diff --git a/doc/modules/calibration.rst b/doc/modules/calibration.rst index 19df08ea3b1fe..cfc185c854edb 100644 --- a/doc/modules/calibration.rst +++ b/doc/modules/calibration.rst @@ -11,16 +11,22 @@ When performing classification you often want not only to predict the class label, but also obtain a probability of the respective label. This probability gives you some kind of confidence on the prediction. Some models can give you poor estimates of the class probabilities and some even do not support -probability prediction. The calibration module allows you to better calibrate +probability prediction (e.g., some instances of +:class:`~sklearn.linear_model.SGDClassifier`). +The calibration module allows you to better calibrate the probabilities of a given model, or to add support for probability prediction. Well calibrated classifiers are probabilistic classifiers for which the output -of the predict_proba method can be directly interpreted as a confidence level. +of the :term:`predict_proba` method can be directly interpreted as a confidence +level. For instance, a well calibrated (binary) classifier should classify the samples -such that among the samples to which it gave a predict_proba value close to 0.8, +such that among the samples to which it gave a :term:`predict_proba` value +close to 0.8, approximately 80% actually belong to the positive class. +.. _calibration_curve: + Calibration curves ------------------ @@ -37,7 +43,7 @@ class is the positive class (in each bin). .. currentmodule:: sklearn.linear_model :class:`LogisticRegression` returns well calibrated predictions by default as it directly -optimizes log-loss. In contrast, the other methods return biased probabilities; +optimizes :ref:`log_loss`. In contrast, the other methods return biased probabilities; with different biases per method: .. currentmodule:: sklearn.naive_bayes @@ -73,24 +79,28 @@ to 0 or 1 typically. .. currentmodule:: sklearn.svm Linear Support Vector Classification (:class:`LinearSVC`) shows an even more -sigmoid curve as the RandomForestClassifier, which is typical for -maximum-margin methods (compare Niculescu-Mizil and Caruana [1]_), which -focus on hard samples that are close to the decision boundary (the support -vectors). +sigmoid curve than :class:`~sklearn.ensemble.RandomForestClassifier`, which is +typical for maximum-margin methods (compare Niculescu-Mizil and Caruana [1]_), +which focus on difficult to classify samples that are close to the decision +boundary (the support vectors). Calibrating a classifier ------------------------ .. currentmodule:: sklearn.calibration -Calibrating a classifier consists in fitting a regressor (called a +Calibrating a classifier consists of fitting a regressor (called a *calibrator*) that maps the output of the classifier (as given by -:term:`predict` or :term:`predict_proba`) to a calibrated probability in [0, -1]. Denoting the output of the classifier for a given sample by :math:`f_i`, +:term:`decision_function` or :term:`predict_proba`) to a calibrated probability +in [0, 1]. Denoting the output of the classifier for a given sample by :math:`f_i`, the calibrator tries to predict :math:`p(y_i = 1 | f_i)`. -The samples that are used to train the calibrator should not be used to -train the target classifier. +The samples that are used to fit the calibrator should not be the same +samples used to fit the classifier, as this would +introduce bias. The classifier performance on its training data would be +better than for novel data. Using the classifier output from training data +to fit the calibrator would thus result in a biased calibrator that maps to +probabilities closer to 0 and 1 than it should. Usage ----- @@ -98,9 +108,12 @@ Usage The :class:`CalibratedClassifierCV` class is used to calibrate a classifier. :class:`CalibratedClassifierCV` uses a cross-validation approach to fit both -the classifier and the regressor. For each of the k `(trainset, testset)` -couple, a classifier is trained on the train set, and its predictions on the -test set are used to fit a regressor. We end up with k +the classifier and the regressor. The data is split into k +`(train_set, test_set)` couples (as determined by `cv`). The classifier +(`base_estimator`) is trained on the train set, and its predictions on the +test set are used to fit a regressor. This ensures that the data used to fit +the classifier is always disjoint from the data used to fit the calibrator. +After fitting, we end up with k `(classifier, regressor)` couples where each regressor maps the output of its corresponding classifier into [0, 1]. Each couple is exposed in the `calibrated_classifiers_` attribute, where each entry is a calibrated @@ -111,30 +124,89 @@ predicted probabilities of the `k` estimators in the `calibrated_classifiers_` list. The output of :term:`predict` is the class that has the highest probability. -The regressor that is used for calibration depends on the `method` -parameter. `'sigmoid'` corresponds to a parametric approach based on Platt's -logistic model [3]_, i.e. :math:`p(y_i = 1 | f_i)` is modeled as -:math:`\sigma(A f_i + B)` where :math:`\sigma` is the logistic function, and -:math:`A` and :math:`B` are real numbers to be determined when fitting the -regressor via maximum likelihood. `'isotonic'` will instead fit a -non-parametric isotonic regressor, which outputs a step-wise non-decreasing -function (see :mod:`sklearn.isotonic`). - -An already fitted classifier can be calibrated by setting `cv="prefit"`. In -this case, the data is only used to fit the regressor. It is up to the user +Alternatively an already fitted classifier can be calibrated by setting +`cv="prefit"`. In this case, the data is not split and all of it is used