sklearn/examples/cluster/plot_affinity_propagation.py

"""
=================================================
Demo of affinity propagation clustering algorithm
=================================================

Reference:
Brendan J. Frey and Delbert Dueck, "Clustering by Passing Messages
Between Data Points", Science Feb. 2007

"""

import numpy as np

from sklearn import metrics
from sklearn.cluster import AffinityPropagation
from sklearn.datasets import make_blobs

# %%
# Generate sample data
# --------------------
centers = [[1, 1], [-1, -1], [1, -1]]
X, labels_true = make_blobs(
    n_samples=300, centers=centers, cluster_std=0.5, random_state=0
)

# %%
# Compute Affinity Propagation
# ----------------------------
af = AffinityPropagation(preference=-50, random_state=0).fit(X)
cluster_centers_indices = af.cluster_centers_indices_
labels = af.labels_

n_clusters_ = len(cluster_centers_indices)

print("Estimated number of clusters: %d" % n_clusters_)
print("Homogeneity: %0.3f" % metrics.homogeneity_score(labels_true, labels))
print("Completeness: %0.3f" % metrics.completeness_score(labels_true, labels))
print("V-measure: %0.3f" % metrics.v_measure_score(labels_true, labels))
print("Adjusted Rand Index: %0.3f" % metrics.adjusted_rand_score(labels_true, labels))
print(
    "Adjusted Mutual Information: %0.3f"
    % metrics.adjusted_mutual_info_score(labels_true, labels)
)
print(
    "Silhouette Coefficient: %0.3f"
    % metrics.silhouette_score(X, labels, metric="sqeuclidean")
)

# %%
# Plot result
# -----------
import matplotlib.pyplot as plt

plt.close("all")
plt.figure(1)
plt.clf()

colors = plt.cycler("color", plt.cm.viridis(np.linspace(0, 1, 4)))

for k, col in zip(range(n_clusters_), colors):
    class_members = labels == k
    cluster_center = X[cluster_centers_indices[k]]
    plt.scatter(
        X[class_members, 0], X[class_members, 1], color=col["color"], marker="."
    )
    plt.scatter(
        cluster_center[0], cluster_center[1], s=14, color=col["color"], marker="o"
    )
    for x in X[class_members]:
        plt.plot(
            [cluster_center[0], x[0]], [cluster_center[1], x[1]], color=col["color"]
        )

plt.title("Estimated number of clusters: %d" % n_clusters_)
plt.show()
first commit 2024-08-05 09:32:03 +02:00			`"""`
			`=================================================`
			`Demo of affinity propagation clustering algorithm`
			`=================================================`

			`Reference:`
			`Brendan J. Frey and Delbert Dueck, "Clustering by Passing Messages`
			`Between Data Points", Science Feb. 2007`

			`"""`

			`import numpy as np`

			`from sklearn import metrics`
			`from sklearn.cluster import AffinityPropagation`
			`from sklearn.datasets import make_blobs`

			`# %%`
			`# Generate sample data`
			`# --------------------`
			`centers = [[1, 1], [-1, -1], [1, -1]]`
			`X, labels_true = make_blobs(`
			`n_samples=300, centers=centers, cluster_std=0.5, random_state=0`
			`)`

			`# %%`
			`# Compute Affinity Propagation`
			`# ----------------------------`
			`af = AffinityPropagation(preference=-50, random_state=0).fit(X)`
			`cluster_centers_indices = af.cluster_centers_indices_`
			`labels = af.labels_`

			`n_clusters_ = len(cluster_centers_indices)`

			`print("Estimated number of clusters: %d" % n_clusters_)`
			`print("Homogeneity: %0.3f" % metrics.homogeneity_score(labels_true, labels))`
			`print("Completeness: %0.3f" % metrics.completeness_score(labels_true, labels))`
			`print("V-measure: %0.3f" % metrics.v_measure_score(labels_true, labels))`
			`print("Adjusted Rand Index: %0.3f" % metrics.adjusted_rand_score(labels_true, labels))`
			`print(`
			`"Adjusted Mutual Information: %0.3f"`
			`% metrics.adjusted_mutual_info_score(labels_true, labels)`
			`)`
			`print(`
			`"Silhouette Coefficient: %0.3f"`
			`% metrics.silhouette_score(X, labels, metric="sqeuclidean")`
			`)`

			`# %%`
			`# Plot result`
			`# -----------`
			`import matplotlib.pyplot as plt`

			`plt.close("all")`
			`plt.figure(1)`
			`plt.clf()`

			`colors = plt.cycler("color", plt.cm.viridis(np.linspace(0, 1, 4)))`

			`for k, col in zip(range(n_clusters_), colors):`
			`class_members = labels == k`
			`cluster_center = X[cluster_centers_indices[k]]`
			`plt.scatter(`
			`X[class_members, 0], X[class_members, 1], color=col["color"], marker="."`
			`)`
			`plt.scatter(`
			`cluster_center[0], cluster_center[1], s=14, color=col["color"], marker="o"`
			`)`
			`for x in X[class_members]:`
			`plt.plot(`
			`[cluster_center[0], x[0]], [cluster_center[1], x[1]], color=col["color"]`
			`)`

			`plt.title("Estimated number of clusters: %d" % n_clusters_)`
			`plt.show()`