function [J grad] = nnCostFunction(nn_params, ... input_layer_size, ... hidden_layer_size, ... num_labels, ... X, y, lambda) %NNCOSTFUNCTION Implements the neural network cost function for a two layer %neural network which performs classification % [J grad] = NNCOSTFUNCTON(nn_params, hidden_layer_size, num_labels, ... % X, y, lambda) computes the cost and gradient of the neural network. The % parameters for the neural network are "unrolled" into the vector % nn_params and need to be converted back into the weight matrices. % % The returned parameter grad should be a "unrolled" vector of the % partial derivatives of the neural network. % % Reshape nn_params back into the parameters Theta1 and Theta2, the weight matrices % for our 2 layer neural network 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)); % Setup some useful variables m = size(X, 1); % You need to return the following variables correctly J = 0; Theta1_grad = zeros(size(Theta1)); Theta2_grad = zeros(size(Theta2)); % ====================== YOUR CODE HERE ====================== % Instructions: You should complete the code by working through the % following parts. % % Part 1: Feedforward the neural network and return the cost in the % variable J. After implementing Part 1, you can verify that your % cost function computation is correct by verifying the cost % computed in ex4.m % % Part 2: Implement the backpropagation algorithm to compute the gradients % Theta1_grad and Theta2_grad. You should return the partial derivatives of % the cost function with respect to Theta1 and Theta2 in Theta1_grad and % Theta2_grad, respectively. After implementing Part 2, you can check % that your implementation is correct by running checkNNGradients % % Note: The vector y passed into the function is a vector of labels % containing values from 1..K. You need to map this vector into a % binary vector of 1's and 0's to be used with the neural network % cost function. % % Hint: We recommend implementing backpropagation using a for-loop % over the training examples if you are implementing it for the % first time. % % Part 3: Implement regularization with the cost function and gradients. % % Hint: You can implement this around the code for % backpropagation. That is, you can compute the gradients for % the regularization separately and then add them to Theta1_grad % and Theta2_grad from Part 2. % X = [ones(m, 1) X]; cost_vector = zeros(m, 1); for c = 1:m a1 = X(c, :); % one training example z2 = Theta1 * a1'; a2 = sigmoid(z2); a2 = [ones(1, 1); a2]; z3 = Theta2 * a2; a3 = sigmoid(z3); actual_vector = zeros(num_labels, 1); number = y(c, 1); actual_vector(number, 1) = 1; cost_vector(c, 1) = sum(actual_vector .* log(a3)) + sum((1 - actual_vector) .* log(1 - a3)); delta3 = a3 - actual_vector; z2 = [1; z2]; delta2 = (Theta2' * delta3) .* sigmoidGradient(z2); delta2 = delta2(2:end); Theta2_grad = Theta2_grad + delta3 * a2'; Theta1_grad = Theta1_grad + delta2 * a1; end J = (-1 / m) * sum(cost_vector); square_sum_theta1 = sum(sum(Theta1 .^ 2)) - sum(Theta1 .^ 2)(1, 1); square_sum_theta2 = sum(sum(Theta2 .^ 2)) - sum(Theta2 .^ 2)(1, 1); reg = (lambda / (2 * m)) * (square_sum_theta1 + square_sum_theta2); J = J + reg; Theta1_grad = Theta1_grad .* (1 / m); Theta2_grad = Theta2_grad .* (1 / m); reg_theta1 = Theta1 * (lambda / m); reg_theta1(:, 1) = 0; Theta1_grad = Theta1_grad + reg_theta1; reg_theta2 = Theta2 * (lambda / m); reg_theta2(:, 1) = 0; Theta2_grad = Theta2_grad + reg_theta2; % ------------------------------------------------------------- % ========================================================================= % Unroll gradients grad = [Theta1_grad(:) ; Theta2_grad(:)]; end