# Euclidean distance with weights

I am currently using `SciPy` to calculate the euclidean distance

``````dis = scipy.spatial.distance.euclidean(A,B)
``````

where; A, B are 5-dimension bit vectors. It works fine now, but if I add weights for each dimension then, is it still possible to use scipy?

What I have now: `sqrt((a1-b1)^2 + (a2-b2)^2 +...+ (a5-b5)^2)`

What I want: `sqrt(w1(a1-b1)^2 + w2(a2-b2)^2 +...+ w5(a5-b5)^2)` using scipy or numpy or any other efficient way to do this.

Thanks

-

The suggestion of writing your own weighted L2 norm is a good one, but the calculation provided in this answer is incorrect. If the intention is to calculate

then this should do the job:

``````def weightedL2(a,b,w):
q = a-b
return np.sqrt((w*q*q).sum())
``````
-

Simply define it yourself. Something like this should do the trick:

``````def mynorm(A, B, w):
import numpy as np
q = np.matrix(w * (A - B))
return np.sqrt((q * q.T).sum())
``````
-
That isn't the norm contained in the question - you have squared the weights. Also the `.sum()` is completely redundant, `q*q.T` is the inner product of the vector with itself, ie. it is the sum. – talonmies Jan 14 '12 at 12:05
You are correct about the weights, I should have been more careful, however your criticism about the `.sum()` being completely redundant is misguided. The result of `q * q.T` would be a 1x1 matrix, which would be an unexpected return type for a norm function, the sum will turn it into a scalar. – wim Jan 14 '12 at 14:02
But why use `sum()` to cast to a scalar? `np.asscalar` will be several times faster`? – talonmies Jan 14 '12 at 14:14
I don't know the reason, but that is how it is implemented in `scipy.spatial.distance.euclidean` .. I just assume the authors of scipy know what's best – wim Jan 14 '12 at 14:52