sklearn/examples/cluster/plot_dict_face_patches.py

"""
Online learning of a dictionary of parts of faces
=================================================

This example uses a large dataset of faces to learn a set of 20 x 20
images patches that constitute faces.

From the programming standpoint, it is interesting because it shows how
to use the online API of the scikit-learn to process a very large
dataset by chunks. The way we proceed is that we load an image at a time
and extract randomly 50 patches from this image. Once we have accumulated
500 of these patches (using 10 images), we run the
:func:`~sklearn.cluster.MiniBatchKMeans.partial_fit` method
of the online KMeans object, MiniBatchKMeans.

The verbose setting on the MiniBatchKMeans enables us to see that some
clusters are reassigned during the successive calls to
partial-fit. This is because the number of patches that they represent
has become too low, and it is better to choose a random new
cluster.

"""

# %%
# Load the data
# -------------

from sklearn import datasets

faces = datasets.fetch_olivetti_faces()

# %%
# Learn the dictionary of images
# ------------------------------

import time

import numpy as np

from sklearn.cluster import MiniBatchKMeans
from sklearn.feature_extraction.image import extract_patches_2d

print("Learning the dictionary... ")
rng = np.random.RandomState(0)
kmeans = MiniBatchKMeans(n_clusters=81, random_state=rng, verbose=True, n_init=3)
patch_size = (20, 20)

buffer = []
t0 = time.time()

# The online learning part: cycle over the whole dataset 6 times
index = 0
for _ in range(6):
    for img in faces.images:
        data = extract_patches_2d(img, patch_size, max_patches=50, random_state=rng)
        data = np.reshape(data, (len(data), -1))
        buffer.append(data)
        index += 1
        if index % 10 == 0:
            data = np.concatenate(buffer, axis=0)
            data -= np.mean(data, axis=0)
            data /= np.std(data, axis=0)
            kmeans.partial_fit(data)
            buffer = []
        if index % 100 == 0:
            print("Partial fit of %4i out of %i" % (index, 6 * len(faces.images)))

dt = time.time() - t0
print("done in %.2fs." % dt)

# %%
# Plot the results
# ----------------

import matplotlib.pyplot as plt

plt.figure(figsize=(4.2, 4))
for i, patch in enumerate(kmeans.cluster_centers_):
    plt.subplot(9, 9, i + 1)
    plt.imshow(patch.reshape(patch_size), cmap=plt.cm.gray, interpolation="nearest")
    plt.xticks(())
    plt.yticks(())


plt.suptitle(
    "Patches of faces\nTrain time %.1fs on %d patches" % (dt, 8 * len(faces.images)),
    fontsize=16,
)
plt.subplots_adjust(0.08, 0.02, 0.92, 0.85, 0.08, 0.23)

plt.show()
first commit 2024-08-05 09:32:03 +02:00			`"""`
			`Online learning of a dictionary of parts of faces`
			`=================================================`

			`This example uses a large dataset of faces to learn a set of 20 x 20`
			`images patches that constitute faces.`

			`From the programming standpoint, it is interesting because it shows how`
			`to use the online API of the scikit-learn to process a very large`
			`dataset by chunks. The way we proceed is that we load an image at a time`
			`and extract randomly 50 patches from this image. Once we have accumulated`
			`500 of these patches (using 10 images), we run the`
			:func:`~sklearn.cluster.MiniBatchKMeans.partial_fit` method
			`of the online KMeans object, MiniBatchKMeans.`

			`The verbose setting on the MiniBatchKMeans enables us to see that some`
			`clusters are reassigned during the successive calls to`
			`partial-fit. This is because the number of patches that they represent`
			`has become too low, and it is better to choose a random new`
			`cluster.`

			`"""`

			`# %%`
			`# Load the data`
			`# -------------`

			`from sklearn import datasets`

			`faces = datasets.fetch_olivetti_faces()`

			`# %%`
			`# Learn the dictionary of images`
			`# ------------------------------`

			`import time`

			`import numpy as np`

			`from sklearn.cluster import MiniBatchKMeans`
			`from sklearn.feature_extraction.image import extract_patches_2d`

			`print("Learning the dictionary... ")`
			`rng = np.random.RandomState(0)`
			`kmeans = MiniBatchKMeans(n_clusters=81, random_state=rng, verbose=True, n_init=3)`
			`patch_size = (20, 20)`

			`buffer = []`
			`t0 = time.time()`

			`# The online learning part: cycle over the whole dataset 6 times`
			`index = 0`
			`for _ in range(6):`
			`for img in faces.images:`
			`data = extract_patches_2d(img, patch_size, max_patches=50, random_state=rng)`
			`data = np.reshape(data, (len(data), -1))`
			`buffer.append(data)`
			`index += 1`
			`if index % 10 == 0:`
			`data = np.concatenate(buffer, axis=0)`
			`data -= np.mean(data, axis=0)`
			`data /= np.std(data, axis=0)`
			`kmeans.partial_fit(data)`
			`buffer = []`
			`if index % 100 == 0:`
			`print("Partial fit of %4i out of %i" % (index, 6 * len(faces.images)))`

			`dt = time.time() - t0`
			`print("done in %.2fs." % dt)`

			`# %%`
			`# Plot the results`
			`# ----------------`

			`import matplotlib.pyplot as plt`

			`plt.figure(figsize=(4.2, 4))`
			`for i, patch in enumerate(kmeans.cluster_centers_):`
			`plt.subplot(9, 9, i + 1)`
			`plt.imshow(patch.reshape(patch_size), cmap=plt.cm.gray, interpolation="nearest")`
			`plt.xticks(())`
			`plt.yticks(())`


			`plt.suptitle(`
			`"Patches of faces\nTrain time %.1fs on %d patches" % (dt, 8 * len(faces.images)),`
			`fontsize=16,`
			`)`
			`plt.subplots_adjust(0.08, 0.02, 0.92, 0.85, 0.08, 0.23)`

			`plt.show()`