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8_2.sce
clc //Initialization of variables Vc=12.7 //cm/s r=2 //cm r2=5 //cm R=354 rho=0.85 V=6.37 //cm/s D=0.1 //m //calculations k=Vc/r2^2 f=64/R T0=f/4 *rho*V^2 /2 T02=T0/10 hr=f*(V*10^-2)^2 /(2*9.81*D) //results printf("Friction factor = %.2f",f) printf("\n Shear stress at the pipe wall = %.3f N/m^2",T02) printf("\n Head loss per pipe length = %.5f m/m",hr)
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//heat equation using crank-nicolson method //example 9.8 //page 364 clc;clear;close; U=0.01878; //h=1/2;l=1/8,i=1; u01=0;u21=1/8; u11=(u21+u01)/6; printf(' u11=%f\n\n',u11); printf('error is %f\n\n',abs(u11-U)); //h=1/4,l=1/8,i=1,2,3 A=[-3 -1 0;1 -3 1;0 1 -3]; C=[0;0;-1/8]; X=A^-1*C; printf(' u12=%f\n\n',X(2,1)); printf('error is %f\n\n',abs(X(2,1)-U));
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function bad_connection(path_out,prt_out,nout,path_in,prt_in,nin) // alert for badly connected blocks // path_out : Path of the "from block" in scs_m // path_in : Path of the "to block" in scs_m //! // Copyright INRIA [lhs,rhs]=argn(0) if rhs==6 then //two connected blocks lp=mini(size(path_out,'*'),size(path_in,'*')) k=find(path_out(1:lp)<>path_in(1:lp)) path=path_out(1:k(1)-1) // common superbloc path path_out=path_out(k(1)) // "from" block number path_in=path_in(k(1)) // "to" block number if path==[] then hilite_obj(scs_m(path_out)) if or(path_in<>path_out) then hilite_obj(scs_m(path_in)),end message(['Hilited block(s) have connected ports '; 'with incompatible sizes'; ' output port '+string(prt_out)+' size is :'+string(nout); ' input port '+string(prt_in)+' size is :'+string(nin)]); hilite_obj(scs_m(path_out)) if or(path_in<>path_out) then hilite_obj(scs_m(path_in)),end else mxwin=maxi(winsid()) for k=1:size(path,'*') hilite_obj(scs_m(path(k))) scs_m=scs_m(path(k))(3)(8); scs_show(scs_m,mxwin+k) end hilite_obj(scs_m(path_out)) if or(path_in<>path_out) then hilite_obj(scs_m(path_in)),end message(['Hilited block(s) have connected ports '; 'with incompatible sizes'; string(prt_out)+' output port size is :'+string(nout); string(prt_in)+' input port size is :'+string(nin)]); for k=size(path,'*'):-1:1,xdel(mxwin+k),end scs_m=null() unhilite_obj(scs_m(path(1))) end else // connected links do not verify block contraints if rhs==2 then mess=prt_out; else mess=['Hilited block has connected ports '; 'with incompatible sizes'] end path=path_out(1:$-1) // superbloc path path_out=path_out($) // block number if path==[] then hilite_obj(scs_m(path_out)) message(mess) hilite_obj(scs_m(path_out)) else mxwin=maxi(winsid()) for k=1:size(path,'*') hilite_obj(scs_m(path(k))) scs_m=scs_m(path(k))(3)(8); scs_show(scs_m,mxwin+k) end hilite_obj(scs_m(path_out)) message(mess) for k=size(path,'*'):-1:1,xdel(mxwin+k),end scs_m=null() unhilite_obj(scs_m(path(1))) end end function scs_show(scs_m,win) oldwin=xget('window') xset('window',win);xbasc() wpar=scs_m(1) wsiz=wpar(1) xset('wdim',wsiz(1),wsiz(2)) [frect1,frect]=xgetech() wdm=xget('wdim') xsetech([-1 -1 8 8]/6,[0 0 wdm(1) wdm(2)]) drawobjs(scs_m)
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clc clear //Input data CO2=10//Volumetric analysis composition in percent N2=80//Volumetric analysis composition in percent C=80//Carbon content of the fuel in percent mO2=32//Molecular weight of O2 mCO2=44//Molecular weight of CO2 mN2=28//Molecular weight of N2 mC=12//Molecular weight of carbon //Calculations O2=100-(N2+CO2)//Volumetric analysis composition in percent pCO2=(CO2/100)*mCO2//Proportional weight for CO2 pO2=(O2/100)*mO2//Proportional weight for O2 pN2=(N2/100)*mN2//Proportional weight for N2 T=(pCO2+pO2+pN2)//Total proportional weight ppCO2=(pCO2/T)//Weight per kg of exhaust gas for CO2 ppO2=(pO2/T)//Weight per kg of exhaust gas for O2 ppN2=(pN2/T)//Weight per kg of exhaust gas for N2 wC=(ppCO2*(mC/mCO2))//Weight of carbon per kg of exhaust gases in kg WC=((C/100)/wC)//Weight of exhaust gases per kg of fuel burned in kg wa=(WC-(ppCO2+ppO2+ppN2))//Weight of air supplied per kg fuel in kg //Output printf('Weight of air supplied per kg of fuel is %i kg',wa)
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clc phim=3.20// v x=3.25// v Eg=1.11//eV Na=10^14// cm^-3 k=1.3806*10^-23// JK^-1 T=300// K ni=1.5*10^10// cm^-3 e=1.6*10^-19// eV phifp=(((k*T)/e)*log(Na/ni)) disp(phifp,"the value of phifp in V is") phims=phim-(x+(Eg/2)+phifp) disp(phims,"work function difference in V is ")
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function precise = is_precise(Function, x, precision) // Example: |Y| < 10^-3 precise = abs(Function(x)) < ( 10^-precision ); endfunction // Find root value with newton method function [x, root] = newton_root(Function, x, precision, max_loop) // set default value if ~exists('max_loop', 'local') then max_loop = 10; end for i = 1:max_loop // checks accuracy and stops if that's true if is_precise(Function, x, precision) then break; end angular_coeficient = numderivative(Function, x) // when tangent touch "x" axis x = x - Function(x) / angular_coeficient; end endfunction // Find root value with secant method function [x, root] = secant_root(Function, x, precision, max_loop) //set default value if ~exists('max_loop', 'local') then max_loop = 10; end // starting x1 with increased precision value x1 = x + 10^-precision; for i = 1:max_loop if is_precise(Function, x, precision) then break; end angular_coeficient = (Function(x1) - Function(x)) / ( x1 - x ); x1 = x; x = x - Function(x) / angular_coeficient; end endfunction function y = sample_function(x) // roots = 15, 2, -5, -25 // use point to operate with vector y = (x - 15).*(x - 2).*(x + 5).*(x + 25) endfunction
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function concatenate_points_pcd() // Concatenates the points of multiple point cloud data. // // Syntax // PointCloud(InputPCDFIle1, InputPCDFile2, ... , InputPCDFilen,"concatenate_points_pcd") // // Parameters // InputPCDFile[1,2,...,n] : These are the Input Files in PCD format // // Description // All the input point clouds are concatenated and the result is stored in an "output.pcd" file that is generated implicitly. // // Examples // // PointCloud("cce1.pcd", "cce2.pcd","concatenate_points_pcd") // //Authors //Ankit Kumar //Akshay S Rao //Mohammed Rehab Sait //Aliasgar AV endfunction
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//chapter6,Example6_5,pg 122 ni=2.5*10^19 um=0.39 up=0.19 e=1.6*10^-19 L=6*10^-3 R=120 A=0.5*10^-6 sigp=L/(R*A) p=sigp/(e*up) Na=p n=(ni^2)/Na sigm=n*e*um ratio=sigp/sigm printf("p-type impurity concentration\n") disp(p) printf("\nproportion of conductivity due to hole and electron\n") printf("ratio=%.f",ratio);printf(":1")
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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.")
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//Determining horizontal force F //From fig 2.14(b) //Resolving the forces //Fy=0 gives R=1500/cosd(30) //N //Fx=0 gives F=R*sind(30) //N printf("Horizontal force of F=%.0f N is required to be applied",F)
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clear; clc; Gt=25,Gr=18,r=200,Pr=5*10^-3 ; Gdt=10^(Gt/10),Gdr=10^(Gr/10); Pt=Pr*(4*%pi*r)^2 /(Gdr*Gdt); disp(Pt,'Minimum power received in Watt =');
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errcatch(-1,"stop");mode(2);//Find weight fractions //Ex:10.4 ; ; c_be=100; c_e=1.65; c_o=10; w=(c_be-c_o)/(c_be-c_e); disp(w,"weight fractions = "); exit();
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Ia=500 Ra=0.05 Vb=2 Va=Ia*Ra+Vb Vt=330 disp(Vt)
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//Solutions to Problems In applied mechanics //A N Gobby clear all; //equation of motion and acceleration clc //initialisation of variables d=4//ft w=5//lbf v=10//lbf q=9.27//ft/s //CALCULATIONS W=w*d//ft lbf P=v*d//ft lbf M=(q)^2/d/2//ft/s^2 //RESULTS printf('the equation of motion and acceleration=% f ft/s^2',M)
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sce
ATWM1_Working_Memory_MEG_Salient_Uncued_Run1.sce
# ATWM1 MEG Experiment scenario = "ATWM1_Working_Memory_MEG_salient_uncued_run1"; #scenario_type = fMRI; # Fuer Scanner #scenario_type = fMRI_emulation; # Zum Testen scenario_type = trials; # for MEG #scan_period = 2000; # TR #pulses_per_scan = 1; #pulse_code = 1; pulse_width=6; default_monitor_sounds = false; active_buttons = 2; response_matching = simple_matching; button_codes = 10, 20; default_font_size = 28; default_font = "Arial"; default_background_color = 0 ,0 ,0 ; write_codes=true; # for MEG only begin; #Picture definitions box { height = 300; width = 300; color = 0, 0, 0;} frame1; box { height = 290; width = 290; color = 255, 255, 255;} frame2; box { height = 30; width = 4; color = 0, 0, 0;} fix1; box { height = 4; width = 30; color = 0, 0, 0;} fix2; box { height = 30; width = 4; color = 255, 0, 0;} fix3; box { height = 4; width = 30; color = 255, 0, 0;} fix4; box { height = 290; width = 290; color = 128, 128, 128;} background; TEMPLATE "StimuliDeclaration.tem" {}; trial { sound sound_incorrect; time = 0; duration = 1; } wrong; trial { sound sound_correct; time = 0; duration = 1; } right; trial { sound sound_no_response; time = 0; duration = 1; } miss; # Start of experiment (MEG only) - sync with CTF software trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; } expStart; time = 0; duration = 1000; code = "ExpStart"; port_code = 80; }; # baselinePre (at the beginning of the session) trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; }default; time = 0; duration = 10000; #mri_pulse = 1; code = "BaselinePre"; port_code = 91; }; TEMPLATE "ATWM1_Working_Memory_MEG.tem" { trigger_encoding trigger_retrieval cue_time preparation_time encoding_time single_stimulus_presentation_time delay_time retrieval_time intertrial_interval alerting_cross stim_enc1 stim_enc2 stim_enc3 stim_enc4 stim_enc_alt1 stim_enc_alt2 stim_enc_alt3 stim_enc_alt4 trial_code stim_retr1 stim_retr2 stim_retr3 stim_retr4 stim_cue1 stim_cue2 stim_cue3 stim_cue4 fixationcross_cued retr_code the_target_button posX1 posY1 posX2 posY2 posX3 posY3 posX4 posY4; 42 62 292 292 399 125 1742 2992 2592 fixation_cross gabor_162 gabor_120 gabor_052 gabor_081 gabor_162_alt gabor_120 gabor_052_alt gabor_081 "1_1_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2600_gabor_patch_orientation_162_120_052_081_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_052_framed gabor_circ blank blank blank blank fixation_cross_white "1_1_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_052_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1992 2992 2142 fixation_cross gabor_055 gabor_014 gabor_032 gabor_084 gabor_055 gabor_014_alt gabor_032_alt gabor_084 "1_2_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2150_gabor_patch_orientation_055_014_032_084_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_032_framed gabor_circ blank blank blank blank fixation_cross_white "1_2_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_032_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2142 2992 2092 fixation_cross gabor_164 gabor_008 gabor_141 gabor_097 gabor_164 gabor_008_alt gabor_141 gabor_097_alt "1_3_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2100_gabor_patch_orientation_164_008_141_097_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_052_framed blank blank blank blank fixation_cross_white "1_3_Retrieval_Working_Memory_MEG_P5_LR_Salient_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; 42 61 292 292 399 125 1992 2992 2192 fixation_cross gabor_040 gabor_002 gabor_119 gabor_077 gabor_040 gabor_002 gabor_119_alt gabor_077_alt "1_4_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_2200_gabor_patch_orientation_040_002_119_077_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_166_framed gabor_circ blank blank blank blank fixation_cross_white "1_4_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_166_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2192 2992 1942 fixation_cross gabor_120 gabor_169 gabor_098 gabor_079 gabor_120 gabor_169 gabor_098_alt gabor_079_alt "1_5_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_1950_gabor_patch_orientation_120_169_098_079_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_049_framed gabor_circ blank blank blank blank fixation_cross_white "1_5_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_049_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2092 2992 2142 fixation_cross gabor_172 gabor_157 gabor_051 gabor_123 gabor_172_alt gabor_157 gabor_051_alt gabor_123 "1_6_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2150_gabor_patch_orientation_172_157_051_123_target_position_1_3_retrieval_position_1" gabor_172_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_6_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_172_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 63 292 292 399 125 2092 2992 1942 fixation_cross gabor_024 gabor_113 gabor_083 gabor_141 gabor_024 gabor_113_alt gabor_083_alt gabor_141 "1_7_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_300_300_399_2100_3000_1950_gabor_patch_orientation_024_113_083_141_target_position_2_3_retrieval_position_1" gabor_160_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_7_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_160_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2092 2992 2042 fixation_cross gabor_034 gabor_081 gabor_162 gabor_140 gabor_034 gabor_081_alt gabor_162_alt gabor_140 "1_8_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2050_gabor_patch_orientation_034_081_162_140_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_162_framed gabor_circ blank blank blank blank fixation_cross_white "1_8_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_162_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1792 2992 2192 fixation_cross gabor_102 gabor_153 gabor_016 gabor_037 gabor_102_alt gabor_153 gabor_016 gabor_037_alt "1_9_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2200_gabor_patch_orientation_102_153_016_037_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_037_framed blank blank blank blank fixation_cross_white "1_9_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_037_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 63 292 292 399 125 2042 2992 2042 fixation_cross gabor_074 gabor_118 gabor_133 gabor_012 gabor_074_alt gabor_118 gabor_133_alt gabor_012 "1_10_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_300_300_399_2050_3000_2050_gabor_patch_orientation_074_118_133_012_target_position_1_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_152_framed blank blank blank blank fixation_cross_white "1_10_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_152_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2042 2992 2592 fixation_cross gabor_138 gabor_098 gabor_082 gabor_155 gabor_138 gabor_098 gabor_082_alt gabor_155_alt "1_11_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_2600_gabor_patch_orientation_138_098_082_155_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_082_framed gabor_circ blank blank blank blank fixation_cross_white "1_11_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_082_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1892 2992 2592 fixation_cross gabor_042 gabor_152 gabor_177 gabor_065 gabor_042_alt gabor_152 gabor_177_alt gabor_065 "1_12_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2600_gabor_patch_orientation_042_152_177_065_target_position_1_3_retrieval_position_1" gabor_088_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_12_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_088_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1842 2992 2542 fixation_cross gabor_013 gabor_173 gabor_046 gabor_103 gabor_013 gabor_173_alt gabor_046_alt gabor_103 "1_13_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2550_gabor_patch_orientation_013_173_046_103_target_position_2_3_retrieval_position_2" gabor_circ gabor_173_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_13_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_173_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2242 2992 1892 fixation_cross gabor_142 gabor_002 gabor_121 gabor_034 gabor_142_alt gabor_002 gabor_121 gabor_034_alt "1_14_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_1900_gabor_patch_orientation_142_002_121_034_target_position_1_4_retrieval_position_1" gabor_142_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_14_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_142_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1992 2992 2492 fixation_cross gabor_051 gabor_177 gabor_009 gabor_116 gabor_051_alt gabor_177 gabor_009 gabor_116_alt "1_15_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2500_gabor_patch_orientation_051_177_009_116_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_116_framed blank blank blank blank fixation_cross_white "1_15_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_116_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1842 2992 2392 fixation_cross gabor_069 gabor_134 gabor_008 gabor_086 gabor_069_alt gabor_134 gabor_008_alt gabor_086 "1_16_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2400_gabor_patch_orientation_069_134_008_086_target_position_1_3_retrieval_position_1" gabor_114_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_16_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_114_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 64 292 292 399 125 1942 2992 2342 fixation_cross gabor_180 gabor_136 gabor_028 gabor_002 gabor_180 gabor_136_alt gabor_028_alt gabor_002 "1_17_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_300_300_399_1950_3000_2350_gabor_patch_orientation_180_136_028_002_target_position_2_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_002_framed blank blank blank blank fixation_cross_white "1_17_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_002_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1992 2992 1892 fixation_cross gabor_099 gabor_071 gabor_130 gabor_151 gabor_099 gabor_071_alt gabor_130 gabor_151_alt "1_18_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_1900_gabor_patch_orientation_099_071_130_151_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_012_framed blank