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I am trying to port a MATLAB/Octave program to Python using NumPy 1.8.0 and Python 2.7.3. I've used this reference as help in converting MATLAB functions to NumPy methods with great success, until I get to the point where I want to compute the correlation between two matrices.

The first matrix is 40000x25 floats, the second matrix is 40000x1 ints. In Octave I use the statement corr(a,b) and get a 25x1 matrix of floats. Trying the corresponding method in NumPy (numpy.correlate(a,b)) produces an error:

Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
  File "/Library/Python/2.7/site-packages/numpy-1.8.0.dev_1a9aa5a_20130415-py2.7-macosx-10.8-intel.egg/numpy/core/numeric.py", line 751, in correlate
  return multiarray.correlate2(a,v,mode)
ValueError: object too deep for desired array

I can get it to work if I change the code to calculate a correlation for each column of a, like so:

for i in range(25):
    c2[i] = numpy.correlate(a[:,i], b)

However, the values in the c2 array are different than the output from Octave. Octave returns a 25x1 matrix of floats all less than 1. The values I get from NumPy are floats between -270 and 900.

I have tried to understand what the two algorithms are doing under the hood but have failed miserably. Can someone point out my logic failure?

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1 Answer 1

up vote 6 down vote accepted

It appears that there exists a numpy.corrcoef which computes the correlation coefficients, as desired. However, its interface is different from the Octave/Matlab corr.

First of all, by default, the function treats rows as variables, with the columns being observations. To mimic the behavior of Octave/Matlab, you can pass a flag which reverses this.

Also, according to this answer, the numpy.cov function (which corrcoef uses internally, I assume) returns a 2x2 matrix, each of which contain a specific covariance:

cov(a,a)  cov(a,b)

cov(a,b)  cov(b,b)

As he points out, the [0][1] element is what you'd want for cov(a,b). Thus, perhaps something like this will work:

for i in range(25):
    c2[i] = numpy.corrcoef(a[:,i], b, rowvar=0)[0][1]

For reference, here are some excerpts of the two functions that you had tried. It seems to be that they perform completely different things.


— Function File: corr (x, y)

Compute matrix of correlation coefficients.

If each row of x and y is an observation and each column is a variable, then the (i, j)-th entry of corr (x, y) is the correlation between the i-th variable in x and the j-th variable in y.

      corr (x,y) = cov (x,y) / (std (x) * std (y))

If called with one argument, compute corr (x, x), the correlation between the columns of x.

And Numpy:

numpy.correlate(a, v, mode='valid', old_behavior=False)[source]

Cross-correlation of two 1-dimensional sequences.

This function computes the correlation as generally defined in signal processing texts:

z[k] = sum_n a[n] * conj(v[n+k])

with a and v sequences being zero-padded where necessary and conj being the conjugate.

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I have tried that but numpy.cov(a,b) returns a 2x2 array of floats and I don't know how that relates to the correlation. –  Crystal May 22 '13 at 18:40
or try to simply get Pearson's r –  Rasman May 22 '13 at 18:52
or this –  Rasman May 22 '13 at 18:53
@Rasman - I have tried corrcoef, but it also returns a 2x2 array that I don't know what to do with. I just tried pearsonsr and have the same questions. While these values look much better than what I'm getting from correlate, I'm still not getting the same answers as the octave function. Should I expect to? –  Crystal May 22 '13 at 19:02
@Crystal: I think I may have found what the 2x2 array is all about. I've edited my answer to give a possible solution. –  voithos May 22 '13 at 19:03

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