
K=Eb/w
AA=(Ra*V*1.41)/(K*Z)
Wmc=AA*((sind(P)*B)-(sind(a-P)*A))*(1/(1-A)) //Critical Speed in rad/Sec
Wrpm=(Wmc*60)/(2*%pi) //speed in rpm
//As the motor speed of 400 rpm is less than the critical speed ,the drive is operating under continuous conduction mode
af=30 //firing angle in Degree
Va=(V*1.414)*(1+cosd(af))*(1/%pi) //Armature voltage in volts
//At 400 RPM
Eb1=Eb*(N2/N) //This Value Is Wrongly Calculated in Textbook
T=K*(Va-Eb1)*(1/Ra) //Torque in N-m
//Motor back emf for critical speed equal to 1149.67 rpm
Ec=(Wrpm*Eb)/N //critical emf in volts
Tc=K*(Va-Ec)*(1/Ra) //Critical Torque in N-m
//Since the motor torque of 70 N-m is greater than the critical torque Tc ,the drive is operating in continuous conduction
Ia=T/K //Armature current in Amp
Eb2=Va-(Ia*Ra) // Back emf in Volts
Nm=(Eb2*N)/161 //Answer changed due wrong value is taken in book of Eb1
//Results
printf('\n\n The motor Torque =%0.1f N-m \n\n',T)
printf('\n\n The motor Speed =%0.1f RPM \n\n',Nm)
//The answer provided in the textbook is wrong
|
e9cb7cc1c6477e1f4b65c719d599f44d9ecc8519
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/812/CH4/EX4.07/4_07.sce
|
6f000042702ab03bbe575981095732f4ad320fae
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 544
|
sce
|
4_07.sce
|
//Force to hold//
pathname=get_absolute_file_path('4.07.sce')
filename=pathname+filesep()+'4.07-data.sci'
exec(filename)
//Velocity at section 1(in m/sec):
V1=V2*A2/A1
//Gauge pressure(in kPa):
p1g=p1-patm
u1=V1;u2=-V2;
//Reaction force component in the x direction(in N):
Rx=-p1g*A1-u1*d*V1*A1
//Reaction force component in the y direction(in N):
Ry=u2*d*V2*A2
printf("\n\nRESULTS\n\n")
printf("\n\nForce to hold elbow acting to the left: %.3f kN\n\n",Rx/1000)
printf("\n\nForce to hold elbow acting downwards: %.3f N\n\n",Ry)
|
449b0083d071341839c43730714dbffc69d4111b
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3673/CH3/EX3.7/Ex3_7.sce
|
8bda2244545050c827e48006fe018dc2a5492dd9
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 447
|
sce
|
Ex3_7.sce
|
//Example 3_7 page no:122
clc
R4=4//resistance in ohm
R3=3//resistance in ohm
R6=6//resistance in ohm
Rt=((R3*R6)/(R3+R6))//resistance in parallel
//after adding ammeter
R3=4
RT=R4+((R3*R6)/(R3+R6))//total resistance
It=10/(4+((6*3)/(6+3)))//total current
I3=It*Rt/R3
V=It*1
Ia=V/RT;
Ia=1.21-Ia;
disp(Ia,"current flowing in ammeter is (in A)")
//current in ammeter has more decimal places hence values are rounded off in text book
|
999ecd190f89de19b05933cdd1fb9fff780d7a27
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3845/CH6/EX6.1/Ex6_1.sce
|
4a5427f9d03886c3d8a8055d9a0f8f5c55e7c692
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 418
|
sce
|
Ex6_1.sce
|
//Example 6.1
v=15;//Velocity (m/s)
r=0.300;//Radius (m)
omega=v/r;//Angular velocity (rad/s)
printf('Angular Velocity = %0.1f rad/s',omega)
//Discussion:
r1=1.2;//Tire radius for earth mover (m)
omega1=v/r1;//Angular velocity (rad/s)
printf('\nDiscussion: For earth mover\nAngular Velocity = %0.1f rad/s',omega1)
//Openstax - College Physics
//Download for free at http://cnx.org/content/col11406/latest
|
bb4bd2861a564ebe0639439e4ae07e40e71d2862
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/995/CH4/EX4.10/Ex4_10.sce
|
c407cacd2428e3cb68bbca41e0b10112af00aea7
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 195
|
sce
|
Ex4_10.sce
|
//Ex:4.10
clc;
clear;
close;
L=1*10^-3;
f1=100;
f2=10000;
X_L1=(2*%pi*f1*L);
X_L2=(2*%pi*f2*L);
printf("Reactance at 100Hz = %f ohm",X_L1);
printf("\nReactance at 10kHz = %f ohm",X_L2);
|
f0a3c8db7e7def254d39c372330993fe9aab4f08
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3131/CH19/EX19.6/Ex19_6.sce
|
b1ca583579122808d6745b87d08b4d53097af734
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 412
|
sce
|
Ex19_6.sce
|
clear all; clc;
disp("Ex 19_6")
// Using Principle of Conservation of Angular Momentum,
//Eqn 1 : (0.2-0.03)*10*(v_G)1+0.156*w_1=0.2*10*(v_G)2+0.156*w_2
//Since no slipping occurs,equation 1 reduces to (v_G)2=0.892*(v_G)1
//Using Conservation of Energy Principle, Equation 2 is: 0.5*10*(v_G)2^2 + 0.5*0.156*w_2^2+0=0+{98.1*0.03}
//Put w_2=5*(v_G)2 and equation 1 in the above equation,
disp("(v_G)1=0.729 m/s")
|
c4c904d7f8a9b8f602dc6c3491826d3adbb4ba20
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/770/CH18/EX18.2/18_2.sce
|
4f46a16fdaca8aa3cf09859be36c4194447f8a01
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,812
|
sce
|
18_2.sce
|
clear;
clc;
//Example - 18.2
//Page number - 650
printf("Example - 18.2 and Page number - 650\n\n");
// Given
T_1 = 298.15;//[K] - Standard reaction temperature
a_CO2 = 5.316;
a_H2O = 7.700;
a_O2 = 6.085;
a_C2H6 = 1.648;
b_CO2 = 1.4285*10^(-2);
b_H2O = 0.04595*10^(-2);
b_O2 = 0.3631*10^(-2);
b_C2H6 = 4.124*10^(-2);
c_CO2 = -0.8362*10^(-5);
c_H2O = 0.2521*10^(-5);
c_O2 = -0.1709*10^(-5);
c_C2H6 = -1.530*10^(-5);
d_CO2 = 1.784*10^(-9);
d_H2O = -0.8587*10^(-9);
d_O2 = 0.3133*10^(-9);
d_C2H6 = 1.740*10^(-9);
// The standard enthalpy of formation at 298.15 K is given by
delta_H_for_CO2 = -94.052;//[kcal/mol]
delta_H_for_C2H6 = -20.236;//[kcal/mol]
delta_H_for_H2O = -57.7979;//[kcal/mol]
// The reaction with stoichiometric amount of air is
// C2H6 + (7/2)O2 - 2CO2 + 3H2O
// The reaction with 4 mol of O2 and 10 mol CO2 is
// C2H6 + 4O2 + 10CO2 - 12H2O + 3H2O + 0.5O2
// The product consists of 12 mol of CO2, 3 mol of water vapour and 0.5 mol of oxygen
delta_H_rkn_298 = 2*delta_H_for_CO2 + 3*delta_H_for_H2O - delta_H_for_C2H6;//[kcal]
delta_H_rkn_298 = delta_H_rkn_298*10^(3);//[cal]
// For exit stream
sum_ai_ni = 12*a_CO2 + 3*a_H2O + 0.5*a_O2;
sum_bi_ni = 12*b_CO2 + 3*b_H2O + 0.5*b_O2;
sum_ci_ni = 12*c_CO2 + 3*c_H2O + 0.5*c_O2;
sum_di_ni = 12*d_CO2 + 3*d_H2O + 0.5*d_O2;
// From energy balance equation we get
// delta_H_rkn_298 + sum_ai_ni*(T_2 - T_1) + (sum_bi_ni/2)*(T_2^(2) - T_1^(2)) + (sum_ci_ni/3)*(T_2^(3) - T_1^(3)) + (sum_di_ni/4)*(T_2^(4) - T_1^(4))
// Solving above equation for T_2
deff('[y]=f(T_2)','y=delta_H_rkn_298 +sum_ai_ni*(T_2-T_1)+(sum_bi_ni/2)*(T_2^(2)-T_1^(2))+(sum_ci_ni/3)*(T_2^(3)-T_1^(3))+(sum_di_ni/4)*(T_2^(4)-T_1^(4))');
T_2 = fsolve(-1,f);
printf(" The adiabatic flame temperature is %f K",T_2);
|
1ec52ad5290bcd21c009fc8acd59416f1d0d771b
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3523/CH12/EX12.17.10/Ex12_10.sce
|
61f8a1d626f5bd309c689d38c832b7fd491676d3
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 392
|
sce
|
Ex12_10.sce
|
//Example 10// Ch 12
clc;
clear;
close;
// given data
a=1;//inner thickness of cable in cm
epsilonr1=4.5;
epsilonr2=3.6;
r1=2;//in cm
b=2.65;//in cm
V=53.8;//in kV
Emax1=V/(a*[log(r1)+(epsilonr1/epsilonr2)*log(1.325)]);
printf("max stress in rubber %f kV/cm",Emax1)
Emax2=V/(r1*[((epsilonr2/epsilonr1)*log(r1))+ log(1.325)]);
printf("max stress in paper %f kV/cm",Emax2)
|
e9ac42237276bc014bba4e250be2d9504415c18f
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/132/CH14/EX14.5/Example14_5.sce
|
3a039198467d3a95ca12e76e24d186a376801e54
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 693
|
sce
|
Example14_5.sce
|
//Example 14.5
//Program to Determine the Magnitude and the Frequency of the
//wave Voltage fed to the Y-input
clear;
clc ;
close ;
//Given Circuit Data
Am=3.5; //V, Amplitude
tb=0.1*10^(-3); //seconds
TP=4; //Time Period
//Calculation
Vm=2*Am;
V=Vm/sqrt(2);
T=TP*tb;
f=1/T;
//Displaying The Results in Command Window
printf("\n\t The Magnitude of Wave Voltage, V = %f V .",V);
printf("\n\t The Frequency of Wave Voltage, f = %f kHz .",f/10^3);
//Plot of the given Wave
figure
x=-6:0.01:6;
y=Am*cos(1.6*x); //Given Waveform
plot (x,y);
a= gca ();
a.x_location="origin";
a.y_location="origin";
xlabel ('X Axis');
ylabel ('Y Axis');
title ('CRO OUTPUT');
xgrid (6);
|
64fada471b227bc68205fbe01b2ee12f19cd2694
|
f542bc49c4d04b47d19c88e7c89d5db60922e34e
|
/PresentationFiles_Subjects/CONT/RQ44PTA/ATWM1_Working_Memory_MEG_RQ44PTA_Session1/ATWM1_Working_Memory_MEG_Salient_Cued_Run1.sce
|
5b3146121b08513becd9d88331a6ff694a67e843
|
[] |
no_license
|
atwm1/Presentation
|
65c674180f731f050aad33beefffb9ba0caa6688
|
9732a004ca091b184b670c56c55f538ff6600c08
|
refs/heads/master
| 2020-04-15T14:04:41.900640
| 2020-02-14T16:10:11
| 2020-02-14T16:10:11
| 56,771,016
| 0
| 1
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 49,384
|
sce
|
ATWM1_Working_Memory_MEG_Salient_Cued_Run1.sce
|
# ATWM1 MEG Experiment
scenario = "ATWM1_Working_Memory_MEG_salient_cued_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 = 28;
default_font = "Arial";
default_background_color = 0 ,0 ,0 ;
write_codes=true; # for MEG only
begin;
#Picture definitions
box { height = 300; width = 300; color = 0, 0, 0;} frame1;
box { height = 290; width = 290; 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 = 290; width = 290; color = 128, 128, 128;} 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;
41 62 292 292 399 125 1842 2992 2242 fixation_cross gabor_144 gabor_055 gabor_030 gabor_091 gabor_144 gabor_055_alt gabor_030_alt gabor_091 "1_1_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2250_gabor_patch_orientation_144_055_030_091_target_position_2_3_retrieval_position_2" gabor_circ gabor_055_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_1_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_055_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2242 2992 2592 fixation_cross gabor_054 gabor_166 gabor_015 gabor_126 gabor_054 gabor_166 gabor_015_alt gabor_126_alt "1_2_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2600_gabor_patch_orientation_054_166_015_126_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_081_framed blank blank blank blank fixation_cross_target_position_3_4 "1_2_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_081_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1992 2992 1892 fixation_cross gabor_034 gabor_109 gabor_004 gabor_172 gabor_034 gabor_109_alt gabor_004_alt gabor_172 "1_3_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_1900_gabor_patch_orientation_034_109_004_172_target_position_2_3_retrieval_position_2" gabor_circ gabor_156_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_3_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_156_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1892 2992 2492 fixation_cross gabor_029 gabor_084 gabor_136 gabor_064 gabor_029_alt gabor_084 gabor_136_alt gabor_064 "1_4_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2500_gabor_patch_orientation_029_084_136_064_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_136_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_4_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_136_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1942 2992 2142 fixation_cross gabor_038 gabor_072 gabor_116 gabor_003 gabor_038_alt gabor_072_alt gabor_116 gabor_003 "1_5_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_2150_gabor_patch_orientation_038_072_116_003_target_position_1_2_retrieval_position_1" gabor_178_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_5_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_178_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 64 292 292 399 125 1842 2992 2192 fixation_cross gabor_031 gabor_005 gabor_121 gabor_076 gabor_031_alt gabor_005 gabor_121 gabor_076_alt "1_6_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_300_300_399_1850_3000_2200_gabor_patch_orientation_031_005_121_076_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_121_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_6_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_121_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2142 2992 2542 fixation_cross gabor_175 gabor_147 gabor_089 gabor_125 gabor_175_alt gabor_147_alt gabor_089 gabor_125 "1_7_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_2550_gabor_patch_orientation_175_147_089_125_target_position_1_2_retrieval_position_1" gabor_175_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_7_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_175_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1792 2992 1992 fixation_cross gabor_155 gabor_002 gabor_176 gabor_119 gabor_155 gabor_002_alt gabor_176_alt gabor_119 "1_8_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2000_gabor_patch_orientation_155_002_176_119_target_position_2_3_retrieval_position_2" gabor_circ gabor_139_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_8_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_139_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 64 292 292 399 125 2142 2992 2242 fixation_cross gabor_054 gabor_117 gabor_089 gabor_161 gabor_054_alt gabor_117 gabor_089 gabor_161_alt "1_9_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_300_300_399_2150_3000_2250_gabor_patch_orientation_054_117_089_161_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_089_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_9_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_089_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1742 2992 2242 fixation_cross gabor_063 gabor_177 gabor_147 gabor_124 gabor_063_alt gabor_177 gabor_147_alt gabor_124 "1_10_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2250_gabor_patch_orientation_063_177_147_124_target_position_1_3_retrieval_position_1" gabor_063_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_10_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_063_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1892 2992 2492 fixation_cross gabor_091 gabor_005 gabor_128 gabor_021 gabor_091_alt gabor_005_alt gabor_128 gabor_021 "1_11_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2500_gabor_patch_orientation_091_005_128_021_target_position_1_2_retrieval_position_2" gabor_circ gabor_005_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_11_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_005_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2192 2992 2492 fixation_cross gabor_131 gabor_093 gabor_024 gabor_157 gabor_131 gabor_093 gabor_024_alt gabor_157_alt "1_12_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2200_3000_2500_gabor_patch_orientation_131_093_024_157_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_024_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_12_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_024_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2192 2992 2042 fixation_cross gabor_036 gabor_002 gabor_144 gabor_056 gabor_036_alt gabor_002_alt gabor_144 gabor_056 "1_13_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2050_gabor_patch_orientation_036_002_144_056_target_position_1_2_retrieval_position_1" gabor_086_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_13_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_086_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1792 2992 1942 fixation_cross gabor_161 gabor_037 gabor_009 gabor_126 gabor_161_alt gabor_037_alt gabor_009 gabor_126 "1_14_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_1950_gabor_patch_orientation_161_037_009_126_target_position_1_2_retrieval_position_2" gabor_circ gabor_087_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_14_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_087_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2042 2992 2442 fixation_cross gabor_132 gabor_060 gabor_177 gabor_111 gabor_132 gabor_060_alt gabor_177_alt gabor_111 "1_15_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_2450_gabor_patch_orientation_132_060_177_111_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_177_framed gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_15_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_177_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 63 292 292 399 125 1842 2992 1992 fixation_cross gabor_058 gabor_033 gabor_090 gabor_145 gabor_058_alt gabor_033 gabor_090 gabor_145_alt "1_16_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_300_300_399_1850_3000_2000_gabor_patch_orientation_058_033_090_145_target_position_1_4_retrieval_position_2" gabor_circ gabor_170_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_16_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_170_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2042 2992 1942 fixation_cross gabor_100 gabor_130 gabor_165 gabor_076 gabor_100_alt gabor_130 gabor_165_alt gabor_076 "1_17_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_1950_gabor_patch_orientation_100_130_165_076_target_position_1_3_retrieval_position_1" gabor_100_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_17_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_100_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1942 2992 2342 fixation_cross gabor_068 gabor_174 gabor_134 gabor_110 gabor_068 gabor_174 gabor_134_alt gabor_110_alt "1_18_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_2350_gabor_patch_orientation_068_174_134_110_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_156_framed blank blank blank blank fixation_cross_target_position_3_4 "1_18_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_156_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1742 2992 2342 fixation_cross gabor_080 gabor_030 gabor_096 gabor_053 gabor_080 gabor_030 gabor_096_alt gabor_053_alt "1_19_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2350_gabor_patch_orientation_080_030_096_053_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_007_framed