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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(:)];

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?

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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.

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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);

    % Derivatives are computed for layer 2 and 3.

    % Theta grad is computed without regularization.

    % Regularization is added to grad computation.

    % 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.

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