blob_id stringlengths 40 40 | directory_id stringlengths 40 40 | path stringlengths 6 214 | content_id stringlengths 40 40 | detected_licenses listlengths 0 50 | license_type stringclasses 2 values | repo_name stringlengths 6 87 | snapshot_id stringlengths 40 40 | revision_id stringlengths 40 40 | branch_name stringclasses 15 values | visit_date timestamp[us]date 2016-08-04 09:00:04 2023-09-05 17:18:33 | revision_date timestamp[us]date 1998-12-11 00:15:10 2023-09-02 05:42:40 | committer_date timestamp[us]date 2005-04-26 09:58:02 2023-09-02 05:42:40 | github_id int64 436k 586M ⌀ | star_events_count int64 0 12.3k | fork_events_count int64 0 6.3k | gha_license_id stringclasses 7 values | gha_event_created_at timestamp[us]date 2012-11-16 11:45:07 2023-09-14 20:45:37 ⌀ | gha_created_at timestamp[us]date 2010-03-22 23:34:58 2023-01-07 03:47:44 ⌀ | gha_language stringclasses 36 values | src_encoding stringclasses 17 values | language stringclasses 1 value | is_vendor bool 1 class | is_generated bool 1 class | length_bytes int64 5 10.4M | extension stringclasses 15 values | filename stringlengths 2 96 | content stringlengths 5 10.4M |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
3529b7c751c4dd83f035d0512036acc537b6b259 | 1bb72df9a084fe4f8c0ec39f778282eb52750801 | /test/TF44.prev.tst | b29a543fb6ad9249c4fdc5369cde7447063e06fc | [
"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 | 2,895 | tst | TF44.prev.tst | Expanding for base=2, level=3, reasons+features=base,same,similiar,evenexp invall,norm
Refined variables=x,y,z
[0+1x,0+1y,0+1z]: unknown -> [1] [0,0,0] x⁴-y⁴-2z²
-> solution [0,0,0],trivial(3) [1,1,0],trivial(3)
---------------- level 0
expanding queue[0]^-1,meter=[2,2,2]: x⁴-y⁴-2z²
[0+2x,0+2y,0+2z]: unknown -> [1] [0,0,0] 2x⁴-2y⁴-z²
-> solution [0,0,0],trivial(3) [2,2,0],trivial(3)
[1+2x,1+2y,0+2z]: unknown -> [2] [1,1,0] x+3x²+4x³+2x⁴-y-3y²-4y³-2y⁴-z²
-> solution [1,1,0],trivial(3) [3,3,0],trivial(3)
endexp[0]
---------------- level 1
expanding queue[1]^0,meter=[2,2,2]: 2x⁴-2y⁴-z²
[0+4x,0+4y,0+4z]: unknown -> [3] [0,0,0] 8x⁴-8y⁴-z²
-> solution [0,0,0],trivial(3) [4,4,0],trivial(3)
[2+4x,2+4y,0+4z]: unknown -> [4] [1,1,0] 4x+12x²+16x³+8x⁴-4y-12y²-16y³-8y⁴-z²
-> solution [2,2,0],trivial(3) [6,6,0],trivial(3)
endexp[1]
expanding queue[2]^0,meter=[2,2,2]: x+3x²+4x³+2x⁴-y-3y²-4y³-2y⁴-z²
[1+4x,1+4y,0+4z]: unknown -> [5] [0,0,0] x+6x²+16x³+16x⁴-y-6y²-16y³-16y⁴-2z²
-> solution [1,1,0],trivial(3) [5,5,0],trivial(3)
[3+4x,1+4y,0+4z]: negative-1 [5] by {x=>-x-1}
[1+4x,3+4y,0+4z]: negative-1 [5] by {y=>-y-1}
[3+4x,3+4y,0+4z]: negative-1 [5] by {x=>-x-1,y=>-y-1}
-> solution [3,3,0],trivial(3) [7,7,0],trivial(3)
endexp[2]
---------------- level 2
expanding queue[3]^1,meter=[2,2,2]: 8x⁴-8y⁴-z²
[0+8x,0+8y,0+8z]: same 32x⁴-32y⁴-z² map {x=>x/2,y=>y/2} -> [1] 2x⁴-2y⁴-z²
-> solution [0,0,0],trivial(3) [8,8,0],trivial(3)
[4+8x,0+8y,0+8z]: unknown -> [6] [1,0,0] 16x+48x²+64x³+32x⁴-32y⁴-z²+2
[0+8x,4+8y,0+8z]: unknown -> [7] [0,1,0] 32x⁴-16y-48y²-64y³-32y⁴-z²-2
[4+8x,4+8y,0+8z]: unknown -> [8] [1,1,0] 16x+48x²+64x³+32x⁴-16y-48y²-64y³-32y⁴-z²
-> solution [4,4,0],trivial(3) [12,12,0],trivial(3)
endexp[3]
expanding queue[4]^1,meter=[2,2,2]: 4x+12x²+16x³+8x⁴-4y-12y²-16y³-8y⁴-z²
[2+8x,2+8y,0+8z]: unknown -> [9] [0,0,0] 2x+12x²+32x³+32x⁴-2y-12y²-32y³-32y⁴-z²
-> solution [2,2,0],trivial(3) [10,10,0],trivial(3)
[6+8x,2+8y,0+8z]: negative-1 [9] by {x=>-x-1}
[2+8x,6+8y,0+8z]: negative-1 [9] by {y=>-y-1}
[6+8x,6+8y,0+8z]: negative-1 [9] by {x=>-x-1,y=>-y-1}
-> solution [6,6,0],trivial(3) [14,14,0],trivial(3)
endexp[4]
expanding queue[5]^2,meter=[2,2,2]: x+6x²+16x³+16x⁴-y-6y²-16y³-16y⁴-2z²
[1+8x,1+8y,0+8z]: unknown -> [10] [0,0,0] x+12x²+64x³+128x⁴-y-12y²-64y³-128y⁴-4z²
-> solution [1,1,0],trivial(3) [9,9,0],trivial(3)
[5+8x,5+8y,0+8z]: unknown -> [11] [1,1,0] 125x+300x²+320x³+128x⁴-125y-300y²-320y³-128y⁴-4z²
-> solution [5,5,0],trivial(3) [13,13,0],trivial(3)
[1+8x,1+8y,4+8z]: unknown -> [12] [0,0,1] x+12x²+64x³+128x⁴-y-12y²-64y³-128y⁴-4z-4z²-1
[5+8x,5+8y,4+8z]: unknown -> [13] [1,1,1] 125x+300x²+320x³+128x⁴-125y-300y²-320y³-128y⁴-4z-4z²-1
endexp[5]
---------------- level 3
Maximum level 3 [14] mod 2: x⁴-y⁴-2z²
|
04baa62e9dbc98221e65877475b185bf8a0929b9 | 20299e0ddeae804fa1b39a7e3d2964b4d6f29638 | /labs/lab1/Twochips.tst | c88066cd1f8d90f35caf4a08a7d626d51579e0b9 | [
"MIT"
] | permissive | Spud304/nand2tetris | 4cdc53ec18ff65ab44f50d6cf95367476171c6e4 | 0e4448f403721b5d2720c1fadbc74eebeee093fb | refs/heads/master | 2023-03-04T06:55:53.733219 | 2020-11-09T06:47:24 | 2020-11-09T06:47:24 | 308,123,827 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 153 | tst | Twochips.tst | load Twochips.hdl,
output-file Twochips.out,
compare-to Twochips.cmp,
output-list in%B3.1.3 out%B3.1.3;
set in 0,
eval,
output;
set in 1,
eval,
output; |
dae0bf4c00d87969e41c9798182752529050e376 | 449d555969bfd7befe906877abab098c6e63a0e8 | /3392/CH10/EX10.2/Ex10_2.sce | 3e2ca1900de3909388a647b3ee22b21dd47248bd | [] | 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 | Ex10_2.sce | clc
// initialization of variables
clear
d=100 //mm
Ix=2.45e+06 //mm^4
E=72 //GPa
L=6.8 //m
K=110 //N/mm
l=1.1 //m
P=12 //kN
//calculations
E=E*10^3
P=P*10^3
l=l*10^3
k=K/l
L1=7*l
Beta=(k/(4*E*Ix))^(1/4)
if(l<%pi/(4*Beta))
if(L1>3*%pi/(2*Beta))
y_max=P*Beta/(2*k)
M_max=P/(4*Beta)
S_max=M_max*d/(2*Ix)
end
end
printf('y_max = %.3f mm',y_max)
printf('\n M_max = %.2f kN.m',M_max/10^6)
printf('\n S_max = %.1f MPa',S_max)
A_bl=exp(-Beta*l)*(sin(Beta*l)+cos(Beta*l))
A_2bl=exp(-Beta*2*l)*(sin(Beta*2*l)+cos(Beta*2*l))
A_3bl=exp(-Beta*3*l)*(sin(Beta*3*l)+cos(Beta*3*l))
y_C=P*Beta/(2*k)*A_bl
y_B=P*Beta/(2*k)*A_2bl
y_A=P*Beta/(2*k)*A_3bl
printf('\n y_C = %.2f mm',y_C)
printf('\n y_B = %.2f mm',y_B)
printf('\n y_A = %.2f mm',y_A)
|
8b1cbca4724dfb87368bedd958b7ba38e876d339 | 81a5c9fb4452c596031b1d529ea71e53e423de8d | /print5.sce | 5fc76b21002047847f80d41c60410b2c348838a6 | [] | no_license | thevinitgupta/scilab | b9d6b31b27bd3192d3713470c4a51da080d6a572 | c0aa61b0463c3501d43b73fdec07b9dc7fc27b21 | refs/heads/main | 2023-03-22T07:49:10.980286 | 2021-03-12T13:32:10 | 2021-03-12T13:32:10 | 346,394,901 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 46 | sce | print5.sce | array = [4:3:18]
for i = array
disp(i)
end |
7a8815d8e72fc77a6b3ac4593872473aceb49ba1 | 449d555969bfd7befe906877abab098c6e63a0e8 | /3871/CH10/EX10.8/Ex10_8.sce | 4a7179509ae83196cc2e73835700fc3127e457a2 | [] | 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 | 359 | sce | Ex10_8.sce | //===========================================================================
//chapter 10 example 8
clc;clear all;
//variable declaration
S = 6; //resistance in Ω
AB = 25; //length of AB in cm
BC = 75; //length of BC in cm
//calculations
R = (AB/BC)*S; //unknown reistance in Ω
//result
mprintf("unknown resistance = %3.0f Ω ",R);
|
0da0d509a81ce4a3910f94d0b2d8239ad36f4730 | 0896434fe17d3300e03ad0250029673ebf70bacc | /sheet_7/Scilab_codes/PD_controller.sce | 79f1a5c3754e7cedf027736d8fc55b2a1514b6ef | [] | no_license | TheShiningVampire/EE324_Controls_Lab | 8ff1720b852bf24dca3c172082f5f898f80f69f3 | 9aea73eed3f5a4ac6c19a799f8aebe09f4af0be8 | refs/heads/main | 2023-07-09T17:30:38.041544 | 2021-08-23T12:14:29 | 2021-08-23T12:14:29 | null | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 237 | sce | PD_controller.sce | clear
close
clc
s = poly(0,'s');
G = (s+ 0.2)/((s^2 + 3*s + 2)*(s+0.01 ));
Glin = syslin('c',G);
evans(Glin,100);
// Finding theta from the damping ratio
zeta = 0.591;
theta = acos(zeta);
x = -2:0.1:0;
y = -tan(theta)*x;
plot(x, y);
|
c206da534dc68c8f1c8931090ecc25dc5777565c | ac66d3377862c825111275d71485e42fdec9c1bd | /Resources/res/map/map1112.sce | 88ce1e948a5735d438d1e5f59d0033950f0e6a92 | [] | no_license | AIRIA/CreazyBomber | 2338d2ad46218180f822682d680ece3a8e0b46c3 | 68668fb95a9865ef1306e5b0d24fd959531eb7ad | refs/heads/master | 2021-01-10T19:58:49.272075 | 2014-07-15T09:55:00 | 2014-07-15T09:55:00 | 19,776,025 | 0 | 2 | null | null | null | null | UTF-8 | Scilab | false | false | 1,155 | sce | map1112.sce | <?xml version="1.0" encoding="UTF-8"?>
<Project Name="map1112" Width="13" Height="9" CellSize="40" BackgroundSize="1" Background="9plus.png">
<Cell Name="木箱" X="2" Y="1" />
<Cell Name="木箱" X="3" Y="1" />
<Cell Name="木箱" X="5" Y="1" />
<Cell Name="木箱" X="6" Y="1" />
<Cell Name="木箱" X="8" Y="1" />
<Cell Name="木箱" X="9" Y="1" />
<Cell Name="出生点" X="1" Y="2" />
<Cell Name="樱桃树" X="4" Y="2" />
<Cell Name="木箱" X="6" Y="2" />
<Cell Name="樱桃树" X="10" Y="2" />
<Cell Name="木箱" X="3" Y="3" />
<Cell Name="丛林图腾2" X="4" Y="3" />
<Cell Name="丛林图腾2" X="10" Y="3" />
<Cell Name="木箱" X="1" Y="4" />
<Cell Name="樱桃树" X="1" Y="5" />
<Cell Name="木箱" X="3" Y="5" />
<Cell Name="丛林图腾2" X="5" Y="5" />
<Cell Name="木箱" X="7" Y="5" />
<Cell Name="丛林图腾1" X="10" Y="5" />
<Cell Name="丛林图腾2" X="2" Y="6" />
<Cell Name="木箱" X="2" Y="7" />
<Cell Name="木箱" X="6" Y="7" />
<Cell Name="通关点-1" X="7" Y="7" />
<Cell Name="猿人" X="9" Y="7" arg0="7" />
<Cell Name="蘑菇怪" X="9" Y="7" arg0="1" />
</Project> |
1d846cc4152b8be2b064e526691ebe2055839808 | 449d555969bfd7befe906877abab098c6e63a0e8 | /615/CH3/EX3.8/3_8.sce | 74f39269da87621d73cd144d2e587645c9a236cf | [] | 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 | 881 | sce | 3_8.sce | //chemical kinetics and catalysis//
//example 3.8//
t1=5;
t2=15;
t3=25;
t4=45;
a=37;//volume of KMnO4 in cm^3 at t=0 or value of a//
a1=29.8;//volume of KMnO4 in cm^3 or a-x value at t=5min//
a2=19.6;//volume of KMnO4 in cm^3 or a-x value at t=15min//
a3=12.3;//volume of KMnO4 in cm^3 or a-x value at t=25min//
a4=5;//volume of KMnO4 in cm^3 or a-x value at t=45min//
k1=(2.303/t1)*log10(a/a1);
printf("\nRate constant value at t=5min is %f/min",k1);
k2=(2.303/t2)*log10(a/a2);
printf("\nRate constant value at t=15min is %f/min",k2);
k3=(2.303/t3)*log10(a/a3);
printf("\nRate constant value at t=25min is %f/min",k3);
k4=(2.303/t4)*log10(a/a4);
printf("\nRate constant value at t=45min is %f/min",k4);
printf("\nAs the different values of k are nearly same,the reaction is of first oredr.");
k=(k1+k2+k3+k4)/4;
printf("\nThe average value of k is %f/min",k); |
5498636baf45bd6475711e02e2c61348380e21c2 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2672/CH6/EX6.10/Ex6_10.sce | f1cc77e0d03fc43554a1b750e9ccfbaa2a1163ba | [] | 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 | 263 | sce | Ex6_10.sce | //Example 6_10
clc;
clear;
close;
format('v',4);
Rm=20;//ohm(meter resistance)
Rs=5;//kohm(series resistance)
Im=1;///mA
Idc=2*Im/%pi;//mA
RL=Rm+Rs*1000;//ohm
Vm=Idc/1000*%pi*RL/2;///V
v0_max=2*sqrt(2)*Vm;//V
disp(v0_max,"Full scale reading(V) : ");
|
dccd200536fb26862c8778c6d4cae9b17093853c | 449d555969bfd7befe906877abab098c6e63a0e8 | /2609/CH1/EX1.9/ex_1_9.sce | 844ee3fb4e623526c50284928f6ad3f558dcc332 | [] | 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 | 489 | sce | ex_1_9.sce | //Ex 1.9
clc;
clear;
close;
format('v',5);
Beta=100;//unitless
VBE=0.715;//V
R=5.6;//kohm
RC=1;//kohm
VCC=10;//V
VCB1=0;//V(Q1 will act as diode)
IREF=(VCC-VBE)/R;//mA
//KCL at node x : IREF=IC1+2*IB;
//KCL at node y : I1=IC2+IB3;//as Beta>>1
IREF=(VCC-VBE)/R;//mA
//as IREF=2*IC1/Beta+IC1
IC1=IREF/(1+2/Beta);//mA
IC2=IC1;//mA
IC3=IC1;//mA
disp(IC1,"Collector current in each transistor, IC1=IC2=IC3 in mA");
IRC=IC1+IC2+IC3;//mA
disp(IRC,"Current through RC(mA)");
|
1ded16953124dcce53844118c282feed9e642189 | 449d555969bfd7befe906877abab098c6e63a0e8 | /3720/CH14/EX14.5/Ex14_5.sce | 9656c27106744b0bd6a51c91b103b52edf4a0e83 | [] | 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 | 508 | sce | Ex14_5.sce | //Example 14-5
clc;clear;
// Properties
rho_a=1.20;// kg/m^3
rho_w=998;// kg/m^3
n=1750;
alpha_1=0;
alpha_2=40;
r_1=0.04;// m
r_2=0.08;// m
b_1=0.052;// m
b_2=0.023;// m
v=0.13;// m^3/s
g=9.81// m/s^2
// Calculation
V_1n=(v/(2*%pi*r_1*b_1));
V_1t=0;//since alpha_1=0
V_2n=(v/(2*%pi*r_2*b_2));
V_2t=V_2n*tand(40);
omega=(2*%pi*n)/60;
H=((omega/g)*((r_2*V_2t)-(r_1*V_1t)));
H_wc=H*(rho_a/rho_w)*1000;// mm
bhp=(rho_a*g*v*H);
printf('The required brake horsepower,bhp=%0.1f W\n',bhp);
|
26879ab820136227fbc07c6f8b2ab9ebc431abf8 | 449d555969bfd7befe906877abab098c6e63a0e8 | /845/CH2/EX2.6/Ex2_6.sce | e6b8f27e36cf96c6b3bec7a3ed9a5bafc5bc271c | [] | 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 | 394 | sce | Ex2_6.sce | //Example 2.6
clc
clear
function f = fun6(x)
f = 1./ sqrt(x+1);
endfunction
tol = 1e-4;
maxit = 6;
xold = 1;
iter = 1;
while(1)
xnew = fun6(xold);
EA = abs(xnew - xold);
if EA < tol | iter > maxit then
break
end
xold = xnew;
iter = iter + 1;
end
root = round(xnew*10^4) / 10^4; //rounded to 4 decimal places
disp(root,"root = ")
|
4f1dd76d9778387c4abf6509eec1922a1bbdb69b | 936c3b35ba232dc3649cc1c6275365a215b2b00d | /simulation_par_discretisation.sce | f3af4c5973964e4616240cf4cc7a64850fb9677e | [] | no_license | Pierre-Edouard/Projet-modal-sna | 7adb267a560af6286807a0a4330f83898a9fc11c | e73a5361f4b081c7c5c019fc48fcab91206db0c3 | refs/heads/master | 2016-09-05T18:30:16.523787 | 2013-05-17T14:15:08 | 2013-05-17T14:15:08 | null | 0 | 0 | null | null | null | null | ISO-8859-1 | Scilab | false | false | 1,604 | sce | simulation_par_discretisation.sce | //------------------------------------------------------------------------------
// Simule le système avec discrétisation en temps
//------------------------------------------------------------------------------
//------------------------------------------------------------------------------
// Simule une trajectoire de l'état du système à l'aide d'une discrétisation en
// temps. (PREMIERE VERSION --> n'utilise pas de loi géométrique)
//------------------------------------------------------------------------------
//
// lambda : (reel) Parametre de la loi d'arrivee des paquets
// mu : (reel) Parametre de la loi d'envoi des paquets.
// tmax : (reel) Temps jusqu'auquel on désire simuler le système.
// h : (reel) Pas de la discrétisation en temps.
// nbSimulations : (entier) Le nombre de simulations à effectuer
//
// T : (vecteur ligne) Discrétisation du temps entre 0 et tmax avec un pas h.
// X: (matrice) Valeur de l'encombrement aux instants donnés par t. Chaque ligne
// correspond à une simulations.
