def test_cross(self):
''' Make sure individuals can be crossed correctly.
'''
father = BinaryIndividual(ranges=[(0, 1)]).init(solution=[0.398])
mother = BinaryIndividual(ranges=[(0, 1)]).init(solution=[0.298])
crossover = UniformCrossover(pc=1.0, pe=0.5)
child1, child2 = crossover.cross(father, mother)
def test_clone(self):
''' Make sure individual can be cloned correctly.
'''
indv = BinaryIndividual(ranges=[(0, 1)],
eps=0.001).init(solution=[0.398])
indv_clone = indv.clone()
self.assertListEqual(indv.chromsome, indv_clone.chromsome)
self.assertAlmostEqual(indv.solution[0],
indv_clone.solution[0],
places=2)
self.assertEqual(indv.ranges, indv_clone.ranges)
self.assertEqual(indv.eps, indv_clone.eps)
def tain_svm():
indv_template = BinaryIndividual(ranges=[(-8, 8), (-8, 8), (-8, 8)],
eps=[0.001, 0.001, 0.001])
population = Population(indv_template=indv_template, size=1000)
population.init() # Initialize population with individuals.
# In[ ]:
selection = RouletteWheelSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
# mutation = FlipBitMutation(pm=0.1)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
analysis=[ConsoleOutput, FitnessStore])
#############################################################
indv = engine.population.best_indv(engine.fitness).variants
c, e, g = indv.variants[1], indv.variants[2], indv.variants[-1]
clf = svm.svR(C=c, epsilon=e, gamma=g, kernel='rbf')
data_x, data_y = preprocess_pca()
clf.fit(data_x, data_y)
predictval = clf.predict(data_x)
reaval = data_y
print(predictval)
# In[ ]:
engine.run(ng=100)
def ga(df, start, end, _positionList, ranges=[(20,100),(0.01, 1),(0.01, 1),(0.01, 1),(1, 5)], eps=0.01):
indv_template = BinaryIndividual(ranges=ranges, eps=eps)
population = Population(indv_template=indv_template, size=100)
population.init() # Initialize population with individuals.
# Use built-in operators here.
selection = RouletteWheelSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitMutation(pm=0.3)
engine = GAEngine(population=population, selection=selection,
crossover=crossover, mutation=mutation,
analysis=[FitnessStore])
@engine.fitness_register
def fitness(indv):
n, upper, lower, adds, cutoff = indv.solution
df['KAMA'] = talib.KAMA(df.close, int(n))
df['VAR'] = talib.VAR(df.close-df.KAMA.shift(1) - df.close.shift(1)+df.KAMA.shift(2),10)
profitsList, buypriceList, sellpriceList, fits,positionList = profitsCal(df, start, end, _positionList, upper=upper, lower=lower, adds = adds, cutoff=cutoff)
return float(fits)
@engine.analysis_register
class ConsoleOutput(OnTheFlyAnalysis):
master_only = True
interval = 1
def register_step(self, g, population, engine):
best_indv = population.best_indv(engine.fitness)
msg = 'Generation: {}, best fitness: {:.3f}'.format(g, engine.fmax)
print(best_indv.solution)
engine.logger.info(msg)
engine.run(ng=30)
return population.best_indv(engine.fitness).solution, _positionList
def setUp(self):
self.maxDiff = True
self.indv_template = BinaryIndividual(ranges=[(0, 1)])
def fitness(indv):
x, = indv.solution
return x**3 - 60*x**2 + 900*x + 100
self.fitness = fitness
def test_run(self):
'''
Make sure GA engine can run correctly.
'''
indv_template = BinaryIndividual(ranges=[(0, 10)], eps=0.001)
population = Population(indv_template=indv_template, size=50).init()
# Create genetic operators.
selection = RouletteWheelSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitMutation(pm=0.1)
# Create genetic algorithm engine.
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation)
@engine.fitness_register
@engine.dynamic_linear_scaling()
def fitness(indv):
x, = indv.solution
return x + 10 * sin(5 * x) + 7 * cos(4 * x)
engine.run(50)
def test_selection(self):
indv = BinaryIndividual(ranges=[(0, 30)])
p = Population(indv)
p.init()
selection = TournamentSelection()
father, mother = selection.select(p, fitness=self.fitness)
self.assertTrue(isinstance(father, BinaryIndividual))
self.assertTrue(isinstance(mother, BinaryIndividual))
def test_mutate_binary_indv(self):
''' Make sure the individual can be mutated correctly.
