verbose=False) print(ret.F) with Video(GIF("animation.gif")) as vid: for algorithm in ret.history: if algorithm.n_gen % 5 == 0: X, F = algorithm.pop.get("X", "F") nds = NonDominatedSorting().do(F, only_non_dominated_front=True) other = [k for k in range(len(F)) if k not in nds] fig, (ax1, ax2) = plt.subplots(2, figsize=(8, 6)) fig.suptitle("%s - %s - Gen %s" % ("ZDT1", "NSGA2", algorithm.n_gen), fontsize=16) pcp = PCP(ax=ax1, bounds=(problem.xl, problem.xu)) pcp.set_axis_style(color="black", alpha=0.7) pcp.add(X[other], color="blue", linewidth=0.5) pcp.add(X[nds], color="red", linewidth=2) pcp.do() sc = Scatter(ax=ax2) sc.add(F[other], color="blue") sc.add(F[nds], color="red") sc.add(problem.pareto_front(), plot_type="line", color="black") sc.do() vid.record()
termination=('n_gen', 50), seed=1, save_history=True, verbose=False) print(ret.F) with Video(GIF("animation.gif")) as vid: for algorithm in ret.history: if algorithm.n_gen % 1 == 0: X, F = algorithm.pop.get("X", "F") nds = NonDominatedSorting().do(F, only_non_dominated_front=True) other = [k for k in range(len(F)) if k not in nds] fig, (ax1, ax2) = plt.subplots(2, figsize=(8, 6)) fig.suptitle("%s - %s - Gen %s" % ("ZDT1", "NSGA2", algorithm.n_gen), fontsize=16) pcp = PCP(ax=ax1, bounds=(problem.xl, problem.xu)) pcp.add(X[other], color="blue", linewidth=0.5) pcp.add(X[nds], color="red", linewidth=2) pcp.do() sc = Scatter(ax=ax2) sc.add(F[other], color="blue") sc.add(F[nds], color="red") sc.add(problem.pareto_front(), plot_type="line") sc.do() vid.record()
plt.xlabel("Function Evaluations") plt.ylabel("Hypervolume") # fig.savefig(LATEX_DIR + 'convergence.eps', format='eps') plt.show() from pymoo.factory import get_visualization, get_decomposition F = res.F weights = np.array([0.01, 0.99]) decomp = get_decomposition("asf") # We apply the decomposition and retrieve the best value (here minimum): I = get_decomposition("asf").do(F, weights).argmin() print("Best regarding decomposition: Point %s - %s" % (I, F[I])) plot = get_visualization("scatter") plot.add(F, color="blue", alpha=0.5, s=30) plot.add(F[I], color="red", s=40) plot.do() # plot.apply(lambda ax: ax.arrow(0, 0, F[I][0], F[I][1], color='black', # head_width=0.001, head_length=0.001, alpha=0.4)) plot.show() ## Parallel Coordinate Plots from pymoo.visualization.pcp import PCP plotPCP = PCP().add(res.F).add(res.F[I], color='r').show() print( f'A solução ideal é encontrada para a deformação {res.F[I][0]:.4f}m e massa {res.F[I][0]:.4f}kg com os parametros a {res.X[I][0]:.4f} b {res.X[I][1]:.4f} e h {res.X[I][2]:.4f}' )
from pymoo.factory import get_problem, get_reference_directions from pymoo.visualization.pcp import PCP ref_dirs = get_reference_directions("das-dennis", 6, n_partitions=5) * [2, 4, 8, 16, 32, 64] F = get_problem("dtlz1").pareto_front(ref_dirs) PCP().add(F).show() plot = PCP() plot.set_axis_style(color="grey", alpha=0.5) plot.add(F, color="grey", alpha=0.3) plot.add(F[50], linewidth=5, color="red") plot.add(F[75], linewidth=5, color="blue") plot.show() plot.reset() plot.normalize_each_axis = False plot.bounds = [[1, 1, 1, 2, 2, 5], [32, 32, 32, 32, 32, 32]] plot.show()
def notify(self, algorithm): problem = algorithm.problem pcp = PCP(title=("Gen %s" % algorithm.n_gen, { 'pad': 30 }), bounds=(problem.xl, problem.xu), labels=["$x_%s$" % k for k in range(problem.n_var)]) pcp.set_axis_style(color="grey", alpha=0.5) pcp.add(algorithm.pop.get("X"), color="black", alpha=0.8, linewidth=1.5) if algorithm.off is not None: pcp.add(algorithm.off.get("X"), color="blue", alpha=0.8, linewidth=0.5) pcp.add(algorithm.opt.get("X"), color="red", linewidth=4) pcp.do() self.video.record()
import numpy as np from pymoo.algorithms.nsga3 import NSGA3 from pymoo.factory import get_problem, get_reference_directions from pymoo.optimize import minimize from pymoo.visualization.pcp import PCP p = "dtlz5" # create the reference directions to be used for the optimization ref_dirs = get_reference_directions("das-dennis", 5, n_partitions=6) problem = get_problem(p, n_obj=5) # create the algorithm object algorithm = NSGA3(ref_dirs=ref_dirs) # execute the optimization ret = minimize( problem, algorithm, # pf=problem.pareto_front(ref_dirs), seed=1, termination=('n_gen', 1000), verbose=True) np.savetxt("%s_%s.f" % (p, len(ref_dirs)), ret.F) PCP().add(ret.F).show()
# START load_data from pymoo.factory import get_problem, get_reference_directions ref_dirs = get_reference_directions("das-dennis", 6, n_partitions=5) * [2, 4, 8, 16, 32, 64] F = get_problem("dtlz1").pareto_front(ref_dirs) # END load_data # START pcp from pymoo.visualization.pcp import PCP PCP().add(F).show() # END pcp # START pcp_highlight plot = PCP() plot.set_axis_style(color="grey", alpha=0.5) plot.add(F, color="grey", alpha=0.3) plot.add(F[50], linewidth=5, color="red") plot.add(F[75], linewidth=5, color="blue") plot.show() # END pcp_highlight # START pcp_other plot = PCP(title=("Run", { 'pad': 30 }), n_ticks=10, legend=(True, { 'loc': "upper left" }),