//
function [T,X]=trajectoireDiscrete(lambda, mu, tmax, h, nbSimulations)
imax = ceil(tmax/h)
X = zeros(nbSimulations, 1)
i = 1
IncrA = 1*(grand(nbSimulations, imax+1, 'def')<=(lambda*h))
IncrD = (-1)*(grand(nbSimulations, imax+1, 'def')<=(mu*h))
while i<=imax
X = [X, X(:,$) + IncrA(:,i).*(X(:,$)==0) + (IncrD(:,i) + IncrA(:,i)).*(X(:,$)>0)]
i = i+1
end
T = linspace(0, imax*h, imax+1)
endfunction
[t,X] = trajectoireDiscrete(0.4,0.5,10000,1, 1)
disp(size(t))
disp(size(X))
plot2d(t,X, style=[color('red')])
|
052c67f2d93a80de7266ea35b11abe3c4ebcc845 | 449d555969bfd7befe906877abab098c6e63a0e8 | /545/CH4/EX4.16/ch_4_eg_16.sce | 09a6a26d37381a92ebbd2d832bcc29754f9f7ec9 | [] | 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 | 1,185 | sce | ch_4_eg_16.sce | clc
//given rxn A-->B-->C
rc_k1=1, rc_k2=1 //given rate constants
u=1 //mean axial velocity
disp("the solution of eg 4.16 -->Plug Flow Reactor")
function dA_by_dx=f1e(x,A,B,C),
dA_by_dx=-A,
endfunction
function dB_by_dx=f2e(x,A,B,C),
dB_by_dx=A-B,
endfunction
function dC_by_dx=f3e(x,A,B,C),
dC_by_dx=B,
endfunction
A=1,B=0,C=0
for x=.1:.1:10,
h=.1 //step increment of 0.1
k1=h*f1e(x,A,B,C)
l1=h*f2e(x,A,B,C)
m1=h*f3e(x,A,B,C)
k2=h*f1e(x+h/2,A+k1/2,B+l1/2,C+m1/2)
l2=h*f2e(x+h/2,A+k1/2,B+l1/2,C+m1/2)
m2=h*f3e(x+h/2,A+k1/2,B+l1/2,C+m1/2)
k3=h*f1e(x+h/2,A+k2/2,B+l2/2,C+m2/2)
l3=h*f2e(x+h/2,A+k2/2,B+l2/2,C+m2/2)
m3=h*f3e(x+h/2,A+k2/2,B+l2/2,C+m2/2)
k4=h*f1e(x+h,A+k3,B+l3,C+m3)
l4=h*f2e(x+h,A+k3,B+l3,C+m3)
m4=h*f3e(x+h,A+k3,B+l3,C+m3)
A=A+(k1+2*k2+2*k3+k4)/6
B=B+(l1+2*l2+2*l3+l4)/6
C=C+(m1+2*m2+2*m3+m4)/6
if x==.5 |x==1|x==2|x==5 then disp(C,B,A,"mtr is",x,"the conc. of A,B,C at a distance of");
end
end
disp(C,B,A,"the conc. of A,B,C at a distance of 10 mtr is"); |
b1081654bec1e3797910d38f0080918196229d1f | 449d555969bfd7befe906877abab098c6e63a0e8 | /1301/CH3/EX3.10/ex3_10.sce | cad2a45de387f505b8d9b829b67232c19967e3a6 | [] | 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 | 293 | sce | ex3_10.sce | clc;
m=1500; //mass in kg
F=3000; //force in Newton
t=5; //time in sec
a=F/m; //calculating acc. (Newton's Law)
disp(a,"Accelaration in m/sec square = "); //displaying result
v=a*t; //kinematical equation
disp(v,"Velocity in m/sec = "); //displaying result |
3c3ec65de4be2322ac78405b0a36a20c2918e541 | f542bc49c4d04b47d19c88e7c89d5db60922e34e | /PresentationFiles_Subjects - Kopie/CONT/JH56CNU/ATWM1_Working_Memory_MRI_Nonsalient_Uncued_Run1.sce | cb5a9519d2b58f7861b8c6e9d588a7b63c78b4da | [] | 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 | 12,282 | sce | ATWM1_Working_Memory_MRI_Nonsalient_Uncued_Run1.sce | # ATWM1 MRI Experiment
scenario = "ATWM1_Working_Memory_MRI_nonsalient_uncued_run1";
scenario_type = fMRI; # Fuer Scanner
#scenario_type = fMRI_emulation; # Zum Testen
#scenario_type = trials;
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;
# 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 = 9400;
mri_pulse = 1;
code = "BaselinePre";
#port_code = 1;
};
TEMPLATE "ATWM1_Working_Memory_MRI.tem" {
trigger_volume_encoding trigger_volume_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;
6 12 292 292 399 125 11543 2992 14342 fixation_cross gabor_140 gabor_124 gabor_180 gabor_065 gabor_140_alt gabor_124_alt gabor_180 gabor_065 "1_1_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_300_300_399_11601_3000_14400_gabor_patch_orientation_140_124_180_065_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_065_framed blank blank blank blank fixation_cross_white "1_1_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_065_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
21 27 292 292 399 125 11543 2992 14342 fixation_cross gabor_173 gabor_156 gabor_084 gabor_022 gabor_173 gabor_156_alt gabor_084 gabor_022_alt "1_2_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_300_300_399_11601_3000_14400_gabor_patch_orientation_173_156_084_022_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_131_framed gabor_circ blank blank blank blank fixation_cross_white "1_2_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_131_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
36 41 292 292 399 125 9543 2992 12342 fixation_cross gabor_138 gabor_082 gabor_067 gabor_154 gabor_138 gabor_082_alt gabor_067 gabor_154_alt "1_3_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_300_300_399_9601_3000_12400_gabor_patch_orientation_138_082_067_154_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_021_framed gabor_circ blank blank blank blank fixation_cross_white "1_3_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_021_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
49 54 292 292 399 125 9543 2992 14342 fixation_cross gabor_064 gabor_122 gabor_144 gabor_180 gabor_064_alt gabor_122_alt gabor_144 gabor_180 "1_4_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_300_300_399_9601_3000_14400_gabor_patch_orientation_064_122_144_180_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_144_framed gabor_circ blank blank blank blank fixation_cross_white "1_4_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_144_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
63 68 292 292 399 125 9543 2992 12342 fixation_cross gabor_084 gabor_005 gabor_052 gabor_067 gabor_084_alt gabor_005 gabor_052 gabor_067_alt "1_5_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_300_300_399_9601_3000_12400_gabor_patch_orientation_084_005_052_067_target_position_2_3_retrieval_position_2" gabor_circ gabor_005_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_5_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_005_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
76 81 292 292 399 125 9543 2992 12342 fixation_cross gabor_055 gabor_019 gabor_161 gabor_145 gabor_055_alt gabor_019 gabor_161 gabor_145_alt "1_6_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_UncuedRetriev_300_300_399_9601_3000_12400_gabor_patch_orientation_055_019_161_145_target_position_2_3_retrieval_position_1" gabor_055_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_6_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_055_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
89 94 292 292 399 125 9543 2992 12342 fixation_cross gabor_068 gabor_178 gabor_141 gabor_007 gabor_068_alt gabor_178 gabor_141_alt gabor_007 "1_7_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_300_300_399_9601_3000_12400_gabor_patch_orientation_068_178_141_007_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_052_framed blank blank blank blank fixation_cross_white "1_7_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_052_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
102 108 292 292 399 125 11543 2992 14342 fixation_cross gabor_151 gabor_039 gabor_064 gabor_012 gabor_151_alt gabor_039_alt gabor_064 gabor_012 "1_8_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_UncuedRetriev_300_300_399_11601_3000_14400_gabor_patch_orientation_151_039_064_012_target_position_3_4_retrieval_position_1" gabor_151_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_8_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_151_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
117 122 292 292 399 125 9543 2992 14342 fixation_cross gabor_130 gabor_113 gabor_004 gabor_056 gabor_130_alt gabor_113 gabor_004 gabor_056_alt "1_9_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_300_300_399_9601_3000_14400_gabor_patch_orientation_130_113_004_056_target_position_2_3_retrieval_position_2" gabor_circ gabor_162_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_9_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_162_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
131 137 292 292 399 125 11543 2992 14342 fixation_cross gabor_163 gabor_135 gabor_090 gabor_111 gabor_163_alt gabor_135 gabor_090 gabor_111_alt "1_10_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_300_300_399_11601_3000_14400_gabor_patch_orientation_163_135_090_111_target_position_2_3_retrieval_position_2" gabor_circ gabor_135_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_10_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_135_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
146 152 292 292 399 125 11543 2992 12342 fixation_cross gabor_149 gabor_177 gabor_026 gabor_042 gabor_149_alt gabor_177 gabor_026_alt gabor_042 "1_11_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_300_300_399_11601_3000_12400_gabor_patch_orientation_149_177_026_042_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_042_framed blank blank blank blank fixation_cross_white "1_11_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_042_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
160 166 292 292 399 125 11543 2992 14342 fixation_cross gabor_078 gabor_031 gabor_162 gabor_002 gabor_078 gabor_031_alt gabor_162_alt gabor_002 "1_12_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_UncuedRetriev_300_300_399_11601_3000_14400_gabor_patch_orientation_078_031_162_002_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_115_framed gabor_circ blank blank blank blank fixation_cross_white "1_12_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_115_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
175 180 292 292 399 125 9543 2992 12342 fixation_cross gabor_005 gabor_027 gabor_142 gabor_074 gabor_005 gabor_027_alt gabor_142 gabor_074_alt "1_13_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_300_300_399_9601_3000_12400_gabor_patch_orientation_005_027_142_074_target_position_1_3_retrieval_position_1" gabor_053_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_13_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_053_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
188 194 292 292 399 125 11543 2992 14342 fixation_cross gabor_112 gabor_172 gabor_049 gabor_026 gabor_112 gabor_172_alt gabor_049 gabor_026_alt "1_14_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_300_300_399_11601_3000_14400_gabor_patch_orientation_112_172_049_026_target_position_1_3_retrieval_position_1" gabor_112_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_14_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_112_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96;
203 208 292 292 399 125 9543 2992 12342 fixation_cross gabor_022 gabor_140 gabor_103 gabor_067 gabor_022 gabor_140_alt gabor_103_alt gabor_067 "1_15_Encoding_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_300_300_399_9601_3000_12400_gabor_patch_orientation_022_140_103_067_target_position_1_4_retrieval_position_1" gabor_157_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_15_Retrieval_Working_Memory_MRI_P6_LR_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_157_retrieval_position_1" 2 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 = 20600;
code = "BaselinePost";
#port_code = 2;
}; |
d865bc6c1a23691c8ea3d7da491f748bb0976878 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1397/CH6/EX6.1/6_1.sce | 98afebd3f4fc5ea9312cd58d645901415fb25d2c | [] | 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 | 314 | sce | 6_1.sce | //clc();
clear;
//To determine density
n=8; //number of atoms per unit cell
a=5.6*10^-10; //lattice constant in m
M=710.59; //atomic weight of Germanium in a.m.u
N=6.02*10^26; //avagadro number in kg/mol
rho=(n*M)/(N*a^3);
printf("density in kg/m^3 is ");
disp(rho);
|
7e0e399edc687570c7605647d23bd2c1d1baf42f | 449d555969bfd7befe906877abab098c6e63a0e8 | /3754/CH10/EX10.9/10_9.sce | c1a5e764894c31cc054ccba53d4847f38344dc8c | [] | 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 | 494 | sce | 10_9.sce | clear//
//Variables
p = 100.0 //resistivity (in ohm-meter)
q = 1.6 * 10**-19 //Charge on a electron (in Coulomb)
un = 0.36 //donor concentration (in per cubic-meter)
//Calculation
sig = 1/p //conductivity (in siemen per meter)
n = sig /(q * un) //intrinsic concentration (in per cubic-meter)
ND = n //Donor concentration (in per cubic-meter)
//Result
printf("\n Donor concentration is %0.3f m**-3.",ND)
|
85c99f3630be08956882fda7d314682b42a0ace8 | 4545588c8427debaf17f9dc71b0ace32f4fb5d67 | /avr32/services/dsp/dsplib/conception/operators/fixed_point_sqrt.sci | 76f0fa6da53b377489653a637b1e2e04f6a6127a | [] | no_license | eewiki/asf | 02e06cec0465b28dd689dea801e6be6cbcd47eca | 8d0f55bd089f2e68d2b53aa76adbb02c07cdb166 | refs/heads/master | 2021-01-16T18:20:22.690176 | 2015-03-09T05:42:50 | 2015-03-09T05:42:50 | 18,419,213 | 34 | 30 | null | 2014-12-25T05:13:20 | 2014-04-03T21:42:46 | C | UTF-8 | Scilab | false | false | 1,827 | sci | fixed_point_sqrt.sci | // Fixed point 16-bit cosine and sine
clear
// Emulate the clz instruction for avr32uc3
function res=clz(x)
res = 0;
while x != 0,
x = floor(x/2);
res = res + 1;
end;
res = 32 - res;
endfunction
// Reciproot Iteration
function res=fp_sqrt(a, b, y)
if (y < 0) then,
res = -1
return
end;
// Find an approximation of 1/sqrt(x);
// Value between 0 && 16
under_bit_val = floor((32-clz(y))/2);
x = 2^(-under_bit_val);
//printf("Approx: %f (%f^2 -> %f)\t", sqrt(1/(y+0.00000001)), 1/(x+0.00000001), x*x);
z = y/2;
x = x*(1.5 - z*x*x);
x = x*(1.5 - z*x*x);
x = x*(1.5 - z*x*x);
x = x*(1.5 - z*x*x);
error_corr = 1;
if (modulo(b, 2) == 1) then,
error_corr = 1/sqrt(2);
end;
res = (x*y)*2^(-floor(b/2))*error_corr;
endfunction
// Reciproot Iteration
function res=fix_sqrt(a, b, y)
if (y < 0) then,
res = -1
return
end;
// Find an approximation of 1/sqrt(x);
// Value between 0 && 16
//under_bit_val = b-floor((32-clz(y))/2);
under_bit_val = (b-16)+floor(clz(y)/2);
// fixed point version of x
x = 2^(under_bit_val);
a = x*x;
a = floor(y*a/(2^(b+1)));
x = floor(x*(1.5*2^b - a)/2^b);
printf("[%i]\n", x);
error_corr = 1;
if (modulo(b, 2) == 1) then,
error_corr = 1/sqrt(2);
end;
res = y*error_corr;
res = floor((x*res)/2^b);
res = res*2^(-floor(b/2));
endfunction
function res=DSP_Q(a, b, x)
res = floor(x*2^b);
endfunction
QA = 1;
QB = 15;
e = 0;
for nbr=0:0.1:1,
e = e + abs(sqrt(nbr) - fp_sqrt(QA, QB, DSP_Q(QA, QB, nbr)));
printf("%f\t%.11f %.11f *%.11f\n", nbr, sqrt(nbr), fp_sqrt(QA, QB, DSP_Q(QA, QB, nbr)), fix_sqrt(QA, QB, DSP_Q(QA, QB, nbr)));
end;
fix_sqrt(QA, QB, DSP_Q(QA, QB, 0.636))
|
9773b90af6a967bad1043760e93b7c78b8e7e9a1 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1931/CH10/EX10.10/10.sce | af53d1aafcaaafc9030bfcb715dfe40916206078 | [] | 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 | 10.sce | clc
clear
//INPUT DATA
Eg=0.72*1.6*10^-19//The band gap of Ge in J
T1=293//Temperature in K
T2=313//Temperature in K
x1=2//The conductivity of Ge at T1 in ohm^-1 m^-1
e=1.6*10^-19//charge of electron in coulombs
kb=1.38*10^-23//Boltzmann's constant m^2 Kg s^-2 k^-1
//CALCULATION
x2=x1*(exp((Eg/(2*kb))*((1/T1)-(1/T2))))//The ratio of conductiveness
//OUTPUT
printf('The conductivity of Ge at T2 is %3.4f ohm^-1 m^-1',x2)
|
4521ec4da0b29da8ccbc7eeacc5e05a0febae6ae | 449d555969bfd7befe906877abab098c6e63a0e8 | /1370/CH3/EX3.6/example3_6.sce | b6895f7053841057e9b5ce69fc2325c036e80dfe | [] | 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 | 573 | sce | example3_6.sce | //example3.6
clc
disp("R1=1 ohm, R2=2 ohm, X1=3 ohm, X2=5 ohm")
k=110/220
disp(k,"K=V2/V1=")
r=1+(2/((0.5)^2))
disp(r,"Therefore, (R_1e)[in ohm]=R1+R2''=R1+(R2/K^2)=")
x=3+(5/((0.5)^2))
disp(x,"Therefore, (X_1e)[in ohm]=X1+X2=X1+(X2/K^2)=")
z=sqrt((9^2)+(23^2))
format(8)
disp(z,"Therefore, (Z_1e)[in ohm]=sqrt((R_1e^2)+(X_1e^2))=")
r=9*(0.5^2)
disp(r,"Therefore, (R_2e)[in ohm]=(K^2)*(R_1e)=")
x=(0.5^2)*23
disp(x,"and, (X_2e)[in ohm]=(K^2)*(X_1e)=")
z=(0.5^2)*24.6981
format(7)
disp(z,"Therefore, (Z_2e)[in ohm]=sqrt((R_2e^2)+(X_2e^2))=(K^2)*(Z_1e)=")
|
82fe973a616a792aab20af31e8e62941bff87db1 | 449d555969bfd7befe906877abab098c6e63a0e8 | /3835/CH8/EX8.2/Ex8_2.sce | 1938b2f5d828e4923265a6746128e0575b40a19f | [] | 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 | Ex8_2.sce | clear
//
//given
pg=10 //poles of generator
r=720 //synchronous speed
f=pg*r/120
printf("\n frequency= %0.0f Hz",f)
//it has been shown that synchronous motor runs at a speed lower than the synchronous speed.The nearest synchronous speed possible in present case is 1200
//case a
r=1200 //synchronous speed possible for present case
pi=120*f/r //poles of the induction motor
printf("\n The number of poles of an induction motor is= %0.1f",pi )
//case b
n=1170 //load speed
slip=(1200-n)/1200 //calculated as 0.025
printf("\n slip=0.025pu")
|
2ea16afd507b3db592691aefea00c4151ab3c269 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2705/CH12/EX12.3/Ex12_3.sce | 37084b47a8702525283ef633fe9d186b8845a315 | [] | 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 | 1,387 | sce | Ex12_3.sce | clear;
clc;
disp('Example 12.3');
// aim : To determine the
// (a) throat and exit areas
// (b) degree of undercooling at exit
// Given values
P1 = 2;// inlet pressure of air, [MN/m^2]
T1 = 273+325;// inlet temperature of air, [MN/m^2]
P2 = .36;// exit pressure, [MN/m^2]
m_dot = 7.5;// flow rate of air, [kg/s]
n = 1.3;// polytropic index
// solution
// (a)
// using steam table
v1 = .132;// [m^3/kg]
// given expansion following law PV^n=constant
Pt = P1*(2/(n+1))^(n/(n-1));// critical pressure, [MN/m^2]
//velocity at throat is
Ct = sqrt(2*n/(n-1)*P1*10^6*v1*(1-(Pt/P1)^(((n-1)/n))));// [m/s]
vt = v1*(P1/Pt)^(1/n);// [m^3/kg]
// using m_dot/At=Ct/vt
At = m_dot*vt/Ct*10^6;// throat area, [mm^2]
mprintf('\n (a) The throat area is = %f mm^2\n',At);
// at exit
C2 = sqrt(2*n/(n-1)*P1*10^6*v1*(1-(P2/P1)^(((n-1)/n))));// [m/s]
v2 = v1*(P1/P2)^(1/n);// [m^3/kg]
A2 = m_dot*v2/C2*10^6;// exit area, [mm^2]
mprintf('\n The exit area is = %f mm^2\n',A2);
// (b)
T2 = T1*(P2/P1)^((n-1)/n);//outlet temperature, [K]
t2 = T2-273;//[C]
// at exit pressure saturation temperature is
ts = 139.9;// saturation temperature,[C]
Doc = ts-t2;// Degree of undercooling,[C]
mprintf('\n (b) The Degree of undercooling at exit is = %f C\n',Doc);
// There is some calculation mistake in the book so answer is not matching
// End
|
252f1fe1415668eabe1652863e76a5872b40b74b | 449d555969bfd7befe906877abab098c6e63a0e8 | /1199/CH2/EX2.37/2_37.sci | e5a49262533894055cb493c192853e356e24e55d | [] | 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 | 337 | sci | 2_37.sci | // 2.37
clc;
displacement=0.5;
Vo=2*10^-3;
Se_LVDT=Vo/displacement;
printf("senstivity of the LVDT=%.3f V/mm",Se_LVDT)
Af=250;
Se_instrument=Se_LVDT*Af;
printf("\nSenstivity of the instrument=%.1f V/mm",Se_instrument)
sd=5/100;
Vo_min=50/5;
Re_instrument=1*1/1000;
printf("\nresolution of instrument=%.3f mm",Re_instrument)
|
035fe519fadcf78bc4f5ebfddc4df79109ce3217 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1301/CH8/EX8.10/ex8_10.sce | 061e82272e38d29f1634c7d704fd7a315e432d25 | [] | 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 | 399 | sce | ex8_10.sce | clc;
g=9.8; //gravitational constant in m/sec square
d=1.03*10^3; //density of sea water in kg/m cube
depth=50; //depth in m
side=20; //length of side in cm
p=d*depth*g; //calculating pressure on window
A=side*side*10^-4; //calculating area in metre square
F=p*A; //calculating FOrce in Newton
disp(F,"Force acting on window in Newton = "); //displaying result. |
35258d23ce759f9a607e3828dd4141716caff92f | 449d555969bfd7befe906877abab098c6e63a0e8 | /2276/CH3/EX3.19/chapter3_ex19.sce | f166dbf560a465f52ce424a9350c2ed1e62a20c2 | [] | 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 | 647 | sce | chapter3_ex19.sce | clc
clear
//input
v1=240;//voltage of a d.c. shunt motor in volts
ra=1;//armature current in ohms of a d.c. shunt motor
rf=240;//field current in ohms of a d.c. shunt motor
ifl=20;//full load current in amperes
w=200;//speed in rad/s
v2=200;//reduced voltage in volts
//calculations
//flux/pole is assumed to be proportional to the field current
//for a 240V supply
E1=v1-(ifl*ra);//induced e.m.f. in volts
i=ifl*(v1/v2);//new current in amperes
E2=v2-(i*ra);//induced e.m.f. for new current in volts
W=w*(E2/E1)*(i/ifl);//new speed in rad/s
//output
mprintf('with the reduced voltage the motor will run at %3.0f rad/s',W)
|
b2febafac415024cd530e1ff009162516a311d3e | 449d555969bfd7befe906877abab098c6e63a0e8 | /1694/CH2/EX2.32/EX2_32.sce | 024c5d58f8f3e79db3ab470d16fce6f6be220a22 | [] | 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 | 490 | sce | EX2_32.sce | clear;
clc;
printf("\nEx2.32\n");
//page no.-72
//given
v=5000;..............//speed of e in m/s
m=9*10^-31;......//mass of e
del_v=0.00003;........//change in velocity
h=6.63*10^-34;......//planck's constant
p=m*v;.................//momentum
del_p=p*del_v;..........//change in momentum in kg*m/sec
//By Heisenberg's uncertainty principle,
del_x=h/(2*%pi*del_p)...............//uncertainty in position in m
printf("\nminimum uncertainty in position is 7.82*10^4 m\n");
|
022956ef23a8e3cb33137f1d519f877ef699ee48 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1752/CH5/EX5.5/exa_5_5.sce | 7ecb4f6458f6596678a243e7d1afff6db0429377 | [] | 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 | 933 | sce | exa_5_5.sce | //Exa 5.5
clc;
clear;
close;
//given data
k=.026;// in W/mK
v= 16.8*10^-6;// in m^2/s
miu=2*10^-5;// in kg/ms
Pr=0.708;
V=15;// in m/s
x=2;// in m
A=2*1;// in m^2
Re=V*x/v;
del_t=40-10;// in degree C
// since Re > 3 *10^5, hence turbulent flow at x=2 m length of laminar flow region is x_L then
Re_1=3*10^5;
// Re_1 = 3*10^5 = V*x_L/v
x_L= Re_1*v/V;
// Part (a)
//Nu= h*x_L/k = 0.664*Re_1^(1/2)*Pr^(1/3);
h= 0.664*Re_1^(1/2)*Pr^(1/3)*k/x_L;// in W/m^2
disp(h,"The average heat transfer coefficient over the laminar boundary layer in W/m^2 ");
// Part(b)
//Nu= h*x/k = (0.037*Re^0.8-872)*Pr^(1/3);
h= (0.037*Re^0.8-872)*Pr^(1/3)*k/x;// in W/m^2
disp(h,"The average heat transfer coefficient over entire plate in W/m^2 ");
// Part (c)
q=h*A*del_t;
disp(q,"Total heat transfer rate in watt");
// Note: Calculation of the part(a) in this book is wrong, so answer of the part(a) in the book is wrong
|
d2911711ef835c0f5026e0e9a428cb9ace40270e | 389bd4af3bf5a0f54f51e8aafea5035f568ba445 | /soru2_2510.sce | ac75596d4a4a2fcf31b4aa56af0c556ed14b860f | [] | no_license | esraatlici/Bilgisayar-Destekli-Matematik | d47f057d9cb7ee987e367c67f8923cfcf02342d8 | dae1079f60fc7e0d3b54802b4cbed9182b52fcd7 | refs/heads/main | 2022-12-25T11:14:25.575530 | 2020-10-05T15:09:58 | 2020-10-05T15:09:58 | 301,447,895 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 187 | sce | soru2_2510.sce | function g=f(x)
k=1;
for x=0:0.5:10
t=x^2+exp(-2*x);
if(t>0)
r(k)=t;
end
k=k+1;
end
g=(r);
endfunction
|
0a891ec5cfd827c53944bc0b21efd1dec318df02 | 449d555969bfd7befe906877abab098c6e63a0e8 | /443/DEPENDENCIES/20_3_data.sci | c77339d8be3032e7655405428e0874031df6b42e | [] | 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 | 404 | sci | 20_3_data.sci | //CO2+CO
CO2=7.5
CO=0
//N
N=83.5
//Fuel flow (in kg/h)
ff=15
//Compression ratio
cr=16
//Diameter(in cm)
d=25*(10^(-2))
//Length (in cm)
l=30*(10^(-2))
//Ambient temperature ( in kelvin )
t=308
//Universal gas constant
r=287
//Exhaust pressure ( in bars )
ep=1.05*(10^(5))
//Calorofic value ( in KJ )
CV=42200
//Speed (in rpm)
s=400
//Indicated thermal efficiency (nith)
nith=0.4 |
8b80871556ad0ec6bd34f19ce81034baa468e877 | 9d545f988a80789144df937ce4a90017c378cb92 | /pract.sce | de7a7d62bf82d07c9b006b142876369521d302e5 | [] | no_license | tshrjn/EE304P | 215dc669daaf372242afe2c1f580a36df26e51ce | ac1c045262dd0b419354d2d22861c734508b7b8e | refs/heads/master | 2021-01-10T03:02:18.270276 | 2015-12-01T02:42:16 | 2015-12-01T02:42:16 | 46,113,211 | 1 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 2,096 | sce | pract.sce | // Functions are defined initially, start reading from THE Main !
function [levelNos,xq] = uniform_quantize ( x , b ,mx,mn)
//Returns time-domain Quant. levels in decimal format & quatised values
// Levels
l = 2^b;
// StepSize or delta or region width
s = (mx - mn) / l;
// Quantization levels
ql = [mn: s :mx ] ;
qv = [mn - (s/2): s : mx + (s/2)]
// Decision Levels
// dl =[mn+( s /2 ) : s :mx];
disp(ql);
disp(qv);
index = 1;
xq = [] ;
levelNos = [];
while index <= length(x)
count =2;
while count <= length(ql)
if x(index) < ql(1) then
levelNos(1,index) = 1
xq(1,index) = qv(1)
elseif x(index) > ql(count)
count = count +1;
continue
else
xq(1,index) = qv(count );
levelNos(1,index) = count ;
//if x(index) <= dl(count − 1)
// xq(1, index) = ql(count −1);
//else
// xq(1 ,index ) = ql(count);
//end
end
break;
end
// disp(x(index));
// disp(xq(1,index));
// disp(levelNos(1,index));
index = index +1;
end
endfunction
//n=100;
//a=zeros(n+1,1);
//******************** MAIN STARTS HERE *************************************************?
// Input function
fs = 100;
fm = 5;
time = [0:1/fs:2/fm];
input = sin(2*%pi*fm*time)
//plot(input)
// End of input function
n = 4;
// Setting Boundaries
//a = zeros(n+1); // Array of Boundaries
//a(1) = -150
//a(n+1) = 150
//a(floor(n/2)) = 0
//
//******************************************************************* PCM Begins ***************************/
maxBoundary = 150;
minBoundary = -150;
input = maxBoundary*input;
//plot(input)
xq = zeros(length(input));
[levelNos,xq] = uniform_quantize(input,2,maxBoundary,minBoundary);
txSignal = dec2bin(levelNos);
//plot(xq);
//disp(levelNos);
//plot(txSignal);
//plot(txSignal);
//**Channel Modellin here if required*****
//****************************************
// Error checking
sm = 0
for i = 1:length(xq)
sm = sm + (input(i) - xq(i))^2;
disp(xq(i) - input(i))
end
sm = sm/ length(xq);
//disp(sm,length(xq),length(input))
disp(sm)
|
0ed0bb3c99936fb6ce3a86bc30ad4e9206225593 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1475/CH1/EX1.22/Example_1_22.sce | 31799cf7b6efc27e5bc2e270be880f210377f900 | [] | 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 | 476 | sce | Example_1_22.sce | //Example 1.22 10 distinguishable ball are distributed at random into 4 boxes.
clc;
clear;
N=(4^10);
disp(N,"total no. of ways in which 4 boxes are selected to distribute 10 balls =");
M= (factorial(10)/(factorial(2)*factorial(8)))*(3^8);
// M= 10C2 * 3^8
disp(M,"No. of favourable cases when a specified box recieve 2 balls out of 10, and remaining 8 balls are distributed are ");
P=M/N;
disp(,P,"Probability that a specified box recieves exactly 2 balls = ");
|
15d767a8006064acb2c583ade604baa6025ddf9f | d56141249002a5da7c4a2641dbdfc609809046a8 | /octopus/td_charge_flow2.sce | a0330dc06c5f35ed2ebd2d21dd371b83d6a85a92 | [] | no_license | kcbhamu/DFTutilities | 14a77226c1229ec61563cc08316d6c32814ddb57 | d6c859407a6b13c8bc5340c08db7a0125d6ed4e6 | refs/heads/master | 2021-06-24T15:23:58.675113 | 2017-08-23T20:56:44 | 2017-08-23T20:56:44 | null | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 5,832 | sce | td_charge_flow2.sce | // This code calculates the following properties of two separate compartment
// 1. total charges
// 2. charge dfferent w/ repsect to a reference time
// 3. ac current flow through a plane
// To use it, you need to download all td.xxxxxxx. You will also need to
// assign plane to separate two compartment.
// Recall that, the meshs in Octopus are [Vx/h,Vy/z,Vz/h].
// Note that: it calculates the "charge" ! Therefore, when it comes to
// current, it should have a reverse sign tot_charge(:,9) which dones't
// include in the code.