'''
indv = BinaryIndividual(ranges=[(0, 1)]).init(solution=[0.398])
mutation = FlipBitMutation(pm=1.0)
chromsome_before = [0, 1, 1, 0, 0, 1, 0, 1, 1]
chromsome_after = [1, 0, 0, 1, 1, 0, 1, 0, 0]
self.assertListEqual(indv.chromsome, chromsome_before)
mutation.mutate(indv, engine=None)
self.assertListEqual(indv.chromsome, chromsome_after)
def doga(units, ploads, hload, size=50, ng=5, pc=0.8, pe=0.5, pm=0.1):
# 计算不同典型日下,最小运行成本均值
def calcost(indv):
# 输入改造方案
for chpunit, rtype in zip(chpunits, indv):
chpunit.rtype = rtype
meancost = 0
# ploads为字典,key:典型日出现的概率,value:[典型日负荷曲线,风电出力极限曲线1,...,风电出力极限曲线n]
for p in ploads.keys():
x = ProSimu()
x.pload = ploads[p][0]
x.hload = hload
wn = 0
for wpunit in wpunits:
wn += 1
wpunit.maxwp = ploads[p][wn]
x.units = units
meancost += x.getoptvalue()*p
return meancost
ranges = list()
wpunits = list()
chpunits = list()
for unit in units:
if unit.ptype == 0: # Wind Power Unit
wpunits += [unit]
elif unit.ptype == 2: # CHP Unit-1
ranges += [(0, 4)]
chpunits += [unit]
elif unit.ptype == 3: # CHP Unit-2
ranges += [(0, 3)]
chpunits += [unit]
template = BinaryIndividual(ranges, eps=1)
population = Population(indv_template=template, size=size).init()
selection = TournamentSelection()
crossover = UniformCrossover(pc=pc, pe=pe)
mutation = FlipBitMutation(pm=pm)
engine = GAEngine(population=population, selection=selection, crossover=crossover, mutation=mutation,
analysis=[ConsoleOutput, FitnessStore])
@engine.fitness_register
@engine.minimize
def fitness(indv):
# print(type(float(calcost(indv.solution))))
return float(calcost(indv.solution))
engine.run(ng=ng)
bestindv = population.best_indv(engine.fitness).solution
for unitt, rtype in zip(chpunits, bestindv):
unitt.rtype = rtype
result = calcost(bestindv)
print('Best individual:', bestindv)
print('Optimal result:', result)
def test_selection(self):
indv = BinaryIndividual(ranges=[(0, 30)])
p = Population(indv)
p.init()
selection = RouletteWheelSelection()
father, mother = selection.select(p, fitness=self.fitness)
self.assertTrue(isinstance(father, BinaryIndividual))
self.assertTrue(isinstance(mother, BinaryIndividual))
self.assertNotEqual(father.chromsome, mother.chromsome)
def __init__(self, objfunc, var_bounds, individual_size, max_iter,
max_or_min, **kwargs):
super().__init__(objfunc)
self.max_iter = max_iter
# 定义个体 / 种群
self.individual = BinaryIndividual(ranges=var_bounds, eps=0.001)
self.population = Population(indv_template=self.individual,
size=individual_size).init()
# Create genetic operators.
# selection = RouletteWheelSelection()
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
self.engine = GAEngine(population=self.population,
selection=selection,
crossover=crossover,
mutation=mutation,
analysis=[FitnessStore])
@self.engine.fitness_register
def fitness(indv):
"""
适应度函数: 注意这里默认为优化得到最小值
:param indv:
:return:
"""
x = indv.solution
if max_or_min == 'max':
return objfunc(x, **kwargs)
else:
return -objfunc(x, **kwargs)
@self.engine.analysis_register
class ConsoleOutputAnalysis(OnTheFlyAnalysis):
interval = 1
master_only = True
def register_step(self, g, population, engine):
best_indv = population.best_indv(engine.fitness)
msg = 'Generation: {}, best fitness: {:.3f}'.format(
g, engine.fitness(best_indv))
# self.logger.info(msg)
def finalize(self, population, engine):
best_indv = population.best_indv(engine.fitness)
x = best_indv.solution
y = engine.fitness(best_indv)
msg = 'Optimal solution: ({}, {})'.format(x, y)
def test_binary_encoding(self):
''' Make sure individual can decode and encode binary gene correctly.