blank blank blank blank fixation_cross_target_position_3_4 "1_19_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_007_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2092 2992 1942 fixation_cross gabor_037 gabor_058 gabor_115 gabor_090 gabor_037 gabor_058_alt gabor_115 gabor_090_alt "1_20_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_1950_gabor_patch_orientation_037_058_115_090_target_position_2_4_retrieval_position_2" gabor_circ gabor_058_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_20_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_058_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2242 2992 1892 fixation_cross gabor_088 gabor_059 gabor_124 gabor_144 gabor_088_alt gabor_059 gabor_124_alt gabor_144 "1_21_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_1900_gabor_patch_orientation_088_059_124_144_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_124_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_21_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_124_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 64 292 292 399 125 1892 2992 2442 fixation_cross gabor_076 gabor_031 gabor_157 gabor_048 gabor_076_alt gabor_031 gabor_157 gabor_048_alt "1_22_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_300_300_399_1900_3000_2450_gabor_patch_orientation_076_031_157_048_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_157_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_22_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_157_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1742 2992 2092 fixation_cross gabor_019 gabor_109 gabor_040 gabor_152 gabor_019_alt gabor_109 gabor_040_alt gabor_152 "1_23_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2100_gabor_patch_orientation_019_109_040_152_target_position_1_3_retrieval_position_1" gabor_019_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_23_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_019_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 64 292 292 399 125 2242 2992 2592 fixation_cross gabor_003 gabor_077 gabor_127 gabor_093 gabor_003 gabor_077_alt gabor_127_alt gabor_093 "1_24_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_300_300_399_2250_3000_2600_gabor_patch_orientation_003_077_127_093_target_position_2_3_retrieval_position_1" gabor_003_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_24_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_003_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1942 2992 2142 fixation_cross gabor_034 gabor_162 gabor_052 gabor_108 gabor_034 gabor_162 gabor_052_alt gabor_108_alt "1_25_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_2150_gabor_patch_orientation_034_162_052_108_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_052_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_25_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_052_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1892 2992 2042 fixation_cross gabor_070 gabor_149 gabor_097 gabor_125 gabor_070 gabor_149_alt gabor_097 gabor_125_alt "1_26_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2050_gabor_patch_orientation_070_149_097_125_target_position_2_4_retrieval_position_2" gabor_circ gabor_149_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_26_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_149_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1942 2992 1992 fixation_cross gabor_152 gabor_004 gabor_062 gabor_126 gabor_152_alt gabor_004 gabor_062_alt gabor_126 "1_27_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_2000_gabor_patch_orientation_152_004_062_126_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_110_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_27_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_110_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2192 2992 2092 fixation_cross gabor_169 gabor_111 gabor_051 gabor_093 gabor_169 gabor_111_alt gabor_051_alt gabor_093 "1_28_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2100_gabor_patch_orientation_169_111_051_093_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_003_framed gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_28_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_003_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1842 2992 2242 fixation_cross gabor_040 gabor_145 gabor_078 gabor_168 gabor_040 gabor_145 gabor_078_alt gabor_168_alt "1_29_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2250_gabor_patch_orientation_040_145_078_168_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_126_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_29_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_126_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2192 2992 1892 fixation_cross gabor_038 gabor_176 gabor_110 gabor_065 gabor_038_alt gabor_176_alt gabor_110 gabor_065 "1_30_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2200_3000_1900_gabor_patch_orientation_038_176_110_065_target_position_1_2_retrieval_position_2" gabor_circ gabor_176_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_30_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_176_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1942 2992 2492 fixation_cross gabor_179 gabor_013 gabor_053 gabor_128 gabor_179_alt gabor_013 gabor_053_alt gabor_128 "1_31_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_2500_gabor_patch_orientation_179_013_053_128_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_053_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_31_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_053_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2042 2992 2342 fixation_cross gabor_103 gabor_148 gabor_125 gabor_041 gabor_103_alt gabor_148 gabor_125 gabor_041_alt "1_32_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2350_gabor_patch_orientation_103_148_125_041_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_179_framed blank blank blank blank fixation_cross_target_position_1_4 "1_32_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_179_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 63 292 292 399 125 2092 2992 1992 fixation_cross gabor_008 gabor_113 gabor_037 gabor_098 gabor_008 gabor_113_alt gabor_037_alt gabor_098 "1_33_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_300_300_399_2100_3000_2000_gabor_patch_orientation_008_113_037_098_target_position_2_3_retrieval_position_1" gabor_145_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_33_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_145_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1792 2992 2242 fixation_cross gabor_017 gabor_175 gabor_130 gabor_056 gabor_017_alt gabor_175 gabor_130_alt gabor_056 "1_34_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2250_gabor_patch_orientation_017_175_130_056_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_085_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_34_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_085_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1892 2992 1892 fixation_cross gabor_037 gabor_120 gabor_168 gabor_153 gabor_037_alt gabor_120 gabor_168 gabor_153_alt "1_35_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_1900_gabor_patch_orientation_037_120_168_153_target_position_1_4_retrieval_position_1" gabor_085_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_35_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_085_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 64 292 292 399 125 1792 2992 2342 fixation_cross gabor_032 gabor_086 gabor_137 gabor_061 gabor_032_alt gabor_086_alt gabor_137 gabor_061 "1_36_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_300_300_399_1800_3000_2350_gabor_patch_orientation_032_086_137_061_target_position_1_2_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_061_framed blank blank blank blank fixation_cross_target_position_1_2 "1_36_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_061_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1992 2992 2292 fixation_cross gabor_084 gabor_173 gabor_036 gabor_015 gabor_084 gabor_173 gabor_036_alt gabor_015_alt "1_37_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2300_gabor_patch_orientation_084_173_036_015_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_015_framed blank blank blank blank fixation_cross_target_position_3_4 "1_37_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_015_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2042 2992 2542 fixation_cross gabor_174 gabor_149 gabor_107 gabor_043 gabor_174_alt gabor_149 gabor_107 gabor_043_alt "1_38_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_2550_gabor_patch_orientation_174_149_107_043_target_position_1_4_retrieval_position_1" gabor_174_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_38_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_174_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1842 2992 2442 fixation_cross gabor_034 gabor_178 gabor_069 gabor_140 gabor_034 gabor_178_alt gabor_069_alt gabor_140 "1_39_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2450_gabor_patch_orientation_034_178_069_140_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_069_framed gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_39_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_069_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2042 2992 1892 fixation_cross gabor_010 gabor_179 gabor_072 gabor_039 gabor_010 gabor_179 gabor_072_alt gabor_039_alt "1_40_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_1900_gabor_patch_orientation_010_179_072_039_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_089_framed blank blank blank blank fixation_cross_target_position_3_4 "1_40_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_089_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2092 2992 2292 fixation_cross gabor_051 gabor_073 gabor_025 gabor_094 gabor_051_alt gabor_073_alt gabor_025 gabor_094 "1_41_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2300_gabor_patch_orientation_051_073_025_094_target_position_1_2_retrieval_position_1" gabor_051_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_41_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_051_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 64 292 292 399 125 2142 2992 2342 fixation_cross gabor_111 gabor_006 gabor_081 gabor_026 gabor_111 gabor_006_alt gabor_081 gabor_026_alt "1_42_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_300_300_399_2150_3000_2350_gabor_patch_orientation_111_006_081_026_target_position_2_4_retrieval_position_1" gabor_111_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_42_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_111_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1742 2992 2192 fixation_cross gabor_111 gabor_023 gabor_165 gabor_086 gabor_111 gabor_023_alt gabor_165 gabor_086_alt "1_43_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2200_gabor_patch_orientation_111_023_165_086_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_133_framed blank blank blank blank fixation_cross_target_position_2_4 "1_43_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_133_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1992 2992 2092 fixation_cross gabor_014 gabor_150 gabor_127 gabor_085 gabor_014 gabor_150_alt gabor_127_alt gabor_085 "1_44_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2100_gabor_patch_orientation_014_150_127_085_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_127_framed gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_44_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_127_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2242 2992 2192 fixation_cross gabor_134 gabor_020 gabor_102 gabor_084 gabor_134 gabor_020_alt gabor_102 gabor_084_alt "1_45_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2200_gabor_patch_orientation_134_020_102_084_target_position_2_4_retrieval_position_2" gabor_circ gabor_020_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_45_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_020_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1992 2992 2042 fixation_cross gabor_061 gabor_090 gabor_007 gabor_034 gabor_061 gabor_090_alt gabor_007 gabor_034_alt "1_46_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2050_gabor_patch_orientation_061_090_007_034_target_position_2_4_retrieval_position_2" gabor_circ gabor_090_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_46_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_090_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 63 292 292 399 125 2142 2992 2592 fixation_cross gabor_160 gabor_128 gabor_091 gabor_053 gabor_160 gabor_128_alt gabor_091_alt gabor_053 "1_47_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_300_300_399_2150_3000_2600_gabor_patch_orientation_160_128_091_053_target_position_2_3_retrieval_position_1" gabor_112_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_47_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_112_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1742 2992 2592 fixation_cross gabor_041 gabor_150 gabor_001 gabor_123 gabor_041_alt gabor_150_alt gabor_001 gabor_123 "1_48_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2600_gabor_patch_orientation_041_150_001_123_target_position_1_2_retrieval_position_1" gabor_180_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_48_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_180_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2092 2992 1942 fixation_cross gabor_027 gabor_070 gabor_042 gabor_178 gabor_027_alt gabor_070 gabor_042_alt gabor_178 "1_49_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2100_3000_1950_gabor_patch_orientation_027_070_042_178_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_091_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_49_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_091_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1892 2992 2392 fixation_cross gabor_164 gabor_124 gabor_141 gabor_105 gabor_164_alt gabor_124 gabor_141 gabor_105_alt "1_50_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2400_gabor_patch_orientation_164_124_141_105_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_058_framed blank blank blank blank fixation_cross_target_position_1_4 "1_50_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_058_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2242 2992 2392 fixation_cross gabor_038 gabor_167 gabor_128 gabor_103 gabor_038_alt gabor_167 gabor_128_alt gabor_103 "1_51_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2400_gabor_patch_orientation_038_167_128_103_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_079_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_51_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_079_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 64 292 292 399 125 2192 2992 2292 fixation_cross gabor_054 gabor_079 gabor_110 gabor_140 gabor_054 gabor_079_alt gabor_110 gabor_140_alt "1_52_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_300_300_399_2200_3000_2300_gabor_patch_orientation_054_079_110_140_target_position_2_4_retrieval_position_1" gabor_054_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_52_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_054_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2242 2992 2542 fixation_cross gabor_038 gabor_103 gabor_075 gabor_013 gabor_038 gabor_103 gabor_075_alt gabor_013_alt "1_53_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2550_gabor_patch_orientation_038_103_075_013_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_150_framed blank blank blank blank fixation_cross_target_position_3_4 "1_53_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_150_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2042 2992 2292 fixation_cross gabor_081 gabor_049 gabor_155 gabor_100 gabor_081 gabor_049 gabor_155_alt gabor_100_alt "1_54_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_2300_gabor_patch_orientation_081_049_155_100_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_155_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_54_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_155_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1842 2992 2092 fixation_cross gabor_124 gabor_011 gabor_166 gabor_077 gabor_124 gabor_011_alt gabor_166 gabor_077_alt "1_55_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2100_gabor_patch_orientation_124_011_166_077_target_position_2_4_retrieval_position_2" gabor_circ gabor_011_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_55_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_011_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 63 292 292 399 125 1742 2992 2292 fixation_cross gabor_178 gabor_005 gabor_032 gabor_072 gabor_178 gabor_005 gabor_032_alt gabor_072_alt "1_56_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_300_300_399_1750_3000_2300_gabor_patch_orientation_178_005_032_072_target_position_3_4_retrieval_position_2" gabor_circ gabor_053_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_56_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_053_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2142 