Metadata-Version: 2.1
Name: prince
Version: 0.3.7
Summary: Statistical factor analysis in Python
Home-page: https://github.com/MaxHalford/prince
Author: Max Halford
Author-email: maxhalford25@gmail.com
License: MIT
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        ## Introduction
        
        Prince is a library for doing [factor analysis](https://www.wikiwand.com/en/Factor_analysis). This includes a variety of methods including [principal component analysis (PCA)](https://www.wikiwand.com/en/Principal_component_analysis) and [correspondence analysis (CA)](https://www.wikiwand.com/en/Correspondence_analysis). The goal is to provide an efficient implementation for each algorithm along with a nice API.
        
        ## Installation
        
        :warning: Prince is only compatible with Python 3.
        
        :snake: Although it isn't a requirement, using [Anaconda](https://www.continuum.io/downloads) is highly recommended.
        
        **Via PyPI**
        
        ```sh
        >>> pip install prince  # doctest: +SKIP
        ```
        
        **Via GitHub for the latest development version**
        
        ```sh
        >>> pip install git+https://github.com/MaxHalford/Prince  # doctest: +SKIP
        ```
        
        Prince doesn't have any extra dependencies apart from the usual suspects (`sklearn`, `pandas`, `matplotlib`) which are included with Anaconda.
        
        ## Usage
        
        ### Guidelines
        
        Each estimator provided by `prince` extends scikit-learn's `TransformerMixin`. This means that each estimator implements a `fit` and a `transform` method which makes them usable in a transformation pipeline. The `fit` method is actually an alias for the `row_principal_components` method which returns the row principal components. However you also can also access the column principal components with the `column_principal_components`.
        
        Under the hood Prince uses a [randomised version of SVD](https://research.fb.com/fast-randomized-svd/). This is much faster than using the more commonly full approach. However the results may have a small inherent randomness. For most applications this doesn't matter and you shouldn't have to worry about it. However if you want reproducible results then you should set the `random_state` parameter.
        
        The randomised version of SVD is an iterative method. Because each of Prince's algorithms use SVD, they all possess a `n_iter` parameter which controls the number of iterations used for computing the SVD. On the one hand the higher `n_iter` is the more precise the results will be. On the other hand increasing `n_iter` increases the computation time. In general the algorithm converges very quickly so using a low `n_iter` (which is the default behaviour) is recommended.
        
        The following papers give a good overview of the field of factor analysis if you want to go deeper:
        
        - [A Tutorial on Principal Component Analysis](https://arxiv.org/pdf/1404.1100.pdf)
        - [Theory of Correspondence Analysis](http://statmath.wu.ac.at/courses/CAandRelMeth/caipA.pdf)
        - [Finding structure with randomness: Probabilistic algorithms for constructing approximate matrix decompositions](https://arxiv.org/pdf/0909.4061.pdf)
        - [Computation of Multiple Correspondence Analysis, with code in R](https://core.ac.uk/download/pdf/6591520.pdf)
        - [Singular Value Decomposition Tutorial](https://davetang.org/file/Singular_Value_Decomposition_Tutorial.pdf)
        
        ### Principal component analysis (PCA)
        
        If you're using PCA it is assumed you have a dataframe consisting of numerical continuous variables. In this example we're going to be using the [Iris flower dataset](https://www.wikiwand.com/en/Iris_flower_data_set).
        
        ```python
        >>> import pandas as pd
        >>> import prince
        >>> from sklearn import datasets
        
        >>> X, y = datasets.load_iris(return_X_y=True)
        >>> X = pd.DataFrame(data=X, columns=['Sepal length', 'Sepal width', 'Petal length', 'Sepal length'])
        >>> y = pd.Series(y).map({0: 'Setosa', 1: 'Versicolor', 2: 'Virginica'})
        >>> X.head()
           Sepal length  Sepal width  Petal length  Sepal length
        0           5.1          3.5           1.4           0.2
        1           4.9          3.0           1.4           0.2
        2           4.7          3.2           1.3           0.2
        3           4.6          3.1           1.5           0.2
        4           5.0          3.6           1.4           0.2
        
        ```
        
        The `PCA` class implements scikit-learn's `fit`/`transform` API. It's parameters have to passed at initialisation before calling the `fit` method.
        
