I have this Backpropagation implementation in MATLAB, and have an issue with training it. Early on in the training phase, all of the outputs go to 1. I have normalized the input data(except the desired class, which is used to generate a binary target vector) to the interval [0, 1]. I have been referring to the implementation in Artificial Intelligence: A Modern Approach, Norvig et al.
Having checked the pseudocode against my code(and studying the algorithm for some time), I cannot spot the error. I have not been using MATLAB for that long, so have been trying to use the documentation where needed.
I have also tried different amounts of nodes in the hidden layer and different learning rates(ALPHA).
The target data encodings are as follows:- when the target is to classify as, say 2, the target vector would be [0,1,0], say it were 1, [1, 0, 0] so on and so forth. I have also tried using different values for the target, such as (for class 1 for example) [0.5, 0, 0].
I noticed that some of my weights go above 1, resulting in large net values.
Hopefully somebody can spot the error. I have been trying to debug this all evening/morning.
%Topological constants NUM_HIDDEN = 8+1;%written as n+1 so is clear bias is used NUM_OUT = 3; %Training constants ALPHA = 0.01; TARG_ERR = 0.01; MAX_EPOCH = 50000; %Read and normalize data file. X = normdata(dlmread('iris.data')); X = shuffle(X); %X_test = normdata(dlmread('iris2.data')); %epocherrors = fopen('epocherrors.txt', 'w'); %Weight matrices. %Features constitute size(X, 2)-1, however size is (X, 2) to allow for %appending bias. w_IH = rand(size(X, 2), NUM_HIDDEN)-(0.5*rand(size(X, 2), NUM_HIDDEN)); w_HO = rand(NUM_HIDDEN+1, NUM_OUT)-(0.5*rand(NUM_HIDDEN+1, NUM_OUT));%+1 for bias %Layer nets net_H = zeros(NUM_HIDDEN, 1); net_O = zeros(NUM_OUT, 1); %Layer outputs out_H = zeros(NUM_HIDDEN, 1); out_O = zeros(NUM_OUT, 1); %Layer deltas d_H = zeros(NUM_HIDDEN, 1); d_O = zeros(NUM_OUT, 1); %Control variables error = inf; epoch = 0; %Run the algorithm. while error > TARG_ERR && epoch < MAX_EPOCH for n=1:size(X, 1) x = [X(n, 1:size(X, 2)-1) 1]';%Add bias for hiddens & transpose to column vector. o = X(n, size(X, 2)); %Forward propagate. net_H = w_IH'*x;%Transposed w. out_H = [sigmoid(net_H); 1]; %Append 1 for bias to outputs net_O = w_HO'*out_H; out_O = sigmoid(net_O); %Again, transposed w. %Calculate output deltas. d_O = ((targetVec(o, NUM_OUT)-out_O) .* (out_O .* (1-out_O))); %Calculate hidden deltas. for i=1:size(w_HO, 1); delta_weight = 0; for j=1:size(w_HO, 2) delta_weight = delta_weight + d_O(j)*w_HO(i, j); end d_H(i) = (out_H(i)*(1-out_H(i)))*delta_weight; end %Update hidden-output weights for i=1:size(w_HO, 1) for j=1:size(w_HO, 2) w_HO(i, j) = w_HO(i, j) + (ALPHA*out_H(i)*d_O(j)); end end %Update input-hidden weights. for i=1:size(w_IH, 1) for j=1:size(w_IH, 2) w_IH(i, j) = w_IH(i, j) + (ALPHA*x(i)*d_H(j)); end end out_O o %out_H %w_IH %w_HO %d_O %d_H end end function outs = sigmoid(nets) outs = zeros(size(nets, 1), 1); for i=1:size(nets, 1) if nets(i) < -45 outs(i) = 0; elseif nets(i) > 45 outs(i) = 1; else outs(i) = 1/1+exp(-nets(i)); end end end