2992 2392 fixation_cross gabor_115 gabor_132 gabor_027 gabor_008 gabor_115 gabor_132 gabor_027_alt gabor_008_alt "1_57_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2400_gabor_patch_orientation_115_132_027_008_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_056_framed blank blank blank blank fixation_cross_target_position_3_4 "1_57_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_056_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 2092 2992 2142 fixation_cross gabor_096 gabor_037 gabor_022 gabor_066 gabor_096 gabor_037_alt gabor_022 gabor_066_alt "1_58_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2100_3000_2150_gabor_patch_orientation_096_037_022_066_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_112_framed blank blank blank blank fixation_cross_target_position_2_4 "1_58_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_112_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2092 2992 2142 fixation_cross gabor_029 gabor_080 gabor_060 gabor_105 gabor_029 gabor_080 gabor_060_alt gabor_105_alt "1_59_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2150_gabor_patch_orientation_029_080_060_105_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_105_framed blank blank blank blank fixation_cross_target_position_3_4 "1_59_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_105_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1792 2992 2142 fixation_cross gabor_090 gabor_136 gabor_121 gabor_151 gabor_090 gabor_136_alt gabor_121 gabor_151_alt "1_60_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2150_gabor_patch_orientation_090_136_121_151_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_013_framed blank blank blank blank fixation_cross_target_position_2_4 "1_60_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_013_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1742 2992 2042 fixation_cross gabor_163 gabor_178 gabor_005 gabor_112 gabor_163_alt gabor_178_alt gabor_005 gabor_112 "1_61_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2050_gabor_patch_orientation_163_178_005_112_target_position_1_2_retrieval_position_1" gabor_025_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_61_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_025_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 63 292 292 399 125 1842 2992 2392 fixation_cross gabor_080 gabor_028 gabor_043 gabor_115 gabor_080_alt gabor_028_alt gabor_043 gabor_115 "1_62_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_300_300_399_1850_3000_2400_gabor_patch_orientation_080_028_043_115_target_position_1_2_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_161_framed blank blank blank blank fixation_cross_target_position_1_2 "1_62_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_161_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1892 2992 2042 fixation_cross gabor_173 gabor_142 gabor_087 gabor_102 gabor_173 gabor_142_alt gabor_087 gabor_102_alt "1_63_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2050_gabor_patch_orientation_173_142_087_102_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_102_framed blank blank blank blank fixation_cross_target_position_2_4 "1_63_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_102_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1792 2992 2542 fixation_cross gabor_004 gabor_112 gabor_091 gabor_128 gabor_004_alt gabor_112 gabor_091_alt gabor_128 "1_64_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2550_gabor_patch_orientation_004_112_091_128_target_position_1_3_retrieval_position_1" gabor_053_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_64_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_053_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 2192 2992 1942 fixation_cross gabor_173 gabor_108 gabor_152 gabor_091 gabor_173 gabor_108_alt gabor_152 gabor_091_alt "1_65_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2200_3000_1950_gabor_patch_orientation_173_108_152_091_target_position_2_4_retrieval_position_2" gabor_circ gabor_108_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_65_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_108_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1992 2992 1992 fixation_cross gabor_010 gabor_157 gabor_118 gabor_035 gabor_010_alt gabor_157 gabor_118 gabor_035_alt "1_66_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_2000_gabor_patch_orientation_010_157_118_035_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_084_framed blank blank blank blank fixation_cross_target_position_1_4 "1_66_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_084_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 63 292 292 399 125 1792 2992 2442 fixation_cross gabor_158 gabor_098 gabor_046 gabor_132 gabor_158_alt gabor_098 gabor_046_alt gabor_132 "1_67_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_300_300_399_1800_3000_2450_gabor_patch_orientation_158_098_046_132_target_position_1_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_178_framed blank blank blank blank fixation_cross_target_position_1_3 "1_67_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_178_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 62 292 292 399 125 1992 2992 2192 fixation_cross gabor_158 gabor_094 gabor_029 gabor_180 gabor_158_alt gabor_094 gabor_029_alt gabor_180 "1_68_Encoding_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2200_gabor_patch_orientation_158_094_029_180_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_029_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_68_Retrieval_Working_Memory_MEG_P1_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_029_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 63 292 292 399 125 2142 2992 2192 fixation_cross gabor_050 gabor_035 gabor_091 gabor_005 gabor_050_alt gabor_035 gabor_091 gabor_005_alt "1_69_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_300_300_399_2150_3000_2200_gabor_patch_orientation_050_035_091_005_target_position_1_4_retrieval_position_2" gabor_circ gabor_173_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_69_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_173_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
41 61 292 292 399 125 1942 2992 2092 fixation_cross gabor_070 gabor_107 gabor_023 gabor_087 gabor_070_alt gabor_107 gabor_023_alt gabor_087 "1_70_Encoding_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_2100_gabor_patch_orientation_070_107_023_087_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_159_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_70_Retrieval_Working_Memory_MEG_P1_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_159_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
};
# 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;
};
|
850a8b10cafe6c60ab05d2ea69933958da17f5f3
|
fa8b52b9b1d92d2574eb471bb12758f13885b2b1
|
/old.tst
|
ed473e528b98961c00fb822208eab2c756cd2880
|
[
"MIT"
] |
permissive
|
Spontifixus/spontifixus.github.io
|
c56d5d66272589fd634199503abe414b4db4d1f1
|
3bef06e08b881d15c13b938e1b53f9105b7c52c2
|
refs/heads/master
| 2021-01-01T19:22:46.229038
| 2018-05-18T20:44:13
| 2018-05-18T20:44:13
| 98,575,960
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 3,697
|
tst
|
old.tst
|
### Datenschutzerklärung für die Nutzung von Disqus
Die Kommentarfunktion dieser Website wird von [Disqus, Inc., Law Enforcement Requests, 301 Howard St., Suite 300, San Francisco, CA 94105, USA][3] realisiert. Beachten Sie daher auch die [Disqus Privacy Policy][4].
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Diese Seite nutzt zur einheitlichen Darstellung von Schriftarten so genannte Web Fonts, die von [Google Inc., 1600 Amphitheatre Parkway Mountain View, CA 94043, USA][5] bereitgestellt werden. Beim Aufruf einer Seite lädt Ihr Browser die benötigten Web Fonts in ihren Browsercache, um Texte und Schriftarten korrekt anzuzeigen. Wenn Ihr Browser Web Fonts nicht unterstützt, wird eine Standardschrift von Ihrem Computer genutzt.
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Diese Website nutzt Funktionen des Webanalysedienstes Google Analytics. Anbieter ist die [Google Inc., 1600 Amphitheatre Parkway Mountain View, CA 94043, USA][5].
Google Analytics verwendet so genannte "Cookies". Das sind Textdateien, die auf Ihrem Computer gespeichert werden und die eine Analyse der Benutzung der Website durch Sie ermöglichen. Die durch den Cookie erzeugten Informationen über Ihre Benutzung dieser Website werden in der Regel an einen Server von Google in den USA übertragen und dort gespeichert.
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#### Browser Plugin
Sie können die Speicherung der Cookies durch eine entsprechende Einstellung Ihrer Browser-Software verhindern; wir weisen Sie jedoch darauf hin, dass Sie in diesem Fall gegebenenfalls nicht sämtliche Funktionen dieser Website vollumfänglich werden nutzen können. Sie können darüber hinaus die Erfassung der durch den Cookie erzeugten und auf Ihre Nutzung der Website bezogenen Daten (inkl. Ihrer IP-Adresse) an Google sowie die Verarbeitung dieser Daten durch Google verhindern, indem Sie das unter dem folgenden Link verfügbare Browser-Plugin herunterladen und installieren: https://tools.google.com/dlpage/gaoptout?hl=de
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Wir haben mit Google einen Vertrag zur Auftragsdatenverarbeitung abgeschlossen und setzen die strengen Vorgaben der deutschen Datenschutzbehörden bei der Nutzung von Google Analytics vollständig um.
#### IP-Anonymisierung
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|
928d0a0b1526f33fcc58f98be0c88c5e3fdefa23
|
e6d5f1d801a3fe887b5dc04b8cc0a9eabc1fd432
|
/Semana_8/verificadiagdom.sce
|
bc16099fa2f77c2ff856f78182e0655084e7db71
|
[] |
no_license
|
lordjuacs/MateIII
|
70def332063e56eb10fb47678a7e6130dc0dca63
|
164c53b61c9e35e565121f77ba2c578680a3ab56
|
refs/heads/master
| 2021-05-24T15:56:01.078904
| 2020-07-27T19:57:34
| 2020-07-27T19:57:34
| 253,643,962
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 206
|
sce
|
verificadiagdom.sce
|
function op = verificadiagdom(A)
[m, n] = size(A)
op = 1
for k=1:n
if abs(A(k,k)) < = sum(abs(A(k,:))) - abs(A(k,k))
op = 0
break
end
end
endfunction
|
5b90ea85401f5729444b900e11bf367a565d092d
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/545/CH4/EX4.15/ch_4_eg_15.sce
|
28e01af25dea9f87d7ae9d7f0998f17260ef0d7c
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 622
|
sce
|
ch_4_eg_15.sce
|
clc
disp("the solution of eg 4.15 -->Plug Flow Reactor")
rc_k1=1 //given rate constant
u=1 //mean axial velocity
function dCa_by_dx=fm(x,Ca),
dCa_by_dx=-Ca,
endfunction
Ca=1
for x=.1:.1:10,
h=0.1 //step increment of 0.1
k1=h*fm(x,Ca)
k2=h*fm(x+h/2,Ca+k1/2)
k3=h*fm(x+h/2,Ca+k2/2)
k4=h*fm(x+h,Ca+k3)
Ca=Ca+(k1+2*k2+2*k3+k4)/6
if x==.5|x==1|x==2|x==5 then disp(Ca,"length is",x,"the value of conc. at");
end
end
disp(Ca,"the value of Ca at x=10 using Runge Kutta method in plug flow reactor is");
|
4f98daca4b82def0ac52db90eafdb13b3fdbc281
|
676ffceabdfe022b6381807def2ea401302430ac
|
/library/Demos/LocalRegions/Tests/LocProject_Diff3D_Reg_Tet_Ortho_Basis_P6_Q7.tst
|
cac8f2d41ab77836f4deebc35dbdce0893f28886
|
[
"MIT"
] |
permissive
|
mathLab/ITHACA-SEM
|
3adf7a49567040398d758f4ee258276fee80065e
|
065a269e3f18f2fc9d9f4abd9d47abba14d0933b
|
refs/heads/master
| 2022-07-06T23:42:51.869689
| 2022-06-21T13:27:18
| 2022-06-21T13:27:18
| 136,485,665
| 10
| 5
|
MIT
| 2019-05-15T08:31:40
| 2018-06-07T14:01:54
|
Makefile
|
UTF-8
|
Scilab
| false
| false
| 568
|
tst
|
LocProject_Diff3D_Reg_Tet_Ortho_Basis_P6_Q7.tst
|
<?xml version="1.0" encoding="utf-8"?>
<test>
<description>LocProject_Diff3D Reg. Tet Ortho Basis, P=6, Q=7</description>
<executable>LocProject</executable>
<parameters>-s tetrahedron -b Ortho_A Ortho_B Ortho_C -o 6 6 6 -p 7 7 7 -c 0.0 0.0 0.0 1.0 0.0 0.0 0.0 1.0 0.0 0.0 0.0 1.0 -d</parameters>
<metrics>
<metric type="L2" id="1">
<value tolerance="1e-12">1.90683e-14</value>
</metric>
<metric type="Linf" id="2">
<value tolerance="1e-12">3.05533e-13</value>
</metric>
</metrics>
</test>
|
301f8f901c97a55c7dd3d0d07b8e4b271356a826
|
8781912fe931b72e88f06cb03f2a6e1e617f37fe
|
/scilab/scilab-examples/sge/myscijob.sce
|
07a8045e7b6855a6f014e4d527fde6563122b909
|
[] |
no_license
|
mikeg2105/matlab-old
|
fe216267968984e9fb0a0bdc4b9ab5a7dd6e306e
|
eac168097f9060b4787ee17e3a97f2099f8182c1
|
refs/heads/master
| 2021-05-01T07:58:19.274277
| 2018-02-11T22:09:18
| 2018-02-11T22:09:18
| 121,167,118
| 1
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 621
|
sce
|
myscijob.sce
|
//function myscijob()
//env=getenv('SGE_TASK_ID');
//env='1';
//This example is used to demonstrate submission of a task array
//of scilab jobs using the EASA portal to submit an array of jobs
// to the ////White Rose grid portal
//sgetid is define in the driver file by the EASA application
//sgetid=sscanf(env,'%d');
a=rand(2+sgetid,2+sgetid);
b=rand(2+sgetid,1);
A=sparse(a);
[h,rk]=lufact(A);
x=lusolve(h,b);
res=a*x-b
filename=sprintf('myscitest%d.out',sgetid);
fprintfMat(filename,x);
//define mtvars variables that will be saved to output
myvars=['x', 'res'];
//exit();
//endfunction
|
516d163d0bb9e9e31e2628efbb3e6cc0b7df348e
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1658/CH18/EX18.7/Ex18_7.sce
|
579f116c03a47d6143a9d63d093d1d8ac3b60742
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 428
|
sce
|
Ex18_7.sce
|
clc;
//e.g 18.7
Vcc=30;
Rb=1.5*10**6;
Rc=5*10**3;
beta=100;
Ic=Vcc/Rc;//saturation current
disp('mA',Ic*10**3,"Ic=");
Vce=Vcc;//cut-off voltage
disp('V',Vce*1,"Vce=");
Ib=Vcc/Rb;//base current
disp('microA',Ib*10**6,"Ib=");
Ic=beta*Ib;
disp('mA',Ic*10**3,"Ic=");
Vce=Vcc-Ic*Rc;
disp('V',Vce*1,"Vce=");
i=6:-0.2:0;
plot2d(i);
a=gca() //get the current axes
a.box="off";
xlabel("VCE");
ylabel( "IC");
|
c9338d938d1faaf84317660cce37f9118ffd1d05
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3673/CH8/EX8.a.3/Example_a_8_3.sce
|
ac65d1e4dbc548ebdf369180cd584a992c5b93ed
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 439
|
sce
|
Example_a_8_3.sce
|
//Example_a_8_3 page no:326
clc;
Vmax=10;
Vrms=Vmax/sqrt(2);
Vc=500;
Q=Vc/Vrms;
BW=400;
Z=100;
R=Z;
omega_r=Q*BW;
fr=omega_r/(2*%pi);
L=R/BW;
C=1/((2*%pi*fr)^2*L);
C=C*10^9;
disp(fr,"the resonant frequency is (in Hz)");
disp(L,"the inductance of the circuit is (in H)");
disp(C,"the capacitance of the circuit is (in nF)");
//resonant frequency varies slightly with text book hence in text book value of Q is rounded off
|
82908f8c8b6bc254b72ca1f2bd76230afb7f0cfb
|
97135f725c599527ba0fd95a5289373c755daf3b
|
/Examples/test-suite/scilab/char_constant_runme.sci
|
b8848d013aa9646629ee9266d938b33f472893e5
|
[] |
no_license
|
maqalaqil/swag-c-
|
b8880cfc92424d5bbca1fe15ed98663a41063f27
|
6fd1ba2bf1d353f24c116a3c89a8540292b86a7d
|
refs/heads/master
| 2020-07-06T21:02:08.949652
| 2019-09-01T07:56:55
| 2019-09-01T07:56:55
| 203,137,066
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 350
|
sci
|
char_constant_runme.sci
|
exec("alaqiltest.start", -1);
if CHAR_CONSTANT_get() <> "x" then alaqiltesterror(); end
if STRING_CONSTANT_get() <> "xyzzy" then alaqiltesterror(); end
if ESC_CONST_get() <> ascii(1) then alaqiltesterror(); end
if ia_get() <> ascii('a') then alaqiltesterror(); end
if ib_get() <> ascii('b') then alaqiltesterror(); end
exec("alaqiltest.quit", -1);
|
4493af9d582d7aa649d28edcc0f3b47d0c765cd8
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1268/CH5/EX5.5/5_5.sce
|
395114163a8d2c5e2687151e7a57db6fabe4a001
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 211
|
sce
|
5_5.sce
|
clc;
disp("Example 5.5")
// WE need to calculate the integral of the manipulated expression in terms of y/delta
int= integrate('2*y-(5*y*y)+(4*y*y*y)-(y*y*y*y)','y',2,1)
disp(int, "Momentum thickness is ")
|
cfff1df53daf64748d7a093b5d241fc97cb97e63
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1979/CH6/EX6.6/Ex6_6.sce
|
650b5309705e4e6c62c8172ddd506b7ccbfd55f1
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 787
|
sce
|
Ex6_6.sce
|
//Chapter-6, Example 6.6, Page 239
//=============================================================================
clc;
//Input parameters
p1=0.5;//reflection coefficient at port 1
p2=0.6;//reflection coefficient at port 2
p3=1;//reflection coefficient at port 3
p4=0.8;//reflection coefficient at port 4
//[S]=[0,0,0.707,0.707;0,0,0.5,-0.707;0.707,0.707,0,0;-0.707,0.707,0,0];//S matrix of magic Tee
//solving for b1,b2,b3,b4 we get it as
//calculations
b1=0.6566;
b2=0.7576;
b3=0.6536;
b4=0.0893;
P1=(b1)^2;//power at port1 in watts
disp(P1);
P2=(b2)^2;//power at port2 in watts
disp(P2);
P3=(b3)^2;//power at port3 in watts
disp(P3);
P4=(b4)^2;//power at port4 in watts
disp(P4);
//=================================END OF PROGRAM==============================
|
486fb687aa9c987c2cbfaf9a10652e245d8908e1
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2732/CH3/EX3.4/Ex3_4.sce
|
1029d1c60fd56d9dcad662f90a5d0f3c5638e29e
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,484
|
sce
|
Ex3_4.sce
|
clc
// initialization of variables
clear
epsillon=[0.01 -0.02 0
-0.02 0.03 -0.01
0 -0.01 0] // dimensionless
a_xx=0.6
theta=acos(a_xx) // radians
//calculations
// theta=theta*%pi/180
a=[cos(theta) 0 -sin(theta)
0 1 0
sin(theta) 0 cos(theta)]
b=a.'
