# numpy covariance between each column of a matrix and a vector

Based on this post, I can get covariance between two vectors using `np.cov((x,y), rowvar=0)`. I have a matrix MxN and a vector Mx1. I want to find the covariance between each column of the matrix and the given vector. I know that I can use `for` loop to write. I was wondering if I can somehow use `np.cov()` to get the result directly.

As Warren Weckesser said, the `numpy.cov(X, Y)` is a poor fit for the job because it will simply join the arrays in one M by (N+1) array and find the huge (N+1) by (N+1) covariance matrix. But we'll always have the definition of covariance and it's easy to use:

``````A = np.sqrt(np.arange(12).reshape(3, 4))   # some 3 by 4 array
b = np.array([[2], [4], [5]])              # some 3 by 1 vector
cov = np.dot(b.T - b.mean(), A - A.mean(axis=0)) / (b.shape[0]-1)
``````

This returns the covariances of each column of A with b.

``````array([[ 2.21895142,  1.53934466,  1.3379221 ,  1.20866607]])
``````

The formula I used is for sample covariance (which is what numpy.cov computes, too), hence the division by (b.shape[0] - 1). If you divide by `b.shape[0]` you get the unadjusted population covariance.

For comparison, the same computation using `np.cov`:

``````import numpy as np
A = np.sqrt(np.arange(12).reshape(3, 4))
b = np.array([[2], [4], [5]])
np.cov(A, b, rowvar=False)[-1, :-1]
``````

Same output, but it takes about twice this long (and for large matrices, the difference will be much larger). The slicing at the end is because `np.cov` computes a 5 by 5 matrix, in which only the first 4 entries of the last row are what you wanted. The rest is covariance of A with itself, or of b with itself.

### Correlation coefficient

The correlation coefficientis obtained by dividing by square roots of variances. Watch out for that -1 adjustment mentioned earlier: `numpy.var` does not make it by default, to make it happen you need `ddof=1` parameter.

``````corr = cov / np.sqrt(np.var(b, ddof=1) * np.var(A, axis=0, ddof=1))
``````

Check that the output is the same as the less efficient version

``````np.corrcoef(A, b, rowvar=False)[-1, :-1]
``````
• That is what I wanted! Thanks a lot for your help and clear explanations. Can you please tell me about the axis? Does axis=0 mean columns? I was reading that correlation is easier to compare than cov. Now that you calculated it based on definition, I think I can just divide "cov" by square root of each of the variances. I want to know the usage of axis, so I can use for that purpose as well. Commented Jan 5, 2018 at 20:39
• 0 = row index, 1= column index. Saying axis=0 in `mean` means compute the mean running over the row index. The other index stays constant. So it ends up being the mean of each column. Try small examples like `np.array([[1,2], [4, 7]])` to see how it works.
– user6655984
Commented Jan 5, 2018 at 21:07
• And I expanded the answer to address the correlation part, because it's a bit tricky.
– user6655984
Commented Jan 5, 2018 at 21:12
• Thanks a million! It is clear now. I also tried an example with hand to clearly understands the index meaning. I got it, thanks. Commented Jan 5, 2018 at 21:22
• The answer was really great. I only have one improvement. The `numpy` package has already provided `np.std()` function to calculate standard deviation. Therefore the calculation for corr can be simplified as `corr = cov / (np.std(b, ddof=1) * np.std(A, axis=0, ddof=1))`. The answer also has a deep understanding of sample and population statistics! Commented Jun 20, 2019 at 14:49