Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have been studying neural networks, and I have written the below. I haven't got a clue if i've done this the right way or not, I just made it up as i went along ....

Can someone please tell me if it will produce the correct output ?

Also, any pointers are much appreciated :)

import random
import math

weightsMin = -1000
weightsMax = 1000
weightsDivisor = 1000
bias = 1.00
hiddenActivationID = 6
outputActivationID = 5

class ActivationFunctions:
    def hardLimit(self, n):
        if n >= 0: return 1
        else: return 0

    def symetricalHardLimit(self, n):
        if n >= 0: return 1
        else: return -1

    def linear(self, n):
        return n

    def saturatingLinear(self, n):
        if n < 0: return 0
        elif n > 1: return 1
        else: return n

    def logSigmoid(self, n):
        return 1 / (1 + math.exp(-n))

    def hyperbolicTangentSigmoid(self, n):
        return math.tanh(n)

    def activationFunction(self, functionID, n):
        """ ID reference:
                1: hardLimit
                2: symetricalHardLimit
                3: linear
                4: saturatingLinear
                5: logSigmoid
                6: hyperbolicTangentSigmoid """
        if functionID == 1:
            return self.hardLimit(n)
        elif functionID == 2:
            return self.symetricalHardLimit(n)
        elif functionID == 3:
            return self.linear(n)
        elif functionID == 4:
            return self.saturatingLinear(n)
        elif functionID == 5:
            return self.logSigmoid(n)
        elif functionID == 6:
            return self.hyperbolicTangentSigmoid(n)

class NeuronModel:
        def __init__(self, numWeights):
            self.weights = []
            for i in xrange(numWeights+1):
                self.weights.append(random.randint(weightsMin, weightsMax)
                                    / float(weightsDivisor))

class LayerModel:
        def __init__(self, numNeurons, numWeights):
            self.neurons = []
            for i in xrange(numNeurons):
                self.neurons.append(NeuronModel(numWeights))

class NeuralNetworkModel:
    def __init__(self, numInputs, numOutputs, hiddenLayers):
        self.layers = []
        for i in xrange(len(hiddenLayers)):
            if i == 0: self.layers.append(LayerModel(hiddenLayers[i], numInputs))
            else: self.layers.append(LayerModel(hiddenLayers[i], hiddenLayers[i-1]))
        if len(hiddenLayers) == 0: self.layers.append(LayerModel(numOutputs, numInputs))
        else: self.layers.append(LayerModel(numOutputs, hiddenLayers[-1]))

class NeuralNetwork(ActivationFunctions):
    def __init__(self, numInputs, numOutputs, hiddenLayers):
        self.createNeuralNetwork(numInputs, numOutputs, hiddenLayers)

    def createNeuralNetwork(self, numInputs, numOutputs, hiddenLayers):
        self.neuralNetwork = NeuralNetworkModel(numInputs, numOutputs, hiddenLayers)

    def getNumConnections(self):
        numConnections = 0
        for layer in self.neuralNetwork.layers:
            for neuron in layer.neurons:
                for weight in neuron.weights:
                    numConnections += 1
        return numConnections

    def getWeights(self):
        weights = []
        for layer in self.neuralNetwork.layers:
            for neuron in layer.neurons:
                for weight in neuron.weights:
                    weights.append(weight)
        return weights

    def setWeights(self, weights):
        counter = 0
        for layer in self.neuralNetwork.layers:
            for neuron in layer.neurons:
                for i in xrange(len(neuron.weights)):
                    neuron.weights[i] = weights[counter]
                    counter += 1

    def getOutput(self, inputs):
        for layerNum in xrange(len(self.neuralNetwork.layers)):
            layerOut = []
            inputs.append(float(bias))
            for neuron in self.neuralNetwork.layers[layerNum].neurons:
                neuronOut = 0
                for inputNum in xrange(len(inputs)):
                    neuronOut += (inputs[inputNum] * neuron.weights[inputNum])
                if layerNum == len(self.neuralNetwork.layers)-1:
                    neuronOut = self.activationFunction(outputActivationID,
                                                        neuronOut)
                else:
                    neuronOut = self.activationFunction(hiddenActivationID,
                                                        neuronOut)
                layerOut.append(neuronOut)
            inputs = layerOut
        return inputs
share|improve this question
    
Define "correct output", and what happened when you tested this code? Did it behave as expected? –  Mat Apr 27 '12 at 11:02
    
Hi Mat, i have tested this and it 'seems' to produce the correct output - based on the given weight values. However, when i attempt to train this (using a genetic algorithm) it doesn't seem to converge. Obviously this could be something to do with the training process, or the data etc. but i just wanted to confirm the neural network itself is working correctly. –  Sherlock Apr 27 '12 at 11:10
2  
Just a note: Implementations of neural networks done by neuron object and built from those objects tend to be very slow. Using matrix for one layer representation and algorithms using matrix multiplications / additions are faster and easier to debug. –  Fenikso Apr 27 '12 at 11:24
    
Thanks for the note Fenisko, I will look into using matrix instead of objects, cheers –  Sherlock Apr 27 '12 at 11:34

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Browse other questions tagged or ask your own question.