Metadata-Version: 2.1
Name: scikit-activeml
Version: 0.2.3
Summary: Our package scikit-activeml is a Python library for active learning on top of SciPy and scikit-learn.
Home-page: https://github.com/scikit-activeml/scikit-activeml
Author: Daniel Kottke
Author-email: daniel.kottke@uni-kassel.de
License: BSD 3-Clause License
Keywords: active learning,machine learning,semi-supervised learning,data mining,pattern recognition,artificial intelligence
Platform: UNKNOWN
Classifier: Intended Audience :: Science/Research
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: BSD License
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.7
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3.9
Classifier: Operating System :: OS Independent
Requires-Python: >=3.7
Description-Content-Type: text/x-rst
License-File: LICENSE.txt

.. intro_start

|Doc|_ |Codecov|_ |PythonVersion|_ |PyPi|_ |Paper|_

.. |Doc| image:: https://img.shields.io/badge/docs-latest-green
.. _Doc: https://scikit-activeml.github.io/scikit-activeml-docs/

.. |Codecov| image:: https://codecov.io/gh/scikit-activeml/scikit-activeml/branch/master/graph/badge.svg
.. _Codecov: https://app.codecov.io/gh/scikit-activeml/scikit-activeml

.. |PythonVersion| image:: https://img.shields.io/badge/python-3.7%20%7C%203.8%20%7C%203.9-blue
.. _PythonVersion: https://img.shields.io/badge/python-3.7%20%7C%203.8%20%7C%203.9-blue

.. |PyPi| image:: https://badge.fury.io/py/scikit-activeml.svg
.. _PyPi: https://badge.fury.io/py/scikit-activeml

.. |Paper| image:: https://img.shields.io/badge/paper-10.20944/preprints202103.0194.v1-blue
.. _Paper: https://www.preprints.org/manuscript/202103.0194/v1

|

.. image:: https://raw.githubusercontent.com/scikit-activeml/scikit-activeml/master/docs/logos/scikit-activeml-logo.png
   :width: 200

|

Machine learning applications often need large amounts of training data to
perform well. Whereas unlabeled data can be easily gathered, the labeling process
is difficult, time-consuming, or expensive in most applications. Active learning can help solve
this problem by querying labels for those data samples that will improve the performance
the most. Thereby, the goal is that the learning algorithm performs sufficiently well with
fewer labels

With this goal in mind, **scikit-activeml** has been developed as a Python module for active learning
on top of `scikit-learn <https://scikit-learn.org/stable/>`_. The project was initiated in 2020 by the
`Intelligent Embedded Systems Group <https://www.uni-kassel.de/eecs/en/sections/intelligent-embedded-systems/home>`_
at the University of Kassel and is distributed under the `3-Clause BSD licence
<https://github.com/scikit-activeml/scikit-activeml/blob/master/LICENSE.txt>`_.

.. intro_end

.. overview_start

Overview
========

Our philosophy is to extend the ``sklearn`` eco-system with the most relevant
query strategies for active learning and to implement tools for working with partially
unlabeled data. An overview of our repository's structure is given in the image below.
Each node represents a class or interface. The arrows illustrate the inheritance
hierarchy among them. The functionality of a dashed node is not yet available in our library.

.. image:: https://raw.githubusercontent.com/scikit-activeml/scikit-activeml/master/docs/logos/scikit-activeml-structure.png
   :width: 1000

In our package ``skactiveml``, there three major components, i.e., ``SkactivemlClassifier``,
``QueryStrategy``, and the not yet supported ``SkactivemlRegressor``.
The classifier and regressor modules are necessary to deal with partially unlabeled
data and to implement active-learning specific estimators. This way, an active learning
cycle can be easily implemented to start with zero initial labels. Regarding the
active learning query strategies, we currently differ between
the pool-based (a large pool of unlabeled samples is available) and stream-based
(unlabeled samples arrive sequentially, i.e., as a stream) paradigm.
On top of both paradigms, we also distinguish the single- and multi-annotator
setting. In the latter setting, multiple error-prone annotators are queried
to provide labels. As a result, an active learning query strategy not only decides
which samples but also which annotators should be queried.

.. overview_end

.. user_installation_start

User Installation
=================

The easiest way of installing scikit-activeml is using ``pip``:

::

    pip install -U scikit-activeml

.. install_end

.. examples_start

Examples
========
In the following, there are two simple examples illustrating the straightforwardness
of implementing active learning cycles with our Python package ``skactiveml``.
For more in-depth examples, we refer to our
`tutorial section <https://scikit-activeml.github.io/scikit-activeml-docs/>`_ offering
a broad overview of different use-cases:

- `pool-based active learning -- getting started <https://github.com/scikit-activeml/scikit-activeml/blob/master/tutorials/00_pool_getting_started.ipynb>`_,
- `deep pool-based active learning -- scikit-activeml with skorch <https://github.com/scikit-activeml/scikit-activeml/blob/master/tutorials/01_deep_pool_al_with_skorch.ipynb>`_,
- `multi-annotator pool-based active learning -- getting started <https://github.com/scikit-activeml/scikit-activeml/blob/master/tutorials/10_multiple_annotators_getting_started.ipynb>`_,
- `stream-based active learning -- getting started <https://github.com/scikit-activeml/scikit-activeml/blob/master/tutorials/20_stream_getting_started.ipynb>`_,
- and `batch stream-based active learning with pool-based query strategies <https://github.com/scikit-activeml/scikit-activeml/blob/master/tutorials/21_stream_batch_with_pool_al.ipynb>`_.