        ```python
        >>> pca = prince.PCA(
        ...     n_components=2,
        ...     n_iter=3,
        ...     rescale_with_mean=True,
        ...     rescale_with_std=True,
        ...     copy=True,
        ...     engine='auto',
        ...     random_state=42
        ... )
        >>> pca = pca.fit(X)
        
        ```
        
        The available parameters are:
        
        - `n_components`: the number of components that are computed. You only need two if your intention is to make a chart.
        - `n_iter`: the number of iterations used for computing the SVD
        - `rescale_with_mean`: whether to substract each column's mean
        - `rescale_with_std`: whether to divide each column by it's standard deviation
        - `copy`: if `False` then the computations will be done inplace which can have possible side-effects on the input data
        - `engine`: what SVD engine to use (should be one of `['auto', 'fbpca', 'sklearn']`)
        - `random_state`: controls the randomness of the SVD results.
        
        Once the `PCA` has been fitted, it can be used to extract the row principal coordinates as so:
        
        ```python
        >>> pca.transform(X).head()  # Same as pca.row_principal_coordinates(X).head()
                  0         1
        0 -2.264542  0.505704
        1 -2.086426 -0.655405
        2 -2.367950 -0.318477
        3 -2.304197 -0.575368
        4 -2.388777  0.674767
        
        ```
        
        Each column stands for a principal component whilst each row stands a row in the original dataset. You can display these projections with the `plot_row_principal_coordinates` method:
        
        ```python
        >>> ax = pca.plot_row_principal_coordinates(
        ...     X,
        ...     ax=None,
        ...     figsize=(6, 6),
        ...     x_component=0,
        ...     y_component=1,
        ...     labels=None,
        ...     group_labels=y,
        ...     ellipse_outline=False,
        ...     ellipse_fill=True,
        ...     show_points=True
        ... )
        >>> ax.get_figure().savefig('images/pca_row_principal_coordinates.png')
        
        ```
        
        <div align="center">
          <img src="images/pca_row_principal_coordinates.png" />
        </div>
        
        Each principal component explains part of the underlying of the distribution. You can see by how much by using the accessing the `explained_inertia_` property:
        
        ```python
        >>> pca.explained_inertia_  # doctest: +ELLIPSIS
        [0.727704..., 0.230305...]
        
        ```
        
        The explained inertia represents the percentage of the inertia each principal component contributes. It sums up to 1 if the `n_components` property is equal to the number of columns in the original dataset. you The explained inertia is obtained by dividing the eigenvalues obtained with the SVD by the total inertia, both of which are also accessible.
        
        ```python
        >>> pca.eigenvalues_  # doctest: +ELLIPSIS
        [436.622712..., 138.183139...]
        
        >>> pca.total_inertia_
        600.0
        
        >>> pca.explained_inertia_
        [0.727704..., 0.230305...]
        
        ```
        
        You can also obtain the correlations between the original variables and the principal components.
        
        ```python
        >>> pca.column_correlations(X)
                             0         1
        Sepal length  0.891224  0.357352
        Sepal width  -0.449313  0.888351
        Petal length  0.991684  0.020247
        Sepal length  0.964996  0.062786
        
        ```
        
        You may also want to know how much each observation contributes to each principal component. This can be done with the `row_component_contributions` method.
        
        ```python
        >>> pca.row_component_contributions(X).head()
                  0         1
        0  0.011745  0.001851
        1  0.009970  0.003109
        2  0.012842  0.000734
        3  0.012160  0.002396
        4  0.013069  0.003295
        
        ```
        
        ### Correspondence analysis (CA)
        
        You should be using correspondence analysis when you want to analyse a contingency table. In other words you want to analyse the dependencies between two categorical variables. The following example comes from section 17.2.3 of [this textbook](http://ce.aut.ac.ir/~shiry/lecture/Advanced%20Machine%20Learning/Manifold_Modern_Multivariate%20Statistical%20Techniques%20-%20Regres.pdf). It shows the number of occurrences between different hair and eye colors.
        
