610 lines
21 KiB
Python
610 lines
21 KiB
Python
"""Calibration of predicted probabilities."""
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# Author: Alexandre Gramfort <alexandre.gramfort@telecom-paristech.fr>
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# Balazs Kegl <balazs.kegl@gmail.com>
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# Jan Hendrik Metzen <jhm@informatik.uni-bremen.de>
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# Mathieu Blondel <mathieu@mblondel.org>
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#
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# License: BSD 3 clause
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import warnings
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from inspect import signature
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from math import log
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import numpy as np
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from scipy.special import expit
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from scipy.special import xlogy
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from scipy.optimize import fmin_bfgs
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from .preprocessing import LabelEncoder
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from .base import (BaseEstimator, ClassifierMixin, RegressorMixin, clone,
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MetaEstimatorMixin)
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from .preprocessing import label_binarize, LabelBinarizer
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from .utils import check_X_y, check_array, indexable, column_or_1d
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from .utils.validation import check_is_fitted, check_consistent_length
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from .utils.validation import _check_sample_weight
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from .isotonic import IsotonicRegression
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from .svm import LinearSVC
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from .model_selection import check_cv
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class CalibratedClassifierCV(BaseEstimator, ClassifierMixin,
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MetaEstimatorMixin):
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"""Probability calibration with isotonic regression or sigmoid.
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See glossary entry for :term:`cross-validation estimator`.
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With this class, the base_estimator is fit on the train set of the
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cross-validation generator and the test set is used for calibration.
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The probabilities for each of the folds are then averaged
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for prediction. In case that cv="prefit" is passed to __init__,
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it is assumed that base_estimator has been fitted already and all
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data is used for calibration. Note that data for fitting the
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classifier and for calibrating it must be disjoint.
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Read more in the :ref:`User Guide <calibration>`.
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Parameters
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----------
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base_estimator : instance BaseEstimator
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The classifier whose output decision function needs to be calibrated
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to offer more accurate predict_proba outputs. If cv=prefit, the
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classifier must have been fit already on data.
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method : 'sigmoid' or 'isotonic'
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The method to use for calibration. Can be 'sigmoid' which
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corresponds to Platt's method or 'isotonic' which is a
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non-parametric approach. It is not advised to use isotonic calibration
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with too few calibration samples ``(<<1000)`` since it tends to
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overfit.
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Use sigmoids (Platt's calibration) in this case.
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cv : integer, cross-validation generator, iterable or "prefit", optional
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Determines the cross-validation splitting strategy.
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Possible inputs for cv are:
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- None, to use the default 5-fold cross-validation,
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- integer, to specify the number of folds.
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- :term:`CV splitter`,
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- An iterable yielding (train, test) splits as arrays of indices.
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For integer/None inputs, if ``y`` is binary or multiclass,
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:class:`sklearn.model_selection.StratifiedKFold` is used. If ``y`` is
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neither binary nor multiclass, :class:`sklearn.model_selection.KFold`
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is used.
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Refer :ref:`User Guide <cross_validation>` for the various
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cross-validation strategies that can be used here.
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If "prefit" is passed, it is assumed that base_estimator has been
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fitted already and all data is used for calibration.
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.. versionchanged:: 0.22
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``cv`` default value if None changed from 3-fold to 5-fold.
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Attributes
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----------
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classes_ : array, shape (n_classes)
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The class labels.
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calibrated_classifiers_ : list (len() equal to cv or 1 if cv == "prefit")
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The list of calibrated classifiers, one for each crossvalidation fold,
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which has been fitted on all but the validation fold and calibrated
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on the validation fold.
