# How can the Euclidean distance be calculated with NumPy?

I have two points in 3D:

``````(xa, ya, za)
(xb, yb, zb)
``````

And I want to calculate the distance:

``````dist = sqrt((xa-xb)^2 + (ya-yb)^2 + (za-zb)^2)
``````

What's the best way to do this with NumPy, or with Python in general? I have:

``````a = numpy.array((xa ,ya, za))
b = numpy.array((xb, yb, zb))
``````

``````dist = numpy.linalg.norm(a-b)
``````

Theory Behind this: as found in Introduction to Data Mining

This works because Euclidean distance is l2 norm and the default value of ord parameter in numpy.linalg.norm is 2. There's a function for that in SciPy. It's called Euclidean.

Example:

``````from scipy.spatial import distance
a = (1, 2, 3)
b = (4, 5, 6)
dst = distance.euclidean(a, b)
``````
• If you look for efficiency it is better to use the numpy function. The scipy distance is twice as slow as numpy.linalg.norm(a-b) (and numpy.sqrt(numpy.sum((a-b)**2))). On my machine I get 19.7 µs with scipy (v0.15.1) and 8.9 µs with numpy (v1.9.2). Not a relevant difference in many cases but if in loop may become more significant. From a quick look at the scipy code it seems to be slower because it validates the array before computing the distance. – Algold Jul 22 '15 at 10:29
• does this work on numpy arrays? – Mike Palmice Jan 10 '18 at 20:59
• @MikePalmice yes, scipy functions are fully compatible with numpy. But take a look at what aigold suggested here (which also works on numpy array, of course) – Avision Jan 12 '18 at 8:48
• @Avision not sure if it will work for me since my matrices have different numbers of rows; trying to subtract them to get one matrix doesn't work – Mike Palmice Jan 15 '18 at 1:29
• @MikePalmice what exactly are you trying to compute with these two matrices? what is the expected input/output? – Avision Jan 16 '18 at 14:07

For anyone interested in computing multiple distances at once, I've done a little comparison using perfplot (a small project of mine).

The first advice is to organize your data such that the arrays have dimension `(3, n)` (and are C-contiguous obviously). If adding happens in the contiguous first dimension, things are faster, and it doesn't matter too much if you use `sqrt-sum` with `axis=0`, `linalg.norm` with `axis=0`, or

``````a_min_b = a - b
numpy.sqrt(numpy.einsum('ij,ij->j', a_min_b, a_min_b))
``````

which is, by a slight margin, the fastest variant. (That actually holds true for just one row as well.)

The variants where you sum up over the second axis, `axis=1`, are all substantially slower. Code to reproduce the plot:

``````import numpy
import perfplot
from scipy.spatial import distance

def linalg_norm(data):
a, b = data
return numpy.linalg.norm(a - b, axis=1)

def linalg_norm_T(data):
a, b = data
return numpy.linalg.norm(a - b, axis=0)

def sqrt_sum(data):
a, b = data
return numpy.sqrt(numpy.sum((a - b) ** 2, axis=1))

def sqrt_sum_T(data):
a, b = data
return numpy.sqrt(numpy.sum((a - b) ** 2, axis=0))

def scipy_distance(data):
a, b = data
return list(map(distance.euclidean, a, b))

def sqrt_einsum(data):
a, b = data
a_min_b = a - b
return numpy.sqrt(numpy.einsum("ij,ij->i", a_min_b, a_min_b))

def sqrt_einsum_T(data):
a, b = data
a_min_b = a - b
return numpy.sqrt(numpy.einsum("ij,ij->j", a_min_b, a_min_b))

def setup(n):
a = numpy.random.rand(n, 3)
b = numpy.random.rand(n, 3)
out0 = numpy.array([a, b])
out1 = numpy.array([a.T, b.T])
return out0, out1

perfplot.save(
"norm.png",
setup=setup,
n_range=[2 ** k for k in range(22)],
kernels=[
linalg_norm,
linalg_norm_T,
scipy_distance,
sqrt_sum,
sqrt_sum_T,
sqrt_einsum,
sqrt_einsum_T,
],
logx=True,
logy=True,
xlabel="len(x), len(y)",
)
``````
• Thank you. I learnt something new today! For single dimension array, the string will be `i,i->` – Tirtha R Dec 17 '18 at 19:26
• itd be evern more cool if there was a comparision of memory consumptions – dragonLOLz Feb 17 at 15:18
• I would like to use your code but I am struggling with understanding how the data is supposed to be organized. Can you give an example? How does `data` have to look like? – Johannes Wiesner Sep 18 at 10:23