        ```python
        import pandas as pd
        
        >>> pd.set_option('display.float_format', lambda x: '{:.6f}'.format(x))
        >>> X = pd.DataFrame(
        ...    data=[
        ...        [326, 38, 241, 110, 3],
        ...        [688, 116, 584, 188, 4],
        ...        [343, 84, 909, 412, 26],
        ...        [98, 48, 403, 681, 85]
        ...    ],
        ...    columns=pd.Series(['Fair', 'Red', 'Medium', 'Dark', 'Black']),
        ...    index=pd.Series(['Blue', 'Light', 'Medium', 'Dark'])
        ... )
        >>> X
                Fair  Red  Medium  Dark  Black
        Blue     326   38     241   110      3
        Light    688  116     584   188      4
        Medium   343   84     909   412     26
        Dark      98   48     403   681     85
        
        ```
        
        Unlike the `PCA` class, the `CA` only exposes scikit-learn's `fit` method.
        
        ```python
        >>> import prince
        >>> ca = prince.CA(
        ...     n_components=2,
        ...     n_iter=3,
        ...     copy=True,
        ...     engine='auto',
        ...     random_state=42
        ... )
        >>> X.columns.rename('Hair color', inplace=True)
        >>> X.index.rename('Eye color', inplace=True)
        >>> ca = ca.fit(X)
        
        ```
        
        The parameters and methods overlap with those proposed by the `PCA` class.
        
        ```python
        >>> ca.row_principal_coordinates(X)
                       0         1
        Blue   -0.400300 -0.165411
        Light  -0.440708 -0.088463
        Medium  0.033614  0.245002
        Dark    0.702739 -0.133914
        
        >>> ca.column_principal_coordinates(X)
                       0         1
        Fair   -0.543995 -0.173844
        Red    -0.233261 -0.048279
        Medium -0.042024  0.208304
        Dark    0.588709 -0.103950
        Black   1.094388 -0.286437
        
        ```
        
        You can plot both sets of principal coordinates with the `plot_principal_coordinates` method.
        
        ```python
        >>> ax = ca.plot_principal_coordinates(
        ...     X=X,
        ...     ax=None,
        ...     figsize=(6, 6),
        ...     x_component=0,
        ...     y_component=1,
        ...     show_row_labels=True,
        ...     show_col_labels=True
        ... )
        >>> ax.get_figure().savefig('images/ca_principal_coordinates.png')
        
        ```
        
        <div align="center">
          <img src="images/ca_principal_coordinates.png" />
        </div>
        
        Like for the `PCA` you can access the inertia contribution of each principal component as well as the eigenvalues and the total inertia.
        
        ```python
        >>> ca.eigenvalues_  # doctest: +ELLIPSIS
        [0.199244..., 0.030086...]
        
        >>> ca.total_inertia_  # doctest: +ELLIPSIS
        0.230191...
        
        >>> ca.explained_inertia_  # doctest: +ELLIPSIS
        [0.865562..., 0.130703...]
        
        ```
        
        ### Multiple correspondence analysis (MCA)
        
        Multiple correspondence analysis (MCA) is an extension of correspondence analysis (CA). It should be used when you have more than two categorical variables. The idea is simply to compute the one-hot encoded version of a dataset and apply CA on it. As an example we're going to use the [ballons dataset](https://archive.ics.uci.edu/ml/machine-learning-databases/balloons/) taken from the [UCI datasets website](https://archive.ics.uci.edu/ml/datasets.html).
        