// revsed: change x,y,z order, 12/02/2015
clear; clc; xdel(winsid());
// Parameters ==========================================================
work_dir='D:\Work\CO_junction\md_cw1' // upper of td.xxxxxxxx
h_par=0.2 // h parameter used in Octopus
ref_dir='gs' // a number or 'gs'
start_dir=0 // start dir
end_dir=80000//60000 // end dir
dir_int=50 // dir inteveral
time_step=0.002 // time step used in calculation
div_plane=[1,36]; // [axis,plane index], axis=1,2,3;
task='plot' // 'plot' or 'run'
// Predef ==============================================================
// check input variables
if pmodulo(start_dir,dir_int)~=0 | pmodulo(end_dir,dir_int)~=0
disp('Error: mod(ref_dir/start_dir/end_dir, dir_int)~=0');
abort
end
// td folder name function
function name_str=td_name_conv(name_num)
name_str=string(name_num);
name_str='td.'+strcat(repmat('0',1,7-length(name_str)))+name_str;
endfunction
// read reference density ==============================================
if task=='run' then
if ref_dir=='gs'
fid=mopen(work_dir+'/static/density.xsf','r')
else
fid=mopen(work_dir+'/'+td_name_conv(ref_dir)+'/density.xsf','r')
end
desc_lines=0
while grep(mgetl(fid,1),'DATAGRID_3D_function')==[]
desc_lines=desc_lines+1
end
desc_lines=desc_lines+6;
data_grid=mfscanf(1,fid,'%f %f %f')
mgetl(fid,5)
ref_data=mfscanf(prod(data_grid),fid,'%f');
mclose(fid);
// reshape ref_data to [x,y,z] ordering
ref_data=matrix(ref_data,data_grid(1),data_grid(2),data_grid(3));
// total charge of two part of the reference state
ref_charge=zeros(1,2);
select div_plane(1)
case 1
ref_charge(1)=sum(ref_data(1:div_plane(2),:,:))
ref_charge(2)=sum(ref_data(div_plane(2)+1:$,:,:))
case 2
ref_charge(1)=sum(ref_data(:,1:div_plane(2),:))
ref_charge(2)=sum(ref_data(:,div_plane(2)+1:$,:))
case 3
ref_charge(1)=sum(ref_data(:,:,1:div_plane(2)))
ref_charge(2)=sum(ref_data(:,:,div_plane(2)+1:$))
end
// calculate total charge and current flows ============================
tot_run=round((end_dir-start_dir)/dir_int)+1
// tot_charge=[time,tot,tot1,tot2,gs_diff1,gs_diff2,td_diff1,td_diff2,flow]
tot_charge=zeros(tot_run,9)
for n=1:tot_run
tic();
fold_num=start_dir+(n-1)*dir_int;
fid=mopen(work_dir+'/'+td_name_conv(fold_num)+'/density.xsf','r');
file_desc=mgetl(fid,desc_lines)
clear read_data
read_data=mfscanf(prod(data_grid),fid,'%f');
// reshape to [z,y,x] ordering
read_data=matrix(read_data,data_grid(1),data_grid(2),data_grid(3));
// total charge of the whole system
tot_charge(n,1)=(start_dir+(n-1)*dir_int)*0.002 //time
tot_charge(n,2)=sum(read_data); // total charge
// total charge of two parts
select div_plane(1)
case 1 // x
tot_charge(n,3)=sum(read_data(1:div_plane(2),:,:));
tot_charge(n,4)=sum(read_data(div_plane(2)+1:$,:,:));
case 2 // y
tot_charge(n,3)=sum(read_data(:,1:div_plane(2),:));
tot_charge(n,4)=sum(read_data(:,div_plane(2)+1:$,:));
case 3 // z
tot_charge(n,3)=sum(read_data(:,:,1:div_plane(2)));
tot_charge(n,4)=sum(read_data(:,:,div_plane(2)+1:$));
end
// charge difference compare to ref_data of two parts
tot_charge(n,5:6)=tot_charge(n,3:4)-ref_charge
// charge diff comp to last time step
if n > 1 then
tot_charge(n,7:8)=tot_charge(n,3:4)-tot_charge(n-1,3:4)
end
mclose(fid);
disp('running folder #'+string(fold_num)+'...'+string(toc())+' sec')
end
tot_charge(:,2:8)=tot_charge(:,2:8)*h_par^3;
// calculate current (muA)
tot_charge(:,9)=(1.6022*tot_charge(:,8))/(time_step*dir_int*0.658212)*(1e+2);
save(work_dir+'/tot_charge.sod','tot_charge')
elseif task=='plot'
load(work_dir+'/tot_charge.sod');
end
// Plot ================================================================
figure(1)
plot(tot_charge(:,1)*0.658,tot_charge(:,8));
a=gce(); a.children.thickness=2;
plot(tot_charge(:,1)*0.658,zeros(length(tot_charge(:,1)),1),'r:')
a=gce(); a.children.thickness=2;
set(gcf(),'background',8)
set(gca(),'thickness',4)
set(gca(),'font_size',4);
ylabel('charge(e)');
xlabel('time (fs)');
title('charge fluctation')
xsave(work_dir+'/tot_charge_flu.scg', gcf())
figure(2)
plot(tot_charge(:,1)*0.658,tot_charge(:,9));
a=gce(); a.children.thickness=2;
plot(tot_charge(:,1)*0.658,zeros(length(tot_charge(:,1)),1),'r:');
a=gce(); a.children.thickness=2;
set(gcf(),'background',8)
set(gca(),'thickness',4)
set(gca(),'font_size',4);
ylabel('current (mu-A)');
xlabel('time (fs)');
title('AC current')
xsave(work_dir+'/tot_charge_ac.scg', gcf())
figure(3)
plot(tot_charge(:,1)*0.658,tot_charge(:,6));
a=gce(); a.children.thickness=2;
plot(tot_charge(:,1)*0.658,zeros(length(tot_charge(:,1)),1),'r:');
a=gce(); a.children.thickness=2;
set(gcf(),'background',8)
set(gca(),'thickness',4)
set(gca(),'font_size',4);
ylabel('charge (e)');
xlabel('time (fs)');
title('charge accumulation')
xsave(work_dir+'/tot_charge_e.scg', gcf())
|
0053b6efba7f3c39205ebe72c9efff56f5ff18a5 | 449d555969bfd7befe906877abab098c6e63a0e8 | /821/CH7/EX7.22/7_22.sce | cdc80b9d145b3e4e2c0e71c20c8313a6e7d76131 | [] | 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 | 781 | sce | 7_22.sce | CNH3=0.1;//concentration of NH3 solution//
CNH4Cl=0.1;//concentration of NH4Cl solution//
POH=4.74;
PH=14-POH+log10(CNH3/CNH4Cl);
printf('PH of the solution=PH=%f',PH);
printf('\nOn adding 0.01mol of HCl,assuming that no volume change occurs,0.01mol of NH4Cl is produced.\nTherefore,the concentration of NH3 decreases by 0.01 and that of NH4Cl increases by 0.01 ');
C1NH3=0.09;
C1NH4Cl=0.11;
PH1=14-POH+log10(C1NH3/C1NH4Cl);
printf('\nPH of the solution=PH1=%f',PH1);
printf('\nOn adding 0.01mol of NaOH,assuming that no volume change occurs,0.01mol of NH3 is produced.\nTherefore,the concentration of NH3 increases by 0.01 and that of NH4Cl decreases by 0.01 ');
C2NH3=0.11;
C2NH4Cl=0.09;
PH2=14-POH+log10(C2NH3/C2NH4Cl);
printf('\nPH of the solution=PH2=%f',PH2);
|
16db8e97a1ac53e046ddfe2779ae2fb1ca46ddde | 59e7c95649eb8894e1d6f0bcac3ca7ea2b023217 | /Posição do Elemento Vetor.sce | 7fe76a38d5d158ef0f03de92354410e6669aeef5 | [] | no_license | nascimento-luciano/Scilab-Matlab | cb5ee9d97df3ed0f4311573df0fd37a88b3394d8 | 1cba42b68cc7954ff4c7dd6b13c7d8e6bd3d039e | refs/heads/main | 2023-03-19T21:06:18.691193 | 2021-03-18T00:57:29 | 2021-03-18T00:57:29 | 348,877,701 | 1 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 211 | sce | Posição do Elemento Vetor.sce | a = input("Digitar o vetor linha a = ");
n = size(a);
soma = 0;
for i = 1:n(2)
soma = soma+a(i)
end
m = soma/n(2);
for i = 1:n(2)
if a(i)<(m) then
disp(i)
end
end
disp(p);
|
5a0abdd211b493b0b0e1a42afd727318216fa915 | 449d555969bfd7befe906877abab098c6e63a0e8 | /154/DEPENDENCIES/ch7_26.sce | 8b763778c51a7f5e1a027272a73af83a50245709 | [] | 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 | 491 | sce | ch7_26.sce | clc
disp("Example 7.26")
printf("\n")
printf("Given")
disp("Period =10s")
disp("Interval is 1ms")
disp("Voltage of binary signal is either 0.5 or -0.5")
T=10;
//During 10s period there are 10000 intervals of 1ms each
//For calculating average equal number of intervals are considered at 0.5V and -0.5V
vavg=(0.5*5000-0.5*5000)/10000
//The effective value of v(t) is
//Let V=V^2eff
V=(0.5^2*5000+(-0.5)^2*5000)/10000
Veff=sqrt(V)
printf("vavg=%dV\nVeff=%3.2fV\n",vavg,Veff)
|
5608becd43adb54a360cba05290d66305a758d8a | 449d555969bfd7befe906877abab098c6e63a0e8 | /3782/CH2/EX2.1/Ex2_1.sce | 767f9735284cc6866e7fb40bf868996419a143e0 | [] | 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 | 160 | sce | Ex2_1.sce |
//
//
ag=5
giv=0.03
L=20
l=(giv*L/(sin(ag*%pi/180)))
AB=l
BC=AB*(sin(ag*(%pi/180)))
BC=BC/20
printf("\n max length of offset should be %0.3f meters',l)
|
519a52bcfbcc2907ebdfaafb6737dc4715a7fb1e | 8217f7986187902617ad1bf89cb789618a90dd0a | /browsable_source/2.5/Unix-Windows/scilab-2.5/tests/examples/clearglobal.man.tst | f5b0f9983175e03028af39c7753c03d38d370a69 | [
"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 | 84 | tst | clearglobal.man.tst | clear;lines(0);
global a b c
a=1;b=2;c=3;
who('global')
clearglobal b
who('global')
|
76809238a0f9efc19186a694258622f01a326223 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2132/CH4/EX4.11/Example4_11.sce | d23a100efa71c22fb644f7096af708f95ba71e7b | [] | 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 | 309 | sce | Example4_11.sce | //Example 4.11
clc;
clear;
close;
format('v',9);
//Given data :
S1=1.9;//sp. gravity
S2=1.2;//sp. gravity
S3=0.79;//sp. gravity
h2=545/1000;//m
h1=750/1000;//m
h3=h1-h2;//m
w=1000*9.81;//N/m^3
pAB=(h1*S1-h2*S2-h3*S3)*w;//N/m^2
disp(pAB,"Pressure difference between the two vessel in N/m^2: ");
|
6c551a0e17f845464162862417376e14cc1ebe7b | 73f78cdeffea591ff380589c4b1dd03d77d63e0a | /projects/08/test4/test4.tst | f928946733f817e7ffdebc8eb111757a07bec432 | [] | no_license | orensam/nand2tetris | bf7fe02f4580aff3dfa17e76145c0591112a9adb | dff1e1c014d27030037d4afb834cfdbf221c379d | refs/heads/master | 2020-07-21T21:28:27.084153 | 2014-10-28T10:20:09 | 2014-10-28T10:20:09 | 17,370,144 | 1 | 5 | null | null | null | null | UTF-8 | Scilab | false | false | 183 | tst | test4.tst | load test4.asm,
output-file test4.out,
compare-to test4.cmp,
output-list RAM[5000]%D1.6.1 RAM[5001]%D1.6.1 RAM[5010]%D1.6.1 RAM[5011]%D1.6.1;
repeat 1000000 {
ticktock;
}
output;
|
63d44698eef662803227abe9f0c90e189a54457b | b74b2ace796d50f1d2550b2ac8747b0c55e7faa7 | /macros/gitpull.sci | 9758c23c471045a5dda957f8aae57d01195660b6 | [] | no_license | slevin48/plotdeploy | 2f1a5aea6b14b540b7890a86c588e8361e237152 | 2bbba304a9151beb4b01104746ea41f95d73bd78 | refs/heads/master | 2023-02-14T22:09:40.476472 | 2021-01-08T19:00:04 | 2021-01-08T19:00:04 | 263,965,966 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 80 | sci | gitpull.sci | function res = gitpull()
res = unix_g("git pull heroku master")
endfunction
|
cfd2e5acb0de0c026d8cd35c73038aaa3ba6689e | 449d555969bfd7befe906877abab098c6e63a0e8 | /2489/CH16/EX16.2/16_2.sce | 5f4b4f5734af0fad9a1a436fb057fdbd8c8824d3 | [] | 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 | 16_2.sce | clc
//Intitalisation of variables
clear
c= 0.01 //M
ka= 1.75*10^-5
pkw= 14
ka1= 1.79
//CALCULATIONS
pH= 0.5*pkw-0.5*log(ka)+0.5*log(c)-ka1
//RESULTS
printf ('pH of solution = %.2f ',pH)
|
970350c48bd5602bf50f959c627521673bb65d56 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1580/CH2/EX2.4/Ch02Ex4.sce | b5dec60842f9af3555dc46abf226e141ea72a67e | [] | 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 | 433 | sce | Ch02Ex4.sce | // Scilab Code Ex2.4 : Page-2.23 (2004)
clc;clear;
r = 1; // For simplicity assume radius of atom to be unity, unit
a = 4*r/sqrt(2); // Lattice constant, unit
R = (a/2)-r; // R be the radius of interstitial sphere that can fit into void, unit
printf ("\nMaximum Radius of interstitial sphere that can fit into FCC = %5.3fr", R);
// Result
// Maximum Radius of interstitial sphere that can fit into FCC = 0.414r
|
67ab56c42753cc3ec360a3b002750f58e1c1ab2c | 8217f7986187902617ad1bf89cb789618a90dd0a | /browsable_source/2.3/Unix-Windows/scilab-2.3/tests/colnew.tst | 439ba215aa87099f22a933cfd489bc5c3c5c830b | [
"LicenseRef-scancode-warranty-disclaimer",
"LicenseRef-scancode-public-domain",
"MIT"
] | 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 | 257 | tst | colnew.tst | getf('SCI/tests/colnew.sci','c')
[z,zf]=col1();
if maxi(abs(z-zf))>1.e-5 then pause,end
[z,zf]=col2(0);
// Fortran Coded version
if maxi(abs(z-zf))>1.e-2 then pause,end
[z,zf]=col2(1);
// Scilab coded version
if maxi(abs(z-zf))>1.e-2 then pause,end
|
71f36a35c9466dfdbf3a1a2569661c25f0a5915f | 449d555969bfd7befe906877abab098c6e63a0e8 | /215/CH16/EX16.3/ex16_3.sce | f81eeff075ccc85c6a7829ea6b2d8c7b37bf7598 | [] | 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 | 644 | sce | ex16_3.sce | clc
//Example 16.3
disp('Given')
disp('R=10 ohm L=2mH C=200 nF w=48 krad/s vs=100*cos(wt) mV')
R=10; L=2*10^-3; C=200*10^-9; w=48*10^3;
vsamp=100;
w0=1/sqrt(L*C)
printf("w0= %3.1f krad/s \n",w0*10^-3);
Q0=w0*L/R
printf("Q0=%d \n",Q0)
B=w0/Q0
printf("Bandwidth= %3.1f krad/s \n",B*10^-3);
//Number of half bandwidths be N
N=2*(w-w0)/B
disp(N)
//Impedance Z(s)=(1+i*N)*R
//Finding the magnitude and angle
magZ=sqrt(1+N^2)*R
angZ=atan(N)*(180/%pi)
disp(angZ,'angZ=')
printf("Equivalent impedance value=%3.2f ohm \n",magZ)
//Approx current magnitude is
Iamp=vsamp/magZ
printf("\n Approx current magnitude= %3.2f mA \n",Iamp); |
054681c3a524724a10a5e1fb5d0a1dd7d57dfd47 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2120/CH9/EX9.12/ex9_12.sce | 9d7bd5c14b8bf94535c03078452d4ea18e18db26 | [] | 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 | 338 | sce | ex9_12.sce | // Exa 9.12
clc;
clear;
close;
// Given data
m = 0.5;// in kg
M = 6.6;// in kg
x1 = M / (M+m);
h_dry = 2683;//in kJ/kg
C_p = 2.1;
h_sen = 814.5;//in kJ/kg
L = 1973;// in kJ/kg
t_sup = 120;// in °C
t_sat = 104.8;// in °C
x2 =(h_dry+C_p*(t_sup - t_sat)-h_sen)/ L;
x = x2 * x1;
disp(x,"the dryness fraction of steam is");
|
ed11a19a888aa283668545cea139a8d28ddd18fe | 449d555969bfd7befe906877abab098c6e63a0e8 | /1358/CH7/EX7.5/Example75.sce | 31c2d4ed796984768c7fffc84a32e61bef764e71 | [] | 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 | 1,107 | sce | Example75.sce | // Display mode
mode(0);
// Display warning for floating point exception
ieee(1);
clear;
clc;
disp("Turbomachinery Design and Theory,Rama S. R. Gorla and Aijaz A. Khan, Chapter 7, Example 5")
disp("Velocities are in m/s, temperature in Kelvin, Angles in degrees.")
disp("Degree of reaction DOR = 0")
disp("DOR = (T2-T3)/(T1-T3)")
disp("Therefore T2 = T3")
disp("From isentropic p–T relation for expansion")
T01 = 1000;
disp("P01/P03 = r")
r = 1.8
T03a = T01/(r^0.249)
disp("Using turbine efficiency")
disp("T03 = T01-etat*(T01-T03a)")
etat = 0.85;
T03 = T01 - etat*(T01-T03a)
disp("In order to find static temperature at turbine outlet, using static and stagnation temperature relation")
C3 = 270;
Cpg = 1.147;
T3 = T03- C3^2 / (2*Cpg*1000)
T2 = T3;
disp("Dynamic Temperature in K is C^2 /2Cpg = Td")
Td = 1000-T2
C2 = (2*Cpg*1000*Td)^0.5//m/s
disp("Since Cpg*DeltaTos = U*(Cw3+Cw2) = U*Cw2 (Cw3=0)")
U = 290;
Cw2 = Cpg*1000*(1000-884)/U//m/s
disp("From velocity triangle")
alpha2 = asin(Cw2/C2)*180/%pi
Ca2 = C2;
beta2 = atan((Cw2-U)/(Ca2*cos(alpha2*%pi/180)))*180/%pi
|
33ce672d5e79641e67dc020c709880ec47731f55 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1898/CH14/EX14.6/Ex14_6.sce | 26ad594d57eeadaca68e19c96a5aa2e0e08e1b0e | [] | 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 | 751 | sce | Ex14_6.sce | clear all; clc;
disp("Scilab Code Ex 14.6 : ")
//Given:
l_ab = 1; //m
l_bc = 2; //m
N_ab = 11.547*1000; //N
Nb = 20*1000; //N
Nc = -23.094*1000; //N
N_ac = -20*1000; //N
A = 100/(1000^2); //mm^2
E = 200*10^9; //N/m^2
P = 20*10^3;//N
//Eqn 14-26
P_by_2 = P/2;
l_ac = sqrt(l_bc^2 - l_ab^2);
del = 0;
N2= [N_ab^2 Nc^2 N_ac^2];
L = [l_ab l_bc l_ac];
for i = 1:3
del = del + (N2(i)*L(i))/(2*A*E);
end
del_bh = del/P_by_2;
del_bh = del_bh*1000;
//Display:
printf('\n\nThe horizontal displacement at point B = %1.2fmm',del_bh);
//-------------------------------------------------------------------------END-------------------------------------------------------------------------------------------
|
76fcee5c43ea0cfdea5f497855e5f79991249a8f | 449d555969bfd7befe906877abab098c6e63a0e8 | /3428/CH12/EX6.12.13/Ex6_12_13.sce | a57ef3cd98a1bebc25f3b2b7b1eeb85249e867f6 | [] | 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 | 339 | sce | Ex6_12_13.sce | //Section-6,Example-5,Page no.-P.48
//To calculate the quantity of ethyl alcohol required.
clc;
dl_Tf=10 //(K)
K_f=1.86 //(Kkgmol^-1)
M_w=62
d=1 //density (assumption)
V=10 //Volume(L)
M=V*d
W=((dl_Tf*M*M_w)/K_f)*10^-3
disp(W,'Quantity of ethyl alcohol required(kg)')
|
8fe14b67618441137667503b753c0219ea506306 | 584105ff5b87869494a42f632079668e4c3f82de | /TestCases/OpticalFlowFarneback/test3.sce | 7166aef4fb8f4dbd016bba4d9d8ed4073cac2e55 | [] | no_license | kevgeo/FOSSEE-Computer-Vision | 0ceb1aafb800580498ea7d79982003714d88fb48 | 9ca5ceae56d11d81a178a9dafddc809238e412ba | refs/heads/master | 2021-01-17T21:11:31.309967 | 2016-08-01T14:45:40 | 2016-08-01T14:45:40 | 63,127,286 | 6 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 1,214 | sce | test3.sce |
//Reading path of file and executing function
//Checking if error message pops up when NumPyramidLevels is less than one
opticalFlowFarneback("FileName","ped.avi","NumPyramidLevels",0.6);
//output
//!--error 999
//Invalid Value for NumPyramidLevels. Please enter value more than or equal to one.
//Reading path of file and executing function
//Checking if error message pops up when NumPyramidLevels is less than one
opticalFlowFarneback("FileName","juggling.mp4","NumPyramidLevels",0.6);
//output
//!--error 999
//Invalid Value for NumPyramidLevels. Please enter value more than or equal to one.
//Reading path of file and executing function
//Checking if error message pops up when NumPyramidLevels is less than one
opticalFlowFarneback("FileName","juggling2.mp4","NumPyramidLevels",0.6);
//output
//!--error 999
//Invalid Value for NumPyramidLevels. Please enter value more than or equal to one.
//Reading path of file and executing function
//Checking if error message pops up when NumPyramidLevels is less than one
opticalFlowFarneback("FileName","singleball.avi","NumPyramidLevels",0.6);
//output
//!--error 999
//Invalid Value for NumPyramidLevels. Please enter value more than or equal to one.
|
43984d7473967b2c931957a32bce322d51b7dad7 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2699/CH14/EX14.18/Ex14_18.sce | bde27139554fc8c276bca811d24883074161d117 | [] | 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 | 561 | sce | Ex14_18.sce | //example 14.18 PG-14.40
clc
clear
printf(" Refer to the Figure-14.50 shown\n\n")
printf(" The Boolean expression for the output Y is :\n\n")
printf(" Y = (A''+B'')''.BC\n\n")
printf(" Y = ((AB)'')''.BC ....Since A''+B''=(AB)'' and (A'')''= A\n")
printf(" DeMorgan''s Therem\n\n")
printf(" Y = A.B.B.C ........Since A.A=A\n\n")
printf(" Y = ABC\n\n")
printf(" Truth Table\n")
printf(" A B C Y")
a=zeros(1,4)
b=[0 0 1 0;0 1 0 0;0 1 1 0;1 0 0 0;1 0 1 0;1 1 0 0]
c=ones(1,4)
d=[a;b;c]
disp(d)
|
49df5328b6191420048e2f24364959ad1cc6b0b5 | 57e3f1898d0364ee8f61b3eebfb77304d7b59bee | /Simplex.sce | d7f7fac496e3bbde286fd00d97d641dad63ebc79 | [] | no_license | Arma-X/Metodos-de-Otimizacao | 74d3cfebc74224ebda1c738273a29232c2317e74 | 599b0d1d50238bc27a612983ce63fb8d02e85219 | refs/heads/main | 2023-08-04T07:27:42.937906 | 2021-09-16T16:42:58 | 2021-09-16T16:42:58 | 407,217,368 | 1 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 2,640 | sce | Simplex.sce | //// @ Método Simplex @
clc;
clear;
p = [2;3];
q = [3;2];
r = [1;4];
global c;
global b;
global g;
global w;
c = [0;0];
b = p;
g = q;
w = r;
function y=f(p)
// y = (p(2)^2)/4 + (p(1)^2)/9;
y = (p(1)+2)^2+(p(2)-10)^2;
endfunction
function y=func(x1,x2)
y=(x1-2)^4 + (x1 - 2*x2)^2;
endfunction
function ordena(p,q,r)
global b;
global g;
global w;
if ((f(p) < f(q)) & f(p) < f(r)) then
if (f(q) < f(r)) then
b = p;
g = q;
w = r;
else
b = p;
g = r;
w = q;
end
elseif ((f(q) < f(p)) & f(q) < f(r)) then
if (f(p) < f(r)) then
b = q;
g = p;
w = r;
else
b = q;
g = r;
w = p;
end
elseif ((f(r) < f(p)) & f(r) < f(q)) then
if (f(p) < f(q)) then
b = r;
g = p;
w = q;
else
b = r;
g = q;
w = p;
end
end
endfunction
function centroide(p,q)
global c;
c(1) = (p(1)+q(1))/2;
c(2) = (p(2)+q(2))/2;
endfunction
function r=reflexao()
global c;
global b;
global g;
global w;
centroide(b,g);
r = c+(c-w);
endfunction
function e=expansao()
global c;
global b;
global g;
global w;
centroide(b,g);
e=c+2*(c-w);
endfunction
function con=contracao()
global c;
global b;
global g;
global w;
centroide(b,g);
con=c+0.5*(c-w);
endfunction
function encolher()
global c;
global b;
global g;
global w;
centroide(b,g);
g = b + 0.5*c;
centroide(b,w);
w = b + 0.5*c;
endfunction
function simplex()
global c;
global b;
global g;
global w;
n = 10000;
i=1;
while (i<n)
ordena(b,g,w);
reflete = reflexao();
if(f(reflete)>f(b)&f(reflete)<f(g))
w = reflete;
end
if( f(reflete) <= f(b) ) then
expande = expansao();
if ( f(expande) < f(reflete) ) then
w = expande;
else
w = reflete;
end
end
if( f(reflete)>f(w)) then
contrai = contracao();
if ( f(contrai) < f(w) ) then
w = contrai;
else
encolher();
end
end
i = i + 1;
end
ordena(b,g,w);
endfunction
// ----------------------------- main ------------------------
simplex();
mprintf("(%.7f,%.7f)", b(1),b(2));
|
c6b9289216d3fbf6e2805c0438fd5ac5568a0ec5 | c61d570c37971fa455028a89d2163f455f91c291 | /script_fisico/bissecao.sci | f900b229be21355ee39d1973fcdd896f09b5b291 | [] | no_license | OgliariNatan/-ScientificComputing | a0af891f900f3f146a9751fd169f96052bd4ba83 | 070ea9d70430ef0c9e7944f491426b73af7c12b0 | refs/heads/master | 2020-04-04T23:13:12.585946 | 2017-07-03T21:46:18 | 2017-07-03T21:46:18 | 81,988,821 | 1 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 1,451 | sci | bissecao.sci | function [raiz,n] = bissecao(fun,xl,xu,es)
// [raiz,n] -> variaveis de saída
// -> raiz procurada
// -> n é o numero de iterações realizadas
// (fun,xl,xu,es) -> variaveis de entrada
// -> fun é a função desejada
// -> xl é o limite inferior do intervalo de busca
// -> xu é o limite superior do intervalo de busca
// -> es é o critério de parada
//Exemplo de Chamada
//exec ('path\bissecao.sci',-1) {-1 não mostra o código de execução}
//fun = 'log(x) +x'
//[raiz,n]=bissecao(fun,0.1,2,0.1)
//Autor: Daniel HC Souza
//IMPLEMENTACAÇÃO....