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References
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----------
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.. [1] Obtaining calibrated probability estimates from decision trees
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and naive Bayesian classifiers, B. Zadrozny & C. Elkan, ICML 2001
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.. [2] Transforming Classifier Scores into Accurate Multiclass
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Probability Estimates, B. Zadrozny & C. Elkan, (KDD 2002)
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.. [3] Probabilistic Outputs for Support Vector Machines and Comparisons to
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Regularized Likelihood Methods, J. Platt, (1999)
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.. [4] Predicting Good Probabilities with Supervised Learning,
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A. Niculescu-Mizil & R. Caruana, ICML 2005
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"""
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def __init__(self, base_estimator=None, method='sigmoid', cv=None):
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self.base_estimator = base_estimator
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self.method = method
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self.cv = cv
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def fit(self, X, y, sample_weight=None):
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"""Fit the calibrated model
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Parameters
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----------
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X : array-like, shape (n_samples, n_features)
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Training data.
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y : array-like, shape (n_samples,)
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Target values.
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sample_weight : array-like of shape (n_samples,), default=None
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Sample weights. If None, then samples are equally weighted.
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Returns
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-------
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self : object
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Returns an instance of self.
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"""
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X, y = check_X_y(X, y, accept_sparse=['csc', 'csr', 'coo'],
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force_all_finite=False, allow_nd=True)
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X, y = indexable(X, y)
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le = LabelBinarizer().fit(y)
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self.classes_ = le.classes_
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# Check that each cross-validation fold can have at least one
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# example per class
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n_folds = self.cv if isinstance(self.cv, int) \
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else self.cv.n_folds if hasattr(self.cv, "n_folds") else None
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if n_folds and \
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np.any([np.sum(y == class_) < n_folds for class_ in
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self.classes_]):
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raise ValueError("Requesting %d-fold cross-validation but provided"
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" less than %d examples for at least one class."
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% (n_folds, n_folds))
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self.calibrated_classifiers_ = []
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if self.base_estimator is None:
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# we want all classifiers that don't expose a random_state
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# to be deterministic (and we don't want to expose this one).
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base_estimator = LinearSVC(random_state=0)
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else:
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base_estimator = self.base_estimator
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if self.cv == "prefit":
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calibrated_classifier = _CalibratedClassifier(
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base_estimator, method=self.method)
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if sample_weight is not None:
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calibrated_classifier.fit(X, y, sample_weight)
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else:
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calibrated_classifier.fit(X, y)
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self.calibrated_classifiers_.append(calibrated_classifier)
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else:
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cv = check_cv(self.cv, y, classifier=True)
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fit_parameters = signature(base_estimator.fit).parameters
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estimator_name = type(base_estimator).__name__
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if (sample_weight is not None
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and "sample_weight" not in fit_parameters):
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warnings.warn("%s does not support sample_weight. Samples"
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" weights are only used for the calibration"
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" itself." % estimator_name)
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sample_weight = check_array(sample_weight, ensure_2d=False)
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base_estimator_sample_weight = None
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else:
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if sample_weight is not None:
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sample_weight = _check_sample_weight(sample_weight, X)
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base_estimator_sample_weight = sample_weight
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for train, test in cv.split(X, y):
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this_estimator = clone(base_estimator)
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if base_estimator_sample_weight is not None:
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this_estimator.fit(
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X[train], y[train],
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sample_weight=base_estimator_sample_weight[train])
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else:
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this_estimator.fit(X[train], y[train])
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calibrated_classifier = _CalibratedClassifier(
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this_estimator, method=self.method,
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classes=self.classes_)
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if sample_weight is not None:
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calibrated_classifier.fit(X[test], y[test],
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sample_weight[test])
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else:
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calibrated_classifier.fit(X[test], y[test])
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self.calibrated_classifiers_.append(calibrated_classifier)
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return self
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def predict_proba(self, X):
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"""Posterior probabilities of classification
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This function returns posterior probabilities of classification
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according to each class on an array of test vectors X.
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Parameters
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----------
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X : array-like, shape (n_samples, n_features)
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The samples.
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Returns
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-------
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C : array, shape (n_samples, n_classes)
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The predicted probas.