Another instance of this problem solving method:

``````def dist(x,y):
return numpy.sqrt(numpy.sum((x-y)**2))

a = numpy.array((xa,ya,za))
b = numpy.array((xb,yb,zb))
dist_a_b = dist(a,b)
``````
• can you use numpy's sqrt and/or sum implementations? That should make it faster (?). – u0b34a0f6ae Sep 9 '09 at 20:03
• I found this on the other side of the interwebs `norm = lambda x: N.sqrt(N.square(x).sum())` ; `norm(x-y)` – u0b34a0f6ae Sep 9 '09 at 20:09
• scratch that. it had to be somewhere. here it is: `numpy.linalg.norm(x-y)` – u0b34a0f6ae Sep 9 '09 at 20:11

I want to expound on the simple answer with various performance notes. np.linalg.norm will do perhaps more than you need:

``````dist = numpy.linalg.norm(a-b)
``````

Firstly - this function is designed to work over a list and return all of the values, e.g. to compare the distance from `pA` to the set of points `sP`:

``````sP = set(points)
pA = point
distances = np.linalg.norm(sP - pA, ord=2, axis=1.)  # 'distances' is a list
``````

Remember several things:

• Python function calls are expensive.
• [Regular] Python doesn't cache name lookups.

So

``````def distance(pointA, pointB):
dist = np.linalg.norm(pointA - pointB)
return dist
``````

isn't as innocent as it looks.

``````>>> dis.dis(distance)
2           0 LOAD_GLOBAL              0 (np)
2 LOAD_ATTR                1 (linalg)
4 LOAD_ATTR                2 (norm)
6 LOAD_FAST                0 (pointA)
8 LOAD_FAST                1 (pointB)
10 BINARY_SUBTRACT
12 CALL_FUNCTION            1
14 STORE_FAST               2 (dist)

3          16 LOAD_FAST                2 (dist)
18 RETURN_VALUE
``````

Firstly - every time we call it, we have to do a global lookup for "np", a scoped lookup for "linalg" and a scoped lookup for "norm", and the overhead of merely calling the function can equate to dozens of python instructions.

Lastly, we wasted two operations on to store the result and reload it for return...

First pass at improvement: make the lookup faster, skip the store

``````def distance(pointA, pointB, _norm=np.linalg.norm):
return _norm(pointA - pointB)
``````

We get the far more streamlined:

``````>>> dis.dis(distance)
2           0 LOAD_FAST                2 (_norm)
2 LOAD_FAST                0 (pointA)
4 LOAD_FAST                1 (pointB)
6 BINARY_SUBTRACT
8 CALL_FUNCTION            1
10 RETURN_VALUE
``````

The function call overhead still amounts to some work, though. And you'll want to do benchmarks to determine whether you might be better doing the math yourself:

``````def distance(pointA, pointB):
return (
((pointA.x - pointB.x) ** 2) +
((pointA.y - pointB.y) ** 2) +
((pointA.z - pointB.z) ** 2)
) ** 0.5  # fast sqrt
``````

On some platforms, `**0.5` is faster than `math.sqrt`. Your mileage may vary.

**** Advanced performance notes.

Why are you calculating distance? If the sole purpose is to display it,

`````` print("The target is %.2fm away" % (distance(a, b)))
``````

move along. But if you're comparing distances, doing range checks, etc., I'd like to add some useful performance observations.

Let’s take two cases: sorting by distance or culling a list to items that meet a range constraint.

``````# Ultra naive implementations. Hold onto your hat.

def sort_things_by_distance(origin, things):
return things.sort(key=lambda thing: distance(origin, thing))

def in_range(origin, range, things):
things_in_range = []
for thing in things:
if distance(origin, thing) <= range:
things_in_range.append(thing)
``````

The first thing we need to remember is that we are using Pythagoras to calculate the distance (`dist = sqrt(x^2 + y^2 + z^2)`) so we're making a lot of `sqrt` calls. Math 101:

``````dist = root ( x^2 + y^2 + z^2 )
:.
dist^2 = x^2 + y^2 + z^2
and
sq(N) < sq(M) iff M > N
and
sq(N) > sq(M) iff N > M
and
sq(N) = sq(M) iff N == M
``````

In short: until we actually require the distance in a unit of X rather than X^2, we can eliminate the hardest part of the calculations.

``````# Still naive, but much faster.

def distance_sq(left, right):
""" Returns the square of the distance between left and right. """
return (
((left.x - right.x) ** 2) +
((left.y - right.y) ** 2) +
((left.z - right.z) ** 2)
)

def sort_things_by_distance(origin, things):
return things.sort(key=lambda thing: distance_sq(origin, thing))

def in_range(origin, range, things):
things_in_range = []

# Remember that sqrt(N)**2 == N, so if we square
# range, we don't need to root the distances.
range_sq = range**2

for thing in things:
if distance_sq(origin, thing) <= range_sq:
things_in_range.append(thing)
``````

Great, both functions no-longer do any expensive square roots. That'll be much faster. We can also improve in_range by converting it to a generator:

``````def in_range(origin, range, things):
range_sq = range**2
yield from (thing for thing in things
if distance_sq(origin, thing) <= range_sq)
``````

This especially has benefits if you are doing something like:

``````if any(in_range(origin, max_dist, things)):
...
``````

But if the very next thing you are going to do requires a distance,

``````for nearby in in_range(origin, walking_distance, hotdog_stands):
print("%s %.2fm" % (nearby.name, distance(origin, nearby)))
``````

consider yielding tuples:

``````def in_range_with_dist_sq(origin, range, things):
range_sq = range**2
for thing in things:
dist_sq = distance_sq(origin, thing)
if dist_sq <= range_sq: yield (thing, dist_sq)
``````

This can be especially useful if you might chain range checks ('find things that are near X and within Nm of Y', since you don't have to calculate the distance again).

But what about if we're searching a really large list of `things` and we anticipate a lot of them not being worth consideration?

There is actually a very simple optimization:

``````def in_range_all_the_things(origin, range, things):
range_sq = range**2
for thing in things:
dist_sq = (origin.x - thing.x) ** 2
if dist_sq <= range_sq:
dist_sq += (origin.y - thing.y) ** 2
if dist_sq <= range_sq:
dist_sq += (origin.z - thing.z) ** 2
if dist_sq <= range_sq:
yield thing
``````

Whether this is useful will depend on the size of 'things'.

``````def in_range_all_the_things(origin, range, things):
range_sq = range**2
if len(things) >= 4096:
for thing in things:
dist_sq = (origin.x - thing.x) ** 2
if dist_sq <= range_sq:
dist_sq += (origin.y - thing.y) ** 2
if dist_sq <= range_sq:
dist_sq += (origin.z - thing.z) ** 2
if dist_sq <= range_sq:
yield thing
elif len(things) > 32:
for things in things:
dist_sq = (origin.x - thing.x) ** 2
if dist_sq <= range_sq:
dist_sq += (origin.y - thing.y) ** 2 + (origin.z - thing.z) ** 2
if dist_sq <= range_sq:
yield thing
else:
... just calculate distance and range-check it ...
``````

