# Fastest way to Calculate the Euclidian distance between 2 sets of vectors using numpy or scipy

OK I have recently discovered that the the `scipy.spatial.distance.cdist` command is very quick for solving a COMPLETE distance matrix between two vector arrays for source and destination. see: calculate euclidean distance with numpy I wanted to try to duplicate those performance gains when solving the distance between two equal sized arrays. The distance between two SINGLE vectors is rather straight forward to calculate as shown in the previous link. We can take vectors:

``````    import numpy as np
A=np.random.normal(size=(3))
B=np.random.normal(size=(3))
``````

and then use ´numpy.linalg.norm´ where

``````    np.linalg.norm(A-B)
``````

is equivalent to

``````    temp = A-B
np.sqrt(temp[0]**2+temp[1]**2+temp[2]**2)
``````

which works nicely however when I want to know the distance between two sets of vectors where `my_distance = distance_between( A[i], B[i] ) for all i` the second solution works perfectly. In that as expected:

``````    A=np.random.normal(size=(3,42))
B=np.random.normal(size=(3,42))
temp = A-B
np.sqrt(temp[0]**2+temp[1]**2+temp[2]**2)
``````

gives me a set of 42 distances between the `i`th element of `A` to the `i`th element of `B`. Whereas the `norm` function correctly calculates the norm for the entire matrix giving me a single value that is not what I'm looking for. The behaviour with the 42 distances is what I want to maintain, hopefully with nearly as much speed as I get from `cdist` for solving complete matrices. So the question is whats the most efficient way using python and numpy/scipy to calculate `i` distances between data with shape `(n,i)`?

Thanks, Sloan

-

``````np.sqrt(np.sum(temp**2,0))
Strangely enough its actually 3x faster to use `np.sqrt(temp[0]**2+temp[1]**2+temp[2]**2)` for 1 million elements. – SoulNibbler Dec 12 '12 at 12:06