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Their goals are all the same: to find similar vectors. Which do you use in which situation? (any practical examples?)

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up vote 32 down vote accepted

Pearson correlation and cosine similarity are invariant to scaling, i.e. multiplying all elements by a nonzero constant. Pearson correlation is also invariant to adding any constant to all elements. For example, if you have two vectors X1 and X2, and your Pearson correlation function is called pearson(), pearson(X1, X2) == pearson(X1, 2 * X2 + 3). This is a pretty important property because you often don't care that two vectors are similar in absolute terms, only that they vary in the same way.

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Apologies. I was slightly wrong. Cosine similarity is not invariant to adding a constant to all elements. I've fixed this. The larger point still holds. – dsimcha Jan 24 '10 at 2:01

The difference between Pearson Correlation Coefficient and Cosine Similarity can be seen from their formulas:

enter image description here

The reason Pearson Correlation Coefficient is invariant to adding any constant is that the means are subtracted out by construction. It is also easy to see that Pearson Correlation Coefficient and Cosine Similarity are equivalent when X and Y have means of 0, so we can think of Pearson Correlation Coefficient as demeaned version of Cosine Similarity.

For practical usage, let's consider returns of the two assets x and y:

In [275]:

In [276]: x = np.array([0.1, 0.2, 0.1, -0.1, 0.5])

In [277]: y = x + 0.1

enter image description here

These asset's returns have exactly the same variability, which is measured by Pearson Correlation Coefficient (1), but they are not exactly similar which is measured by cosine similarity (0.971).

In [281]: np.corrcoef([x, y])
array([[ 1.,  1.],   # The off diagonal are correlations 
       [ 1.,  1.]])  # between x and y

In [282]: from sklearn.metrics.pairwise import cosine_similarity

In [283]: cosine_similarity(x, z)
Out[283]: array([[ 0.97128586]])
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