blank blank blank fixation_cross_white "1_18_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_012_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 63 292 292 399 125 2242 2992 2342 fixation_cross gabor_055 gabor_091 gabor_121 gabor_004 gabor_055 gabor_091 gabor_121_alt gabor_004_alt "1_19_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_300_300_399_2250_3000_2350_gabor_patch_orientation_055_091_121_004_target_position_3_4_retrieval_position_2" gabor_circ gabor_141_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_19_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_141_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1792 2992 2292 fixation_cross gabor_148 gabor_133 gabor_087 gabor_018 gabor_148_alt gabor_133_alt gabor_087 gabor_018 "1_20_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2300_gabor_patch_orientation_148_133_087_018_target_position_1_2_retrieval_position_1" gabor_148_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_20_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_148_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2242 2992 2342 fixation_cross gabor_040 gabor_100 gabor_118 gabor_064 gabor_040_alt gabor_100 gabor_118_alt gabor_064 "1_21_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2350_gabor_patch_orientation_040_100_118_064_target_position_1_3_retrieval_position_1" gabor_040_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_21_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_040_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1842 2992 1992 fixation_cross gabor_041 gabor_127 gabor_176 gabor_110 gabor_041_alt gabor_127 gabor_176 gabor_110_alt "1_22_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2000_gabor_patch_orientation_041_127_176_110_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_110_framed blank blank blank blank fixation_cross_white "1_22_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_110_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1742 2992 2292 fixation_cross gabor_018 gabor_151 gabor_169 gabor_124 gabor_018 gabor_151_alt gabor_169 gabor_124_alt "1_23_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2300_gabor_patch_orientation_018_151_169_124_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_079_framed blank blank blank blank fixation_cross_white "1_23_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_079_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2242 2992 2292 fixation_cross gabor_156 gabor_087 gabor_025 gabor_069 gabor_156_alt gabor_087 gabor_025_alt gabor_069 "1_24_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2300_gabor_patch_orientation_156_087_025_069_target_position_1_3_retrieval_position_1" gabor_108_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_24_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_108_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2192 2992 2442 fixation_cross gabor_063 gabor_105 gabor_168 gabor_043 gabor_063_alt gabor_105 gabor_168_alt gabor_043 "1_25_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2450_gabor_patch_orientation_063_105_168_043_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_122_framed gabor_circ blank blank blank blank fixation_cross_white "1_25_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_122_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1742 2992 2242 fixation_cross gabor_172 gabor_034 gabor_139 gabor_002 gabor_172 gabor_034_alt gabor_139 gabor_002_alt "1_26_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2250_gabor_patch_orientation_172_034_139_002_target_position_2_4_retrieval_position_2" gabor_circ gabor_084_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_26_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_084_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 64 292 292 399 125 2192 2992 2392 fixation_cross gabor_090 gabor_156 gabor_120 gabor_009 gabor_090_alt gabor_156_alt gabor_120 gabor_009 "1_27_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_300_300_399_2200_3000_2400_gabor_patch_orientation_090_156_120_009_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_120_framed gabor_circ blank blank blank blank fixation_cross_white "1_27_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_120_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2192 2992 2442 fixation_cross gabor_119 gabor_103 gabor_044 gabor_063 gabor_119 gabor_103_alt gabor_044 gabor_063_alt "1_28_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2450_gabor_patch_orientation_119_103_044_063_target_position_2_4_retrieval_position_2" gabor_circ gabor_150_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_28_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_150_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1892 2992 2542 fixation_cross gabor_004 gabor_170 gabor_155 gabor_123 gabor_004_alt gabor_170_alt gabor_155 gabor_123 "1_29_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2550_gabor_patch_orientation_004_170_155_123_target_position_1_2_retrieval_position_2" gabor_circ gabor_170_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_29_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_170_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1742 2992 2592 fixation_cross gabor_038 gabor_125 gabor_158 gabor_020 gabor_038 gabor_125_alt gabor_158_alt gabor_020 "1_30_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2600_gabor_patch_orientation_038_125_158_020_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_158_framed gabor_circ blank blank blank blank fixation_cross_white "1_30_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_158_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1942 2992 1892 fixation_cross gabor_141 gabor_082 gabor_164 gabor_056 gabor_141_alt gabor_082 gabor_164 gabor_056_alt "1_31_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_1900_gabor_patch_orientation_141_082_164_056_target_position_1_4_retrieval_position_1" gabor_005_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_31_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_005_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1942 2992 2442 fixation_cross gabor_150 gabor_006 gabor_177 gabor_064 gabor_150_alt gabor_006 gabor_177 gabor_064_alt "1_32_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_2450_gabor_patch_orientation_150_006_177_064_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_112_framed blank blank blank blank fixation_cross_white "1_32_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_112_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 64 292 292 399 125 1992 2992 2042 fixation_cross gabor_122 gabor_013 gabor_081 gabor_049 gabor_122_alt gabor_013_alt gabor_081 gabor_049 "1_33_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_300_300_399_2000_3000_2050_gabor_patch_orientation_122_013_081_049_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_081_framed gabor_circ blank blank blank blank fixation_cross_white "1_33_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_081_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1892 2992 2242 fixation_cross gabor_180 gabor_101 gabor_146 gabor_122 gabor_180 gabor_101_alt gabor_146_alt gabor_122 "1_34_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2250_gabor_patch_orientation_180_101_146_122_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_146_framed gabor_circ blank blank blank blank fixation_cross_white "1_34_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_146_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1892 2992 2492 fixation_cross gabor_146 gabor_086 gabor_123 gabor_037 gabor_146_alt gabor_086 gabor_123 gabor_037_alt "1_35_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2500_gabor_patch_orientation_146_086_123_037_target_position_1_4_retrieval_position_1" gabor_010_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_35_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_010_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 63 292 292 399 125 1792 2992 2092 fixation_cross gabor_087 gabor_024 gabor_049 gabor_008 gabor_087 gabor_024 gabor_049_alt gabor_008_alt "1_36_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_300_300_399_1800_3000_2100_gabor_patch_orientation_087_024_049_008_target_position_3_4_retrieval_position_1" gabor_136_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_36_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_136_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1792 2992 1892 fixation_cross gabor_075 gabor_161 gabor_091 gabor_132 gabor_075_alt gabor_161 gabor_091_alt gabor_132 "1_37_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_1900_gabor_patch_orientation_075_161_091_132_target_position_1_3_retrieval_position_1" gabor_075_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_37_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_075_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2042 2992 2492 fixation_cross gabor_058 gabor_090 gabor_004 gabor_176 gabor_058_alt gabor_090 gabor_004 gabor_176_alt "1_38_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2500_gabor_patch_orientation_058_090_004_176_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_038_framed blank blank blank blank fixation_cross_white "1_38_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_038_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1792 2992 2092 fixation_cross gabor_178 gabor_068 gabor_037 gabor_111 gabor_178_alt gabor_068 gabor_037 gabor_111_alt "1_39_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2100_gabor_patch_orientation_178_068_037_111_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_111_framed blank blank blank blank fixation_cross_white "1_39_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_111_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 64 292 292 399 125 1892 2992 2542 fixation_cross gabor_002 gabor_107 gabor_045 gabor_165 gabor_002 gabor_107_alt gabor_045_alt gabor_165 "1_40_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_300_300_399_1900_3000_2550_gabor_patch_orientation_002_107_045_165_target_position_2_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_165_framed blank blank blank blank fixation_cross_white "1_40_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_165_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1942 2992 1992 fixation_cross gabor_087 gabor_136 gabor_117 gabor_168 gabor_087_alt gabor_136 gabor_117 gabor_168_alt "1_41_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_2000_gabor_patch_orientation_087_136_117_168_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_029_framed blank blank blank blank fixation_cross_white "1_41_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_029_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1742 2992 2342 fixation_cross gabor_170 gabor_013 gabor_103 gabor_120 gabor_170 gabor_013_alt gabor_103_alt gabor_120 "1_42_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2350_gabor_patch_orientation_170_013_103_120_target_position_2_3_retrieval_position_2" gabor_circ gabor_013_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_42_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_013_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1742 2992 2492 fixation_cross gabor_075 gabor_108 gabor_018 gabor_142 gabor_075 gabor_108_alt gabor_018 gabor_142_alt "1_43_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2500_gabor_patch_orientation_075_108_018_142_target_position_2_4_retrieval_position_2" gabor_circ gabor_108_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_43_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_108_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1792 2992 2242 fixation_cross gabor_066 gabor_110 gabor_141 gabor_081 gabor_066_alt gabor_110 gabor_141 gabor_081_alt "1_44_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2250_gabor_patch_orientation_066_110_141_081_target_position_1_4_retrieval_position_1" gabor_066_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_44_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_066_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1992 2992 2392 fixation_cross gabor_038 gabor_124 gabor_095 gabor_158 gabor_038 gabor_124 gabor_095_alt gabor_158_alt "1_45_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_2400_gabor_patch_orientation_038_124_095_158_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_018_framed blank blank blank blank fixation_cross_white "1_45_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_018_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 63 292 292 399 125 1842 2992 2142 fixation_cross gabor_117 gabor_081 gabor_028 gabor_142 gabor_117_alt gabor_081 gabor_028 gabor_142_alt "1_46_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_300_300_399_1850_3000_2150_gabor_patch_orientation_117_081_028_142_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_165_framed gabor_circ blank blank blank blank fixation_cross_white "1_46_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_165_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1892 2992 2042 fixation_cross gabor_059 gabor_118 gabor_136 gabor_094 gabor_059 gabor_118_alt gabor_136_alt gabor_094 "1_47_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2050_gabor_patch_orientation_059_118_136_094_target_position_2_3_retrieval_position_2" gabor_circ gabor_165_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_47_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_165_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2192 2992 2242 fixation_cross gabor_131 gabor_175 gabor_008 gabor_060 gabor_131 gabor_175_alt gabor_008_alt gabor_060 "1_48_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2250_gabor_patch_orientation_131_175_008_060_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_147_framed gabor_circ blank blank blank blank fixation_cross_white "1_48_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_147_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2242 2992 1892 fixation_cross gabor_180 gabor_100 gabor_012 gabor_132 gabor_180 gabor_100_alt gabor_012_alt gabor_132 "1_49_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_1900_gabor_patch_orientation_180_100_012_132_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_062_framed gabor_circ blank blank blank blank fixation_cross_white "1_49_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_062_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 64 292 292 399 125 1742 2992 2192 fixation_cross gabor_071 gabor_027 gabor_087 gabor_053 gabor_071_alt gabor_027 gabor_087 gabor_053_alt "1_50_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_300_300_399_1750_3000_2200_gabor_patch_orientation_071_027_087_053_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_087_framed gabor_circ blank blank blank blank fixation_cross_white "1_50_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_087_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1792 2992 1942 fixation_cross gabor_163 gabor_086 gabor_002 gabor_127 gabor_163 gabor_086 gabor_002_alt gabor_127_alt "1_51_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_1950_gabor_patch_orientation_163_086_002_127_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_047_framed gabor_circ blank blank blank blank fixation_cross_white "1_51_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_047_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2142 2992 2042 fixation_cross gabor_062 gabor_152 gabor_135 gabor_088 gabor_062 gabor_152_alt gabor_135_alt gabor_088 "1_52_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2050_gabor_patch_orientation_062_152_135_088_target_position_2_3_retrieval_position_2" gabor_circ gabor_013_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_52_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_013_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1842 2992 2192 fixation_cross gabor_070 gabor_122 gabor_038 gabor_100 gabor_070_alt gabor_122 gabor_038 gabor_100_alt "1_53_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2200_gabor_patch_orientation_070_122_038_100_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_100_framed blank blank blank blank fixation_cross_white "1_53_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_100_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2142 2992 2292 fixation_cross gabor_064 gabor_172 gabor_085 gabor_124 gabor_064_alt gabor_172_alt gabor_085 gabor_124 "1_54_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2150_3000_2300_gabor_patch_orientation_064_172_085_124_target_position_1_2_retrieval_position_2" gabor_circ gabor_035_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_54_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_035_retrieval_position_2" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 63 292 292 399 125 2192 2992 2242 fixation_cross gabor_034 gabor_177 gabor_113 gabor_153 gabor_034_alt gabor_177 gabor_113 gabor_153_alt "1_55_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_300_300_399_2200_3000_2250_gabor_patch_orientation_034_177_113_153_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_063_framed gabor_circ blank blank blank blank fixation_cross_white "1_55_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_063_retrieval_position_3" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2092 2992 1992 fixation_cross gabor_093 gabor_132 gabor_078 gabor_026 gabor_093_alt gabor_132 gabor_078 gabor_026_alt "1_56_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2100_3000_2000_gabor_patch_orientation_093_132_078_026_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_162_framed blank blank blank blank fixation_cross_white "1_56_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_162_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2042 2992 2392 fixation_cross gabor_139 gabor_098 gabor_082 gabor_064 gabor_139 gabor_098 gabor_082_alt gabor_064_alt "1_57_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2400_gabor_patch_orientation_139_098_082_064_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_016_framed blank blank blank blank fixation_cross_white "1_57_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_016_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2092 2992 2342 fixation_cross gabor_121 gabor_105 gabor_170 gabor_088 gabor_121_alt gabor_105 