# Efficient distance calculation between N points and a reference in numpy/scipy

I just started using scipy/numpy. I have an 100000*3 array, each row is a coordinate, and a 1*3 center point. I want to calculate the distance for each row in the array to the center and store them in another array. What is the most efficient way to do it?

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possible duplicate of calculate euclidean distance with numpy – Fred Foo Jun 21 '11 at 18:25
@larsmans: I don't think it's a duplicate since the answers only pertain to the distance between two points rather than the distance between N points and a reference point. And certainly the responses don't point the OP to the efficient scipy solution that I show below. – JoshAdel Jun 21 '11 at 18:38
@JoshAdel: ok, fair enough. – Fred Foo Jun 21 '11 at 18:59

I would take a look at `scipy.spatial.distance.cdist`:

http://docs.scipy.org/doc/scipy/reference/generated/scipy.spatial.distance.cdist.html

``````import numpy as np
import scipy

a = np.random.normal(size=(10,3))
b = np.random.normal(size=(1,3))

dist = scipy.spatial.distance.cdist(a,b) # pick the appropriate distance metric
``````

`dist` for the default distant metric is equivalent to:

``````np.sqrt(np.sum((a-b)**2,axis=1))
``````

although `cdist` is much more efficient for large arrays (on my machine for your size problem, `cdist` is faster by a factor of ~35x).

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I would use the sklearn implementation of the euclidean distance. The advantage is the usage of the more efficient expression by using Matrix multiplication:

``````dist(x, y) = sqrt(dot(x, x) - 2 * dot(x, y) + dot(y, y)
``````

A simple script would look like this:

``````import numpy as np

x = np.random.rand(1000, 3)
y = np.random.rand(1000, 3)

dist = np.sqrt(np.dot(x, x)) - (dot(x, y) + dot(x, y)) + dot(y, y)
``````

The advantage of this approach has been nicely described in the sklearn documentation: http://scikit-learn.org/stable/modules/generated/sklearn.metrics.pairwise.euclidean_distances.html#sklearn.metrics.pairwise.euclidean_distances

I am using this approach to crunch large datamatrices (10000, 10000) with some minor modifications like using the np.einsum function.

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You can also use the development of the norm (similar to remarkable identities). This is probably the most efficent way to compute the distance of a matrix of points.

Here is a code snippet that I originally used for a k-Nearest-Neighbors implementation, in Octave, but you can easily adapt it to numpy since it only uses matrix multiplications (the equivalent is numpy.dot()):

``````% Computing the euclidian distance between each known point (Xapp) and unknown points (Xtest)
% Note: we use the development of the norm just like a remarkable identity:
% ||x1 - x2||^2 = ||x1||^2 + ||x2||^2 - 2*<x1,x2>
[napp, d] = size(Xapp);
[ntest, d] = size(Xtest);

A = sum(Xapp.^2, 2);
A = repmat(A, 1, ntest);

B = sum(Xtest.^2, 2);
B = repmat(B', napp, 1);

C = Xapp*Xtest';

dist = A+B-2.*C;
``````
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You may need to specify a more detailed manner the distance function you are interested of, but here is a very simple (and efficient) implementation of Squared Euclidean Distance based on `inner product` (which obviously can be generalized, straightforward manner, to other kind of distance measures):

``````In []: P, c= randn(5, 3), randn(1, 3)
In []: dot(((P- c)** 2), ones(3))
Out[]: array([  8.80512,   4.61693,   2.6002,   3.3293,  12.41800])
``````

Where `P` are your points and `c` is the center.

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On my machine this is still 18x slower than `cdist` for the OP's problem size. – JoshAdel Jun 22 '11 at 3:25
@JoshAdel: That's big difference. FWIW, with `numpy` 1.6 in my modest machine: for `n`= 1e5, timing s are `cdist` 3.5 ms and `dot` 9.5 ms. So `dot`is only some 3 times slower. However with much smaller `n` (<2e3) 'dot' will be faster. Thanks – eat Jun 22 '11 at 11:55