// Verificação se existe raizes no intervalo
x = xu;
fu = evstr(fun);
x = xl;
fl = evstr(fun);
if fu*fl>0 then
raiz = "Não há Raizes no intervalo fornecido";
n = 0;
else
if argn(2) < 4 then
es = 0.0001;
end
//inicialização de variaveis
ea = 100; xr_novo = xl; n=0;
//inicio do calculo
printf("Iteração\tErro\n");
while ea > es do
xr_velho = xr_novo;
xr_novo = (xl+xu)/2;
if xr_novo ~= 0 then
ea = abs((xr_novo - xr_velho)/xr_novo)*100;
end
printf("%d\t\t%f\n",n,ea);
x = xr_novo;
fr = evstr(fun);
x = xl;
fl = evstr(fun);
if fl*fr>0 then
xl = xr_novo;
else
xu = xr_novo;
end
n = n+1;
end
raiz = xr_novo;
end
endfunction
|
f6670385026383cef24dfc97ebb2affebb823a10 | 449d555969bfd7befe906877abab098c6e63a0e8 | /587/CH3/EX3.15/example3_15.sce | ca05c81084d1e686ed4708da8bee52c10c75c68f | [] | 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 | 1,515 | sce | example3_15.sce | clear;
clc;
//Example3.15[Cost of Heat Loss through walls in winter]
//Given:-
R_va_insu=2.3;//thickness to thermal conductivity ratio[m^2.degreeCelcius/W]
L1=12;//length of first wall of house[m]
L2=12;//length of second wall of house[m]
L3=9;//length of third wall of house[m]
L4=9;//length of fourth wall of house[m]
H=3;//height of all the walls[m]
T_in=25;//Temperature inside house[degree Celcius]
T_out=7;;//average temperature of outdoors on a certain day[degree Celcius]
ucost=0.075;//Unit Cost of elctricity[$/kWh]
h_in=8.29,h_out=34.0;//Heat transfer coefficients for inner and outer surface of the walls respectively[W/m^2.degree Celcius]
v=24*(3600/1000);//velocity of wind[m/s]
//Solution:-
//Heat transfer Area of walls=(Perimeter*Height)
A=(L1+L2+L3+L4)*H;//[m^2]
//Individual Resistances
R_conv_in=1/(h_in*A);//Convection Resistance on inner surface of wall[degree Celcius/W]
R_conv_out=1/(h_out*A);//Convection Resistance on outer surface of wall[degree Celcius/W]
R_wall=R_va_insu/A;//Conduction resistance to wall[degree Celcius/W]
//All resistances are in series
R_total=R_conv_in+R_wall+R_conv_out;//[degree Celcius/W]
Q_=(T_in-T_out)/R_total;//[W]
disp("W",Q_,"The steady rate of heat transfer through the walls of the house is")
delta_t=24;//Time period[h]
Q=(Q_/1000)*delta_t;//[kWh/day]
disp("kWh/day",Q,"The total amount of heat lost through the walss during a 24 hour period ")
cost=Q*ucost;//[$/day]
disp("per day",cost,"Cost of heat consumption is $")
|
9ccba18bffcd7b3e81b09f236f956f5aca6a710d | 623a9dd972dc78dbde5d5b8dc187acd6a1eb5910 | /TP2/gauss.sci | ea3d2ab1150a9e3f3b48e328efafa8969b6a5e8d | [] | no_license | gtessi/CN2012-FICH | 0daad054ceb6c36636ee5e8b174a676b9e0acb9b | 4024384653b61b5af9e1c11ffb575e154025ee47 | refs/heads/master | 2020-03-27T05:53:04.684505 | 2018-08-25T03:03:15 | 2018-08-25T03:03:15 | 146,059,800 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 425 | sci | gauss.sci | function x = gauss(A,b)
n=length(b);
x=zeros(n,1);
for (k=1:n-1)
for (i=k+1:n)
if (A(k,k)==0) then
mprintf('No existe solución única.\n\n')
abort;
end
m=A(i,k)/A(k,k);
A(i,k)=0;
A(i,k+1:n)=A(i,k+1:n)-m*A(k,k+1:n);
b(i)=b(i)-m*b(k);
end
end
x=backSub(A,b);
endfunction |
e4dec93abf10f5b437deac1f7ce7809ea3a6c54f | 449d555969bfd7befe906877abab098c6e63a0e8 | /866/CH16/EX16.20/16_20.sce | 1f1547151b9564ee9136b88f2335291bf67a2414 | [] | 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 | 671 | sce | 16_20.sce | clc
//initialisation of variables
W= 6 //KN/m
F= 40 //KN
l1= 5 //m
l2= 3 //m
l3= 3 //m
l= 12 //mm
Smab= 9*10^6 //mm^4
Smbc= 12*10^6 //mm^4
E= 200000 //N/mm^2
//CALCULATIONS
MFab= (-W*l1^2/12)+((-W*Smab*E*l))/((l1*10^3)^2*10^6)
MFba= (W*l1^2/12)+((-W*Smab*E*l))/((l1*10^3)^2*10^6)
MFbc= -(F*(l2+l3)/8)+(3*E*Smbc*l)/(((l2+l3)*10^3)^2*10^6)
MFcb= (F*(l2+l3)/8)
DFba= ((4*E*Smab)/l1)/(((4*E*Smab)/l1)+((3*E*Smbc)/(l2+l3)))
DFbc= 1-DFba
//RESULTS
printf ('MFab= %.1f KN m',MFab)
printf (' \n MFbc= %.1f KN m',MFba)
printf (' \n MFbc= %.1f KN m',MFbc)
printf (' \n MFbc= %.1f KN m',MFcb)
printf (' \n DFab= %.2f ',DFba)
printf (' \n DFbc= %.2f.',DFbc)
|
0a2aac325a4e110650a3c950231cfb8337ecce6a | 449d555969bfd7befe906877abab098c6e63a0e8 | /626/CH2/EX2.14/2_14.sce | 7f40a623eac5e220d762f47cc023735f5f0d0fb3 | [] | 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 | 542 | sce | 2_14.sce | clear;
clc;
close;
disp("Example2.14")
p=20 //p=p2/p1 i.e. compression ratio.
gm=1.4 // gamma
//Vx1=Vx2 i.e. axial velocity remains same.
//calculations:
d=p^(1/gm) //d=d2/d1 i.e. density ratio
A=1/d // A=A2/A1 i.e. area ratio which is related to density ratio as: A2/A1=d1/d2.
//disp(A)
Fx=1-p*A //Fx=Fxwall/p1*A1 i.e nondimensional axial force.
disp(Fx,"The non-dimensional axial force is :")
disp("The negative sign on the axial force experienced by the compressor structure signifies a thrust production by this component.") |
3302ed1124882651ef4a0941acefd8d659aca268 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1478/CH2/EX2.18.44.C/2_18_44_C.sce | 6997c24eb0d016f963a5838099dd9d7aeb05ce78 | [] | 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 | 974 | sce | 2_18_44_C.sce | //water and its treatment//
//example 2.18.44.C//
clc
Purity_Lime=.90
Purity_soda=.95
W1=81;//amount of Ca(HCO3)2 in ppm//
W2=42;//amount of MgCO3 in ppm//
W3=4.1;//amount of NaAlO2 in ppm//
W4=3.65;//amount of HCl in ppm//
W5=82;//amount of Ca(NO3)2 in ppm//
W6=4.5;//amount of NaCl in ppm//
M1=100/162;//multiplication factor of Ca(HCO3)2//
M2=100/84;//multiplication factor of MgCO3//
M3=100/82;//multiplication factor of NaAlO2//
M4=100/36.5//multiplication factor of HCl//
P1=W1*M1;//in terms of CaCO3//L
P2=W2*M2;//in terms of CaCO3//L
P3=W3*M3;//in terms of CaCO3//-L-S
P4=W4*M4;//in terms of CaCO3//L+S
printf ("We do not take Ca(NO3)2 and NaCl since they do not react with lime/soda");
V=20000;//volume of water in litres//
L=0.74*(P1+P2*2-P3+P4)*V/Purity_Lime;//lime required in mg//
L=L/10^6;
printf("\nLime required is %.3fkg",L);
S=1.06*(P4-P3)*V/Purity_soda;//soda required in mg//
S=S/10^6;
printf("\nSoda required is %.1fkg",S) |
7fd9ae0850357ab5b0fb8a860be55b3d9736d2de | 0a1c3ed3b471bd0805778ea1f03dc265bd5ea963 | /test/logic.tst | 65f2c15548b3eed9eb27d49a57b7df2d82f9536e | [] | no_license | goldenpartner/Assignment1 | 32aeb4bc435c840e930189fd62533b3710cbe490 | c13e732c338d1ca04abc2b355d8a48bd76907bcc | refs/heads/master | 2021-01-12T11:54:30.972457 | 2016-10-18T03:33:30 | 2016-10-18T03:33:30 | 69,310,866 | 0 | 2 | null | null | null | null | UTF-8 | Scilab | false | false | 125 | tst | logic.tst | LOAD s0, 07
LOAD s1, 01
LOAD s2, 05
OR s0, s1
AND s0, s2
XOR s3, 01
OUTPUT s0, 00
OUTPUT s1, 00
OUTPUT s2, 00
OUTPUT s3, 00
|
f7034fe13f38b0a6f33fae44ebe8fd4f801d1045 | 449d555969bfd7befe906877abab098c6e63a0e8 | /944/CH6/EX6.18/example6_18_TACC.sce | 8a5cc5830436ad4dfb84605fe508c2b7940403e2 | [] | 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 | 408 | sce | example6_18_TACC.sce | //example 6.18
clear;
clc;
//Given:
R=82;//Universal gas constant[atm.ml.K^-1.mol^-1]
T=298;//Temperature[K]
V=250;//volume of water[ml]
m2=2.6;//mass of the protein
M2=85000;//molar mass of protein[g.mol^-1]
//To find the osmotic pressure of a solution
n2=m2/M2;//no. of moles of protein
II=(n2*R*T)/V;//Osmotic pressure of a solution[atm]
printf("The osmotic pressure is %f atm ",II);
|
b0b785d49242682f7c999ca4dcc92118fba05274 | 449d555969bfd7befe906877abab098c6e63a0e8 | /3720/CH1/EX1.5/Ex1_5.sce | 7e340f007a1d0fb4e96574f3e634ae7f62c91642 | [] | 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 | 318 | sce | Ex1_5.sce | //Example 1_5
clc;clear;funcprot(0);
//Given relations
// x-y=4;
//x^2+y^2=x+y+20;
//Solution
// Assume x=y(1);y=y(2);
function[X]=unknowns(y);
X(1)=y(1)-y(2)-4;
X(2)=y(1)^2+y(2)^2-y(1)-y(2)-20;
endfunction
y=[1 1];
z=fsolve(y,unknowns);
printf('x=%0.0f \n',z(1));
printf('y=%0.0f \n',z(2));
|
cdfe600eb5eca5ba2e55424718b9b97b200c9b99 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2048/CH7/EX7.9/data01.sce | c72c576d4ffb45cdc5290cdf0f8a2d796cf4267e | [] | 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 | 469 | sce | data01.sce | // Left coprime factorization as discussed in Example 7.13 on page 295.
// 7.9
exec('rowjoin.sci',-1);
exec('makezero.sci',-1);
exec('colsplit.sci',-1);
exec('clcoef.sci',-1);
exec('polsize.sci',-1);
exec('seshft.sci',-1);
exec('indep.sci',-1);
exec('move_sci.sci',-1);
exec('t1calc.sci',-1);
exec('left_prm.sci',-1);
D = [1 0 0 0 0 0
0 1 0 1 0 0
0 0 1 1 1 0];
N = [
1 0 0
0 1 0
0 0 1];
dD = 1;
dN = 0;
[B,dB,A,dA] = left_prm(N,dN,D,dD)
|
eacdaa77f42211c1473920fd8ef9ca71c0d49c1b | 449d555969bfd7befe906877abab098c6e63a0e8 | /1133/CH3/EX3.5/Example3_5.sce | 97ded7f3cf68421b8e7222ac3536e1f7a226aad6 | [] | 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 | 1,769 | sce | Example3_5.sce | //Example 3.5
clc
disp("Step 1: Identity topology")
disp(" The feedback voltage is applied across R1 (100 ohm), which is in series with input signal. Hence feedback is voltage series feedback.")
disp("")
disp("Step 2 and Step 3: Find input and output circuit")
disp(" To find input circuit, set Vo = 0, which gives parallel combination of R1 with R2 at E1 as shown in the fig.3.45. To find output circuit, set Ii = 0 by opening the input node, E1 at emitter of Q1, which gives the series combination of R2 and R1 across the output. The resultant circuit is shown in fig.3.45")
disp("")
disp("Step 4: Find the open loop voltage gain (Av)")
rl2=(4.7*4.8)/(4.7+4.8) // in k-ohm
format(5)
disp(rl2," R_L2(in k-ohm) =")
disp("Since h_oe = h_re = 0 we can use approximate analysis")
disp(" A_i2 = -hfe = -50")
disp(" R_i2 = hie = 1.1 k-ohm")
av2=(-50*2.37)/1.1
format(7)
disp(av2," A_v2 = A_i2*R_L2 / R_i2 =")
rl1=(10*47*33*1.1)/((47*33*1.1)+(10*33*1.1)+(10*47*1.1)+(10*47*33)) // in ohm
format(5)
disp(rl1*10^3," R_L1(in ohm) =")
disp(" A_i1 = -hfe = -50")
ri1=1.1+(51*((0.1*4.7)/(4.8))) // in k-ohm
format(6)
disp(ri1," R_i1(in k-ohm) = hie + (1+hfe)*Re =")
av1=(-50*942)/(6.093*10^3)
format(5)
disp(av1," A_v1 = A_i1*R_L1 / R_i1 =")
av=-7.73*-107.73
format(7)
disp(av,"Therefore, A_v = A_v1 * A_v2 =")
disp("")
disp("Step 5: Calculate beta and D")
disp(" beta = R1 / R1+R2 = 1/48")
d=1+(832.75/48) // in ohm
format(6)
disp(d," D(in ohm) = 1 + A*beta =")
disp("")
disp("Step 5: Calculate A_vf, R_of and R_if")
avf=832.75/18.35
disp(avf," A_vf = A_v / D =")
rif=6.093*18.35 // in k-ohm
disp(rif," R_if(in k-ohm) = R_i1 * D =")
rof=(2.37*10^3)/18.35 // in ohm
format(7)
disp(rof," R_of(in ohm) = R_o / D =") |
7befdfc3a9aad728e05986f824ef72c168452eab | 978b15852ad0d9219e0cd69e9da3a9140b84aa97 | /exo5+exo6/jacobi.sce | bbbdfa5311663d8c2a4965434718d5f014270381 | [] | no_license | nadine867/TP_CN | cd2acc700471c7f595ada5f2b799b43ca44590ce | fcf09074e27723ca3e9b1eec870386c848b190f9 | refs/heads/master | 2023-02-03T04:07:38.525606 | 2020-12-18T20:23:55 | 2020-12-18T20:23:55 | 316,060,516 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 858 | sce | jacobi.sce | //méthode de jaccobi pour résoudre Ax=b
function[sol,niter,info]= jacobi(A,b,nmaxit,tol)
//vérification aucun terme de la diagonal de A n'est nul
if ~and(diag(A)) then
error('erreur:diagonale est nulle')
end
//décomposition de A=D-E-F
D=diag(diag(A))
E=-triu(A)+D
F=-tril(A)+D
x=inv(A)*b
sol=b
niter=0
info=0
err=[]
for k=1:nmaxit
sol =(eye(n,n)-inv(D)*A)*sol+inv(D)*b
err=[err,norm(x-sol)];
if max(abs(A*sol-b))< tol
info = 1;
niter= k;
break
end
end
plot(1:niter,log(err))
endfunction
n=3
A=[2 -1 0;-1 2 -1;0 -1 2]
b=[5; 3; 2]
[sol,niter,info]= jacobi(A,b,100,0.01)
x=inv(A)*b
b=A*x;
|
9eb70e7e0cb85c8b3101496da569d139d00516aa | 449d555969bfd7befe906877abab098c6e63a0e8 | /1382/CH3/EX3.12/ex_3_12.sce | e8e29a7f3d50e34eb20d1dcc85387331bca9bce1 | [] | 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 | 477 | sce | ex_3_12.sce | // Example 3.12 : the percent second harmonic distortion
clc, clear;
Vcc=50; // voltage in volts
Vmin=5; // minimum voltage in volts
pi=3.142857;
Pd=40; // total power dissipation in watt
Icmax=Pd/(((2*Vcc)/pi)-((Vcc-Vmin)/2));
Pin=(2/pi)*(Vcc*Icmax);
Pout=((Icmax/2)*(Vcc-Vmin));
eta=(Pout/Pin)*100;
disp(Icmax,"maximum collector current (A) = ")
disp(Pin,"total power input (W) = ")
disp(Pout,"ac power output (W) = ")
disp(eta,"conversion efficiency (%) = ")
|
9cda110f8c6162ab000059f0efe040439f5f97ed | 449d555969bfd7befe906877abab098c6e63a0e8 | /1898/CH3/EX3.3/Ex3_3.sce | 076c55e7ff38419cf4d21ab957dac12be8083a26 | [] | 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 | 950 | sce | Ex3_3.sce | clear all; clc;
disp("Scilab Code Ex 3.3 : ")
//Given:
p = 10000; //N
E_al = 70*(10^3); //MPa
l_ab = 600; //mm
d_ab = 20; //mm
l_bc = 400; //mm
d_bc = 15; //mm
//Calculations:
a_ab = (%pi/4)*(d_ab^2);// Area of AB
a_bc = (%pi/4)*(d_bc^2);
stress_ab = p/a_ab;// Stress = load/area
stress_bc = p/a_bc;
e_ab = stress_ab/E_al; //Hookes's Law. Elastic strain.
e_bc = 0.045; //mm/mm . From the graph for stress_bc
elongation = (l_ab*e_ab)+ (l_bc*e_bc);
strain_rec = stress_bc/E_al; //Strain Recovery
e_og = e_bc-strain_rec;// mm/mm
rod_elong = e_og*l_bc;
//Display:
printf("\n\nThe elongation of the rod when load is applied =%10.1f mm",elongation);
printf("\nThe permanent elongation of the rod when load is removed = %0.1f mm",rod_elong);
//-------------------------------------------------------------------------END----------------------------------------------------------------------------------
|
6a1b79efbf50cb341e137006cd62aa4a2e595711 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2882/CH7/EX7.16/Ex7_16.sce | 773ce56f279fea4b6ec6370d402c0c33296eead4 | [] | 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 | 745 | sce | Ex7_16.sce | //Tested on Windows 7 Ultimate 32-bit
//Chapter 7 Field Effect Transistors Pg no. 253
clear;
clc;
//Given Data
//Figure 7.47
ID_ON=5D-3;//ON drain current in amperes
VGS_th=5;//threshold gate to source voltage in volts
VGS=9;//gate to source voltage in volts
VDD=20;//drain supply voltage in volts
RD=1D3;//drain resistance in ohms
R1=2.2D3;//voltage divider network resistance R1 in ohms
R2=3.3D3;//voltage divider network resistance R2 in ohms
//Solution
VGS_Q=VDD*R2/(R1+R2);//gate to source voltage in volts
C=ID_ON/(VGS-VGS_th)^2;//constant C in ampere/volt^2
ID=C*(VGS_Q-VGS_th)^2;//drain current in amperes
VDS=VDD-ID*RD;//drain to source voltage in volts
printf("VGS = %d Volts\n VDS = %.2f Volts",VGS_Q,VDS);
|
3bbd77bf2c9edf5224da1f4664ac6fed52ef9f85 | 8217f7986187902617ad1bf89cb789618a90dd0a | /source/2.5/tests/examples/isdef.man.tst | 57f806232794c451a286097353c1140ea5755448 | [
"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 | 51 | tst | isdef.man.tst | clear;lines(0);
A=1;
isdef('A')
clear A
isdef('A')
|
a9e3738dee97f78cb68b692a34c6e451e161a20f | 449d555969bfd7befe906877abab098c6e63a0e8 | /2021/CH4/EX4.6/EX4_6.sce | 41d34e5572965ed3bc452354490bf9c770ef4d12 | [] | 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 | 296 | sce | EX4_6.sce | //Finding of Weight and Metacentric height
//Given
l=4;
b=2;
h=1;
d=0.6;
v=l*b*d;
rho=1000;
g=9.81;
//To Find
wd=rho*g*v;
disp("Weight of the body ="+string(wd)+" Newtons");
I=(l*b^3)/12;
h1=h/2;
d1=d/2;
h2=h1-d1;
mh=(I/v)-h2;
disp("Metacentric Height ="+string(mh)+" meter");
|
3f1a72a45bf802ff5fbe3dfa178380a5015a4694 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2705/CH4/EX4.8/Ex4_8.sce | 7cfe9998053954b64ae946b7f66ffb77b17e1497 | [] | 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 | 381 | sce | Ex4_8.sce | clear;
clc;
disp('Example 4.8');
// aim : To determine
// the specific volume of wet steam
// Given values
P = 1.25; // pressure, [MN/m^2]
x = .9; // dry fraction
// solution
// from steam table at given pressure
vg = .1569;// [m^3/kg]
// hence
v = x*vg; // [m^3/kg]
mprintf('\nThe specific volume of wet steam is = %f m^3/kg \n',v);
// End
|
d068549fa9fc384bd16920835780ff556518571a | 449d555969bfd7befe906877abab098c6e63a0e8 | /1862/CH6/EX6.5/C6P5.sce | 2a445060765d38d9696cc7772a4cca163ba33220 | [] | 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 | 1,214 | sce | C6P5.sce |
clear
clc
//to find velocity of second glider after collision
// GIVEN::
//we consider +ve x direction as initial motion of first glider
//mass of first glider
m1 = 1.25//in kg
//initial velocity of first glider in +ve x direction
v1ix = 3.62//in m/s
//mass of second glider
m2 = 2.30//in kg
//final velocity of first glider in +ve x direction
// - sign since after collision first glider is moving in -ve x direction
v1fx = -1.07//in m/s
//initial velocity of second glider in +ve x direction
//since 2nd glider is initially at rest
v2ix = 0//in m/s
// SOLUTION:
//applying conservation of momentum
//final velocitiy of second glider in +ve x direction
v2fx = (m1/m2)*(v1ix-v1fx)//in m/s
//change in momentums for glider having mass m1
delta_p1x = m1*(v1fx-v1ix)//in Kg.m/s
//change in momentums for glider having mass m2
delta_p2x = m2*(v2fx-v2ix)//in Kg.m/s
printf ("\n\n Velocitiy of second glider in +ve x direction after collision v2fx = \n\n %.2f m/s",v2fx);
printf ("\n\n Change in momentums for glider having mass m1 delta_p1x = \n\n %.2f Kg.m/s",delta_p1x);
printf ("\n\n Change in momentums for glider having mass m2 delta_p2x = \n\n %.2f Kg.m/s",delta_p2x);
|
a43b24488d695fadc5f7f903158eed6feaf0054d | ac1f8441b0319b4a391cd5a959bd3bb7988edfa7 | /data/news2015/news2015/SplitsNEWS15/EnHi/enhi.2.tst | a6565b2828ee7e82593ac7f750213c03d445417d | [
"MIT"
] | permissive | SaeedNajafi/transliterator | 4d58b8604fa31f52ee2dce7845e002a18214fd5e | 523a087b777a5d6eec041165dabb43848f6222e6 | refs/heads/master | 2021-09-18T17:02:59.083727 | 2018-07-17T06:01:21 | 2018-07-17T06:01:21 | 129,796,130 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 66,566 | tst | enhi.2.tst | a a b h a a आ भ ा
a a b h e e r आ भ ी र
a a c h a a r y a s u t a a आ च ा र ् य स ु त ा