gabor_170_alt gabor_088 "1_58_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2100_3000_2350_gabor_patch_orientation_121_105_170_088_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_170_framed gabor_circ blank blank blank blank fixation_cross_white "1_58_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_170_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1842 2992 2442 fixation_cross gabor_057 gabor_034 gabor_114 gabor_169 gabor_057_alt gabor_034 gabor_114 gabor_169_alt "1_59_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2450_gabor_patch_orientation_057_034_114_169_target_position_1_4_retrieval_position_1" gabor_057_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_59_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_057_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 1942 2992 2192 fixation_cross gabor_085 gabor_109 gabor_049 gabor_125 gabor_085_alt gabor_109 gabor_049_alt gabor_125 "1_60_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_2200_gabor_patch_orientation_085_109_049_125_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_049_framed gabor_circ blank blank blank blank fixation_cross_white "1_60_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_049_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 64 292 292 399 125 2142 2992 1942 fixation_cross gabor_180 gabor_043 gabor_158 gabor_091 gabor_180 gabor_043_alt gabor_158 gabor_091_alt "1_61_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_300_300_399_2150_3000_1950_gabor_patch_orientation_180_043_158_091_target_position_2_4_retrieval_position_1" gabor_180_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_61_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_180_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1842 2992 1942 fixation_cross gabor_134 gabor_071 gabor_103 gabor_020 gabor_134_alt gabor_071 gabor_103_alt gabor_020 "1_62_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_1950_gabor_patch_orientation_134_071_103_020_target_position_1_3_retrieval_position_1" gabor_087_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_62_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_087_retrieval_position_1" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 2042 2992 1992 fixation_cross gabor_108 gabor_042 gabor_071 gabor_087 gabor_108 gabor_042_alt gabor_071_alt gabor_087 "1_63_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2000_gabor_patch_orientation_108_042_071_087_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_021_framed gabor_circ blank blank blank blank fixation_cross_white "1_63_Retrieval_Working_Memory_MEG_P5_LR_Salient_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; 42 62 292 292 399 125 2142 2992 1992 fixation_cross gabor_104 gabor_085 gabor_142 gabor_169 gabor_104 gabor_085_alt gabor_142 gabor_169_alt "1_64_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_2000_gabor_patch_orientation_104_085_142_169_target_position_2_4_retrieval_position_2" gabor_circ gabor_085_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_64_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_085_retrieval_position_2" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2142 2992 2292 fixation_cross gabor_132 gabor_104 gabor_086 gabor_159 gabor_132 gabor_104 gabor_086_alt gabor_159_alt "1_65_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_2300_gabor_patch_orientation_132_104_086_159_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_159_framed blank blank blank blank fixation_cross_white "1_65_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_159_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2242 2992 2092 fixation_cross gabor_042 gabor_099 gabor_131 gabor_063 gabor_042 gabor_099_alt gabor_131 gabor_063_alt "1_66_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2100_gabor_patch_orientation_042_099_131_063_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_063_framed blank blank blank blank fixation_cross_white "1_66_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_063_retrieval_position_4" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 61 292 292 399 125 1892 2992 2142 fixation_cross gabor_068 gabor_153 gabor_017 gabor_042 gabor_068 gabor_153 gabor_017_alt gabor_042_alt "1_67_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2150_gabor_patch_orientation_068_153_017_042_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_179_framed blank blank blank blank fixation_cross_white "1_67_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_179_retrieval_position_4" 2 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 64 292 292 399 125 1942 2992 2142 fixation_cross gabor_046 gabor_110 gabor_031 gabor_002 gabor_046 gabor_110_alt gabor_031 gabor_002_alt "1_68_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_300_300_399_1950_3000_2150_gabor_patch_orientation_046_110_031_002_target_position_2_4_retrieval_position_3" gabor_circ gabor_circ gabor_031_framed gabor_circ blank blank blank blank fixation_cross_white "1_68_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_031_retrieval_position_3" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 62 292 292 399 125 2042 2992 2092 fixation_cross gabor_070 gabor_052 gabor_142 gabor_160 gabor_070_alt gabor_052 gabor_142 gabor_160_alt "1_69_Encoding_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_2100_gabor_patch_orientation_070_052_142_160_target_position_1_4_retrieval_position_1" gabor_070_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_69_Retrieval_Working_Memory_MEG_P5_LR_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_070_retrieval_position_1" 1 45.96 45.96 -45.96 45.96 -45.96 -45.96 45.96 -45.96; 42 63 292 292 399 125 2092 2992 2542 fixation_cross gabor_034 gabor_173 gabor_096 gabor_119 gabor_034_alt gabor_173 gabor_096 gabor_119_alt "1_70_Encoding_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_300_300_399_2100_3000_2550_gabor_patch_orientation_034_173_096_119_target_position_1_4_retrieval_position_3" gabor_circ gabor_circ gabor_050_framed gabor_circ blank blank blank blank fixation_cross_white "1_70_Retrieval_Working_Memory_MEG_P5_LR_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_050_retrieval_position_3" 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 = 5000; code = "BaselinePost"; port_code = 92; };
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//Chapter 11 Example 3// clc clear // from the diagram line voltage=5V and potential across each disk=V// vl=5; vd=1; s1=vd/(vl-vd); printf("\n At point A line to pin capacitance = %.2fC \n",s1); // at point b v=2V// vd=2; s2=vd/(vl-vd); printf("\n At point B line to pin capacitance = %.2fC \n",s2); // at point c v=3V// vd=3; s3=vd/(vl-vd); printf("\n At point C line to pin capacitance = %.2fC \n",s3); // at point d v=4V// vd=4; s4=vd/(vl-vd); printf("\n At point D line to pin capacitance = %.2fC \n",s4);
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clear clc //Example 17.5 disp('Example 17.5') deltaT=[0.05 0.25 0.5 1]';//sampling time K=-20; theta=1+(deltaT/2);//Add half of sampling time to delay for finding PI settings tau=5; //Table 11.3 ITAE disturbance settings //Note that there is an error in book solution saying Table 11.2 //It should be table 11.3 Y=0.859*(theta/tau)^(-0.977);Kc=Y/K; taui=tau*(0.674*(theta/tau)^-0.680).^-1; mprintf('\n ITAE(disturbance) \n') mprintf(' deltaT Kc tauI') mprintf('\n %f %f %f',deltaT,Kc,taui) //Finding digital controller settings //Eqn 17-55 a0=1+deltaT./taui; a1=-(1); //since tauD=0 a2=0; z=%z; Gcz=Kc.*(a0+a1*z^-1)./(1-z^-1); //Refer to table 17.1 to convert continuous transfer function to digital form Gp=K*(1-exp(-1/tau*deltaT)).*z^(-1+(-1)./deltaT)./(1-exp((-1)/tau*deltaT)*z^-1);//z^(-1/deltaT) for delay G_CL=syslin('d',((Gp)./(Gcz.*Gp+1))); t=0:deltaT(1):15 u=ones(1,length(t)); yt=flts(u,G_CL(1,1)); plot(t,yt,'-') t=0:deltaT(2):15 u=ones(1,length(t)); yt=flts(u,G_CL(2,1)); plot(t,yt,'green--') t=0:deltaT(3):15 u=ones(1,length(t)); yt=flts(u,G_CL(3,1)); plot(t,yt,'black-.') t=0:deltaT(4):15 u=ones(1,length(t)); yt=flts(u,G_CL(4,1)); plot(t,yt,'red:') set(gca(),"data_bounds",[0 15 -8 1]); //putting bounds on display l=legend("$\Delta t=0.05\ min$","$\Delta t=0.25\ min$","$\Delta t=0.5\ min$","$\Delta t=1\ min$",position=4); xtitle("Example 17.5","Time(min)","$y$"); a=get("current_axes"); c=a.y_label;c.font_size=5; mprintf("\nNote that there is a mismatch between the book simulation and what\n... what we get from SCILAB. The book is wrong. This has been crosschecked using\n... simulation in SIMULINK(MATLAB)")
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clc clear printf("example 3.6 page number 94\n\n") //to find the flow rate and concentration G1 = 3600 //in m3/h P = 106.6 //in kPa T = 40 //in degree C q = G1*(P/101.3)*(273/((273+T))); //in m3/s m = q/22.4; //in kmol/h y1 = 0.02; Y1 = y1/(1-y1); printf("mole ratio of benzene = %f kmol benzene/kmol dry gas",Y1) Gs = m*(1-y1); printf("\n\nmoles of benzene free gas = %f kmol drygas/h",Gs) //for 95% removal Y2 = Y1*(1-0.95); printf("\n\nfinal mole ratio of benzene = %f kmol benzene/kmol dry gas",Y2) x2 = 0.002 X2 = 0.002/(1-0.002); //at equilibrium y* = 0.2406X //part 1 //for oil rate to be minimum the wash oil leaving the absorber must be in equilibrium with the entering gas y1 = 0.02; x1 = y1/(0.2406); X1 = x1/(1-x1); min_Ls = Gs*((Y1-Y2)/(X1-X2)); printf("\n\nminimum Ls required = %f kg/h",min_Ls*260) //for 1.5 times of the minimum Ls = 1.5*min_Ls; printf("\n\nflow rate of wash oil = %f kg/h",Ls*260) X1 = X2 + (Gs*((Y1-Y2)/Ls)); printf("\n\nconcentration of benzene in wash oil = %f kmol benzene/kmol wash oil",X1)
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//Exam:5.3 clc; clear; close; T=300;//Temperature(in Kelevin) t=2*10^-14;//time(in sec) V_c=8.9;//volume of 63.54gm of copper(in cc) Aw_c=63.54;//Atomic weight of copper(in a.m.u) e=1.6*10^(-19); m=9.1*10^-31; N_a=6.023*10^23;//avogadro's number n=(N_a/(Aw_c/V_c))*10^6;//Number of electrons per m^3 conductivity=(e^2)*n*t/m;//conductivity of copper at 300K(in mho/m) disp(conductivity,'conductivity of copper at 300K(in mho/m)=');
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// Generation du maillage d'un terrain // definition d'un profil et extrusion clear xmin = 0; xmax = 100; ymin = 0; ymax = 100; // Nb de points du maillage Nx = 50; // nb d'ecartements en x Ny = 50; // nb d'ecartements en y X = [xmin:(xmax-xmin)/(Nx-1):xmax]'; Y = [ymin:(ymax-ymin)/(Ny-1):ymax]'; Z = []; xlim = 40; for i=1:Nx, x = X(i); if x<xlim then, z = 0.09 * x; zlim = 0.09 * xlim; else z = 0.02 * (x - xlim) + zlim; end Z = [Z ; z]; end clf plot2d(X, Z, style=-1); // visu profil X1 = X; Y1 = Y; Z1 = Z; // extrusion for i=1:Nx-1, Y = [Y ; Y1]; end for j=1:Ny-1, X = [X ; X1]; Z = [Z ; Z1]; end // Generation du fichier csv DIR = "" //DIR = "/Users/scls/openphysic/scilab/divers/digital_elevation_model/" //DIR = "C:\" fd = mopen(DIR+"mnt2.csv","w"); // ouverture en ecriture d'un fichier sep = ","; mfprintf(fd,"%.3f"+sep+"%.3f"+sep+"%.3f"+"\n",X,Y,Z); // sortie fichier mclose(fd); // fermeture du fichier halt clf //plot3d(X,Y,Z); param3d(X,Y,Z); p=gce();//get the handle on the just drawn polyline p.mark_mode='on';//enable the mark drawing (a mark at each given point) p.line_mode='off';//disable line drawing between given points //drawlater(); //param3d1(X,Y,list(Z,ones(Z))) //drawnow(); //halt //xdel
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/starter_files/hw2/Not4.tst
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Not4.tst
load Not4.hdl, output-file Not4.out, compare-to Not4.cmp, output-list in%B3.4.3 out%B3.4.3; set in 0, eval, output; set in 1, eval, output; set in 2, eval, output; set in 3, eval, output; set in 4, eval, output; set in 5, eval, output; set in 6, eval, output; set in 7, eval, output; set in 8, eval, output; set in 9, eval, output; set in 10, eval, output; set in 11, eval, output; set in 12, eval, output; set in 13, eval, output; set in 14, eval, output; set in 15, eval, output;
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Example3_21.sce
//Example 3.21 //Program to Compute Linear Convolution of following sequences //x[n]=[1,2,-1,2,3,-2,-3,-1,1,1,2,-1] //h[n]=[1,2] clear; clc ; close ; x=[1,2,-1,2,3,-2,-3,-1,1,1,2,-1]; h=[1,2]; // Linear Convolution Computation y=convol (x,h); //Display Sequence y[n] in command window disp(y,"y[n]=");
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10_3.sce
clc clear //Input data T1=300;//The maximum temperature at which carnot cycle operates in K T2=250;//The minimum temperature at which carnot cycle operates in K //Calculations COPr=T2/(T1-T2);//COP of the refrigerating machine COPh=T1/(T1-T2)//COP of heat pump n=((T1-T2)/T1)*100;//COP or efficiency of the heat engine in percentage //Output data printf('(a)COP of the machine when it is operated as a refrigerating machine is %3.2f\n (b)COP when it is operated as heat pump is %3.2f\n (c)COP or efficiency of the Heat engine is %3.2f percent',COPr,COPh,n)
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Ex1_9.sce
//Example 1_9 page no:100 clc; //given T = 1400; Tl = 1900; k = 7.85/1400; motor_rpm = 750; //calculating load torque Tm = Tl - (Tl/1.53); slip = k * 660; speed = motor_rpm - 35.2; disp("After 5s"); disp(Tm,"the torque at the end of 5s is (in Nm)"); disp(slip,"the slip is (in rad/s)"); disp(speed,"the speed is(rpm)"); Tm = (Tl)-( Tl - 0)*exp(-0.085*10); disp("After 10s"); disp(Tm,"the torque at the end of 10s is (in Nm)"); slip = k * 1088; speed = motor_rpm - 58; disp(slip,"the slip is (in rad/s)"); disp(speed,"the speed is(rpm)"); T_m = 1088; Tm = 280 + ( T_m - 280)*exp(-0.085*15); disp("After 15s"); disp(Tm,"the torque at the end of 15s is (in Nm)"); slip = k * Tm; speed = motor_rpm - 27; disp(slip,"the slip is (in rad/s)"); disp(speed,"the speed is(rpm)"); Tm = 280 + ( 1088 - 280)*exp(-0.085*30); slip = k * 343; speed = motor_rpm - 18.4; disp("After 30s"); disp(Tm,"the torque at the end of 30s is (in Nm)"); disp(slip,"the slip is (in rad/s)"); disp(speed,"the speed is(rpm)"); Tm = Tl - (Tl - 280)*exp(-0.085*10) slip = k * 1235; speed = motor_rpm - 66; disp("At the end of this period"); disp(Tm,"the torque at the end of this period is (in Nm)"); disp(slip,"the slip is (in rad/s)"); disp(speed,"the speed is(rpm)"); Tm = 280 + ( 1235 - 280)*exp(-0.085*30); slip = k * Tm; speed = motor_rpm - 19; disp("At the end of second off-peak period"); disp(Tm,"the torque at the end of this period is (in Nm)"); disp(slip,"the slip is (in rad/s)"); disp(speed,"the speed is(rpm)"); //the result vary slightly hence values are rounded off in text book
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12_1w.sce
//developed in windows XP operating system 32bit //platform Scilab 5.4.1 clc;clear; //example 12.1w //calculation of the amplitude,time period,maximum speed and velocity at time t //given data //x = (5 m)*sind((%pi s^-1)t + (180/3))......equation of simple harmonic motion //calculation A=5//amplitude(in m) w=%pi T=(2*%pi)/w//time period(in s) vmax=A*w//maximum speed v=A*w*cosd(180+(180/3)) printf('the amplitude is %d m',A) printf('\nthe time period is %d s',T) printf('\nthe maximum speed is %3.2f m/s',vmax) printf('\nthe velocity at time t=1 s is %3.2f m/s',v)
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Ex3_12.sce
clear // //given //case a B=1 //Wb/m**2 u1=4*3.14*10**-7 A=10**-4 //cm**2 per=800 //permeability n=250 //number of turns flux=B*A printf("\n flux %0.5f Wb",flux) r=781250 //AT/Wb calculated using formula for reluctance mmf=flux*r //AT i=mmf/n //exciting current required in A printf("\n i %0.5f A",i) l=(n*flux)/i //self inductance of the coil printf("\n l= %0.5f H",l) w=(l*i*i)/2 //energy stored printf("\n w= %0.5f J",w) //case b airgap=1*10**-3 //air gap is assumed rair=airgap/(u1*A) //reluctance of air gap in AT/Wb mmfa=flux*rair //mmf of air in AT printf("\n mmfa") //rcore=((2.5*3.14)-0.1)/(32*3.14*10**-6) //reluctance of core //mmfc=flux*rcore mmfc=780 //AT F=mmfc+mmfa I=F/n //A printf("\n exciting current= %0.2f A",I) n=250 //number of turns L=(n*flux)/I //self inductanc eof coil with air gap printf("\n l= %0.5f H",L) e=(L*I*I)/2 //energy stored in coil printf("\n e= %0.5f J",e)
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Example4_6.sce
//Example 4.6 //Program to find the DFT of a Sequence x[n]=[1,2,3,4,4,3,2,1] //using DIT Algorithm. clear; clc ; close ; x = [1,2,3,4,4,3,2,1]; //FFT Computation X = fft (x , -1); disp(X,'X(z) = ');
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chapter7_ex12.sce
clc clear //input r=20;//resistance of resistor connected in series with inductor in ohms v=240;//supply voltage in volts f=50;//supply frequency in hertz pdr=130;//potential drop across resistor in volts pdl=170;//potential drop across inductor in volts //calculations cosp=((v*v)-(pdr^2)-(pdl^2))/(2*pdr*pdl);//power factor i=pdr/r;//current in amperes p=pdl*i*cosp;//power in watts //output mprintf('the power dissipated by the inductor is %3.0f W',p)
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Ex5_4.sce
//Example 5.4 //Root locus for satellite attitude control with modified //PD control or Lead compensator. xdel(winsid())//close all graphics Windows clear; clc; //------------------------------------------------------------------ //System transfer function and its root locus s=poly(0,'s'); sysL=(s+1)/(s^2*(s+12)); evans(sysL,100) //Title, labels and grid to the figure exec .\fig_settings.sci; // custom script for setting figure properties title(['Root locus for', '$L(s)=(s+1)/s^2(s+12)$'],'fontsize',3) zoom_rect([-6 -3 2 3]) h=legend(''); h.visible = "off" //------------------------------------------------------------------
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example1_sce.sce
// chapter 11 // example 11.1 //page 394 Rt=10*10^3;Ct=.005*10^-6;C=10*10^-6; V=20;//in volts fout=.25/(Ct*Rt);//free running frequency disp(fout) fL=(8*fout)/V;//lock range disp(fL)// it may be -ve or +ve fc=sqrt(fL/(2*3.14*3.6*1000*C));// capture range disp(fc)
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ex2_25.sce