'''
indv = BinaryIndividual(ranges=[(0, 1)], eps=0.001)
indv.init(solution=[0.398])
# Test binary chromsome.
ref_chromsome = [0, 1, 1, 0, 0, 1, 0, 1, 1]
self.assertListEqual(indv.chromsome, ref_chromsome)
# Test decode.
self.assertListEqual(indv.decode(), [0.396484375])
indv = BinaryIndividual(ranges=[(0, 1), (-1, 1)], eps=0.001)
indv.init(solution=[0.398, 0.66])
# Test binary chromsome.
ref_chromsome = [
0, 1, 1, 0, 0, 1, 0, 1, 1, 1, 1, 0, 1, 0, 1, 0, 0, 0, 1
]
self.assertListEqual(indv.chromsome, ref_chromsome)
# Test decode.
self.assertListEqual(indv.decode(), [0.396484375, 0.658203125])
def __init__(self ,k ,total_implied_variance ,slice_before ,slice_after ,tau):
self.k =k
self.total_implied_variance =total_implied_variance
self.slice_before =slice_before
self.slice_after = slice_after
self.tau = tau
# Define population.
indv_template = BinaryIndividual(ranges=[(1e-5, 20),(1e-5, 20),(1e-5, 20)], eps=0.001)
self.population = Population(indv_template=indv_template, size=30).init()
# Create genetic operators.
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitMutation(pm=0.1)
# Create genetic algorithm engine.
self.engine = GAEngine(population=self.population, selection=selection,
crossover=crossover, mutation=mutation,
analysis=[FitnessStore])
# Define fitness function.
@self.engine.fitness_register
@self.engine.minimize
def fitness(indv):
a, b, m, rho, sigma = indv.solution
model_total_implied_variance=svi_raw(self.k,np.array([a, b, m, rho, sigma]),self.tau)
value = norm(self.total_implied_variance - model_total_implied_variance,ord=2)
# if bool(len(self.slice_before)) and np.array(model_total_implied_variance < self.slice_before).any():
# value +=(np.count_nonzero(~np.array(model_total_implied_variance < self.slice_before))*100)
# # value = 1e6
#
# if bool(len(self.slice_after)) and np.array(model_total_implied_variance > self.slice_after).any():
# value += float(np.count_nonzero(~np.array(model_total_implied_variance > self.slice_after)) * 100)
# # value = 1e6
# if np.isnan(value):
# value = 1e6
value = float(value)
return value
def test_init(self):
''' Make sure the individual can be initialized correctly.
'''
indv = BinaryIndividual(ranges=[(0, 1)], eps=0.001)
# Check chromsome initialization.
indv.init(chromsome=[0, 1, 1, 0, 0, 0, 1, 1, 1, 0])
self.assertListEqual([0, 1, 1, 0, 0, 0, 1, 1, 1, 0], indv.chromsome)
self.assertListEqual(indv.solution, [0.388671875])
# Check solution initialization.
indv.init(solution=[0.398])
self.assertListEqual(indv.solution, [0.398])
self.assertListEqual(indv.chromsome, [0, 1, 1, 0, 0, 1, 0, 1, 1])
def test_mutate(self):
''' Make sure the individual can be mutated correctly.
'''
indv_template = BinaryIndividual(ranges=[(0, 10)], eps=0.001)
population = Population(indv_template=indv_template, size=50).init()
# Create genetic operators.
selection = RouletteWheelSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.03, pbm=0.2, alpha=0.6)
# Create genetic algorithm engine.
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation)
@engine.fitness_register
def fitness(indv):
x, = indv.solution
return x + 10 * sin(5 * x) + 7 * cos(4 * x)
mutation.mutate(indv_template, engine)
(math.pow(x, 2) + math.pow(y, 2)))))
b = -math.exp(0.5 *
(math.cos(2 * math.pi * x) + math.cos(2 * math.pi * y)))
c = math.exp(1)
d = 20
result = a + b + c + d
global best
if best < abs(result):
best = abs(result)
print('The best outcome reward till now is {}'.format(best))
count += 1
return result
search_domain = (-5, 5)
indv_template = BinaryIndividual(ranges=[search_domain, search_domain],
eps=0.001)
# Define population
population = Population(indv_template=indv_template, size=50).init()
