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# numpy dot product of ith row with ith column

In numpy:

``````A = np.array([[1,2,3],[4,5,6]])
array([[1, 3, 5],
[2, 4, 6]])

B = np.array([[1,2],[3,4],[5,6]])
array([[1, 2],
[3, 4],
[5, 6]])

A.dot(B)
array([[35, 44],
[44, 56]])
``````

I only care about getting A.dot(B).diagonal() = array([35, 56])

Is there a way I can get array([35, 56]) without having to compute the inner products of all the rows and columns? i.e. inner product of the ith row with ith column. I ask because performance difference becomes more significant for larger matrices...

thanks

-

This is just matrix multiplication for 2D arrays:

``````C[i, j] = sum(A[i, ] * B[, j])
``````

So since you just want the diagonal elements, looks like you're after

``````sum(A[i, ] * B[, i]) # for each i
``````

So you could just use list comprehension:

``````[np.dot(A[i,:], B[:, i]) for i in xrange(A.shape[0])]
# [22, 64]
``````

OR, (and this only works because you want a `diagonal` so this assumes that if A's dimensions are `n x m`, B's dimensions will be `m x n`):

``````np.sum(A * B.T, axis=1)
# array([22, 64])
``````

(no fancy numpy tricks going on here, just playing around with the maths).

-
thanks again... so it's not as elegant as stackoverflow.com/questions/2301046/… :( – ejang Nov 20 '12 at 1:05
Well if you found that question you can translate it directly into numpy (I thought of the exact same thing as soon as I posted the answer and added it to my answer) – mathematical.coffee Nov 20 '12 at 1:07

Can you simply leave out the row in the parameter you don't care about?

The 2x3 x 3x2 gives you a 2x2 result.

A 1x3 x 3x2 matrices will give you only the top row of [A][B], a 1x2 matrix.

EDIT: misread the question. Still, each value in the matrix is produced by the product of the transpose of a column and a row.

-
sorry, i realized that i was actually looking for the diagonal, not the first row – ejang Nov 20 '12 at 1:04