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"""
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check_is_fitted(self)
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X = check_array(X, accept_sparse=['csc', 'csr', 'coo'],
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force_all_finite=False)
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# Compute the arithmetic mean of the predictions of the calibrated
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# classifiers
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mean_proba = np.zeros((X.shape[0], len(self.classes_)))
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for calibrated_classifier in self.calibrated_classifiers_:
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proba = calibrated_classifier.predict_proba(X)
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mean_proba += proba
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mean_proba /= len(self.calibrated_classifiers_)
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return mean_proba
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def predict(self, X):
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"""Predict the target of new samples. Can be different from the
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prediction of the uncalibrated classifier.
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Parameters
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----------
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X : array-like, shape (n_samples, n_features)
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The samples.
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Returns
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-------
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C : array, shape (n_samples,)
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The predicted class.
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"""
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check_is_fitted(self)
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return self.classes_[np.argmax(self.predict_proba(X), axis=1)]
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class _CalibratedClassifier:
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"""Probability calibration with isotonic regression or sigmoid.
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It assumes that base_estimator has already been fit, and trains the
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calibration on the input set of the fit function. Note that this class
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should not be used as an estimator directly. Use CalibratedClassifierCV
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with cv="prefit" instead.
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Parameters
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----------
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base_estimator : instance BaseEstimator
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The classifier whose output decision function needs to be calibrated
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to offer more accurate predict_proba outputs. No default value since
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it has to be an already fitted estimator.
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method : 'sigmoid' | 'isotonic'
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The method to use for calibration. Can be 'sigmoid' which
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corresponds to Platt's method or 'isotonic' which is a
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non-parametric approach based on isotonic regression.
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classes : array-like, shape (n_classes,), optional
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Contains unique classes used to fit the base estimator.
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if None, then classes is extracted from the given target values
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in fit().
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See also
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--------
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CalibratedClassifierCV
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References
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----------
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.. [1] Obtaining calibrated probability estimates from decision trees
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and naive Bayesian classifiers, B. Zadrozny & C. Elkan, ICML 2001
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.. [2] Transforming Classifier Scores into Accurate Multiclass
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Probability Estimates, B. Zadrozny & C. Elkan, (KDD 2002)
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.. [3] Probabilistic Outputs for Support Vector Machines and Comparisons to
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Regularized Likelihood Methods, J. Platt, (1999)
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.. [4] Predicting Good Probabilities with Supervised Learning,
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A. Niculescu-Mizil & R. Caruana, ICML 2005
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"""
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def __init__(self, base_estimator, method='sigmoid', classes=None):
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self.base_estimator = base_estimator
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self.method = method
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self.classes = classes
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def _preproc(self, X):
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n_classes = len(self.classes_)
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if hasattr(self.base_estimator, "decision_function"):
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df = self.base_estimator.decision_function(X)
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if df.ndim == 1:
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df = df[:, np.newaxis]
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elif hasattr(self.base_estimator, "predict_proba"):
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df = self.base_estimator.predict_proba(X)
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if n_classes == 2:
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df = df[:, 1:]
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else:
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raise RuntimeError('classifier has no decision_function or '
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'predict_proba method.')
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idx_pos_class = self.label_encoder_.\
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transform(self.base_estimator.classes_)
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return df, idx_pos_class
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def fit(self, X, y, sample_weight=None):
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"""Calibrate the fitted model
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Parameters
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----------
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X : array-like, shape (n_samples, n_features)
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Training data.
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y : array-like, shape (n_samples,)
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Target values.
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sample_weight : array-like of shape (n_samples,), default=None
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Sample weights. If None, then samples are equally weighted.
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Returns
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-------
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self : object
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Returns an instance of self.
