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I have a (26424 x 144) array and I want to perform PCA over it using Python. However, there is no particular place on the web that explains about how to achieve this task (There are some sites which just do PCA according to their own - there is no generalized way of doing so that I can find). Anybody with any sort of help will do great.

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is your array sparse (mostly 0) ? Do you care how much of the variance the top 2-3 components capture -- 50 %, 90 % ? – denis Nov 5 '12 at 11:55
No its not sparse, I have it filtered for erroneous values. Yes, I am interested in finding about how many principal components are needed to explain > 75% and >90% of the variance...but not sure how. Any ideas on this? – khan Nov 6 '12 at 8:10
look at the sorted evals from eigh in Doug's answer -- post the top few and the sum if you like, here or a new question. And see wikipedia PCA cumulative energy – denis Nov 6 '12 at 12:46

5 Answers 5

up vote 17 down vote accepted

You can find a PCA function in the matplotlib module:

from matplotlib.mlab import PCA
data = array(randint(10,size=(10,3)))
results = PCA(data)

results will store the various parameters of the PCA. It is from the mlab part of matplotlib, which is the compatibility layer with the MATLAB syntax

EDIT: on the blog nextgenetics I found a wonderful demonstration of how to perform and display a PCA with the matplotlib mlab module, have fun and check that blog!

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Enrico, thanks. I am using this 3D scenario to 3D PCA plots. Thanks again. I will get in touch if some problem occurs. – khan Nov 5 '12 at 3:32
@khan the function PCA from matplot.mlab is deprecated. (…). In addition, it uses SVD, which given the size of the OPs data matrix will be an expensive computation. Using a covariance matrix (see my answer below) you can reduce the size of the matrix in the eigenvector computation by more than 100X. – doug Nov 5 '12 at 5:59
I have no doubt that your code may be faster, but for a quick and dirt PCA an already prepared and tested solution can be better. DRY. By the way, it doesn't seem to be deprecated. the deprecated function is the prepca, but is a different one. – EnricoGiampieri Nov 5 '12 at 14:04
@doug: it isn't deprecated ... they just dropped it documentation. I assume. – khan Nov 6 '12 at 7:18

I posted my answer even though another answer has already been accepted; the accepted answer relies on a deprecated function; additionally, this deprecated function is based on Singular Value Decomposition (SVD), which (although perfectly valid) is the much more memory- and processor-intensive of the two general techniques for calculating PCA. This is particularly relevant here because of the size of the data array in the OP. Using covariance-based PCA, the array used in the computation flow is just 144 x 144, rather than 26424 x 144 (the dimensions of the original data array).

Here's a simple working implementation of PCA using the linalg module from SciPy. Because this implementation first calculates the covariance matrix, and then performs all subsequent calculations on this array, it uses far less memory than SVD-based PCA.

(the linalg module in NumPy can also be used with no change in the code below aside from the import statement, which would be from numpy import linalg as LA.)

The two key steps in this PCA implementation are:

  • calculating the covariance matrix; and

  • taking the eivenvectors & eigenvalues of this cov matrix

In the function below, the parameter dims_rescaled_data refers to the desired number of dimensions in the rescaled data matrix; this parameter has a default value of just two dimensions, but the code below isn't limited to two but it could be any value less than the column number of the original data array.

def PCA(data, dims_rescaled_data=2):
    returns: data transformed in 2 dims/columns + regenerated original data
    pass in: data as 2D NumPy array
    import numpy as NP
    from scipy import linalg as LA
    m, n = data.shape
    # mean center the data
    data -= data.mean(axis=0)
    # calculate the covariance matrix
    R = NP.cov(data, rowvar=False)
    # calculate eigenvectors & eigenvalues of the covariance matrix
    # use 'eigh' rather than 'eig' since R is symmetric, 
    # the performance gain is substantial
    evals, evecs = LA.eigh(R)
    # sort eigenvalue in decreasing order
    idx = NP.argsort(evals)[::-1]
    evecs = evecs[:,idx]
    # sort eigenvectors according to same index
    evals = evals[idx]
    # select the first n eigenvectors (n is desired dimension
    # of rescaled data array, or dims_rescaled_data)
    evecs = evecs[:, :dims_rescaled_data]
    # carry out the transformation on the data using eigenvectors
    # and return the re-scaled data, eigenvalues, and eigenvectors
    return, data.T).T, eigenvalues, eigenvectors

def test_PCA(data, dims_rescaled_data=2):
    test by attempting to recover original data array from
    the eigenvectors of its covariance matrix & comparing that
    'recovered' array with the original data
    _ , _ , eigenvectors = PCA(data, dim_rescaled_data=2)
    data_recovered =, m).T
    data_recovered += data_recovered.mean(axis=0)
    assert NP.allclose(data, data_recovered)

def plot_pca(data):
    from matplotlib import pyplot as MPL
    clr1 =  '#2026B2'
    fig = MPL.figure()
    ax1 = fig.add_subplot(111)
    data_resc, data_orig = PCA(data)
    ax1.plot(data_resc[:, 0], data_resc[:, 1], '.', mfc=clr1, mec=clr1)