a a c h a a r y s u t आ च ा र ् य स ु त
a a c h a r y n a n d a n a a आ च ा र ् य न ं द न ा
a a d i s h v a r आ द ि श ् व र
a a f r e e n आ फ र ी न
a a j k a a r j u n आ ज क ा अ र ् ज ु न
a a j k a y e h g h a r आ ज क ा य ह घ र
a a j k e a n g a a r e y आ ज क े अ ँ ग ा र े
a a k a a s h a आ क ा श
a a m e r s o h a i l आ म े र स ो ह े ल
a a p k a p y a r आ प क ा प ् य ा र
a a p k i k h a t i r आ प क ी ख ा त ि र
a a s h i q आ श ि क
a a t a n k आ त ं क
a b a h i m अ ब ह ी म
a b b a a s अ ब ् ब ा स
a b d u l h a l i m अ ब ् द ु ल ह ल ी म
a b d u l j a b b a a r अ ब ् द ु ल ज ब ् ब ा र
a b d u l k h a a l i q अ ब ् द ु ल ख ा ल ि क
a b d u l m a a l i k अ ब ् द ु ल म ा ल ि क
a b d u l m u h a y a m e e n अ ब ् द ु ल म ु ह ा य म ी न
a b d u l n a f e e अ ब ् द ु ल न फ ी
a b d u l r a q i b अ ब ् द ु ल र क ी ब
a b d u r r a h m a a n अ ब ् द ु र र ह म ा न
a b d u s अ ब ् द ु स
a b d u s s a l a a m अ ब ् द ु स स ल ा म
a b d u s s h a f i अ ब ् द ु स श फ ी
a b h a आ भ ा
a b h i j a t आ भ ि ज ा त
a b h i n a t h अ भ ि न ा थ
a b o d h अ ब ो ध
a b u l f a z a l अ ब ु ल फ ज ल
a c h a l a अ च ल ा
a c h h n e r a j u n c t i o n अ छ न े र ा ज ं क ् श न
a d i t y a n a n d a n आ द ि त ् य न ं द न
a d w a a k e e अ द ् व ा क ी
a f e e r a h अ फ ी र ा ह
a f s a n a अ फ स ा न ा
a f t a b a h m e d आ फ त ा ब अ ह म द
a g g i e ए ग ी
a g n i s a k s h i अ ग ् न ि स ा क ् ष ी
a h a d आ ह ड
a h a m a d अ ह म द
a h l a d आ ह ् ल ा द
a j e e b i t t e f a q अ ज ी ब इ त ् त ि फ ा क ़
a j w a d अ ज व ा द
a k a l m a n d अ क ल म ं द
a k s h a r अ क ् ष र
a l a m n a g a r आ ल म न ग र
a l a n m u l l a l l y ऐ ल न म ु ल ा ल ी
a l g e r h i s s अ ल ् ग र ह ि स
a l h a d आ ल ् ह ा द
a l i b a b a m a r j i n a अ ल ी ब ा ब ा म र ् ज ी न ा
a l i b a g h अ ल ी ब ा ग
a l i c i a ए ल ी स ि य ा
a l i s a अ ल ि स ा
a l i w a l अ ल ी व ा ल
a l l a u d i n l a i l a अ ल ा उ द ् द ी न ल ै ल ा
a l l e g h e n y अ ल ् ल े ग ह े न ् य े
a l p a n a a अ ल ् प न ा
a l p h o n s e अ ल ् फ ो ं स े
a l t a i r n a n o t e c h n o l o g i e s अ ल ् ट ा य र न ै न ो ट े क र ् न ल ॉ ज ि स
a l t a m a h a अ ल ् त म ा ह ा
a l v i n g r e e n i d g e ए ल ् व ि न ग ् र ी न ि ज
a m a l अ म ल
a m a r a s h r e e अ म र ा श ् र ी
a m a r k a a n t अ म र क ा ं त
a m b u j अ ं ब ु ज
a m e r a d a h e s s ए म र े ड ा ह े स
a m e r i c a n e l e c t r i c p o w e r अ म े र ि क न इ ल े क ् ट ् र ि क प ॉ व र
a m e t h i अ म े ठ ी
a m i r a h अ म ि र ा ह
a m o h a अ म ो ह
a m r i t e s h v a r अ म ृ त े श ् व र
a n a d y r ए न ा ड ा य र
a n a n d e e आ न ं द ी
a n d r a l y n ए ण ् ड ् र े ल ि न
a n g i o t e c h p h a r m a c e u t i c a l s ए न ् ज ि य ो ट े क फ ़ ा र ् म ा स ु ट ि क ल ् स
a n g l o a m e r i c a n ए ं ग ् ल ो अ म े र ि क न
a n g l o - d u t c h w a r ए ं ग ् ल ो - ड च व ा र
a n g o o r i अ ं ग ू र ी
a n i s e ए न ी ज
a n o k h a m i l a n अ न ो ख ा म ि ल न
a n o k h a m o d h अ न ो ख ा म ो ड ़
a n o k h i m o h a b b a t अ न ो ख ी म ो ह ब ् ब त
a n u h y a अ न ु ह ् य ा
a n u r o d h अ न ु र ो ध
a p n a b a n a l o अ प न ा ब न ा ल ो
a p o o r v अ प ू र ् व
a p t e आ प ् ट े
a r a b k a s a u d a g a r अ र ब क ा स ौ द ा ग र
a r a b i a n अ र ब ी
a r a b i a n अ र े ब ी य न
a r a r i y a अ र ा र ि य ा
a r d a n अ र ् द न
a r e e b अ र ी ब
a r g e n t i n a m u s e u m o f n a t u r a l s c i e n c e s अ र ् ज े ं ट ी न ा म ् य ु ज़ ि य म ऑ फ न ै च र ल स ा इ ं स े स
a r i a n e ए र ि य न
a r i j i t अ र ि ज ि त
a r i s h t a n e m i अ र ि ष ् ट न े म ि
a r i s t o t l e o n a s s i s ए र ी स ् ट ो ट ल ओ न ा स ि स
a r m a n d h a m m e r अ र म ं ड ह ॅ म र
a r p a n a a अ र ् प ण ा
a r p i t a a अ र ् प ि त ा
a r s i k e r e j u n c t i o n अ र स ि क े र ी ज ं क ् श न
a r t h u r h a l e y आ र ् थ र ह ॅ ल े
a r u n e s h अ र ु ण े श
a s h a a आ श ा
a s h i s h k a p o o r आ श ी ष क प ू र
a s h l e y d e s i l v a ऐ श ् ल े ड े स ि ल ् व ा
a s h o k l e y l a n d अ श ो क ल ी ल ै ं ड
a s i a n h o t e l s ए श ि य न ह ो ट ल ् स
a s m a अ स ् म ा
a s o k a d e s i l v a अ स ो क ा ड े स ि ल ् व ा
a t a b a q u e अ त ा ब ै क
a t a l a n t a ए ट ल ा ं ट ा
a t e l i अ ट े ल ी
a t h a b a s c a अ थ ा ब ा स ् क ा
a t h i y a अ थ ि य ा
a t i s h b a a z आ त ि श ब ा ज ़
a t m a n a n d आ त ् म ा न ं द
a t o m a w a r d ए ट म अ व ा र ् ड
a t r a u l i r o a d अ त ् र ौ ल ी र ो ड
a t r e अ त ् र े
a t r u अ ट र ू
a t t a r अ ट ् ट ा र
a t t a r अ ट ् ट ा र
a t t u r अ ट ् ट ू र
a t u l y a अ त ु ल ् य
a u n r i h a r j u n c t i o n औ ं र ि ह र ज ं क ् श न
a u r a t a u r p a t t h a r औ र त औ र प त ् थ र
a v a n i s h अ व न ी श
a v e s t h a g e n ए व स ् थ ज ़ े न
a v i s h k a r s a l v i आ व ि ष ् क ा र स ा ल ् व ि
a w a t i f अ व ा त ि फ
a y y o o b अ य ् य ू ब
a z a m n a g a r r o a d आ ज़ म न ग र
b a b o o j i ब ा ब ू ज ी
b a d a b h a i ब ड़ ा भ ा ई
b a d r u d i n ब द ् र ु द ि न
b a d w a l ब ड़ व ा ल
b a g e v a d i ब ा ग े व द ी
b a h a d u r ब ह ा द ु र
b a h a d u r d a k u ब ह ा द ु र ड ा क ू
b a h a u d e e n ब ह ा उ द ् द ी न
b a h i r ब ह ि र
b a h r a i n ब ह र ी न
b a h u h o t o a i s i ब ह ू ह ो त ो ऐ स ी
b a i k u n t h p u r ब ै क ु ं ठ प ु र
b a i r a a g ब ै र ा ग
b a i r a g n i a ब ै र ा ग न ि य ा
b a i t a r a n i व ै त र ण ी
b a j a l a ब ज ा ल ा
b a l a j i ब ा ल ा ज ी
b a l a s o r e ब ा ल ा स ो र
b a l a w a l i ब ल ा व ा ल ी
b a l c h a n d r a ब ा ल च ं द ् र
b a l e e l ब ल ी ल
b a l i p a r a ब ल ी प ा र ा
b a n d h a n b a h o n k a ब ं ध न ब ा ँ ह ो ं क ा
b a n s i b i r j u ब ं स ी ब ि र ज ू
b a n s i p a h a r p u r ब ं स ी प ह ा र प ु र
b a n w e t ब न व े ट
b a r a n o f ब ै र न ऑ फ
b a r b e r t o n f r i e n d s ब ा र ् ब े र ट ॉ न फ ् र े ं ड स
b a r e e r a h ब र ी र ह
b a r g a d i ब र ग ा ड़ ी
b a r k a a t ब र क ा त
b a r k a k a n a ब र क ा क ा न ा
b a r n a l a ब र न ल ा
b a r n a l a ब र न ा ल ा
b a r r o w ब ै र ॉ
b a r r y h a d l e e ब ै र ी ह ै ड ल ी
b a r s i t o w n ब र स ी ट ा उ न
b a r u a ब र ु आ
b a s a v a s a g a r d a m ब स ा व ा स ा ग र ड ै म
b a t a a n ब ट ा न
b a t u d a m ब ट ु ड ै म
b a w a ब ा व ा
b a y a n ब े य ा न
b a y a r d c o v e f o r t ब े य ा र ् ड क ो व फ ो र ् ट
b e e r a a m ब ल ् ल ी र ा म
b e g u i n e ब े ज ू इ न
b e k h b a r ब े ख ब र
b e l i e v e r s ब ि ल ि व र ् स
b e l l s o u t h ब े ल स ा उ थ
b e l r a y a n ब े ल र े य ा न
b e s k i d y ब े स ् क ि ड े
b e s r o l i ब े स र ो ल ी
b e s t b u y ब े स ् ट ब ा य
b e t a a b ब े त ा ब
b h a a n o o भ ा न ू
b h a a r a t e e भ ा र त ी
b h a d b h o k e भ ा ड भ ो क े
b h a d r e s h भ द ् र े श
b h a i s a h e b भ ा ई स ा ह ब
b h a t k e r a h i भ ट क े र ा ह ी
b h a t n i j u n c t i o n भ ट न ी ज ं क ् श न
b h a t t u भ ट ् ट ु
b h a v a l k a r भ व ा ल क र
b h e d i l u t e r a भ े द ी ल ु ट े र ा
b h e l भ े ल
b h i m g a r j a n a भ ी म ग र ् ज न ा
b h i t i w a l a भ ि ट ी व ा ल ा
b h u c h c h u भ ु च ् च ु
b i n d u s a r ब ि न ् द ु स र
b i r j u u s t a d ब ि र ज ू उ स ् त ा द
b i s h n a t h g a n j ब ि श न ा थ ग ं ज
b i t r a g u n t a ब ि त ् र ा ग ु ं ट ा
b k o f r a j a s t h a n ब ै ं क ऑ फ र ा ज स ् थ ा न
b l o c k i s l a n d ब ् ल ॉ क आ इ ल ै ं ड
b l o o m b e r g t o w e r ब ् ल ू म ब र ् ग ट ॉ व र
b o b w o o l m e r ब ॉ ब व ू ल ् म र
b o r d i ब ो र द ी
b o w d e n f o r t ब ो ड न फ ो र ् ट
b r e n d a n f r a s e r ब ् र े ं ड न फ ़ ् र े स ि र
b r i a n l u c k h u r s t ब ् र े न ल क ह र ् स ् ट
b r i a n m u r p h y ब ् र ा य न म र ् फ ी
b r i s t o l c h a n n e l ब ् र ि स ् ट ल च ै न ल
b r u c e e d g a r ब ् र ू स ए ग र
b r y a n t ब ् र ा य ं ट
b u d d h d e v ब ु द ् ध द े व
b u r n s ब र ् न ् स
b u r r e n ब र े न
b u x a r ब क ् स र
b u z d i l ब ु ज़ द ि ल
c a l l u m क ै ल म
c a l v a r y b a p t i s t क ् ल े व र ी ब ै प ट ि स ् ट
c a m b r i d g e s c h o o l , i n d i r a p u r a m क ै म ् ब ् र ि ज स ् क ू ल , इ ं द ि र ा प ु र म
c a r d i g a n क ा र ् ड ि ग न
c a r l o w क ा र ् ल ो
c a r n a t i c w a r क ा र ् न े ट ि क व ा र
c a r r क ा र
c a s t l e o f v i b o r g क ै स ल ऑ फ व ि ब ो र ् ग
c e r e b u s स े र े ब स
c e r e l i a स े र े ल ि य ा
c e r i s e स े र ी स
c h a k r a d h a r p u r च क ् र ध र प ु र
c h a k r a v a r t y r a j a g o p a l a c h a r i च क ् र व र ् त ी र ा ज ग ो प ा ल ा च ा र ी
c h a l a l a छ ल ा ल ा
c h a m a r a k a p u g e d e r a च ा म र ा क प ु ग े द े र ा
c h a m e l i च म े ल ी
c h a m r a u r a च म र ौ र ा
c h a n d a n च ं द न
c h a n d a n च न ् द न
c h a n d a n n a g a r च ं द न न ग र
c h a n d n i च ा ँ द न ी
c h a n d n i च ा ं द न ी
c h a n e t i च न े ट ी
c h a n g e z k h a n च ं ग े ज ़ ख ा न
c h a n g e z k h a n च ं ग े ज़ ख ा न
c h a r k h i d a d r i च र ख ी द ा द र ी
c h a r l o t क ा र ् ल ो ट
c h a s t i t y च े स ् ट ि ट ी
c h a t p a t i च ट प ट ी
c h e k o v च े क ॉ व
c h e n g च े ं ग
c h e r i च े र ी
c h h a p r a k a c h e r i छ प र ा क च े र ी
c h h a t w a l छ ट व ा ल
c h h a y a छ ा य ा
c h h o t a g u d h a छ ो ट ा ग ु ध ा
c h i d a m b a r च ि द म ् ब र
c h i f l e y t o w e r च ि फ ़ ् ल े ट ॉ व र
c h i n a t e l e c o m m u n i c a t i o n s च ा इ न ा ट े ल ी क म ् य ु न ि क े श ं स
c h i n n a m a l a i च ि न ् न ा म ल ा ई
c h i n n a r r e s e r v o i r च ि न ् न ा र र ि ज़ र व ा य र
c h i n t a m a n i s u r d a a s च ि ं त ा म ण ी स ू र द ा स
c h i r k e y च ि र क ी
c h i t a d h a n च ि त ध न
c h i t r a च ि त ् र ा
c h i t r a l i च ि त ् र ा ल ी
c h i t r a n i च ि त ् र ा ण ि
c h i t t a r r e s e r v o i r - 2 च ि त ् त र र ि ज़ र व ा य र - 2
c h o b e क ो ब े
c h o k i s o r a t h च ो क ी स ो र थ
c h o p r a च ो प ड़ ा
c h o r k e g h a r c h o r n i च ो र क े घ र च ो र न ी
c h u r c h o f t h e h a r v e s t च र ् च ऑ फ द ह ा र ् व े स ् ट
c i s c o स ि स ् क ो
c l a r e n c e क ् ल ा र े ं स
c l e a v a n t क ् ल ी व े ं ट
c o c a - c o l a i n d i a क ो क ा - क ो ल ा इ ं ड ि य ा
c o d y क ो ड ी
c o l l e g e g i r l क ॉ ल े ज ग र ् ल
c o m m e r z b a n k z e n t r a l e क ॉ म र ् ज ़ ब ै ं क ज ़ े न ट ् र ल े
c o r e t t a s c o t t k i n g a w a r d क ॉ र े ट ा स ् क ॉ ट क ि ं ग अ व ा र ् ड
c o s m o क ो स ् म ो
c o s t a r i c a क ो स ् ट ा र ि क ा
c r e a t i v e t e c h n o l o g y क ् र ि ए ट ि व ट े क ् न ो ल ॉ ज ी
c r e t e क ् र े ट
c r o c k e r क ् र ो क र
c u m m i n s i n d i a क ् य ू म ि ं स इ ं ड ि य ा
c u r t i s क र ् ट ि स
c u t t e r क ट र
c w e n स ् व े न
c y c l e w a l i स ा य क ल व ा ल ी
d a a t a द ा त ा
d a a t e द ा त े
d a d a द ा द ा
d a h a n a द ह न ा
d a i r e ड े य र
d a i r e द ै र े
d a i w a h o u s e i n d u s t r y ड ै व ा ह ा उ स इ ं ड स ् ट ् र ी
d a k u a u r j a w a n ड ा क ू औ र ज व ा न
d a k u m a n g a l s i n g h ड ा क ू म ं ग ल स ि ं ह
d a l t o n ड े ल ् ट न
d a l t o n g a n j ड ै ल ् ट न ग ं ज
d a m a n a n d d e e v द म न ए ण ् ड द ी व
d a m a s c u s द म ा स ् क स
d a m i e n m a r t y n ड े म ि न म ा र ् ट ि न
d a n c u l l e n ड ै न क ू ल न
d a n a p a n i द ा न ा प ा न ी
d a n g ड ं ग
d a n g o a p o s i ड ै ं ग ो आ प ो स ी
d a r b a r द र ब ा र
d a r r i n ड ै र ि न
d a r r y l b r o w n ड े र ि ल ब ् र ा उ न
d a r y a p u r द र ि य ा प ु र
d a s द ा स
d a y a द य ा
d a y a n a n d द य ा न न ् द
d a y i t a द य ि त ा
d a y s ड े ज
d e b u c h a u d u r y द े ब ू च ौ ध र ी
d e e n द ी न
d e e p d a s g u p t a द ी प द ा स ग ु प ् त ा
d e e p a k द ी प क
d e e p a n k a r द ी प ं क र
d e h a j द े ह ज
d e h r i o n s o n e द े ह र ी ऑ न स ो न े
d e l f i n a ड े ल ् फ ि न ा
d e r r o n ड े र ो न
d e s c a r t e s s y s t e m s g r o u p ड े स क ा र ् ट े स स ि स ् ट म ् स ग ् र ु प
d e s m o n d h a y n e s ड े स ् म ं ड ह े न ् स
d e v a y u s h द े व य श
d e v o n a ड े व ो न ा
d e v r a j द े व र ा ज
d e v t a द े व त ा
d h a m a n g a o n ध म न ग ा ं व
d h a n b a d ध न ब ा द
d h a n s i n d i ध ा न स ि ं ड ी
d h a r m a n a n d ध र ् म ा न न ् द
d h a r m p a l ध र ् म प ा ल
d h e k n e ढ े क ण े
d h o l a j u n c t i o n ध ो ल ा ज ं क ् श न
d h o l a k ढ ो ल क
d h r i t i ध ृ त ि
d h u n d ध ु ं द
d i d e r o t ड ि ड ो र ो ट
d i d r i k a ड ि ड ् र ि क ा
d i k s h a p a l द ि क ् ष प ा ल
d i l b h i t e r a h u m b h i t e r e द ि ल भ ी त े र ा ह म भ ी त े र े
d i l r u b a द ि ल र ु ब ा
d i n d a y a l द ी न द य ा ल
d i n o ड ी न ो
d i v y a b h a s k a r द ि व ् य भ ा स ् क र
d i w a n k h a v a t i द ि व ा न ख व ा त ी
d o b i g h a z a m e e n द ो ब ी घ ा ज़ म ी न
d o c h o r द ो च ो र
d o d i l o n k i d a s t a n द ो द ि ल ो ं क ी द ा स ् त ा ं
d o k a l i y a n द ो क ल ि य ा ँ
d o r a h a द ो र ा ह ा
d o c t o r s h a i t a n ड ॉ क ् ट र श ै त ा न
d o o j k a c h a n d द ू ज क ा च ा ँ द
d o o s r i s i t a द ू स र ी स ी त ा
d o r a h a द ो र ा ह ा
d o r i ड ो र ी
d o t ड ॉ ट
d o y e n ड ो ए न
d r e a d n o u g h t ड ् र े ड न ॉ ट
d r e w ड ् र य ू
d r e w ड ् र ि य ू
d u d h w a k h a r a द ु ध व ा ख र ा
d u l a l द ु ल ा ल
d u l h a b i k t a h a i द ु ल ् ह ा ब ि क त ा ह ै
d u l o n द ू ल ो ं
d u n c a n f l e t c h e r ड ं क न फ ् ल े च र
d u n i y a m e r i j e b m e i n द ु न ि य ा म े र ी ज े ब म े ं
d u n i y a d a r i द ु न ि य ा द ा र ी
d u r a u n d h a j u n c t i o n द ु र ौ ं ध ा ज ं क ् श न
d y a n ड ा य ए न
e a v a n इ व ा न
e c t e l ए क ् ट े ल
e d m u n d ए ड म ं ड
e d w a r d ए ड व र ् ड
e g g b u c k l a n d k e e p ए ग ब क ल ै ं ड क ी प
e i s n e r a w a r d s ई स ् न र अ व ा र ् ड ् स
e j a z ए ज ा ज़
e k b a a p c h h e b e t e ए क ब ा प छ ह ब े ट े
e k m a i n a u r e k t u ए क म ै ं औ र ए क त ू
e k s h o l a ए क श ो ल ा
e k a v a l i ए क ा व ल ी
e l e c t r o s t e e l इ ल े क ् ट ् र ो स ् ट ी ल
e l k h a r t ए ल ् क ह ा र ् ट
e l l e n ए ल े न
e m i r ए म ि र
e n e l ए न ल
e n y a ए न ् य ा
e r n a ए र ् न ा
e u s t a c i a य ू स ् ट े स ि य ा
e v a d n e इ व े ड न
f a ' a t e t e फ ा ट े ट
f a i z फ ै ज़
f a i z a b a d फ ़ ै ज ़ ा ब ा द
f a k h r u n n i s a फ ख र ु न ् न ि स ा
f a l e w a l फ ल े व ा ल
f a l l o n फ ै ल न
f a l n a फ ल न ा
f a r h a n a h फ र ह ा न ा ह
f a r h a t फ र ह त
f a r r a g u t फ ै र ा ग ट
f a r z k i j u n g फ र ् ज ़ क ी ज ं ग
f a t e h a b a d j u n c t i o n फ त े ह ा ब ा द ज ं क ् श न
f e d e r a l b a n k फ ़ े ड े र ल ब ै ं क
f e l i c i a फ े ल ि स ि य ा
f e l i s s h e l f फ ़ ि ल ी स श ् च े ल ् फ ी
f e l l फ े ल
f e r n फ र ् न
f i d e l e d w a r d s फ ि ड ल ए ड व र ् ड ् स
f i d e l i o फ ि ड े ल ि य ो
f i n e e n फ ि न ी न
f i n o l e x i n d u s t r i e s फ ़ ि न ो ल े क ् स इ ं ड स ् ट ् र ी ज ़
f i o n n u a l a फ ि य ो न ् य ू ए ल ा
f i r s t s e r v i c e c o r p o r a t i o n फ ़ र ् स ् ट स र ् व ि स क ॉ र ् प ो र े श न
f l o r i n a m u s e u m o f m o d e r n a r t फ ् ल ो र ि न ा म ् य ु ज़ ि य म ऑ फ म ॉ ड र ् न आ र ् ट
f l o r r i e फ ् ल ो र ी
f o r m i d a b l e फ ो र ् म ि ड े ब ल
f o r t e d m o n t o n फ ो र ् ट ए ड म ॉ न ् ट न
f o r t e l l i c e फ ो र ् ट ए ल ि स
f o r t m e i g s फ ो र ् ट म े ग ् स
f o r t m o n c k t o n फ ो र ् ट म ॉ न ् क ट न
f o r t m o r g a n फ ो र ् ट म ॉ र ् ग न
f o r t n a s c o p i e फ ो र ् ट न ै स ् क ो प ी
f o r t o p d e r u i g e n h o e k s e d i j k फ ो र ् ट ऑ प ड े र ु ग न ह ो ए क स े ड ि ज ् क
f o r t r o s s फ ो र ् ट र ॉ स
f o r t r o y a l फ ो र ् ट र ॉ य ल
f o r t v r e d e b u r g फ ो र ् ट व ् र े ड ब र ् ग
f o r t w e n t w o r t h फ ो र ् ट व े ं ट व र ् थ
f o r t z a c h a r y t a y l o r फ ो र ् ट ज ़ क र ी ट े ल र
f r e e s e a s फ ़ ् र ी स ी ज ़
f r u g फ ् र ग
f u j a i फ ु ज ा ई
g a a l i ग ा ल ी
g a b o n ग ा ब ो न
g a g a n ग ग न
g a j a v a a n ग ज व ा न
g a m a n ग म न
g a n d h i p e a c e p r i z e ग ा ं ध ी प ी स प ् र ा इ ज़
g a n g a g a n j ग ं ग ा ग ं ज
g a r e t h b r e e s e ग ै र े थ ब ् र ी स
g a r y r o b e r t s o n ग े र ी र ॉ ब र ् ट ् स न
g a u t a m i ग ौ त म ी
g a v a n ग ै व ा न
g a y ग ा य
g e e t a n j a l i ग ी त ा ं ज ल ि
g e n i c a ज े न ि क ा
g e o d e s i c ज ि य ो ड े स ि क
g e o f f a r n o l d ज ि ऑ फ आ र न ॉ ल ् ड
g e o r g i a ज ा र ् ज ि य ा
g e o r g i a ज ॉ र ् ज ि य ा
g e r m a i n e ज र ् म े न
g h a y a l घ ा य ल
g h a z i p u r c i t y ग ा ज़ ी प ु र स ि ट ी
g h o s u n d a घ ो स ु ं द ा
g i b b s b r o t h e r s m e d a l ग ि ब ् स ब ् र द र म े ड ल
g i l l ग ि ल
g i r g a l a ग ि र ग ा ल ा
g i r i n d r a ग ि र ी ं द ् र
g i r i p a t i ग ि र ि प त ि
g i r i r a a j ग ि र ि र ा ज
g i z i ग ि ज़ ी
g l o r i a ग ् ल ो र ि य ा
g l o r i o u s ग ् ल ो र ि य स
g o k u l k a r a j a ग ो क ु ल क ा र ा ज ा
g o l e ग ो ल े
g o l i a t h ग ो ल ि अ थ
g o o d r u m b a p t i s t ग ू ड र ु म ब ै प ट ि स ् ट
g o v i n d g a r h ग ो व ि ं द ग ढ ़
g r e a t b r i t a i n ग ् र े ट ब ् र ि ट े न
g r i f f i n ग ् र ि फ ि न
g r y t a ग ् र ी ट ा
g u a r a c h a ग ु आ र ा च ा
g u d d i ग ु ड ् ड ी
g u j i n d p o w e r ग ु ज र ा त इ ं ड प ॉ व र
g u l s a n o b a r ग ु ल स न ो ब र
g u m l a ग ु म ल ा
g u n a h ग ु न ा ह
g u n t u r j u n c t i o n ग ु ं ट ू र ज ं क ् श न
g u r j i t ग ु र ज ी त
g u r s h a r a n s i n g h ग ु र श र ण स ि ं ह
g u r u d w a r a b a u l i s a h i b ग ु र ू द ् व ा र ा ब ा उ ल ी स ा ह ि ब
g u r u d w a r a g u r u k e w a d a l i ग ु र ू द ् व ा र ा ग ु र ू क े व ड ा ल ी
g u r u d w a r a o m k a r e s h w a r ग ु र ू द ् व ा र ा ओ ं क ा र े श व र
g u r u d w a r a s a h i b d e w a ग ु र ू द ् व ा र ा स ा ह ि ब द े व ा
g u r u d w a r a t i k a n a s a h i b ग ु र ू द ् व ा र ा ट ि क ा ण ा स ा ह ि ब
g u r u v a y u r ग ु र ु व य ू र
g u s t a v o ग ु स ् त ा व ो
g y m n a s t i c s ज ि म न ा स ् ट ि क ् स
h a a s h i m ह ा श ि म
h a b i s ह ब ी स
h a f i z u r r a h m a n ह फ ि ज़ ु र र ह म ा न
h a f s ह फ ् स
h a l w a n i ह ल व ा न ी
h a m a j o l i ह म ज ो ल ी
h a m a r i k i s m a t ह म ा र ी क ि स ् म त
h a m n a h ह म ् न ा ह
h a r h a r m a h a d e v ह र ह र म ह ा द े व
h a r z ह ा र ् ज ़
h a s a n t h a f e r n a n d o ह स ा ं थ ा फ र ् न े ं ड ो