And again, consider yielding the dist_sq. Our hotdog example then becomes:

``````# Chaining generators
info = in_range_with_dist_sq(origin, walking_distance, hotdog_stands)
info = (stand, dist_sq**0.5 for stand, dist_sq in info)
for stand, dist in info:
print("%s %.2fm" % (stand, dist))
``````
• Why not add such an optimized function to numpy? An extension for pandas would also be great for a question like this stackoverflow.com/questions/47643952/… – Keith Dec 5 '17 at 4:52
• I edited your first mathematical approach to distance. You were using a `pointZ` that didn't exist. I think what you meant was two points in three dimensional space and I edited accordingly. If I was wrong, please let me know. – Bram Vanroy Nov 14 '18 at 9:42

It can be done like the following. I don't know how fast it is, but it's not using NumPy.

``````from math import sqrt
a = (1, 2, 3) # Data point 1
b = (4, 5, 6) # Data point 2
print sqrt(sum( (a - b)**2 for a, b in zip(a, b)))
``````
• Doing maths directly in python is not a good idea as python is very slow, specifically `for a, b in zip(a, b)`. But useful none the less. – Sigex May 5 at 13:30

I find a 'dist' function in matplotlib.mlab, but I don't think it's handy enough.

I'm posting it here just for reference.

``````import numpy as np
import matplotlib as plt

a = np.array([1, 2, 3])
b = np.array([2, 3, 4])

# Distance between a and b
dis = plt.mlab.dist(a, b)
``````
• This is no longer applicable. (mpl 3.0) – Nico Schlömer Jul 31 at 8:18

Starting `Python 3.8`, the `math` module directly provides the `dist` function, which returns the euclidean distance between two points (given as tuples or lists of coordinates):

``````from math import dist

dist((1, 2, 6), (-2, 3, 2)) # 5.0990195135927845
``````

And if you're working with lists:

``````dist([1, 2, 6], [-2, 3, 2]) # 5.0990195135927845
``````

You can just subtract the vectors and then innerproduct.

``````a = numpy.array((xa, ya, za))
b = numpy.array((xb, yb, zb))

tmp = a - b
sum_squared = numpy.dot(tmp.T, tmp)
result sqrt(sum_squared)
``````

It is simple code and is easy to understand.

• this will give me the square of the distance. you're missing a sqrt here. – Nathan Fellman Sep 10 '11 at 20:37

I like `np.dot` (dot product):

``````a = numpy.array((xa,ya,za))
b = numpy.array((xb,yb,zb))

distance = (np.dot(a-b,a-b))**.5
``````

Having `a` and `b` as you defined them, you can use also:

``````distance = np.sqrt(np.sum((a-b)**2))
``````

A nice one-liner:

``````dist = numpy.linalg.norm(a-b)
``````

However, if speed is a concern I would recommend experimenting on your machine. I found that using the `math` library's `sqrt` with the `**` operator for the square is much faster on my machine than the one-liner NumPy solution.

I ran my tests using this simple program:

``````#!/usr/bin/python
import math
import numpy
from random import uniform

def fastest_calc_dist(p1,p2):
return math.sqrt((p2 - p1) ** 2 +
(p2 - p1) ** 2 +
(p2 - p1) ** 2)

def math_calc_dist(p1,p2):
return math.sqrt(math.pow((p2 - p1), 2) +
math.pow((p2 - p1), 2) +
math.pow((p2 - p1), 2))

def numpy_calc_dist(p1,p2):
return numpy.linalg.norm(numpy.array(p1)-numpy.array(p2))

TOTAL_LOCATIONS = 1000

p1 = dict()
p2 = dict()
for i in range(0, TOTAL_LOCATIONS):
p1[i] = (uniform(0,1000),uniform(0,1000),uniform(0,1000))
p2[i] = (uniform(0,1000),uniform(0,1000),uniform(0,1000))

total_dist = 0
for i in range(0, TOTAL_LOCATIONS):
for j in range(0, TOTAL_LOCATIONS):
dist = fastest_calc_dist(p1[i], p2[j]) #change this line for testing
total_dist += dist

print total_dist
``````

On my machine, `math_calc_dist` runs much faster than `numpy_calc_dist`: 1.5 seconds versus 23.5 seconds.

