python实现简单遗传算法_Python

ObjFunction.py

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									import math

									def GrieFunc(vardim, x, bound):

									 """

									 Griewangk function

									 """

									 s1 = 0.

									 s2 = 1.

									 for i in range(1, vardim + 1):

									  s1 = s1 + x[i - 1] ** 2

									  s2 = s2 * math.cos(x[i - 1] / math.sqrt(i))

									 y = (1. / 4000.) * s1 - s2 + 1

									 y = 1. / (1. + y)

									 return y

									def RastFunc(vardim, x, bound):

									 """

									 Rastrigin function

									 """

									 s = 10 * 25

									 for i in range(1, vardim + 1):

									  s = s + x[i - 1] ** 2 - 10 * math.cos(2 * math.pi * x[i - 1])

									 return s

GAIndividual.py

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									import numpy as np

									import ObjFunction

									class GAIndividual:

									 '''

									 individual of genetic algorithm

									 '''

									 def __init__(self, vardim, bound):

									  '''

									  vardim: dimension of variables

									  bound: boundaries of variables

									  '''

									  self.vardim = vardim

									  self.bound = bound

									  self.fitness = 0.

									 def generate(self):

									  '''

									  generate a random chromsome for genetic algorithm

									  '''

									  len = self.vardim

									  rnd = np.random.random(size=len)

									  self.chrom = np.zeros(len)

									  for i in xrange(0, len):

									   self.chrom[i] = self.bound[0, i] + \

									    (self.bound[1, i] - self.bound[0, i]) * rnd[i]

									 def calculateFitness(self):

									  '''

									  calculate the fitness of the chromsome

									  '''

									  self.fitness = ObjFunction.GrieFunc(

									   self.vardim, self.chrom, self.bound)

GeneticAlgorithm.py

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									import numpy as np

									from GAIndividual import GAIndividual

									import random

									import copy

									import matplotlib.pyplot as plt

									class GeneticAlgorithm:

									 '''

									 The class for genetic algorithm

									 '''

									 def __init__(self, sizepop, vardim, bound, MAXGEN, params):

									  '''

									  sizepop: population sizepop

									  vardim: dimension of variables

									  bound: boundaries of variables

									  MAXGEN: termination condition

									  param: algorithm required parameters, it is a list which is consisting of crossover rate, mutation rate, alpha

									  '''

									  self.sizepop = sizepop

									  self.MAXGEN = MAXGEN

									  self.vardim = vardim

									  self.bound = bound

									  self.population = []

									  self.fitness = np.zeros((self.sizepop, 1))

									  self.trace = np.zeros((self.MAXGEN, 2))

									  self.params = params

									 def initialize(self):

									  '''

									  initialize the population

									  '''

									  for i in xrange(0, self.sizepop):

									   ind = GAIndividual(self.vardim, self.bound)

									   ind.generate()

									   self.population.append(ind)

									 def evaluate(self):

									  '''

									  evaluation of the population fitnesses

									  '''

									  for i in xrange(0, self.sizepop):

									   self.population[i].calculateFitness()

									   self.fitness[i] = self.population[i].fitness

									 def solve(self):

									  '''

									  evolution process of genetic algorithm

									  '''

									  self.t = 0

									  self.initialize()

									  self.evaluate()

									  best = np.max(self.fitness)

									  bestIndex = np.argmax(self.fitness)

									  self.best = copy.deepcopy(self.population[bestIndex])

									  self.avefitness = np.mean(self.fitness)

									  self.trace[self.t, 0] = (1 - self.best.fitness) / self.best.fitness

									  self.trace[self.t, 1] = (1 - self.avefitness) / self.avefitness

									  print("Generation %d: optimal function value is: %f; average function value is %f" % (

									   self.t, self.trace[self.t, 0], self.trace[self.t, 1]))

									  while (self.t < self.MAXGEN - 1):

									   self.t += 1

									   self.selectionOperation()

									   self.crossoverOperation()

									   self.mutationOperation()

									   self.evaluate()

									   best = np.max(self.fitness)

									   bestIndex = np.argmax(self.fitness)

									   if best > self.best.fitness:

									    self.best = copy.deepcopy(self.population[bestIndex])

									   self.avefitness = np.mean(self.fitness)

									   self.trace[self.t, 0] = (1 - self.best.fitness) / self.best.fitness

									   self.trace[self.t, 1] = (1 - self.avefitness) / self.avefitness

									   print("Generation %d: optimal function value is: %f; average function value is %f" % (

									    self.t, self.trace[self.t, 0], self.trace[self.t, 1]))

									  print("Optimal function value is: %f; " %

									    self.trace[self.t, 0])

									  print "Optimal solution is:"

									  print self.best.chrom

									  self.printResult()

									 def selectionOperation(self):