V1=70.71 //Defining voltage equations in rectangular form V2=%i*176.78 V3=91.86+%i*53.04 V4=100-%i*100; V=V1+V2+V3+V4; [Ro,Theta]=polar(V); function y=f(t), y=Ro*sqrt(2)*sin(t+Theta), endfunction disp("Volts",Ro*sqrt(2),"Maximum Voltage value with V2 polarity as it is") V=V1-V2+V3+V4; [Ro1,Theta1]=polar(V); function y1=f(t), y1=Ro1*sqrt(2)*sin(t+Theta), endfunction disp("Volts",Ro1*sqrt(2),"Maximum Voltage value with polarity of V2 reversed")
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clc clear //Input data Po1=500 //Stagnation pressure in kPa To1=600 //Stagnation temperature in K C1=100 //inlet velocity in m/s A1=0.01 //Inlet Area in m^2 A2=0.01 //Exit Area in m^2 Mx=1.2 //Mach number before the shock Ax=37.6 //Area just before the shock in cm^2 Ay=37.6 //Area just after the shock in cm^2 Px=109.9 //Pressure before the shock in kPa Poy=350 //Stagnation pressure after shock in kPa k=1.4 //Adiabatic constant R=287 //Specific gas constant in J/kg-K Cp=1005 //Specific heat capacity at constant volume in J/kg-K //Calculation T1=To1+(C1^2/(2*Cp)) //Inlet static temperature in K ai_1=sqrt(k*R*T1) //Velocity of sound at inlet in m/s M1=C1/ai_1 //Inlet Mach number p1=0.973 //Static to Stagnation pressure ratio at entry from gas tables @M1 P1=Po1*p1 //Inlet static pressure in kPa d1=P1*10^3/(R*T1) //Density at inlet in kg/m^3, P1 in Pa m=d1*A1*C1 //Mass flow rate at inlet in kg/s p2=0.528 //Ratio of critical pressure to stagnation pressure from gas tables @M=1 Pt=Po1*p2 //Critical pressure in kPa t1=0.834 //Ratio of critical temperature to stagnation temperature from gas tables @M=1 Tt=t1*To1 //critical temperature in K ai_t=sqrt(k*R*Tt) //Velocity of sound at critical state in m/s Ct=ai_t //Velocity of air at critical state in m/s a1=2.964 //Ratio of inlet area to critical area from gas tables @M=1 At=A1/a1 //critical area in m^2 dt=Pt/(R*Tt) //Density at critical state in kg/m^3 mt=dt*At*Ct //Mass flow rate at critical satate in kg/s //Sub-division (a) a2=1.030 //Ratio of area after shock to critical area from gas tables @Mx Ay_a=At*a2 //Area after shock in cm^2 p3=0.412 //Ratio of upstram of shock to stagnation pressures from isentropic gas tables @Mx Px_a=Po1*p3 //Pressure upstram of shock in kPa t2=0.776 //Ratio of upstram of shock to stagnation temperature from isentropic gas tables @Mx Tx_a=To1*t2 //Temperature upstram of shock in K My_a=0.84 //Mach number downstream of shock from normal shock gas tables @Mx p4=1.497 //Static pressure ratio after and before the shock from gas tables @My Py_a=Px_a*p4 //Static pressure after shock in kPa t3=1.099 //Temperature ratio after and before the shock from gas tables @My Ty_a=Tx_a*t3 //Temperature ratio after the shock in K p5=2.407 //Stagnation pressure after shock to Static pressure before shock from gas tables @My Poy_a=Px_a*p5 //Stagnation pressure after shock in kPa a3=1.204 //Ratio of area after shock to throat area after shock from isentropic gas tables @My At2_a=(Ay_a/a3)*10^4 //Throat area at exit in m^2, calculation mistake in textbook a4=A2/At2_a //Ratio of areas to find gas tables M2_a=0.2 //Exit mach number at section-A from gas tables @a4 p5=0.973 //ratio of exit pressure to stagnation pressure after shock from gas tables P2_a=p5*Poy_a //exit pressure in kPa //Sub-division (b) a5=Ax/At //Ratio of area before shock to critical area Mx_b=1.4 //Mach number at section-B from gas tables @a5 p6=0.314 //Ratio of upstram of shock to stagnation pressures from isentropic gas tables @Mx_b Px_b=Po1*p6 //Pressure upstram of shock in kPa t4=0.718 //Ratio of upstram of shock to stagnation temperature from isentropic gas tables @Mx_b Tx_b=To1*t4 //Temperature upstram of shock in K p20=3.049 //Stagnation pressure ratio after shock to Static pressure before shock from gas tables Poy_b=Px_b*p20 //Stagnation pressure after shock in kPa My_b=0.735 //Mach number downstream of shock from normal shock gas tables @Mx_b p7=2.085 //Static pressure ratio after and before the shock from gas tables @My_b Py_b=Px_b*p7 //Static pressure after shock in kPa t5=1.260 //Temperature ratio after and before the shock from gas tables @My_b Ty_b=Tx_b*t5 //Temperature after the shock in K a6=1.071 //Ratio of area after shock to throat area after shock from isentropic gas tables My_b=0.735 At2_b=Ay/a6 //Throat area at exit in m^2 a7=A2/At2_b //Ratio of areas M2_b=0.21 //Exit mach number at section-B from gas tables @a7 p8=0.9697 //ratio of exit pressure to stagnation pressure after shock from gas tables P2_b=p8*Poy_b //exit pressure in kPa //Sub-division (c) p9=Px/Po1 //Ratio of upstram of shock to stagnation pressures Mx_c=1.65 //Mach number at section-B from gas tables @p9 a8=1.292 //Ratio of area before shock to critical area from gas tables @p9 Ax_c=At*a8*10^4 //Area before shock in cm^2 t6=0.647 //Ratio of upstram of shock to stagnation temperature from isentropic gas tables @p9 Tx_c=To1*t6 //Temperature upstram of shock in K My_c=0.654 //Mach number downstream of shock from normal shock gas tables @Mx_c p10=3.0095 //Static pressure ratio after and before the shock from gas tables @My_c Py_c=Px*p10 //Pressure downstram of shock in kPa t7=1.423 //Temperature ratio after and before the shock from gas tables @My_c Ty_c=Tx_c*t7 //Temperature after the shock in K p12=4 //Stagnation pressure after shock to Static pressure before shock from gas tables @Mx_c Poy_c=Px*p12 //Stagnation pressure after shock in kPa a9=1.136 //Ratio of area after shock to throat area after shock from gas tables My_c=0.654 At2_c=Ax_c/a9 //Throat area at exit in m^2 a8=A2/At2_c //Ratio of areas M2_c=0.23 //Exit mach number at section-B from gas tables @a8 p11=0.964 //ratio of exit pressure to stagnation pressure after shock from gas tables P2_c=p11*Poy_c //exit pressure in kPa //Sub-division (D) p13=Poy/Po1 //Pressure ratio, Since Pox=Po1 Mx_d=2.04 //Mach number upstream of shock from gas tables @p13 My_d=0.571 //Mach number downstream of shock from gas tables @p13 p14=4.688 //Static pressure ratio after and before the shock from gas tables @My_d t8=1.72 //Temperature ratio after and before the shock from gas tables @My_d p15=5.847 //Stagnation pressure after shock to Static pressure before shock from gas tables @Mx_d p16=0.120 //Ratio of upstram of shock to stagnation pressures from isentropic tables @Mx_d Px_d=Po1*p16 //Pressure upstram of shock in kPa t9=0.546 //Ratio of upstram of shock to stagnation temperature from isentropic gas tables @Mx_d Tx_d=To1*t9 //Temperature upstram of shock in K p21=4.688 //Static pressure ratio after and before the shock from gas tables Py_d=Px_d*p21 //Pressure downstram of shock in kPa t12=1.72 //Ratio of upstram of shock to stagnation temperature from isentropic gas tables Ty_d=Tx_d*t12 //Temperature after the shock in K a9=1.745 //Ratio of area before shock to throat area from isentropic gas tables Ax_d=At*a9*10^4 //Area before shock in cm^2 a10=1.226 //Ratio of area after shock to throat area after shock from isentropic tables @My_d At2_d=(Ax_d/a10) //Throat area at exit in cm^2 a11=A2/At2_d //Ratio of areas M2_d=0.29 //Exit mach number at section-B from gas tables @a11 p17=0.943 //ratio of exit pressure to stagnation pressure after shock from gas tables P2_d=p17*Poy //exit pressure in kPa //Sub-division (e) a12=Ax/At //Ratio of areas Mx_e=2.62 //Mach number upstream of shock from gas tables @a12 t10=0.421 //Ratio of upstram of shock to stagnation temperature from isentropic gas tables Tx_e=To1*t10 //Temperature upstram of shock in K p18=0.0486 //Ratio of upstram of shock to stagnation pressures from isentropic tables @Mx_e Px_e=p18*Po1 //Pressure upstram of shock in kPa My_e=0.502 //Mach number downstream of shock from gas tables @Mx_e p19=7.842 //Static pressure ratio after and before the shock from gas tables @My_e Py_e=Px_e*p19 //Pressure downstram of shock in kPa P2_e=Py_e //Exit pressure in kPa t11=2.259 //Temperature ratio after and before the shock from gas tables @My_d Ty_e=Tx_e*t11 //Temperaure downstram of shock in K T2_e=Ty_e //Exit temperature in K //Output printf('At throat:\n Mass flow rate is %3.2f kg/s\n Area at throat is %3.5f m^2\n Pressure is %3i kPa\n Temperature is %3.1f K\n Velocity is %3.1f m/s\n (a)At section (A):\n Pressure upstream is %3i kPa\n Temperature upstream is %3.1f K\n Mack number downstream is %3.2f\n Pressure downstream is %3.3f kPa\n Temperature downstream is %3.3f K\n Stagnation pressure downstream is %3.1f kPa\n Area is %3.3f cm^2\n At exit:\n Mach number is %3.1f\n Pressure is %3.1f kPa\n (b)At section (B):\n Pressure upstream is %3i kPa\n Temperature upstream is %3.1f K\n Mack number upstream is %3.1f\n Mack number downstream is %3.3f\n Pressure downstream is %3.2f kPa\n Temperature downstream is %3.2f K\n Stagnation pressure downstream is %3.1f kPa\n Area is %3.3f cm^2\n At exit:\n Mach number is %3.2f\n Pressure is %3.1f kPa\n (c)At section (C):\n Area upstream is %3.2f cm^2\n Temperature upstream is %3.1f K\n Mack number upstream is %3.2f\n Mack number downstream is %3.3f\n Pressure downstream is %3.2f kPa\n Temperature downstream is %3.2f K\n Stagnation pressure downstream is %3i kPa\n Area is %3.4f cm^2\n At exit:\n Mach number is %3.2f\n Pressure is %3.1f kPa\n (d)At section (D):\n Pressure upstream is %3i kPa\n Temperature upstream is %3.1f K\n Area upstream is %3.3f cm^2\n Mack number upstream is %3.2f\n Mack number downstream is %3.2f\n Pressure downstream is %3.2f kPa\n Temperature downstream is %3.2f K\n Area is %3.3f cm^2\n At exit:\n Mach number is %3.2f\n Pressure is %3.2f kPa\n (e)At section (E):\n Pressure upstream is %3.1f kPa\n Temperature upstream is %3.1f K\n Mack number upstream is %3.2f\n Mack number downstream is %3.3f\n Pressure downstream is %3.1f kPa\n Temperature downstream is %3.2f K\n At exit:\n Temperature is %3.2f K\n Pressure is %3.1f kPa\n',m,At,Pt,Tt,Ct,Px_a,Tx_a,My_a,Py_a,Ty_a,Poy_a,At2_a,M2_a,P2_a,Px_b,Tx_b,Mx_b,My_b,Py_b,Ty_b,Poy_b,At2_b,M2_b,P2_b,Ax_c,Tx_c,Mx_c,My_c,Py_c,Ty_c,Poy_c,At2_c,M2_c,P2_c,Px_d,Tx_d,Ax_d,Mx_d,My_d,Py_d,Ty_d,At2_d,M2_d,P2_d,Px_e,Tx_e,Mx_e,My_e,Py_e,Ty_e,T2_e,P2_e)
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/3754/CH29/EX29.6/29_6.sce
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29_6.sce
clear// //Variables A1v = 100.0 //Voltage gain with negative feedback Vin = 50.0 * 10**-3 //Input voltage without feedback (in volts) V1in = 0.6 //Input voltage with feedback (in volts) //Calculation V1o = A1v * V1in //Output voltage with feedback (in volts) Vo = V1o //Output voltage without feedback (in volts) Av = Vo / Vin //Voltage gain without feedback beta = (Av/A1v - 1) / Av //feedback ratio //Result printf("\n The value of voltage gain without feedback is %0.3f .\nThe value of voltage gain with feedback is %0.3f .",Av,A1v)
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/275/CH6/EX6.6.31/Ch6_6_31.sce
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Ch6_6_31.sce
clc disp("Example 6.31") printf("\n") disp("calculate output voltage for given specification") printf("given") disp("Rf=360k,R1=120k,Vi=0.5,0.6sin314t,-0.3") Rf=360*10^3 R1=120*10^3 Af=1+(Rf/R1) t=0 //initialise t value Vi=[0.5, 0.6*cos(314*t),-0.3] Vo=Af*Vi //calculate output voltage printf("output voltage =%f volt,\n%f volt,\n%f volt",Vo)
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/911/CH5/EX5.11.b/ex_5_11_b.sce
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ex_5_11_b.sce
//example 5.11(b)// clc ; clear ; disp ( ' Given the truthtable has high output for following conditons : ' ); a =[1 0 0 0; 1 1 0 1 ;1 1 0 0 ; 1 0 0 0 ] // given truthtable// disp (a) for (i =1:3) //finding the terms i n pos if a(i ,1) ==0 then b(i ,1)= 'A' else b(i ,1)= 'A^ ' end if a(i ,2) ==0 then b(i ,2)= 'B ' else b(i ,2)= 'B^ ' end if a(i ,3) ==0 then b(i ,3)= 'C ' else b(i ,3)= 'C^ ' end end disp (b) disp ( 'The product of sums equation is : ' ) //displaying the POS// x= strcat ([ " ( " b(1 ,1) " + " b(1 ,3) " ) " ]); disp (x)
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/23/CH2/EX2.15/Example_2_15.sce
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Example_2_15.sce
clear; clc; //Example 2.15 //Caption : Program To find the Heat to be Removed during Compression //Given values V=600;//[m/s] W_compression=240;//[KJ/Kg] //Solution //Using Eqn(2.32a) Q=(1/2*(V*V)/1000)-W_compression; disp('KJ/kg',-Q,'Thus Heat Removed from each KG of air compressed is') //End
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/409/CH28/EX28.2/Example28_2.sce
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Example28_2.sce
clear ; clc; // Example 28.2 printf('Example 28.2\n\n'); //page no. 872 // Solution // Given p = 100 ;// Mass of product - [kg] f_HCl = 25/100 ;//Fraction of HCl in product //Product analysis HCl = f_HCl*p ;// Mass of HCl in product - [kg] H2O = (1-f_HCl)*p ;// Mass of H2O in product -[kg] mw_HCl = 36.37 ;// Molecular weight of HCl -[kg] mw_H2O = 18.02 ;// Molecular weight of H2O -[kg] mol_HCl = HCl /mw_HCl ;// Moles of HCl - [kg mol] mol_H2O = H2O /mw_H2O; // Moles of H2O - [kg mol] total_mol = mol_HCl + mol_H2O ;// Total no. of moles -[kg mol] mf_HCl = mol_HCl / total_mol ;// mole fraction of HCl mf_H2O = mol_H2O / total_mol ; // mole fraction of H2O mr = mol_H2O/mol_HCl ;// Mole ratio of H2O to HCl MW = mf_HCl*mw_HCl + mf_H2O*mw_H2O ;// Molecular t. of solution-[kg] Ref_T = 25 ;//Reference temperature-[degree C] // Energy balance reduces to Q = del_H // Additional data is obtained from Table E.1 , according to book it is a follows - mol1_HCl = total_mol ;// Moles of HCl // Moles of HCl output -[g mol] Hf1_HCl = -157753 ;// Heat of formation of HCl output-[J/ g mol HCl ] Hf_HCl = -92311 ;// Heat of formation of HCl input-[J/ g mol HCl ] Hf_H2O = 0 ;// Heat of formation of H2O input-[J/ g mol HCl ] H1_HCl = 556 ;// Change in enthalpy during temperature change from 25 C to 35 C of HCl - [J/g mol] H_HCl = integrate('(29.13 - 0.134*.01*T)','T',298,393) ;// Change in enthalpy during temperature change from 25 C to 120 C of HCl - [J/g mol] H_H2O = 0 ;// Change in enthalpy during temperature change from 25 C to 25 C of H2O - [J/g mol] H_in = (Hf_HCl + H_HCl)*mol_HCl + (Hf_H2O + H_H2O)*mol_H2O ;// Enthalpy change of input -[J] H_out = Hf1_HCl*mol_HCl +H1_HCl*mol1_HCl ;// Enthalpy change of output -[J] del_H = H_out - H_in ;// Net enthalpy change n process - [J] Q = del_H; // By energy balance - [J] printf('The amount of heat removed from the absorber by cooling water is, %.0f J.\n ',Q);
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/137/CH12/EX12.2/prob_12_2.sce
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prob_12_2.sce
//page 540 //problem 12.2 //as En=sqrt(nc^2+ns^2),where both nc and ns are gaussian with variance 6n^2,according to the following eqn P(En>=A)=integrate(En/6n^2)*e^(-En^2/2*6n^2)dEn; // the value of this integral is the probability of which is 0.01 //hence e^(-A^2/2*6n^2)=0.01 //let g=A^2/(2*6n^2); clc; g=-(log(0.01)/log(%e)); // the variance 6n^2 of the bandpass noise of PSD N/2 and the bandwidth 2B is 2NB.Hence at the onset of the threshold // therefore A^2/(2*6n^2)=A^2/(4NB)=g //for tone modulation //Si=A^2+m'^2/2; //Si=3*A^2/4; gma_th=3*(g);// gma_th=Si/NB=3*A^2/(4NB); disp(gma_th,'gamma threshold');
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/98/CH14/EX14.7/example14_7.sce
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example14_7.sce
//Chapter 14 //Example 14_7 //Page 368 clear;clc; lr=10*1e3; ly=8*1e3; lb=5*1e3; v=400; ph_v=v/sqrt(3); ir=lr/ph_v; iy=ly/ph_v; ib=lb/ph_v; hc=iy*cos(30*%pi/180)-ib*cos(30*%pi/180); vc=ir-iy*cos(60*%pi/180)-ib*cos(60*%pi/180); in=sqrt(hc^2+vc^2); printf("(i) Phase voltage = %.2f V \n", ph_v); printf("\t Ir = %.1f A \n", ir); printf("\t Iy = %.1f A \n", iy); printf("\t Ib = %.1f A \n", ib); printf("(ii) The three line currents are different in magnitude and displaced by 120 degrees from one another. Resolving currents on x and y axis:\n"); printf("\t Resultant horizontal component = %.1f A \n", hc); printf("\t Resultant vertical component = %.1f A \n", vc); printf("\t Current in nuetral wire = %.1f A \n", in);
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/2063/CH10/EX10.2/10_2.sce
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10_2.sce
clc clear //Input data m=400;//Mass of fruits supplied to a cold storage in kg T1=293;//Temperature at which fruits are stored in K T2=268;//Temperature of cold storage in K t=8;//The time untill which fruits are cooled in hours hfg=105;//Latent heat of freezing in kJ/kg Cf=1.25;//Specific heat of fruit TR=210;//One tonne refrigeration in kJ/min //Calculations Q1=m*Cf*(T1-T2);//Sensible heat in kJ Q2=m*hfg;//Latent heat of freezing in kJ Q=Q1+Q2;//Heat removed from fruits in 8 hrs Th=(Q1+Q2)/(t*60);//Total heat removed in one minute in kJ/kg Rc=Th/TR;//Refrigerating capacity of the plant in TR //Output printf('The refrigeration capacity of the plant is %3.3f TR',Rc)
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/23/CH1/EX1.4/Example_1_4.sce
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Example_1_4.sce
clear; clc; //To find Approx Value function[A]=approx(V,n) A=round(V*10^n)/10^n;//V-Value n-To what place funcprot(0) endfunction //Example 1.4 //Caption : Program to find the velocity and Energy //Given values M=2500;//Mass=2500Kg h1=10;//height1=10m h2=100;//height2=100m g=9.8;//Acceleration of gravity(m/s^2) //Solution //(a) PE1=M*h1*g;//(J) disp('J',PE1,'(a)Potential energy of the elevator in its Initial Position') //(b) W=M*g*integrate('1','l',h1,h2);//(J) disp('J',W,'(b)Work Done in Raising the Elevator') //(c) PE2=M*g*h2;//(J) disp('J',PE2,'(c)Potential energy of the elevator in its Highest Position') //(d) KE2=0; PE3=0; KE3=PE2;//(J) //Conservation Of Mechanical Energy u=approx((2*KE3/M)^(1/2),2);//(m/s) disp('m/s',u,'(d)Velocity of the Elevator') disp('J',KE3,'(d)Kinetic Energy of the Elevator') //(e) PE_Spring=KE3;//(J) disp('J',PE_Spring,'(e)Potential energy of compressed spring ') //(f) TE=PE1+W; disp('J',TE,'(f)Total Energy of the System') //End
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/2699/CH13/EX13.44/Ex13_44.sce
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Ex13_44.sce
//EX13_44 Pg-24 clc clear x=['1011']; y=['0101']; //binary to decimal conversion// x=bin2dec(x) y=bin2dec(y) z=x-y; a=dec2bin(z)//decimal to binary conversion// printf('the subtraction of given numbers is: ') printf("0%s",a)
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/905/CH1/EX1.9/1_9.sce
