understar/plot_rbm_logistic_classification.py

## plot_rbm_logistic_classification.py
"""
==============================================================
Restricted Boltzmann Machine features for digit classification
==============================================================

For greyscale image data where pixel values can be interpreted as degrees of
blackness on a white background, like handwritten digit recognition, the
Bernoulli Restricted Boltzmann machine model (:class:`BernoulliRBM
<sklearn.neural_network.BernoulliRBM>`) can perform effective non-linear
feature extraction.

In order to learn good latent representations from a small dataset, we
artificially generate more labeled data by perturbing the training data with
linear shifts of 1 pixel in each direction.

This example shows how to build a classification pipeline with a BernoulliRBM
feature extractor and a :class:`LogisticRegression
<sklearn.linear_model.LogisticRegression>` classifier. The hyperparameters
of the entire model (learning rate, hidden layer size, regularization)
were optimized by grid search, but the search is not reproduced here because
of runtime constraints.

Logistic regression on raw pixel values is presented for comparison. The
example shows that the features extracted by the BernoulliRBM help improve the
classification accuracy.
"""

from __future__ import print_function

print(__doc__)

# Authors: Yann N. Dauphin, Vlad Niculae, Gabriel Synnaeve
# License: BSD

import numpy as np
import matplotlib.pyplot as plt

from scipy.ndimage import convolve
from sklearn import linear_model, datasets, metrics
from sklearn.cross_validation import train_test_split
from sklearn.neural_network import BernoulliRBM
from sklearn.pipeline import Pipeline


###############################################################################
# Setting up

def nudge_dataset(X, Y):
    """
    This produces a dataset 5 times bigger than the original one,
    by moving the 8x8 images in X around by 1px to left, right, down, up
    """
    direction_vectors = [
        [[0, 1, 0],
         [0, 0, 0],
         [0, 0, 0]],

        [[0, 0, 0],
         [1, 0, 0],
         [0, 0, 0]],

        [[0, 0, 0],
         [0, 0, 1],
         [0, 0, 0]],

        [[0, 0, 0],
         [0, 0, 0],
         [0, 1, 0]]]

    shift = lambda x, w: convolve(x.reshape((8, 8)), mode='constant',
                                  weights=w).ravel()
    X = np.concatenate([X] +
                       [np.apply_along_axis(shift, 1, X, vector)
                        for vector in direction_vectors])
    Y = np.concatenate([Y for _ in range(5)], axis=0)
    return X, Y

# Load Data
digits = datasets.load_digits()
X = np.asarray(digits.data, 'float32')
X, Y = nudge_dataset(X, digits.target)
X = (X - np.min(X, 0)) / (np.max(X, 0) + 0.0001)  # 0-1 scaling

X_train, X_test, Y_train, Y_test = train_test_split(X, Y,
                                                    test_size=0.2,
                                                    random_state=0)

# Models we will use
logistic = linear_model.LogisticRegression()
rbm = BernoulliRBM(random_state=0, verbose=True)

classifier = Pipeline(steps=[('rbm', rbm), ('logistic', logistic)])

###############################################################################
# Training

# Hyper-parameters. These were set by cross-validation,
# using a GridSearchCV. Here we are not performing cross-validation to
# save time.
rbm.learning_rate = 0.06
rbm.n_iter = 20
# More components tend to give better prediction performance, but larger
# fitting time
rbm.n_components = 100
logistic.C = 6000.0

# Training RBM-Logistic Pipeline
classifier.fit(X_train, Y_train)

# Training Logistic regression
logistic_classifier = linear_model.LogisticRegression(C=100.0)
logistic_classifier.fit(X_train, Y_train)

###############################################################################
# Evaluation

print()
print("Logistic regression using RBM features:\n%s\n" % (
    metrics.classification_report(
        Y_test,
        classifier.predict(X_test))))

print("Logistic regression using raw pixel features:\n%s\n" % (
    metrics.classification_report(
        Y_test,
        logistic_classifier.predict(X_test))))

###############################################################################
# Plotting

plt.figure(figsize=(4.2, 4))
for i, comp in enumerate(rbm.components_):
    plt.subplot(10, 10, i + 1)
    plt.imshow(comp.reshape((8, 8)), cmap=plt.cm.gray_r,
               interpolation='nearest')
    plt.xticks(())
    plt.yticks(())
plt.suptitle('100 components extracted by RBM', fontsize=16)
plt.subplots_adjust(0.08, 0.02, 0.92, 0.85, 0.08, 0.23)

plt.show()
	"""
	==============================================================
	Restricted Boltzmann Machine features for digit classification
	==============================================================

	For greyscale image data where pixel values can be interpreted as degrees of
	blackness on a white background, like handwritten digit recognition, the
	Bernoulli Restricted Boltzmann machine model (:class:`BernoulliRBM
	<sklearn.neural_network.BernoulliRBM>`) can perform effective non-linear
	feature extraction.