# Create genetic operators.
#selection = RouletteWheelSelection()
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
# Create genetic algorithm engine.
# Here we pass all built-in analysis to engine constructor.
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
import os
import sys
from gaft import GAEngine
from gaft.components import BinaryIndividual, Population
from gaft.operators import RouletteWheelSelection, UniformCrossover, FlipBitMutation
from gaft.plugin_interfaces.analysis import OnTheFlyAnalysis
from gaft.analysis import FitnessStore
from multiprocessing import Value
sys.path.insert(0, os.path.join(os.path.dirname(os.path.abspath(__file__)), '..'))
from track_eval.test_net import *
tracker_num = Value('i', 0)
if __name__ == '__main__':
arg_set.logger_handler.removeHandler(arg_set.logfile_handler)
indv_template = BinaryIndividual(ranges=[(1.0000001, 1.25), (0.9, 1.0), (0.15, 0.7), (0.05, 0.7)], eps=0.0001)
population = Population(indv_template=indv_template, size=50)
population.init()
selection = RouletteWheelSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitMutation(pm=0.1)
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
analysis=[FitnessStore])
# @engine.analysis_register
# class ConsoleOutput(OnTheFlyAnalysis):
# master_only = True
from gaft.operators import TournamentSelection
from gaft.operators import UniformCrossover
from gaft.operators import FlipBitBigMutation
# Built-in best fitness analysis.
from gaft.analysis.fitness_store import FitnessStore
from gaft.analysis.console_output import ConsoleOutput
# Analysis plugin base class.
from gaft.plugin_interfaces.analysis import OnTheFlyAnalysis
data = scipy.io.loadmat('./burgers_shock.mat')
max_train_iter = 2
# Define population.
indv_template = BinaryIndividual(ranges=[(2, 50), (2, 20)], eps=0.001)
population = Population(indv_template=indv_template, size=18).init()
# Create genetic operators.
#selection = RouletteWheelSelection()
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
# Create genetic algorithm engine.
# Here we pass all built-in analysis to engine constructor.
engine = GAEngine(population=population, selection=selection,
crossover=crossover, mutation=mutation,
analysis=[FitnessStore])
from gaft import GAEngine
from gaft.components import BinaryIndividual
from gaft.components import Population
from gaft.operators import TournamentSelection
from gaft.operators import UniformCrossover
from gaft.operators import FlipBitBigMutation
# Built-in best fitness analysis.
from gaft.analysis.fitness_store import FitnessStore
from gaft.analysis.console_output import ConsoleOutput
# Analysis plugin base class.
from gaft.plugin_interfaces.analysis import OnTheFlyAnalysis
# Define population.
indv_template = BinaryIndividual(ranges=[(1, 200), (2, 3)], eps=0.001)
population = Population(indv_template=indv_template, size=18).init()
# Create genetic operators.
# selection = RouletteWheelSelection()
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
# Create genetic algorithm engine.
# Here we pass all built-in analysis to engine constructor.
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
from gaft import GAEngine
from gaft.components import BinaryIndividual
from gaft.components import Population
from gaft.operators import TournamentSelection
from gaft.operators import UniformCrossover
from gaft.operators import FlipBitMutation
from gaft.plugin_interfaces.analysis import OnTheFlyAnalysis
matplotlib.use('tkagg')
# lab: 7 variant
start, end, eps = 0, 10, 0.001
indv_template = BinaryIndividual(ranges=[(start, end)], eps=eps)
population = Population(indv_template=indv_template, size=10).init()
selection = TournamentSelection()
crossover = UniformCrossover(pc=1.0, pe=0.5)
mutation = FlipBitMutation(pm=0.1)
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
analysis=[])
def npfunc():
t = np.arange(start, end, eps)
n_nines = []
for s in scores:
precisao = str(s).split('.')[1]
noves = re.search(r'(^9*)', precisao)
n_nines.append(len(noves[0]))
fig = plt.figure()
ax = fig.add_subplot(111)
ax.plot(geracoes, n_nines)
plt.show()
if __name__ == "__main__":
individuo = BinaryIndividual(ranges=[(-100, 100), (-100, 100)],
eps=0.000001)
populacao = Population(indv_template=individuo, size=100)
populacao.init()
selecao = TournamentSelection()
crossover = UniformCrossover(pc=0.65, pe=0.65)
mutacao = FlipBitMutation(pm=0.008)
engine = GAEngine(population=populacao,
selection=selecao,
crossover=crossover,
mutation=mutacao,
analysis=[FitnessStore, ConsoleOutput])
@engine.fitness_register
def aptidao(ind):
def test_multi_precisions(self):
''' Make sure we can construct individual using different decrete precisions.