epsillon_new=a*epsillon*b
// calculation of strain invariants
// for epsillon
J1=epsillon(1,1)+epsillon(2,2)+epsillon(3,3)
J2=epsillon(1,1)*epsillon(2,2)+epsillon(2,2)*epsillon(3,3)+epsillon(3,3)*epsillon(1,1)-2*(epsillon(1,2)^2+epsillon(2,3)^2+epsillon(3,1)^2)
J3=epsillon(1,1)*epsillon(2,2)*epsillon(3,3)+2*epsillon(1,2)*epsillon(2,3)*epsillon(3,1)-(epsillon(1,1)*epsillon(2,3)^2+epsillon(2,2)*epsillon(3,1)^2+epsillon(3,3)*epsillon(1,2)^2)
// for epsillon_new
J11=epsillon_new(1,1)+epsillon_new(2,2)+epsillon_new(3,3)
J22=epsillon_new(1,1)*epsillon_new(2,2)+epsillon_new(2,2)*epsillon_new(3,3)+epsillon_new(3,3)*epsillon_new(1,1)-2*(epsillon_new(1,2)^2+epsillon_new(2,3)^2+epsillon_new(3,1)^2)
J33=epsillon_new(1,1)*epsillon_new(2,2)*epsillon_new(3,3)+2*epsillon_new(1,2)*epsillon_new(2,3)*epsillon_new(3,1)-(epsillon_new(1,1)*epsillon_new(2,3)^2+epsillon_new(2,2)*epsillon_new(3,1)^2+epsillon_new(3,3)*epsillon_new(1,2)^2)
// Results
printf('The new strain tensor is')
disp(epsillon_new)
printf('The strain invariants of old stress tensor are J1=%0.2f J2=%.e J3=%.e \n and that of the new stress tensor are J1=%0.2f J2=%.e J3=%.e',J1,J2,J3,J11,J22,J33)
|
1491ce65bdff8250ef861c56df6a175188fcecd0
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3281/CH9/EX9.3/ex9_3.sce
|
4f5b663179816fce08f5ecae56da34ec8f26f2e4
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 342
|
sce
|
ex9_3.sce
|
//Page Number: 451
//Example 9.3
clc;
//Given
XeGe=4.0; //eV
XeGaAs=4.1; //eV
delEgGe=0.78; //eV
delEgGaAs=1.42; //eV
//Conduction band differential
delEc=XeGe-XeGaAs;
disp('eV',delEc,'Conduction band differential:');
//Valence band differential
delEv=delEgGaAs-delEgGe-delEc;
disp('eV',delEv,'Valence band differential:');
|
0a695a61cb2786050e8297ae61827ed55280f483
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1898/CH4/EX4.2/Ex4_2.sce
|
6e18e809977dd44c69eb717c0898140fdff4c5e3
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,029
|
sce
|
Ex4_2.sce
|
clear all; clc;
disp("Scilab Code Ex 4.2 : ")
//Given:
a_ab = 400; //mm^2
d_rod = 10; //mm
r_rod = d_rod/(2*1000); //radius in m
P = 80; //kN
E_st = 200*(10^9); //Pa
E_al = 70*(10^9); //Pa
l_ab = 400; //mm
l_bc = 600; //mm
//Calculations:
//Internal forces: tension = compression = 80kN.
//Displacement:
//delta =PL/AE
numerator1 = P*(10^3)*(l_bc/1000);
denominator1 = (%pi*r_rod^2*E_st);
delta_cb = numerator1/denominator1; //to the right
numerator2 = -P*(10^3)*(l_ab/1000);
denominator2 = (a_ab* 10^-6 *E_al);
delta_a = -numerator2/denominator2; //to the right
delta_c = delta_a+delta_cb;
//Display:
printf("\n\nThe displacement of C with respect to B = +%1.6f m',delta_cb);
printf("\nThe displacement of B with respect to A = +%1.6f m",delta_a);
printf('\nThe displacement of C relative to A = +%1.5f m',delta_c);
//------------------------------------------------------------------END---------------------------------------------------------------------
|
1173cc9c2c04d12807f288d02ca2ed30693bff1d
|
1bb72df9a084fe4f8c0ec39f778282eb52750801
|
/test/BMB.prev.tst
|
3e0e1924e7e90d8e42860e37f9e3b10192eb4e84
|
[
"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
| 2023-08-04T07:48:00
| 30,116,803
| 2
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 233
|
tst
|
BMB.prev.tst
|
[[16384,32768,8192,8192],[0,32768,0,0],[49152,-32768,57344,-8192],[-49152,32768,-49152,16384]],det=288230376151711744 is inverse of [[65536,0,0,0],[0,65536,0,0],[0,0,65536,0],[0,0,0,65536]],det=18446744073709551616,identity = false
|
da9c9adbdb3fd5897dace0105a4058a621a465de
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/992/CH2/EX2.12/ex2_12.sce
|
2d82bc4ce9366dabb82a16cf15b5918e8c0c9d60
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 360
|
sce
|
ex2_12.sce
|
clc;
clear;
//Given:
spacing=20//in Hz
bg=100//in Hz
bw=5//modulated by a signal Hz
printf("\n\n\t first sideband pair %d to 100Hz and 100Hz to %d",(bg-bw),(bg+bw) );
//For second pair
bg2=120// in Hz
bw=5//modulated by a signal Hz
printf("\n\n\t second sideband pair %d to 120Hz and 120Hz to %d",(bg2-bw),(bg2+bw) );
printf("No overlap occurs");
|
89881a39f74eeba608593f7d26e3cf297405c025
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/125/CH6/EX6.23/Fig6_23.sce
|
8ec3f9b9b153dc0f2c38e933647c7fcd299ccd68
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 798
|
sce
|
Fig6_23.sce
|
//Caption:Scilab code to Perform median filtering of colour image
//Fig6.23(a)
//page 353
clc;
close;
a=imread('E:\DIP_JAYARAMAN\Chapter6\peppers.png'); //SIVP toolbox
N=input('enter the window size');
b=imresize(a,[256,256]);
b=imnoise(b,'salt & pepper',.1);
[m n]=size(b);
R=b(:,:,1);
G=b(:,:,2);
B=b(:,:,3);
Out_R=Func_medianall(R,N);//Applying Median filter to ‘R’ plane
Out_G=Func_medianall(G,N);//Applying Median filter to ‘G’ plane
Out_B=Func_medianall(B,N);//Applying Median filter to ‘B’ plane
Out_Image(:,:,1)=Out_R;
Out_Image(:,:,2)=Out_G;
Out_Image(:,:,3)=Out_B;
b = uint8(b);
Out_Image = uint8(Out_Image);
//ShowColorImage(b,'noise added')
//title('noise added')
figure
ShowColorImage(Out_Image,'3x3 median filtered')
title('3x3 median filtered')
|
22ebb2f3eddb5a03d0c2d7baf67a6937e1b71523
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2240/CH23/EX22.7/EX22_7.sce
|
c9297ea4750c7c273d31d638267384642440447d
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 625
|
sce
|
EX22_7.sce
|
// Grob's Basic Electronics 11e
// Chapter No. 22
// Example No. 22_7
clc; clear;
// Assume the capacitor is discharging after being charged to 200 V. How much will the voltage across C be 0.01 s after the beginning of discharge? The series resistance is the same on discharge as on charge.
// Given data
C = 0.01*10^-6; // Capacitor=0.01 uFarad
R = 1*10^6; // Resistor=1 MOhms
V = 200; // Capacitor voltage=200 Volts
disp ('In one time constant, C discharges to 37% of its initial voltage')
V1 = 0.37*V;
disp (V1,'The Capacitor voltage after 0.01 sec start of discharge in volts')
|
140bccfbd67346f17fb88524c23e2f8a96442638
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2339/CH3/EX3.23.1/Ex3_23.sce
|
7f01ed0aa5c242c39d62d181cf0c3c1931c79aca
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 732
|
sce
|
Ex3_23.sce
|
clc
clear
//Inputs
//The Values in the program are as follows:
//Temperature in Celcius converted to Kelvin(by adding 273)
//Pressure in bar converted to kPa (by multiplying 100)
//Volume in m^3
//Value of R,Cp and Cv in kJ/kg K
m=28;
V1=3;
T1=100+273;
T2=37+273;
G=1.4;
Ro=8.314;
v=V1/m;
R=Ro/m;
P1=(m*R*T1)/V1;
printf('The Specific Volume: %1.3f m^3/kg',v);
printf('\n')
printf('The Initial Pressure: %1.2f kPa',P1);
printf('\n')
P2=(P1*T2)/T1;
printf('The Final Pressure: %1.2f kPa',P2);
printf('\n')
Cv=(R)/(G-1);
Cp=Cv*G;
U=m*Cv*(T2-T1);
H=m*Cp*(T2-T1);
printf('Change in Internal Energy: %1.2f kJ',U);
printf('\n');
printf('Change in Heat energy: %1.2f kJ',H);
printf('\n')
|
871ac6618e7492de23055c512f8545bcaa04e185
|
527c41bcbfe7e4743e0e8897b058eaaf206558c7
|
/NZFunctions/Hypothesis/FLCrossTabUdt-NZ-UM-01.tst
|
0f7f432dd468603bbaffededec841e01a8a37632
|
[] |
no_license
|
kamleshm/intern_fuzzy
|
c2dd079bf08bede6bca79af898036d7a538ab4e2
|
aaef3c9dc9edf3759ef0b981597746d411d05d34
|
refs/heads/master
| 2021-01-23T06:25:46.162332
| 2017-07-12T07:12:25
| 2017-07-12T07:12:25
| 93,021,923
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,732
|
tst
|
FLCrossTabUdt-NZ-UM-01.tst
|
-- Fuzzy Logix, LLC: Functional Testing Script for DB Lytix functions on Netezza
--
-- Copyright (c): 2016 Fuzzy Logix, LLC
--
-- NOTICE: All information contained herein is, and remains the property of Fuzzy Logix, LLC.
-- The intellectual and technical concepts contained herein are proprietary to Fuzzy Logix, LLC.
-- and may be covered by U.S. and Foreign Patents, patents in process, and are protected by trade
-- secret or copyright law. Dissemination of this information or reproduction of this material is
-- strictly forbidden unless prior written permission is obtained from Fuzzy Logix, LLC.
