I’ve recently been working with neural networks and currently have a neural network class and a simple program to evolve the network weights.
The class and a few methods are defined in NeuralFunctions.py. The function createRandomWeights is currently set up to create a 9 neuron network when test = True and a completely random network when test = False.
The weights are defined as:
# Neural Network Class Functions # NeuralFunctions.py # Written in Python. See http://www.python.org/ # Placed in the public domain. # Chad Bonner 1.31.2015 # Based on Back-Propagation Neural Networks by # Neil Schemenauer <nas@arctrix.com> print "NeuralNet v1.0" import math import random import numpy as np weightLimit = 5 #Somewhat arbitrary choice #-------------Support Functions---------------- random.seed() def createRandomWeights(n, weightLimit, test): # n = number of neurons # create matrix for weights if test == True: weights = np.array([[0.0 for i in range(n)] for j in range(n)]) weights[2,0] = random.uniform(-weightLimit,weightLimit) weights[2,1] = random.uniform(-weightLimit,weightLimit) weights[3,0] = random.uniform(-weightLimit,weightLimit) weights[3,1] = random.uniform(-weightLimit,weightLimit) weights[4,2] = random.uniform(-weightLimit,weightLimit) weights[4,3] = random.uniform(-weightLimit,weightLimit) else: weights = np.array([[random.uniform(-weightLimit,weightLimit) for i in range(n)] for j in range(n)]) return weights def createNets(numNets, sizeNet, numOut): # Create population of neural nets # Create a set of network connection weights with random weights # Instantiate nets and load with weights # Set test = True to use predefined weights test = True nets = [] #create empty variable to hold neural nets for id in range(numNets): #create weights for neuron connections weights = createRandomWeights(sizeNet, weightLimit, test) #instantiate a neural net # id=0, number of neurons, number of outputs, dna nets.append(NeuralNet(id, sizeNet, numOut, weights)) return nets # our sigmoid function, tanh is a little nicer than the standard 1/(1+e^-x) def sigmoid(x): # init output variable y = np.array([0.0]*len(x)) for i in range(len(x)): y[i] = math.tanh(x[i])*2 return y #------------ Neural Net Class Definition ------------------------------ class NeuralNet: def __init__(self, id, n, no, weights): # n = number of neurons # no = number of outputs self.id = id self.n = n self.no = no self.weights = weights # activations for nodes self.ai = np.array([0]*self.n) #make all inputs neutral self.an = np.array([0]*self.n) #neuron outputs self.summ = np.array([0]*self.n) #init neuron activation levels to 0 def identifyNet(self): print 'Net ', self.id def update(self, neuronInputs): # init neuron activation levels to 0 self.summ = np.array([0]*self.n) # Apply inputs to input neurons self.ai[:len(neuronInputs)] = neuronInputs # Add neuron inputs to activation level self.summ = self.ai + np.dot(self.weights, self.an) # set neuron outputs self.an = sigmoid(self.summ) # net output is the output from the last no neurons out = (self.an[self.n-self.no:]) #print "out", out return out
# Evolution.py # # Written in Python. See http://www.python.org/ # Placed in the public domain. # Chad Bonner 1.31.2015 from __future__ import division import NeuralFunctions as nf import weightedRandomChoice as wrc import random import numpy as np import csv import operator from collections import defaultdict # Setup numGenerations = 50 #number of generations numIterations = 4 #number of times to run each net numNets =2000 #Size of the population sizeNet = 5 #Number of neurons in each net numOut = 1 #Number of outputs for each net nets = [] #create empty variable to hold neural nets nextGenNets = [] #create empty variable to hold neural nets netFitness = {} #dictionary to hold net index and fitness indexParents = [] #index of nets to be parents of next gen parentDNA = [] #dna of parents childDNA = [] #dna of children in the next gen inputs = np.array([[0,0],[1,0],[0,1],[1,1]]) #============================================================================ #inputs = np.array([[0,0,0,0],[0,0,0,1],[0,0,1,0],[0,0,1,1], # [0,1,0,0],[0,1,0,1],[0,1,1,0],[0,1,1,1], # [1,0,0,0],[1,0,0,1],[1,0,1,0],[1,0,1,1], # [1,1,0,0],[1,1,0,1],[1,1,1,0],[1,1,1,1]]) #============================================================================ def netEvaluate(nets, inputs): #Apply input to each net and evaluate fitness fitness = {} #dictionary to hold net index and fitness for index, net in enumerate(nets): #let signals progagate through net for iterations #then look at output fitness[index] = 0 for i in range(len(inputs)): #print "Input:", i for c in range(numIterations): #allow for propgation to output out = net.update(inputs[i]) out = net.update(inputs[i]) #============================================================================ #Modify fitness here to suit application #Arbitrary choice of matching for input pattern 0101. A