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I have a code that works in Matlab version R2010a but shows errors in matlab R2008a. I am trying to implement a self organizing fuzzy neural network with extended kalman filter. I have the code running but it only works in matlab version R2010a. It doesn't work with other versions. Any help?

The error message that i am getting is "Parse error at ']' at lines 49, 130 188 & 189"

Code attach

function [ c, sigma , W_output ] = SOFNN( X, d, Kd )
%SOFNN Self-Organizing Fuzzy Neural Networks
%Input Parameters
% X(r,n) - rth traning data from nth observation
% d(n) - the desired output of the network (must be a row vector)
% Kd(r) - predefined distance threshold for the rth input

%Output Parameters
% c(IndexInputVariable,IndexNeuron)
% sigma(IndexInputVariable,IndexNeuron)
% W_output is a vector

%Setting up Parameters for SOFNN
SigmaZero=4;
delta=0.12;
threshold=0.1354;
k_sigma=1.12;

%For more accurate results uncomment the following
%format long;

%Implementation of a SOFNN model
[size_R,size_N]=size(X);
%size_R - the number of input variables
c=[]; 
sigma=[]; 
W_output=[];
u=0; % the number of neurons in the structure
Q=[];
O=[];
Psi=[];
for n=1:size_N
    x=X(:,n);    
    if u==0 % No neuron in the structure?
        c=x;
        sigma=SigmaZero*ones(size_R,1);
        u=1;
        Psi=GetMePsi(X,c,sigma);
        [Q,O] = UpdateStructure(X,Psi,d);
        pT_n=GetMeGreatPsi(x,Psi(n,:))';        
    else
        [Q,O,pT_n] = UpdateStructureRecursively(X,Psi,Q,O,d,n);
    end;

    KeepSpinning=true;
    while KeepSpinning
        %Calculate the error and if-part criteria
        ae=abs(d(n)-pT_n*O); %approximation error
        [phi,~]=GetMePhi(x,c,sigma);
        [maxphi,maxindex]=max(phi); % maxindex refers to the neuron's index

        if ae>delta
            if maxphi<threshold
                %enlarge width
                [minsigma,minindex]=min(sigma(:,maxindex));
                sigma(minindex,maxindex)=k_sigma*minsigma;
                Psi=GetMePsi(X,c,sigma);
                [Q,O] = UpdateStructure(X,Psi,d);
                pT_n=GetMeGreatPsi(x,Psi(n,:))';                               
            else
                %Add a new neuron and update structure
                ctemp=[];
                sigmatemp=[];
                dist=0;
                for r=1:size_R
                    dist=abs(x(r)-c(r,1));
                    distIndex=1;
                    for j=2:u
                        if abs(x(r)-c(r,j))<dist
                            distIndex=j;
                            dist=abs(x(r)-c(r,j));
                        end;
                    end;
                    if dist<=Kd(r)
                        ctemp=[ctemp; c(r,distIndex)];
                        sigmatemp=[sigmatemp ; sigma(r,distIndex)];
                    else
                        ctemp=[ctemp; x(r)];
                        sigmatemp=[sigmatemp ; dist];
                    end;
                end;
                c=[c ctemp];
                sigma=[sigma sigmatemp];
                Psi=GetMePsi(X,c,sigma);
                [Q,O] = UpdateStructure(X,Psi,d);
                KeepSpinning=false;
                u=u+1;
            end;
        else
            if maxphi<threshold
                %enlarge width
                [minsigma,minindex]=min(sigma(:,maxindex));
                sigma(minindex,maxindex)=k_sigma*minsigma;
                Psi=GetMePsi(X,c,sigma);
                [Q,O] = UpdateStructure(X,Psi,d);
                pT_n=GetMeGreatPsi(x,Psi(n,:))';                
            else
                %Do nothing and exit the while
                KeepSpinning=false;                
            end;
        end;        
    end;
end;
W_output=O;
end

function [Q_next, O_next,pT_n] = UpdateStructureRecursively(X,Psi,Q,O,d,n)
%O=O(t-1) O_next=O(t)
p_n=GetMeGreatPsi(X(:,n),Psi(n,:));
pT_n=p_n';
ee=abs(d(n)-pT_n*O); %|e(t)|
temp=1+pT_n*Q*p_n;
ae=abs(ee/temp);

if ee>=ae
    L=Q*p_n*(temp)^(-1);
    Q_next=(eye(length(Q))-L*pT_n)*Q;
    O_next=O + L*ee;
else
    Q_next=eye(length(Q))*Q;
    O_next=O;
end;
end

function [ Q , O ] = UpdateStructure(X,Psi,d)
GreatPsiBig = GetMeGreatPsi(X,Psi);

%M=u*(r+1)
%n - the number of observations
[M,~]=size(GreatPsiBig);