	In order to learn good latent representations from a small dataset, we
	artificially generate more labeled data by perturbing the training data with
	linear shifts of 1 pixel in each direction.

	This example shows how to build a classification pipeline with a BernoulliRBM
	feature extractor and a :class:`LogisticRegression
	<sklearn.linear_model.LogisticRegression>` classifier. The hyperparameters
	of the entire model (learning rate, hidden layer size, regularization)
	were optimized by grid search, but the search is not reproduced here because
	of runtime constraints.

	Logistic regression on raw pixel values is presented for comparison. The
	example shows that the features extracted by the BernoulliRBM help improve the
	classification accuracy.
	"""

	from __future__ import print_function

	print(__doc__)

	# Authors: Yann N. Dauphin, Vlad Niculae, Gabriel Synnaeve
	# License: BSD

	import numpy as np
	import matplotlib.pyplot as plt

	from scipy.ndimage import convolve
	from sklearn import linear_model, datasets, metrics
	from sklearn.cross_validation import train_test_split
	from sklearn.neural_network import BernoulliRBM
	from sklearn.pipeline import Pipeline


	###############################################################################
	# Setting up

	def nudge_dataset(X, Y):
	"""
	This produces a dataset 5 times bigger than the original one,
	by moving the 8x8 images in X around by 1px to left, right, down, up
	"""
	direction_vectors = [
	[[0, 1, 0],
	[0, 0, 0],
	[0, 0, 0]],

	[[0, 0, 0],
	[1, 0, 0],
	[0, 0, 0]],

	[[0, 0, 0],
	[0, 0, 1],
	[0, 0, 0]],

	[[0, 0, 0],
	[0, 0, 0],
	[0, 1, 0]]]

	shift = lambda x, w: convolve(x.reshape((8, 8)), mode='constant',
	weights=w).ravel()
	X = np.concatenate([X] +
	[np.apply_along_axis(shift, 1, X, vector)
	for vector in direction_vectors])
	Y = np.concatenate([Y for _ in range(5)], axis=0)
	return X, Y

	# Load Data
	digits = datasets.load_digits()
	X = np.asarray(digits.data, 'float32')
	X, Y = nudge_dataset(X, digits.target)
	X = (X - np.min(X, 0)) / (np.max(X, 0) + 0.0001) # 0-1 scaling

	X_train, X_test, Y_train, Y_test = train_test_split(X, Y,
	test_size=0.2,
	random_state=0)

	# Models we will use
	logistic = linear_model.LogisticRegression()
	rbm = BernoulliRBM(random_state=0, verbose=True)

	classifier = Pipeline(steps=[('rbm', rbm), ('logistic', logistic)])

	###############################################################################
	# Training

	# Hyper-parameters. These were set by cross-validation,
	# using a GridSearchCV. Here we are not performing cross-validation to
	# save time.
	rbm.learning_rate = 0.06
	rbm.n_iter = 20
	# More components tend to give better prediction performance, but larger
	# fitting time
	rbm.n_components = 100
	logistic.C = 6000.0

	# Training RBM-Logistic Pipeline
	classifier.fit(X_train, Y_train)

	# Training Logistic regression
	logistic_classifier = linear_model.LogisticRegression(C=100.0)
	logistic_classifier.fit(X_train, Y_train)

	###############################################################################
	# Evaluation

	print()
	print("Logistic regression using RBM features:\n%s\n" % (
	metrics.classification_report(
	Y_test,
	classifier.predict(X_test))))

	print("Logistic regression using raw pixel features:\n%s\n" % (
	metrics.classification_report(
	Y_test,
	logistic_classifier.predict(X_test))))

	###############################################################################
	# Plotting

	plt.figure(figsize=(4.2, 4))
	for i, comp in enumerate(rbm.components_):
	plt.subplot(10, 10, i + 1)
	plt.imshow(comp.reshape((8, 8)), cmap=plt.cm.gray_r,
	interpolation='nearest')
	plt.xticks(())
	plt.yticks(())
	plt.suptitle('100 components extracted by RBM', fontsize=16)
	plt.subplots_adjust(0.08, 0.02, 0.92, 0.85, 0.08, 0.23)

	plt.show()