how to save the network training in the particular iteration

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ajith on 23 Jul 2013

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https://nl.mathworks.com/matlabcentral/answers/82868-how-to-save-the-network-training-in-the-particular-iteration

in a BPN training i need to save the network in the particular iteration and i load that when it needs and also begin the iteration when its stops how its possible sir

   function Network = bbackprop(L,n,m,smse,X,D)
  %%%%%VERIFICATION PHASE %%%%%
  % determine number of input samples, desired output and their dimensions
  [P,N] = size(X);
  [Pd, M] = size (D);
% make user that each input vector has a corresponding desired output
if P ~= Pd 
    error('backprop:invalidTrainingAndDesired', ...
          'The number of input vectors and desired ouput do not match');
end
% make sure that at least 3 layers have been specified and that the 
% the dimensions of the specified input layer and output layer are
% equivalent to the dimensions of the input vectors and desired output
if length(L) < 3 
    error('backprop:invalidNetworkStructure','The network must have at least 3 layers');
else
    if N ~= L(1) || M ~= L(end)
        e = sprintf('Dimensions of input (%d) does not match input layer (%d)',N,L(1));
        error('backprop:invalidLayerSize', e);
    elseif M ~= L(end)
        e = sprintf('Dimensions of output (%d) does not match output layer (%d)',M,L(end));
        error('backprop:invalidLayerSize', e);    
    end
end
%%%%%INITIALIZATION PHASE %%%%%
nLayers = length(L); % we'll use the number of layers often  
% randomize the weight matrices (uniform random values in [-1 1], there
% is a weight matrix between each layer of nodes. Each layer (exclusive the 
% output layer) has a bias node whose activation is always 1, that is, the 
% node function is C(net) = 1. Furthermore, there is a link from each node
% in layer i to the bias node in layer j (the last row of each matrix)
% because it is less computationally expensive then the alternative. The 
% weights of all links to bias nodes are irrelevant and are defined as 0
w = cell(nLayers-1,1); % a weight matrix between each layer
for i=1:nLayers-2        
    w{i} = [1 - 2.*rand(L(i+1),L(i)+1) ; zeros(1,L(i)+1)];
end
w{end} = 1 - 2.*rand(L(end),L(end-1)+1);

% initialize stopping conditions mse = Inf; % assuming the intial weight matrices are bad epochs = 0;

a = cell(nLayers,1); % one activation matrix for each layer a{1} = [X ones(P,1)]; % a{1} is the input + '1' for the bias node activation % a{1} remains the same throught the computation for i=2:nLayers-1 a{i} = ones(P,L(i)+1); % inner layers include a bias node (P-by-Nodes+1) end a{end} = ones(P,L(end)); % no bias node at output layer

net = cell(nLayers-1,1); % one net matrix for each layer exclusive input for i=1:nLayers-2; net{i} = ones(P,L(i+1)+1); % affix bias node end net{end} = ones(P,L(end));

prev_dw = cell(nLayers-1,1); sum_dw = cell(nLayers-1,1); for i=1:nLayers-1 prev_dw{i} = zeros(size(w{i})); % prev_dw starts at 0 sum_dw{i} = zeros(size(w{i})); end

% loop until computational bounds are exceeded or the network has converged % to a satisfactory condition. We allow for 30000 epochs here, it may be % necessary to increase or decrease this bound depending on the number of % training while mse > smse %&& epochs < 30000 change been done by dinesh % FEEDFORWARD PHASE: calculate input/output off each layer for all samples for i=1:nLayers-1 net{i} = a{i} * w{i}'; % compute inputs to current layer

        % compute activation(output of current layer, for all layers
        % exclusive the output, the last node is the bias node and
        % its activation is 1
        if i < nLayers-1 % inner layers
            a{i+1} = [2./(1+exp(-net{i}(:,1:end-1)))-1 ones(P,1)];
        else             % output layers
            a{i+1} = 2 ./ (1 + exp(-net{i})) - 1;
        end
    end
    % calculate sum squared error of all samples
    err = (D-a{end});       % save this for later
    sse = sum(sum(err.^2)); % sum of the error for all samples, and all nodes
    delta = err .* (1 + a{end}) .* (1 - a{end});
    for i=nLayers-1:-1:1
        sum_dw{i} = n * delta' * a{i};
        if i > 1
            delta = (1+a{i}) .* (1-a{i}) .* (delta*w{i});
        end
    end
    % update the prev_w, weight matrices, epoch count and mse
    for i=1:nLayers-1
        % we have the sum of the delta weights, divide through by the 
        % number of samples and add momentum * delta weight at (t-1)
        % finally, update the weight matrices
        prev_dw{i} = (sum_dw{i} ./ P) + (m * prev_dw{i});
        w{i} = w{i} + prev_dw{i};
    end   
    epochs = epochs + 1;
    mse = sse/(P*M); % mse = 1/P * 1/M * summed squared error
    %This is the line written by me
    if mod(epochs,1000)==0
        disp('MSE:');disp(mse);disp(' EPOCHS');disp(epochs);
    end
end