'''
indv = BinaryIndividual(ranges=[(0, 1), (0, 10)],
eps=[0.01, 1.0]).init(solution=[0.3, 0.5])
self.assertNotEqual(indv.precisions[0], indv.precisions[1])
def func2(t, a=1.3, b=1.9, c=1.1, d=-1.5):
return (a * t + b) * math.cos(c * math.pi * t + d)
'''
@engine.fitness_register
@engine.minimize
def fitness(indv):
x, = indv.solution
return x + 10*sin(5*x) + 7*cos(4*x)
'''
if __name__ == '__main__':
# Create individual (use binary encoding)
indv = BinaryIndividual(ranges=[(0, 10)], eps=0.001)
# Create a population with 50 individuals
population = Population(indv_template=indv, size=50).init()
# Create genetic operators: selection, crossover, mutation
# 1. Tournament selection
selection = TournamentSelection()
# 2. Uniform crossover
# pc is the probabililty of crossover operation
# pe is the exchange probabiltiy for each possible gene bit in chromsome
crossover = UniformCrossover(pc=0.8, pe=0.5)
# 3. Flip bit mutation
# pm is the probability of mutation
mutation = FlipBitMutation(pm=0.1)
# Create an engine to run
engine1 = GAEngine(population=population,
selection=selection,
PBM = PM * 5
# alpha: intensive factor (0.5, 1)
ALPHA = 0.6
# Run
# ng: Evolution iteration steps (generations number)
NG = 150
# Built-in best fitness analysis.
from gaft.analysis.fitness_store import FitnessStore
from gaft.analysis.console_output import ConsoleOutput
# Define population.
indv_template = BinaryIndividual(ranges=[XB, YB], eps=EPS)
population = Population(indv_template=indv_template,
size=POPULATION_SIZE).init()
# Create genetic operators.
selection = SELECTION
crossover = UniformCrossover(pc=PC, pe=PE)
mutation = FlipBitBigMutation(pm=PM, pbm=PBM, alpha=ALPHA)
# Create genetic algorithm engine.
# Here we pass all built-in analysis to engine constructor.
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
analysis=[ConsoleOutput, FitnessStore])
from gaft.components import Population
from gaft.operators import *
from gaft.analysis.fitness_store import FitnessStore
from gaft.analysis.console_output import ConsoleOutput
from gaft.plugin_interfaces.analysis import OnTheFlyAnalysis
import os
from math import sin, cos, pi, exp
import numpy as np
# Define Generation
generation = 50
# Define Population and the Constraints
population_size = 10
indv_template = BinaryIndividual(ranges=[(-3, 12.1), (4.1, 5.8)], eps=0.001)
population = Population(indv_template=indv_template,
size=population_size).init()
# Define Genetic Operators
## Selection : RouletteWheelSelection, TournamentSelection, LinearRankingSelection, ExpotentialRankingSelection
#selection = RouletteWheelSelection()
selection = TournamentSelection()
## Crossover
### pc : probability of crossover(usually between 0.25 - 1.0)
### pe : gene exchange probability
crossover = UniformCrossover(pc=0.8, pe=0.5)
## Mutate
### pm : The probability of mutation (usually between 0.001 ~ 0.1)
from gaft import GAEngine
from gaft.components import BinaryIndividual
from gaft.components import DecimalIndividual
from gaft.components import Population
from gaft.operators import RouletteWheelSelection
from gaft.operators import TournamentSelection
from gaft.operators import UniformCrossover
from gaft.operators import FlipBitBigMutation
from gaft.operators import FlipBitMutation
# Built-in best fitness analysis.
from gaft.analysis.fitness_store import FitnessStore
from gaft.analysis.console_output import ConsoleOutput
import time
# Define population.
indv_template = BinaryIndividual(ranges=[(1,1000),(0,1)], eps=0.01)
#indv_template = DecimalIndividual(ranges=[(1, 1000),(0.0,0.5)], eps=0.001)
population = Population(indv_template=indv_template, size=80).init()
# Create genetic operators.
selection = RouletteWheelSelection()
#selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
#mutation = FlipBitMutation(pm=0.1)
