# Sampling uniformly distributed random points inside a spherical volume

I am looking to be able to generate a random uniform sample of particle locations that fall within a spherical volume.

The image below (courtesy of http://nojhan.free.fr/metah/) shows what I am looking for. This is a slice through the sphere, showing a uniform distribution of points:

This is what I am currently getting:

You can see that there is a cluster of points at the center due to the conversion between spherical and Cartesian coordinates.

The code I am using is:

def new_positions_spherical_coordinates(self):
theta = numpy.random.uniform(0.,1.,(self.number_of_particles,1))*pi
phi = numpy.arccos(1-2*numpy.random.uniform(0.0,1.,(self.number_of_particles,1)))
x = radius * numpy.sin( theta ) * numpy.cos( phi )
y = radius * numpy.sin( theta ) * numpy.sin( phi )
z = radius * numpy.cos( theta )
return (x,y,z)


Below is some MATLAB code that supposedly creates a uniform spherical sample, which is similar to the equation given by http://nojhan.free.fr/metah. I just can't seem to decipher it or understand what they did.

function X = randsphere(m,n,r)

% This function returns an m by n array, X, in which
% each of the m rows has the n Cartesian coordinates
% of a random point uniformly-distributed over the
% interior of an n-dimensional hypersphere with
% radius r and center at the origin.  The function
% 'randn' is initially used to generate m sets of n
% random variables with independent multivariate
% normal distribution, with mean 0 and variance 1.
% Then the incomplete gamma function, 'gammainc',
% is used to map these points radially to fit in the
% hypersphere of finite radius r with a uniform % spatial distribution.
% Roger Stafford - 12/23/05

X = randn(m,n);
s2 = sum(X.^2,2);
X = X.*repmat(r*(gammainc(s2/2,n/2).^(1/n))./sqrt(s2),1,n);


I would greatly appreciate any suggestions on generating a truly uniform sample from a spherical volume in Python.

There seem to be plenty of examples showing how to sample from a uniform spherical shell, but that seems to be easier an easier problem. The issue has to do with the scaling - there should be fewer particles at a radius of 0.1 than at a radius of 1.0 to generate a uniform sample from the volume of the sphere.

Edit: Fixed and removed the fact I asked for normally and I meant uniform.

• depending on your purposes, it can also be usefull to look at quasi-random numbers instead of (software) random numbers Commented Dec 1, 2015 at 12:02

While I prefer the discarding method for spheres, for completeness I offer the exact solution.

In spherical coordinates, taking advantage of the sampling rule:

phi = random(0,2pi)
costheta = random(-1,1)
u = random(0,1)

theta = arccos( costheta )
r = R * cuberoot( u )


now you have a (r, theta, phi) group which can be transformed to (x, y, z) in the usual way

x = r * sin( theta) * cos( phi )
y = r * sin( theta) * sin( phi )
z = r * cos( theta )

• I feel like an idiot now. All I had to do was take the cube root of the radius? Perfect thanks for your patience and continuous part in the discussion :) Commented Mar 23, 2011 at 17:03
• @Tim: As I said in the comments to Jim's answer, most books prefer the discard method for spheres. Even with hardware support cube roots take a few cycles, and the trig needed to get back to Cartesian coordinates cost some time too. Also note that I've hidden a second application of this method by drawing costheta uniformly. Commented Mar 23, 2011 at 17:06
• Ah okay I get it. The cost of running the cubed root for all of them is more than the cost of everything thrown out. I think I will do it both ways and allow me to decide on use of the function. Anyways thank you again for your help! Commented Mar 23, 2011 at 17:26
• what is R, u, and costheta. I'm assuming R is the magnitude but why is u randomly generated? Commented Sep 5, 2017 at 0:13
• @Archmede The variable u is merely a dummy to make the steps clear. The reason for taking the cube root of a uniform sample is buried in the fundamental theorem of sampling which I explain in the linked questions. You're right about R (for radius because I'm a physicists) and costheta is the cosine of theta (thrown this way because of the sampling theorem again). Commented Sep 5, 2017 at 1:11

There is a brilliant way to generate uniformly points on sphere in n-dimensional space, and you have pointed this in your question (I mean MATLAB code).

