Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

(Hebbian learning)

I was given the task of programming the Oja's learning rule and Sanger's learning rule in Matlab, to train a neural network. This NN has 6 inputs and 4 outputs, and my training set comes from a multivariate uniform distribution, such as Xi ~ U(-ai,ai) and ai≠aj, for all i≠j

These are the most relevant files (Most comments and oja.m were not included)


TS = generarVectoresUnif(6, [1, 4, 9, 36, 25, 16], 512);
TS = TS';
W = unifrnd(0,1,[4,6]);
% it not very fast. That's why I put 500 iterations
W_sanger = sanger(W,TS,500, 0.05)


function [ TS ] = generarVectoresUnif( dim, rangos, n )
dimensiones = int8(dim);
tamanio = int32(n);
TS = [];

for i = 1:dimensiones
   TS = [TS, unifrnd(-rangos(i), rangos(i), [tamanio, 1]) ];


( NOTE: W is a 4 x 6 size matrix. Wi is the weight vector for the i-th output. Wij = (Wi)j. In the example, TS is a 6 x 512 size matrix )

function [ W ] = sanger( W_init, trainingset, iteraciones , eta)

W = W_init;

% obtiene los tamaños desde los parametros de entrada
size_input = size(W,2);
size_output = size(W,1);
n_patterns = size(trainingset, 2);

% one-tenth part
diezmo = iteraciones/10;

for it = 1:iteraciones

   if 0 == mod(it, diezmo)
      disp(horzcat('Iteracion numero ', num2str(it), ' de ',num2str(iteraciones)));

   % for each pattern
   for u = 1:n_patrones

      DeltaW = zeros(size(W));

      % Vi = sum{j=1...N} Wij * Xj
      V = W * trainingset(:,u);

      % sumatorias(i,j) is going to replace sum{k=1..i} Vk*Wkj
      sumatorias = zeros(size_output,size_input);
      for j = 1:size_input
         for k = 1:size_output
             % sumar de 1 hasta i, sin hacer otro ciclo
             sumatorias(k,j) = (V' .* [ones(1,k), zeros(1,size_output-k)]) * W(:,j);

       % calcula la variacion
       for i = 1:size_output
          for j=1:size_input
             % Delta Wij = eta * Vi * ( xj - sum{k=1..i} Vk*Wkj )
              DeltaW(i,j) = eta * V(i,1) * (trainingset(j,u) - sumatorias(i,j));

       W = W + DeltaW;      
       %W = 1/norm(W) * W; %<---is it necessary? [Hertz] doesn't mention it



Could you tell me please what I am doing wrong? Values of the matrix grow really fast. I have the same problem with oja.m

I've tried:

  • Replacing eta by 1/it --->NaN
  • Replacing eta by an exponential function of number of iterations --->ok, but it's not what I expected
  • Uncommenting W = 1/norm(W) * W;. This actually works, but it shouldn't be necessary, or should it?
share|improve this question
(Hebbian Learning) –  Jared Farrish Oct 23 '11 at 21:19
Oja's and Sanger's learning rules –  A.J. Oct 23 '11 at 21:51

2 Answers 2

up vote 1 down vote accepted

You need small values of eta. Consider your update rule:

DeltaW(i,j) = eta * V(i,1) * (trainingset(j,u) - sumatorias(i,j));

If eta is large, DeltaW is likely to have a large absolute value (i.e. very big, e.g. 100000, or very small, e.g. -111111). The next time around the loop sumatorias(i,j) will be quite large, because it is a function of the weights. The more iterations you have, the larger your weights will become, eventually leading to an overflow.

share|improve this answer

Ok. After several tries, I made it work.

I choose a relatively small value of eta: 0.00001

W_sanger = sanger(W,TS,1000, 0.00001) 

It's still slow, because of not taking advantage of matrix multiplication, which is optimized by Matlab.

I hope it helps someone else to not repeat the same mistake.


share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.