--
--
-- Functional Test Specifications:
--
-- Test Category: Hypothesis Testing Functions
--
-- Last Updated: 05-29-2017
--
-- Author: <deept.mahendiratta@fuzzylogix.com>
--
-- BEGIN: TEST SCRIPT
--timing on
-- BEGIN: TEST(s)
-----*******************************************************************************************************************************
---FLCrossTabUdt
-----*******************************************************************************************************************************
--Input TABLE
SELECT *
FROM tblCrossTab
LIMIT 20;
--Output table
SELECT a.*
FROM(
SELECT 1 AS groupid,
a.tabrowid,
a.tabcolid,
NVL(LAG(0) OVER (PARTITION BY groupid ORDER BY a.tabrowid), 1)
AS begin_flag,
NVL(LEAD(0) OVER (PARTITION BY groupid ORDER BY a.tabrowid), 1)
AS end_flag
FROM tblCrossTab a) AS z,
TABLE(FLCrossTabUdt(z.groupid,
z.tabrowid,
z.tabcolid,
z.begin_flag,
z.end_flag)) AS a;
-- END: TEST(s)
-- END: TEST SCRIPT
--timing off
|
be31ca7dbcf9eb34add65cf1d4035228de5192dc
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3754/CH24/EX24.7/24_7.sce
|
d9ff05811d88999d6a6595369552c581d1055c8f
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,042
|
sce
|
24_7.sce
|
clear//
//Variables
VCC = 12.0 //Source voltage (in volts)
RC = 4.0 //Collector resistance (in kilo-ohm)
RE = 3.3 //Emitter resistance (in kilo-ohm)
beta = 120.0 //Common emitter current gain
VBE = 0.7 //Emitter-to-Base Voltage (in volts)
R1 = 60.0 //Resistance (in kilo-ohm)
R2 = 30.0 //Resistance (in kilo-ohm)
//Calculation
Vth = VCC * R2 / (R1 + R2) //Thevenin's voltage (in volts)
Rth = R1 * R2 / (R1 + R2) //Thevenin's equivalent voltage (in volts)
IE = (Vth - VBE)/(RE + Rth/beta) //Emitter current (in milli-Ampere)
r1e = 25.0 / IE * 10**-3 //a.c. resistance of emitter diode (in kilo-hm)
rL = RC //Load resistance (in kilo-ohm)
Av = RC / r1e //Voltage gain
//Result
printf("\n The voltage gain is %0.1f .",Av)
|
a0cc910d0d3c336d8da22a1c49c989a20edc682a
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1442/CH6/EX6.6/6_6.sce
|
2635d1b230fe9054ed9d6c08e5339833b03ae262
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 285
|
sce
|
6_6.sce
|
clc
//initialisation of variables
m1= 0.03 //kg
v1= 2.1977 //m^3/kg
h2= 3073.8 //kJ/kg
h1= 3061.6 //kJ/kg
p2= 600 //kPa
p1= 120 //kPa
//CALCULATIONS
V=m1*v1
r= ((h2-h1)/v1)+p2-p1
//RESULTS
printf (' volume of container = %.5f m^3',V)
printf (' \n pressure = %.2f kPa',r)
|
40d4688d593cfd771930f3833378c1a1d11aa49e
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1760/CH1/EX1.3/EX1_3.sce
|
be1fd8fc8deebc5767e00eaa0fc59e151a43ff6e
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 328
|
sce
|
EX1_3.sce
|
//EXAMPLE 1-3 PG NO-18
A20=0.00393; //ALPHA 20
R30=1.3; //RESITANCE 30
A30=A20/(1+A20*(30-20)); //ALPHA 30
disp('i)Alpha30 (A30) = '+string (A30)+' ');
T=[((1.6/1.3)-1)/0.00378]; // THE RISE IN TEMPERATURE TO BE FIND where T=t-30
disp('ii)Resistance Temperature (t-30) = '+string (T)+' degree celcious');
|
b2038d8c8ea7eb4138a310245f0f405aca8efed4
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3760/CH6/EX6.64/Ex6_64.sce
|
d3469b9a8bf5e4f849769e6e03de8e98f204bb0d
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 977
|
sce
|
Ex6_64.sce
|
clc;
v=3300; // rated voltage of induction motor
p=6; // number of poles
f=50; // frequency
t=3.2; // stator to rotor turns
r=0.1; // rotor resistance
x=1; // rotor leakage reactance
R=t^2*r; // rotor resistance referred to stator
X=t^2*x; // rotor reactance referred to stator
ws=(4*%pi*f)/p; // synchronous speed
disp('case a');
is=(v/sqrt(3))/(sqrt(R^2+X^2));
printf('Starting current at rated voltage is %f A\n',is);
Ts=(3*is^2*R)/ws;
printf('Starting torque at rated voltage is %f Nm\n',Ts);
disp('case b');
is=50; // starting current
// is=Vp/(sqrt((R+rex)^2+X^2) where rex is external resistance and Vp is phase voltage
// solving above equation we get a quadratic equation in rex whose terms are
t1=1;
t2=2*R;
t3=(R^2+X^2)-((v/sqrt(3))/is)^2;
p=[ t1 t2 t3 ];
rex=roots(p);
printf('External resistance referred to rotor is %f ohms\n',rex(2)/t^2);
Ts=(3*is^2*(R+rex(2)))/ws;
printf('Starting torque under new condition is %f Nm\n',Ts);
|
313ed1f4c479d0820db8579bbee6f600b0d3cc30
|
4a1effb7ec08302914dbd9c5e560c61936c1bb99
|
/Project 2/Experiments/Ripper-C/results/Ripper-C.balance-10-1tra/result7s0.tst
|
8eef5d0702c13b059582368c0a553df57becaefd
|
[] |
no_license
|
nickgreenquist/Intro_To_Intelligent_Systems
|
964cad20de7099b8e5808ddee199e3e3343cf7d5
|
7ad43577b3cbbc0b620740205a14c406d96a2517
|
refs/heads/master
| 2021-01-20T13:23:23.931062
| 2017-05-04T20:08:05
| 2017-05-04T20:08:05
| 90,484,366
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 544
|
tst
|
result7s0.tst
|
@relation balance
@attribute Left-weight real[1.0,5.0]
@attribute Left-distance real[1.0,5.0]
@attribute Right-weight real[1.0,5.0]
@attribute Right-distance real[1.0,5.0]
@attribute Balance_scale{L,B,R}
@inputs Left-weight,Left-distance,Right-weight,Right-distance
@outputs Balance_scale
@data
R B
R R
R B
B L
R R
R R
R R
R R
B B
R R
R B
R B
R R
L B
R B
L B
R B
L B
L L
R R
L B
R R
R R
L B
L L
B B
L B
R R
R B
L R
B R
R R
L L
L L
L B
R R
L B
L B
L R
B R
L L
L B
R R
R B
R R
L B
L B
R L
R R
R L
R R
R R
L L
L L
L L
L L
L L
L L
L L
L B
L L
L B
|
dd928bd2ffee9c0c33784d28ccb62015e5d6e5cf
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2141/CH10/EX10.9/Ex10_9.sce
|
b6602538e9cf4a470971a922a4888a0894c62528
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 443
|
sce
|
Ex10_9.sce
|
clc
//initialisation of variables
P1=3000//lbf/in^2
P2=200//lbf/in^2
T=492//F
Tr=360/227//F
h1=3.6//Btu/lb mole-R
h2=-29.2//Btu/lbm
Cp=0.248 //Btu/lbm-R
T2=265//F
T1=360//F
Tr2=265/227//f
Pr3=0.406//lbm/in^2
h3=0.7 //Btu/lb mole-R
h4=5.7 //Btu/lbm
//CALCULATIONS
Pr1=(P1/T)//lbf/in^2
Pr2=(P2/T)//lbf/in^2
h=Cp*(T1-T2)//Btu/lbm
H=h2+h+h4//Btu/lbm
//RESULTS
printf('the final temperature of the nitrogen =% f Btu/lbm',H)
|
c0efa7144a52ff9e3a1788a88946c81bd6328615
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1088/CH24/EX24.2/Example2.sce
|
32a03a7407dbc5df665b678374a34982c8ae652b
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 2,868
|
sce
|
Example2.sce
|
clear
flag=1
mode(-1)
clc
printf("Example 2 : Show the method of showing PID,PPID in both parent and child process \n")
disp("****************************************************************")
disp("Answer : ")
disp("INSTRUCTIONS : ")
halt(' ')
disp("1.These programs are part of systems programming PURELY in Unix and the commands have NO EQUIVALENT IN SCILAB")
halt(' ')
disp("2.However the .c files which are displayed here are also made into a seperate file.If you are a unix user then try compiling and running the programme with gcc or cc compiler")
halt(' ')
disp("3.The outputs displayed here are just MOCK OUTPUTS which are DISPLAYED IN THE TEXTBOOK")
halt(' ')
disp("4.The inconvenience is regretted.")
halt('.............Press [ENTER] to continue.....')
halt("")
clc
printf("\tUNIX SHELL SIMULATOR(DEMO VERSION WITH PRELOADED COMMANDS)\n\n\n")
i=0
i=i+1;f(i)='/* Program: fork.c -- A simple fork Shows PID,PPID in both parent and child*/'
i=i+1;f(i)=''
i=i+1;f(i)='#include <stdio.h>'
i=i+1;f(i)='#include <sys/types.h>'
i=i+1;f(i)=''
i=i+1;f(i)='int main(void) {'
i=i+1;f(i)=' pid_t pid;'
i=i+1;f(i)=' '
i=i+1;f(i)=' printf('+ascii(34)+'Before forking\n'+ascii(34)+');'
i=i+1;f(i)=' pid = fork(); /* Replicates current processes */'
i=i+1;f(i)=' '
i=i+1;f(i)=' if(pid >0) { /* In the parent process; make sure */'
i=i+1;f(i)=' sleep(1); /* That the parent does not die before child */'
i=i+1;f(i)=' printf('+ascii(34)+'PARENT -- PID: %d PPID %d, CHILD PID: %d\n'+ascii(34)+',getpid(),getppid(),pid);}'
i=i+1;f(i)=' '
i=i+1;f(i)=' else if (pid == 0) /* In the child process */'
i=i+1;f(i)=' printf('+ascii(34)+'CHILD -- PID: %d PPID: %d\n'+ascii(34)+',getpid(),getppid());'
i=i+1;f(i)=' else { /* pid must be -1 here */'
i=i+1;f(i)=' printf('+ascii(34)+'Fork error\n'+ascii(34)+');'
i=i+1;f(i)=' exit(1);}'
i=i+1;f(i)=' printf('+ascii(34)+'Both process continue from here\n'+ascii(34)+'); /* In both processes */'
i=i+1;f(i)=' exit(0);'
i=i+1;f(i)='}'
n=i
printf("\n\n$ cat fork.c # to open the file emp.lst")
halt(' ')
u=mopen('fork.c','wt')
for i=1:n
mfprintf(u,"%s\n",f(i))
printf("%s\n",f(i))
end
mclose(u)
halt('')
clc
halt(' ')
printf("$ cc fork.c")
halt(' ')
printf("$ a.out")
halt(' ')
printf("Before forking\nCHILD -- PID: 1556 PPID: 1555\nBoth processes continue from here # This statement runs in child\nPARENT -- PID: 1555 PPID: 1450,CHILD PID: 1556\nBoth processes continue from here ...as well as in parent\n")
halt(' ')
printf("\n\n\n$ exit #To exit the current simulation terminal and return to Scilab console\n\n")
halt("........# (hit [ENTER] for result)")
//clc()
printf("\n\n\t\t\tBACK TO SCILAB CONSOLE...\nLoading initial environment')
sleep(1000)
|
6f84c86f3402cd066d7c09ec844c50452dcec5fa
|
0cb3ef9e2be55e6924e840d829ad2ad1a9879f2d
|
/Hack CPU/test1.tst
|
313efbb0fa8953b7705748fcf069e63f673209a1
|
[] |
no_license
|
jayakamal-geek/Hardware-Description-Language
|
5cdbe71b9ebeb823afed69216763ccf9c7d81b6c
|
3b75f43321b02ba05ff1c652942315ebb1d4d1bc
|
refs/heads/main
| 2023-04-29T10:45:00.885647
| 2021-05-23T09:44:05
| 2021-05-23T09:44:05
| 370,012,967
| 1
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 668
|
tst
|
test1.tst
|
load Computer.hdl,
output-file test1.out,
output-list time%S1.4.1 reset%B2.1.2 ARegister[0]%D1.7.1 DRegister[0]%D1.7.1 RAM64[16]%D1.7.1 RAM64[17]%D1.7.1 RAM64[18]%D1.7.1;
// Load a program written in the Hack machine language.
// The program adds the two constants 2 and 3 and writes the result in RAM[0].
ROM32K load test1.hack,
set RAM64[16] 6,
set RAM64[17] 14,
output;
// First run (at the beginning PC=0)
repeat 15 {
tick, tock, output;
}
// Reset the PC
set reset 1,
set RAM64[16] 16,
set RAM64[17] 12,
set RAM64[18] 0,
tick, tock, output;
// Second run, to check that the PC was reset correctly.
set reset 0,
repeat 12 {
tick, tock, output;
}
|
0c3532c852eb27597e02e20c87eb788f5ecfc3e6
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2063/CH9/EX9.18/9_18.sce
|
be5aa8331184cdc60cddede40f3e1a762a8eb696
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 502
|
sce
|
9_18.sce
|
clc
clear
//Input data
P1=1;//Initial pressure of air entering a two stage air compressor with complete intercooling in bar
P3=25;//Delivery pressure of air toe the mains in bar
T1=303;//Initial temperature in K
n=1.35;//Compression index
//Calculations
P2=(P1*P3)^(0.5);//Inter cooler pressure for perfect intercooling in bar
R=(P2/P1)^(0.5);//Ratio of cylindrical diameters
//Output
printf('The ratio of cylinder diameters for the efficiency of compression to be maximum is %3.3f',R)
|
e4f8d929466c379babea9c31fdc2807c8722e431
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1016/CH16/EX16.3/ex16_3.sce
|
d1af51a51eeccd5a493b94f378b7163dff18b42f
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 401
|
sce
|
ex16_3.sce
|
clc;clear;
//Example 16.3
//given data
B=0.75;//magnetic flux intensity in Wb/m^2
m1=1.67*10^-27;//mass in Kg
m2=3.31*10^-27;//mass in Kg
e=1.6*10^-19;//the charge on electron in C
Rm=2;//radius in m
//calculations
Q=e;
Emax=3.12*10^12*B^2*Q^2*Rm^2/m1;
disp(Emax,'Maximum energies in Mev for proton');
Emax=3.12*10^12*B^2*Q^2*Rm^2/m2;
disp(Emax,'Maximum energies in Mev for deuteron')
|
40361c8c30e92e2842f3ce3425d66ba2aba51642
|
8217f7986187902617ad1bf89cb789618a90dd0a
|
/source/2.5/macros/percent/%l_n_p.sci
|
47506dea1692eff0139594f9ea2af1811d6047fe
|
[
"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
| 2022-09-13T14:41:51
| 258,270,193
| 0
| 1
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 58
|
sci
|
%l_n_p.sci
|
function [r]=%l_n_p(l1,l2)
//!