to +fit the regressor. It is up to the user make sure that the data used for fitting the classifier is disjoint from the data used for fitting the regressor. -:class:`CalibratedClassifierCV` can calibrate probabilities in a multiclass -setting if the base estimator supports multiclass predictions. The classifier -is calibrated first for each class separately in a one-vs-rest fashion [4]_. -When predicting probabilities, the calibrated probabilities for each class +:func:`sklearn.metrics.brier_score_loss` may be used to assess how +well a classifier is calibrated. However, this metric should be used with care +because a lower Brier score does not always mean a better calibrated model. +This is because the Brier score metric is a combination of calibration loss +and refinement loss. Calibration loss is defined as the mean squared deviation +from empirical probabilities derived from the slope of ROC segments. +Refinement loss can be defined as the expected optimal loss as measured by the +area under the optimal cost curve. As refinement loss can change +independently from calibration loss, a lower Brier score does not necessarily +mean a better calibrated model. + +:class:`CalibratedClassifierCV` supports the use of two 'calibration' +regressors: 'sigmoid' and 'isotonic'. + +Sigmoid +^^^^^^^ + +The sigmoid regressor is based on Platt's logistic model [3]_: + +.. math:: + p(y_i = 1 | f_i) = \frac{1}{1 + \exp(A f_i + B)} + +where :math:`y_i` is the true label of sample :math:`i` and :math:`f_i` +is the output of the un-calibrated classifier for sample :math:`i`. :math:`A` +and :math:`B` are real numbers to be determined when fitting the regressor via +maximum likelihood. + +The sigmoid method assumes the :ref:`calibration curve ` +can be corrected by applying a sigmoid function to the raw predictions. This +assumption has been empirically justified in the case of :ref:`svm` with +common kernel functions on various benchmark datasets in section 2.1 of Platt +1999 [3]_ but does not necessarily hold in general. Additionally, the +logistic model works best if the calibration error is symmetrical, meaning +the classifier output for each binary class is normally distributed with +the same variance [6]_. This is can be a problem for highly imbalanced +classification problems, where outputs do not have equal variance. + +In general this method is most effective when the un-calibrated model is +under-confident and has similar calibration errors for both high and low +outputs. + +Isotonic +^^^^^^^^ + +The 'isotonic' method fits a non-parametric isotonic regressor, which outputs +a step-wise non-decreasing function (see :mod:`sklearn.isotonic`). It +minimizes: + +.. math:: + \sum_{i=1}^{n} (y_i - \hat{f}_i)^2 + +subject to :math:`\hat{f}_i >= \hat{f}_j` whenever +:math:`f_i >= f_j`. :math:`y_i` is the true +label of sample :math:`i` and :math:`\hat{f}_i` is the output of the +calibrated classifier for sample :math:`i` (i.e., the calibrated probability). +This method is more general when compared to 'sigmoid' as the only restriction +is that the mapping function is monotonically increasing. It is thus more +powerful as it can correct any monotonic distortion of the un-calibrated model. +However, it is more prone to overfitting, especially on small datasets [5]_. + +Overall, 'isotonic' will perform as well as or better than 'sigmoid' when +there is enough data (greater than ~ 1000 samples) to avoid overfitting [1]_. + +Multiclass support +^^^^^^^^^^^^^^^^^^ + +Both isotonic and sigmoid regressors only +support 1-dimensional data (e.g., binary classification output) but are +extended for multiclass classification if the `base_estimator` supports +multiclass predictions. For multiclass predictions, +:class:`CalibratedClassifierCV` calibrates for +each class separately in a :ref:`ovr_classification` fashion [4]_. When +predicting +probabilities, the calibrated probabilities for each class are predicted separately. As those probabilities do not necessarily sum to one, a postprocessing is performed to normalize them. -The :func:`sklearn.metrics.brier_score_loss` may be used to evaluate how -well a classifier is calibrated. - .. topic:: Examples: * :ref:`sphx_glr_auto_examples_calibration_plot_calibration_curve.py` @@ -144,15 +216,31 @@ well a classifier is calibrated. .. topic:: References: - .. [1] Predicting Good Probabilities with Supervised Learning, + .. [1] `Predicting Good Probabilities with Supervised Learning + `_, A. Niculescu-Mizil & R. Caruana, ICML 2005 - .. [2] On the combination of forecast probabilities for - consecutive precipitation periods. Wea. Forecasting, 5, 640–650., - Wilks, D. S., 1990a - - .. [3] Probabilistic Outputs for Support Vector Machines and Comparisons - to Regularized Likelihood Methods, J. Platt, (1999) - - .. [4] Transforming Classifier Scores into Accurate Multiclass - Probability Estimates, B. Zadrozny & C. Elkan, (KDD 2002) + .. [2] `On the combination of forecast probabilities for + consecutive precipitation periods. + `_ + Wea. Forecasting, 5, 640–650., Wilks, D. S., 1990a + + .. [3] `Probabilistic Outputs for Support Vector Machines and Comparisons + to Regularized Likelihood Methods. + `_ + J. Platt, (1999) + + .. [4] `Transforming Classifier Scores into Accurate Multiclass + Probability Estimates. + `_ + B. Zadrozny & C. Elkan, (KDD 2002) + + .. [5] `Predicting accurate probabilities with a ranking loss. + `_ + Menon AK, Jiang XJ, Vembu S, Elkan C, Ohno-Machado L. + Proc Int Conf Mach Learn. 2012;2012:703-710 + + .. [6] `Beyond sigmoids: How to obtain well-calibrated probabilities from + binary classifiers with beta calibration + `_ + Kull, M., Silva Filho, T. M., & Flach, P. (2017). \ No newline at end of file