#!/usr/bin/python # -*- coding: utf-8 -*- """ ========================================================= Vector Quantization Example ========================================================= The classic image processing example, Lena, an 8-bit grayscale bit-depth, 512 x 512 sized image, is used here to illustrate how `k`-means is used for vector quantization. """ print(__doc__) # Code source: Gael Varoqueux # Modified for Documentation merge by Jaques Grobler # License: BSD 3 clause import numpy as np import scipy as sp import pylab as pl from sklearn import cluster n_clusters = 5 np.random.seed(0) try: lena = sp.lena() except AttributeError: # Newer versions of scipy have lena in misc from scipy import misc lena = misc.lena() X = lena.reshape((-1, 1)) # We need an (n_sample, n_feature) array k_means = cluster.KMeans(n_clusters=n_clusters, n_init=4) k_means.fit(X) values = k_means.cluster_centers_.squeeze() labels = k_means.labels_ # create an array from labels and values lena_compressed = np.choose(labels, values) lena_compressed.shape = lena.shape vmin = lena.min() vmax = lena.max() # original lena pl.figure(1, figsize=(3, 2.2)) pl.imshow(lena, cmap=pl.cm.gray, vmin=vmin, vmax=256) # compressed lena pl.figure(2, figsize=(3, 2.2)) pl.imshow(lena_compressed, cmap=pl.cm.gray, vmin=vmin, vmax=vmax) # equal bins lena regular_values = np.linspace(0, 256, n_clusters + 1) regular_labels = np.searchsorted(regular_values, lena) - 1 regular_values = .5 * (regular_values[1:] + regular_values[:-1]) # mean regular_lena = np.choose(regular_labels.ravel(), regular_values) regular_lena.shape = lena.shape pl.figure(3, figsize=(3, 2.2)) pl.imshow(regular_lena, cmap=pl.cm.gray, vmin=vmin, vmax=vmax) # histogram pl.figure(4, figsize=(3, 2.2)) pl.clf() pl.axes([.01, .01, .98, .98]) pl.hist(X, bins=256, color='.5', edgecolor='.5') pl.yticks(()) pl.xticks(regular_values) values = np.sort(values) for center_1, center_2 in zip(values[:-1], values[1:]): pl.axvline(.5 * (center_1 + center_2), color='b') for center_1, center_2 in zip(regular_values[:-1], regular_values[1:]): pl.axvline(.5 * (center_1 + center_2), color='b', linestyle='--') pl.show()