// Copyright INRIA
r=%t
|
c1aa116e63f38e72624d8fd443c70e49f10ef216
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3831/CH18/EX18.9/Ex18_9.sce
|
161812b5e997f048beb6e33d55cfc245aaff9651
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 377
|
sce
|
Ex18_9.sce
|
// Example 18_9
clc;funcprot(0);
// Given data
T=20.0+273.15;// K
// Calculation
theta_v=2740;// K
c_vbyR=(5/2)+((((theta_v/T)^2)*exp((theta_v/T)))/(exp(theta_v/T)-1)^2);
Y=8.3143;// kJ/kg.K
M_NO=30.01;// The molecular mass of nitrous oxide
R_NO=Y/M_NO;// kJ/kg.K
c_v_NO=R_NO*c_vbyR;// kJ/kg.K
printf("\nThe value of c_v/R for nitrous oxide is %1.2f.",c_vbyR);
|
40ad9029deb922ed8623a6780347c2e5618b902d
|
a2845a06ebac1138c6854d691780b120cdd556ab
|
/simpsons.sce
|
2e7ed9ef10bd291273d1ae1223e3e5ada726303c
|
[] |
no_license
|
asp2809/Scilab-Programs
|
d734202084dc70e2b4e3281410833d315ce1558c
|
6a49e9401ee81dd3ffc909fe6a3954b5e184c70c
|
refs/heads/master
| 2020-03-10T15:11:33.831289
| 2018-10-05T09:50:06
| 2018-10-05T09:50:06
| 129,443,439
| 1
| 0
| null | 2018-10-05T09:50:07
| 2018-04-13T19:10:50
|
Scilab
|
UTF-8
|
Scilab
| false
| false
| 423
|
sce
|
simpsons.sce
|
//program to find the integration of a function f(x)=1/(1+x) using simpsons method and then finding the error by comparing it with the original value
function [e]=simpsons(a,b,n)
deff('y = f(x)','y = 1/(1+x)')
h=((b-a)/n)
sum1=0
while(a<b)
sum1=sum1+((h/3)*(f(a) + (4*f(a+h)) + f(a+2*h)))
a=a+2*h
end
disp(sum1)
ans=1.94591
e=(abs(ans-sum1)/ans)*100
endfunction
|
8689419dc4d71e546f026272ff90bfd284389daa
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2753/CH2/EX2.1/Ex2_1.sce
|
2a0baf3ab611495469a771a9d573ec35d874e89a
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 197
|
sce
|
Ex2_1.sce
|
//Example 2.1:
clc;
clear;
close;
//given data :
Pmax=364;//dissipation in milliwatt
Vz=9.1;//in V
Izmax=Pmax/Vz;//in mA
format('v',4)
disp(Izmax,"maximum current the diode can handle is ,(mA)=")
|
5b196303c722715327c9b3c4ec8c29d5035ee8b7
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1820/CH4/EX4.8/Example4_8.sce
|
1e2071f42e7bc3229ac7d79745a92e57e0c93958
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 3,156
|
sce
|
Example4_8.sce
|
// ELECTRIC POWER TRANSMISSION SYSTEM ENGINEERING ANALYSIS AND DESIGN
// TURAN GONEN
// CRC PRESS
// SECOND EDITION
// CHAPTER : 4 : OVERHEAD POWER TRANSMISSION
// EXAMPLE : 4.8 :
clear ; clc ; close ; // Clear the work space and console
// GIVEN DATA
V_RL_L = 138*10^3 ; // transmission line voltage in V
R = 0.1858 // Line constant in Ω/mi
f = 60 // frequency in Hertz
L = 2.60*10^-3 // Line constant in H/mi
C = 0.012*10^-6 // Line constant in F/mi
pf = 0.85 // Lagging power factor
P = 50*10^6 // load in VA
l = 150 // length of 3-Φ transmission line in mi
// CALCULATIONS
// For case (a)
z = R + %i*2*%pi*f*L ; // Impedance per unit length in Ω/mi
y = %i*2*%pi*C*f ; // Admittance per unit length in S/mi
g = sqrt(y*z) ; // Propagation constant of line per unit length
// For case (b)
lamda = (2 * %pi)/imag(g) ; // Wavelength of propagation in mi
V = lamda * f ; // Velocity of propagation in mi/sec
// For case (c)
Z_C = sqrt(z/y) ;
V_R = V_RL_L/sqrt(3) ;
theta_R = acosd(pf) ;
I_R = P/(sqrt(3)*V_RL_L) * ( cosd(theta_R) - %i*sind(theta_R) ) ; // Receiving end current in A
V_R_incident = (1/2)*(V_R + I_R*Z_C) ; // Incident voltage at receiving end in V
V_R_reflected = (1/2)*(V_R - I_R*Z_C) ; // Reflected voltage at receiving end in V
// For case (d)
V_RL_N = V_R_incident + V_R_reflected ; // Line-to-neutral voltage at receiving end in V
V_RL_L = sqrt(3)*V_RL_N // Receiving end Line voltage in V
// For case (e)
g_l = real(g) * l + %i * imag(g) * l ; // Propagation constant of line
a = real(g) ; // a = α is the attenuation constant
b = imag(g) ; // b = β is the phase constant
V_S_incident = (1/2) * (V_R+I_R*Z_C) * exp(a*l) * exp(%i*b*l) ; // Incident voltage at sending end in V
V_S_reflected = (1/2) * (V_R-I_R*Z_C) * exp(-a*l) * exp(%i*(-b)*l) ; // Reflected voltage at sending end in V
// For case (f)
V_SL_N = V_S_incident + V_S_reflected ; // Line-to-neutral voltage at sending end in V
V_SL_L = sqrt(3)*V_SL_N ; // sending end Line voltage in V
// DISPLAY RESULTS
disp("EXAMPLE : 4.8 : SOLUTION :-") ;
printf("\n (a) Attenuation constant , α = %.4f Np/mi \n",real(g)) ;
printf("\n Phase change constant, β = %.4f rad/mi \n",imag(g)) ;
printf("\n (b) Wavelength of propagation = %.2f mi \n",lamda) ;
printf("\n velocity of propagation = %.2f mi/s \n",V) ;
printf("\n (c) Incident voltage receiving end , V_R(incident) = %.2f<%.2f V \n",abs(V_R_incident),atan(imag(V_R_incident),real(V_R_incident))*(180/%pi));
printf("\n Receiving end reflected voltage , V_R(reflected) = %.2f<%.2f V \n",abs(V_R_reflected),atan(imag(V_R_reflected),real(V_R_reflected))*(180/%pi)) ;
printf("\n (d) Line voltage at receiving end , V_RL_L = %d V \n",V_RL_L) ;
printf("\n (e) Incident voltage at sending end , V_S(incident) = %.2f<%.2f V \n",abs(V_S_incident),atan(imag(V_S_incident),real(V_S_incident))*(180/%pi)) ;
printf("\n Reflected voltage at sending end , V_S(reflected) = %.2f<%.2f V \n",abs(V_S_reflected),atan(imag(V_S_reflected),real(V_S_reflected))*(180/%pi)) ;
printf("\n (f) Line voltage at sending end , V_SL_L = %.2f V \n",abs(V_SL_L)) ;
|
fe40793b4484213f897d3feb4463f4bbe441b27a
|
857f7516c898df1639b27c209cf85ba30f76f696
|
/SoundAndNoise.sce
|
5ee9a698174c74f3f3dc986ed2326afc77070535
|
[] |
no_license
|
pracheejaviya1/signals-and-systems
|
ba72429fc1022d72245c2b2305e341fc9faea7c7
|
604aa7a71a858c03f816702f689ea05dc139ecf4
|
refs/heads/master
| 2022-02-25T23:54:46.695092
| 2019-11-16T12:41:14
| 2019-11-16T12:41:14
| 222,097,028
| 1
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 130
|
sce
|
SoundAndNoise.sce
|
clear;
clf;
dt = 1/22050;
t = 0:dt:4;
noise = 1.*rand(t);
x = cos(2.*(%pi).*t.*20000000);
y = noise + x;
sound(x);
sound(y);
|
51ff23b51721eeb3e64bc93bead68ced06bf0f3a
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/446/CH12/EX12.2/12_2.sce
|
c7f1e5966480d015db24ec06d8097aed3e0d0a69
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 325
|
sce
|
12_2.sce
|
clear
clc
disp('Exa-12.2');
r0=1.2; //standard value.
A=12;
r= r0*A^(1/3);printf('The value of mean radius for C is: %.2f fm\n',r);
A=70; //given value
r= r0*A^(1/3);printf('The value of mean radius for C is: %.2f fm\n',r);
A=209;
r= r0*A^(1/3);printf('The value of mean radius for C is: %.2f fm',r);
|
1bd853c57e1f0547829f66880d1fe71d716b5e39
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/62/CH2/EX2.14.a/ex_2_14.sce
|
6d33b96f2eaeb49781053576cf1fc8f937acd612
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 812
|
sce
|
ex_2_14.sce
|
//Example 2.14:Convolution Integral
clear;
close;
clc;
t =-5:1/100:5;
for i=1:length(t)
if t(i)<0 then
h1(i)=0;
h2(i)=0;
else
h1(i)=exp(-2.*t(i));
h2(i)=2*exp(-t(i));
end
end
h=convol(h1,h2);
figure
a=gca();
a.x_location="origin";
plot2d(t,h1)
xtitle('Impulse Response exp(-2*t)','t','h1(t)');
a.children.children.thickness = 3;
a.children.children.foreground= 2;
figure
a=gca();
plot2d(t,h2)
xtitle('Impulse Response 2*exp(-t)','t','h2(t)');
a.children.children.thickness = 3;
a.children.children.foreground= 2;
figure
a=gca();
t1=-10:1/100:10;
a.y_location="origin";
plot2d(t1,h)
xtitle('Impulse Response of the overall system =h1(t)*h2(t)','t','h(t)');
a.children.children.thickness = 3;
a.children.children.foreground= 2;
|
52bfb590a0180c48a6425dee3fc91c325e9bb05a
|
a159f59d19e2b03b234e9c2977ba4a932180e648
|
/Software/GreenScilabV0.9/bin/gl_retrieve_structure.sci
|
acd445e976332064ccbdb65c8d7c052a4ec93b63
|
[] |
no_license
|
OpenAgricultureFoundation/openag_sim
|
e052bbcc31b1d7f9b84add066327b479785f8723
|
425e678b55e24b5848d17181d25770175b8c2c3f
|
refs/heads/master
| 2021-07-01T06:25:08.753260
| 2017-09-20T21:44:18
| 2017-09-20T21:44:18
| 80,540,145
| 0
| 1
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 7,386
|
sci
|
gl_retrieve_structure.sci
|
//****************************************
// Copyright (c) 2003 LIAMA
// File name: Gl_retrieve_structure
// Author: Kang Mengzhen Version: 1.0 Date: 2003-6-20
// Display 3D, skeleton or linear file of plant occording to structure description file
//History:
//Author time version description
//Kang Mengzhen
//****************************************
//StrFileName = xgetfile('*.str','\str', title='open str file');
StrFileName=GL_SYS_DIR+'str'+SEPARATOR+FileID+'.str';
[fidstr, err] = mopen(StrFileName, 'rb');
if err then
disp(err)
disp('.str file read error.');
abort
end
//read data from str file
//disp(strcat(['Reading data from :',StrFileName,' ...']));
[rFilepath,rFileID,rFileextension]=fileparts(realFile);
rStrFileName=GL_SYS_DIR+'str'+SEPARATOR+rFileID+'.str';
disp(strcat(['Reading data from :',rStrFileName,' ...']));
IDSmb=zeros(1,4);//integer ID of organs
//read 10 data from the header
data=mget(10,'l', fidstr);
//data=[maxp N NumStr IDSmbInternode IDSmbLeaf IDSmbFemalFlower IDSmbMalFlower LifetimeInternode LifetimeLeaf LifetimeFlower];
maxp=data(1);N=data(2); NumStr=data(3);IDSmb(1:4)=data(4:7);To=data(8:10);
//read second 10 data from the header
data=mget(10,'l', fidstr);//Tr
Tr=data(1:maxp);
//read second third data from the header
data=mget(10,'l', fidstr); //NumInit
NumInit=data(1:maxp);
//read second fourth data from the header
data=mget(10,'l', fidstr) ;//Nr
Nr=data(1:maxp);
//get organ smb file name according to their id
[Smb_I,Smb_L,Smb_Ff,Smb_Fm]=Draw_ID2SMB(IDSmb);
//load geometrical data of each organ symbal,Smb_I,Smb_L,Smb_Ff,Smb_Fm
exec(GL_SYS_DIR+'bin'+SEPARATOR+'Draw_load_SMB.sci');
//printf(strcat(['Number of structures :' string(NumStr) ' ...\n']));
//read structure information(StrInf) for NumStr*40 bytes
StrInf=zeros(NumStr,10);
StrId=zeros(maxp,N,N,N,max(Tr),max(NumInit),nr);
for i=1:NumStr //for each substructure
//read 10 data
data=mget(10,'l', fidstr); //data=[4 p k j i r g m NO 0];4-substrucuture, p-phy_age of substructure
//k-chr_age of substructure, j-upper j GUs in this substructure, i-chr_age of plant, r-random index(1 for deterministic case)
//g-geometrical index(substructure can have several initial angles, m-reiteration order(1 for highest order))
//NO-number of blockes in this substrcture
//keep information for i-th substructure in StrInf(i,:)
StrInf(i,:)=data;
//Build a map StrId, so that given information of a substructure, it's index can be easily found.
StrId(data(2),data(3),data(4),data(5),data(6),data(7),data(8))=i;
end;
printf('\n');
//number of blocks NO in each structure
StrSz=StrInf(:,9)';
//sum of number of blocks NO in each structure
StrSzSum=sum(StrSz);
printf(strcat(['Total number of data blocks :',string(StrSzSum),'.\n']));
printf('Reading data blocks ......\n');
//read block information(data) for NumStr*40 bytes
data=zeros(StrSzSum,22);
for i=1:StrSzSum //for each block
// read 8 integer data
temp=mget(8,'l', fidstr);
data(i,1:8)=temp;
//read 14 float data
temp=mget(14,'f', fidstr);
data(i,9:22)=temp;
//when every 1/5 part of all blockes are read, disp info
templenround=round(StrSzSum/5);
if templenround > 0 then
if i- round(i/templenround)*templenround==0 then
printf(' %4d \n',i);
end;
end;
end;
clear temp
mclose (fidstr); //close .str file
printf('\n');
//global XI YI ZI CI
//prompt dialogue
///labels=['Phy_age(1-'+string(maxp) +')';'Chr_age plant:(1-'+string(N)+')';'Chr_age substructure:(1-'+string(N)+')(<=Chr_age of plant)';'Initial Angle(1-'+string(NumInit(1))+ ')';'Reiteration (1-'+string(Nr(1))+')'];
//labels=['PA','CA plant','CA sub','Init_Ang','Reiter Order'];
//labels=['PA','CA plant','CA sub'];//suppose Init_Ang=1 and Reiter Order=1
//init=['1';string(N);string(N)];
//dlgTitle='choose a structure';
//[ok,p,i,j]=getvalue(dlgTitle,labels,list("vec",1,"vec",1,"vec",1),init);
//if ~ ok then
// p=0;i=0;j=0;
