""" =================================================== Hierarchical clustering with and without structure =================================================== This example demonstrates hierarchical clustering with and without connectivity constraints. It shows the effect of imposing a connectivity graph to capture local structure in the data. Without connectivity constraints, the clustering is based purely on distance, while with constraints, the clustering respects local structure. For more information, see :ref:`hierarchical_clustering`. There are two advantages of imposing connectivity. First, clustering with sparse connectivity matrices is faster in general. Second, when using a connectivity matrix, single, average and complete linkage are unstable and tend to create a few clusters that grow very quickly. Indeed, average and complete linkage fight this percolation behavior by considering all the distances between two clusters when merging them (while single linkage exaggerates the behaviour by considering only the shortest distance between clusters). The connectivity graph breaks this mechanism for average and complete linkage, making them resemble the more brittle single linkage. This effect is more pronounced for very sparse graphs (try decreasing the number of neighbors in `kneighbors_graph`) and with complete linkage. In particular, having a very small number of neighbors in the graph, imposes a geometry that is close to that of single linkage, which is well known to have this percolation instability. The effect of imposing connectivity is illustrated on two different but similar datasets which show a spiral structure. In the first example we build a Swiss roll dataset and run hierarchical clustering on the position of the data. Here, we compare unstructured Ward clustering with a structured variant that enforces k-Nearest Neighbors connectivity. In the second example we include the effects of applying a such a connectivity graph to single, average and complete linkage. """ # Authors: The scikit-learn developers # SPDX-License-Identifier: BSD-3-Clause # %% # Generate the Swiss Roll dataset. # -------------------------------- import time from sklearn.cluster import AgglomerativeClustering from sklearn.datasets import make_swiss_roll n_samples = 1500 noise = 0.05 X1, _ = make_swiss_roll(n_samples, noise=noise) X1[:, 1] *= 0.5 # Make the roll thinner # %% # Compute clustering without connectivity constraints # --------------------------------------------------- print("Compute unstructured hierarchical clustering...") st = time.time() ward_unstructured = AgglomerativeClustering(n_clusters=6, linkage="ward").fit(X1) elapsed_time_unstructured = time.time() - st label_unstructured = ward_unstructured.labels_ print(f"Elapsed time: {elapsed_time_unstructured:.2f}s") print(f"Number of points: {label_unstructured.size}") # %% # Plot unstructured clustering result import matplotlib.pyplot as plt import numpy as np fig1 = plt.figure() ax1 = fig1.add_subplot(111, projection="3d", elev=7, azim=-80) ax1.set_position([0, 0, 0.95, 1]) for l in np.unique(label_unstructured): ax1.scatter( X1[label_unstructured == l, 0], X1[label_unstructured == l, 1], X1[label_unstructured == l, 2], color=plt.cm.jet(float(l) / np.max(label_unstructured + 1)), s=20, edgecolor="k", ) _ = fig1.suptitle( f"Without connectivity constraints (time {elapsed_time_unstructured:.2f}s)" ) # %% # Compute clustering with connectivity constraints # ------------------------------------------------ from sklearn.neighbors import kneighbors_graph connectivity = kneighbors_graph(X1, n_neighbors=10, include_self=False) print("Compute structured hierarchical clustering...") st = time.time() ward_structured = AgglomerativeClustering( n_clusters=6, connectivity=connectivity, linkage="ward" ).fit(X1) elapsed_time_structured = time.time() - st label_structured = ward_structured.labels_ print(f"Elapsed time: {elapsed_time_structured:.2f}s") print(f"Number of points: {label_structured.size}") # %% # Plot structured clustering result fig2 = plt.figure() ax2 = fig2.add_subplot(111, projection="3d", elev=7, azim=-80) ax2.set_position([0, 0, 0.95, 1]) for l in np.unique(label_structured): ax2.scatter( X1[label_structured == l, 0], X1[label_structured == l, 1], X1[label_structured == l, 2], color=plt.cm.jet(float(l) / np.max(label_structured + 1)), s=20, edgecolor="k", ) _ = fig2.suptitle( f"With connectivity constraints (time {elapsed_time_structured:.2f}s)" ) # %% # Generate 2D spiral dataset. # --------------------------- n_samples = 1500 np.random.seed(0) t = 1.5 * np.pi * (1 + 3 * np.random.rand(1, n_samples)) x = t * np.cos(t) y = t * np.sin(t) X2 = np.concatenate((x, y)) X2 += 0.7 * np.random.randn(2, n_samples) X2 = X2.T # %% # Capture local connectivity using a graph # ---------------------------------------- # Larger number of neighbors will give more homogeneous clusters to # the cost of computation time. A very large number of neighbors gives # more evenly distributed cluster sizes, but may not impose the local # manifold structure of the data. knn_graph = kneighbors_graph(X2, 30, include_self=False) # %% # Plot clustering with and without structure # ****************************************** fig3 = plt.figure(figsize=(8, 12)) subfigs = fig3.subfigures(4, 1) params = [ (None, 30), (None, 3), (knn_graph, 30), (knn_graph, 3), ] for subfig, (connectivity, n_clusters) in zip(subfigs, params): axs = subfig.subplots(1, 4, sharey=True) for index, linkage in enumerate(("average", "complete", "ward", "single")): model = AgglomerativeClustering( linkage=linkage, connectivity=connectivity, n_clusters=n_clusters ) t0 = time.time() model.fit(X2) elapsed_time = time.time() - t0 axs[index].scatter( X2[:, 0], X2[:, 1], c=model.labels_, cmap=plt.cm.nipy_spectral ) axs[index].set_title( "linkage=%s\n(time %.2fs)" % (linkage, elapsed_time), fontdict=dict(verticalalignment="top"), ) axs[index].set_aspect("equal") axs[index].axis("off") subfig.subplots_adjust(bottom=0, top=0.83, wspace=0, left=0, right=1) subfig.suptitle( "n_cluster=%i, connectivity=%r" % (n_clusters, connectivity is not None), size=17, ) plt.show()