%Others Ways of getting Q=[P^T(t)*P(t)]^-1
%**************************************************************************
%opts.SYM = true;
%Q = linsolve(GreatPsiBig*GreatPsiBig',eye(M),opts);
%
%Q = inv(GreatPsiBig*GreatPsiBig');
%Q = pinv(GreatPsiBig*GreatPsiBig');
%**************************************************************************
Y=GreatPsiBig\eye(M);
Q=GreatPsiBig'\Y;

O=Q*GreatPsiBig*d';
end


%This function works too with x
% (X=X and Psi is a Matrix) - Gets you the whole GreatPsi
% (X=x and Psi is the row related to x) - Gets you just the column related with the observation
function [GreatPsi] = GetMeGreatPsi(X,Psi)
%Psi - In a row you go through the neurons and in a column you go through number of
%observations **** Psi(#obs,IndexNeuron) ****
GreatPsi=[];
[N,U]=size(Psi);
for n=1:N
    x=X(:,n);
    GreatPsiCol=[];
    for u=1:U
        GreatPsiCol=[ GreatPsiCol ; Psi(n,u)*[1; x] ];
    end;
    GreatPsi=[GreatPsi GreatPsiCol];
end;
end


function [phi, SumPhi]=GetMePhi(x,c,sigma)
[r,u]=size(c);
%u - the number of neurons in the structure
%r - the number of input variables

phi=[];
SumPhi=0;

for j=1:u % moving through the neurons
    S=0;
    for i=1:r % moving through the input variables
        S = S + ((x(i) - c(i,j))^2) / (2*sigma(i,j)^2);
    end;    
    phi = [phi exp(-S)];        
    SumPhi = SumPhi + phi(j);   %phi(u)=exp(-S)
end;
end


%This function works too with x, it will give you the row related to x
function [Psi] = GetMePsi(X,c,sigma)
[~,u]=size(c);
[~,size_N]=size(X);
%u - the number of neurons in the structure
%size_N - the number of observations
Psi=[];
for n=1:size_N        
    [phi, SumPhi]=GetMePhi(X(:,n),c,sigma);    
    PsiTemp=[];
    for j=1:u
        %PsiTemp is a row vector ex: [1 2 3]
        PsiTemp(j)=phi(j)/SumPhi;
    end;

    Psi=[Psi; PsiTemp];    
    %Psi - In a row you go through the neurons and in a column you go through number of
    %observations **** Psi(#obs,IndexNeuron) ****
end;

end
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  • 1
    Can you please do two things: 1) Post the error message - "I get an error message" is far less helpful than "I get error message X at line Y" - and 2) reduce the code to a short, self-contained, compilable example. As it stands we would have to actually copy your entire wall of code into MATLAB and run it, and that's assuming we have both old MATLAB and new MATLAB installed (I don't; I only have the latest MATLAB.) This is too much effort and will keep people from wanting to answer your question. Apr 11, 2012 at 5:32
  • 2
  • 1
    Additionally, even if I did want to install two versions of MATLAB and copy-paste your code into each of them, I couldn't actually run your code because I don't know what arguments the SOFNN function should take. This is not to mention all the function calls like GetMeGreatPsi() which won't work for us because we don't have those functions. Again, you need a short, self-contained example - pasting your entire code base helps no-one. Apr 11, 2012 at 5:36
  • 1
    Its not a duplicate. The codes are the same but i have 2 different questions pertaining to the same code. Apr 11, 2012 at 5:37
  • 1
    @user1325655: nonetheless, the remarks in the other question stand - you need to learn more about how this site works. Have you read the Frequently Asked Questions and the guide on how to ask questions? Apr 11, 2012 at 5:40

1 Answer 1

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Lines 49, 130, 188, and 190 are pasted below. Notice the trend?

[phi,~]=GetMePhi(x,c,sigma);
[M,~]=size(GreatPsiBig);
[~,u]=size(c);
[~,size_N]=size(X)

Basically as of MATLAB 2009b, the tilde operator was instituted so that variables that you didn't use later didn't have to be stored in memory. It also means that any code with tildes in it won't be backwards compatible before that version.

6
  • 1
    You actually waded through that wall of code? Take my +1. :P Apr 11, 2012 at 5:51
  • Thank you for your answer. Is there any way i can rectify the problem? Apr 11, 2012 at 5:51
  • 1
    As a sidenote, [~,u]=size(c) is equivalent to u = size(c,2) - that is, you can tell size() which dimension of the input matrix it should measure. See doc size for details. Apr 11, 2012 at 5:52
  • @user1325655: You can rectify the problem by not using the ~ syntax for don't-cares. Apr 11, 2012 at 5:53
  • @Li-aungYip Lol no, I had a hunch that turned out to be right
    – Squazic
    Apr 11, 2012 at 5:53

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