179 lines
5.6 KiB
Python
179 lines
5.6 KiB
Python
# -*- coding: utf-8 -*-
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"""
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Created on Mon May 16 10:42:18 2016
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@author: hossam
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"""
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import random
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import numpy
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import math
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from solution import solution
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import time
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def MFO(objf, lb, ub, dim, N, Max_iteration):
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# Max_iteration=1000
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# lb=-100
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# ub=100
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# dim=30
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#N = 50 # Number of search agents
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if not isinstance(lb, list):
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lb = [lb] * dim
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if not isinstance(ub, list):
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ub = [ub] * dim
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# Initialize the positions of moths
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Moth_pos = numpy.zeros((N, dim))
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for i in range(dim):
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Moth_pos[:, i] = numpy.random.uniform(0, 1, N) * (ub[i] - lb[i]) + lb[i]
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Moth_fitness = numpy.full(N, float("inf"))
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# Moth_fitness=numpy.fell(float("inf"))
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Convergence_curve = numpy.zeros(Max_iteration)
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sorted_population = numpy.copy(Moth_pos)
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fitness_sorted = numpy.zeros(N)
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#####################
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best_flames = numpy.copy(Moth_pos)
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best_flame_fitness = numpy.zeros(N)
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####################
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double_population = numpy.zeros((2 * N, dim))
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double_fitness = numpy.zeros(2 * N)
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double_sorted_population = numpy.zeros((2 * N, dim))
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double_fitness_sorted = numpy.zeros(2 * N)
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#########################
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previous_population = numpy.zeros((N, dim))
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previous_fitness = numpy.zeros(N)
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s = solution()
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print('MFO is optimizing "' + objf.__name__ + '"')
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timerStart = time.time()
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s.startTime = time.strftime("%Y-%m-%d-%H-%M-%S")
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Iteration = 1
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# Main loop
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while Iteration < Max_iteration:
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# Number of flames Eq. (3.14) in the paper
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Flame_no = round(N - Iteration * ((N - 1) / Max_iteration))
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for i in range(0, N):
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# Check if moths go out of the search spaceand bring it back
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for j in range(dim):
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Moth_pos[i, j] = numpy.clip(Moth_pos[i, j], lb[j], ub[j])
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# evaluate moths
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Moth_fitness[i] = objf(Moth_pos[i, :])
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if Iteration == 1:
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# Sort the first population of moths
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fitness_sorted = numpy.sort(Moth_fitness)
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I = numpy.argsort(Moth_fitness)
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sorted_population = Moth_pos[I, :]
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# Update the flames
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best_flames = sorted_population
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best_flame_fitness = fitness_sorted
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else:
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#
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# # Sort the moths
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double_population = numpy.concatenate(
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(previous_population, best_flames), axis=0
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)
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double_fitness = numpy.concatenate(
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(previous_fitness, best_flame_fitness), axis=0
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)
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#
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double_fitness_sorted = numpy.sort(double_fitness)
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I2 = numpy.argsort(double_fitness)
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#
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#
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for newindex in range(0, 2 * N):
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double_sorted_population[newindex, :] = numpy.array(
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double_population[I2[newindex], :]
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)
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fitness_sorted = double_fitness_sorted[0:N]
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sorted_population = double_sorted_population[0:N, :]
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#
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# # Update the flames
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best_flames = sorted_population
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best_flame_fitness = fitness_sorted
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#
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# # Update the position best flame obtained so far
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Best_flame_score = fitness_sorted[0]
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Best_flame_pos = sorted_population[0, :]
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#
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previous_population = Moth_pos
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previous_fitness = Moth_fitness
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#
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# a linearly dicreases from -1 to -2 to calculate t in Eq. (3.12)
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a = -1 + Iteration * ((-1) / Max_iteration)
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# Loop counter
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for i in range(0, N):
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#
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for j in range(0, dim):
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if (
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i <= Flame_no
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): # Update the position of the moth with respect to its corresponsing flame
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#
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# D in Eq. (3.13)
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distance_to_flame = abs(sorted_population[i, j] - Moth_pos[i, j])
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b = 1
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t = (a - 1) * random.random() + 1
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#
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# % Eq. (3.12)
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Moth_pos[i, j] = (
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distance_to_flame * math.exp(b * t) * math.cos(t * 2 * math.pi)
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+ sorted_population[i, j]
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)
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# end
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#
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if (
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i > Flame_no
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): # Upaate the position of the moth with respct to one flame
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#
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# % Eq. (3.13)
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distance_to_flame = abs(sorted_population[i, j] - Moth_pos[i, j])
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b = 1
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t = (a - 1) * random.random() + 1
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#
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# % Eq. (3.12)
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Moth_pos[i, j] = (
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distance_to_flame * math.exp(b * t) * math.cos(t * 2 * math.pi)
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+ sorted_population[Flame_no, j]
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)
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Convergence_curve[Iteration] = Best_flame_score
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# Display best fitness along the iteration
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if Iteration % 1 == 0:
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print(
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[
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"At iteration "
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+ str(Iteration)
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+ " the best fitness is "
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+ str(Best_flame_score)
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]
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)
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Iteration = Iteration + 1
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timerEnd = time.time()
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s.endTime = time.strftime("%Y-%m-%d-%H-%M-%S")
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s.executionTime = timerEnd - timerStart
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s.convergence = Convergence_curve
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s.optimizer = "MFO"
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s.bestIndividual = Best_flame_pos
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s.objfname = objf.__name__
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return s
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