msaroufim/nn.py

## nn.py
class NeuralNetwork:
    def __init__(self, x, y):
        self.input      = x
        self.weights1   = np.random.rand(self.input.shape[1],4)
        self.weights2   = np.random.rand(4,1)
        self.y          = y
        self.output     = np.zeros(self.y.shape)

    def feedforward(self):
        self.layer1 = sigmoid(np.dot(self.input, self.weights1))
        self.output = sigmoid(np.dot(self.layer1, self.weights2))

    def backprop(self):
        # application of the chain rule to find derivative of the loss function with respect to weights2 and weights1
        d_weights2 = np.dot(self.layer1.T, (2*(self.y - self.output) * sigmoid_derivative(self.output)))
        d_weights1 = np.dot(self.input.T,  (np.dot(2*(self.y - self.output) * sigmoid_derivative(self.output), self.weights2.T) * sigmoid_derivative(self.layer1)))

        # update the weights with the derivative (slope) of the loss function
        self.weights1 += d_weights1
        self.weights2 += d_weights2
	class NeuralNetwork:
	def __init__(self, x, y):
	self.input = x
	self.weights1 = np.random.rand(self.input.shape[1],4)
	self.weights2 = np.random.rand(4,1)
	self.y = y
	self.output = np.zeros(self.y.shape)

	def feedforward(self):
	self.layer1 = sigmoid(np.dot(self.input, self.weights1))
	self.output = sigmoid(np.dot(self.layer1, self.weights2))

	def backprop(self):
	# application of the chain rule to find derivative of the loss function with respect to weights2 and weights1
	d_weights2 = np.dot(self.layer1.T, (2(self.y - self.output) sigmoid_derivative(self.output)))
	d_weights1 = np.dot(self.input.T, (np.dot(2(self.y - self.output) sigmoid_derivative(self.output), self.weights2.T) * sigmoid_derivative(self.layer1)))

	# update the weights with the derivative (slope) of the loss function
	self.weights1 += d_weights1
	self.weights2 += d_weights2