I am trying to implement a two-layer perceptron with backpropagation to solve the parity problem. The network has 4 binary inputs, 4 hidden units in the first layer and 1 output in the second layer. I am using this for reference, but am having problems with convergence.
First, I will note that I am using a sigmoid function for activation, and so the derivative is (from what I understand) the sigmoid(v) * (1 - sigmoid(v)). So, that is used when calculating the delta value.
So, basically I set up the network and run for just a few epochs (go through each possible pattern -- in this case, 16 patterns of input). After the first epoch, the weights are changed slightly. After the second, the weights do not change and remain so no matter how many more epochs I run. I am using a learning rate of 0.1 and a bias of +1 for now.
The process of training the network is below in pseudocode (which I believe to be correct according to sources I've checked):
Feed Forward Step:
v = SUM[weight connecting input to hidden * input value] + bias y = Sigmoid(v) set hidden.values to y v = SUM[weight connecting hidden to output * hidden value] + bias y = Sigmoid(v) set output value to y
Backpropagation of Output Layer:
error = desired - output.value outputDelta = error * output.value * (1 - output.value)
Backpropagation of Hidden Layer:
for each hidden neuron h: error = outputDelta * weight connecting h to output hiddenDelta[i] = error * h.value * (1 - h.value)
for each hidden neuron h connected to the output layer h.weight connecting h to output = learningRate * outputDelta * h.value for each input neuron x connected to the hidden layer x.weight connecting x to h[i] = learningRate * hiddenDelta[i] * x.value
This process is of course looped through the epochs and the weight changes persist. So, my question is, are there any reasons that the weights remain constant after the second epoch? If necessary I can post my code, but at the moment I am hoping for something obvious that I'm overlooking. Thanks all!
EDIT: Here are the links to my code as suggested by sarnold: