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.. THIS FILE WAS AUTOMATICALLY GENERATED BY SPHINX-GALLERY.
.. TO MAKE CHANGES, EDIT THE SOURCE PYTHON FILE:
.. "auto_examples/feature_selection/plot_select_from_model_diabetes.py"
.. LINE NUMBERS ARE GIVEN BELOW.

.. only:: html

    .. note::
        :class: sphx-glr-download-link-note

        :ref:`Go to the end <sphx_glr_download_auto_examples_feature_selection_plot_select_from_model_diabetes.py>`
        to download the full example code or to run this example in your browser via JupyterLite or Binder.

.. rst-class:: sphx-glr-example-title

.. _sphx_glr_auto_examples_feature_selection_plot_select_from_model_diabetes.py:


============================================
Model-based and sequential feature selection
============================================

This example illustrates and compares two approaches for feature selection:
:class:`~sklearn.feature_selection.SelectFromModel` which is based on feature
importance, and
:class:`~sklearn.feature_selection.SequentialFeatureSelector` which relies
on a greedy approach.

We use the Diabetes dataset, which consists of 10 features collected from 442
diabetes patients.

.. GENERATED FROM PYTHON SOURCE LINES 15-19

.. code-block:: Python


    # Authors: The scikit-learn developers
    # SPDX-License-Identifier: BSD-3-Clause








.. GENERATED FROM PYTHON SOURCE LINES 20-25

Loading the data
----------------

We first load the diabetes dataset which is available from within
scikit-learn, and print its description:

.. GENERATED FROM PYTHON SOURCE LINES 25-31

.. code-block:: Python

    from sklearn.datasets import load_diabetes

    diabetes = load_diabetes()
    X, y = diabetes.data, diabetes.target
    print(diabetes.DESCR)





.. rst-class:: sphx-glr-script-out

 .. code-block:: none

    .. _diabetes_dataset:

    Diabetes dataset
    ----------------

    Ten baseline variables, age, sex, body mass index, average blood
    pressure, and six blood serum measurements were obtained for each of n =
    442 diabetes patients, as well as the response of interest, a
    quantitative measure of disease progression one year after baseline.

    **Data Set Characteristics:**

    :Number of Instances: 442

    :Number of Attributes: First 10 columns are numeric predictive values

    :Target: Column 11 is a quantitative measure of disease progression one year after baseline

    :Attribute Information:
        - age     age in years
        - sex
        - bmi     body mass index
        - bp      average blood pressure
        - s1      tc, total serum cholesterol
        - s2      ldl, low-density lipoproteins
        - s3      hdl, high-density lipoproteins
        - s4      tch, total cholesterol / HDL
        - s5      ltg, possibly log of serum triglycerides level
        - s6      glu, blood sugar level

    Note: Each of these 10 feature variables have been mean centered and scaled by the standard deviation times the square root of `n_samples` (i.e. the sum of squares of each column totals 1).

    Source URL:
    https://www4.stat.ncsu.edu/~boos/var.select/diabetes.html

    For more information see:
    Bradley Efron, Trevor Hastie, Iain Johnstone and Robert Tibshirani (2004) "Least Angle Regression," Annals of Statistics (with discussion), 407-499.
    (https://web.stanford.edu/~hastie/Papers/LARS/LeastAngle_2002.pdf)





.. GENERATED FROM PYTHON SOURCE LINES 32-44

Feature importance from coefficients
------------------------------------

To get an idea of the importance of the features, we are going to use the
:class:`~sklearn.linear_model.RidgeCV` estimator. The features with the
highest absolute `coef_` value are considered the most important.
We can observe the coefficients directly without needing to scale them (or
scale the data) because from the description above, we know that the features
were already standardized.
For a more complete example on the interpretations of the coefficients of
linear models, you may refer to
:ref:`sphx_glr_auto_examples_inspection_plot_linear_model_coefficient_interpretation.py`. 

.. GENERATED FROM PYTHON SOURCE LINES 44-56

.. code-block:: Python

    import matplotlib.pyplot as plt
    import numpy as np

    from sklearn.linear_model import RidgeCV

    ridge = RidgeCV(alphas=np.logspace(-6, 6, num=5)).fit(X, y)
    importance = np.abs(ridge.coef_)
    feature_names = np.array(diabetes.feature_names)
    plt.bar(height=importance, x=feature_names)
    plt.title("Feature importances via coefficients")
    plt.show()




.. image-sg:: /auto_examples/feature_selection/images/sphx_glr_plot_select_from_model_diabetes_001.png
   :alt: Feature importances via coefficients
   :srcset: /auto_examples/feature_selection/images/sphx_glr_plot_select_from_model_diabetes_001.png
   :class: sphx-glr-single-img





.. GENERATED FROM PYTHON SOURCE LINES 57-68

Selecting features based on importance
--------------------------------------

Now we want to select the two features which are the most important according
to the coefficients. The :class:`~sklearn.feature_selection.SelectFromModel`
is meant just for that. :class:`~sklearn.feature_selection.SelectFromModel`
accepts a `threshold` parameter and will select the features whose importance
(defined by the coefficients) are above this threshold.

Since we want to select only 2 features, we will set this threshold slightly
above the coefficient of third most important feature.

.. GENERATED FROM PYTHON SOURCE LINES 68-80

.. code-block:: Python

    from time import time

    from sklearn.feature_selection import SelectFromModel

    threshold = np.sort(importance)[-3] + 0.01

    tic = time()
    sfm = SelectFromModel(ridge, threshold=threshold).fit(X, y)
    toc = time()
    print(f"Features selected by SelectFromModel: {feature_names[sfm.get_support()]}")
    print(f"Done in {toc - tic:.3f}s")





.. rst-class:: sphx-glr-script-out

 .. code-block:: none

    Features selected by SelectFromModel: ['s1' 's5']
    Done in 0.002s




.. GENERATED FROM PYTHON SOURCE LINES 81-95

Selecting features with Sequential Feature Selection
----------------------------------------------------

Another way of selecting features is to use
:class:`~sklearn.feature_selection.SequentialFeatureSelector`
(SFS). SFS is a greedy procedure where, at each iteration, we choose the best
new feature to add to our selected features based a cross-validation score.
That is, we start with 0 features and choose the best single feature with the
highest score. The procedure is repeated until we reach the desired number of
selected features.

We can also go in the reverse direction (backward SFS), *i.e.* start with all
the features and greedily choose features to remove one by one. We illustrate
both approaches here.

.. GENERATED FROM PYTHON SOURCE LINES 95-121

.. code-block:: Python


    from sklearn.feature_selection import SequentialFeatureSelector

    tic_fwd = time()
    sfs_forward = SequentialFeatureSelector(
        ridge, n_features_to_select=2, direction="forward"
    ).fit(X, y)
    toc_fwd = time()

    tic_bwd = time()
    sfs_backward = SequentialFeatureSelector(
        ridge, n_features_to_select=2, direction="backward"
    ).fit(X, y)
    toc_bwd = time()

    print(
        "Features selected by forward sequential selection: "
        f"{feature_names[sfs_forward.get_support()]}"
    )
    print(f"Done in {toc_fwd - tic_fwd:.3f}s")
    print(
        "Features selected by backward sequential selection: "
        f"{feature_names[sfs_backward.get_support()]}"
    )
    print(f"Done in {toc_bwd - tic_bwd:.3f}s")





.. rst-class:: sphx-glr-script-out

 .. code-block:: none

    Features selected by forward sequential selection: ['bmi' 's5']
    Done in 0.254s
    Features selected by backward sequential selection: ['bmi' 's5']
    Done in 0.713s




.. GENERATED FROM PYTHON SOURCE LINES 122-153

Interestingly, forward and backward selection have selected the same set of
features. In general, this isn't the case and the two methods would lead to
different results.

We also note that the features selected by SFS differ from those selected by
feature importance: SFS selects `bmi` instead of `s1`. This does sound
reasonable though, since `bmi` corresponds to the third most important
feature according to the coefficients. It is quite remarkable considering
that SFS makes no use of the coefficients at all.

