.. currentmodule:: sklearn.model_selection

.. _TunedThresholdClassifierCV:

==================================================
Tuning the decision threshold for class prediction
==================================================

Classification is best divided into two parts:

* the statistical problem of learning a model to predict, ideally, class probabilities;
* the decision problem to take concrete action based on those probability predictions.

Let's take a straightforward example related to weather forecasting: the first point is
related to answering "what is the chance that it will rain tomorrow?" while the second
point is related to answering "should I take an umbrella tomorrow?".

When it comes to the scikit-learn API, the first point is addressed providing scores
using :term:`predict_proba` or :term:`decision_function`. The former returns conditional
probability estimates :math:`P(y|X)` for each class, while the latter returns a decision
score for each class.

The decision corresponding to the labels are obtained with :term:`predict`. In binary
classification, a decision rule or action is then defined by thresholding the scores,
leading to the prediction of a single class label for each sample. For binary
classification in scikit-learn, class labels predictions are obtained by hard-coded
cut-off rules: a positive class is predicted when the conditional probability
:math:`P(y|X)` is greater than 0.5 (obtained with :term:`predict_proba`) or if the
decision score is greater than 0 (obtained with :term:`decision_function`).

Here, we show an example that illustrates the relation between conditional
probability estimates :math:`P(y|X)` and class labels::

    >>> from sklearn.datasets import make_classification
    >>> from sklearn.tree import DecisionTreeClassifier
    >>> X, y = make_classification(random_state=0)
    >>> classifier = DecisionTreeClassifier(max_depth=2, random_state=0).fit(X, y)
    >>> classifier.predict_proba(X[:4])
    array([[0.94     , 0.06     ],
           [0.94     , 0.06     ],
           [0.0416..., 0.9583...],
           [0.0416..., 0.9583...]])
    >>> classifier.predict(X[:4])
    array([0, 0, 1, 1])

While these hard-coded rules might at first seem reasonable as default behavior, they
are most certainly not ideal for most use cases. Let's illustrate with an example.

Consider a scenario where a predictive model is being deployed to assist
physicians in detecting tumors. In this setting, physicians will most likely be
interested in identifying all patients with cancer and not missing anyone with cancer so
that they can provide them with the right treatment. In other words, physicians
prioritize achieving a high recall rate. This emphasis on recall comes, of course, with
the trade-off of potentially more false-positive predictions, reducing the precision of
the model. That is a risk physicians are willing to take because the cost of a missed
cancer is much higher than the cost of further diagnostic tests. Consequently, when it
comes to deciding whether to classify a patient as having cancer or not, it may be more
beneficial to classify them as positive for cancer when the conditional probability
estimate is much lower than 0.5.

Post-tuning the decision threshold
==================================

One solution to address the problem stated in the introduction is to tune the decision
threshold of the classifier once the model has been trained. The
:class:`~sklearn.model_selection.TunedThresholdClassifierCV` tunes this threshold using
an internal cross-validation. The optimum threshold is chosen to maximize a given
metric.

The following image illustrates the tuning of the decision threshold for a gradient
boosting classifier. While the vanilla and tuned classifiers provide the same
:term:`predict_proba` outputs and thus the same Receiver Operating Characteristic (ROC)
and Precision-Recall curves, the class label predictions differ because of the tuned
decision threshold. The vanilla classifier predicts the class of interest for a
conditional probability greater than 0.5 while the tuned classifier predicts the class
of interest for a very low probability (around 0.02). This decision threshold optimizes
a utility metric defined by the business (in this case an insurance company).

.. figure:: ../auto_examples/model_selection/images/sphx_glr_plot_cost_sensitive_learning_002.png
   :target: ../auto_examples/model_selection/plot_cost_sensitive_learning.html
   :align: center

Options to tune the decision threshold
--------------------------------------

The decision threshold can be tuned through different strategies controlled by the
parameter `scoring`.

One way to tune the threshold is by maximizing a pre-defined scikit-learn metric. These
metrics can be found by calling the function :func:`~sklearn.metrics.get_scorer_names`.
By default, the balanced accuracy is the metric used but be aware that one should choose
a meaningful metric for their use case.

.. note::

    It is important to notice that these metrics come with default parameters, notably
    the label of the class of interest (i.e. `pos_label`). Thus, if this label is not
    the right one for your application, you need to define a scorer and pass the right
    `pos_label` (and additional parameters) using the
    :func:`~sklearn.metrics.make_scorer`. Refer to :ref:`scoring` to get
    information to define your own scoring function. For instance, we show how to pass
    the information to the scorer that the label of interest is `0` when maximizing the
    :func:`~sklearn.metrics.f1_score`::

        >>> from sklearn.linear_model import LogisticRegression
        >>> from sklearn.model_selection import TunedThresholdClassifierCV
        >>> from sklearn.metrics import make_scorer, f1_score
        >>> X, y = make_classification(
        ...   n_samples=1_000, weights=[0.1, 0.9], random_state=0)
        >>> pos_label = 0
        >>> scorer = make_scorer(f1_score, pos_label=pos_label)
        >>> base_model = LogisticRegression()
        >>> model = TunedThresholdClassifierCV(base_model, scoring=scorer)
        >>> scorer(model.fit(X, y), X, y)
        0.88...
        >>> # compare it with the internal score found by cross-validation
        >>> model.best_score_
        0.86...

Important notes regarding the internal cross-validation
-------------------------------------------------------

By default :class:`~sklearn.model_selection.TunedThresholdClassifierCV` uses a 5-fold
stratified cross-validation to tune the decision threshold. The parameter `cv` allows to
control the cross-validation strategy. It is possible to bypass cross-validation by
setting `cv="prefit"` and providing a fitted classifier. In this case, the decision
threshold is tuned on the data provided to the `fit` method.

However, you should be extremely careful when using this option. You should never use
the same data for training the classifier and tuning the decision threshold due to the
risk of overfitting. Refer to the following example section for more details (cf.
:ref:`TunedThresholdClassifierCV_no_cv`). If you have limited resources, consider using
a float number for `cv` to limit to an internal single train-test split.

The option `cv="prefit"` should only be used when the provided classifier was already
trained, and you just want to find the best decision threshold using a new validation
set.

.. _FixedThresholdClassifier:

Manually setting the decision threshold
---------------------------------------

The previous sections discussed strategies to find an optimal decision threshold. It is
also possible to manually set the decision threshold using the class
:class:`~sklearn.model_selection.FixedThresholdClassifier`.

Examples
--------

- See the example entitled
  :ref:`sphx_glr_auto_examples_model_selection_plot_tuned_decision_threshold.py`,
  to get insights on the post-tuning of the decision threshold.
- See the example entitled
  :ref:`sphx_glr_auto_examples_model_selection_plot_cost_sensitive_learning.py`,
  to learn about cost-sensitive learning and decision threshold tuning.