//end
//while i>0
//parameter for slected substructure, 7 charactors
//para=[p, j, j, i, 1, 1,1];
p=1;
if Flag_geo_3D(p)==1 then// draw 3D
CurT=timer();
f=scf();
f.visible='off';
drawlater();
if Flag_geo_full==0 then //compute only plant geometry at age N
i0=N;
else
i0=1;
end
mode_boundary=2;
for i=i0:N
para=[1, i, i, i, 1, 1,1];
XI=[];YI=[];ZI=[];CI=[];
XB=list();YB=list();ZB=list();CB=[];
XFf=list();YFf=list();ZFf=list();CFf=[];
XFm=list();YFm=list();ZFm=list();CFm=[];
V=eye(3,3);O=zeros(1,3);
[XI, YI, ZI, CI, XB, YB, ZB, CB, XFf, YFf, ZFf, CFf, XFm, YFm, ZFm, CFm]=Draw_3D(para,V,O,StrInf,StrId,NumStr,StrSz,data,x_B,y_B,z_B,x_Ff,y_Ff,z_Ff,x_Fm,y_Fm,z_Fm,To,XI, YI, ZI, CI, XB, YB, ZB, CB, XFf, YFf, ZFf, CFf, XFm, YFm, ZFm, CFm);
//draw internodes
n=size(XI,2);
plot3d(XI,YI,list(ZI,CI),flag=[mode_boundary,4,0]); // QR 2005 12//
e=gce(); e.hiddencolor=-1; //e.color_mode=-e.color_mode;
if Flag_geo_leaf==1//draw leaves
for i = 1:length(XB); //for each face i in the smb
x=XB(i); y=YB(i); z=ZB(i);
plot3d(x,y,list(z,CB(i)),flag=[mode_boundary,4,0]) //QR 2005 12
//plot3d(x,y,list(z,CB(i))) //QR 2005 12
h=get("hdl");
h.hiddencolor=-CB(i);
end
e=gce(); e.hiddencolor=-1; //e.color_mode=-e.color_mode;
end
if Flag_geo_fruit==1//draw female flower
for i = 1:length(XFf); //for each face i in the smb
x=XFf(i); y=YFf(i); z=ZFf(i);
drawlater();
plot3d(x,y,list(z,CFf(i)),flag=[mode_boundary,4,0]) // QR 2005 12
e=gce(); e.hiddencolor=-1;
h=get("hdl");
h.hiddencolor=-CFf(i);
//e.color_mode=-e.color_mode;
end
//draw male flower
for i = 1:length(XFm); //for each face i in the smb
x=XFm(i);
y=YFm(i);
z=ZFm(i);
drawlater();
plot3d(x,y,list(z,CFm(i)),flag=[mode_boundary,4,0]) // QR 2005 12
e=gce();
e.hiddencolor=-1;
//e.color_mode=-e.color_mode;
end
end
a=get("current_axes");
a.cube_scaling="off";
//a.isoview="on" ;
//a.axes_visibles="off";
[parts,fname,extension] = fileparts(realFile);
ind_fname = strindex(fname, 'maize');
if ind_fname == [] then
a.rotation_angles = [90,90] ;
else
a.rotation_angles = [90,0] ;
end;
a.margins=[0 0 0 0];
a.axes_visible=['on' 'on' 'on'];
clear XI YI ZI CI XB YB ZB CB XFf YFf ZFf CFf XFm YFm ZFm CFm
end
f.visible='on';
f.rotation_style = "multiple";
drawnow();
//PassT=timer()-CurT;
printf(strcat(['3D: ',string(timer()),' seconds.\n']));
//h.color_mode=-2;
end//draw 3D
|
83a0fab1d9f62a3277ec003563b767fe85a8a865
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1118/CH26/EX26.2/eg26_2.sce
|
d61c7cb8ad6beb9fcb0414d9ae36d53c2aacf275
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 321
|
sce
|
eg26_2.sce
|
clear;
//clc();
i1=20;
f=50;
v=230;
q1=acosd(0.75);
q2=acosd(0.9);
ic=i1*cosd(q1)*(tand(q1)-tand(q2));
cap=ic/(v*2*(%pi)*f);
printf("The capaciatnce is:%.2f uF\n",cap*1000000);
qc=v*ic;
printf("The kVAr is:%.3f kVAr\n",qc/1000);
i2=i1*cosd(q1)/cosd(q2);
printf("the new supply current is:%.2f A",i2);
|
b2b7fd3d24f36ad0299beae9f1fee497c13103c9
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/671/CH14/EX14.15/14_15.sce
|
d233ecf6bf3be6a3b03e90e700da5d65034be103
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 161
|
sce
|
14_15.sce
|
V=5.9
Rx=0
Rm=2000
R1=49000
Ifsd=100E-6
Vam=Rm*Ifsd
I=(V-Vam)/R1
Ish=I-Ifsd
R2=Vam/Ish
disp(R2)
I=0.6*I
Req=V/I
Rx=Req-R1-Rm*R2/(R2+Rm)
disp(Rx)
|
733a1e9154fcac5b7a9e2f5dca867931e288de35
|
676ffceabdfe022b6381807def2ea401302430ac
|
/solvers/CompressibleFlowSolver/Tests/CylinderSubsonic_FRHU_SEM.tst
|
2f97958a498557f995d01399eef52a26b5596df4
|
[
"MIT"
] |
permissive
|
mathLab/ITHACA-SEM
|
3adf7a49567040398d758f4ee258276fee80065e
|
065a269e3f18f2fc9d9f4abd9d47abba14d0933b
|
refs/heads/master
| 2022-07-06T23:42:51.869689
| 2022-06-21T13:27:18
| 2022-06-21T13:27:18
| 136,485,665
| 10
| 5
|
MIT
| 2019-05-15T08:31:40
| 2018-06-07T14:01:54
|
Makefile
|
UTF-8
|
Scilab
| false
| false
| 1,035
|
tst
|
CylinderSubsonic_FRHU_SEM.tst
|
<?xml version="1.0" encoding="utf-8"?>
<test>
<description>Euler, Subsonic Cylinder, Dirichlet bcs, FRHU, SEM</description>
<executable>CompressibleFlowSolver</executable>
<parameters>CylinderSubsonic_FRHU_SEM.xml</parameters>
<files>
<file description="Session File">CylinderSubsonic_FRHU_SEM.xml</file>
</files>
<metrics>
<metric type="L2" id="1">
<value variable="rho" tolerance="1e-12">10.7744</value>
<value variable="rhou" tolerance="1e-12">1.07625</value>
<value variable="rhov" tolerance="1e-8">0.0228178</value>
<value variable="E" tolerance="1e-12">2.228e+06</value>
</metric>
<metric type="Linf" id="2">
<value variable="rho" tolerance="1e-12">1.22537</value>
<value variable="rhou" tolerance="1e-12">0.148574</value>
<value variable="rhov" tolerance="1e-8">0.0874203</value>
<value variable="E" tolerance="1e-12">253419</value>
</metric>
</metrics>
</test>
|
70885604c7d8bcbe58b9bc2e11c21816cda0619c
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1373/CH3/EX3.29/Chapter3_Example29.sce
|
d5f1d0fc9d3163503a7f3f29af7a2c019d6b3bd0
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,281
|
sce
|
Chapter3_Example29.sce
|
//Chapter-3, Example 3.29, Page 104
//=============================================================================
clc
clear
//INPUT DATA
W=1;//Length of the cylinder in m
D=0.05;//Diameter of the cylinder in m
Ta=45;//Ambient temperature in degree C
n=10;//Number of fins
k=120;//Thermal conductivity of the fin material in W/m.K
t=0.00076;//Thickness of fin in m
L=0.0127;//Height of fin in m
h=17;//Heat transfer coefficient in W/m^2.K
Ts=150;//Surface temperature of cylinder in m
//CALCULATIONS
P=(2*W);//Perimeter of cylinder in m
A=(W*t);//Surface area of cyinder in m^2
m=sqrt((h*P)/(k*A));//Calculation of m for determining heat transfer rate
Qfin=(sqrt(h*P*k*A)*(Ts-Ta)*((tanh(m*L)+(h/(m*k)))/(1+((h/(m*k))*tanh(m*L)))));//Heat transfer through the fin in kW
Qb=h*((3.14*D)-(n*t))*W*(Ts-Ta);//Heat from unfinned (base) surface in W
Q=((Qfin*10)+Qb);//Total heat transfer in W
Ti=((Ts-Ta)/(cosh(m*L)+((h*sinh(m*L))/(m*k))));//Ti to calculate temperature at the end of the fin in degree C
T=(Ti+Ta);//Temperature at the end of the fin in degree C
//OUTPUT
mprintf('Rate of heat transfer is %3.2f W\nTemperature at the end of the fin is %3.2f degree C',Q,T )
//=================================END OF PROGRAM==============================
|
2e1837d493f5219f501b69978e19f9f5df4aace6
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/260/CH4/EX4.19/4_19.sce
|
f5ac2db40aeffe062f63d41447e2bfd243d8b2b7
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 503
|
sce
|
4_19.sce
|
//Eg-4.19
//pg-193
clear
clc
a=[1 -14 71.74 -153.9 122.2525];
b0=0;
b01=1;
g=-1;
d=1;
printf('The results for 10 iterations are presented below\n\n')
printf(' i g d b1 b2 r1 r2\n')
for i=1:10
b1=a(2)-g*b01-d*b0;
b2=a(3)-g*b1-d*b01;
r1=a(4)-g*b2-d*b1;
r2=a(5)-d*b2;
dnew=a(5)/b2;
gnew=(a(4)-dnew*b1)/b2;
d=dnew;
g=gnew;
printf(' %d %f %f %f %f %f %f\n',i,g,d,b1,b2,r1,r2)
end
|
b9e0a678f92d556e154f1fd546ae361ea08b75a8
|
8217f7986187902617ad1bf89cb789618a90dd0a
|
/browsable_source/2.1.1/Unix/scilab-2.1.1/macros/calpol/pdivg.sci
|
892aefc01b8569b8ca81a0ade0af07153f1f3621
|
[
"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
| 2022-09-13T14:41:51
| 258,270,193
| 0
| 1
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 234
|
sci
|
pdivg.sci
|
function pdiv(P1,P2)
// Element wise euclidan division of two polynomial matrices
// This is just a loop for pdiv
//!
[n,m]=size(P1);
for l=1:n,
for k=1:m,
[rlk,qlk]=pppdiv(P1(l,k),p2),R(l,k)=rlk;Q(l,k)=qlk;
end;
end
|
d9875fc6e17511ee648f9c0a5e8f08b21d6a0525
|
178822612bcd418dc12ba7a649304a24ab618d60
|
/Numerical Analysis/descente.sci
|
b157f4576ab7c8796ca4bdba13940d1849e71201
|
[] |
no_license
|
engom/Math_Problem_Solving
|
b56c6cbfbff6c416c519795b9ab8f0c0bbba5ea3
|
6538c476681ae4ee803ea9b3a8944c5f370e1961
|
refs/heads/master
| 2022-05-25T01:13:16.123161
| 2016-02-13T11:32:28
| 2016-02-13T11:32:28
| null | 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 219
|
sci
|
descente.sci
|
function[x]= descente(A,b)
n=size(A)
i=1:n
j=1:n
A=A(i,j)
x(1)=b(1)/A(1,1)
for k=2:n
s=0
for j=1:k-1
s=s+A(k,j)*x(j)
end
x(k)=(b(k)-s)/A(k,k)
end
endfunction
|
75aaefc3ce20ca32fc00b35f57f9c20617783754
|
a62e0da056102916ac0fe63d8475e3c4114f86b1
|
/set5/s_Electrical_And_Electronic_Principles_And_Technology_J._Bird_1529.zip/Electrical_And_Electronic_Principles_And_Technology_J._Bird_1529/CH15/EX15.21/15_21.sce
|
39956cb60d29e1c41fbfac5356317c57511496aa
|
[] |
no_license
|
hohiroki/Scilab_TBC
|
cb11e171e47a6cf15dad6594726c14443b23d512
|
98e421ab71b2e8be0c70d67cca3ecb53eeef1df6
|
refs/heads/master
| 2021-01-18T02:07:29.200029
| 2016-04-29T07:01:39
| 2016-04-29T07:01:39
| null | 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 311
|
sce
|
15_21.sce
|
errcatch(-1,"stop");mode(2);//Chapter 15, Problem 21
;
R=2; //resistance in ohm
L=60e-3; //inductance in henry
C=30e-6; //capacitance in farad
Q=(1/R)*sqrt(L/C); //Q factor
printf("Q factor = %f ",Q);
exit();
|
4f7eb36131464a24273dd8e506a7af3da19aab35
|
3073307fa4b6da9371518f0718c199501b8c5c71
|
/viejos/cubic_spline_nat.sci
|
f6cbadeff1d9eb74c3dcf8e981a51ec450b00839
|
[] |
no_license
|
fern17/CalculoNumerico
|
8b04abdf8e1da4b69a1256334a4bc58ff5c9180d
|
c793733ce17616361dd02f358ef63c1d9be5c99e
|
refs/heads/master
| 2020-06-04T00:06:19.723655
| 2011-12-20T13:47:40
| 2011-12-20T13:47:40
| 2,929,202
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 723
|
sci
|
cubic_spline_nat.sci
|
function [a,b,c,d] = cubic_spline_nat(x,f)
n = length(x);
h = zeros(n,1);
a = f;
for i=1:n-1
h(i) = x(i+1) - x(i);
end
for i=2:n-1
alfa(i) = 3/h(i) * (a(i+1) - a(i))- 3/h(i-1) * (a(i) - a(i-1));
end
l = ones(n,1);
mu = zeros(n,1);
zeta = zeros(n,1);
for i=2:n-1
l(i) = 2 * (x(i+1) - x(i-1)) - h(i-1)*mu(i-1);
mu(i) = h(i)/l(i);
zeta(i) = (alfa(i) - h(i-1) * zeta(i-1)) / l(i);
end
b = zeros(n,1);
c = zeros(n,1);
d = zeros(n,1);
for j=(n-1):-1:1
c(j) = zeta(j) - mu(j)*c(j+1);
b(j) = (a(j+1) - a(j)) / h(j) - (h(j)/3) * (c(j+1) + 2*c(j));
d(j) = (c(j+1) - c(j)) / (3*h(j));
end
endfunction
|
dffa73cd9ca88f61898fdb0cd479f03efacff503
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2444/CH1/EX1.3/ex1_3.sce
|
0e924a618e903baedc6f1f866e445a0f34d19c54
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 358
|
sce
|
ex1_3.sce
|
// Exa 1.3
clc;
clear;
close;
format('v',10)
// Given data
e = 1.6*10^-19;// in C
m = 9.1*10^-31;// in kg
miu_e = 7.04 * 10^-3;// in m^2/V-s
n = 5.8*10^28;// in /m^3
torque = (miu_e/e)*m;// in sec
disp(torque,"The relaxation time in sec is");
sigma = n*e*miu_e;
rho = 1/sigma ;// in ohm-m
disp(rho,"The resistivity of conductor in ohm-m is");
|
2101c7a1a11030fde7579358517e95737959fd6f
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/2321/CH10/EX10.5.4/EX10_5_4.sce
|
e6b0fd84007bad275b2cbcf451bc56608cf3a8ee
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 733
|
sce
|
EX10_5_4.sce
|
//Example No. 10.5.4
clc;
clear;
close;
format('v',6);
Do_dB=14;//dB(Directivity)
f=2.4;//GHz(Frequency)
c=3*10^8;//m/s(Speed of light)
lambda=c/(f*10^6);//m(Wavelength)
Do=10^(Do_dB/10);//unitless(Directivity)
C=lambda;//m////for optimum result(Circumference)
alfa=14;//degree;////for optimum result(Pitch angle)
S=C*tand(alfa);//m(Spacing)
N=Do/15/(C/lambda)^2/(S/lambda);//turns
N=round(N);//turns
Rin=140*C/lambda;//Ω(Input impedence)
disp(Rin,"Input impedence in Ω is : ");
HPBW=52/(C/lambda*sqrt(N*S/lambda));//degree
disp(HPBW,"HPBW in degree : ");
format('v',4);
FNBW=115/(C/lambda*sqrt(N*S/lambda));//degree
disp(FNBW,"FNBW in degree : ");
AR=(2*N+1)/2/N;//(Axial ratio)
disp(AR,"Axial ratio : ");
|
0c6eed9a9266418d7430fac4c08ce06c8801e322
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/278/CH24/EX24.8/ex_24_8.sce
|
3c8a468fd320d0dc8c1ac6f267afa446dbdd050a
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 327
|
sce
|
ex_24_8.sce
|
//find..
