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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.

Best regards,

%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);
            d_H(i) = (out_H(i)*(1-out_H(i)))*delta_weight;

        %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));

        %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));

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;
            outs(i) = 1/1+exp(-nets(i));
share|improve this question
Have you tried setting ALPHA to a smaller value? 0.4 seems a bit too large –  BartoszKP Aug 4 '13 at 23:23
@BartoszKP Thanks for the response. Using 0.1 and 0.01 yield the same results. –  VisionIncision Aug 4 '13 at 23:27
Where are you calculating the gradient of the sigmoid function? Or maybe it is just too early to see it. –  Thomas Jungblut Aug 5 '13 at 5:18
If I remember correctly "(out_H(i)*(1-out_H(i)))" is the gradient. –  BartoszKP Aug 5 '13 at 10:06
Yes, that is the gradient(for the i'th hidden node) –  VisionIncision Aug 5 '13 at 10:14
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2 Answers

up vote 1 down vote accepted

After chat discussions and the question update, there are still two main problems with this code:

1) No bias. Without the bias each neuron can only represent a line which crosses the origin. If data is normalized (i.e. values are between 0 and 1), some configurations are inseparable.

2) Lack of guarding against high gradient values (point 1 in my previous answer).

I know you've said that you've tried these fixes, but they are somehow essential, and you must not give them up. Please repost the code with these two issues fixed.


The problem lies within the sigmoid function:

function outs = sigmoid(nets)
            outs(i) = 1/1+exp(-nets(i)); % parenthesis missing!!!!!!

It should be:

function outs = sigmoid(nets)
            outs(i) = 1/(1+exp(-nets(i)));

The lack of parenthesis caused that the sigmoid output was larger than 1 sometimes. That made the gradient calculation incorrect (because it wasn't a gradient of this function). This caused the gradient to be negative. And this caused that the delta for the output layer was most of the time in the wrong direction. After the fix (the after correctly maintaining the error variable - this seems to be missing in your code) all seems to work fine.

share|improve this answer
Updated. I have added comments to signify where I add bias. One weighted bias node outputting 1 per non-output layer. Still the same result. Thanks for sticking with this. –  VisionIncision Aug 7 '13 at 17:23
Thanks for the comments in the code, I think I understand everything it does - however could you provide the definition of the targetVec function? I'll try to run this program at my machine and debug it. From reading it as it is now, it seems it should work (depending on targetVec implementation) –  BartoszKP Aug 7 '13 at 23:18
I think I've found the answer :) I've edited my post :) –  BartoszKP Aug 8 '13 at 0:01
YES!! Thank you so much! I honestly do not know how I missed that! –  VisionIncision Aug 8 '13 at 21:27
Yeah, me too :D It was in plain sight all the time ;) –  BartoszKP Aug 9 '13 at 9:37
add comment

From what we've established in the comments the only thing that comes in my mind are all recipes written down together in this great NN archive:


First things you could try are:

1) How to avoid overflow in the logistic function? Probably that's the problem - many times I've implemented NNs the problem was with such an overflow.

2) How should categories be encoded?

And more general:

3) How does ill-conditioning affect NN training?

4) Help! My NN won't learn! What should I do?

share|improve this answer
Wow, what a great resource, thanks! 1) I thought the function I use(1/1+e^-t) was the logistic function? 2) I have encoded my desired output vector as described there. As for the other points, I shall have a read/experiment and let you know if there is any update. Regards –  VisionIncision Aug 5 '13 at 11:46
You're right. So that'll be probably this problem - I also encountered such problems with overflow when using this function in ANNs. I've updated the answer accordingly. –  BartoszKP Aug 5 '13 at 11:57
Ah ok, thanks, why the constant 45? Regards. –  VisionIncision Aug 5 '13 at 12:04
Update:- having attempted to deal with the logistic overflow problem, I still only get outputs of 1. Regards. –  VisionIncision Aug 5 '13 at 12:12
It really doesn't matter - 45 in relation to outputs in range 0-1 is still a very large number. Could you provide class ratio in your training and testing data files? –  BartoszKP Aug 5 '13 at 13:26
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