h a s i n a m a a n j a y e g i ह स ी न ा म ा न ज ा ए ग ी
h a t h o n k i l a k e e r ह ा थ ो ं क ी ल क ी र
h a t y a r e ह त ् य ा र े
h a y a h ह य ा ह
h e e r r a n j h a ह ी र र ा ं झ ा
h e i n e k e n ह े ं क े न
h e l l e j o e l o s m e n t ह े ल े ज ो ए ल ऑ स म े ं ट
h e l s i n k i ह े ल स ि ं क ी
h e n r y w i l l i a m s ह े न र ी व ि ल ि य म ् स
h i b b a a n ह ि ब ् ब न
h i d a y a t i n a y a t k h a n ह ि द ा य त इ न ा य त ख ा न
h i m a t s i n g k a s e i ह ि म त स ि ं ग क ा स ी
h i m m a t a u r m e h n a t ह ि म ् म त औ र म े ह न त
h i n d k a l a l ह ि ं द क ा ल ा ल
h i p h i p h u r r e y ह ि प ह ि प ह ु र ् र े
h i r a ह ी र ा
h i s t o r i c a l m u s e u m o f c r e t e ह ि स ् ट ॉ र ि क ल म ् य ु ज़ ि य म ऑ फ क ् र े ट
h o l i k a a ह ो ल ि क ा
h o o r - e - a r a b ह ू र - ए - अ र ब
h u m e k h a i n ह म ए क ह ै ं
h u m n a u j a w a n ह म न ौ ज व ा न
h u m r a h i ह म र ा ह ी
h u n t e r i a n m u s e u m a n d g a l l e r y ह ु ं ट े र ि य न म ् य ु ज़ ि य म ए ण ् ड ग ै ल र ी
h u t c h i s o n w h a m p o a ह च ि ं स न व ् ह े ं प ो आ
h w a n g e ह व ा ं ग े
i a n c a l l e n इ आ न क ै ल े न
i a n s m i t h इ आ न स ् म ि थ
i k r a m इ क र ा म
i l s e इ ल ् स ी
i n ' a m इ न आ म
i n d i k a d e s a r a m इ ं ड ि क ा ड े स ा र म
i n e s h इ न े श
i n g e r s o l l r a n d इ ं ग र स ॉ ल र ै ं ड
i n s a a f k i a w a z इ ं स ा फ क ी आ व ा ज ़
i n t e r n a t i o n a l c r o o k इ ं ट र न े श न ल क ् र ु क
i n t e r n a t i o n a l p a p e r इ ं ट र न े श न ल प े प र
i n t e r n e t i n i t i a t i v e j a p a n इ ं ट र न े ट इ न ी श ि ए ट ि व ज ा प ा न
i p h i g e n i e इ फ ि ज े न ी
i r e n e इ र े न े
i s a b e l l a इ स ा ब े ल ा
i s i k a n a a m d u n i y a h a i इ स ी क ा न ा म द ु न ि य ा ह ै
i t o y o k a d o इ त ो य ो क ा ड ो
i z h a a r इ ज ़ ह ा र
j a a n h a t h e l i p e ज ा न ह थ े ल ी प े
j a a n - e - w a f a ज ा न - ए - व फ ा
j a a n b a a z ज ा ँ ब ा ज ़
j a a y e n t o j a a y e n k a h a n ज ा ए ँ त ो ज ा ए ँ क ह ा ँ
j a c q u i ज ै क ी
j a d u ज ा द ू
j a g m o h a n ज ग म ो ह न
j a g r a n ज ा ग र ण
j a h a n g i r ज ह ा ँ ग ी र
j a h a z i l u t e r a ज ह ा ज़ ी ल ु ट े र ा
j a i d e e p ज य द ी प
j a i s a l m e r f o r t ज ै स ल म े र फ ो र ् ट
j a l e n d r ज ल े ं द ् र
j a m e s h o p e s ज े म ् स ह ो प ् स
j a m e s w h i t a k e r ज े म ् स व ् ह ि ट े क र
j a m m u a n d k a s h m i r ज म ् म ू ए ण ् ड क श ् म ी र
j a n e a n j a n e ज ा न े अ न ज ा न े
j a n i n a ज ै न ि न ा
j a s p e r ज ै स ् प र
j a u r e g u i b e r r y ज ॉ र ् ग ् य ू ब ै र ी
j a y a s h e k h a r ज य श े ख र
j a y e s h v a r ज य े श ् व र
j e e n e d o ज ी न े द ो
j e s s o p ज े स ॉ प
j e s s u p ज े स प
j e t - s k i i n g ज े ट - स ् क ी इ ं ग
j h e l u m झ े ल म
j i h a d ज ि ह ा द
j i h a n ज ि ह ा न
j i m c a r t e r ज ि म ी क ा र ् ट र
j o c e l i n ज ो स े ल ि न
j o d i d a r ज ो ड़ ी द ा र
j o h n e d r i c h ज ॉ न ए ड र ि क
j o h n f . k e n n e d y ज ॉ न ए फ . क े न े ड ी
j o h n p e n n ज ॉ न प े न
j o h n t h e b a p t i s t ज ॉ न द ब ै प ट ि स ् ट
j o s e p h i n e ज ो स फ ि न
j o y ज ॉ य
j u l i a ज ू ल ि य ा
j u l i u s s c i s s o r ज ु ल ि य स स ी ज र
j u n a i d z i a ज ु न ै द ज़ ि य ा
j u s t i n l a n g e r ज स ् ट ि न ल ै ं ग र
j y o t i b a p h u l e n a g a r ज ् य ो त ी ब ा फ ु ल े न ग र
k a a l e e c h a r a n क ा ल ी च र ण
k a a m n a क ा म न ा
k a f e e l क फ ी ल
k a f i l a क ा फ ि ल ा
k a g a क ा ग ा
k a i s e k a i s e l o g क ै स े क ै स े ल ो ग
k a l a d h a n d h a g o r e y l o g क ा ल ा ध ं ध ा ग ो र े ल ो ग
k a m e s h क ा म े श
k a n a k p r i y a क न क प ् र ि य ा
k a n d a r p a क न ् द र ् प
k a n t i क ा ं त ि
k a p i s t h a l a m क प ि स ् त ल ा म
k a p o o r क प ू र
k a r m y o g i क र ् म य ो ग ी
k a r t i k e y a क र ् त ि क े य
k a r u n a k a r क र ु ण ा क र
k a r u n a m a y i क र ु ण ा म य ी
k a s h i f a h क श ि फ ा ह
k a t e b क ा त ि ब
k a t h a क थ ा
k a t h i r a h क थ ि र ा ह
k a t i m a क ै ट ी म ा
k a u s h i k क ौ श ि क
k a w a b a t a y a s u n a r i p r i z e क ा व ा ब ा ट ा य स ु न ा र ी प ् र ा इ ज़
k d d i क ड ् ड ी
k e d a r n a t h क े द ा र न ा थ
k e e f e r क ी फ र
k e i t h s t a c k p o l e क ै थ स ् ट ै क प ो ल
k e l a v a r a p a l l i r e s e r v o i r क े ल ा व र ा प ल ् ल ी र ि ज़ र व ा य र
k e l v i n क े ल ् व ि न
k e n i l w o r t h क े न ि ल व र ् थ
k e s a r क े स र
k h a d a k w a s l a ख ड़ क व ा स ल ा
k h a f i d ख ा फ ि द
k h a h e r a ख ह े र ा
k h a l d a ख ा ल ड़ ा
k h a l i d a h ख ल ि द ा ह
k h a t t a m e e t h a ख ट ् ट ा म ी ठ ा
k h a t t d a ख ट ् ट ड़ ा
k h e l m o h a b b a t k a ख े ल म ो ह ब ् ब त क ा
k h i d k i ख ि ड़ क ी
k h o o n i s a y a ख ू न ी स ा य ा
k h u d d a r ख ु द ् द ा र
k h u s b a k h t ख ु श ब ख ् त
k h u w a y l a h ख ु व य ल ा ह
k h w a j a m i r d a r d ख ् व ा ज ा म ी र द र ् द
k i a n a क ि य ा न ा
k i n g g e o r g e ' s w a r क ि ं ग ज ॉ र ् ज ् स व ा र
k i n g p h i l i p ' s w a r क ि ं ग फ ि ल ि प ् स व ा र
k i r a y e d a r क ि र ा ए द ा र
k i r t i n a s h a क ी र ् त ि न ा श ा
k n u d क न ु द
k o n i g क ॉ न ि ग
k o t a क ो ट ा
k o t h e क ो ठ े
k r a t a a r a a m क ृ त ा र ा म
k r u g e r क ् र ू ग र
k u c h i p u d i क ु च ी प ु ड़ ी
k u d r a t क ु द र त
k u n t a l a क ु ं त ल ा
k u t h a r a i y a r r e s e r v o i r क ु थ ा र इ य र र ि ज़ र व ा य र
l a a l a m a n i ल ा ल म ण ि
l a d w a ल ा ड व ा
l a d y g o d i v a ल े ड ी ग ॉ ड ि व ा
l a h a r e n ल ह र े ं
l a h e r i l a l a ल ह र ी ल ा ल ा
l a k e n a k u r u ल े क न ा क ु र ु
l a k k h i s a r a i ल क ् ख ी स र ा य
l a n k e s h v a r ल ं क े श ् व र
l a v a d a ल व े ड ा
l a y a k ल ा य क
l e a r ल ी य र
l e i g h n a ल ै ग ़ न ा
l e i l a ल ी ल ा
l e o n a r d o d i c a p r i o ल ि य ो न ा र ् ड ो ड ी क ै प ् र ि य ो
l e o n o r a ल ि य ो न ो र ा
l e t h i a ल े थ ि य ा
l i c i a ल ि स ि य ा
l i l a c ल ि ल े क
l i o n a ल ि य ो न ा
l i v i n g s t o n e ल ि व ि ं ग स ् ट ो न
l i y a a k a t ल ि य ा क त
l o g i e a w a r d ल ॉ ग अ व ा र ् ड ् स
l o h o u ल ि ह ो ऊ
l o n d o n u n i v e r s i t y b u s i n e s s s c h o o l ल ं ड न य ू न ि व र ् स ि ट ी ब ि ज ़ न े स स ् क ू ल
l o u h a r a ल ौ ह ा र ा
l o u i e ल ु ई
l u c k y n u m b e r ल क ी न ं ब र
l u c y ल ् य ू स ी
m a a k a p y a r म ा ँ क ा प ् य ा र
m a a l a a k a a r म ा ल ा क ा र
m a a n a k a l a a l म ा ण क ल ा ल
m a a n i k म ा ण ि क
m a a n i k म ा न ि क
m a a w i म ा व ी
m a b e l म ब े ल
m a d a m z a p a t t a म ै ड म ज़ प ा ट ् ट ा
m a d a n a p a a l म द न प ा ल
m a d h u m a y म ध ु म य
m a g h a v a a j i t म घ व ा ज ि त
m a g n e s i u m म ै ग ् न ि श ि य म
m a h a s h a k t i m a a n म ह ा श क ् त ि म ा न
m a h a a r a a j a a म ह ा र ा ज ा
m a h a a y o g e e म ह ा य ो ग ी
m a h a d e v i म ह ा द े व ी
m a h a r a s h t r a म ह ा र ा ष ् ट ् र
m a h a s a t i t u l s i म ह ा स त ी त ु ल स ी
m a h i j u b a म ह ि ज ु ब ा
m a h i k a म ह ि क ा
m a h i r a म ह ि र ा
m a i k h a n a म ै ख ा न ा
m a i n h o o n j a d u g a r म ै ं ह ू ँ ज ा द ू ग र
m a i n a a म ै न ा
m a i n e j e e n a s e e k h l i y a म ै ं न े ज ी न ा स ी ख ल ि य ा
m a k e n n a म क े न ् न ा
m a k h a n i म ख ा न ी
m a k k a d म क ् क ड़
m a l a म ा ल ा
m a l c o l m म ा ल ् क म
m a l c o l m म ॅ ल क ॉ ल ् म
m a l c o l m j a r v i s म ै ल ् क म ज र ् व ि स
m a l i k a म ल ि क ा
m a n i n d u s t r i e s म ह ि ं द ् र ा इ ं ड स ् ट ् र ी ज ़
m a n o f t h e y e a r / p e r s o n o f t h e y e a r म ै न ऑ फ द ई य र / प र ् स न ऑ फ द ई य र
m a n a p o o l s म ा न ा प ू ल ् स
m a n d a k i n i म न ् द ा क ि न ी
m a n d i r म ं द ि र
m a n i s h म न ी ष
m a n j u s h a म ं ज ू ष ा
m a n n c u p म ा न क प
m a n o h a r म न ो ह र
m a n o r a n j a n म न ो र ं ज न
m a n z a n a म ं ज ़ ा न ा
m a p u t o म े प ट ो
m a r i l e e म ै र ि ल ी
m a r i s म ै र ि स
m a r k b u r g e s s म ा र ् क ब र ् ग े स
m a r k t w a i n म ा र ् क ट ् व े न
m a r k w a u g h म ा र ् क व ॉ
m a s t e r j i म ा स ् ट र ज ी
m a s u d म स ू द
m a t h e w s i n c l a i r म ै थ ् य ू स ि न क ् ल े य र
m a t o n d k a r म ा त ो ं ड क र
m a t t h e w e l l i o t t म ै थ ् य ू इ ल ि य ो ट
m a t w a l e म त व ा ल े
m a u r i z i o म ौ र ि ज़ ि ओ
m a w e n g e m w e n a म व े ं ज ी म ् व े न ा
m a x i n d i a म ै क ् स इ ं ड ि य ा
m a y s a r a h म य ् य स र ह
m a y u r म य ू र
m c k i l e म ै क क ि ल े
m e d a l s o f h o n o r म े ड ल ् स ऑ फ ऑ न र
m e d h a a v i n e e म े ध ा व ि न ी
m e e t o n e g r e e t o n e म ी ट व न ग ् र ी ट व न
m e h a n d i l a g i m e r e h a a t h म े ह ँ द ी ल ग ी म े र े ह ा थ
m e k h a l i n म े ख ल ि न
m e l b r o o k s म ॅ ल ब ् र ु क ् स
m e l b a म े ल ् ब ा
m e m d i d i म े म द ी द ी
m e n a r a t e l e k o m h e a d q u a r t e r s म े न र ा ट े ल ी क ॉ म ह े ड क ् व ा र ् ट र ् स
m e n d h e म े ं ढ े
m e r a y a a r m e r a d u s h m a n म े र ा य ा र म े र ा द ु श ् म न
m e r i b i w i k i s h a a d i म े र ी ब ी व ी क ी श ा द ी
m e r i z u b a a n म े र ी ज ़ ु ब ा न
m e r u b e t i r i म े र ु ब े त ि र ी
m i a n m i r म ि ल न म ी र
m i c h e l i n म ि श े ल ि न
m i k e v e l e t t a म ा इ क व े ल े ट ा
m i l t o n s m a l l म ि ल ् ट न स ् म ॉ ल
m i l u n म ि ल न
m i m i म ि म ी
m i r z a p u r म ि र ् ज ़ ा प ु र
m i s s g o o d n i g h t म ि स ग ु ड न ा इ ट
m o h a b b a t a u r j u n g म ो ह ब ् ब त औ र ज ं ग
m o h i n i a t a m म ो ह ि न ी अ ट ् ट म
m o h n i s h म ो ह न ी श
m o o n s i l v e r म ू न स ि ल ् व र
m o s c o w म ॉ स ् क ो
m o s t v a l u a b l e p l a y e r a w a r d म ो स ् ट व ै ल ् य ु ए ब ल प ् ल े य र अ व ा र ् ड
m o t i m a h a l म ो त ी म ह ल
m o u n t a b u म ा उ ं ट आ ब ू
m r i g e n d r a म ृ ग े ं द ् र
m u ' a l l a म ु अ ल ् ल ा
m u ' a w i y a h म ु आ व ि य ा ह
m u b a r a k म ु ब ा र क
m u b i n म ु ब ी न
m u d a s s a r n a z a r म ु द स ् स र न ा ज़ र
m u h r i z म ु ह र ि ज़
m u j a f f a r n a g a r म ु ज ़ फ ़ ् फ ़ र न ग र
m u k h a d a a म ु ख ड ़ ा
m u k t a a p r a s u म ु क ् त ा प ् र स ु
m u k t i म ु क ् त ि
m u l e म ु ल े
m u n i c i p a l g a l l e r y o f p i r a e u s म ् य ु न ि स ि प ल ग ै ल र ी ऑ फ प ा य र स
m u n i c i p a l g a l l e r y o f r h o d e s म ् य ु न ि स ि प ल ग ै ल र ी ऑ फ र ो ड ् स
m u r a l i म ु र ल ी
m u r a l i d h a r म ु र ल ी ध र
m u r s h i d a b a d म ु र ् श ि द ा ब ा द
m u t a t k a r म ु ट ा ट क र
m y r o n म ा य र ॉ न
n a a g c h a m p a न ा ग च ं प ा
n a b i g h न ब ि घ
n a f r a t k i a n d h i न फ र त क ी आ ँ ध ी
n a g a s a k i u n i v e r s i t y न ा ग ा स ा क ी य ू न ि व र ् स ि ट ी
n a i b न ै ब
n a j d a h न ज ् द ा
n a k h r e न ख र े
n a l d u r g न ल द ु र ् ग
n a m n o n न ॅ म न ॉ न
n a m a n न म न
n a r n a r a y a n न र न ा र ा य ण
n a r r a g a n s e t t न ॅ र ा ग न स े ट
n a s h i t न ा श ि त
n a s i r न ा स ि र
n a s p e r s l i m i t e d न ै स ् प र ् स ल ि म ि ट े ड
n a s r न स ् र
n a t a l i c o l e न त ा ल ी क ो ल
n a t h a n a s t l e न ै थ न ए स ् ल े
n a t h a n h a u r i t z न ा थ न ह ॉ र ि ट ् ज़
n a t i o n a l m u s e u m o f c h i n a न े श न ल म ् य ु ज़ ि य म ऑ फ च ा इ न ा
n a t i o n a l p a r k s o f b r a z i l न े श न ल प ा र ् क ् स ऑ फ ब ् र ा ज ़ ी ल
n a t i o n a l r o y a l m u s e u m o f s c o t l a n d न े श न ल र ॉ य ल म ् य ु ज़ ि य म ऑ फ स ् क ॉ ट ल ै ं ड
n a v e e n a न व ी न ा
n a z n e e n न ा ज़ न ी ं
n e e l a d r i न ी ल ा द ् र ि
n e n e न े न े
n e t h e r l a n d s न ी द र ल ै ं ड ् स
n e w m u s e u m o f c o n t e m p o r a r y a r t न ् य ू म ् य ु ज़ ि य म ऑ फ क ं ट े म ् प र र ी आ र ् ट
n e w b e r y m e d a l न ् य ू ब े र ी म े ड ल
n i l e e n न ि ल ी न
n o b e l i u m न ॉ ब े ल ि य म
n u r a n i न ु र ा न ी
o a m r a ओ आ म र ा
o c t a v i o ओ क ् ट ा व ि ओ
o l d r o m a n ओ ल ् ड र ो म न
o l i v i a ओ ल ि व ि य ा
o m a r ओ म ा र
o m p r a k a s h ओ म प ् र क ा श
o r d e r o f c h r i s t ऑ ड र ऑ फ क ् र ा इ स ् ट
o r d e r o f i n d u s t r i a l m e r i t ऑ ड र ऑ फ इ ं ड स ् ट ् र ि य ल म े र ि ट
o r d e r o f s i k a t u n a ऑ ड र ऑ फ स ि क ा ट ु न ा
o r d e r o f t h e l i o n o f f i n l a n d ऑ ड र ऑ फ द ल ा य न ऑ फ फ ि न ल ै ं ड
o r d e r o f w i l l i a m ऑ ड र ऑ फ़ व ि ल ि य म
o r d e r o r l a b i a l e g o ऑ ड र ऑ र ् ल ा ब ा य ल े ग ो
o r e ओ र
o r e ओ र े
o r i e n t a l h o t e l s ओ र ि ए ं ट ल ह ो ट ल ् स
o v a ओ व ा
o z a r k h e d d a m ओ ज़ र ख े द ड ै म
p a a p k i k a m a i प ा प क ी क म ा ई
p a h a d i k a n y a प ह ा ड़ ी क न ् य ा
p a k d a m a n प ा क द ा म न
p a m e l i a प ा म े ल ि य ा
p a n n a प न ् न ा
p a r a g u a y प र ा ग ् व े
p a r a g u a y a n h a r p प ै र ा ग ु ए न ह ा र ् प
p a r a k r a m प र ा क ् र म
p a r a m e s h t h i n प र म े ष ् ठ ि न
p a r a s m h a m b r e y प ा र स म ् ह ा ं ब ् र े
p a r e e प र ी
p a r e e k s h a प र ी क ् ष ा
p a r e s h प र े श
p a r i s प े र ि स
p a s s i n g s h o w प ा स ि ं ग श ो
p a t i p a r m e s h w a r प त ि प र म े श ् व र
p a t r a l e k h a प त ् र ल े ख ा
p a t t h a r o n k a s a u d a g a r प त ् थ र ो ं क ा स ौ द ा ग र
p a t t y प ै ट ी
p a u l s h e a h a n प ॉ ल श ी ह न
p a u l v r e l l i s g r e e k h i s t o r y m u s e u m प ॉ ल व ् र े ल ि स ग ् र ी क ह ि स ् ट ् र ी म ् य ु ज़ ि य म
p a u l a प ौ ल ा
p a w a n प व न
p e a c h t r e e w a r प ी च ट ् र ी व ा र
p e e t a a प ी त ा
p e l a g i a प े ल ा ग ि य ा
p e r i n o v e r प े र ी न ओ व र
p e t e r c o m a n प ी ट र क ॉ म े न
p e t e r m a r t i n प ी ट र म ा र ् ट ि न
p h i l e d m o n d s फ ि ल ए ड म ं ड ् स
p h o e n i x फ ी न ि क ् स
p i e t e r s t r y d o m प ी ट र स ् ट ् र ा ए ड म
p i g g o t t प ि ग ो ट
p i l a n i प ि ल ा न ी
p i t a m b a r प ि त ा म ् ब र
p i y a l i प ि य ा ल ी
p l a i n f i e l d b i b l e प ् ल े न फ ि ल ् ड ब ा य ब ल
p o l a r m u s i c p r i z e प ो ल र म ् य ु ज़ ि क प ् र ा इ ज़
p o o r a n प ू र ण
p o s c o प ॉ स ् क ो
p o s c o प ो स ् क ो
p r a b h j i t प ् र भ ज ी त
p r a b i r प ् र ब ी र
p r a n a t i प ् र ण त ि
p r a s h a n s a प ् र श ं स ा
p r a t o s h प ् र त ो श
p r e e t प ् र ी त
p r e m j a a l प ् र े म ज ा ल
p r e m k i d e v i प ् र े म क ी द े व ी
p r e m p u j a r i प ् र े म प ु ज ा र ी
p r e t v a m प ् र ी त व म
p r e u s s e n प ् र ू स े न
p r i n c e s s प ् र ि ं स े स
p r o - f i n l a n d i a m e d a l प ् र ो - फ ि न ल ै ं ड ि य ा म े ड ल
p r o k o f i e v प ् र ो क ो फ ी व
p u g r e e प ग ड़ ी
p u j a r i प ु ज ा र ी
p u l i t z e r p r i z e प ु ल ि ट ज़ र प ् र ा इ ज़
p u n a r m i l a n प ु न र म ि ल न
p u n j a b i प ं ज ा ब ी
p u r u s प ् य ु र स
p u s h k a r प ु ष ् क र
p u s h p a n j a l i प ु ष ् प ा ं ज ल ि
p u s h p a n j a l i प ु ष ् प ा ं ज ल ी
p y a a s i a n k h e n प ् य ा स ी आ ँ ख े ं
p y a r k a r i s h t a प ् य ा र क ा र ि श ् त ा
p y a r k a r k e d e k h o प ् य ा र क र क े द े ख ो
p y a r k i d a s t a n प ् य ा र क ी द ा स ् त ा ं
q a i d i क ै द ी
r a a h i b a d a l g a y e र ा ह ी ब द ल ग ए
r a a j a m a n i र ा ज म ण ि
r a a m a t e k e र ा म ट े क े
r a a n c h i र ा ं च ी
r a a s h i र ा श ि
r a d e t z k y र ै ड ज ़ ् क ी
r a d h i k a र ा ध ि क ा
r a g h u v a n s h र घ ु व ं श
r a i n c a l c i n i n g र े न क ै ल ् स ि ं इ ं ग
r a j l a x m i र ा ज ल क ् ष ् म ी
r a j n a r t a k i र ा ज न र ् त क ी
r a j i n s a l e h र ा ज ि न स ा ल े ह
r a j m u k u t र ा ज म ु क ु ट
r a m a v t a r र ा म अ व त ा र
r a m a y a n a र ा म ा य ण
r a n d र े ं ड
r a n g a a u r r a j a र ं ग ा औ र र ा ज ा
r a n g e e n k a h a n i र ं ग ी न क ह ा न ी
r a n g n a t h a r र ं ग न ा थ ा र
r a n i a u r j a n i र ा न ी औ र ज ा न ी
r a o s a h e b र ा व स ा ह ब
r a s t e a u r m a n z i l र ा स ् त े औ र म ं ज़ ि ल
r a t n a b a l i र त ् न ब ा ल ी
r a t n a p r a b h a र त ् न प ् र भ ा
r a t t u र त ् त ु
r a v i r a t n a y e k e र व ि र त ् न ा य क े
r a y i l l i n g w o r t h र े इ ल ि ं ग व र ् थ
r a y i l l i n g w o r t h र े इ ल ि ं ग व ॉ र ् थ
r e a d र ी ड
r e g h e र े ग े
r e n a i s s a n c e t o w e r र े न े स ा न ् स ट ॉ व र
r e n e e र े न ी
r e q u i n t o र े क ् व ि ं ट ो
r e s h a m k i d o r i र े श म क ी ड ो र ी
r e s h m a a u r s h e r a र े श ् म ा औ र श े र ा
r e y k j a v i k र ि क ज ़ व ि क
r i c h a r d p e t r i e र ि च र ् ड प े ट ् र ी
r i s h i y a k e t u ऋ ष ि य क े त ु
r o b e r t k e y र ॉ ब र ् ट क ी
r o c c o र ो क ो
r o c h a k र ो च क
r o c k b r i d g e र ॉ क ब ् र ि ज
r o c k b r o o k u n i t e d र ॉ क ब ् र ु क य ू न ा इ ट े ड म े थ ो ड ि स ् ट
r o h a n l a l र ो ह न ल ा ल
r o m a n t i c i n d i a र ो म ा ं ट ि क इ ं ड ि य ा
r o m e s h b h a n d a r i र ो म े श भ ं ड ा र ी
r o t i k a p a d a a u r m a k a n र ो ट ी क प ड़ ा औ र म क ा न
r o w i n g र ो इ ं ग
r o y र ॉ य
r o z a l i a र ो ज़ ा ल ि य ा
r u h a n i र ु ह ा न ी
r u p a s h r i र ू प श ् र ी
r u p n a g a r र ु प न ग र
r u s s e l a r n o l d र ु स ् स े ल आ र न ॉ ल ् ड
r y u g y o n g h o t e l य ु ं ग य ो ं ग ह ो ट े ल
s a a k s h i स ा क ् ष ी
s a b a p r i z e स ब ा प ् र ा इ ज़
s a b e e h स ब ी ह
s a b h y स भ ् य
s a b i n a स ब ी न ा
s a d h n a स ा ध न ा
s a e e d a z a d स ई द आ ज़ ा द
s a h i l स ा ह ि ल
s a i f u n s e m i c o n d u c t o r s स े फ ़ न स े म ी क ं ड क ् ट र ् स
s a i n t l o u i s स े ं ट ल ु इ स
s a i n t x a v i e r s ' s s c h o o l , c h a n d i g a r h स े ं ट ज ़ े व ि य र ् स स ् क ू ल , च ं ड ी ग ढ ़
s a j i d a l i स ा ज ि द अ ल ी
s a k h a r o v p r i z e स ख ा र ो व प ् र ा इ ज़
s a l a d i n स ल ा द ि न
s a l a h स ा ल े ह
s a l e e m j a f f a r स ल ी म ज ा फ र
s a l e e m a h स ल ी म ा ह
s a m a r a h स म र ा ह
s a m a r e n d u स म र े ं द ु
s a m a r p a n स म र ् प ण
s a m a s y a स म स ् य ा
s a m i स ा म ी
s a m l e s h w a r स ् य ा म ल े श ् व र
s a m r a n स ा म र न
s a n m a r t i n o स ै न म ा र ् ट ि न ो
s a n b o r n स ै न ब ॉ र ् न
s a n d u r i स ं द ू र ी
s a n g r u r स ं ग र ु र
s a n y u k t a स ं य ु क ् त ा
s a r n a स र न ा
s a r o j a n i स र ो ज न ी