To finish with, we should note that
:class:`~sklearn.feature_selection.SelectFromModel` is significantly faster
than SFS. Indeed, :class:`~sklearn.feature_selection.SelectFromModel` only
needs to fit a model once, while SFS needs to cross-validate many different
models for each of the iterations. SFS however works with any model, while
:class:`~sklearn.feature_selection.SelectFromModel` requires the underlying
estimator to expose a `coef_` attribute or a `feature_importances_`
attribute. The forward SFS is faster than the backward SFS because it only
needs to perform `n_features_to_select = 2` iterations, while the backward
SFS needs to perform `n_features - n_features_to_select = 8` iterations.

Using negative tolerance values
-------------------------------

:class:`~sklearn.feature_selection.SequentialFeatureSelector` can be used
to remove features present in the dataset and return a
smaller subset of the original features with `direction="backward"`
and a negative value of `tol`.

We begin by loading the Breast Cancer dataset, consisting of 30 different
features and 569 samples.

.. GENERATED FROM PYTHON SOURCE LINES 153-162

.. code-block:: Python

    import numpy as np

    from sklearn.datasets import load_breast_cancer

    breast_cancer_data = load_breast_cancer()
    X, y = breast_cancer_data.data, breast_cancer_data.target
    feature_names = np.array(breast_cancer_data.feature_names)
    print(breast_cancer_data.DESCR)





.. rst-class:: sphx-glr-script-out

 .. code-block:: none

    .. _breast_cancer_dataset:

    Breast cancer Wisconsin (diagnostic) dataset
    --------------------------------------------

    **Data Set Characteristics:**

    :Number of Instances: 569

    :Number of Attributes: 30 numeric, predictive attributes and the class

    :Attribute Information:
        - radius (mean of distances from center to points on the perimeter)
        - texture (standard deviation of gray-scale values)
        - perimeter
        - area
        - smoothness (local variation in radius lengths)
        - compactness (perimeter^2 / area - 1.0)
        - concavity (severity of concave portions of the contour)
        - concave points (number of concave portions of the contour)
        - symmetry
        - fractal dimension ("coastline approximation" - 1)

        The mean, standard error, and "worst" or largest (mean of the three
        worst/largest values) of these features were computed for each image,
        resulting in 30 features.  For instance, field 0 is Mean Radius, field
        10 is Radius SE, field 20 is Worst Radius.

        - class:
                - WDBC-Malignant
                - WDBC-Benign

    :Summary Statistics:

    ===================================== ====== ======
                                            Min    Max
    ===================================== ====== ======
    radius (mean):                        6.981  28.11
    texture (mean):                       9.71   39.28
    perimeter (mean):                     43.79  188.5
    area (mean):                          143.5  2501.0
    smoothness (mean):                    0.053  0.163
    compactness (mean):                   0.019  0.345
    concavity (mean):                     0.0    0.427
    concave points (mean):                0.0    0.201
    symmetry (mean):                      0.106  0.304
    fractal dimension (mean):             0.05   0.097
    radius (standard error):              0.112  2.873
    texture (standard error):             0.36   4.885
    perimeter (standard error):           0.757  21.98
    area (standard error):                6.802  542.2
    smoothness (standard error):          0.002  0.031
    compactness (standard error):         0.002  0.135
    concavity (standard error):           0.0    0.396
    concave points (standard error):      0.0    0.053
    symmetry (standard error):            0.008  0.079
    fractal dimension (standard error):   0.001  0.03
    radius (worst):                       7.93   36.04
    texture (worst):                      12.02  49.54
    perimeter (worst):                    50.41  251.2
    area (worst):                         185.2  4254.0
    smoothness (worst):                   0.071  0.223
    compactness (worst):                  0.027  1.058
    concavity (worst):                    0.0    1.252
    concave points (worst):               0.0    0.291
    symmetry (worst):                     0.156  0.664
    fractal dimension (worst):            0.055  0.208
    ===================================== ====== ======

    :Missing Attribute Values: None

    :Class Distribution: 212 - Malignant, 357 - Benign

    :Creator:  Dr. William H. Wolberg, W. Nick Street, Olvi L. Mangasarian

    :Donor: Nick Street

    :Date: November, 1995

    This is a copy of UCI ML Breast Cancer Wisconsin (Diagnostic) datasets.
    https://goo.gl/U2Uwz2

    Features are computed from a digitized image of a fine needle
    aspirate (FNA) of a breast mass.  They describe
    characteristics of the cell nuclei present in the image.