        ```python
        import pandas as pd
        
        >>> X = pd.read_csv('https://archive.ics.uci.edu/ml/machine-learning-databases/balloons/adult+stretch.data')
        >>> X.columns = ['Color', 'Size', 'Action', 'Age', 'Inflated']
        >>> X.head()
            Color   Size   Action    Age Inflated
        0  YELLOW  SMALL  STRETCH  ADULT        T
        1  YELLOW  SMALL  STRETCH  CHILD        F
        2  YELLOW  SMALL      DIP  ADULT        F
        3  YELLOW  SMALL      DIP  CHILD        F
        4  YELLOW  LARGE  STRETCH  ADULT        T
        
        ```
        
        The `MCA` also implements the `fit` and `transform` methods.
        
        ```python
        >>> import prince
        >>> mca = prince.MCA(
        ...     n_components=2,
        ...     n_iter=3,
        ...     copy=True,
        ...     engine='auto',
        ...     random_state=42
        ... )
        >>> mca = mca.fit(X)
        
        ```
        
        As usual you can retrieve the row and column principal components via their respective methods.
        
        ```python
        >>> mca.row_principal_coordinates(X).head()
                  0         1
        0  0.705387  0.000000
        1 -0.386586  0.000000
        2 -0.386586  0.000000
        3 -0.852014  0.000000
        4  0.783539 -0.633333
        
        >>> mca.column_principal_coordinates(X).head()
                             0         1
        Color_PURPLE  0.117308  0.689202
        Color_YELLOW -0.130342 -0.765780
        Size_LARGE    0.117308 -0.689202
        Size_SMALL   -0.130342  0.765780
        Action_DIP   -0.853864 -0.000000
        
        ```
        
        Like the `CA` class, the `MCA` class also has `plot_principal_coordinates` method.
        
        ```python
        >>> ax = mca.plot_principal_coordinates(
        ...     X=X,
        ...     ax=None,
        ...     figsize=(6, 6),
        ...     show_row_points=True,
        ...     row_points_size=10,
        ...     show_row_labels=False,
        ...     show_column_points=True,
        ...     column_points_size=30,
        ...     show_column_labels=False,
        ...     legend_n_cols=1
        ... )
        >>> ax.get_figure().savefig('images/mca_principal_coordinates.png')
        
        ```
        
        <div align="center">
          <img src="images/mca_principal_coordinates.png" />
        </div>
        
        The eigenvalues and inertia values are also accessible.
        
        ```python
        >>> mca.eigenvalues_  # doctest: +ELLIPSIS
        [0.401656..., 0.211111...]
        
        >>> mca.total_inertia_
        1.0
        
        >>> mca.explained_inertia_  # doctest: +ELLIPSIS
        [0.401656..., 0.211111...]
        
        ```
        
        
        ## Going faster
        
        By default `prince` uses `sklearn`'s randomized SVD implementation (the one used under the hood for [`TruncatedSVD`](http://scikit-learn.org/stable/modules/generated/sklearn.decomposition.TruncatedSVD.html)). One of the goals of Prince is to make it possible to use a different SVD backend. For the while the only other supported backend is [Facebook's randomized SVD implementation](https://research.facebook.com/blog/fast-randomized-svd/) called [fbpca](http://fbpca.readthedocs.org/en/latest/). You can use it by setting the `engine` parameter to `'fbpca'`:
        
        ```python
        >>> import prince
        >>> pca = prince.PCA(engine='fbpca')
        
        ```
        
        If you are using Anaconda then you should be able to install `fbpca` without any pain by running `pip install fbpca`.
        
        ## Incoming features
        
        I've got a lot on my hands aside from `prince`, so feel free to give me a hand!
        
        - [Factor Analysis of Mixed Data (FAMD)](https://www.wikiwand.com/en/Factor_analysis_of_mixed_data)
        - [Generalized Procustean Analysis (GPA)](https://www.wikiwand.com/en/Generalized_Procrustes_analysis)
        - [Multiple Factorial Analysis (MFA)](https://www.wikiwand.com/en/Multiple_factor_analysis)
        
        ## License
        
        The MIT License (MIT). Please see the [license file](LICENSE) for more information.
        
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