To get a measurable difference between `fastest_calc_dist` and `math_calc_dist` I had to up `TOTAL_LOCATIONS` to 6000. Then `fastest_calc_dist` takes ~50 seconds while `math_calc_dist` takes ~60 seconds.

You can also experiment with `numpy.sqrt` and `numpy.square` though both were slower than the `math` alternatives on my machine.

My tests were run with Python 2.6.6.

• You're badly misunderstanding how to use numpy... Don't use loops or list comprehensions. If you're iterating through, and applying the function to each item, then, yeah, the numpy functions will be slower. The whole point is to vectorize things. – Joe Kington Nov 13 '10 at 3:36
• If I move the numpy.array call into the loop where I am creating the points I do get better results with numpy_calc_dist, but it is still 10x slower than fastest_calc_dist. If I have that many points and I need to find the distance between each pair I'm not sure what else I can do to advantage numpy. – user118662 Nov 13 '10 at 16:41
• I realize this thread is old, but I just want to reinforce what Joe said. You are not using numpy correctly. What you are calculating is the sum of the distance from every point in p1 to every point in p2. The solution with numpy/scipy is over 70 times quicker on my machine. Make p1 and p2 into an array (even using a loop if you have them defined as dicts). Then you can get the total sum in one step, `scipy.spatial.distance.cdist(p1, p2).sum()`. That is it. – Scott B May 14 '11 at 0:14
• Or use `numpy.linalg.norm(p1-p2).sum()` to get the sum between each point in p1 and the corresponding point in p2 (i.e. not every point in p1 to every point in p2). And if you do want every point in p1 to every point in p2 and don't want to use scipy as in my previous comment, then you can use np.apply_along_axis along with numpy.linalg.norm to still do it much, much quicker then your "fastest" solution. – Scott B May 14 '11 at 0:16
• Previous versions of NumPy had very slow norm implementations. In current versions, there's no need for all this. – Fred Foo Oct 20 '13 at 10:04

Here's some concise code for Euclidean distance in Python given two points represented as lists in Python.

``````def distance(v1,v2):
return sum([(x-y)**2 for (x,y) in zip(v1,v2)])**(0.5)
``````
• Numpy also accepts lists as inputs (no need to explicitly pass a numpy array) – Alejandro Sazo Apr 2 '17 at 19:07
``````import numpy as np
from scipy.spatial import distance
input_arr = np.array([[0,3,0],[2,0,0],[0,1,3],[0,1,2],[-1,0,1],[1,1,1]])
test_case = np.array([0,0,0])
dst=[]
for i in range(0,6):
temp = distance.euclidean(test_case,input_arr[i])
dst.append(temp)
print(dst)
``````
``````import math

dist = math.hypot(math.hypot(xa-xb, ya-yb), za-zb)
``````

You can easily use the formula

``````distance = np.sqrt(np.sum(np.square(a-b)))
``````

which does actually nothing more than using Pythagoras' theorem to calculate the distance, by adding the squares of Δx, Δy and Δz and rooting the result.

Calculate the Euclidean distance for multidimensional space:

`````` import math

x = [1, 2, 6]
y = [-2, 3, 2]

dist = math.sqrt(sum([(xi-yi)**2 for xi,yi in zip(x, y)]))
5.0990195135927845
``````

Find difference of two matrices first. Then, apply element wise multiplication with numpy's multiply command. After then, find summation of the element wise multiplied new matrix. Finally, find square root of the summation.

``````def findEuclideanDistance(a, b):
euclidean_distance = a - b
euclidean_distance = np.sum(np.multiply(euclidean_distance, euclidean_distance))
euclidean_distance = np.sqrt(euclidean_distance)
return euclidean_distance
``````