# What is the difference between MATLAB/Octave corr and Python numpy.correlate?

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?

-

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.

Octave:

— 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.

-
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