How to solve exceed number of array element (1) problem?

Question

shahin sharafi on 5 Aug 2021

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https://se.mathworks.com/matlabcentral/answers/892972-how-to-solve-exceed-number-of-array-element-1-problem

Commented: darova on 5 Aug 2021

Hi

As I try to run the bellow code, I will encounter the Index exceeds the number of array elements (1). As I tried the Time_Delay_Bra as a constant, the problem will be solved. However as I use it as "Time_Delay_Bra=0.1:0.05:0.2", it causes problem for me.

Could you please help me with this mattter.

Thank youo in advance

%% 
tic
clear all
 clc 
 close all
 %%
Mass=60;Lenght=1;Ja=60;g=9.81;beta2=411.67;
Kp_Bra=2.15;Kd_Bra=0.75;
alpha=(Mass*Lenght*g)/Ja;Zeta3=beta2/Ja; 
N=7;
 
Time_Delay_Bra=0.1:0.05:0.2;
Time_Delay_Exo=0.1:0.05:0.2;
AreaCount=1;
AreaVector=zeros(1,AreaCount);
AreaMatrix=zeros(length(Time_Delay_Exo),length(Time_Delay_Bra));
for j=1:length(Time_Delay_Bra)
for jj=1:length(Time_Delay_Exo)
    
%% Legendre Polynomial 
s1=0;
s2=-Time_Delay_Bra(j);
s3=-Time_Delay_Exo(jj);
[Phi_0_s,Phi_BTD_s,Phi_ETD_s]=Shape_Function(N,s1,s2,s3);
%% 
Time_Delay_Bra=Time_Delay_Bra(j);
 [M,C]=M_C(N,Time_Delay_Bra);
%% 
count=1;
KP_Exo=0:20:800;
KD_Exo=0:20:800; 
x=zeros(1,count);
y=zeros(1,count);
MaximunEigenValuesMatrix=zeros(length(KP_Exo),length(KD_Exo));
WantedEigenValuesforDefinedGaines=zeros(1,1);
 for ii=1:length(KP_Exo)
  KP_Exo(ii)
  for i=1:length(KD_Exo)
         
   KP1=KP_Exo(ii)/Ja;
   KD1=KD_Exo(i)/Ja
Final_Matirx=Evaluation(KP1,KD1,alpha,Phi_0_s,Phi_BTD_s,Phi_ETD_s,M,C,Zeta3,Kp_Bra,Kd_Bra);
Max_Real_EignValues=max(real(eig(Final_Matirx)));
if Max_Real_EignValues<0
MaximunEigenValuesMatrix(ii,i)=max(real(eig(Final_Matirx)));  
x(1,count)=KP1*Ja;
    y(1,count)=KD1*Ja;
    count=count+1;
end 
    hold on
 end
 end
  k = boundary(x',y');% generate boundary of data points
 plot(x(k),y(k))
 Area= polyarea(x,y);
AreaMatrix(jj,j)=Area;
 
end
end
 
toc
%% 
function [Phi_0_s,Phi_BTD_s,Phi_ETD_s]=Shape_Function(N,s1,s2,s3)
% % Shape Function for the Zero PArt
Phi_0_s(1)=1;
Phi_0_s(2)=1+2*s1/(-s2);  
for k=3:N
Phi_0_s(k)=((2*k-3)*Phi_0_s(2)*Phi_0_s(k-1)-(k-2)*Phi_0_s(k-2))/(k-1);
end 
Phi_0_s=Phi_0_s';
%% Shape Function for the Brain TimeDelay Part
Phi_BTD_s(1)=1;
Phi_BTD_s(2)=1+2*s2/(-s2);  
for k=3:N
Phi_BTD_s(k)=((2*k-3)*Phi_BTD_s(2)*Phi_BTD_s(k-1)-(k-2)*Phi_BTD_s(k-2))/(k-1);
end 
Phi_BTD_s=Phi_BTD_s';
%% Shape Function for the Exo TimeDelay Part
Phi_ETD_s(1)=1;
Phi_ETD_s(2)=1+2*s3/(-s2);  
for k=3:N
Phi_ETD_s(k)=((2*k-3)*Phi_ETD_s(2)*Phi_ETD_s(k-1)-(k-2)*Phi_ETD_s(k-2))/(k-1);
end 
Phi_ETD_s=Phi_ETD_s';
end 
function  [M,C]=M_C(N,Time_Delay_Bra)
Delta=zeros(N,N);
M=zeros(N,N);
C=zeros(N,N);
for i=1:N
    for j=1:N
       if i==j
        Delta(i,j)=1;
       else 
         Delta(i,j)=0;  
       end
    end
    end 
for i=1:N
    for j=1:N
M(i,j)=(Time_Delay_Bra*Delta(i,j))/(2*i-1);  
      if i<j
       if rem(i+j, 2) == 1 
           C(i,j)=2; 
       else 
          C(i,j)=0;     
    end 
   end 
  end 
end
end
function [L]=Evaluation(KP1,KD1,alpha,Phi_0_s,Phi_BTD_s,Phi_ETD_s,M,C,Zeta3,Kp_Bra,Kd_Bra)
kp_exo=KP1;
kd_exo=KD1;
kp_bra=Zeta3*Kp_Bra;
kd_bra=Zeta3*Kd_Bra;
%% G1&G2
G1=alpha*Phi_0_s'-kp_exo*Phi_ETD_s'-kp_bra*Phi_BTD_s';
G2=-kd_bra*Phi_BTD_s'-kd_exo*Phi_ETD_s';
%% C3
C3=Phi_0_s'*inv(M)*Phi_0_s;
%% X Matrix
X1=(Phi_0_s*Phi_0_s')/C3;
X2=-((Phi_0_s*Phi_0_s'/M)*C)/C3;
X3=(Phi_0_s*G1)/C3;
X4=(Phi_0_s*G2-(Phi_0_s*Phi_0_s'/M)*C)/C3;
%% L Matrix
L1=C/M+X2/M;
L2=X1/M;
L3=X3/M;
L4=C/M+X4/M;
L=[L1 L2;L3 L4];
end