Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to implement a regression NN that has 3 layers (1 input, 1 hidden and 1 output layer with a continuous result). As a basis I took a classification NN from coursera.org class, but changed the cost function and gradient calculation so as to fit a regression problem (and not a classification one):

My nnCostFunction now is:

function [J grad] = nnCostFunctionLinear(nn_params, ...
                                   input_layer_size, ...
                                   hidden_layer_size, ...
                                   num_labels, ...
                                   X, y, lambda)

Theta1 = reshape(nn_params(1:hidden_layer_size * (input_layer_size + 1)), ...
                 hidden_layer_size, (input_layer_size + 1));

Theta2 = reshape(nn_params((1 + (hidden_layer_size * (input_layer_size + 1))):end), ...
                 num_labels, (hidden_layer_size + 1));

m = size(X, 1);

a1 = X;
a1 = [ones(m, 1) a1];
a2 = a1 * Theta1';
a2 = [ones(m, 1) a2];
a3 = a2 * Theta2';
Y = y;

J = 1/(2*m)*sum(sum((a3 - Y).^2))

th1 = Theta1;
th1(:,1) = 0; %set bias = 0 in reg. formula
th2 = Theta2;
th2(:,1) = 0;

t1 = th1.^2;
t2 = th2.^2;
th = sum(sum(t1)) + sum(sum(t2));
th = lambda * th / (2*m);
J = J + th; %regularization


del_3 = a3 - Y;
t1 = del_3'*a2;
Theta2_grad = 2*(t1)/m + lambda*th2/m;

t1 = del_3 * Theta2;
del_2 = t1 .*  a2;
del_2 = del_2(:,2:end);
t1 = del_2'*a1;
Theta1_grad = 2*(t1)/m + lambda*th1/m;

grad = [Theta1_grad(:) ; Theta2_grad(:)];
end

Then I use this func in fmincg algorithm, but in firsts iterations fmincg end it's work. I think my gradient is wrong, but I can't find the error.

Can anybody help?

share|improve this question
    
Hi Mikhail, it was a question over 1 year ago, yet I was wondering whether you have already solved this problem? Actually another guy asked the same one, and I provided my code there, compared with Andrew Ng's checkNNGradients(lambda) and obtained the 1e-4 relative difference: stackoverflow.com/questions/20648422/… If you already solved this problem and got even less relative difference, please update by answering your own question; otherwise hopefully my code is helpful. Thanks –  lennon310 Dec 18 '13 at 23:07

2 Answers 2

If I understand correctly, your first block of code (shown below) -

m = size(X, 1);

a1 = X;
a1 = [ones(m, 1) a1];
a2 = a1 * Theta1';
a2 = [ones(m, 1) a2];
a3 = a2 * Theta2';
Y = y;

is to get the output a(3) at the output layer.

Ng's slides about NN has the below configuration to calculate a(3). It's different from what your code presents.

  • in the middle/output layer, you are not doing the activation function g, e.g., a sigmoid function.

enter image description here

In terms of the cost function J without regularization terms, Ng's slides has the below formula:

enter image description here

I don't understand why you can compute it using:

J = 1/(2*m)*sum(sum((a3 - Y).^2))

because you are not including the log function at all.

share|improve this answer
    
log() and sigmoid() - approach of logical regression NN. In coursera examples it's cancer detection, but i want house cost prediction –  Mikhail Erofeev Nov 7 '12 at 4:23

Mikhaill, I´ve been playing with a NN for continuous regression as well, and had a similar issues at some point. The best thing to do here would be to test gradient computation against a numerical calculation before running the model. If that´s not correct, fmincg won´t be able to train the model. (Btw, I discourage you of using numerical gradient as the time involved is much bigger).

Taking into account that you took this idea from Ng´s Coursera class, I´ll implement a possible solution for you to try using the same notation for Octave.

    % Cost function without regularization.
    J = 1/2/m^2*sum((a3-Y).^2); 

    % In case it´s needed, regularization term is added (i.e. for Training).
    if (reg==true);
 J=J+lambda/2/m*(sum(sum(Theta1(:,2:end).^2))+sum(sum(Theta2(:,2:end).^2)));
    endif;

    % Derivatives are computed for layer 2 and 3.
    d3=(a3.-Y);
    d2=d3*Theta2(:,2:end);

    % Theta grad is computed without regularization.
    Theta1_grad=(d2'*a1)./m;
    Theta2_grad=(d3'*a2)./m;

    % Regularization is added to grad computation.
    Theta1_grad(:,2:end)=Theta1_grad(:,2:end)+(lambda/m).*Theta1(:,2:end);
    Theta2_grad(:,2:end)=Theta2_grad(:,2:end)+(lambda/m).*Theta2(:,2:end);

    % Unroll gradients.
    grad = [Theta1_grad(:) ; Theta2_grad(:)];

Note that, since you have taken out all the sigmoid activation, the derivative calculation is quite simple and results in a simplification of the original code.

Next steps: 1. Check this code to understand if it makes sense to your problem. 2. Use gradient checking to test gradient calculation. 3. Finally, use fmincg and check you get different results.

share|improve this answer

Your Answer

 
discard

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.