    Separating plane described above was obtained using
    Multisurface Method-Tree (MSM-T) [K. P. Bennett, "Decision Tree
    Construction Via Linear Programming." Proceedings of the 4th
    Midwest Artificial Intelligence and Cognitive Science Society,
    pp. 97-101, 1992], a classification method which uses linear
    programming to construct a decision tree.  Relevant features
    were selected using an exhaustive search in the space of 1-4
    features and 1-3 separating planes.

    The actual linear program used to obtain the separating plane
    in the 3-dimensional space is that described in:
    [K. P. Bennett and O. L. Mangasarian: "Robust Linear
    Programming Discrimination of Two Linearly Inseparable Sets",
    Optimization Methods and Software 1, 1992, 23-34].

    This database is also available through the UW CS ftp server:

    ftp ftp.cs.wisc.edu
    cd math-prog/cpo-dataset/machine-learn/WDBC/

    .. dropdown:: References

      - W.N. Street, W.H. Wolberg and O.L. Mangasarian. Nuclear feature extraction
        for breast tumor diagnosis. IS&T/SPIE 1993 International Symposium on
        Electronic Imaging: Science and Technology, volume 1905, pages 861-870,
        San Jose, CA, 1993.
      - O.L. Mangasarian, W.N. Street and W.H. Wolberg. Breast cancer diagnosis and
        prognosis via linear programming. Operations Research, 43(4), pages 570-577,
        July-August 1995.
      - W.H. Wolberg, W.N. Street, and O.L. Mangasarian. Machine learning techniques
        to diagnose breast cancer from fine-needle aspirates. Cancer Letters 77 (1994)
        163-171.





.. GENERATED FROM PYTHON SOURCE LINES 163-166

We will make use of the :class:`~sklearn.linear_model.LogisticRegression`
estimator with :class:`~sklearn.feature_selection.SequentialFeatureSelector`
to perform the feature selection.

.. GENERATED FROM PYTHON SOURCE LINES 166-189

.. code-block:: Python

    from sklearn.linear_model import LogisticRegression
    from sklearn.metrics import roc_auc_score
    from sklearn.pipeline import make_pipeline
    from sklearn.preprocessing import StandardScaler

    for tol in [-1e-2, -1e-3, -1e-4]:
        start = time()
        feature_selector = SequentialFeatureSelector(
            LogisticRegression(),
            n_features_to_select="auto",
            direction="backward",
            scoring="roc_auc",
            tol=tol,
            n_jobs=2,
        )
        model = make_pipeline(StandardScaler(), feature_selector, LogisticRegression())
        model.fit(X, y)
        end = time()
        print(f"\ntol: {tol}")
        print(f"Features selected: {feature_names[model[1].get_support()]}")
        print(f"ROC AUC score: {roc_auc_score(y, model.predict_proba(X)[:, 1]):.3f}")
        print(f"Done in {end - start:.3f}s")





.. rst-class:: sphx-glr-script-out

 .. code-block:: none


    tol: -0.01
    Features selected: ['worst perimeter']
    ROC AUC score: 0.975
    Done in 22.646s

    tol: -0.001
    Features selected: ['radius error' 'fractal dimension error' 'worst texture'
     'worst perimeter' 'worst concave points']
    ROC AUC score: 0.997
    Done in 22.174s

    tol: -0.0001
    Features selected: ['mean compactness' 'mean concavity' 'mean concave points' 'radius error'
     'area error' 'concave points error' 'symmetry error'
     'fractal dimension error' 'worst texture' 'worst perimeter' 'worst area'
     'worst concave points' 'worst symmetry']
    ROC AUC score: 0.998
    Done in 19.919s




.. GENERATED FROM PYTHON SOURCE LINES 190-193

We can see that the number of features selected tend to increase as negative
values of `tol` approach to zero. The time taken for feature selection also
decreases as the values of `tol` come closer to zero.


.. rst-class:: sphx-glr-timing

   **Total running time of the script:** (1 minutes 5.806 seconds)


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