>>> # iris, probably the most widely used reference data set in ML
>>> df = "~/iris.csv"
>>> data = NP.loadtxt(df, delimiter=',')
>>> # remove class labels
>>> data = data[:,:-1]
>>> plot_pca(data)

The plot below is a visual representation of this PCA function on the iris data. As you can see, a 2D transformation cleanly separates class I from class II and class III (but not class II from class III, which in fact requires another dimension).

enter image description here

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I agree to your suggestions..seems interesting and honestly, much less memory consuming approach. I have gigs of multidimensional data and I will test these techniques to see which one works the best. Thanks :-) – khan Nov 6 '12 at 7:21
How to retrieve the 1st principal component with this method? Thanks!… – Sibbs Gambling Jul 31 '13 at 9:22
Has this been tested? The provided code does not run. MPL isn't defined, neither is dim1... – Josh Sep 18 '13 at 18:42
I think dim1 should be data.shape and that import matplotlib.pyplot as MPL should be added. – ASGM Aug 19 '14 at 15:55
@doug-- since your test doesn't run (What's m? Why aren't eigenvalues, eigenvectors in the PCA return defined before they are returned? etc), it's kind of hard to use this in any useful way... – mmr Nov 26 '14 at 18:39

This is a job for numpy.

And here's a tutorial demonstrating how pincipal component analysis can be done using numpy's built-in modules like mean,cov,double,cumsum,dot,linalg,array,rank.

Notice that scipy also has a long explanation here -

with the scikit-learn library having more code examples -

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+1 for the link to glowing python – EnricoGiampieri Nov 5 '12 at 0:43
thanks...that glowing python link is real help. – khan Nov 5 '12 at 3:29

Another Python PCA using numpy. The same idea as @doug but that one didn't run.

from numpy import array, dot, mean, std, empty, argsort
from numpy.linalg import eigh, solve
from numpy.random import randn
from matplotlib.pyplot import subplots, show

def cov(data):
        covariance matrix
        note: specifically for mean-centered data
    N = data.shape[1]
    C = empty((N, N))
    for j in range(N):
        C[j, j] = mean(data[:, j] * data[:, j])
        for k in range(N):
            C[j, k] = C[k, j] = mean(data[:, j] * data[:, k])
    return C

def pca(data, pc_count = None):
        Principal component analysis using eigenvalues
        note: this mean-centers and auto-scales the data (in-place)
    data -= mean(data, 0)
    data /= std(data, 0)
    C = cov(data)
    E, V = eigh(C)
    key = argsort(E)[::-1][:pc_count]
    E, V = E[key], V[:, key]
    U = dot(V.T, data.T).T
    return U, E, V

""" test data """
data = array([randn(8) for k in range(150)])
data[:50, 2:4] += 5
data[50:, 2:5] += 5

""" visualize """
trans = pca(data, 3)[0]
fig, (ax1, ax2) = subplots(1, 2)
ax1.scatter(data[:50, 0], data[:50, 1], c = 'r')
ax1.scatter(data[50:, 0], data[50:, 1], c = 'b')
ax2.scatter(trans[:50, 0], trans[:50, 1], c = 'r')
ax2.scatter(trans[50:, 0], trans[50:, 1], c = 'b')

Which yields the same thing as the much shorter

from sklearn.decomposition import PCA

def pca2(data, pc_count = None):
    return PCA(n_components = 4).fit(data).transform(data)

As I understand it, using eigenvalues (first way) is better for high-dimensional data and fewer samples, whereas using Singular value decomposition is better if you have more samples than dimensions.

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Using loops defeats the purpose of numpy. You can achieve the covariance matrix much faster by simply doing matrix multiplication C = – Nicholas Mancuso May 6 at 20:10
Hmm or use numpy.cov I guess. Not sure why I included my own version. – Mark May 21 at 11:28
The result of your data test and visualize seems randomlly. Can you explain the details how to visualize the data? Like how scatter(data[50:, 0], data[50:, 1] make sense? – Peter Zhu Jun 23 at 12:35
@PeterZhu I'm not sure I understand your question. PCA transforms your data to new vectors that maximize variance. The scatter command shows the first two rows plotted against each other. So the projection of the data on on all other dimensions to make it 2D. – Mark Jun 24 at 19:02

Possibly not the exact answer. I've looked for PCA information, what it is useful for and how to apply. Finally I've found the best till now explanation of PCA at the course "Intro to Machine Learning", Chapter PCA:

It is free and explains PCA in 15 min (many other algorithms as well.

For the exercises they use scikit-learn, and for the particular PCA chapter this link:

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