Pool-based Active Learning
##########################

The following code implements an active learning cycle with 20 iterations using a Gaussian process
classifier and uncertainty sampling. To use other classifiers, you can simply wrap classifiers from
``sklearn`` or use classifiers provided by ``skactiveml``. Note that the main difficulty using
active learning with ``sklearn`` is the ability to handle unlabeled data, which we denote as a specific value
(``MISSING_LABEL``) in the label vector ``y``. More query strategies can be found in the documentation.

.. code-block:: python
    
    import numpy as np
    import matplotlib.pyplot as plt
    from sklearn.gaussian_process import GaussianProcessClassifier
    from sklearn.datasets import make_blobs
    from skactiveml.pool import UncertaintySampling
    from skactiveml.utils import unlabeled_indices, MISSING_LABEL
    from skactiveml.classifier import SklearnClassifier
    from skactiveml.visualization import plot_decision_boundary, plot_utilities

    # Generate data set.
    X, y_true = make_blobs(n_samples=200, centers=4, random_state=0)
    y = np.full(shape=y_true.shape, fill_value=MISSING_LABEL)

    # GaussianProcessClassifier needs initial training data otherwise a warning will
    # be raised by SklearnClassifier. Therefore, the first 10 instances are used as
    # training data.
    y[:10] = y_true[:10]

    # Create classifier and query strategy.
    clf = SklearnClassifier(GaussianProcessClassifier(random_state=0),classes=np.unique(y_true), random_state=0)
    qs = UncertaintySampling(method='entropy')

    # Execute active learning cycle.
    n_cycles = 20
    for c in range(n_cycles):
        query_idx = qs.query(X=X, y=y, clf=clf)
        y[query_idx] = y_true[query_idx]

    # Fit final classifier.
    clf.fit(X, y)

    # Visualize resulting classifier and current utilities.
    bound = [[min(X[:, 0]), min(X[:, 1])], [max(X[:, 0]), max(X[:, 1])]]
    unlbld_idx = unlabeled_indices(y)
    fig, ax = plt.subplots(1, 1, figsize=(8, 8))
    ax.set_title(f'Accuracy score: {clf.score(X,y_true)}', fontsize=15)
    plot_utilities(qs, X=X, y=y, clf=clf, feature_bound=bound, ax=ax)
    plot_decision_boundary(clf, feature_bound=bound, confidence=0.6)
    plt.scatter(X[unlbld_idx,0], X[unlbld_idx,1], c='gray')
    plt.scatter(X[:,0], X[:,1], c=y, cmap='jet')
    plt.show()

As output of this code snippet, we obtain the actively trained Gaussian process classifier
including a visualization of its decision boundary and the sample utilities computed with
uncertainty sampling.

.. image:: https://raw.githubusercontent.com/scikit-activeml/scikit-activeml/master/docs/logos/pal-example-output.png
   :width: 400

Stream-based Active Learning
############################

The following code implements an active learning cycle with 200 data points and
the default budget of 10% using a pwc classifier and split uncertainty sampling. 
Like in the pool-based example you can wrap other classifiers from ``sklearn``,
``sklearn`` compatible classifiers or like the example classifiers provided by ``skactiveml``.

.. code-block:: python

    import numpy as np
    import matplotlib.pyplot as plt
    from scipy.ndimage import gaussian_filter1d
    from sklearn.datasets import make_blobs
    from skactiveml.classifier import ParzenWindowClassifier
    from skactiveml.stream import Split
    from skactiveml.utils import MISSING_LABEL

    # Generate data set.
    X, y_true = make_blobs(n_samples=200, centers=4, random_state=0)

    # Create classifier and query strategy.
    clf = ParzenWindowClassifier(random_state=0, classes=np.unique(y_true))
    qs = Split(random_state=0)

    # Initializing the training data as an empty array.
    X_train = []
    y_train = []

    # Initialize the list that stores the result of the classifier's prediction.
    correct_classifications = []

    # Execute active learning cycle.
    for x_t, y_t in zip(X, y_true):
        X_cand = x_t.reshape([1, -1])
        y_cand = y_t
        clf.fit(X_train, y_train)
        correct_classifications.append(clf.predict(X_cand)[0] == y_cand)
        sampled_indices = qs.query(candidates=X_cand, clf=clf)
        qs.update(candidates=X_cand, queried_indices=sampled_indices)
        X_train.append(x_t)
        y_train.append(y_cand if len(sampled_indices) > 0 else MISSING_LABEL)

    # Plot the classifier's learning accuracy.
    fig, ax = plt.subplots(1, 1, figsize=(8, 6))
    ax.set_title(f'Learning curve', fontsize=15)
    ax.set_xlabel('number of learning cycles')
    ax.set_ylabel('accuracy')
    ax.plot(gaussian_filter1d(np.array(correct_classifications, dtype=float), 4))
    plt.show()

As output of this code snippet, we obtain the actively trained pwc classifier incuding
a visualization of its accuracy over the 200 samples.

.. image:: https://raw.githubusercontent.com/scikit-activeml/scikit-activeml/master/docs/logos/stream-example-output.png
   :width: 400

.. examples_end

Citing
======
If you use ``scikit-activeml`` in one of your research projects and find it helpful,
please cite the following:

::

    @article{skactiveml2021,
        title={scikitactiveml: {A} {L}ibrary and {T}oolbox for {A}ctive {L}}earning {A}lgorithms},
        author={Daniel Kottke and Marek Herde and Tuan Pham Minh and Alexander Benz and Pascal Mergard and Atal Roghman and Christoph Sandrock and Bernhard Sick},
        journal={Preprints},
        doi={10.20944/preprints202103.0194.v1},
        year={2021},
        url={https://github.com/scikit-activeml/scikit-activeml}
    }