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clear; clc; // Illustration 1.9 // Page: 27 printf('Illustration 1.9 - Page:27 \n\n'); // Solution //*****Data*****// // A-acetic acid(solute) B-acetone(solvent) T = 313; // [K] // The following data are available (Reid, et al., 1987): // Data for acetic acid T_bA = 390.4; // [K] T_cA = 594.8; // [K] P_cA = 57.9; // [bar] V_cA = 171; // [cubic cm/mole] M_A = 60; // [gram/mole] // Data for acetone T_bB = 329.2; // [K] T_cB = 508; // [K] P_cB = 47; // [bar] V_cB = 209; // [cubic cm/mole] u_bB = 0.264; // [cP] M_B = 58; // [gram/mole] phi = 1; printf('Illustration 1.9 (a) - Page:27 \n\n'); // Solution (a) // Using equation 1.48 V_bA = 0.285*(V_cA)^1.048; // [cubic cm/mole] // Using the Wilke-Chang correlation , equation 1.52 D_abo1 = (7.4*10^-8)*(sqrt(phi*M_B))*T/(u_bB*(V_bA)^.6); printf("Diffusivity of acetic acid in a dilute solution in acetone at 313 K using the Wilke-Chang correlation is %e square cm/s\n",D_abo1); // From Appendix A, the experimental value is 4.04*10^-5 square cm/s D_aboexp = 4.04*10^-5; // [square cm/s] percent_error1 = ((D_abo1-D_aboexp)/D_aboexp)*100; // [%] printf("The percent error of the estimate, compared to the experimental value is %f\n\n ",percent_error1); printf('Illustration 1.9 (b) - Page:28 \n\n'); // Solution (b) // Using the Hayduk and Minhas correlation for nonaqueous solutions V_bA = V_bA*2; // [cubic cm/mole] V_bB = 0.285*(V_cB)^1.048; // [cubic cm/mole] // For acetic acid (A) T_brA = T_bA/T_cA; // [K] // Using equation 1.55 alpha_cA = 0.9076*(1+((T_brA)*log(P_cA/1.013))/(1-T_brA)); sigma_cA = (P_cA^(2/3))*(T_cA^(1/3))*(0.132*alpha_cA-0.278)*(1-T_brA)^(11/9); // [dyn/cm] // For acetone (B) T_brB = T_bB/T_cB; // [K] // Using equation 1.55 alpha_cB = 0.9076*(1+((T_brB*log(P_cB/1.013))/(1-T_brB))); sigma_cB = (P_cB^(2/3))*(T_cB^(1/3))*(0.132*alpha_cB-0.278)*(1-T_brB)^(11/9); // [dyn/cm] // Substituting in equation 1.54 D_abo2 = (1.55*10^-8)*(V_bB^0.27)*(T^1.29)*(sigma_cB^0.125)/((V_bA^0.42)*(u_bB^0.92)*(sigma_cA^0.105)); printf("Diffusivity of acetic acid in a dilute solution in acetone at 313 K using the Hayduk and Minhas correlation is %e square cm/s\n",D_abo2); percent_error2 = ((D_abo2-D_aboexp)/D_aboexp)*100; // [%] printf("The percent error of the estimate, compared to the experimental value is %f\n\n ",percent_error2);
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//Ex:2.5 clc; clear; close; dl_y=1/20;// the ratio of dl to y(wavelength) Rr=80*(%pi^2)*(dl_y)^2;// radiation resistance in ohm printf("The radiation resistance = %f ohm", Rr);
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total_physical_store_count = 0 total_physical_fetch_count = 65536 <cache info> items cached: 1000/1000 regions in use: 1/1 items per region: 65536 counter: 32768 temp_read_num: 65535 temp_write_num: -1 item_req_count = 65536 item_hit_count = 0 item hit ratio = 0% <cache region: 0-65535> item_cost: 1000 flush_cost: 0 counter_total: 32518000 most_recently_used: 65535 least_recently_used: 64536 most_recently_changed: -1 least_recently_changed: -1 most_recently_unchanged: 65535 least_recently_unchanged: 64536
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//Exa 9.6 clc; clear; close; //given data : f_MHz=3000;//in MHz d_Km=384000;//in Km PathLoss=32.45+20*log10(f_MHz)+20*log10(d_Km);//in dB disp(PathLoss,"Path loss in dB : ");
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// sum 28-4 clc; clear; Z1=2; Z2=40; q=8; m=5; d=q*m; P=1.2; lambda=atan(Z1/q); N=1000; Vt=2*%pi*N*20/(60*1000); Vs=Vt/cos(lambda); u=0.032; alpha=20*%pi/180; x=cos(alpha); y=tan(lambda); z=(cos(lambda))/sin(lambda); n=(x-(u*y))/(x+(u*z)); //Let power output be Po Po=P*n; //Let power lost in friction be Pf Pf=P-Po; // printing data in scilab o/p window printf("P is %0.1f kW ",P); printf("\n Po is %0.3f kW ",Po); printf("\n Pf is %0.3f kW ",Pf);
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function [Tn]=chepol(n,var) //Recursive implementation of Chebychev polynomial // n :Polynomial order // var :Polynomial variable (character string) // Tn :Polynomial in var // //! //Author F.D. T1=poly(0,var); T0=1+0*T1; if n=0 then, Tn=T0, return, end, if n=1 then, Tn=T1, return, end, if n>1 then, Tn=2*poly(0,var)*chepol(n-1,var)-chepol(n-2,var), end
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// Example 2.9 // Analysis of Ladder Network Using Proportionality Principle // From figure 2.20 i_1=1; // Assumption v_1=12*i_1; // Working backward toward the source using Ohm's and Kirchhoff's Laws, v_2=v_1/4; // Virtual Voltage across 6 ohm resistor i_2=v_2/6; // Virtual Current through 6 ohm resistor i=i_1+i_2; // Virtual Current through Independent Voltage source v_3=4*i;// Virtual Voltage across 3 Ohm resistor v_s= v_3+v_2;// Virtual Value of Independent Voltage source v_s_cap=72;// Actual Value of Independent Voltage source K=v_s_cap/v_s; // Actual Values of Variables are i_cap=K*i; v_2_cap=K*v_2; i_1_cap=K*i_1; R_eq= v_s_cap/i_cap; //Equivalent resistance of teh Ladder Network disp(i_cap,"Current through Independent Voltage Source(in Amps)=") disp(v_2_cap,"Voltage across 6 Ohm Resistor(in Volts)=") disp(i_1_cap,"Current through 12 Ohm Resistor(in Amps)=") disp(R_eq,"Equivalent Resistance of the Network(in Ohms)=")
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// exa 3.3 Pg 64 clc;clear;close; // Given Data P=20;// kN Sut=300;// MPa n=3;// factor of safety sigma_w=Sut/n;// MPa (Working stress for the link) t=poly(0,'t');// thickness of link A=4*t*t;// mm.sq. sigma_d=P*10**3/A;// N/mm.sq. e=6*t;//mm M=P*10**3*e;// N.mm z=t*(4*t)**2/6;// mm^3 (section modulus at x1-x2) sigma_b=M/z;// N/mm.sq. //maximum tensile stress at x1 = sigma_d+sigma_b=sigma_w ...eqn(1) expr=sigma_d+sigma_b-sigma_w ;// expression of polynomial from above eqn. t=roots(numer(expr));// solving the equation (as denominator will me be multiplied by zero on R.H.S) t=t(2);// mm // discarding -ve roots printf('dimension of cross section of link, t=%.2f mm. Use 23 mm.',t)
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// SERIAL_GATEWAY: function [x, y, typ] = SERIAL_GATEWAY(job, arg1, arg2) x=[];y=[];typ=[]; select job case 'plot' then exprs = arg1.graphics.exprs; comm_port = exprs(1); sending_port = exprs(2); receiving_port = exprs(3); standard_draw(arg1); case 'getinputs' then [x,y,typ]=standard_inputs(arg1); case 'getoutputs' then [x,y,typ]=standard_outputs(arg1); case 'getorigin' then [x,y]=standard_origin(arg1); case 'set' then x=arg1; model=arg1.model; graphics=arg1.graphics; exprs=graphics.exprs; while %t do [ok, comm_port, sending_port, receiving_port, exprs]=.. getvalue('Set parameters for Serial Gateway block',.. ['COM port (1 = COM1, 2 = COM2 ecc.):'; 'Sending Port (for the gateway):'; 'Receiving Port (for the gateway):'],.. list('vec', 1,'vec', 1, 'vec', 1),.. exprs); if ~ok then break; end if (comm_port < 1) then warning('COM port must be a positive integer. Keep previous values'); break; end in = []; out = []; [model,graphics,ok] = check_io(model, graphics, in, out, 1, []); if ok then graphics.exprs = exprs; model.ipar = [comm_port;sending_port;receiving_port]; model.dstate = []; x.graphics = graphics; x.model = model; break; end end case 'define' then comm_port = 1; sending_port = 50002; receiving_port = 50001; model = scicos_model(); model.sim = list('serial_gateway_block', 4); model.in = []; model.out = []; model.evtin = 1; model.ipar = [comm_port;sending_port;receiving_port]; model.dstate = []; model.blocktype = 'd'; model.dep_ut = [%t %f]; exprs = [sci2exp(comm_port),sci2exp(sending_port),sci2exp(receiving_port)]; gr_i = ['xstringb(orig(1),orig(2),.. [''Serial Gateway''],.. sz(1),sz(2),''fill'');']; x = standard_define([4 3], model, exprs, gr_i); end endfunction
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c=10*10^(-6); r=5*10^3; v=24; disp("Part a"); t=r*c; disp("the time constan (in ms) of the circuit i; disp(t*10^3)"); disp("Part b"); rate=v/t; disp("the initial rate of rise of capacitor voltage (in V/s) is"); disp(rate); disp("Part c"); t1=5*t; disp("time taken (in ms) to reach 24 V is"); disp(t1*10^3);
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clc; // page no 34 // prob no1.13 refer fig 1.20 of page no 34 // part A) The signal frequency is f1=110MHz. f=110;// in MHz disp('MHz',f,'A)The freq is'); //The signal peak is two divisions below the reference level of -10dBm, with 10dB/division ,so its -30dBm. PdBm=-30; disp('dBm',PdBm,'The power in dBm'); // The equivalent power can be found from P(dBm)=10logP/1 mW //P(mW)=antilog dBm/10= antilog -30/10=1*10^-3mW=1uW //the voltage can be found from the graph but it is more accurately from P=V^2/R P=10^-6; R=50; disp('W',P,'The power is'); V=sqrt(P*R); disp('volts',V,'The voltage is'); // part B)The signal is 1 division to theleft of center, with 100kHz/div. The freq is 100kHz less than the ref freq of 7.5MHz f=7.5-0.1;// in MHz disp('MHz',f,'B)The freq is'); // With regards to the amplitude, the scale is 1dB/div & the signal is 1 div below the reference level. Therefore the signal has a power level given as PdBm=10-1;// in dBm // This can be converted to watts & volts as same in part A //P(mW)=antilog dBm/10= antilog 9/10=7.94mW P=7.94*10^-3; R=50; disp('W',P,'The power is'); disp('dBm',PdBm,'The power in dBm'); V=sqrt(P*R); disp('volts',V,'The voltage is'); //part C) The signal is 3 divisions to the right of the center ref freq of 543MHz, with 1MHz/div. Therefore the freq is f=543+3*1;// in MHz disp('MHz',f,'C)The freq is'); // from the spectrum, signal level is V=22.4*6/8; disp('mV',V,'The voltage is'); // power is given as P=V^2/R; disp('uW',P,'The power is'); PdBm=10*log10(P*10^-6/10^-3); disp('dBm',PdBm,'The power in dBm');
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//Vane is moving //refer fig. 17.12 (a) and (b) //Velocity of approach Va Va=20 //m/sec //Weight of water impinging in t seconds=385.24*t //Velocity of departure Vd Vd=30-10 //m/sec //Writing impulse momentum equation in x direction Px=105.22 //N Py=392.70 //N P=sqrt((Px^2)+(Py^2)) //N //inclination theta=atand(Py/Px) //degree printf("\nPressure exerted P=%.3f N",P)
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//Example 1_32 clc; clear;close; //Given data: V=90;//V Iload=8;//A t_off=40*10^-6;//s //Ipeak=2*Iload;//assumed //V*sqrt(C/L)=2*Iload C_by_L=(2*Iload/V)^2; //t_off=%pi/2*sqrt(L*C) L_into_C=(t_off/%pi*2)^2; C=sqrt(L_into_C*C_by_L);//F L=L_into_C/C;//H disp(L,"Value of L(H)"); disp(C,"Value of C(F)");
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//Example 5.9 //Mass Flow Rate //Page No. 298 clc;clear;close; L=1; //in m b=0.3; //in m U=30; //in m/s d1=0.0024; //in m rho=1.23; //in kg/m^3 m_ab=rho*U*b*d1/2; Rx=-1*rho*U*U*b*d1/6; Rx=-1*Rx; printf('\nMass flow rate across surface ab = %f kg/s\nThe force required to hold the plate in position is = %f N\n\n',m_ab,Rx); printf('\n\n\nNote: Computational errors in book');
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scenario = "m1 back"; scenario_type = fMRI_emulation; pulses_per_scan = 32; scan_period=1000; #scenario_type = fMRI; pulse_code=10; sequence_interrupt=false; #default active_buttons = 2; button_codes=1,2; default_picture_duration = 500; default_font="times"; default_font_size=48; default_text_color=255,255,255; default_background_color=0,0,0; begin; picture {} default; #blank screen picture { text { caption = "Answer YES or NO for every letter."; }; x=0; y=0; } inst1; picture { text { caption = "Ignore the cases of the letters."; }; x=0; y=0; } inst2; picture { text { caption = "Click YES if the letter you see is the SAME as the letter immediately before it."; }; x=0; y=0; } inst3; picture { text { caption = "Click NO if the letter you see is NOT the same as the letter immediately before it."; }; x=0; y=0; } inst4; picture { text { caption = "P"; }; x=0; y=0; } P; picture { text { caption = "v"; }; x=0; y=0; } v; picture { text { caption = "B"; }; x=0; y=0; } B; picture { text { caption = "b"; }; x=0; y=0; } b; picture { text { caption = "d"; }; x=0; y=0; } d; picture { text { caption = "T"; }; x=0; y=0; } T; picture { text { caption = "D"; }; x=0; y=0; } D; picture { text { caption = "G"; }; x=0; y=0; } G; picture { text { caption = "p"; }; x=0; y=0; } p; picture { text { caption = "t"; }; x=0; y=0; } t; picture { text { caption = "g"; }; x=0; y=0; } g; picture { text { caption = "V"; }; x=0; y=0; } V; #presenting the stimuli trial { picture inst1; mri_pulse= 1; time= 0; duration= 2000; picture inst2; mri_pulse= 3; duration= 2000; picture inst3; mri_pulse= 5; duration= 4000; picture inst4; mri_pulse= 9; duration=4000; picture default; mri_pulse= 13; duration= 2000; picture P; mri_pulse= 15; picture default; mri_pulse= 16; duration= 2000; picture v; mri_pulse= 18; picture default; mri_pulse= 19; duration= 2000; picture B; mri_pulse= 21; picture default; mri_pulse= 22; duration= 2000; picture b; mri_pulse= 24; picture default; mri_pulse= 25; duration= 2000; picture d; mri_pulse= 27; picture default; mri_pulse= 28; duration= 2000; picture T; mri_pulse= 30; picture default; mri_pulse= 31; duration= 2000; picture D; mri_pulse= 33; picture default; mri_pulse= 34; duration= 2000; picture G; mri_pulse= 36; picture default; mri_pulse= 37; duration= 2000; picture p; mri_pulse= 39; picture default; mri_pulse= 40; duration= 2000; picture t; mri_pulse= 42; picture default; mri_pulse= 43; duration= 2000; picture g; mri_pulse= 45; picture default; mri_pulse= 46; duration= 2000; picture V; mri_pulse= 48; picture default; mri_pulse= 49; duration= 2000; };
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function plot(filename1, filename2) clf; fid00 = mopen(filename1, 'r'); fid01 = mopen(filename2, 'r'); if(fid00 == -1) error('cannot open datafile'); end if(fid01 == -1) error('cannot open datafile'); end xselect(); f=gcf(); f.pixmap='on'; x_col=1; d_col=2; e_col=3; // loop over all lines in the file, reading them one at a time num_lines = 0; done_yet = 0; data_done = 0; n = 0; previous = 0; while(done_yet == 0) if(n < 100) n = n + 1; elseif(n >= 100 & n < 10000) n = n + 100; elseif(n >= 10000 & n < 100000) n = n + 1000; elseif(n >= 100000) n = n + 10000; end if(data_done == 0) [num_read00, val00(1), val00(2)] = mfscanf(fid00, "%f %f"); [num_read01, val01(1), val01(2), val01(3)] = mfscanf(fid01, "%f %f %f"); end while(data_done == 0) if (num_read00 ~= 2) data_done = 1; break; end if (num_read01 ~= 3) done_yet = 1; break; end num_lines = num_lines + 1; a_array00(num_lines) = val00(x_col); d_array00(num_lines) = val00(d_col); d_array01(num_lines) = val01(d_col); e_array01(num_lines) = val01(e_col); [num_read00, val00(1), val00(2)] = mfscanf(fid00, "%f %f"); [num_read01, val01(1), val01(2), val01(3)] = mfscanf(fid01, "%f %f %f"); if(num_read00 <= 0) data_done = 1; clf(); // Plot time vs states plot2d(a_array00, [d_array00, d_array01, e_array01],.. leg="", rect=[a_array00(1),0,a_array00(193),0.250]); // Set labels and title xlabel('Energy Transfer (meV)'); ylabel('Intensity(a.u.)'); title('Spectra of TiCr1.85H0.45 measured on TFXA'); //xstring(218*0.9,0.210,'n = ' + string(n)); // Get axes and children a = gca(); a.isoview = 'on'; a.children; intensity = a.children.children(4); intensity.foreground = 1; intensity.thickness = 1; intensity.line_style = 1; intensity.line_mode = "off"; intensity.mark_mode = "on"; intensity.mark_style = 1; model = a.children.children(3); model.foreground = 2; model.thickness = 1; model.line_style = 1; err = a.children.children(2); err.foreground = 5; err.thickness = 1; err.line_style = 1; legends(['n = ' + string(n);'Data';'Model';'Error'],[[0;0],[1;1],[2;1],[5;1]],opt="ur") a.isoview='off'; show_pixmap(); num_lines = 0; previous = 0; break; else previous = val00(x_col) end end clf(); // Plot time vs states plot2d(a_array00, [d_array00, d_array01, e_array01],.. leg="", rect=[a_array00(1),0,a_array00(193),0.250]); // Set labels and title xlabel('Energy Transfer (meV)'); ylabel('Intensity(a.u.)'); title('Spectra of TiCr1.85H0.45 measured on TFXA'); //xstring(218*0.9,0.210,'n = ' + string(n)); // Get axes and children a = gca(); a.isoview = 'on'; a.children; intensity = a.children.children(4); intensity.foreground = 1; intensity.thickness = 1; intensity.line_style = 1; intensity.line_mode = "off"; intensity.mark_mode = "on"; intensity.mark_style = 1; model = a.children.children(3); model.foreground = 2; model.thickness = 1; model.line_style = 1; model.mark_style = 0; err = a.children.children(2); err.foreground = 5; err.thickness = 1; err.line_style = 1; legends(['n = ' + string(n);'Data';'Model';'Error'],[[0;0],[1;1],[2;1],[5;1]],opt="ur") a.isoview='off'; show_pixmap(); num_lines = 0; while(done_yet == 0) if (num_read01 ~= 3) done_yet = 1; break; end num_lines = num_lines + 1; d_array01(num_lines) = val01(d_col); e_array01(num_lines) = val01(e_col); [num_read01, val01(1), val01(2), val01(3)] = mfscanf(fid01, "%f %f %f"); if(val01(x_col) < previous) previous = 0; break; else previous = val01(x_col); end end end mclose(fid00); endfunction
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function [x]=interTempo(n) x=grand(1,1,'exp',480/n) endfunction function [x]=fillTime(m,s) x=max(0,grand(1,1,'nor',m,s)) endfunction function [simtable]=simulatePharma(n,m,s) t=0; while t<=480 do iT=interTempo(n); t=t+iT; simtable($+1,[1:2])=[iT,fillTime(m,s)]; end endfunction function [cumtable]=cumulate(table,col) i=2; rows_number=size(table,'r'); cumtable(1)=simtable(1,col); while i<=rows_number do cumtable(i)=cumtable(i-1)+simtable(i-1,col); i=i+1; end endfunction function [workt]=worktime(table) workt(1)=table(1,2); old=table(1,2); i=2; while i<=size(table,'r') do new=max(0,old-table(i,1))+table(i,2); workt(i)=new; old=new; i=i+1; end endfunction function [min_work]=goSimulate(n,m,s) simtable=simulatePharma(n,m,s); times=cumulate(simtable,2); workt=worktime(simtable); min_work=max(480,times($,$)+workt($,$)) endfunction n = 32; m = 10; s = 4; k = 1; while k <= 365 do workdays(k)=goSimulate(n,m,s); k=k+1; end tabul(workdays) histplot([min(workdays):ceil(max(workdays))],workdays); mean(workdays)
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clc; disp("Peak power is when 100 A flows for 0.01 sec = 1000J/sec"); //displaying