# Create genetic algorithm engine.
# Here we pass all built-in analysis to engine constructor.
engine = GAEngine(population=population, selection=selection,
crossover=crossover, mutation=mutation,
analysis=[ConsoleOutput, FitnessStore])
from math import sin, cos, pi
from gaft import GAEngine
from gaft.components import BinaryIndividual
from gaft.components import Population
from gaft.operators import TournamentSelection
from gaft.operators import UniformCrossover
from gaft.operators import FlipBitBigMutation
# Built-in best fitness analysis.
from gaft.analysis.fitness_store import FitnessStore
from gaft.analysis.console_output import ConsoleOutput
# Define population.
indv_template = BinaryIndividual(ranges=[(-2, 2), (-2, 2)], eps=0.001)
population = Population(indv_template=indv_template, size=50).init()
# Create genetic operators.
#selection = RouletteWheelSelection()
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
# Create genetic algorithm engine.
# Here we pass all built-in analysis to engine constructor.
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
analysis=[ConsoleOutput, FitnessStore])
from gaft import GAEngine
from gaft.components import BinaryIndividual
from gaft.components import Population
from gaft.operators import TournamentSelection
from gaft.operators import UniformCrossover
from gaft.operators import FlipBitBigMutation
from gaft.plugin_interfaces.analysis import OnTheFlyAnalysis
matplotlib.use('tkagg')
x1_range = (-2, 2)
x2_range = (-2, 2)
eps = 0.001
indv_template = BinaryIndividual(ranges=[x1_range, x2_range], eps=eps)
population = Population(indv_template=indv_template, size=10).init()
selection = TournamentSelection()
crossover = UniformCrossover(pc=1, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
engine = GAEngine(population=population,
selection=selection,
crossover=crossover,
mutation=mutation,
analysis=[])
ax = plt.axes(projection='3d')
from gaft import GAEngine
from gaft.components import BinaryIndividual
from gaft.components import Population
from gaft.operators import TournamentSelection
from gaft.operators import UniformCrossover
from gaft.operators import FlipBitMutation
# Analysis plugin base class.
from gaft.plugin_interfaces.analysis import OnTheFlyAnalysis
# Built-in best fitness analysis.
from gaft.analysis.fitness_store import FitnessStore
# Define population.
# 先对你所指定的初始种群进行编码
indv_template = BinaryIndividual(ranges=[(0, 10)], eps=0.001)
'''
:param ranges: value ranges for all entries in solution.
:type ranges: list of range tuples. e.g. [(0, 1), (-1, 1)]
:param eps: decrete precisions for binary encoding, default is 0.001.
:type eps: float or float list with the same length with ranges.
'''
population = Population(indv_template=indv_template, size=30).init()
# Create genetic operators.
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
'''
Crossover operator with uniform crossover algorithm,
see https://en.wikipedia.org/wiki/Crossover_(genetic_algorithm)
pv = find(bus[:, 9] == 2)
myfun_lower_bound = 0
myfun_upper_bound = 1
bounds = np.zeros([len(pv), 2])
bounds[:, 0] = myfun_lower_bound
bounds[:, 1] = myfun_upper_bound
bounds = bounds.tolist()
generations = 15
population_size = 20
# ---------------------------------------------------------------------------------------------------
# Define population.
indv_template = BinaryIndividual(ranges=bounds, eps=0.001)
population = Population(indv_template=indv_template, size=population_size).init()
# Create genetic operators.
#selection = RouletteWheelSelection()
selection = TournamentSelection()
crossover = UniformCrossover(pc=0.8, pe=0.5)
mutation = FlipBitBigMutation(pm=0.1, pbm=0.55, alpha=0.6)
# Create genetic algorithm engine.
# Here we pass all built-in analysis to engine constructor.
engine = GAEngine(population=population, selection=selection,
crossover=crossover, mutation=mutation)
# ===================================================================================================
