def test2(monitor, diffenv=None):
if diffenv == True:
#from mystic.solvers import DifferentialEvolutionSolver as DE
from mystic.solvers import DifferentialEvolutionSolver2 as DE
elif diffenv == False:
from mystic.solvers import NelderMeadSimplexSolver as noDE
else:
from mystic.solvers import PowellDirectionalSolver as noDE
from mystic.termination import ChangeOverGeneration as COG
from mystic.tools import getch, random_seed
random_seed(123)
lb = [-100, -100, -100]
ub = [1000, 1000, 1000]
ndim = len(lb)
npop = 5
maxiter = 10
maxfun = 1e+6
convergence_tol = 1e-10
ngen = 100
crossover = 0.9
percent_change = 0.9
def cost(x):
ax, bx, c = x
return (ax)**2 - bx + c
if diffenv == True:
solver = DE(ndim, npop)
else:
solver = noDE(ndim)
solver.SetRandomInitialPoints(min=lb, max=ub)
solver.SetStrictRanges(min=lb, max=ub)
solver.SetEvaluationLimits(maxiter, maxfun)
solver.SetEvaluationMonitor(monitor)
#solver.SetGenerationMonitor(monitor)
tol = convergence_tol
solver.Solve(cost, termination=COG(tol, ngen))
solved = solver.Solution()
monitor.info("solved: %s" % solved)
func_max = -solver.bestEnergy
return solved, func_max
def test2(monitor, diffenv=None):
if diffenv == True:
#from mystic.solvers import DifferentialEvolutionSolver as DE
from mystic.solvers import DifferentialEvolutionSolver2 as DE
elif diffenv == False:
from mystic.solvers import NelderMeadSimplexSolver as noDE
else:
from mystic.solvers import PowellDirectionalSolver as noDE
from mystic.termination import ChangeOverGeneration as COG
from mystic.tools import getch, random_seed
random_seed(123)
lb = [-100,-100,-100]
ub = [1000,1000,1000]
ndim = len(lb)
npop = 5
maxiter = 10
maxfun = 1e+6
convergence_tol = 1e-10; ngen = 100
crossover = 0.9
percent_change = 0.9
def cost(x):
ax,bx,c = x
return (ax)**2 - bx + c
if diffenv == True:
solver = DE(ndim,npop)
else:
solver = noDE(ndim)
solver.SetRandomInitialPoints(min=lb,max=ub)
solver.SetStrictRanges(min=lb,max=ub)
solver.SetEvaluationLimits(maxiter,maxfun)
solver.SetEvaluationMonitor(monitor)
#solver.SetGenerationMonitor(monitor)
tol = convergence_tol
solver.Solve(cost, termination=COG(tol,ngen))
solved = solver.Solution()
monitor.info("solved: %s" % solved)
func_max = -solver.bestEnergy
return solved, func_max
