stats for simulated annealing
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Louis
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import matplotlib.pyplot as plt
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from libs.clustering import split_tour_across_clusters
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from libs.simulated_annealing import SimulatedAnnealing, total_distance
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import numpy as np
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cities = [[6734, 1453], [2233, 10], [5530, 1424], [401, 841], [3082, 1644], [7608, 4458], [7573, 3716], [7265, 1268], [6898, 1885], [1112, 2049], [5468, 2606], [5989, 2873], [4706, 2674], [4612, 2035], [6347, 2683], [6107, 669], [7611, 5184], [7462, 3590], [7732, 4723], [5900, 3561], [4483, 3369], [6101, 1110], [5199, 2182], [1633, 2809], [4307, 2322], [675, 1006], [7555, 4819], [7541, 3981], [3177, 756], [7352, 4506], [7545, 2801], [3245, 3305], [6426, 3173], [4608, 1198], [23, 2216], [7248, 3779], [7762, 4595], [7392, 2244], [3484, 2829], [6271, 2135], [4985, 140], [1916, 1569], [7280, 4899], [7509, 3239], [10, 2676], [6807, 2993], [5185, 3258], [3023, 1942]]
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optimal = 33523
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colors = [
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'#1f77b4', # Bleu moyen
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'#ff7f0e', # Orange
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'#2ca02c', # Vert
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'#d62728', # Rouge
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'#9467bd', # Violet
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'#8c564b', # Marron
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'#e377c2', # Rose
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'#7f7f7f', # Gris
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'#bcbd22', # Vert olive
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'#17becf', # Turquoise
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'#1b9e77', # Vert Teal
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'#d95f02', # Orange foncé
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'#7570b3', # Violet moyen
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'#e7298a', # Fuchsia
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'#66a61e', # Vert pomme
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'#e6ab02', # Jaune or
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'#a6761d', # Bronze
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'#666666', # Gris foncé
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'#f781bf', # Rose clair
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'#999999', # Gris moyen
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]
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nb_ville = 100
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max_coords = 1000
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nb_truck = 1
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temperatures = [1000, 10000, 100000,]
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cooling_rate = 0.999
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temperature_ok = 0.001
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iterations = 1
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clusters = split_tour_across_clusters(cities, nb_truck)
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for cluster in clusters.values():
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print(len(cluster))
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# create new figure for annealing paths
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colors = [
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'#1f77b4', # Bleu moyen
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'#ff7f0e', # Orange
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'#2ca02c', # Vert
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'#d62728', # Rouge
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'#9467bd', # Violet
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'#8c564b', # Marron
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'#e377c2', # Rose
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'#7f7f7f', # Gris
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'#bcbd22', # Vert olive
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'#17becf', # Turquoise
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'#1b9e77', # Vert Teal
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'#d95f02', # Orange foncé
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'#7570b3', # Violet moyen
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'#e7298a', # Fuchsia
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'#66a61e', # Vert pomme
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'#e6ab02', # Jaune or
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'#a6761d', # Bronze
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'#666666', # Gris foncé
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'#f781bf', # Rose clair
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'#999999', # Gris moyen
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]
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best_routes = []
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average_distances = []
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# Pour chaque température
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for temperature in temperatures:
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# Créez une liste pour stocker les distances pour chaque itération
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distances = []
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# Effectuez un certain nombre d'itérations
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for _ in range(iterations):
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best_routes = []
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for i, cluster_indices in enumerate(clusters.values()):
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# Récupération des coordonnées de la ville
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cluster_cities = [cities[index] for index in cluster_indices]
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# Appel de la fonction simulated_annealing
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simulated_annealing = SimulatedAnnealing(cluster_cities, temperature=temperature, cooling_rate=cooling_rate, temperature_ok=temperature_ok)
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best_route = simulated_annealing.run()
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best_routes.append((best_route, colors[i % len(colors)]))
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# Calculez la distance totale pour toutes les routes obtenues lors de cette itération
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total_distance_for_iteration = sum([total_distance(route) for route, color in best_routes])
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# Ajoutez cette distance à la liste des distances
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distances.append(total_distance_for_iteration)
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# Calculez la moyenne des distances et ajoutez-la à la liste des moyennes des distances
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average_distances.append(np.mean(distances))
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# Créez un nouvel histogramme pour afficher les moyennes des distances
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plt.figure()
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# Affichez un bar pour chaque température, avec la couleur correspondante et la moyenne des distances comme hauteur
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for i in range(len(temperatures)):
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plt.bar(str(temperatures[i]), average_distances[i], color=colors[i % len(colors)])
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# Ajoutez des étiquettes à chaque barre avec la moyenne des distances
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for i in range(len(temperatures)):
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plt.text(i, average_distances[i], round(average_distances[i], 2), ha = 'center')
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# Définir les étiquettes des axes
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plt.xlabel('Température initiale')
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plt.ylabel('Moyenne des distances sur {} itérations'.format(iterations))
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# Afficher l'histogramme
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plt.show()
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