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//Obtain path of solution file path = get_absolute_file_path('solution14_6.sce') //Obtain path of data file datapath = path + filesep() + 'data14_6.sci' //Clear all clc //Execute the data file exec(datapath) //Calculate the kW rating of the chain kW = kWd * Ks/(K1 * K2) printf("\nChoose appropriate chain from table 14.2 on page 550 for %f kW power transmitted at %f rpm\n",kW,n1) printf("\nHere, we choose chain 12A (13.12 kW rating (by interpolation))\n") //Calculate the pitch circle diameter of the driving and the driven sprockets D1 and D2 (mm) D1 = p/sind(180/z1) z2 = floor(z1 * n1/((n2max + n2min)/2)) D2 = p/sind(180/z2) //Calculate the centre distance between two sprockets a (mm) a = 40 * p //Calculate the number of chain links Ln Ln = 2*(a/p) + (z1 + z2)/2 + ((z2 - z1)/(2*%pi))^2 * (p/a) Lnround = floor(Ln) val = (Lnround - (z1 + z2)/2) //Calculate the correct centre distance anew (mm) anew = (p/4)*(val + sqrt(val^2 - 8*((z2 - z1)/(2*%pi))^2)) //ALTERNATIVE DESIGN (add prefix alt_ to each variable name) //Calculate the alternate kW rating of the chain alt_kW = kWd * Ks/(alt_K1 * K2) printf("\nChoose appropriate chain from table 14.2 on page 550 for %f alternate kW power transmitted at %f rpm\n",alt_kW,n1) printf("\nHere, we choose chain 8A (3.61 kW rating (by interpolation))\n") //Calculate the output speed alt_n2 (rpm) alt_n2 = (alt_z1/alt_z2)*n1 //Calculate the centre distance between two sprockets alt_a (mm) alt_a = 30 * alt_p //Calculate the number of chain links alt_Ln alt_Ln = 2*(alt_a/alt_p) + (alt_z1 + alt_z2)/2 + ((alt_z2 - alt_z1)/(2*%pi))^2 * (alt_p/alt_a) alt_Lnround = floor(alt_Ln) alt_val = (alt_Lnround - (alt_z1 + alt_z2)/2) //Calculate the correct centre distance alt_anew (mm) alt_anew = (alt_p/4)*(alt_val + sqrt(alt_val^2 - 8*((alt_z2 - alt_z1)/(2*%pi))^2)) //Print results printf("\nNormal Design\n") printf("\nPitch circle diameter of the driving sprocket(D1) = %f mm\n",D1) printf("\nPitch circle diameter of the driven sprocket(D2) = %f mm\n",D2) printf("\nNumber of chain links(Ln) = %f or %f\n",Ln,Lnround) printf("\nCorrect centre distance between the sprockets(anew) = %f mm\n",anew) printf("\nAlternate Design\n") printf("\nNumber of chain links(Ln) = %f or %f\n",alt_Ln,alt_Lnround) printf("\nCorrect centre distance between the sprockets(anew) = %f mm\n",alt_anew)
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function nilaix=naif_gauss(A,b) M=[A b]; [n,m]=size(M); for j = 1:n-1 for i = j+1:n M(i,:)=-M(i,j)/M(j,j)*M(j,:)+M(i,:); end end A=M(1:n,1:n);b=M(:,n+1); nilaix=sub_balik(A,b); endfunction function solusi=sub_balik(A,b) [n,m]=size(A);//A hrs matriks segitiga atas dan tidak bole elemen diagonal utaman = 0 x(n)=b(n)/A(n,n); for k=n-1:-1:1 jum=0; for j = k+1:n jum=jum+A(k,j)*x(j); end x(k)=(b(k)-jum)/A(k,k) end solusi=x; endfunction
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clc; clear; //clears the console and all previously stored variables function Vt = Heston_EuCall_Laplace (St, r, gamma0, kappa, lambda, sigma_tilde, T, t, K, R) //Laplace transform for the call is defined function y = f_tilde(z) y = K^(1-z) / (z*(z-1)); endfunction //Conditional characteristic function for the Heston model function x = chi_t(u) //function d(u) is defined d=sqrt(lambda^2+sigma_tilde^2*(%i*u+u^2)); //gamma is a function of t in the characteristic function of the Heston model, //since in our case gamma(0) is given and t=0, simple implementation of gamma(t) is used gamma_t=gamma0 //first part of the chi_t(u) function chi_1_t=exp(%i*u*(log(St)+r*(T-t)))*(exp(lambda*(T-t)/2)/(cosh(d*(T-t)/2)+lambda*sinh(d*(T-t)/2)/d))^(2*kappa/sigma_tilde^2); //second part of the chi_t(u) function chi_2_t=exp(-gamma_t*((%i*u+u^2)*sinh(d*(T-t)/2)/d)/(cosh(d*(T-t)/2)+lambda*sinh(d*(T-t)/2)/d)); //finally chi_t is "glued together" x=chi_1_t*chi_2_t; endfunction //Laplace transform for the call and the conditional characteristic function //for the Heston model chi_t function integ=integrand(u) integ=real(f_tilde(R+%i*u) * chi_t(u-%i*R)); endfunction //Computing value of the call option through integration in the range of //0 and 28 (28 is chosen instead of infinityb, ecause the displayed value //does not get more precise after this bound) Vt=(exp(-r*(T-t))/%pi) * intg(0, 28, integrand); endfunction St=100; r=0.05; gamma0=0.2^2; kappa=0.5; lambda=2.5; sigma_tilde=1; T=1; t=0; K=100; R=3; Vt = Heston_EuCall_Laplace (St, r, gamma0, kappa, lambda, sigma_tilde, T, t, K, R) disp("Price of the European Call in the Heston model via the Laplace transform approach is "+string(Vt))
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clc //initialisation of variables z1=12//m z2=36//m z3=22//m z4=28//m z5=12//m z6=72//m q=18//mm z=25//m m=0.3//kg-cm n=0.9//m a=600//mm M=a*(0.2/2)//kg-m H=M*m*q*n//mm //CALCULATIONS V=(%pi*0.2*z)/(60*q)//m/sec V1=(2*%pi*m*z)/(60*1000)//hp N=(12.5*%pi*m*z)/(30*75)//hp //RESULTS printf('the kinematic scheme of a einch with hand crank=% f hp',N)
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clc; //Page no:1-21 //Example-1.1 //Given bandwidth of each message is 4kHz, number of quantum levels are 256 and pulse allocation width of 0.625 micro sec //Let no of quantum levels be Q //Number of pulses used in one group is denoted by P Q=256; P=log2(Q); //Let time for each pulse group be T //Let pulse duration is denoted by d d=0.625; T=d*P; //Let sampling frequency be S fm=4; S=2*fm; //Time period between two samples be t t=(1*10^3)/S; //Total number of messages be tot tot=t/T; disp(P,'Number of pulses used in one group='); disp(+'micro sec',T,'Time for each pulse group='); disp(+'kHz',S,'Sampling frequency='); disp(+'micro sec',t,'Time period between two samples='); disp(tot,'Total number of messages which can be transmitted=');
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// Exa 2.22 clc; clear; close; // given : f1=60 // frequency in Hz omega1=2*%pi*f1 // angular frequency in Hz f2=100 // frequency in MHz f2=100*10^6 // frequency in Hz omega2=2*%pi*f2 // angular frequency in Hz sigma=5.8*10^7 // conductivity in mho/m epsilon_0=8.854*10^-12 // permittivity in free space in F/m mu_0=4*%pi*10^-7 // permeability in free space in H/m epsilon_r=1 // relative permittivity mu_r=1 // relative permeability epsilon=epsilon_r*epsilon_0 // permittivity mu=mu_0*mu_r // permeability disp("At f=60Hz") k1=(sigma)/(omega1*epsilon) // ratio disp(k1," ratio k is equal to") disp("since k>>1 therefore it is very good conductor at f=60Hz:") delta1=(sqrt(2/(omega1*mu*sigma))) // depth of penetration in m disp(delta1,"depth of penetration delta1 in m:") disp("At f=100Hz") k2=sigma/(omega2*epsilon) // ratio disp(k2,"ratio k is equal to") disp("since k2>>1 therefore it is very good conductor at f=100Hz:") delta2=(sqrt(2/(omega2*mu*sigma))) // depth of penetration in m disp(delta2,"depth of penetration delta2 in m:")
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Ex4_24.sce
clear // //Initilization of Variables L=4000 //mm //span //Rectangular Cross-section b=100 //mm //Width d=200 //mm //Thickness F_per=10 //N/mm**2 //Max Bending stress q_max=0.6 //N/mm**2 //Shear stress //Calculations //If the Load W is in KN/m //Max shear Force //F=w*l*2**-1 //KN //After substituting values and further simplifying we get //M=2*w //KN-m //Max Load from Consideration of moment //M=1*6**-1*b*d**2*F_per //After substituting values and further simplifying we get w=(1*6**-1*b*d**2*F_per)*(2*10**6)**-1 //KN/m //Max Load from Consideration of shear stress //q_max=1.5*F*(b*d)**-1 //N //After substituting values and further simplifying we get F=q_max*(1.5)*b*d //N //If w is Max Load in KN/m,then //2*w*1000=8000 //After Rearranging and Further simplifying we get w2=8000*(2*1000)**-1 //KN/m //Result printf("\n Uniformly Distributed Load Beam can carry is %0.2f KN/m",w)
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/1457/CH15/EX15.1/15_1.sce
8617221d941c8c4936df93de8dd4d0d3aff1bf45
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FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
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refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
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15_1.sce
clc //Initialization of variables z2=500//ft z1=300//ft D=[1 1.5 2 2.5 3 4 6] g=32.2 gam=62.4 //calculations Dj=D/12 Vj=sqrt((z2-z1)*2*g./(1.04 + 640.*Dj.^4)) Aj=%pi/4 *Dj.^2 Q=Aj.*Vj Pjet=gam*Q.*Vj.^2 /(2*g) /550 Pj=max(Pjet) for i=1:length(Pjet) if(Pjet(i) ==Pj) break end end diameter=D(i) //results printf("Thus a pipe of %d in will be the optimum",diameter)
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449d555969bfd7befe906877abab098c6e63a0e8
/3819/CH2/EX2.10/Ex2_10.sce
aae7d3f7354959e54f30633b6faf50827a95bcc1
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FOSSEE/Scilab-TBC-Uploads
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Ex2_10.sce
// A Textbook of Fluid Mecahnics and Hydraulic Machines - By R K Bansal // Chapter 2 - Pressure and its measurements // Problem 2.10 //Given Data Set in the Problem SG1=0.8 SG2=13.6 dens1=SG1*1000 dens2=13.6*1000 g=9.81 h2=40/100 h1=15/100 //Calculations //Since, (dens2*g*h2)+(dens1*g*h1)+p=0 p=-((dens2*g*h2)+(dens1*g*h1)) mprintf("The vacuum pressure in the pipe is %f N/cm^2 ",p*10^-4)
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/lgc3 Reborn Varied 120%.sce
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MBHuman/Scenarios
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2023-01-14T02:10:25.103083
2020-11-21T16:47:14
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lgc3 Reborn Varied 120%.sce
Name=lgc3 Reborn Varied 120% PlayerCharacters=Quaker BotCharacters=FS Random.rot IsChallenge=true Timelimit=120.0 PlayerProfile=Quaker AddedBots=FS Random.rot PlayerMaxLives=0 BotMaxLives=0 PlayerTeam=1 BotTeams=2 MapName=kovdmm4p.map MapScale=3.8125 BlockProjectilePredictors=true BlockCheats=true InvinciblePlayer=true InvincibleBots=false Timescale=1.0 BlockHealthbars=true TimeRefilledByKill=0.0 ScoreToWin=1000.0 ScorePerDamage=3.5 ScorePerKill=100.0 ScorePerMidairDirect=0.0 ScorePerAnyDirect=0.0 ScorePerTime=0.0 ScoreLossPerDamageTaken=0.0 ScoreLossPerDeath=0.0 ScoreLossPerMidairDirected=0.0 ScoreLossPerAnyDirected=0.0 ScoreMultAccuracy=false ScoreMultDamageEfficiency=false ScoreMultKillEfficiency=false GameTag=Reflex, Quake, lgc, Dodge WeaponHeroTag=LG, Lightning Gun DifficultyTag=4 AuthorsTag=patys BlockHitMarkers=false BlockHitSounds=false BlockMissSounds=true BlockFCT=false Description=Remake of the original LGC3 mod from Quakeworld. LG duel in an open space. Boost your score by moving around, shorter strafes are incentivized by the scoring system. Bots are chosen at random from a bot rotation with different dodging profiles. GameVersion=2.0.0.2 ScorePerDistance=0.025 MBSEnable=true MBSTime1=0.1 MBSTime2=0.08 MBSTime3=1.3 MBSTime1Mult=0.1 MBSTime2Mult=20.0 MBSTime3Mult=45.0 MBSFBInstead=false MBSRequireEnemyAlive=false [Aim Profile] Name=Default MinReactionTime=0.3 MaxReactionTime=0.4 MinSelfMovementCorrectionTime=0.001 MaxSelfMovementCorrectionTime=0.05 FlickFOV=30.0 FlickSpeed=1.5 FlickError=15.0 TrackSpeed=3.5 TrackError=3.5 MaxTurnAngleFromPadCenter=75.0 MinRecenterTime=0.3 MaxRecenterTime=0.5 OptimalAimFOV=30.0 OuterAimPenalty=1.0 MaxError=40.0 ShootFOV=15.0 VerticalAimOffset=0.0 MaxTolerableSpread=5.0 MinTolerableSpread=1.0 TolerableSpreadDist=2000.0 MaxSpreadDistFactor=2.0 AimingStyle=Original ScanSpeedMultiplier=1.0 MaxSeekPitch=30.0 MaxSeekYaw=30.0 AimingSpeed=5.0 MinShootDelay=0.3 MaxShootDelay=0.6 [Bot Profile] Name=Quaker LS M DodgeProfileNames=LS M DodgeProfileWeights=1.0 DodgeProfileMaxChangeTime=5.0 DodgeProfileMinChangeTime=1.0 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker LS C DodgeProfileNames=LS C DodgeProfileWeights=1.0 DodgeProfileMaxChangeTime=5.0 DodgeProfileMinChangeTime=1.0 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker SS 0306 DodgeProfileNames=SS 0306 DodgeProfileWeights=1.0 DodgeProfileMaxChangeTime=5.0 DodgeProfileMinChangeTime=1.0 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker SS 0205 DodgeProfileNames=SS 0205 DodgeProfileWeights=1.0 DodgeProfileMaxChangeTime=5.0 DodgeProfileMinChangeTime=1.0 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker MS 0407 DodgeProfileNames=MS 0407 DodgeProfileWeights=1.0 DodgeProfileMaxChangeTime=2.0 DodgeProfileMinChangeTime=0.5 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker SMS 02507 DodgeProfileNames=SMS 02507 DodgeProfileWeights=1.0 DodgeProfileMaxChangeTime=5.0 DodgeProfileMinChangeTime=1.0 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker MS SS 0205 DodgeProfileNames=MS 0407;SS 0205 DodgeProfileWeights=1.0;1.0 DodgeProfileMaxChangeTime=1.5 DodgeProfileMinChangeTime=0.5 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker LS SS 0205 DodgeProfileNames=LS M;SS 0205 DodgeProfileWeights=1.0;1.0 DodgeProfileMaxChangeTime=2.0 DodgeProfileMinChangeTime=1.0 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker SMS VSS DodgeProfileNames=SMS 02507;VSS 01504 DodgeProfileWeights=1.0;1.0 DodgeProfileMaxChangeTime=1.5 DodgeProfileMinChangeTime=0.5 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Profile] Name=Quaker SS 0306 VSS DodgeProfileNames=SS 0306;VSS 01504 DodgeProfileWeights=1.0;1.0 DodgeProfileMaxChangeTime=1.5 DodgeProfileMinChangeTime=0.5 WeaponProfileWeights=1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 AimingProfileNames=Default;Default;Default;Default;Default;Default;Default;Default WeaponSwitchTime=5.0 UseWeapons=false CharacterProfile=Quaker SeeThroughWalls=false NoDodging=false NoAiming=false AbilityUseTimer=0.1 UseAbilityFrequency=1.0 UseAbilityFreqMinTime=0.3 UseAbilityFreqMaxTime=0.6 ShowLaser=false LaserRGB=X=1.000 Y=0.300 Z=0.000 LaserAlpha=1.0 [Bot Rotation Profile] Name=FS Random ProfileNames=Quaker LS M;Quaker LS C;Quaker SS 0306;Quaker SS 0205;Quaker MS 0407;Quaker SMS 02507;Quaker MS SS 0205;Quaker LS SS 0205;Quaker SMS VSS;Quaker SS 0306 VSS ProfileWeights=0.5;0.5;1.0;1.0;1.0;1.0;1.0;1.0;1.0;1.0 Randomized=true [Character Profile] Name=Quaker MaxHealth=200.0 WeaponProfileNames=;;LG;;;;; MinRespawnDelay=1.0 MaxRespawnDelay=1.0 StepUpHeight=75.0 CrouchHeightModifier=0.5 CrouchAnimationSpeed=2.0 CameraOffset=X=0.000 Y=0.000 Z=80.000 HeadshotOnly=false DamageKnockbackFactor=4.0 MovementType=Base MaxSpeed=1300.0 MaxCrouchSpeed=500.0 Acceleration=9000.0 AirAcceleration=16000.0 Friction=4.0 BrakingFrictionFactor=2.0 JumpVelocity=800.0 Gravity=3.0 AirControl=0.25 CanCrouch=false CanPogoJump=false CanCrouchInAir=true CanJumpFromCrouch=false EnemyBodyColor=X=0.771 Y=0.000 Z=0.000 EnemyHeadColor=X=1.000 Y=1.000 Z=1.000 TeamBodyColor=X=1.000 Y=0.888 Z=0.000 TeamHeadColor=X=1.000 Y=1.000 Z=1.000 BlockSelfDamage=false InvinciblePlayer=false InvincibleBots=false BlockTeamDamage=false AirJumpCount=0 AirJumpVelocity=0.0 MainBBType=Cylindrical MainBBHeight=320.0 MainBBRadius=58.0 MainBBHasHead=false MainBBHeadRadius=45.0 MainBBHeadOffset=0.0 MainBBHide=false ProjBBType=Cylindrical ProjBBHeight=230.0 ProjBBRadius=55.0 ProjBBHasHead=false ProjBBHeadRadius=45.0 ProjBBHeadOffset=0.0 ProjBBHide=true HasJetpack=false JetpackActivationDelay=0.2 JetpackFullFuelTime=4.0 JetpackFuelIncPerSec=1.0 JetpackFuelRegensInAir=false JetpackThrust=6000.0 JetpackMaxZVelocity=400.0 JetpackAirControlWithThrust=0.25 AbilityProfileNames=;;; HideWeapon=false AerialFriction=0.0 StrafeSpeedMult=1.0 BackSpeedMult=1.0 RespawnInvulnTime=0.0 BlockedSpawnRadius=0.0 BlockSpawnFOV=0.0 BlockSpawnDistance=0.0 RespawnAnimationDuration=0.0 AllowBufferedJumps=true BounceOffWalls=false LeanAngle=0.0 LeanDisplacement=0.0 AirJumpExtraControl=0.0 ForwardSpeedBias=1.0 HealthRegainedonkill=0.0 HealthRegenPerSec=0.0 HealthRegenDelay=0.0 JumpSpeedPenaltyDuration=0.0 JumpSpeedPenaltyPercent=0.0 ThirdPersonCamera=false TPSArmLength=300.0 TPSOffset=X=0.000 Y=150.000 Z=150.000 BrakingDeceleration=2048.0 VerticalSpawnOffset=0.0 TerminalVelocity=0.0 CharacterModel=None CharacterSkin=Default SpawnXOffset=0.0 SpawnYOffset=0.0 InvertBlockedSpawn=false ViewBobTime=0.0 ViewBobAngleAdjustment=0.0 ViewBobCameraZOffset=0.0 ViewBobAffectsShots=false IsFlyer=false FlightObeysPitch=false FlightVelocityUp=800.0 FlightVelocityDown=800.0 [Dodge Profile] Name=LS M MaxTargetDistance=2000.0 MinTargetDistance=0.0 ToggleLeftRight=true ToggleForwardBack=false MinLRTimeChange=0.6 MaxLRTimeChange=1.0 MinFBTimeChange=0.2 MaxFBTimeChange=0.5 DamageReactionChangesDirection=false DamageReactionChanceToIgnore=0.3 DamageReactionMinimumDelay=0.15 DamageReactionMaximumDelay=0.25 DamageReactionCooldown=0.3 DamageReactionThreshold=20.0 DamageReactionResetTimer=0.5 JumpFrequency=0.0 CrouchInAirFrequency=0.0 CrouchOnGroundFrequency=0.0 TargetStrafeOverride=Ignore TargetStrafeMinDelay=0.125 TargetStrafeMaxDelay=0.25 MinProfileChangeTime=0.0 MaxProfileChangeTime=0.0 MinCrouchTime=0.3 MaxCrouchTime=0.6 MinJumpTime=0.3 MaxJumpTime=0.6 LeftStrafeTimeMult=1.0 RightStrafeTimeMult=1.0 StrafeSwapMinPause=0.0 StrafeSwapMaxPause=0.0 BlockedMovementPercent=0.5 BlockedMovementReactionMin=0.125 BlockedMovementReactionMax=0.2 WaypointLogic=Ignore WaypointTurnRate=200.0 MinTimeBeforeShot=0.15 MaxTimeBeforeShot=0.25 IgnoreShotChance=0.0 [Dodge Profile] Name=LS C MaxTargetDistance=700.0 MinTargetDistance=0.0 ToggleLeftRight=true ToggleForwardBack=false MinLRTimeChange=0.6 MaxLRTimeChange=1.0 MinFBTimeChange=0.2 MaxFBTimeChange=0.5 DamageReactionChangesDirection=false DamageReactionChanceToIgnore=0.3 DamageReactionMinimumDelay=0.15 DamageReactionMaximumDelay=0.25 DamageReactionCooldown=0.3 DamageReactionThreshold=20.0 DamageReactionResetTimer=0.5 JumpFrequency=0.0 CrouchInAirFrequency=0.0 CrouchOnGroundFrequency=0.0 TargetStrafeOverride=Ignore TargetStrafeMinDelay=0.125 TargetStrafeMaxDelay=0.25 MinProfileChangeTime=0.0 MaxProfileChangeTime=0.0 MinCrouchTime=0.3 MaxCrouchTime=0.6 MinJumpTime=0.3 MaxJumpTime=0.6 LeftStrafeTimeMult=1.0 RightStrafeTimeMult=1.0 StrafeSwapMinPause=0.0 StrafeSwapMaxPause=0.0 BlockedMovementPercent=0.5 BlockedMovementReactionMin=0.125 BlockedMovementReactionMax=0.2 WaypointLogic=Ignore WaypointTurnRate=200.0 MinTimeBeforeShot=0.15 MaxTimeBeforeShot=0.25 IgnoreShotChance=0.0 [Dodge Profile] Name=SS 0306 MaxTargetDistance=2000.0 