s a t y a n a r a y a n स त ् य न ा र ा य ण
s a u s a a l b a a d स ौ स ा ल ब ा द
s a u t e l a b h a i स ौ त े ल ा ब े ट ा
s a v y a s a a c h e e स व ् य स ा च ी
s a w a n स ा व न
s c h i l l e r p r i z e श ि ल र प ् र ा इ ज़
s e a o f t h e h e b r i d e s स ी ऑ फ ह र ब ् र ि ड ् स
s e e t a a s a r a n स ी त ा स र न
s e l e n i u m स े ल े न ि य म
s e l k i r k स े ल क ् र ि क
s e m g r o u p स े म ग ् र ु प
s e v i e r स े व ि य र
s h a a d a a b श ा द ा ब
s h a a r a n g i k a a श ा र ं ग ि क ा
s h a b b e e r श ब ् ब ी र
s h a b b i r a h m e d श ब ् ब ी र अ ह म द
s h a c h e e श च ी
s h a c h i श च ि
s h a f i u d d i n a h m e d श फ ी उ द ् द ी न अ ह म द
s h a h a b d u l l a t i f b h i t t a i श ा ह अ ब ् द ु ल ल त ी फ भ ि ट ् ट ा ई
s h a h e e d u r r a h m a n श ह ी द ु र र ह म ा न
s h a h r i a r n a f e e s श ह र ि य ा र न फ ी स
s h a k e e l k h a n श क ी ल ख ा न
s h a k t i श क ् त ि
s h a m a a श म ा
s h a m a s h a a d श म श ा द
s h a n श ा न
s h a n g h a i b a o s t e e l g r o u p श ं घ ा ई ब ा ओ स ् ट ी ल ग ् र ु प
s h a r a a b i श र ा ब ी
s h a t a d r u श त द ् र ु
s h a u k e e n श ौ क ी न
s h a u n t a i t श ॉ न ट ै ट
s h a w w a l l a c e श ॉ व ै ल े स
s h e i k h s a i d श े ख स ई द
s h e i k h s h e b e l i श े ख़ श ब े ल ी
s h e n d a y e श े ं ड य े
s h e r i s e श े र ी ज
s h e v g a o n k a r श े व ग ा ँ व क र
s h i k a r p u r i श ि क ा र प ु र ी
s h i v l e e l a श ि व ल ी ल ा
s h i v n e k a r श ि व ण े क र
s h o a i b a k h t a r श ो ए ब ख ा न
s h o b h i t a श ो भ ि त ा
s h o l a y a r r e s e r v o i r श ो ल ा य र र ि ज़ र व ा य र
s h o t p u t श ॉ ट प ु ट
s h r e e l a श ् र ी ल ा
s h r i m a n s a t y a w a d i श ् र ी म ा न स त ् य व ा द ी
s h r i n i v a s श ् र ी न ि व ा स
s h w e t a श ् व े त ा
s i g o u r n e y w e a v e r स ि र ् ग ो न ी व ि व र
s i l a स ि ल ा
s i m a k स ि म क
s i m e o n स ि म े ओ न
s i m o n d o u l l स ा इ म न ड ॉ ल
s i s k i y o u स ि स ् क ि य ो
s i t a m g a r स ि त म ग र
s i w a r स ि व ा र
s k i r r o w स ् क ि र ॉ
s l o w m a n स ् ल ो म े न
s o l a h s a t r a स ो ल ह स त ् र ह
s o m b r e स ो म ् ब ् र े
s o m k a a n t a a स ो म क ा ं त ा
s o o r a j स ू र ज
s o u t h a r l i n g t o n c h u r c h o f c h r i s t स ा उ थ अ र ् ल ि ं ग ् ट न
s o u t h s e m i n o l e b a p t i s t स ा उ थ स े म ी न ो ल ब ै प ट ि स ् ट
s p a n i s h w a l t z स ् प ै न ि श व ा ल ् ट ् ज
s p e n c e r स ् प े न ् स र
s t a n स ् ट ै न
s t a n l e y f o r t स ् ट ै न ल े फ ो र ् ट
s t e i n f e l d c u p स ् ट े न फ ी ल ् ड क प
s t e v e s m i t h स ् ट ी व स ् म ि थ
s t e v e n h a w k i n g स ् ट ी व न ह ॉ क ि ं ग
s t e w स ् ट ी व
s t i l l m a n स ् ट ि ल म ै न
s t u a r t m a t s i k e n y e r i स ् ट ु अ र ् ट म ै ट स ि क े न ् य े र ी
s u c h i स ु च ि
s u g a t e e y स ु ग त ी य
s u h e e r a स ु ह ी र ा
s u l f u r स ल ् फ र
s u m a n a स ु म न
s u m i t o m o स ु म ि ट ो म ो
s u m i t o m o स ु म ि त ो म ो
s u m m a y y a h स ु म े य ् य ा ह
s u m t e r स म ् ट र
s u v a r n a स ु व र ् ण ा
s w a r o o p a a स ् व र ू प ा
s y d n e y स ि ड न ी
s y e d a k h t a r i m a m q u a d r i स य ् य द अ ख ् त र इ म ा म क़ ा द र ी
s y l v a n a स ि ल ् व े न ा
s y n g e n t a स ि न ् ज े ं ट ा
t a a n त ा न
t a c i t a ट े स ि ट ा
t a c y ट े स ी
t a h i r k h a n त ा ह ि र ख ा न
t a k e d a a w a r d ट क े ड ा अ व ा र ् ड
t a k i u d d e e n त क ि उ द ् द ी न
t a l h a h त ल ह ा ह
t a l w a d a त ल व ा ड़ ा
t a m a c a n n i n g ट ा म ा क ै न ि ं ग
t a m e e m a h त म ी म ा ह
t a p a n त प न
t a r u l a t a त र ु ल त ा
t a r u n a त र ु ण ा
t a t e g a l l e r y ट े ट ग ै ल र ी
t a w q e e r त ौ क ी र
t e j a s w i त े ज स ् व ी
t e r e m e r e e b e e c h m e i n त े र े म े र े ब ी च म े ं
t e r r y a l d e r m a n ट े र ी ए ल ् ड र म ै न
t h a k u r ठ ा क ु र
t h a t t e थ त ् त े
t h e a f t e r n o o n द आ फ ् ट र न ू न
t h e b r i t i s h s c h o o l , n e w d e l h i द ब ् र ि ट ि श स ् क ू ल , न ् य ू ड े ल ् ह ी
t h e h i n d u द ह ि न ् द ू
t h e l i v i n g w e l l u n i t e d m e t h o d i s t द ल ि व ि ं ग व े ल य ू न ा इ ट े ड म े थ ो ड ि स ् ट
t h e o d o r a थ ि य ो ड ो र ा
t h e o d o r e d r e i s e r थ ि य ो ड ो र ड ् र े ज ़ र
t h r a c i a n थ ् र ा स ि य न
t h r o g s n e c k थ ् र ॉ ग ् ज न े क
t h u r i n g e n थ र ि ं ग न
t i j u c a त ि ज ु क ा
t i r u p p a r a m k u n r a m त ि र ु प ् प र ा म ् क ु ं र म
t i t a n i a ट ि ट ा न ि य ा
t o m ट ौ म
t o m m y h i l f i g e r ट ॉ म ी ह ि ल ् फ ़ ि ज ़ र
t o n g a n o x i e c h r i s t i a n ट ा ँ ग न ॉ क ् स ी क ् र ि श ् च ि य न
t o r a n त ो र न
t o s h i b a त ो श ि ब ा
t r a c k a n d f i e l d ट ् र ै क ए ण ् ड फ ी ल ् ड
t r a v i s b a p t i s t ट ् र ॅ व ि स ब ै प ट ि स ् ट
t r e n t o n ट ् र े ं ट न
t u d o r ट ् य ू ड र
t u l a ट ु ल ा
t u m u c u m a q u e त ु म ु क ु म ा क
t u r n e r p r i z e ट र ् न र प ् र ा इ ज़
t u t e j a ट ु ट े ज ा
u d i t i उ द ि त ि
u k u l e l e य ु क ु ल े ल े
u l f a h उ ल ् फ ा ह
u n i c h e m l a b s य ु न ि क े म ल ै ब ् स
u n i v e r s i t y o f c a n b e r r a य ू न ि व र ् स ि ट ी ऑ फ क ै न ब े र ा
u n i v e r s i t y o f c o l o r a d o य ू न ि व र ् स ि ट ी ऑ फ क ो ल ो र ै ड ो
u n i v e r s i t y o f k e e l e य ू न ि व र ् स ि ट ी ऑ फ क ी ल े
u n i v e r s i t y o f n e v a d a य ू न ि व र ् स ि ट ी ऑ फ न े व ा ड ा
u n i v e r s i t y o f n o t r e d a m e य ू न ि व र ् स ि ट ी ऑ फ न ो ट र ड े म
u n i v e r s i t y o f p o r t s m o u t h य ू न ि व र ् स ि ट ी ऑ फ प ो र ् ट ् स म ा उ थ
u n i v e r s i t y o f s h e f f i e l d य ू न ि व र ् स ि ट ी ऑ फ श े फ फ ी ल ् ड
u n i v e r s i t y o f s u s s e x य ू न ि व र ् स ि ट ी ऑ फ स ु स े क ् स
u r b a n a अ र ब ा न ा
u r v i उ र ् व ि
u s m a n d a n f o d i o उ स ् म ा न द ा न फ ो ड ि य ो
u t p a l c h a t t e r j e e उ त ् प ल च ै ट र ् ज ी
v a a d i t a a व ा द ि त ा
v a a m a n व ा म न
v a d a n व द न
v a i b h a v e e व ै भ व ी
v a j r a व ज ् र
v a l m a i व ल ् म ा ई
v a n a m a l a व न म ा ल ा
v a n s h a v a r d h a n व ं श व र ् ध न
v a r i व ा र ी
v e s t e c o b u r g व े स ् ट क ॉ ब र ् ग
v e t r a v a t i व े त ् र व त ी
v i d o r व ि ड ो र
v i d u t h a l a i व ि द ु थ ल ई
v i d w a n s व ि द ् व ा ं स
v i j a y b h a r a d w a j व ि ज य भ ा र द ् व ा ज
v i l m a r i s व ि ल ् म े र ि स
v i n c h u r k a r व ि ं च ु र क र
v i n y a व ि न य ा
v i r a t व ि र त
v i r g o व र ् ग ो
v i s h v a a m i t r व ि श ् व ा म ि त ् र
v i s h w a व ि श ् व
v i s i s h t s e v a m e d a l व ि श ि ष ् ट स े व ा म े ड ल
v i v e n d i u n i v e r s a l व ि व े ं द ी य ू न ि व र ् स ल
v y o m e s h व ् य ो म े श
w a h e e d a व ह ी द ा
w a h e m व ह म
w a l d e m a r व ा ल ् ड े म र
w a l k e r m u s e u m व ॉ क र म ् य ु ज़ ि य म
w a l l a c e व ै ल े स
w a l m i k i व ा ल ् म ी क ि
w a l t e r s c o t t व ॉ ल ् ट र स ् क ॉ ट
w a r o f t h e r e u n i o n s व ा र ऑ फ द र ी य ू न ि य ं स
w a t e r p o l o व ा ट र प ो ल ो
w e s t c o a s t s w i n g व े स ् ट क ो स ् ट स ् व ि ं ग
w e s t s a r g u j a व े स ् ट स र ग ु ज ा
w h e e l c h a i r b a s k e t b a l l व ् ह ी ल च े य र ब ा स ् क े ट ब ॉ ल
w i l l i a m i t e w a r i n i r e l a n d व ि ल ि य ा म ा इ ट व ा र इ न आ य र ल ै ं ड
w i l s o n c a s t l e व ि ल ् स न क ॅ स ल
w o h d i n a a y e g a व ो द ि न आ ए ग ा
w o h i b h a y a n a k r a a t व ह ी भ य ा न क र ा त
w o n व ॉ न
w o o d b u f f a l o व ू ड ब फ े ल ो
w o o d s t o c k h i s t o r i c a l s o c i e t y व ु ड स ् ट ॉ क ह ि स ् ट ॉ र ि क ल स ो स ा य ट ी
w o r l d w i d e व र ् ल ् ड व ा इ ड
x e n o p h o n ज ़ े न ो फ ो न
y a b l o n o i य ा ब ् ल ो न ो ई
y a h a n w a h a n य ह ा ँ व ह ा ँ
y a s h o d h a n य श ो ध न
y a s m i n य ा स ् म ि न
y e h w o h m a n z i l t o n a h i n य े व ो म ं ज ़ ि ल त ो न ह ी ं
y e l d a r i य े ल ् द ा र ी
y o g e s h v a r e e य ो ग े श ् व र ी
y v e s व े स
z a d a ज़ ै द ा
z a i r a h ज़ ै र ा ह
z i n d a g a n i ज ़ ि ं द ग ा न ी
z u n h e b o t o ज ु न ् ह े ब ो ट ो
|
96477bb4d47f283ce546ef453c83fe137743d5f4 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1553/CH33/EX33.1/33Ex1.sce | 99ac60a15dc1f563567478722b3f2547cb0a70ba | [] | 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 | 560 | sce | 33Ex1.sce | //Chapter 33 Ex 1
clc;
clear;
close;
facevalue=6000; rate=10/100;
//calculating unexpired time, 26 days (october 31-october 5)+30 days (november)+ 17 days (december)
unexpiredTime=1/5; //converting 73 days into years
bd=facevalue*unexpiredTime*rate; //banker's discount
td=bd/(1+(unexpiredTime*rate)); //true discount
bg=bd-td; //banker's gain
money=facevalue-bd;
mprintf("The bankers discount is Rs.%.0f\n The true discount is Rs.%.2f\n The bankers gain is Rs.%.2f\n The money received by holder of bill is Rs.%.0f",bd,td,bg,money);
|
1222ccab2ed402b1a2ef8cf228c2112f31cceefd | 8217f7986187902617ad1bf89cb789618a90dd0a | /browsable_source/2.5/Unix-Windows/scilab-2.5/tests/examples/interpln.man.tst | 0cb22cee1accb467eb8d8ce769843ddccc6d362e | [
"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 | 159 | tst | interpln.man.tst | clear;lines(0);
x=[1 10 20 30 40];
y=[1 30 -10 20 40];
plot2d(x',y',[-3],"011"," ",[-10,-40,50,50]);
yi=interpln([x;y],-4:45);
plot2d((-4:45)',yi',[3],"000");
|
c21cb214efaf04a74b0ff93ce9b2cbaa156b493c | 449d555969bfd7befe906877abab098c6e63a0e8 | /1199/CH6/EX6.9/6_9.sci | a58b069f167baa6928d6fd921954a0098da3ed6b | [] | 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 | 293 | sci | 6_9.sci | // 6.9
clc;
e=1.6*10^-19;
Ea=2000;
m=9.1*10^-31;
Vox=(2*e*Ea/m)^0.5;
printf("\nmaximum velocity of the beam of electrons=%.2f m/s",Vox)
L=5;
ld=1.5*10^-2;
d=5*10^-3;
S=(L*ld/2*d*Ea);
printf("\ndeflection sensitivity=%.2f mm/V",S)
G=1/S;
printf("\nDeflection Factor=%.2f V/mm",G)
|
95efd5111113efd01b8adf52b88b98c84122971b | 449d555969bfd7befe906877abab098c6e63a0e8 | /1133/CH3/EX3.3/Example3_3.sce | 62a3b49f0abc57585968c043c9a87a466afb70c5 | [] | 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 | 293 | sce | Example3_3.sce | //Example 3.3
clc
disp("(a) We know that")
disp(" dAf/Af = 0.1/1+beta*A * dA/A")
disp("Therefore, 1+beta*A = 37.5")
b=(36.5/2000)*100 // in percentage
format(6)
disp(b,"Therefore, beta(in percentage) =")
af=2000/(1+(0.01825*2000))
disp(af,"(b) Af = A / 1+beta*A =") |
7976c24a30a988dc2ad8030a97dfe9acaf0cb13b | da5b40d917ec2982828bd9bdf06b18b7bf189f26 | /sim/scripts/n2reject.tst | 22971014694c4d106f30026a69d1c428efdce49d | [] | no_license | psy007/NNPC-CHEMICAL-SIM- | 4bddfc1012e0bc60c5ec6307149174bcd04398f9 | 8fb4c90180dc96be66f7ca05a30e59a8735fc072 | refs/heads/master | 2020-04-12T15:37:04.174834 | 2019-02-06T10:10:20 | 2019-02-06T10:10:20 | 162,587,144 | 1 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 1,871 | tst | n2reject.tst | # Nitrogen Rejection Unit (from old Hysim manual)
units Field
$thermo = VirtualMaterials.Peng-Robinson
/ -> $thermo
thermo + Nitrogen Methane Ethane PROPANE
thermo + ISOBUTANE n-BUTANE ISOPENTANE n-PENTANE
hp_feed = Stream.Stream_Material()
hp_ovhd = Stream.Stream_Material()
hp_btms = Stream.Stream_Material()
cd hp_feed.In
T = -215
P = 380
MoleFlow = 1000
Fraction = .5454 .4153 .0347 .0036 .0004 .0003 .0002 .0001
cd /
hp_column = Tower.Tower()
hp_column.Stage_0 + 8 # ten stages`
cd hp_column.Stage_0
l = Tower.LiquidDraw()
l.Port.P = 370
l.Port -> /hp_ovhd.In
/hp_ovhd.In.Fraction.NITROGEN = .99
l.estF = Tower.Estimate('MoleFlow')
l.estF.Value = 200
cond = Tower.EnergyFeed(0)
estReflux = Tower.Estimate('Reflux')
estReflux.Value = 3
estT = Tower.Estimate('T')
estT.Value = -250
cd ../Stage_9
f = Tower.Feed()
f.Port -> /hp_feed.Out
l = Tower.LiquidDraw()
l.Port.P = 377
l.Port -> /hp_btms.In
estT = Tower.Estimate('T')
estT.Value = -230
cd ..
TryToSolve = 1 # start calculation
cd /
hp_ovhd.Out
hp_btms.Out
# now add exchanger for overheads
e1 = Heater.HeatExchanger()
e1.DeltaPC = 0.5
e1.DeltaPH = 0.5
hp_ovhd.Out -> e1.InH
e1.OutH.T = -270
# valve
v1 = Valve.Valve()
e1.OutH -> v1.In
v1.Out.P = 29.3919
e2 = Heater.HeatExchanger()
e2.DeltaPH = .5
e2.DeltaPC = .5
hp_btms.Out -> e2.InH
e2.OutH.T = -230
# another valve
v2 = Valve.Valve()
e2.OutH -> /v2.In
v2.Out.P = 29.3919
lp_column = Tower.Tower()
lp_column.Stage_0 + 4 # six stages
cd lp_column.Stage_0
f = Tower.Feed()
f.Port -> /v1.Out
v = Tower.VapourDraw()
v.Port -> /e1.InC
v.Port.P = 29.392
cd ../Stage_3
f = Tower.Feed()
f.Port -> /v2.Out
cd ../Stage_5
reb = Tower.EnergyFeed(1)
reb.Port -> /hp_column.Stage_0.cond.Port
l = Tower.LiquidDraw()
l.Port -> /e2.InC
l.Port.P = 36.74
cd ..
TryToSolve = 1
copy /
paste /
/e1.OutC
/RootClone.e1.OutC
/e2.OutC
/RootClone.e2.OutC
|
544ef6cc1fb8d8fde50951dfabe5574b2dc08ecb | 449d555969bfd7befe906877abab098c6e63a0e8 | /564/DEPENDENCIES/26_1data.sci | 5cb35cd0d0347b8b5f68036e7a432751d49c3ab6 | [] | 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 | 194 | sci | 26_1data.sci | L12=375;//given,in mm
L23=500;//given,in mm
L34=125;//given,in mm
t12=1.6;//given,in mm
t23=1;//given,in mm
t34=1.2;//given,in mm
x=100;//given,in mm
Load=22000;//given,in mm
G=70000;//in N/mm^2 |
ca8d851d249afee47a61a219d34072ae113d26f8 | 449d555969bfd7befe906877abab098c6e63a0e8 | /172/CH7/EX7.5/ex5.sce | 4008f1006746ac64fe73355c5a05cb48373b2b34 | [] | 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 | 343 | sce | ex5.sce | //example 5
//calculating required work
clear
clc
Tl=24+273 //room temperature in Kelvins
Th=35+273 //atmospheric temperature in Kelvins
Ql=4 //rate of heat rejection from room
B=Tl/(Th-Tl) //coefficient of performance of air conditioner
W=Ql/B //required work in kW
printf("\n hence,the magnitude of reqiured work is W=%.2f kW.\n",W) |
abb3bab0471c3b1bddce80e6554d0f936380f853 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1016/CH10/EX10.2/ex10_2.sce | 40be76900ec038a38b93469d8eab50f16073f3a8 | [] | 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 | 215 | sce | ex10_2.sce | clc;clear;
//Example 10.2
//calculations
amu=1.66*10^-27;//1 amu in kg
c=3*10^8;//speed of light in m/s
m=amu;
E=m*c^2;
kWh=1.6*10^-13;//conversion of kWh in J
E=E/kWh;
disp(E,'energy equivalence in MeV') |
35c0214a0beeaf23302c5c8b948a1513c8ac8315 | 449d555969bfd7befe906877abab098c6e63a0e8 | /842/CH9/EX9.35/Example9_35.sce | 7f926cfe8a849c70ea2055e986b82041c9781a04 | [] | 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 | 203 | sce | Example9_35.sce | //clear//
//Example9.35:Unilateral Inverse Laplace Transform
//X(S) = 1/((s+1)(s+2))
s = %s;
syms t;
X = 1/((s+1)*(s+2));
x = ilaplace(X,s,t);
disp(X)
disp(x)
//Result
// (%e^-t)-(%e^-(2*t))
|
249057dcafe796c314f1f4c42861d159e0242990 | 5af38b06398bff1dfd14d6e6f3c2c1c2027b90c4 | /T1B_fourierplot.sci | 8c35cd1cc95c5f3334c034d86c329432d0662d1c | [] | no_license | charlyov/FourierCoeficientes | 372621463d607d5390574322ceab775ff2e60e2c | 9f0458045c8d205f5d1ad3e68482795e5eedd015 | refs/heads/main | 2023-01-23T10:45:21.011804 | 2020-12-07T07:03:04 | 2020-12-07T07:03:04 | 318,955,360 | 0 | 0 | null | 2020-12-06T13:38:50 | 2020-12-06T05:03:38 | Scilab | UTF-8 | Scilab | false | false | 3,717 | sci | T1B_fourierplot.sci | //COEFICIENTES DE FOURIER POR INTEGRACIÓN NUMÉRICA
//La siguiente función devuelve los coeficientes de Fourier,'a0', 'Ak' & 'Bk' y a0_num, ak_num, bk_num
//El usuario debe ingresar los siguientes argumentos:
//L= Periodicidad de la función f que será aproximada mediante series de Fourier.
//n= número de Coeficientes de Fourier que se quieren calcular
//f= función a ser aproximada mediante series de Fourier
//M = número de dt en los que dividir el intervalo
//Consultado en: https://www.bragitoff.com/2016/03/calculating-fourier-series-and-plotting-it-scilab/
//PARA FIJAR NUESTRA FUNCION INTRODUCIMOS EN CONSOLA: deff("a=f(x)","a= (x^2)*cos(48*x)")
funcprot(0);
//function [a0,A,B,a0_num,A_num,B_num]=T1B_fourierplot(L,k,f,M) //cuando esté lista la función de integración numérica
function [a0,A,B]=T1B_fourierplot(L,k,f)
clf(); //Limpia los gráficos https ://help.scilab.org/docs/5.3.3/en_US/clf.html
for i=1:k
function ak=f1(x,f)
ak=f(x)*cos(i*%pi*x/L);
endfunction
function bk=f2(x,f)
bk=f(x)*sin(i*%pi*x/L);
endfunction
a0=1/L*intg(-L,L,f,.000000001); //CAMBIAR POR INTEGRACION NUMERICA
A(i)=1/L*intg(-L,L,f1,.000000001);//CAMBIAR POR INTEGRACION NUMERICA
B(i)=1/L*intg(-L,L,f2,.000000001);//CAMBIAR POR INTEGRACION NUMERICA
//HACER AQUI LA FUNCIÓN DE INTEGRACIÓN NUMÉRICA PARA a0_num,A_num,B_num
//function [a0_num, A_num, B_num]=trapecios(L, k, f, M)
// Tmin = -L; //límite inferior del intervalo de trabajo,
// Tmax = L;// Límite superior
// dt = (Tmax-Tmin)/(M-1); //diferencial de t ¿PORQUE -1?
// t=zeros(M,1);// vector para los M valores en los que evaluar t
// t2=zeros(M,1);//
// g = zeros (M,1);//vector para los M valores izq que tendrá f(t)
// h = zeros(M,1);//vector para los M valores der que tendrá f(t)
// for m=1:M
// t(m)=Tmin+(m-1)*dt; // vector con límites inferiores de dt
// t2(m)=Tmin+(m)*dt; // vector con límites inferiores de dt
// g(m)= (t(m)^2)*cos(48*t(m)); // función evaluada en límite izq del intervalo dt
// h(m)= (t2(m)^2)*cos(48*t2(m));//función evaluada en límite der del intervalo dt
// end
// a0_num =
// A_num =
// B_num =
////---- Integración Trapezoidal para a0
////https: //www.computerscienceai.com/2019/04/scilab-program-trapezoidal-rule.html
//
// sum=0;
// for i=1:M
// a0_num = (dt/2)*(g(i)+ h(i))+sum);
// end
// disp(a0_num)
//
// //----suma de riemann:
//
// a0_num = (1/L)*(sum(f(m))*dt);
// disp(a0_num)
//
//endfunction
end
function series=solution(x)
series= a0/2;
for i=1:k
series=series+A(i)*cos(i*%pi*x/L)+B(i)*sin(i*%pi*x/L);
end
endfunction
x=-2L:0.1:2L;
plot(x,solution(x));
endfunction
//a).- Con M = 300 en el ejemplo de g(t), obtenga a0, ak y bk para k = 1; 2... 7.
//b).- Con M = 300 en el ejemplo de g(t), obtenga a0, ak y bk para k = 1; 2...7.