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"""
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self.label_encoder_ = LabelEncoder()
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if self.classes is None:
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self.label_encoder_.fit(y)
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else:
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self.label_encoder_.fit(self.classes)
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self.classes_ = self.label_encoder_.classes_
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Y = label_binarize(y, self.classes_)
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df, idx_pos_class = self._preproc(X)
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self.calibrators_ = []
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for k, this_df in zip(idx_pos_class, df.T):
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if self.method == 'isotonic':
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calibrator = IsotonicRegression(out_of_bounds='clip')
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elif self.method == 'sigmoid':
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calibrator = _SigmoidCalibration()
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else:
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raise ValueError('method should be "sigmoid" or '
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'"isotonic". Got %s.' % self.method)
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calibrator.fit(this_df, Y[:, k], sample_weight)
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self.calibrators_.append(calibrator)
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return self
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def predict_proba(self, X):
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"""Posterior probabilities of classification
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This function returns posterior probabilities of classification
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according to each class on an array of test vectors X.
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Parameters
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----------
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X : array-like, shape (n_samples, n_features)
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The samples.
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Returns
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-------
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C : array, shape (n_samples, n_classes)
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The predicted probas. Can be exact zeros.
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"""
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n_classes = len(self.classes_)
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proba = np.zeros((X.shape[0], n_classes))
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df, idx_pos_class = self._preproc(X)
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for k, this_df, calibrator in \
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zip(idx_pos_class, df.T, self.calibrators_):
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if n_classes == 2:
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k += 1
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proba[:, k] = calibrator.predict(this_df)
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# Normalize the probabilities
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if n_classes == 2:
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proba[:, 0] = 1. - proba[:, 1]
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else:
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proba /= np.sum(proba, axis=1)[:, np.newaxis]
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# XXX : for some reason all probas can be 0
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proba[np.isnan(proba)] = 1. / n_classes
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# Deal with cases where the predicted probability minimally exceeds 1.0
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proba[(1.0 < proba) & (proba <= 1.0 + 1e-5)] = 1.0
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return proba
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def _sigmoid_calibration(df, y, sample_weight=None):
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"""Probability Calibration with sigmoid method (Platt 2000)
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Parameters
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----------
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df : ndarray, shape (n_samples,)
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The decision function or predict proba for the samples.
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y : ndarray, shape (n_samples,)
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The targets.
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sample_weight : array-like of shape (n_samples,), default=None
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Sample weights. If None, then samples are equally weighted.
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Returns
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-------
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a : float
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The slope.
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b : float
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The intercept.
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References
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----------
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Platt, "Probabilistic Outputs for Support Vector Machines"
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"""
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df = column_or_1d(df)
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y = column_or_1d(y)
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F = df # F follows Platt's notations
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# Bayesian priors (see Platt end of section 2.2)
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prior0 = float(np.sum(y <= 0))
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prior1 = y.shape[0] - prior0
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T = np.zeros(y.shape)
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T[y > 0] = (prior1 + 1.) / (prior1 + 2.)
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T[y <= 0] = 1. / (prior0 + 2.)
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T1 = 1. - T
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def objective(AB):
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# From Platt (beginning of Section 2.2)
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P = expit(-(AB[0] * F + AB[1]))
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loss = -(xlogy(T, P) + xlogy(T1, 1. - P))
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if sample_weight is not None:
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return (sample_weight * loss).sum()
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else:
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return loss.sum()
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def grad(AB):
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# gradient of the objective function
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P = expit(-(AB[0] * F + AB[1]))
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TEP_minus_T1P = T - P
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if sample_weight is not None:
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TEP_minus_T1P *= sample_weight
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dA = np.dot(TEP_minus_T1P, F)
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dB = np.sum(TEP_minus_T1P)
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return np.array([dA, dB])
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AB0 = np.array([0., log((prior0 + 1.) / (prior1 + 1.))])
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AB_ = fmin_bfgs(objective, AB0, fprime=grad, disp=False)
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return AB_[0], AB_[1]
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class _SigmoidCalibration(RegressorMixin, BaseEstimator):
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"""Sigmoid regression model.
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Attributes
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----------
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a_ : float
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The slope.
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b_ : float
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The intercept.
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"""
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def fit(self, X, y, sample_weight=None):
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"""Fit the model using X, y as training data.
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Parameters
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----------
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X : array-like, shape (n_samples,)
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Training data.
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y : array-like, shape (n_samples,)
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Training target.