MinTargetDistance=0.0 ToggleLeftRight=true ToggleForwardBack=false MinLRTimeChange=0.3 MaxLRTimeChange=0.6 MinFBTimeChange=0.2 MaxFBTimeChange=0.5 DamageReactionChangesDirection=false DamageReactionChanceToIgnore=0.3 DamageReactionMinimumDelay=0.15 DamageReactionMaximumDelay=0.25 DamageReactionCooldown=0.3 DamageReactionThreshold=20.0 DamageReactionResetTimer=0.5 JumpFrequency=0.0 CrouchInAirFrequency=0.0 CrouchOnGroundFrequency=0.0 TargetStrafeOverride=Ignore TargetStrafeMinDelay=0.125 TargetStrafeMaxDelay=0.25 MinProfileChangeTime=0.0 MaxProfileChangeTime=0.0 MinCrouchTime=0.3 MaxCrouchTime=0.6 MinJumpTime=0.3 MaxJumpTime=0.6 LeftStrafeTimeMult=1.0 RightStrafeTimeMult=1.0 StrafeSwapMinPause=0.0 StrafeSwapMaxPause=0.0 BlockedMovementPercent=0.5 BlockedMovementReactionMin=0.125 BlockedMovementReactionMax=0.2 WaypointLogic=Ignore WaypointTurnRate=200.0 MinTimeBeforeShot=0.15 MaxTimeBeforeShot=0.25 IgnoreShotChance=0.0 [Dodge Profile] Name=SS 0205 MaxTargetDistance=2000.0 MinTargetDistance=0.0 ToggleLeftRight=true ToggleForwardBack=false MinLRTimeChange=0.2 MaxLRTimeChange=0.5 MinFBTimeChange=0.2 MaxFBTimeChange=0.5 DamageReactionChangesDirection=false DamageReactionChanceToIgnore=0.3 DamageReactionMinimumDelay=0.15 DamageReactionMaximumDelay=0.25 DamageReactionCooldown=0.3 DamageReactionThreshold=20.0 DamageReactionResetTimer=0.5 JumpFrequency=0.0 CrouchInAirFrequency=0.0 CrouchOnGroundFrequency=0.0 TargetStrafeOverride=Ignore TargetStrafeMinDelay=0.125 TargetStrafeMaxDelay=0.25 MinProfileChangeTime=0.0 MaxProfileChangeTime=0.0 MinCrouchTime=0.3 MaxCrouchTime=0.6 MinJumpTime=0.3 MaxJumpTime=0.6 LeftStrafeTimeMult=1.0 RightStrafeTimeMult=1.0 StrafeSwapMinPause=0.0 StrafeSwapMaxPause=0.0 BlockedMovementPercent=0.5 BlockedMovementReactionMin=0.125 BlockedMovementReactionMax=0.2 WaypointLogic=Ignore WaypointTurnRate=200.0 MinTimeBeforeShot=0.15 MaxTimeBeforeShot=0.25 IgnoreShotChance=0.0 [Dodge Profile] Name=MS 0407 MaxTargetDistance=2000.0 MinTargetDistance=0.0 ToggleLeftRight=true ToggleForwardBack=false MinLRTimeChange=0.4 MaxLRTimeChange=0.7 MinFBTimeChange=0.2 MaxFBTimeChange=0.5 DamageReactionChangesDirection=false DamageReactionChanceToIgnore=0.3 DamageReactionMinimumDelay=0.15 DamageReactionMaximumDelay=0.25 DamageReactionCooldown=0.3 DamageReactionThreshold=20.0 DamageReactionResetTimer=0.5 JumpFrequency=0.0 CrouchInAirFrequency=0.0 CrouchOnGroundFrequency=0.0 TargetStrafeOverride=Ignore TargetStrafeMinDelay=0.125 TargetStrafeMaxDelay=0.25 MinProfileChangeTime=0.0 MaxProfileChangeTime=0.0 MinCrouchTime=0.3 MaxCrouchTime=0.6 MinJumpTime=0.3 MaxJumpTime=0.6 LeftStrafeTimeMult=1.0 RightStrafeTimeMult=1.0 StrafeSwapMinPause=0.0 StrafeSwapMaxPause=0.0 BlockedMovementPercent=0.5 BlockedMovementReactionMin=0.125 BlockedMovementReactionMax=0.2 WaypointLogic=Ignore WaypointTurnRate=200.0 MinTimeBeforeShot=0.15 MaxTimeBeforeShot=0.25 IgnoreShotChance=0.0 [Dodge Profile] Name=SMS 02507 MaxTargetDistance=2000.0 MinTargetDistance=0.0 ToggleLeftRight=true ToggleForwardBack=false MinLRTimeChange=0.25 MaxLRTimeChange=0.7 MinFBTimeChange=0.2 MaxFBTimeChange=0.5 DamageReactionChangesDirection=false DamageReactionChanceToIgnore=0.3 DamageReactionMinimumDelay=0.15 DamageReactionMaximumDelay=0.25 DamageReactionCooldown=0.3 DamageReactionThreshold=20.0 DamageReactionResetTimer=0.5 JumpFrequency=0.0 CrouchInAirFrequency=0.0 CrouchOnGroundFrequency=0.0 TargetStrafeOverride=Ignore TargetStrafeMinDelay=0.125 TargetStrafeMaxDelay=0.25 MinProfileChangeTime=0.0 MaxProfileChangeTime=0.0 MinCrouchTime=0.3 MaxCrouchTime=0.6 MinJumpTime=0.3 MaxJumpTime=0.6 LeftStrafeTimeMult=1.0 RightStrafeTimeMult=1.0 StrafeSwapMinPause=0.0 StrafeSwapMaxPause=0.0 BlockedMovementPercent=0.5 BlockedMovementReactionMin=0.125 BlockedMovementReactionMax=0.2 WaypointLogic=Ignore WaypointTurnRate=200.0 MinTimeBeforeShot=0.15 MaxTimeBeforeShot=0.25 IgnoreShotChance=0.0 [Dodge Profile] Name=VSS 01504 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Mejor_Regresion_1.sce
///////////////////////////////////// // Caculo de la mejor regresión // Este programa calcula el mejor modelo de regresión para un conjunto de valores de ""x"" y "y" // Victor Villarreal // A01039863 // Erick González // A01039859 // 01/04/2019 ///////////////////////////////////// //////////////////////////////////////////////////// // PidoEstimacion // Lee la estimación del valor // Parámetros: // // Retorno: // Valor de la estimación por hacer // //////////////////////////////////////////////////// function dEst = PidoEstimacion () // pido el numero de elementos dEst = input ( "¿Para que valor desea estimar?" ) // pido cada valor del arreglo endfunction //////////////////////////////////////////////////// // PidoValores // Lee la cantidad de valores de x y y con sus respectivos // valores // Parámetros: // // Retorno: // Arreglo con los valores de entrada // //////////////////////////////////////////////////// function ARREGLO = PidoValores () // pido el numero de elementos n = input ( "¿Cuantos valores quieres?" ) // pido cada valor del arreglo for i = 1 : n // con string(i) puedo desplegar que elemento estoy pidiendo ARREGLO ( 1 ,i ) = input ( "Da el elemento " + string ( i ) + ":") end endfunction //////////////////////////////////////////////////// // dXYSuma // Suma las multiplicación de las matrices X y Y // Parámetros: // Arreglo X y Arreglo Y // Retorno: // Suma de la multiplicación de las matrices X y Y // //////////////////////////////////////////////////// function s = dXYSuma (ARRX, ARRY) // inicializo s s = 0 // para cada renglon for i = 1 : size ( ARRX , 2 ) // size(ARR,2) porque es horizontal //acumulo el elemento a la suma s = s + (ARRX(1,i) * ARRY(1,i)) end endfunction //////////////////////////////////////////////////// // dX2YSuma // Suma las multiplicación de las matrices X^2 y Y // Parámetros: // Arreglo X y Arreglo Y // Retorno: // Suma las multiplicación de las matrices X^2 y Y // //////////////////////////////////////////////////// function s = dX2YSuma (ARRX, ARRY) // inicializo s s = 0 // para cada renglon for i = 1 : size ( ARRX , 2 ) // size(ARR,2) porque es horizontal //acumulo el elemento a la suma s = s + (ARRX(1,i)^2 * ARRY(1,i)) end endfunction //////////////////////////////////////////////////// // dXYlnSuma // Suma las multiplicación de las matrices X y ln(Y) // Parámetros: // Arreglo X y Arreglo Y // Retorno: // Suma las multiplicación de las matrices X y ln(Y) // //////////////////////////////////////////////////// function s = dXYlnSuma (ARRX, ARRY) // inicializo s s = 0 // para cada renglon for i = 1 : size ( ARRX , 2 ) // size(ARR,2) porque es horizontal //acumulo el elemento a la suma s = s + (ARRX(1,i) * log(ARRY(1,i))) end endfunction //////////////////////////////////////////////////// // dXlnYlnSuma // Suma las multiplicación de las matrices ln(X) y ln(Y) // Parámetros: // Arreglo X y Arreglo Y // Retorno: // Suma las multiplicación de las matrices ln(X) y ln(Y) // //////////////////////////////////////////////////// function s = dXlnYlnSuma (ARRX, ARRY) // inicializo s s = 0 // para cada renglon for i = 1 : size ( ARRX , 2 ) // size(ARR,2) porque es horizontal //acumulo el elemento a la suma s = s + (log(ARRX(1,i)) * log(ARRY(1,i))) end endfunction //////////////////////////////////////////////////// // Montante // Funcion que simula el metodo montante de una // matriz // // Parámetros: // MAT- recibe una matriz que es la que se va a reducir // // Retorno: // X vector de respuesta de la matriz //////////////////////////////////////////////////// function X = Montante(MAT) //empieza con el pivote = 0 pivote = 1 // para cada renglón i de la matriz se ejecuta el método for(i = 1:size(MAT,1)) for(k = 1:size(MAT,1)) if(i <> k) for(j = i+1:size(MAT,2)) //en caso de que k sea diferente a i se obtiene determinante entre la determinante anterior MAT(k,j) = (MAT(i,i)*MAT(k,j) - MAT(k,i)*MAT(i,j))/pivote end end end //cambia el pivote pivote = MAT(i,i) end //modificas la X para que acomode la respuesta for(i = 1:size(MAT,1)) X(i) = MAT(i,size(MAT,1)+1)/pivote end endfunction //////////////////////////////////////////////////// // dR2 // Calcula los valores cuadrados de la r // Parámetros: // Vector X de los valores y el valor calculado en arreglo // Retorno: // Valor de r^2 // //////////////////////////////////////////////////// function dR2 = R2(X,xCalculated) xMean = sum(log(X)) / size(X,2) dSST = sum((log(X) - xMean)^2) dR2 = (dSST - sum((log(X) - log(xCalculated))^2)) / dSST endfunction //////////////////////////////////////////////////// // Lineal // Calcula la regresión de este tipo // Parámetros: // Numero de terminos, arreglo X y Y, suma de X, // suma de X^2,suma de Y, suma de XY y valor a estimar // Retorno: // Valor de la r^2 y su estimación // //////////////////////////////////////////////////// function [Rlineal,estLineal] = Lineal(iN, iXs, iYs, iXSum, iX2Sum, iYSum, iXYSum, dEst) dNewMat = [iN, iXSum, iYSum; iXSum, iX2Sum, iXYSum] //resolver por Montante X = Montante (dNewMat) //valores evaluados en la regresión xCalculated = X(1,1) + X(2,1)*iXs //valor de la estimación estLineal = X(1,1) + X(2,1)*dEst //caclulo de la r^2 dR2 = R2(iYs,xCalculated) Rlineal = dR2 disp("Lineal : y = " + string(X(1,1)) + " + (" + string(X(2,1)) + ") * x , r2 = " + string(dR2)) disp("Valores Evaluados:") disp(xCalculated) endfunction //////////////////////////////////////////////////// // Cuadrática // Calcula la regresión de este tipo // Parámetros: // Numero de terminos, arreglo X y Y, suma de X, // suma de X^2, uma de X^3, uma de X^4, // suma de Y, suma de XY, suma de X^2Y y el valor a estimar // Retorno: // Valor de la r^2 y su estimación // //////////////////////////////////////////////////// function [RCuadr,estCuadr] = Cuadratica(iN, dXs, dYs, dXSum, dX2Sum, dX3Sum, dX4Sum, dYSum, dXYSum, dX2YSum,dEst) dNewMat2 = [iN, dXSum, dX2Sum, dYSum; dXSum, dX2Sum, dX3Sum, dXYSum; dX2Sum, dX3Sum, dX4Sum, dX2YSum] //resolver por Montante X = Montante (dNewMat2) //valores evaluados en la regresión xCalculated = X(1,1) + X(2,1)*(dXs) +X(3,1)*(dXs^2) //valor de la estimación estCuadr = X(1,1) + X(2,1)*(dEst) +X(3,1)*(dEst^2) //caclulo de la r^2 dR2 = R2(dYs,xCalculated) RCuadr = dR2 disp("Cuadratica : y = " + string(X(1,1)) + " + (" + string(X(2,1)) + ") * x + (" + string(X(3,1)) + ") * x^2, r2 = " + string(dR2)) disp("Valores Evaluados:") disp(xCalculated) endfunction //////////////////////////////////////////////////// // Exponencial // Calcula la regresión de este tipo // Parámetros: // Numero de terminos, arreglo X y Y, suma de X, // suma de X^2,suma de ln(Y), suma de Xln(Y) y valor a estimar // Retorno: // Valor de la r^2 y su estimación // //////////////////////////////////////////////////// function [RExp,estExp] = Exponencial(iN, dXs, dYs, dXSum, dX2Sum, dYlnSum, dXYlnSum,dEst) dNewMat3 = [iN, dXSum, dYlnSum; dXSum, dX2Sum, dXYlnSum] //resolver por Montante X = Montante (dNewMat3) //valores evaluados en la regresión xCalculated = %e^X(1,1)*%e^( X(2,1) * dXs) //valor de la estimación estExp = %e^X(1,1)*%e^( X(2,1) * dEst) //caclulo de la r^2 dR2 = R2(dYs,xCalculated) RExp = dR2 disp("Exponencial : y = " + string(%e^(X(1,1))) + " * e^(" + string(X(2,1)) + " * x), r2 = "+ string(dR2)) disp("Valores Evaluados:") disp(xCalculated) endfunction //////////////////////////////////////////////////// // Exponencial // Calcula la regresión de este tipo // Parámetros: // Numero de terminos, arreglo X y Y, suma de ln(X), // suma de ln(X)^2,suma de ln(Y), suma de ln(X)ln(Y) y valor a estimar // Retorno: // Valor de la r^2 y su estimación // //////////////////////////////////////////////////// function [RPot, estPot] = Potencia(iN, dXs, dYs, dXlnSum, dXln2Sum, dYlnSum, dXlnYlnSum,dEst) dNewMat4 = [iN, dXlnSum, dYlnSum; dXlnSum, dXln2Sum, dXlnYlnSum] //resolver por Montante X = Montante (dNewMat4) //valores evaluados en la regresión xCalculated = %e^X(1,1)*dXs^(X(2,1)) //valor de la estimación estPot = %e^X(1,1)*dEst^(X(2,1)) //caclulo de la r^2 dR2 = R2(dYs,xCalculated) RPot = dR2 disp("Potencia : y = " + string(%e^(X(1,1))) + " * x^(" + string(X(2,1)) + "), r2 = "+ string(dR2)) disp("Valores Evaluados:") disp(xCalculated) endfunction //////////////////////////////////////////////////// // Instrucciones del programa principal //////////////////////////////////////////////////// disp("Ingresa los valores de x") dXs = PidoValores() disp("Ingresa los valores de y") dYs = PidoValores() dEst = PidoEstimacion() //Calculamos todos los valores que utilizaremos en las regresiones iN = size(dXs, 2) dXSum = sum(dXs) dYSum = sum(dYs) dX2Sum = sum(dXs^2) dX3Sum = sum(dXs^3) dX4Sum = sum(dXs^4) dXYSum = dXYSuma(dXs, dYs) dX2YSum = dX2YSuma(dXs, dYs) dXlnSum = sum(log(dXs)) dYlnSum = sum(log(dYs)) dXln2Sum = sum((log(dXs))^2) dXYlnSum = dXYlnSuma(dXs, dYs) dXlnYlnSum = dXlnYlnSuma(dXs, dYs) RLineal = 0 RCuadr = 0 RExp = 0 RPot = 0 estLineal = 0 estCuadr = 0 estExp = 0 estPot = 0 disp("Modelos:") //Regresión Lineal [Rlineal,estLineal] = Lineal(iN, dXs,dYs, dXSum, dX2Sum, dYSum, dXYSum, dEst) //Regresión Cuadrática [RCuadr,estCuadr] = Cuadratica(iN, dXs, dYs, dXSum, dX2Sum, dX3Sum, dX4Sum, dYSum, dXYSum, dX2YSum,dEst) //Regresión Exponencial [RExp,estExp] = Exponencial(iN, dXs, dYs, dXSum, dX2Sum, dYlnSum, dXYlnSum,dEst) //Regresión Potencial [RPot, estPot] = Potencia(iN, dXs, dYs, dXlnSum, dXln2Sum, dYlnSum, dXlnYlnSum,dEst) //vector de las r2 vR2 = [RLineal,RCuadr,RExp,RPot] disp("Conclusiones:") //la mejor r^2 maxR2 = max(vR2) if(maxR2 == RLineal) disp("El mejor modelo es el lineal con R2 = " + string(RLineal)) disp("Usando el mejor modelo el valor estimado para x = " + string(dEst)+ " es: " + string(estLineal)) end if(maxR2 == RCuadr) disp("El mejor modelo es el cuadrático con R2 = " + string(RCuadr)) disp("Usando el mejor modelo el valor estimado para x = " + string(dEst)+ " es: " +string(estCuadr)) end if(maxR2 == RExp) disp("El mejor modelo es el exponencial con R2 = " + string(RExp)) disp("Usando el mejor modelo el valor estimado para x = " + string(dEst)+ " es: " +string(estExp)) end if(maxR2 == RPot) disp("El mejor modelo es el potencial con R2 = " + string(RPot)) disp("Usando el mejor modelo el valor estimado para x = " + string(dEst)+ " es: " +string(estPot)) end
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//Example 1.16 //Determine the power of the signal clc; A=2; theta=0; t=0:0.001:10; y=A*cos(2*%pi*t+theta); P=(integrate('A^2*(cos(2*%pi*t))^2','t',0,2*%pi))/(2*%pi); disp(P,'power of the signal is:'); y=round(P); disp(y,'The given signal is power signal as power is finite');
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// Example 5.22:mid band gain and upper 3 db frequency clc; clear; close; Cmu=3;//capacitance in pico farad Cpi=40;//in pico farad Vt=26;//voltage in milli volts Beta=150;// Icq=1;//current in milli ampere rpi= ((Beta*Vt)/Icq)*10^-3;// gm=(Icq/Vt)*10^3;//transconductance in mili ampere per volt rs=1;//in killo ohms re=4.7;//in killo ohms R1= 40;// in kilo ohms R2= 20;// in kilo ohms R3= 27;// in kilo ohms Rb=(R2*R3)/(R2+R3);// g=(rs*rpi)/(rs+rpi);// tp1=(((Rb*g)*(Cpi+2*Cmu))/(Rb+g))*10^-9;//in second m=rpi/(1+Beta);// tp2= m*(Cmu+Cpi)*10^-9;// Rc=4.7;//collector resistance in killo ohms Rl=10;//load resistance in killo ohms Rld= (Rc*Rl)/(Rc+Rl);// tp3=Cmu*10^-12*Rld*10^3;//in second fh1=(1/(2*%pi*tp1*10^6));//first 3-db upper cut off frequency in mega hertz fh2=(1/(2*%pi*tp2*10^6));//second 3-db upper cut off frequency in mega hertz fh3=(1/(2*%pi*tp3*10^6));//third 3-db upper cut off frequency in mega hertz Avm= -gm*Rld*(rpi/(rpi+1));// disp(fh1,"3-db upper cut off frequency in mega hertz is") disp(fh2,"second 3-db upper cut off frequency in mega hertz") disp(fh3,"third 3-db upper cut off frequency in mega hertz") disp(Avm,"MIDBAND GAIN")
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rc2lar.sci
function g=rc2lar(k) //rc2lar convert reflection coefficient to log area ratios. // Calling Sequence // g = rc2lar(k) // Parameters // k: define the reflection coefficients. // g: returns log area ratios. // Examples //X = [0.5 0.3 0.8 0.9 0.4 0.05]; // g = rc2lar(X) // See also // // Author // Jitendra Singh // if or(type(k)==10) then error ('All reflection coefficients should have magnitude less than unity. ') end if ~isreal(k) then error('Log area ratios not defined for complex reflection coefficients.') end if max(abs(k)) >= 1 then error ('All reflection coefficients should have magnitude less than unity.') end g=-2*atanh(-k); endfunction
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a2e1-IntegralDeterministica.sce
//Integral Deterministica //Metodos dos Trapezios clear N = 100; a = 0; b = 1; dx = (b-a)/N; x = a:dx:b; y = sqrt(1-x.^2); //função a integrar A = 0; for i=1:N T = (y(i)+y(i+1))*dx/2; A = A + T; end estPI = 4*A;
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//Example 13.4 clear; clc; Kv=10^4; wx=10^3; pm=45; wz=wx; wp=(wz^2)/Kv; C=0.1*10^(-6); R2=1/(wz*C); R1=(1/(wp*C))-R2; printf("(a) Designed Passive Lag-Lead Filter :"); printf("\n R1=%.2f kohms",R1*10^(-3)); printf("\n R2=%.2f kohms",R2*10^(-3)); printf("\n C=%.1f uF",C*10^6); wxact=1.27*10^3; T=(1+(%i*(wxact/wz)))/(((%i*wxact)/Kv)*(1+((%i*wxact)/wp))); Tang=((180/%pi)*atan(imag(T)/real(T)))-180; PMact=180+Tang; printf("\n\n(b) Actual Value of wx=%.2f krad/s",wxact*10^(-3)); printf("\n Actual Phase Margin (PM)=%.f deg",PMact);
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// Exa 5.14 clc; clear; close; format('v',6) // Given data A = 125; Beta = 1/10; // Gain of negative feedback Af = A/(1+(A*Beta)); disp(Af,"The gain of negative feedback is");
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clear; clc; close; Vcc = 10; Vbe = 0.7; hfe = 120; hie = 1.175*(10^(3)); hoe = 20*(10^(-6)); Rb = 470*(10^(3)); Rc = 2.7*(10^(3)); Zi = (Rb*hie)/(Rb+hie); disp(Zi,"Input impedance(Zi) :"); ro = 1/hoe; Zo = (ro*Rc)/(ro+Rc); disp(Zo,"Output impedance(Zo) :"); Av = -hfe*Zo/hie; disp(Av,"Voltage gain(Av) :"); Ai = hfe; disp(Ai,"Current gain(Ai) :");
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n= 200; v = 120; p =0.5; if(v < (n/2)) pvalue = 2*cdfbin("PQ", v, n, p,1-p); else pvalue = 2*cdfbin("PQ", n-v, n, p,1-p); end disp(pvalue, "Pvalue is ");
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intfilt.sci