clc
//solution
//given
n1=3
n2=2
d2=120//mm
r2=60//mm
pmax=0.1//N/mm^2
P=25000//W
N=1575//rpm
u=0.3
T=P*60/(2*%pi*N)*1000//N-mm
C=pmax*r2//N/mm
//W=2*%pi*C(r1-r2)=37.7(r1-60)//N
//R=(r1+r2)/2=0.5*r1 +30
n=n1+n2-1
//T=n*u*R*W=22.62*r1^2-81432
r1=sqrt((T+81432)/22.62)
printf("outr dia is,%f mm\n",r1)
|
1adeae7167a83b4bca96c7b460d0fc90e5d5abd3
|
8217f7986187902617ad1bf89cb789618a90dd0a
|
/browsable_source/2.4/Unix-Windows/scilab-2.4/macros/mtlb/mtlb_rand.sci
|
82ebfed56efa5a85df18833324b0b4f58d173cbb
|
[
"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
| 2022-09-13T14:41:51
| 258,270,193
| 0
| 1
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 109
|
sci
|
mtlb_rand.sci
|
function r=mtlb_rand(a)
// Copyright INRIA
if size(a)==[1 1] then
r=rand(a,a)
else
r=rand(a(1),a(2))
end
|
6c4527e07d510dce3a0edfa9031d1dde3502f125
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/623/CH10/EX2.9.2/U2_C9_2.sce
|
067bb56d4ee07a4d4ce3c5cbd3993ced73905aac
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 234
|
sce
|
U2_C9_2.sce
|
//variable initialization
x=0:0.1:9999;
x0=0;
x1=9999;
//calculation
I=integrate('x^2*exp(-x)','x',x0,x1);
A=sqrt(1/(I*(%pi/2)));
r=(1/4)*integrate('x^3*exp(-x)','x',x0,x1);
printf("\n A = %f*a0^-1.5\n r = %.1f*a0",A,r);
|
3949212d7d3b3d34141932fd1b7d3614e70c4c23
|
45e046b9cab35a22858077ef405f8c8b8125a87f
|
/Assignment-1/Questn-9/binom.sce
|
f3914ff2f444fcab9d4ee1ae4ac561320f917a3c
|
[] |
no_license
|
shilpasunil/AP-laboratory
|
4a67e510a05e5ce48f200ee73183627a12a19d55
|
87d55510d6f3c4a80ce1779e9b39430ee20e69b2
|
refs/heads/main
| 2023-02-09T16:13:34.048845
| 2021-01-07T04:43:35
| 2021-01-07T04:43:35
| 327,504,813
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,079
|
sce
|
binom.sce
|
function [time] = formula_based(i,k,time)
tic();
if (k==0 || i==k )then
res=1;
time=time+toc();
return;
elseif (k<i) then
num_p=1;
den_p=1;
if (i< 2* k) then
k=i-k;
for j = 1:k+1
num_p = num_p * (i+1 -j);
den_p =den_p *j;
end
res =num_p/den_p;
time=time+toc();
return;
end
end
res=0;
time=time+toc();
return;
endfunction
n=10;
r=100;
s=1;
ft=zeros(1,n)
rt=zeros(1,n);
dt=zeros(1,n)
noe=zeros(1,n);
for i=1:n
time=0;
dtime=0;
ftime=0;
noe(s)=n;
for j=1:r
k=grand(1,1,"uin",0,i);
[time]= recursive_bin(i,k,time);
[dtime]=dynamic_binomial(i,k,dtime);
[ftime]=formula_based(i,k,ftime);
end
rt(s)=(time/100);
dt(s)=(dtime/100);
ft(s)=ftime/100;
s=s+1;
end
clf
plot(rt,"k");
plot(dt,"m");
plot(ft,"r")
xlabel("N");
ylabel("TIME TAKEN IN s");
title("VARIANTS OF BINARY SEARCH");
xgrid(2);
legend("RECURSIVE","DYNAMIC","FORMULA")
//y=linspace(-2,)
|
3eba7661962f46698bd3101577eabb01548a8844
|
19a22e633cc56583816340cd0367b9c53c4ec593
|
/gaussEle.sce
|
dba8346e1f83ba2465098e5a8e383e4eb88fbca5
|
[] |
no_license
|
BlueNokia/scilab
|
eb835ed1431722af0d6dc2d0c883afe026720579
|
a144ccf7a003a37d0e7925da9812fb4b7912c713
|
refs/heads/master
| 2020-04-25T15:13:40.936378
| 2019-04-14T20:52:56
| 2019-04-14T20:52:56
| 172,870,842
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 844
|
sce
|
gaussEle.sce
|
function [x] = gausselimPP(A,b)
[nA,mA] = size(A)
[nb,mb] = size(b)
if nA<>mA then
error('gausselim - Matrix A must be square');
abort;
elseif mA<>nb then
error('gausselim - incompatible dimensions between A and b');
abort;
end;
a = [A b];
n = nA;
// Augmented matrix
// Matrix size
//Forward elimination with partial pivoting
for k=1:n-1
kpivot = k; amax = abs(a(k,k));
//Pivoting
for i=k+1:n
if abs(a(i,k))>amax then
kpivot = i; amax = a(k,i);
end;
end;
temp = a(kpivot,:); a(kpivot,:) = a(k,:); a(k,:) = temp;
for i=k+1:n
//Forward elimination
for j=k+1:n+1
a(i,j)=a(i,j)-a(k,j)*a(i,k)/a(k,k);
end;
end;
end;
//Backward substitution
x(n) = a(n,n+1)/a(n,n);
for i = n-1:-1:1
sumk=0
for k=i+1:n
sumk=sumk+a(i,k)*x(k);
end;
x(i)=(a(i,n+1)-sumk)/a(i,i);
end;
endfunction;
|
32da83284fb9d0023aee8d1e693619b3194741d0
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/125/CH3/EX3.16/Example3_16.sce
|
f4808115bbda9880489a720538a31de74142d943
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 352
|
sce
|
Example3_16.sce
|
//Caption: Circular correlation between two signals
//Example3.16
//page 134
clc;
x = [5,10;15,20];
h = [3,6;9,12];
h = h(:,$:-1:1);
h = h($:-1:1,:);
X = fft2d(x);
H = fft2d(h);
Y = X.*H;
y = ifft2d(Y);
disp(y,'Circular Correlation result y=')
//Result
// Circular Correlation result y=
//
// 300. 330.
// 420. 450.
|
2edd22ae4f9cdae3494ca5114b01c05aaf70b13e
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/1109/CH3/EX3.12/3_12.sce
|
f9a0f164c202cfd700f464be0aa7c63573b4831c
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 500
|
sce
|
3_12.sce
|
clear;
clc;
l=10;Zo=280*exp(-%i*(%pi/(180/30)));P=0.08*exp(%i*(%pi/(180/40)));f=5000/(2*%pi);
w=2*%pi*f;
Z1=Zo*tanh(P*l/2);
Rs=real(Z1);
Ls=imag(Z1)/w;
printf("-Resistance of series element = %f ohms\n",fix(Rs));
printf("-Inductance of series element = %f mH\n",round(Ls*(10^3)*100)/100);
Z2=Zo/(sinh(P*l));
Rsh=real(Z2);
Csh=-imag(Z2)/w;
printf("-Resistance of shunt element = %f ohms\n",round(Rsh*10)/10);
printf("-Capacitance of shunt element = %f microfarads",fix(Csh*1000)/1000);
|
97f037f18992e95c328de9ecfd6f90319f8fd53d
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3622/CH9/EX9.2/Ex9_2.sce
|
72d87f86839f07c51c4af565662bc28eb0d8c5c8
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 191
|
sce
|
Ex9_2.sce
|
//Initialisation of variables
clc
m=9e-31//mass of electron
e=1.6e-19//charge of electron
V=5000//volts
v=sqrt(2*V*e/m)
printf('maximum speed of electron is %e metre per second \n',v)
|
95b5627238ad5da5b0e708c80eb269cd8ac118c4
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3281/CH7/EX7.12/ex7_12.sce
|
816660d634169c2a1ba367d41f29698e68715d9d
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 498
|
sce
|
ex7_12.sce
|
//Page Number: 377
//Example 7.12
clc;
//Given
V0=10D+3; //V
V01=5D+3; //V
I0=2; //A
b=3D-2; //m
a=2D-2; //m
B0=0.01; //Wb/m2
ebym=1.759D+11;
//Cut off voltage
x=1-((b*b)/(a*a));
V=(ebym*(B0^2)*(a^2)*(x^2))/8;
KV=V/1000; //Kilovolts
disp('KV',KV,'Cut off voltage:');
//Magnetic flux density
y=-sqrt((8*V01)/ebym);
B=y/(a*x);
disp('Wb/m2',B,'Magnetic flux density:');
//Answer in book is wrong for Magnetic flux density as a*a ,where a=2, is taken as 5, which should be 4
|
ca331ad5b3e9cf56698b2816e0ac5fed340e6c3f
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/281/CH4/EX4.7/example4_7.sce
|
9c8dd307e618a0e8a3ac4a651bf037cde7be2ab1
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 1,064
|
sce
|
example4_7.sce
|
disp('chapter 4 ex4.7')
disp('given')
disp('capacitor coupled non inverting amplifier design')
disp("voltage gain=100")
disp("Supply voltage=24v ")
Av=100
Vcc=24
disp("Output amplitude=5V")
Vo=5
disp("lower cut off frequency for the circuit =75Hz")
disp('Rl=5.6kohms')
disp("Ibmax=500nA")
Vbe=0.7
Ibmax=500*10^(-9)
disp("I2>>Ibmax")
I2=100*Ibmax
disp(I2,"I2=")
R1=(Vcc/2)/I2
disp("R1= ")
disp('ohms',R1)
R2=(Vcc/2)/I2
disp(R2,"R2=")
disp("assume R1=220Kohms")
disp("Vi=Vo/Av")
Vi=Vo/Av
disp(Vi,"Vi=")
R1=220000
disp("I4>>Ibmax")
I4=100*Ibmax
disp(I4,"I4=")
R4=Vi/I4
disp(R4,"R4=")
disp("R3+R4=Vo/I4")
R3=(Vo/I4)-R4
disp(R3,"R3=")
Rp=(R1*R2)/(R1+R2)
disp(Rp,"Rp(R1||R2)=")
f1=75
disp("Xc1=Rp/10 at F1")
disp("C1=1/(2*pi*f1*(Rp/10))")
C1=1/(2*%pi*f1*(Rp/10))
disp('farads',C1)
Rl=5600
disp("Xc2=Rl/10 at F1")
disp("C2=1/(2*pi*f1*(Rl/10))")
C2=1/(2*%pi*f1*(Rl/10))
disp('farads',C2)
disp("C1=1/(2*pi*f1*R4)")
C3=1/(2*%pi*f1*R4)
disp('farads',C3)
disp("The circuit voltage should be normally between 9 to 18 volts")
|
74f824f9304f59a19572645cc9954176210a3a8c
|
8217f7986187902617ad1bf89cb789618a90dd0a
|
/browsable_source/2.4.1/Unix-Windows/scilab-2.4.1/macros/util/unix_s.sci
|
63065699a0394c41dc388231e43eaecd9139da7e
|
[
"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
| 2022-09-13T14:41:51
| 258,270,193
| 0
| 1
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 972
|
sci
|
unix_s.sci
|
function unix_s(cmd)
//unix_s - silent shell command execution
//%Syntax
// unix_s(cmd)
//%Parameters
// cmd - a character string
//%Description
// cmd instruction (sh syntax) is passed to shell, the standard output
// is redirected to /dev/null
//%Examples
// unix_s("\rm -f foo")
//%See also
// host unix_g unix_x
//!
// Copyright INRIA
if prod(size(cmd))<>1 then error(55,1),end
if getenv('WIN32','NO')=='OK' & getenv('COMPILER','NO')=='VC++' then
tmp=strsubst(TMPDIR,'/','\')+'\unix.out';
cmd1= cmd + ' > '+ tmp;
else
cmd1='('+cmd+')>/dev/null 2>'+TMPDIR+'/unix.err;';
end
stat=host(cmd1);
if getenv('WIN32','NO')=='OK' & getenv('COMPILER','NO')=='VC++' then
host('del '+tmp);
end
select stat
case 0 then
case -1 then // host failed
error(85)
else //sh failed
if getenv('WIN32','NO')=='OK' & getenv('COMPILER','NO')=='VC++' then
error('unix_s: shell error');
else
msg=read(TMPDIR+'/unix.err',-1,1,'(a)')
error('unix_s: '+msg(1))
end
end
|
145fd3dd5b28ae4bc9891e024a276984a991c698
|
d465fcea94a1198464d7f8a912244e8a6dcf41f9
|
/kMatlab/kRadio_status.sci
|
1a7c9a43a5ce57eb98d5046b762a63ea17f13161
|
[] |
no_license
|
manasdas17/kiks-scilab
|
4f4064ed7619cad9e2117a6c0040a51056c938ee
|
37dc68914547c9d0f423008d44e973ba296de67b
|
refs/heads/master
| 2021-01-15T14:18:21.918789
| 2009-05-11T05:43:11
| 2009-05-11T05:43:11
| null | 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 789
|
sci
|
kRadio_status.sci
|
function [res] = kRadio_status(ref)
// Ouput variables initialisation (not found in input variables)
res=[];
// Display mode
mode(0);
// Display warning for floating point exception
ieee(1);
// [ready_to_send message_recieved send_failed]=kRadio_status(ref);
res = "";
reply = kTurret(ref,4,"F");
// !! L.6: Matlab function sscanf not yet converted, original calling sequence used
[value,count,errmsg] = sscanf(mtlb_e(reply,3:$),"%d");
if value then
// !! L.8: Matlab function bitget not yet converted, original calling sequence used
// !! L.8: Matlab function bitget not yet converted, original calling sequence used
// !! L.8: Matlab function bitget not yet converted, original calling sequence used
res = [bitget(value,1),bitget(value,2),bitget(value,3)];
end;
endfunction
|
6fad22c4f3cef4f9b80ff1ab78076a93290f9ac3
|
449d555969bfd7befe906877abab098c6e63a0e8
|
/3751/CH7/EX7.8/Ex7_8.sce
|
b4b94bb301b6c7a19bdb063ae9e172fe158a78b1
|
[] |
no_license
|
FOSSEE/Scilab-TBC-Uploads
|
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
|
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
|
refs/heads/master
| 2020-04-09T02:43:26.499817
| 2018-02-03T05:31:52
| 2018-02-03T05:31:52
| 37,975,407
| 3
| 12
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 839
|
sce
|
Ex7_8.sce
|
//Fluid Systems- By Shiv Kumar
//Chapter 7- Performance of Water Turbine
//Example 7.8
// To Find Model Runner Speed and Prototype to Model Scale ratio
clc
clear
//Given:-
//For Prototype
Pp=30; //Power Developed, MW
Hp=55; //Head, m
Np=100; //Speed, rpm
Pp=Pp*1000; //KW
//For Model
Pm=25 ; //Power Developed, KW
Hm=6; //Head, m
//Computations:-
Nm=Np*(Hm/Hp)^(5/4)*(Pp/Pm)^(1/2); //rpm
DpbyDm=((Pp/Pm)*(Nm/Np)^3)^(1/5); //A Ratio(Dimensionless)
Lr= DpbyDm; //Scale Ratio
//Results
printf("The Model Runner Speed, Nm=%.2f rpm And\n",Nm)
printf("Prototype to Model Scale Ratio,Lr=%.2f",Lr) //The Answer vary due to Round off Error
|
9205a5d2c8d331a60aa2042ca55461e3bb203110
|
5a2ef4dfbfa1e2ddaadc61a6a8c57bb4a8b0b3dc
|
/personal/MatLab/Math_152/Assignment 3/g215x27/g215x27.sce
|
f573ab8d9284cf1113ea0fe7614654a101ea5987
|
[] |
no_license
|
cjbrooks12/CSCE
|
38e3e2a2746868dba804d7d4fe4970d5dc125d09
|
a5fe329764278ddefa6345dc3852d8fa2eec9cf9
|
refs/heads/master
| 2021-05-16T03:21:29.519222
| 2018-07-05T16:32:06
| 2018-07-05T16:32:06
| 15,951,593
| 0
| 1
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 400
|
sce
|
g215x27.sce
|
for test = 1:1:80
count = 0;
prime = 0;
number = 1;
while number <= test
prime = rem(test, number);
number = number + 1;
if prime == 0 && number ~= test
count = count + 1;
elseif prime == 0
count = count + 1;
end
end
if count == 2
fprintf('%0.0f ', test)
end
end
|
8cee4bd2a4ce4f868124b4ea19b35c86b3b08475
|
564beb66e232557765505973f93cc322a394133a
|
/KONA/scilab/cgs.sci
|
354a935fd51f9a1640bd4c7e9d9d7f60234d2785
|
[] |
no_license
|
KeithEvanSchubert/Keith_On
|
2442bb74b9d531c96d9f10da8df1dede54423094
|
fe8dd1e90e695957346aa176b7e0d0fea30171e3
|
refs/heads/master
| 2021-01-18T22:08:18.862471
| 2019-09-04T17:39:58
| 2019-09-04T17:39:58
| 51,767,267
| 0
| 0
| null | null | null | null |
UTF-8
|
Scilab
| false
| false
| 357
|
sci
|
cgs.sci
|
function [Q,R]=cgs(A)
max_col=size(A,2);
R=zeros(A);
Q=A;
R(1,1)=norm(A(:,1));
Q(:,1)=Q(:,1)/R(1,1);
for col=2:max_col
for col2=1:col-1
row=col2;
R(row,col)=Q(:,col2)'*A(:,col);
Q(:,col)=Q(:,col)-R(row,col)*Q(:,col2);
end
row=col;
R(row,col)=norm( Q(:,col) );
Q(:,col)=Q(:,col)/R(row,col);
end
endfunction
|
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