For an m x n matrix, what's the optimal (fastest) way to compute the mutual information for all pairs of columns (n x n)?

By mutual information, I mean:

I(X, Y) = H(X) + H(Y) - H(X,Y)

where H(X) refers to the Shannon entropy of X.

Currently I'm using np.histogram2d and np.histogram to calculate the joint (X,Y) and individual (X or Y) counts. For a given matrix A (e.g. a 250000 X 1000 matrix of floats), I am doing a nested for loop,

    n = A.shape[1]
    for ix = arange(n)  
        for jx = arange(ix+1,n):
           matMI[ix,jx]= calc_MI(A[:,ix],A[:,jx])

Surely there must be better/faster ways to do this?

As an aside, I've also looked for mapping functions on columns (column-wise or row-wise operations) on arrays, but haven't found a good general answer yet.

Here is my full implementation, following the conventions in the Wiki page:

import numpy as np

def calc_MI(X,Y,bins):

   c_XY = np.histogram2d(X,Y,bins)[0]
   c_X = np.histogram(X,bins)[0]
   c_Y = np.histogram(Y,bins)[0]

   H_X = shan_entropy(c_X)
   H_Y = shan_entropy(c_Y)
   H_XY = shan_entropy(c_XY)

   MI = H_X + H_Y - H_XY
   return MI

def shan_entropy(c):
    c_normalized = c / float(np.sum(c))
    c_normalized = c_normalized[np.nonzero(c_normalized)]
    H = -sum(c_normalized* np.log2(c_normalized))  
    return H

A = np.array([[ 2.0,  140.0,  128.23, -150.5, -5.4  ],
              [ 2.4,  153.11, 130.34, -130.1, -9.5  ],
              [ 1.2,  156.9,  120.11, -110.45,-1.12 ]])

bins = 5 # ?
n = A.shape[1]
matMI = np.zeros((n, n))

for ix in np.arange(n):
    for jx in np.arange(ix+1,n):
        matMI[ix,jx] = calc_MI(A[:,ix], A[:,jx], bins)

Although my working version with nested for loops does it at reasonable speed, I'd like to know if there is a more optimal way to apply calc_MI on all the columns of A (to calculate their pairwise mutual information)?

I'd also like to know:

  1. Whether there are efficient ways to map functions to operate on columns (or rows) of np.arrays (maybe like np.vectorize, which looks more like a decorator)?

  2. Whether there are other optimal implementations for this specific calculation (mutual information)?

  • 1
    Could you expand your example code to include calc_MI and example input for A? Make it so we can copy, paste and run. Will greatly help anyone trying to answer your question. – YXD Dec 10 '13 at 10:06
  • Please read this sscce.org and update your example code to include calc_MI and example input for A. – YXD Dec 10 '13 at 13:53
  • My previous comment was inadvertently entered while I meant to respond to the suggestion. Thanks for pointer to sscce.org. – nahsivar Dec 10 '13 at 13:59
  • is this an accurate self contained example then for your current method? pastebin.com/kbzyvA6K. – YXD Dec 10 '13 at 14:24
  • If your matrix is of size (n, m), there is no easy way of vectorizing the computation of only the n * (n - 1) / 2 unique values you are after, although it is often faster to do a vectorized computation of the n * n values in a full cartesian product, even with the duplicates. The problem with this is that it requires creating all of the intermediate calculation objects at once. With your approach above, you would have to figure out a way of creating a 4D histogramdd... I don't see it working out with your huge dataset. I would look into Cython or a C extension... – Jaime Dec 10 '13 at 16:53

I can't suggest a faster calculation for the outer loop over the n*(n-1)/2 vectors, but your implementation of calc_MI(x, y, bins) can be simplified if you can use scipy version 0.13 or scikit-learn.

In scipy 0.13, the lambda_ argument was added to scipy.stats.chi2_contingency This argument controls the statistic that is computed by the function. If you use lambda_="log-likelihood" (or lambda_=0), the log-likelihood ratio is returned. This is also often called the G or G2 statistic. Other than a factor of 2*n (where n is the total number of samples in the contingency table), this is the mutual information. So you could implement calc_MI as:

from scipy.stats import chi2_contingency

def calc_MI(x, y, bins):
    c_xy = np.histogram2d(x, y, bins)[0]
    g, p, dof, expected = chi2_contingency(c_xy, lambda_="log-likelihood")
    mi = 0.5 * g / c_xy.sum()
    return mi

The only difference between this and your implementation is that this implementation uses the natural logarithm instead of the base-2 logarithm (so it is expressing the information in "nats" instead of "bits"). If you really prefer bits, just divide mi by log(2).

If you have (or can install) sklearn (i.e. scikit-learn), you can use sklearn.metrics.mutual_info_score, and implement calc_MI as:

from sklearn.metrics import mutual_info_score

def calc_MI(x, y, bins):
    c_xy = np.histogram2d(x, y, bins)[0]
    mi = mutual_info_score(None, None, contingency=c_xy)
    return mi
  • 1
    Nice code! What is a reasonable default value for number of bins? – pir Nov 1 '15 at 14:40
  • @felbo That's a good question, and not one that can be easily answered. You might get some ideas if you ask it over at stats.stackexchange.com – Warren Weckesser Nov 1 '15 at 15:08
  • This method does not work if some counts equal zero. Why do you suggest this method over density estimation? Also, I upvoted your answer as it does provide an efficient way to calculate MI for some scenarios. – Jon Dec 10 '17 at 22:39
  • "Why do you suggest this method over density estimation?" I didn't. I only suggested a couple alternative implementations of the code given in the question. – Warren Weckesser Dec 10 '17 at 22:47
  • The two suggested methods differs by continuity correction. Change to chi2_contingency(correction = False) removes this inconsistency. – shouldsee Feb 22 '18 at 12:25

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