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Pairwise ranking using scikit-learn LinearSVC
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""" | |
Implementation of pairwise ranking using scikit-learn LinearSVC | |
Reference: "Large Margin Rank Boundaries for Ordinal Regression", R. Herbrich, | |
T. Graepel, K. Obermayer. | |
Authors: Fabian Pedregosa <[email protected]> | |
Alexandre Gramfort <[email protected]> | |
""" | |
import itertools | |
import numpy as np | |
from sklearn import svm, linear_model, cross_validation | |
def transform_pairwise(X, y): | |
"""Transforms data into pairs with balanced labels for ranking | |
Transforms a n-class ranking problem into a two-class classification | |
problem. Subclasses implementing particular strategies for choosing | |
pairs should override this method. | |
In this method, all pairs are choosen, except for those that have the | |
same target value. The output is an array of balanced classes, i.e. | |
there are the same number of -1 as +1 | |
Parameters | |
---------- | |
X : array, shape (n_samples, n_features) | |
The data | |
y : array, shape (n_samples,) or (n_samples, 2) | |
Target labels. If it's a 2D array, the second column represents | |
the grouping of samples, i.e., samples with different groups will | |
not be considered. | |
Returns | |
------- | |
X_trans : array, shape (k, n_feaures) | |
Data as pairs | |
y_trans : array, shape (k,) | |
Output class labels, where classes have values {-1, +1} | |
""" | |
X_new = [] | |
y_new = [] | |
y = np.asarray(y) | |
if y.ndim == 1: | |
y = np.c_[y, np.ones(y.shape[0])] | |
comb = itertools.combinations(range(X.shape[0]), 2) | |
for k, (i, j) in enumerate(comb): | |
if y[i, 0] == y[j, 0] or y[i, 1] != y[j, 1]: | |
# skip if same target or different group | |
continue | |
X_new.append(X[i] - X[j]) | |
y_new.append(np.sign(y[i, 0] - y[j, 0])) | |
# output balanced classes | |
if y_new[-1] != (-1) ** k: | |
y_new[-1] = - y_new[-1] | |
X_new[-1] = - X_new[-1] | |
return np.asarray(X_new), np.asarray(y_new).ravel() | |
class RankSVM(svm.LinearSVC): | |
"""Performs pairwise ranking with an underlying LinearSVC model | |
Input should be a n-class ranking problem, this object will convert it | |
into a two-class classification problem, a setting known as | |
`pairwise ranking`. | |
See object :ref:`svm.LinearSVC` for a full description of parameters. | |
""" | |
def fit(self, X, y): | |
""" | |
Fit a pairwise ranking model. | |
Parameters | |
---------- | |
X : array, shape (n_samples, n_features) | |
y : array, shape (n_samples,) or (n_samples, 2) | |
Returns | |
------- | |
self | |
""" | |
X_trans, y_trans = transform_pairwise(X, y) | |
super(RankSVM, self).fit(X_trans, y_trans) | |
return self | |
def predict(self, X): | |
""" | |
Predict an ordering on X. For a list of n samples, this method | |
returns a list from 0 to n-1 with the relative order of the rows of X. | |
Parameters | |
---------- | |
X : array, shape (n_samples, n_features) | |
Returns | |
------- | |
ord : array, shape (n_samples,) | |
Returns a list of integers representing the relative order of | |
the rows in X. | |
""" | |
if hasattr(self, 'coef_'): | |
np.argsort(np.dot(X, self.coef_.T)) | |
else: | |
raise ValueError("Must call fit() prior to predict()") | |
def score(self, X, y): | |
""" | |
Because we transformed into a pairwise problem, chance level is at 0.5 | |
""" | |
X_trans, y_trans = transform_pairwise(X, y) | |
return np.mean(super(RankSVM, self).predict(X_trans) == y_trans) | |
if __name__ == '__main__': | |
# as showcase, we will create some non-linear data | |
# and print the performance of ranking vs linear regression | |
np.random.seed(1) | |
n_samples, n_features = 300, 5 | |
true_coef = np.random.randn(n_features) | |
X = np.random.randn(n_samples, n_features) | |
noise = np.random.randn(n_samples) / np.linalg.norm(true_coef) | |
y = np.dot(X, true_coef) | |
y = np.arctan(y) # add non-linearities | |
y += .1 * noise # add noise | |
Y = np.c_[y, np.mod(np.arange(n_samples), 5)] # add query fake id | |
cv = cross_validation.KFold(n_samples, 5) | |
train, test = iter(cv).next() | |
# make a simple plot out of it | |
import pylab as pl | |
pl.scatter(np.dot(X, true_coef), y) | |
pl.title('Data to be learned') | |
pl.xlabel('<X, coef>') | |
pl.ylabel('y') | |
pl.show() | |
# print the performance of ranking | |
rank_svm = RankSVM().fit(X[train], Y[train]) | |
print 'Performance of ranking ', rank_svm.score(X[test], Y[test]) | |
# and that of linear regression | |
ridge = linear_model.RidgeCV(fit_intercept=True) | |
ridge.fit(X[train], y[train]) | |
X_test_trans, y_test_trans = transform_pairwise(X[test], y[test]) | |
score = np.mean(np.sign(np.dot(X_test_trans, ridge.coef_)) == y_test_trans) | |
print 'Performance of linear regression ', score |
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