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I'm trying to recover from a PCA done with scikit-learn, which features are selected as relevant.

A classic example with IRIS dataset.

import pandas as pd
import pylab as pl
from sklearn import datasets
from sklearn.decomposition import PCA

# load dataset
iris = datasets.load_iris()
df = pd.DataFrame(iris.data, columns=iris.feature_names)

# normalize data
df_norm = (df - df.mean()) / df.std()

# PCA
pca = PCA(n_components=2)
pca.fit_transform(df_norm.values)
print pca.explained_variance_ratio_

This returns

In [42]: pca.explained_variance_ratio_
Out[42]: array([ 0.72770452,  0.23030523])

How can I recover which two features allow these two explained variance among the dataset ? Said diferently, how can i get the index of this features in iris.feature_names ?

In [47]: print iris.feature_names
['sepal length (cm)', 'sepal width (cm)', 'petal length (cm)', 'petal width (cm)']

Thanks in advance for your help.

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1  
pca.components_ is what you are looking for. – Sangram Jun 2 at 11:24
up vote 11 down vote accepted

Each principal component is a linear combination of the original variables:

pca-coef

where X_is are the original variables, and Beta_is are the corresponding weights or so called coefficients.

To obtain the weights, you may simply pass identity matrix to the transform method:

>>> i = np.identity(df.shape[1])  # identity matrix
>>> i
array([[ 1.,  0.,  0.,  0.],
       [ 0.,  1.,  0.,  0.],
       [ 0.,  0.,  1.,  0.],
       [ 0.,  0.,  0.,  1.]])

>>> coef = pca.transform(i)
>>> coef
array([[ 0.5224, -0.3723],
       [-0.2634, -0.9256],
       [ 0.5813, -0.0211],
       [ 0.5656, -0.0654]])

Each column of the coef matrix above shows the weights in the linear combination which obtains corresponding principal component:

>>> pd.DataFrame(coef, columns=['PC-1', 'PC-2'], index=df.columns)
                    PC-1   PC-2
sepal length (cm)  0.522 -0.372
sepal width (cm)  -0.263 -0.926
petal length (cm)  0.581 -0.021
petal width (cm)   0.566 -0.065

[4 rows x 2 columns]

For example, above shows that the second principal component (PC-2) is mostly aligned with sepal width, which has the highest weight of 0.926 in absolute value;

Since the data were normalized, you can confirm that the principal components have variance 1.0 which is equivalent to each coefficient vector having norm 1.0:

>>> np.linalg.norm(coef,axis=0)
array([ 1.,  1.])

One may also confirm that the principal components can be calculated as the dot product of the above coefficients and the original variables:

>>> np.allclose(df_norm.values.dot(coef), pca.fit_transform(df_norm.values))
True

Note that we need to use numpy.allclose instead of regular equality operator, because of floating point precision error.

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2  
Awesome and exhaustive answer, thank you very much ! – mazieres Apr 10 '14 at 11:56
2  
There's no need for that identity matrix: your coef is the same as pca.components_.T. scikit-learn estimators always put their learned parameters in public attributes. – Fred Foo Apr 11 '14 at 9:21
2  
insightful answer for people like me trying to learn PCA – goh Nov 8 '14 at 13:00
1  
Why not directly use pca.components_? – Sangram Jun 2 at 11:24
    
Using the identity matrix doesn't work as the inverse transform function adds the empirical mean of each feature. The result gives equal weight (coefficients) to all original variables. (See this answer). By using pca.components_, you get the right answer. – Rahul Murmuria Jun 17 at 3:21

This information is included in the pca attribute: components_. As described in the documentation, pca.components_ outputs an array of [n_components, n_features], so to get how components are linearly related with the different features you have to:

Note: each coefficient represents the correlation between a particular pair of component and feature

import pandas as pd
import pylab as pl
from sklearn import datasets
from sklearn.decomposition import PCA

# load dataset
iris = datasets.load_iris()
df = pd.DataFrame(iris.data, columns=iris.feature_names)

# normalize data
from sklearn import preprocessing
data_scaled = pd.DataFrame(preprocessing.scale(df),columns = df.columns) 

# PCA
pca = PCA(n_components=2)
pca.fit_transform(data_scaled)

# Dump components relations with features:
print pd.DataFrame(pca.components_,columns=data_scaled.columns,index = ['PC-1','PC-2'])

      sepal length (cm)  sepal width (cm)  petal length (cm)  petal width (cm)
PC-1           0.522372         -0.263355           0.581254          0.565611
PC-2          -0.372318         -0.925556          -0.021095         -0.065416
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This should be the accepted answer. – Rahul Murmuria Jun 17 at 3:23

Given your fitted estimator pca, the components are to be found in pca.components_, which represent the directions of highest variance in the dataset.

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