//c).- Con M = 400, grafique el par de funciones{g(t),g7(T)}, el par {g(t),g14(T)},
//el par {g(t),g28(T)},{g(t),g60(T)}
//d).- Con M = 300 en el ejemplo de f(t), del ejercicio 2, grafique el par de funciones el par de funciones{f(t),f7(T)}, el par {f(t),f17(T)}, el par {f(t),f50(T)},{f(t),f100(T)}
//e) con M =200 en el ejemplo de f(t) del ejercicio 2, obtenga los CF. aproximados de a´0,a´k, b´k calculados con integración numérica, los CF exactos a0,ak y bk obtenidos en el mismo ejercicio 2 y los errores absolutos [a0-a´0], [ak-a´k],[bk-b´k].
|
9c0a981692fae52342403528c4bb74a6ca265ad6 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1826/CH5/EX5.1/ex5_1.sce | a526cad2497d06058a4c1c4829c5adb7eb838dbc | [] | 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 | 236 | sce | ex5_1.sce | // Example 5.1, page no-130
clear
clc
a=3.615*10^-10//m
t_ang=0.75 //in degree
h=1
k=1
l=0
d_110=a/sqrt(h^2+k^2+l^2)
D=d_110/tan(t_ang*%pi/(180*2))
printf("The average distance between the dislocations is %.3f A°",D*10^6)
|
7a0e38b7f435b022e1929049e4594493687a77be | 449d555969bfd7befe906877abab098c6e63a0e8 | /1106/CH7/EX7.7/ex7_7.sce | ac7fbda066713b625703ddc0d55f119a08fd225b | [] | 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 | 152 | sce | ex7_7.sce | // Example 7.7, Page No-345
clear
clc
// Answer in textbook is wrong
C=0.1*10^-6
t=1*10^-3
R=t/(1.22*C)
R=R/1000
printf('R= %.1f kohm', R)
|
ae9a3dcca2226da6afff360596b49867f6e449d6 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1640/CH5/EX5.18/5_18.sce | 900f0159c5b826a95919bfbc41a248b06b5c0aef | [] | 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 | 304 | sce | 5_18.sce | clc
//initialisation of variables
A= 10000 //ft^2
H1= 50 //ft
H2= 40 //ft
l= 1500 //ft
d= 6 //in
f= 0.0075
g= 32.2 //f/sec^2
//CALCULATIONS
t= 2*A*sqrt((1.5+(4*f*l/(d/12)))/(2*g))*(sqrt(H1)-sqrt(H2))/(%pi*(d/12)^2/4)
//RESULTS
printf ('Time taken to lower the level of water = %.f sec ',t)
|
3a6982b30cea7ef63a9172ddfd41c7d5426a9a7d | 449d555969bfd7befe906877abab098c6e63a0e8 | /3136/CH6/EX6.10/Ex6_10.sce | be54d5c45158d2cd315d14bb528cadd1971e57c9 | [] | 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 | 1,633 | sce | Ex6_10.sce | clear all; clc;
disp("From table 6.1 at 1.25 SP,the rotating speeds for Q1=11172cfm and Q2=12103cfm are N1=474rpm and N2=483 rpm respectively")
Ns=474+[(483-474)*(12000-11172)]/[12103-11172]
printf(" Hence the rotating speed for the selected fan is determined by inetrpolation %0.0f rpm\n\n",Ns)
disp("Select a few data points around 482 rpm from table 6.1 as:")
Q=[14896 12103 11172 11172 10241 7448];
N=[490 448 436 474 466 360];
SP=[1.0 1.0 1.0 1.25 1.25 0.75];
BHP=[3.66 2.67 2.40 2.97 2.75 1.2];
disp(" Q(cfm) N(rpm) SP(in.wg) BHP(hp)")
table=[Q' N' SP' BHP']
disp(table)
disp("Convert them into conditiond of 482 rpm according to the similarity laws,resulting in")
Q1=[14653 13021 12350 11360 10593 9972];
SP1=[0.967 1.16 1.22 1.29 1.34 1.34];
BHP1=[3.5 3.20 3.24 3.12 3.04 2.88];
table1=[Q1' SP1' BHP1']
disp(" Q(cfm) SP(in.wg) BHP(hp)")
disp(table1)
disp("The system curve can be calculated from the following table")
Q2=[10000 11000 12000 13000 14000];
H2=[0.87 1.05 1.25 1.47 1.70];
sqrQ2 = zeros(1,length(Q2));
for i = 1: length(Q2)
sqrQ2(i) = [Q2(i)]^2;
end
table2=[Q2' H2']
disp(" Q(cfm) H(in.wg)")
disp(table2)
disp("The system curve can be calculated from H versus Q^2. It is plotted as shown.")
//The system curve has not been provided in the book for this numerical. However they have mentioned that the parameters for the curve are H and Q^2,and as such has been plotted here.
plot(sqrQ2,H2)
xlabel("Q^2 ")
ylabel("H")
set(gca(),"grid",[1 1])
xtitle("System curve: H versus Q squared")
|
f87010abd010cb56fe5b30fac26aa6e4d64dfcbf | 717ddeb7e700373742c617a95e25a2376565112c | /3044/CH4/EX4.4/Ex4_4.sce | e1526174ef6ad3d65a55f0bee3dfd558023b4f51 | [] | no_license | appucrossroads/Scilab-TBC-Uploads | b7ce9a8665d6253926fa8cc0989cda3c0db8e63d | 1d1c6f68fe7afb15ea12fd38492ec171491f8ce7 | refs/heads/master | 2021-01-22T04:15:15.512674 | 2017-09-19T11:51:56 | 2017-09-19T11:51:56 | 92,444,732 | 0 | 0 | null | 2017-05-25T21:09:20 | 2017-05-25T21:09:19 | null | UTF-8 | Scilab | false | false | 389 | sce | Ex4_4.sce | //Variable Declaration
p = 0.3 // probability of not passing inspection
n = 18 // total panels
//Calculation
function ans = comb(n,r)
// returns number of total combination of selecting "r" items out of "n"
ans = factorial(n)/(factorial(r)*factorial(n-r))
endfunction
p1 = comb(18,6)*(p^6)*((1-p)^12)
//Results
printf ( "Required probability: %.4f",p1)
|
e6c4ff140646bb6ac3476bd9cad9ec83bf382244 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1460/CH2/EX2.2/2_2.sce | e0f6dff6467bda5d15c6aaea1fb7d13d51948cbf | [] | 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 | 313 | sce | 2_2.sce | clc
//initialization of variables
w=0.1 //lbm
Pv=30000 //ft-lb/lbm
v1=14 //ft^3 /lbm
v2=3 //ft^3/lbm
//calculations
function [W]=func(v)
W=Pv/v
endfunction
Work=w*intg(v1,v2,func)
//results
//Answer varies a bit from the text due to rounding off of log value
printf("Work done = %d ft-lb",Work)
|
7ae65f2547d457e50921d1c1a6d1de1f43f935ad | 0480f6392643f10964ff6b301b2be49036bfe7d9 | /amvsfm.sce | 48cfa772074556e7277d1f99e5f4f04a3be10d77 | [] | no_license | vbv15/helloworld | 02f13332442310e95126067564516a8500b072c3 | 7982e10b0195afc1adb582ec623d95bd8f9556cb | refs/heads/master | 2021-06-28T01:18:01.725621 | 2016-11-11T02:49:46 | 2016-11-11T02:49:46 | 42,517,937 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 343 | sce | amvsfm.sce |
ac=4;
fc=1500;
fm=100;
b=1.5;
ta=1/fm;
t=0:ta/99:2*ta;
y=ac*cos(2*%pi*fc*t+b*sin(2*%pi*fm*t));
plot(t,y);
t=0:ta/99:5*ta;
fc=20000;
y=ac*cos(2*%pi*fc*t+b*sin(2*%pi*fm*t));
plot(t,y);
fc=5000;
y=ac*cos(2*%pi*fc*t+b*sin(2*%pi*fm*t));
plot(t,y);
plot(t,y);
z=ac*cos(2*%pi*fm*t);
plot(t,z);
|
09c592a1a46fbba48c6b728e4150fc5414473f95 | b29e9715ab76b6f89609c32edd36f81a0dcf6a39 | /ketpic2escifiles6/Arrowheaddata.sci | 68dfe27c9499de3a9496aab857971552b3fe8886 | [] | no_license | ketpic/ketcindy-scilab-support | e1646488aa840f86c198818ea518c24a66b71f81 | 3df21192d25809ce980cd036a5ef9f97b53aa918 | refs/heads/master | 2021-05-11T11:40:49.725978 | 2018-01-16T14:02:21 | 2018-01-16T14:02:21 | 117,643,554 | 1 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 1,870 | sci | Arrowheaddata.sci | // 08.05.31
// 09.12.25
// 13.11.13 debugged
// 14.11.02 debugged
function Out=Arrowheaddata(varargin)
global YaSize YaAngle YaPosition YaThick YaStyle;
Eps=10^(-3);
Nargs=length(varargin);
Out=[];
P=varargin(1);
Houkou=varargin(2);
Ookisa=0.2*YaSize;
Hiraki=YaAngle;
Futosa=0;
Thickness=1;
Str=YaStyle;
Flg=0;
for I=3:Nargs
Tmp=varargin(I);
if type(Tmp)==10
if mtlb_findstr(Tmp,'=')~=[]
execstr(Tmp);
Futosa=Thickness;
else
Str=Tmp;
end
end
if type(Tmp)==1 & length(Tmp)==1
if Flg==0
Ookisa=Ookisa*Tmp;
end
if Flg==1
if Tmp<5
Hiraki=Tmp*Hiraki;
else
Hiraki=Tmp;
end
end
Flg=Flg+1;
end
end
Theta=Hiraki*%pi/180;
if size(Houkou,1)>1
P=Doscaling(P);
Houkou=Doscaling(Houkou);
Tmp=Nearestpt(P,Houkou);
A=Op(1,Tmp);
I=floor(Op(2,Tmp));
if I==1 // 14.11.02
if norm(Ptend(Houkou)-Ptstart(Houkou))<Eps
l=Numptcrv(Houkou);
end;
end;
G=Circledata(P,Ookisa*cos(Theta),'N=10');
Flg=0; // 13.11.13
for J=I:-1:1
B=Ptcrv(J,Houkou);
Tmp=IntersectcrvsPp(Listplot([A,B]),G);
if Mixlength(Tmp)>0
Flg=1;
break
end
A=B
end
if Flg==0 // 13.11.13
disp('Arrowhead may be too large (no intersect)');
return
end
Houkou=P-Op(1,Op(1,Tmp));
Houkou=Unscaling(Houkou);
P=Unscaling(P);
end
P=Doscaling(P);
Houkou=Doscaling(Houkou);
E=-1/Vecnagasa(Houkou)*Houkou;
N=[-E(2),E(1)];
if mtlb_findstr(Str,'c')~=[]
P=P-0.5*Ookisa*cos(Theta)*E;
end
if mtlb_findstr(Str,'b')~=[]
P=P-Ookisa*cos(Theta)*E
end
A=P+Ookisa*cos(Theta)*E+Ookisa*sin(Theta)*N;
B=P+Ookisa*cos(Theta)*E-Ookisa*sin(Theta)*N;
Out=Listplot([A,P,B]);
Out=Unscaling(Out);
endfunction
|
d68caf271f31fc9f7d1b1d30a425a235b535e311 | cc8590d48fbf1cc9d2dfffdb260b554a6b07ffea | /Lista3.sce | 3d71044e44fa93d98a21689160820af9f559ef1f | [] | no_license | Anthony20153298/Lista_3 | 0eaaf0b998df219ab0107064b3e20f160df19427 | 6119227f51c38064190b9e30952b1a6bd99fd36f | refs/heads/master | 2022-12-03T18:10:56.713545 | 2020-08-21T07:56:39 | 2020-08-21T07:56:39 | 289,211,589 | 0 | 0 | null | null | null | null | UTF-8 | Scilab | false | false | 4,866 | sce | Lista3.sce | //Motor DC
//Autor: Vasquez Rivera Anthony A.
//Sistema de Control Avanzado
ap= [-675,-26.25;1050,-0.093]// Matrix A
bp = [250,0;0,250]// Matrix B
cp = [1,0;0,1]// Matrix C
dp = 0*ones(2,2)// Matrix D
Gs= syslin("c",ap, bp, cp, dp)//Linear system definition
[tf]=ss2tf(Gs)//Conversion from state-space to transfer function
// Calculation of poles and zeros of the plant //
plzr(tf);// Pole-zero plot
scf(1);
// Definition of stability and performance barriers //
w=logspace(-3,3,400);
a=200;b=130;c=70;
x1=40*ones(1,a); x2=60*zeros(1,b); x3=-40*ones(1,c);
xt=[x1 x2 x3];
x4=[5*ones(1,100) 0*zeros(1,300)];
scf(2);
plot2d("ln", w, x4,3, rect=[10^-1 -60 10^3 60])
plot2d("ln", w, xt)
xgrid(12)
xtitle("Stability Barriers","Frequency w(rad/s)", "Amplitude (dB)");
s= svd(ap);
// Plot of maximum and minimum singular values //
tri = trzeros(Gs)//Transmission zeros and normal rank
w = logspace(-3,3);
svi = svplot(Gs,w);//Singular-value sigma-plot
scf(3);
plot2d("ln", w, 20*log(svi')/log(10))
xgrid(12)
xtitle("Design Plant Singular Values","Frequency (rad/s)", "Amplitude (dB)");
// We add an integrator to the plant //
[ns,nc]=size(bp); // ns = number of entries; nc = number of controls
Ai=[ap,bp;0*ones(nc,ns),0*ones(nc,nc)]; //Matrix A with integrator
Bi=[0*ones(ns,nc); eye(nc,nc)];//Matrix B with integrator
Ci=[cp 0*ones(nc,nc)];//Matrix C with integrator
Di=0*ones(nc,nc);//Matrix D with integrator
sysi=syslin('c',Ai,Bi,Ci,Di);
I=eye(nc);//Identity matrix
// Calculation and plotting of singular values with integrator //
tri = trzeros(sysi)
w = logspace(-3,3);
svi = svplot(sysi,w);
scf(4);
plot2d("ln", w, 20*log(svi')/log(10))
xgrid(12)
xtitle("Design Plant Singular Values","Frequency (rad/s)", "Amplitude (dB)");
// LQR controller //
C=0.7*Ci'*Ci; // Weighting matrix Q
rho=1e-1; // Value of rho
R = rho*eye(nc); // Associated with the cost matrix C
B=Bi*inv(R)*Bi'; // Recalculating B
A=Ai;
// Riccati in the system //
X=riccati(A,B,C,'c','eigen');
// The gain of the controller //
G=inv(R)*Bi'*X;
// Kalman filter layout //
ll= inv(cp*inv(-ap)*bp+dp); // Matrix L
lh = -inv(ap)*bp*ll;
Lp=[lh,
ll];
pnint = eye(nc,nc) // Values for the duality of the Filter
mu = 0.1; // LQR controller, applying Riccati
THETA = mu*eye(nc,nc)
Ah=Ai'; // Calculation of Ah
Bh=Ci'*inv(THETA)*Ci; // Calculation of Bh
Ch=Lp*Lp'; //Calculation of Ch
Xh=riccati(Ah,Bh,Ch,'c','eigen'); // Riccati application to the system
// Calculation of the gain of H
H=(inv(THETA)*Ci*Xh)';
sysh = syslin('c',Ai,H,Ci,Di);
// Calculation of singular values of the filter //
trh = trzeros(sysh)
w = logspace(-3,3);
svh = svplot(sysh,w);
scf(5);
plot2d("ln", w, 20*log(svh')/log(10))
xgrid(12)
xtitle("Singular Values – Kalman Filter","Frequency (rad/s)","Amplitude (dB)");
//Compensator//
Ak = [ Ai-Bi*G-H*Ci 0*ones(ns+nc,nc)
G 0*ones(nc,nc) ]//Matrix A with compensator
Bk = [ H
0*ones(nc,nc) ]//Matrix B with compensator
Ck = [0*ones(nc, ns+nc) eye(nc,nc) ]//Matrix C with compensator
Dk = 0*ones(nc,nc);//Matrix D with compensator
sysk=syslin('c',Ak,Bk,Ck,Dk);
// Calculation of singular values of the compensator //
trk = trzeros(sysk)
w = logspace(-3,3);
svk = svplot(sysk,w);
scf(6);
plot2d("ln", w, 20*log(svk')/log(10))
xgrid(12)
// We analyze in an open loop //
Abo = [ ap bp*Ck
0*ones(ns+nc+nc,ns) Ak ]//Matrix A in open loop
Bbo = [ 0*ones(ns,nc)
Bk ]
//Matrix B in open loop
Cbo = [ cp 0*ones(nc,ns+nc+nc) ]//Matrix C in open loop
Dbo = 0*ones(nc,nc);//Matrix D in open loop
sysbo = syslin('c',Abo,Bbo,Cbo,Dbo);
//Singular values of open loop //
vsbo = svplot(sysbo,w);
scf(7)
plot2d("ln", w, 20*log(vsbo')/log(10))
xgrid(12)
xtitle("Singular values plot del bucle abierto","Frequency (rad/s)", "Amplitude (dB)");
xtitle("Compensator Singular Values","Frequency (rad/s)", "Amplitude (dB)");
// Sensitivity analysis of S //
SS= syslin("c",Abo-Bbo*Cbo, Bbo, -Cbo, eye(nc,nc))
ssi = svplot(SS,w);
scf(8)
plot2d("ln", w, 20*log(ssi')/log(10))
xgrid(12)
xtitle("Singular values plot sensibility S","Frequency (rad/s)", "Amplitude (dB)");
// Sensitivity analysis of T //
ST= syslin('c',Abo-Bbo*Cbo, Bbo, Cbo, Dbo)
sti = svplot(ST,w);
scf(9)
plot2d("ln", w, 20*log(sti')/log(10))
xgrid(12)
xtitle("Singular values plot Sensibility T","Frequency (rad/s)", "Amplitude (dB)");
// Analysis of overlapping S and T //
scf(10)
plot2d("ln", w, [20*log(ssi')/log(10)])
plot2d("ln", w, [20*log(sti')/log(10)])
xgrid(12)
xtitle("Singular values plot S y T","Frequency (rad/s)", "Amplitude (dB)");
|
6c353c4870bfcea665fa584a1dcc3c5b50fb54a0 | 449d555969bfd7befe906877abab098c6e63a0e8 | /257/CH8/EX8.12/example_8_12.sce | ca0e2964c271bc7638efd3414efc2e36d909137c | [] | 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 | 581 | sce | example_8_12.sce | s=%s
F=s^3+4*s^2+13*s+50
disp(routh_t(F))
r=coeff(F)
routh=routh_t(F)
n=length(r)
c=0;
for i=1:n
if (routh(i,1)<0)
c=c+1;
end
end
if(c>=1)
printf("system is unstable")
else printf("there are no roots on RHS")
end
syms s k
G=5*k/(s*(1+s/3)*(1+s/6)*18)
H=1
Kv=limit(s*G*H,s,0)
disp(Kv, " Kv = ")
s=%s
F=s^3+9*s^2+18*s+180
disp(routh_t(F))
r=coeff(F)
routh=routh_t(F)
n=length(r)
c=0;
for i=1:n
if (routh(i,1)<0)
c=c+1;
end
end
if(c>=1)
printf("system is unstable")
else printf("there are no roots on RHS")
end
|
20cb52ba13533f2288fd4678b53f05db07ecd967 | 449d555969bfd7befe906877abab098c6e63a0e8 | /2792/CH9/EX9.6/Ex9_6.sce | ed50f305efcb6b9892f6ecae05800d723a36e37a | [] | 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 | 1,516 | sce | Ex9_6.sce | clc
kbT = 0.026
disp("kbT = "+string(kbT)+"eV") //initializing value of kbT at 300K
apsilen = 11.9*8.85*10^-14
disp("apsilen = "+string(apsilen)+"F/cm") //initializing value of relative permitivity
e = 1.6*10^-19
disp("e= "+string(e)+"C")//initializing value of charge of electron
Na=10^16
disp("Na = "+string(Na)+"cm^-3") //initializing value of doped carrier concentration
ni = 1.5*10^10
disp("ni= "+string(ni)+"cm^-3")//initializing value of intrinsic carrier concentration
apsilen_ox = 3.9*8.85*10^-14
disp("apsilen_ox= "+string(apsilen_ox))//initializing value of relative permitivity of oxide
dox = 500*10^-8
disp("dox= "+string(dox)+"cm")//initializing value of thickness of oxide
Cox= apsilen_ox/dox
disp("The oxide capacitance Cox= apsilen_ox/dox= "+string(Cox)+"F/cm^2")//calculation
phi_F= (-kbT*log(Na/ni))
disp("The potential phi_F= (-kbT*log(Na/ni))= "+string(phi_F)+" V")//calculation
Wmax = sqrt((4*apsilen*(-phi_F))/(e*Na))
disp("The maximum depletion width is ,Wmax = sqrt((4*apsilen*(-phi_F))/(e*Na))= "+string(Wmax)+" cm")//calculation
Cmin = (apsilen_ox/(dox+((apsilen_ox*Wmax)/apsilen)))
disp("The minimum capicitance is ,Cmin = (apsilen_ox/(dox+((apsilen_ox*Wmax)/apsilen)))= "+string(Cmin)+" F/cm^2")//calculation
Cfb = (apsilen_ox/((dox)+((apsilen_ox/apsilen)*(sqrt((kbT*apsilen)/(e*Na))))))
disp("The capicitance under flat band conditions is ,Cfb = (apsilen_ox/((dox)+((apsilen_ox/apsilen)*(sqrt((kbT*apsilen)/(e*Na)))))) = "+string(Cfb)+" F/cm^2")//calculation
|
610f720cdf6ee665aa95e4b8a1e44563ee7f1879 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1241/CH2/EX2.14/exa2_14.sce | 0fe88110ff8f5d6ca62e26af67034107e07cdecc | [] | 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 | 223 | sce | exa2_14.sce | //Example 2-14//
//binary to hexadecimal conversion//
x=bin2dec('1010111010')
//decimal equivalent of the binary number//
a=dec2hex(x)
//Hex equivalent of the decimal number//
disp(a)
//answer in hexadecimal form//
|
f0168ce3266198a6445d48f1b8d1fc4b07a8391d | 449d555969bfd7befe906877abab098c6e63a0e8 | /291/CH8/EX8.3d/eg8_3d.sce | 017239a795e61932e982b12f9985cece391f1c43 | [] | 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 | 611 | sce | eg8_3d.sce | alpha = 0.025;
betaa = 0.25;
u1 = 9.2;
uo = 8;
var =4;
zalpha = cdfnor("X", 0, 1, 1-alpha, alpha);
zbeta = cdfnor("X", 0, 1, 1-betaa, betaa);
//disp(zalpha);
n = ((zalpha + zbeta)/(u1-uo))^2 *var;
disp(ceil(n), "Required number of samples is")
statistic = sqrt(ceil(n)/var)*(u1 - uo);
//disp(statistic);
lim1 = -1*statistic + zalpha;
lim2 = -1*statistic - zalpha;
//disp(lim1)
//disp(lim2)
prob = cdfnor("PQ", lim1 , 0,1 ) - cdfnor("PQ", lim2 , 0,1 );
disp(1-prob, "Thus, if the message is sent the reqd number of times is , then the probability that the null hypothesis will be rejected is") |
def7e48b422fc94acde22ef9bf4492a10bb43373 | 449d555969bfd7befe906877abab098c6e63a0e8 | /3515/CH3/EX3.24/Ex_3_24.sce | bbf4bc526232e659141438eee8a70da66d435b54 | [] | 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 | 380 | sce | Ex_3_24.sce | // Exa 3.24
format('v',5);
clc;
clear;
close;
// Given data
VBE_1= 0.7;// in V
VBE_2= 0.5;// in V
V_T= 0.025;// in V
I_C1= 10;// in mV
I_C1= I_C1*10^-3;// in A
// I_C1= I_S*%e^(VBE_1/V_T) (i)
// I_C2= I_S*%e^(VBE_2/V_T) (ii)
// Devide equation (ii) by (i)
I_C2= I_C1*%e^((VBE_2-VBE_1)/V_T);// in A
disp(I_C2*10^6,"The value of I_C2 in µA is : ")
|
833c61f408cec3f9f1289e134df60bd466747bee | 5bee7340e93b8ea9d588b54e56850d3416c9b860 | /ce2004 lab4/code/delta.sce | 53d7eaa1cc971d8d2a8c8b7771d301f782a29102 | [] | no_license | StevenShi-23/Lab-Report | f2217f466eeff34125127bca48a3a8e8aedc882a | 9510b7cc3b6318d1afaf3bdfc3e118fa2225f064 | refs/heads/master | 2020-07-05T18:46:29.864783 | 2014-04-14T05:35:31 | 2014-04-14T05:35:31 | 73,985,787 | 1 | 0 | null | 2016-11-17T03:17:13 | 2016-11-17T03:17:13 | null | UTF-8 | Scilab | false | false | 197 | sce | delta.sce | function y = Pi(t)
y = step(t + 0.5) - step(t - 0.5)
endfunction
function y = delta(t)
y = 200 * Pi(200 * t);
endfunction
function y = expDelta(t)
y = %e^t .* delta(t - 1)
endfunction |
6f8c2fdbf7b89c0b4dc86c90d07cedbe59cec8f6 | 449d555969bfd7befe906877abab098c6e63a0e8 | /1109/CH4/EX4.4/4_4.sce | d24275762d7714a04c5526874f906440d3bcc540 | [] | 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 | 4_4.sce | clear;
clc;
l=440;L=2.2*(10^-3);C=0.0136*(10^-6);R=0.120;G=0;f=60;
w=2*%pi*f;
Z=R+(%i*w*L);
Y=G+(%i*w*C);
Zo=sqrt(Z/Y);
A=real(Zo);
B=imag(Zo);
printf("-Characteristic impedance = %f + j(%f) ohms\n",round(A),round(B));
P=sqrt(Z*Y);
E=real(P)*10^4;
F=imag(P)*10^3;
printf("-Propagation constant = %f * 10^-4 + j(%f) * 10^-3 per km",fix(E*100)/100,fix(F*100)/100);
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87e7092be0e3c8af333482cb371a5d9ebb0b4bc1 | 449d555969bfd7befe906877abab098c6e63a0e8 | /671/CH3/EX3.1/3_1.sce | a3843c726c1c5e10f3a4a1bc388266dc78a2f4af | [] | 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 | 145 | sce | 3_1.sce | function C=seriesC(C1,C2)
C=C1*C2/(C1+C2)
endfunction
Ceq1=10+seriesC(10,10)
Ceq2=Ceq1
Ceq=seriesC(seriesC(Ceq1,Ceq2),10)
disp(Ceq) |
91a6afa27e4ffb15af7cf9a25090ba512fa03c1e | 449d555969bfd7befe906877abab098c6e63a0e8 | /1247/CH5/EX5.1/example5_1.sce | 110300aa67ea5b83c8fd4bd731b43c65d85aa713 | [] | 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 | 610 | sce | example5_1.sce | clear;
clc;
// Stoichiometry
// Chapter 5
// Energy Balances
// Example 5.1
// Page 186
printf("Example 5.1, Page 186 \n \n");
// solution
// basis pumping of 1 l/s of water
Hadd = 52 // kW
Hlost = 21 // kW
fi = Hadd - Hlost // kW
p1 = 101325 // Pa
p2 = p1
Z1 = -50 // m
Z2 = 10 // m
g = 9.80665 // m/s sq
gc = 1 // kg.m/(N.s sq)
row = 1 // kg/l
W = 1.5*.55 // kW
// energy balance b/w A and B
// dE = E2-E1 = W + Q + (Z1-Z2)*(g/gc)*qm
dE = 31.237 // kW
printf("Increase in internal energy between the storage tank and the bottom of the well = "+string(dE)+" kW.")
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