21

I want to calculate the Euclidean distance in multiple dimensions (24 dimensions) between 2 arrays. I'm using numpy-Scipy.

Here is my code:

import numpy,scipy;

A=numpy.array([116.629, 7192.6, 4535.66, 279714, 176404, 443608, 295522, 1.18399e+07, 7.74233e+06, 2.85839e+08, 2.30168e+08, 5.6919e+08, 168989, 7.48866e+06, 1.45261e+06, 7.49496e+07, 2.13295e+07, 3.74361e+08, 54.5, 3349.39, 262.614, 16175.8, 3693.79, 205865]);

B=numpy.array([0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 151246, 6795630, 4566625, 2.0355328e+08, 1.4250515e+08, 3.2699482e+08, 95635, 4470961, 589043, 29729866, 6124073, 222.3]);

However, I used scipy.spatial.distance.cdist(A[numpy.newaxis,:],B,'euclidean') to calcuate the eucleidan distance.

But it gave me an error

raise ValueError('XB must be a 2-dimensional array.');

I don't seem to understand it.

I looked up scipy.spatial.distance.pdist but don't understand how to use it?

Is there any other better way to do it?

5
  • 3
    Perhaps scipy.spatial.distance.euclidean? Feb 23, 2012 at 14:16
  • 1
    So, you have 2, 24-dimensional points? In that case, @Mr.E's answer is the best option. However, when you have more than 2 points, the various scipy.spatial.distance functions will be more efficient. Feb 23, 2012 at 14:26
  • I thought perhaps I was missing something. Posted as an answer if that solves your problem. Feb 23, 2012 at 17:24
  • 1
    I would like to say something about the error you received long time ago and it might help others in need. Reading from the docs both arrays A and B need to have the same dimensions. This means that if your first array A has a 2-dimensional shape (like you defined with A[numpy.newaxis,:]) also your second array needs to have the same dimensions. Writing B[numpy.newaxis,:] should therefore solve the error. Sep 19, 2020 at 22:36
  • 1
    @JoeKington Who is Mr.E!? :)
    – jtlz2
    Sep 2, 2021 at 17:01

7 Answers 7

26

Perhaps scipy.spatial.distance.euclidean?

Examples

>>> from scipy.spatial import distance
>>> distance.euclidean([1, 0, 0], [0, 1, 0])
1.4142135623730951
>>> distance.euclidean([1, 1, 0], [0, 1, 0])
1.0
14

Use either

numpy.sqrt(numpy.sum((A - B)**2))

or more simply

numpy.linalg.norm(A - B)
11

Starting Python 3.8, you can use standard library's math module and its new dist function, which returns the euclidean distance between two points (given as lists or tuples of coordinates):

from math import dist

dist([1, 0, 0], [0, 1, 0]) # 1.4142135623730951
1
  • 1
    And it's noticeably faster than scipy's euclidean function! +1
    – mauriii
    Aug 26, 2020 at 7:09
7

A and B are 2 points in the 24-D space. You should use scipy.spatial.distance.euclidean.

Doc here

scipy.spatial.distance.euclidean(A, B)
0
5

Since all of the above answers refer to numpy and or scipy, just wanted to point out that something really simple can be done with reduce here

def n_dimensional_euclidean_distance(a, b):
   """
   Returns the euclidean distance for n>=2 dimensions
   :param a: tuple with integers
   :param b: tuple with integers
   :return: the euclidean distance as an integer
   """
   dimension = len(a) # notice, this will definitely throw a IndexError if len(a) != len(b)

   return sqrt(reduce(lambda i,j: i + ((a[j] - b[j]) ** 2), range(dimension), 0))

This will sum all pairs of (a[j] - b[j])^2 for all j in the number of dimensions (note that for simplicity this doesn't support n<2 dimensional distance).

4

Apart from the already mentioned ways of computing the Euclidean distance, here's one that's close to your original code:

scipy.spatial.distance.cdist([A], [B], 'euclidean')

or

scipy.spatial.distance.cdist(np.atleast_2d(A), np.atleast_2d(B), 'euclidean')

This returns a 1×1 np.ndarray holding the L2 distance.

1

Writing your own custom sqaure root sum square is not always safe

You can use math.hypot, numpy.hypot or scipy distance function rather than writing numpy.sqrt(numpy.sum((A - B)**2)) or (i**2 + j**2)**0.5. In your case maybe they can overflow

refer

Speed wise

%%timeit
math.hypot(*(A - B))
# 3 µs ± 64.8 ns per loop (mean ± std. dev. of 7 runs, 100000 loops each)
%%timeit
numpy.sqrt(numpy.sum((A - B)**2))
# 5.65 µs ± 50.7 ns per loop (mean ± std. dev. of 7 runs, 100000 loops each)

Safety wise

Underflow

i, j = 1e-200, 1e-200
np.sqrt(i**2+j**2)
# 0.0

Overflow

i, j = 1e+200, 1e+200
np.sqrt(i**2+j**2)
# inf

No Underflow

i, j = 1e-200, 1e-200
np.hypot(i, j)
# 1.414213562373095e-200

No Overflow

i, j = 1e+200, 1e+200
np.hypot(i, j)
# 1.414213562373095e+200

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