function [h, a]= intfilt(R, L, freqmult) // This function estimate Interpolated FIR Filter Design. // Calling Sequence // h=intfilt(R,L,freqmult) // [h a]=intfilt(R,L,freqmult) // Parameters // R: Samples. It should be numeric // L: bandlimited interpolation samples. It must be nonzero. // freqmult: bandlimitedness of ALPHA times the Nyquist frequency, IT can be numeric or character ('B' or 'L', B is length // (N+1)*L-1 for N odd and (N+1)*L for N even) // h: linear phase FIR filter. // Examples // h=intfilt(20,10,'l') // h=intfilt(20,10,1) // // See also // Authors // Jitendra Singh if or(type(R)==10) | or(type(L)==10) then error ('Argument R and L must be numeric.') else if argn(2)==3 then if type(freqmult)==10 then typ=freqmult; n=L; else freqmult=double(freqmult); typ='b'; end end if freqmult==0 then h=repmat(%nan,[1,(2*R*L-1)]) a=1; else //typ(1)=='b' | typ(1)=='B' if convstr(typ(1), 'u') =='B' then n=2*R*L-1; if freqmult==1 then M=[R R 0 0]; F= [0 1/(2*R) 1/(2*R) 0.5]; else M=R*[1 1]; if type(freqmult)==10 then F=[0 98/2/R]; else F=[0 freqmult/2/R] end for f=(1/R):(1/R):.5, if type(freqmult)==10 then F=[F f-(98/2/R) f+(98/2/R)]; else F=[F f-(freqmult/2/R) f+(freqmult/2/R)]; end M=[M 0 0]; end; if (F(length(F))>.5), F(length(F))=.5; end; end N=n-1; F=F*2; M=M if (max(F)>1) | (min(F)<0) error('Frequencies in F must be in range [0,1]') end if ((length(F)-fix(length(F)./2).*2)~=0) error('Argument F should of even length'); end if (length(F) ~= length(M)) error('The input arguments F & A must have same length'); end W = ones(length(F)/2,1); ftype = ''; ftype = 0; differ = 0; N = N+1; F=F(:)/2; M=M(:); W=sqrt(W(:)); dF = diff(F); if (length(F) ~= length(W)*2) error('There should be one weight per band.'); end if or(dF<0), error('F frequency must be increasing') end if and(dF(2:2:length(dF)-1)==0) & length(dF) > 1, band = 1; else band = 0; end if and((W-W(1))==0) weights = 1; else weights = 0; end L=(N-1)/2; Nodd = N-fix(N./2).*2; if ~Nodd m=(0:L)+.5; else m=(0:L); end k=m'; need_matrix = (~band) | (~weights); if need_matrix I1=k(:,ones(size(m,1),size(m,2)))+m(ones(size(k,1),size(k,2)),:); I2=k(:,ones(size(m,1),size(m,2)))-m(ones(size(k,1),size(k,2)),:); G=zeros(size(I1,1),size(I1,2)); end if Nodd k=k(2:length(k)); b0=0; end; b=zeros(size(k,1),size(k,2)); dd=diff(F); if or(dd==0) & R==1 then h=repmat(%nan,[1,n]) a=1 else for s=1:2:length(F), m=(M(s+1)-M(s))/(F(s+1)-F(s)); b1=M(s)-m*F(s); if Nodd b0 = b0 + (b1*(F(s+1)-F(s)) + m/2*(F(s+1)*F(s+1)-F(s)*F(s)))* abs(W((s+1)/2)^2) ; end b=b(:) b = b+(m/(4*%pi*%pi)*(cos(2*%pi*k*F(s+1))-cos(2*%pi*k*F(s)))./(k.*k))* abs(W((s+1)/2)^2); b = b' + (F(s+1)*(m*F(s+1)+b1)*sinf(2*k*F(s+1))- F(s)*(m*F(s)+b1)*sinf(2*k*F(s)))* abs(W((s+1)/2)^2); if need_matrix mat=matrix((.5*F(s+1)*(sinf(2*I1*F(s+1))+sinf(2*I2*F(s+1)))- .5*F(s)*(sinf(2*I1*F(s))+sinf(2*I2*F(s))) ) * abs(W((s+1)/2)^2),size(G,1),size(G,2)) ; mat=mat'; G=G+mat; end end; if Nodd b=[b0; b']; end; if need_matrix a=G\b; else a=(W(1)^2)*4*b; if Nodd a(1) = a(1)/2; end end if Nodd h=[a(L+1:-1:2)/2; a(1); a(2:L+1)/2].'; else h=.5*[flipud(a); a].'; end; end; //typ(1)=='l' | typ(1)=='L' elseif convstr(typ(1), 'u') =='L' then if n==0 then h=ones(1,R) return end t=0:n*R+1; l=ones(n+1,length(t)); for i=1:n+1 for j=1:n+1 if (j~=i) then l(i,:)=l(i,:).*(t/R-j+1)/(i-j); end end end h=zeros(1,(n+1)*R); for i=0:R-1 for j=0:n h(j*R+i+1)=l((n-j)+1,round((n-1)/2*R+i+1)); end end if h(1) == 0, h(1) = []; end else error ('This type of filter is not recognized.') end a=1; end end endfunction ////// Supplementary function function y=sinf(x) for i=1:length(x) if x(i)==0 then y(i)=1; else y(i)=sin(%pi*x(i))/(%pi*x(i)); end end y=y'; endfunction
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SS4 part2.sce
//SS SCILAB EXPT 4 PART 2 //inverse z transform z=%z; num=2*z*(2*z-1) den=(z-1)*(z-2)^2 h=ldiv(num,den,10) disp("Displaying the first ten terms of the inverse z transform :",h)
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example17_7.sce
//Chapter 17 //Example 17_7 //Page 409 clear;clc; mva1=1500; mva2=1200; v=33; x=1; base=input("Base MVA: "); per_x1=base*100/mva1; per_x2=base*100/mva2; printf("%% reactance of station A = %.2f %% \n\n", per_x1); printf("%% reactance of station B = %.2f %% \n\n", per_x2); per_xt=base*1000*x/10/v^2; printf("%% reactance of interconnector = %.2f %% \n\n", per_xt); x1=per_x1+per_xt; tx1=x1*per_x2/(x1+per_x2); scmva1=base*100/tx1; x2=per_x2+per_xt; tx2=x2*per_x1/(x2+per_x1); scmva2=base*100/tx2; printf("FAULT ON STATION A: \n\n"); printf("Total %% reactance upto fault point F2 = %.2f %% \n\n", tx2); printf("Short circuit MVA = %.2f \n\n", scmva2); printf("FAULT ON STATION B: \n\n"); printf("Total %% reactance upto fault point F1 = %.2f %% \n\n", tx1); printf("Short circuit MVA = %.2f \n\n", scmva1);
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//To Compare the total Magnetic Field due to earth at the two places //Example 36.9 clear; clc; T1=3;//Time period for first place in seconds T2=2;//Time Period for second place in seconds theta1=%pi/4;//Dip in radians at first place theta2=%pi/6;//Dip in radians at second place Br=(T1^2/T2^2)*cos(theta1)/cos(theta2);//Ratio of Magnetic Field due to earth at two places printf("The ratio of Magnetic Field due to earth at the two places = %.3f",Br);
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exec('scilab-base-calculs-testexo5i.sce',-1) //to delete u10=sin(u9)
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// ELECTRICAL MACHINES // R.K.Srivastava // First Impression 2011 // CENGAGE LEARNING INDIA PVT. LTD // CHAPTER : 5 : INDUCTION MACHINES // EXAMPLE : 5.19 clear ; clc ; close ; // Clear the work space and console // GIVEN DATA s = 0.05; // Slip m = 3; // Total Number of phase in Induction Motor p = 4; // Total number of Poles of Induction Motor f = 50; // Frequency in Hertz V = 440; // Operrating Voltage of the Inductuon Motor R1 = 0.10; // Circuit Parameter in Ohms R2 = 0.11; // Circuit Parameter in Ohms X1 = 0.35; // Circuit Parameter in Ohms X2 = 0.40; // Circuit Parameter in Ohms pf = 0.2; // Power factor (Lagging) Pr = 900; // Rotational Loss in Watts Psc = 1000; // Stator core loss in Watts I = 15; // Line current draws by the motor in Amphere // CALCULATIONS Vph = V/sqrt(3); // Per phase Voltage in Volts I_2 = Vph/(R1+(R2/s)+(%i*(X1+X2))); // Current in Amphere Io = I * exp(-( %i * acosd(pf) * %pi/180)); // No-load current in Amphere I1 = Io + I_2; // Input line Current in Amphere PF = cosd(atand(imag(I1)/real(I1))); // Power factor Ws = 2*%pi*((120*f/p)*(1/60)); // Angular Roatation in Radians per Seconds Pg = (3*(abs(I1)^2*R2))/s; // 3-phase air gap power or Rotor intake Power in Watts T = Pg/Ws; // Torque in Newton-Meter Po = Pg*(1-s)-Pr; // Output Power in Watts Po_HP = Po/746; // Output Power in Horse-Power eta = (Po/(Po+Psc+Pr))*100; // Efficiency in Percentage // DISPLAY RESULTS disp("EXAMPLE : 5.19 : SOLUTION :-"); printf("\n (a) Input line current, I1 = %.1f < %.2f A \n",abs(I1),atand(imag(I1),real(I1))) printf("\n (b) Power Factor, Pf = %.4f Lagging \n",PF) printf("\n (c) Output Power, P0 = %.1f HP \n",Po_HP) printf("\n (d) Torque, T = %.2f Nm \n",T) printf("\n (e) Efficiency, eta = %.1f Percenatge \n",eta) printf("\n\n [ TEXT BOOK SOLUTION IS PRINTED WRONGLY ( I verified by manual calculation )]\n" ); printf("\n WRONGLY PRINTED ANSWERS ARE :- (a) I1 = 114.2<-24.68 A instead of %.1f<%.2f A \n ",abs(I1),atand(imag(I1),real(I1))); printf("\n (b) T = 548.24 Nm instead of %.2f Nm \n ",T); printf("\n (c) Po = 108.4 HP instead of %.1f HP \n ",Po_HP);
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//3.5 clc; V=30; Vrms1=2*V/(2^0.5*%pi); printf("RMS value of fundamental component of input voltage = %.1f V", Vrms1) VL=V/2; R=3; Pout=VL^2/R; printf("\nOutput Power = %.0f W", Pout) Ip_thy=VL/R; printf("\nPeak current in each thyristor = %.0f A", Ip_thy) Iavg=Ip_thy/2; printf("\naverage current in each thyristor = %.1f A", Iavg) PIV=2*VL; printf("\nPeak reverse blocking voltahe = %.0f V", PIV)
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// Display mode mode(0); // Display warning for floating point exception ieee(1); clear; clc; disp("Introduction to heat transfer by S.K.Som, Chapter 1, Example 10") //The spacecraft panel has thickness(L)=.01 m //The spacecraft has inner temprature (Ti)=298 K //The spacecraft has outer temprature(T2) //The panel is exposed to deep space where temprature(To)= 0K //The material has Thermal conductivity(k)= 5.0 W/(m*K) //The emissivity(emi)=0.8 //The inner surface of the panel is exposed to airflow resulting in an average heat transfer coefficient(hbri)=70 W/(m^2*K) L=.01; Ti=298; To=0; k=5; emi=0.8; hbri=70; //The stefan Boltzman constant(sigma)= 5.67*10^-8 W/(m^2/K^4) sigma=5.67*10^-8; //Heat transfer from the outer surface takes place only by radiation is given by Q/A=emi*sigma*(T2^4-T0^4)in W/m^2=F1 //heat transfer from the outer surface can also be written as Q/A=(Ti-To)/((1/hbri)+(L/k)+(1/hr))=F2 //Radiation heat transfer coefficient(hr) is defined as Q/A=hr(T2-To) //so hr=4.536*10^-8*T2^3 disp("Heat transfer from the outer surface takes place only by radiation is given by Q/A=F1=emi*sigma*(T2^4-T0^4)in W/m^2 for different values of tempratures in K") disp("heat transfer from the outer surface can also be written as Q/A=F2=(Ti-To)/((1/hbri)+(L/k)+(1/hr)) in W/m^2 at different tempratures in K" ) disp("The values of temprature that are considered are <298 K") for (i=285:292) T2=i,hr=4.536*10^-8*T2^3; F1=emi*sigma*(T2^4-To^4),F2=(Ti-To)/((1/hbri)+(L/k)+(1/hr)) end if F1==F2 then T2=i else T2=292.5,hr=4.536*10^-8*T2^3; F1=emi*sigma*(T2^4-To^4),F2=(Ti-To)/((1/hbri)+(L/k)+(1/hr)) end disp("Satisfactory solutions for Temprature in K is") disp(Temprature = T2) disp("Approximate Rate of Heat Transfer in W/m^2 is") disp(332)
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disp('chapter 10 ex10.4') disp('given') disp('design a wein bridge oscillator to have output frequency of 15kHz') disp('using BIFET op-amp with a supply of +or-12volt') Vcc=12 f=15000 disp('select,C=C1=C2=0.01*10^(-6)F') C=0.01*10^(-6) disp('R=1/(2*%pi*C*f)') R=1/(2*%pi*C*f) disp('ohms',R) disp('use 1kohm standard value') R=1000 disp('R1=R2=R=1kohm') disp('let R4=R2=1kohm') R4=1000 disp('R3=2*R4') R3=2*R4 disp('ohms',R3) disp('use 2.2kohm standard value to give Av>3')
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pathname=get_absolute_file_path('6_4.sce') filename=pathname+filesep()+'6_4data.sci' exec(filename) P=[1 P1(1) P1(2) P1(1)*P1(2); 1 P2(1) P2(2) P2(1)*P2(2); 1 P3(1) P3(2) P3(1)*P3(2); 1 P4(1) P4(2) P4(1)*P4(2)]; alpha1=inv(P)*u; alpha2=inv(P)*v; alpha=[alpha1;alpha2]; deff("[Ex]=f(y)","Ex=alpha(2)+ y*alpha(4)");//εx deff("[Ey]=f1(x)","Ey=alpha(7)+ x*alpha(8)");//εy function[G]=Gxy(x,y)//γxy G=x*alpha(4) +y*alpha(8) +alpha(3)+alpha(6); endfunction //at the centre Pc(1)=(P1(1)+P3(1))/2; Pc(2)=(P1(2)+P3(2))/2; Sy=(E/(1-V^2))*(f1(Pc(2)) +V*f(Pc(1))); Sx=(E/(1-V^2))*(f(Pc(1)) +V*f1(Pc(2))); gxy=Gxy(0,0); txy=(E/(1-V^2))*0.5*(1-V)*gxy;//τxy printf("\nσx: %f N/mm^2",Sx); printf("\nσy: %f N/mm^2",Sy); printf("\nτxy: %f N/mm^2",txy);
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//Moment of Inertia of flywheel //refer fig. 10.24 //Moment of inertia of rim aRo=1.5/2 aRi=1.4/2 at=0.30 rho=7200 //kg/m^3 I1=((%pi)*0.3*7200*(0.75^4-0.7^4))/(2) //units //Moment of inertia of hub bRo=0.25/2 //m bRi=0.1/2 //m bt=0.2 //m I2=(%pi)*(0.2*7200)*(0.125^4-0.05^4)/(2) //units //Moment of inertia of Arms A=8000*(10^-9) //m^2 l=0.575 //m d=(0.575/2)+0.125 //m M=l*A*rho //kg //there are six such arms I3=6*0.03312*((0.575)^2/(12))*(0.4125^2) //units //moment of inertia of flywheel I=I1+I2+I3 //units printf("\nmoment of inertia of flywheel=%.2f units",I)
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//shunt generator was run as a shunt motor at no load I0=5 //current drawn Ish=1.5 //shunt field current Ia0=I0-Ish Ra=.15 //armature circuit resistance V=440 //terminal voltage Wcu=Ia0^2*Ra //armature copper loss Pi=V*I0 //power input Wc=Pi-Wcu //constant losses //calculating efficiency of shunt generator at full load Po=50D+3 //output of generator Il=Po/V //load current Ia=Il+Ish Wcu=Ia^2*Ra //copper losses Wt=Wc+Wcu //total losses e=Po/(Po+Wt)*100 mprintf("Efficiency of shunt generator at full load=%f percent\n", e) //calculating efficiency at 3/4th load I1=3/4*Il //load current Ia=I1+Ish Wcu=Ia^2*Ra //copper losses Wt=Wc+Wcu //total losses e=(3/4*Po)/(3/4*Po+Wt)*100 mprintf("Efficiency at 3/4th load=%f percent\n", e) //calculating efficiency at half load I2=.5*Il //load current Ia=I2+Ish Wcu=Ia^2*.15 //copper losses Wt=Wc+Wcu //total losses e=(.5*Po)/(.5*Po+Wt)*100 mprintf("Efficiency at half load=%f percent", e)
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function A=remplir1(M,r,sig,Dt) for i=1:M for j=1:M if i==j then A(i,j)=-r*i+(((sig*i)^2)/2) elseif j == i-1 then A(i,j)=(-r+1/Dt+r*i-(sig*i)^2) elseif j == i+1 then A(i,j)=(sig*i)^2 else A(i,j)=0 end end end endfunction function B=remplir2(K,L,M) for i=1:M B(i)=max(K-i*(L/(M+1)),0) end endfunction function C=remplir3(r,T,M,sig,n,N,K) C=zeros(M,1); C(1,1)=(-r+((sig^2)/2))*K*(exp(r*(n*T/N-T))); endfunction function Pn=final(r,T,M,sig,N,Dt,K,L) A=remplir1(M,r,sig,Dt); Pn=remplir2(K,L,M); for n=N:-1:1 C=remplir3(r,T,M,sig,n,N,K); Pn=A*Pn+C; end endfunction
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vector_eample.tst
/* * vector_eample.cpp *example of crating a vector and iterating over it *example * Created on: Feb 12, 2016 * Author: klein */ // define vector of char std::vector<std::string> coll; std::string RXBUFFER; char testchar[50]={"andi"}; testchar[4]= '\n'; cout<<testchar[0]<<testchar[3]<<testchar[4]; cout<<testchar[0]<<testchar[3]; // little vector test for(Int_t k=0;k<10;k++){ RXBUFFER = "asdfghjklq"; coll.push_back(RXBUFFER); } // now check the length of the vector cout<<"vector size "<<coll.size()<<"\n"; // now rpint the vecor out for (std::vector<std::string>::iterator pos=coll.begin(); pos!= coll.end();pos++) cout<<"vector "<<*pos<<"\n"; // empty vector coll.clear(); cout<<"vector size after clear "<<coll.size()<<"\n"; //Loop over character array until we find linefeed for(int l =0; l<50;l++){ cout <<testchar[l]; if(testchar[l]=='\n') break; }
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Aula 5.sce
mprintf("---------------QUESTÃO 3-----------------------") b=input("Informe o tamanho dos vetores: ") mprintf("AGORA INSIRA OS VALORES DO PRIMEIRO VETOR!") for i=1:b v1(i)=input("Informe um valor: ") end i=0 mprintf("AGORA INSIRA OS VALORES DO SEGUNDO VETOR!") for i=1:b v2(i)=input("Informe um valor: ") end v=union(v1,v2) disp(v) mprintf("-----------------------------------------------\n") mprintf("---------------QUESTÃO 2-----------------------") r=input("Informe o tamanho do vetor: ") for i=1:r k(i)=input("Informe um valor: ") end mprintf("\nValor mínimo: %d\n",min(k)) mprintf("Valor máximo: %d\n",max(k)) for i=1:r k(i)=k(i)*i end disp(k) mprintf("-----------------------------------------------\n") mprintf("---------------QUESTÃO 1-----------------------") for i=1:4 for j=1:3 mprintf("\nInforme o elemento em [%d][%d] ",i,j) a(i,j)=input("= ") end end mprintf("L2C3= %d\n",a(2,3)) mprintf("L3 C3 X L2 C2 = %d",a(3,3)*a(2,2)) mprintf("\nMaior valor da matriz: %d",max(a)) mprintf("\nMatriz x 3 = \n") disp(3*a) mprintf("\n-----------------------------------------------\n") //PROFESSOR, FIZ ESSE CÓDIGO COMO SE A PRIMEIRA LINHA OU COLUNA FOSSE 1 E NÃO 0,DEVIDO AO TAMANHO DA MATRIZ QUE O SENHOR ESTIPULOU NO ENUNCIADO
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//**************************** sigmadelta ************************************** if (blk_name.entries(bl) =='sigma_delta') then mputl("# sigmadelta",fd_w); for ss=1:scs_m.objs(bl).model.ipar(1) sigma_str= '.subckt sigma_delta_fe in[0]=net' + string(blk(blk_objs(bl),2))+"_"+ string(ss) +" in[1]=net"+string(blk(blk_objs(bl),3))+"_1 in[2]=net"+string(blk(blk_objs(bl),4))+"_1 out[0]=net'+ string(blk(blk_objs(bl),2+numofip))+"_" + string(ss)+" #sd_ota_bias[0] =" +string(sprintf('%1.3e',scs_m.objs(blk_objs(bl)).model.rpar(3*ss-2)))+"&sd_ota_bias[1] =" +string(sprintf('%1.3e',scs_m.objs(blk_objs(bl)).model.rpar(3*ss)))+"&sd_ota_bias[2] =" +string(sprintf('%1.3e',scs_m.objs(blk_objs(bl)).model.rpar(3*ss-1)))+"&sigma_delta_fe_fg[0] =0&sd_ota_bias[3] =2e-6&sd_ota_p_bias[0] =500e-9&sd_ota_n_bias[0] =700e-9&sd_ota_p_bias[1] =500e-9&sd_ota_n_bias[1] =700e-9"; mputl(sigma_str,fd_w); mputl(" ",fd_w); end end
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// Example 5.12 page no-297 clear clc vcc=24 //v re=270 //Ohm rc=10000 //Ohm vce =5 //V vbe=0.6 //v b=45 //beta ic=(vcc-vce)/(rc+(1+b)*re/b) ib=ic/b printf("\nIc = %.3f mA\nIb = %.2f micro A",ic*1000,ib*10^6) //(a) r=(vce-vbe)/ib printf("\n\n(a)In collector base circuit\n\tR = %.2f K-Ohm",r/1000) //(b) s=(1+b)/(1+(b*rc/(rc+r))) printf("\n\n(b)Stability Factor,\n\tS = %.3f",s) //(c) tj=150 ta=25 pd=125 t=(tj-ta)/pd printf("\n\n(c)\nThermal Resistance = %.0f°C/W",t*1000)
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LocProject2D_Quad_Mod_Basis_P6_Q7.tst
<?xml version="1.0" encoding="utf-8"?> <test> <description>Project2D Quad Modified basis P=4 Q=5</description> <executable>LocProject</executable> <parameters>-s quadrilateral -b Modified_A Modified_A -o 6 6 -p 7 7 -c 0.0 0.0 1.0 0.0 1.0 1.0 0.0 1.0</parameters> <metrics> <metric type="L2" id="1"> <value tolerance="1e-12">1.24683e-13</value> </metric> <metric type="Linf" id="2"> <value tolerance="1e-11">5.82645e-13</value> </metric> </metrics> </test>
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/ketpic2escifiles6/Listplot.sci
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ketpic/ketcindy-scilab-support
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2021-05-11T11:40:49.725978
2018-01-16T14:02:21
2018-01-16T14:02:21
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Listplot.sci
// // 08.07.13 // 09.06.13 function Z=Listplot(varargin) Z=[]; for I=1:length(varargin) Data=varargin(I); if Mixtype(Data)==1 if size(Data,1)==1 Tmp=matrix(Data,2,size(Data,2)/2); Z=[Z;Tmp']; else Z=[Z;Data]; end; else for J=1:Mixlength(Data) Tmp=Mixop(J,Data); Z=[Z;Tmp]; end end end endfunction