correct match #will have an output of 1 for an input of 0101 and an output of -1 for #all other input patterns. #Set out = [1,0] for even input # if np.any(np.all(np.equal(inputs[i], # [[0,0,0,0],[0,0,1,0],[0,1,0,0],[0,1,1,0],[1,0,0,0], # [1,0,1,0],[1,1,0,0],[1,1,1,0]]), 1)): # if out[0] >= 1 and out[1] < 0.2: # fitness[index] = fitness[index] + 1 #award points # else: # if out[0] < 0.2 and out[1] >= 1: # fitness[index] = fitness[index] + 1 #award #============================================================================ #============================================================================ # #Modify fitness here to suit application if np.any(np.all(np.equal(inputs[i], [[0,1],[1,0]]), 1)): #print "Should be 1: Out =", out if out >= [0.9]: fitness[index] = fitness[index] + 1 #award points #print "Rewarded for +1 output" else: #print "Should be 0: Out =", out if out < [0.2]: fitness[index] = fitness[index] + 1 #award #print "Rewarded for 0 output" if fitness[index] == 4: fitness[index] = 15 #award a lot of points for correct answer #============================================================================ return fitness def writeFile(f, generation, fitness, fitIndex, nets, inputs, writeAll): # Write data to CSV file outputs = [] #create empty variable to hold net outputs writer = csv.writer(f, delimiter=',') if writeAll == True: for net in nets: writer.writerow(['Generation', 'Fitness', 'ID', 'SizeNet', 'NumOut', 'Weights']) writer.writerow([generation, fitness, net.id, net.n, net.no]) for j in range(net.n): writer.writerow(net.weights[j]) else: writer.writerow(['Generation', 'Fitness', 'ID', 'SizeNet', 'NumOut', 'Weights']) writer.writerow([generation, fitness, nets[fitIndex].id, nets[fitIndex].n, nets[fitIndex].no]) for i in range(len(inputs)): for c in range(numIterations): nets[fitIndex].update(inputs[i]) outputs.append(nets[fitIndex].update(inputs[i])) writer.writerow(outputs) print outputs for j in range(nets[fitIndex].n): writer.writerow(nets[fitIndex].weights[j]) return def breed(netFitness, nets): # Create new population by combining # parents's dna (sexual reproduction). # Each net can combine with any other net, even itself. #print netFitness pairs = zip(netFitness.values(),netFitness.keys()) pairs.sort() pairs.reverse() nextGenNets = [] # clear next gen variable for use for c, net in enumerate(nets): mom = wrc.weighted_random_choice(pairs) #print "mom", mom dad = wrc.weighted_random_choice(pairs) #print "dad", dad childDNA = np.array([[0.0 for i in range(net.n)] for j in range(net.n)]) for neuron in range(net.n): #take one neuron from each parent and combine to form child childDNA[neuron,:] = nets[random.choice((mom,dad))].weights[neuron,:] # now create new net using child dna # instantiate a neural net nextGenNets.append(nf.NeuralNet(c, net.n, net.no, childDNA)) return nextGenNets # ------------------------- Main Routine ------------------------------ #def main(): #Open file to save data csvfile = open('data_out.csv', 'wb') #Create and evaluate initial population of neural nets print "Genesis!" nets = nf.createNets(numNets, sizeNet, numOut) # Apply input to each net and evaluate fitness netFitness = netEvaluate(nets, inputs) fitHistogram = defaultdict(int) #variable to hold count of fitness values #Count frequency of fitness values for value in netFitness.values(): fitHistogram[value] += 1 #print fitHistogram print "Generation Fitness:", "%.3f"%((sum(netFitness.values())/numNets)) # Identify net with maximum fitness and save to log file mostFit = max(netFitness.iteritems(), key=operator.itemgetter(1))[0] mostFitness = netFitness[mostFit] print "Most Fit:", mostFit writeFile(csvfile, 0, mostFitness, mostFit, nets, inputs, False) # Go forth and multiply for generation in range(1, numGenerations): #Breed next generation nets = breed(netFitness, nets) print " " print "Generation:", generation, "born" # Apply input to each net and evaluate fitness netFitness = netEvaluate(nets, inputs) fitHistogram = defaultdict(int) #variable to hold count of fitness values #Count frequency of fitness values for value in netFitness.values(): fitHistogram[value] += 1 print fitHistogram print "Generation Fitness:", "%.3f"%((sum(netFitness.values())/numNets)) # Identify net with maximum fitness and save to log file mostFit = max(netFitness.iteritems(), key=operator.itemgetter(1))[0] mostFitness = netFitness[mostFit] print "Most Fit:", mostFit writeFile(csvfile, generation, mostFitness, mostFit, nets, inputs, False) #print "Best net saved" #print "Iteration", generation, "complete!" csvfile.close() print "Done!"
Currently it takes about 12 seconds to run a population of 50 nets of 500 neurons each for 50 cycles. I’m using numpy to speed things up. I’m sure there are still opportunities for improvement. Creating the nets actually takes longer than running them as shown below (click to enlarge).
Leave a Reply
You must be logged in to post a comment.