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sample_weight : array-like of shape (n_samples,), default=None
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Sample weights. If None, then samples are equally weighted.
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Returns
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-------
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self : object
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Returns an instance of self.
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"""
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X = column_or_1d(X)
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y = column_or_1d(y)
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X, y = indexable(X, y)
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self.a_, self.b_ = _sigmoid_calibration(X, y, sample_weight)
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return self
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def predict(self, T):
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"""Predict new data by linear interpolation.
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Parameters
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----------
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T : array-like, shape (n_samples,)
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Data to predict from.
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Returns
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-------
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T_ : array, shape (n_samples,)
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The predicted data.
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"""
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T = column_or_1d(T)
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return expit(-(self.a_ * T + self.b_))
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def calibration_curve(y_true, y_prob, normalize=False, n_bins=5,
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strategy='uniform'):
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"""Compute true and predicted probabilities for a calibration curve.
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The method assumes the inputs come from a binary classifier.
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Calibration curves may also be referred to as reliability diagrams.
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Read more in the :ref:`User Guide <calibration>`.
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Parameters
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----------
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y_true : array, shape (n_samples,)
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True targets.
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y_prob : array, shape (n_samples,)
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Probabilities of the positive class.
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normalize : bool, optional, default=False
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Whether y_prob needs to be normalized into the bin [0, 1], i.e. is not
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a proper probability. If True, the smallest value in y_prob is mapped
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onto 0 and the largest one onto 1.
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n_bins : int
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Number of bins. A bigger number requires more data. Bins with no data
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points (i.e. without corresponding values in y_prob) will not be
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returned, thus there may be fewer than n_bins in the return value.
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strategy : {'uniform', 'quantile'}, (default='uniform')
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Strategy used to define the widths of the bins.
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uniform
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All bins have identical widths.
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quantile
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All bins have the same number of points.
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Returns
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-------
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prob_true : array, shape (n_bins,) or smaller
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The true probability in each bin (fraction of positives).
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prob_pred : array, shape (n_bins,) or smaller
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The mean predicted probability in each bin.
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References
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----------
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Alexandru Niculescu-Mizil and Rich Caruana (2005) Predicting Good
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Probabilities With Supervised Learning, in Proceedings of the 22nd
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International Conference on Machine Learning (ICML).
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See section 4 (Qualitative Analysis of Predictions).
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"""
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y_true = column_or_1d(y_true)
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y_prob = column_or_1d(y_prob)
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check_consistent_length(y_true, y_prob)
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if normalize: # Normalize predicted values into interval [0, 1]
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y_prob = (y_prob - y_prob.min()) / (y_prob.max() - y_prob.min())
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elif y_prob.min() < 0 or y_prob.max() > 1:
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raise ValueError("y_prob has values outside [0, 1] and normalize is "
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"set to False.")
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labels = np.unique(y_true)
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if len(labels) > 2:
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raise ValueError("Only binary classification is supported. "
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"Provided labels %s." % labels)
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y_true = label_binarize(y_true, labels)[:, 0]
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if strategy == 'quantile': # Determine bin edges by distribution of data
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quantiles = np.linspace(0, 1, n_bins + 1)
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bins = np.percentile(y_prob, quantiles * 100)
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bins[-1] = bins[-1] + 1e-8
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elif strategy == 'uniform':
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bins = np.linspace(0., 1. + 1e-8, n_bins + 1)
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else:
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raise ValueError("Invalid entry to 'strategy' input. Strategy "
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"must be either 'quantile' or 'uniform'.")
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binids = np.digitize(y_prob, bins) - 1
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bin_sums = np.bincount(binids, weights=y_prob, minlength=len(bins))
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bin_true = np.bincount(binids, weights=y_true, minlength=len(bins))
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bin_total = np.bincount(binids, minlength=len(bins))
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nonzero = bin_total != 0
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prob_true = (bin_true[nonzero] / bin_total[nonzero])
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prob_pred = (bin_sums[nonzero] / bin_total[nonzero])
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return prob_true, prob_pred
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