									  '''

									  selection operation for Genetic Algorithm

									  '''

									  newpop = []

									  totalFitness = np.sum(self.fitness)

									  accuFitness = np.zeros((self.sizepop, 1))

									  sum1 = 0.

									  for i in xrange(0, self.sizepop):

									   accuFitness[i] = sum1 + self.fitness[i] / totalFitness

									   sum1 = accuFitness[i]

									  for i in xrange(0, self.sizepop):

									   r = random.random()

									   idx = 0

									   for j in xrange(0, self.sizepop - 1):

									    if j == 0 and r < accuFitness[j]:

									     idx = 0

									     break

									    elif r >= accuFitness[j] and r < accuFitness[j + 1]:

									     idx = j + 1

									     break

									   newpop.append(self.population[idx])

									  self.population = newpop

									 def crossoverOperation(self):

									  '''

									  crossover operation for genetic algorithm

									  '''

									  newpop = []

									  for i in xrange(0, self.sizepop, 2):

									   idx1 = random.randint(0, self.sizepop - 1)

									   idx2 = random.randint(0, self.sizepop - 1)

									   while idx2 == idx1:

									    idx2 = random.randint(0, self.sizepop - 1)

									   newpop.append(copy.deepcopy(self.population[idx1]))

									   newpop.append(copy.deepcopy(self.population[idx2]))

									   r = random.random()

									   if r < self.params[0]:

									    crossPos = random.randint(1, self.vardim - 1)

									    for j in xrange(crossPos, self.vardim):

									     newpop[i].chrom[j] = newpop[i].chrom[

									      j] * self.params[2] + (1 - self.params[2]) * newpop[i + 1].chrom[j]

									     newpop[i + 1].chrom[j] = newpop[i + 1].chrom[j] * self.params[2] + \

									      (1 - self.params[2]) * newpop[i].chrom[j]

									  self.population = newpop

									 def mutationOperation(self):

									  '''

									  mutation operation for genetic algorithm

									  '''

									  newpop = []

									  for i in xrange(0, self.sizepop):

									   newpop.append(copy.deepcopy(self.population[i]))

									   r = random.random()

									   if r < self.params[1]:

									    mutatePos = random.randint(0, self.vardim - 1)

									    theta = random.random()

									    if theta > 0.5:

									     newpop[i].chrom[mutatePos] = newpop[i].chrom[

									      mutatePos] - (newpop[i].chrom[mutatePos] - self.bound[0, mutatePos]) * (1 - random.random() ** (1 - self.t / self.MAXGEN))

									    else:

									     newpop[i].chrom[mutatePos] = newpop[i].chrom[

									      mutatePos] + (self.bound[1, mutatePos] - newpop[i].chrom[mutatePos]) * (1 - random.random() ** (1 - self.t / self.MAXGEN))

									  self.population = newpop

									 def printResult(self):

									  '''

									  plot the result of the genetic algorithm

									  '''

									  x = np.arange(0, self.MAXGEN)

									  y1 = self.trace[:, 0]

									  y2 = self.trace[:, 1]

									  plt.plot(x, y1, 'r', label='optimal value')

									  plt.plot(x, y2, 'g', label='average value')

									  plt.xlabel("Iteration")

									  plt.ylabel("function value")

									  plt.title("Genetic algorithm for function optimization")

									  plt.legend()

									  plt.show()

运行程序：

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									if __name__ == "__main__":

									 bound = np.tile([[-600], [600]], 25)

									 ga = GA(60, 25, bound, 1000, [0.9, 0.1, 0.5])

									 ga.solve()