Why does it work? The answer is: let us look at the probability density of n-dimensional normal distribution. It is equal (up to constant)

exp(-x_1*x_1/2) *exp(-x_2*x_2/2)... = exp(-r*r/2), so it doesn't depend on the direction, only on the distance! This means, after you normalize vector, the resulting distribution's density will be constant across the sphere.

This method should be definitely preferred due to it's simplicity, generality and efficiency (and beauty). The code, which generates 1000 events on the sphere in three dimensions:

size = 1000
n = 3 # or any positive integer
x = numpy.random.normal(size=(size, n))
x /= numpy.linalg.norm(x, axis=1)[:, numpy.newaxis]


BTW, the good link to look at: http://www-alg.ist.hokudai.ac.jp/~jan/randsphere.pdf

As for having uniform distribution within a sphere, instead of normalizing a vector, you should multiply vercor by some f(r): f(r)*r is distributed with density proportional to r^n on [0,1], which was done in the code you posted

• If you have a spare minute, could you look at this question please? stackoverflow.com/q/47472123/3791466 Commented Nov 24, 2017 at 11:23
• This will return points on the surface of the sphere, not inside the volume. Commented Dec 7, 2020 at 21:42
• @JoanSolà yes, it is written in bold Commented Dec 8, 2020 at 9:51
• @Alleo true, I missed it! But it looks like a side note. It'd be good to have the code already for the ball volume, not for the surface and then the final note. Commented Dec 9, 2020 at 11:47

Generate a set of points uniformly distributed within a cube, then discard the ones whose distance from the center exceeds the radius of the desired sphere.

• Good call. Discarding is fairly efficient for spheres, and is recommended in many texts as being faster than the transform needed to sample exactly. Commented Mar 23, 2011 at 16:29
• I thought of that idea, but that would lose ~50% of the total points created. So to create 16,000 particles it would create ~32,000. Since Area of cube is r^3 and sphere is 4/3*pi*(r/2)^3 = so the ratio = ~4/8 = .5 Commented Mar 23, 2011 at 16:31
• This wouldn't result a normal distribution, which is what @Tim was asking for. Normal distribution isn't the same as uniform distribution. Commented Mar 23, 2011 at 16:40
• Oh @Juanchopanza I messed up. I meant uniform. I am going to go fix that now. Commented Mar 23, 2011 at 16:42
• Note that this is not efficient for high dimensions since the volume of the unit ball goes to zero (=probability for sampling a point within the ball). Commented Jun 4, 2015 at 8:23

I agree with Alleo. I translated your Matlab code to Python and it can generate thousands of points very fast (a fraction of second in my computer for 2D and 3D). I've even ran it for up to 5D hyperspheres. I found your code so useful that I'm applying it in a study. Tim McJilton, who should I add as reference?

import numpy as np
from scipy.special import gammainc
from matplotlib import pyplot as plt
ndim = center.size
x = np.random.normal(size=(n_per_sphere, ndim))
ssq = np.sum(x**2,axis=1)
fr = r*gammainc(ndim/2,ssq/2)**(1/ndim)/np.sqrt(ssq)
frtiled = np.tile(fr.reshape(n_per_sphere,1),(1,ndim))
p = center + np.multiply(x,frtiled)
return p

fig1 = plt.figure(1)
ax1 = fig1.gca()
center = np.array([0,0])
ax1.scatter(p[:,0],p[:,1],s=0.5)
ax1.set_xlim(-1.5,1.5)
ax1.set_ylim(-1.5,1.5)
ax1.set_aspect('equal')


Would this be uniform enough for your purposes?

In []: p= 2* rand(3, 1e4)- 1
In []: p= p[:, sum(p* p, 0)** .5<= 1]
In []: p.shape
Out[]: (3, 5216)


A slice of it

In []: plot(p[0], p[2], '.')


looks like:

• This is the same thing that Jim Lewis suggested right? Create a uniform cube and toss out anything not in the sphere? Commented Mar 23, 2011 at 16:34
• @Tim McJilton: Yes, I was typing it while Jim's answer come in and since it's code I'll decided to publish it anyway. Anyway nothing suggested in your question that generating more points actually needed would be someway problematic. Care to elaborate more? Thanks
– eat
Commented Mar 23, 2011 at 16:39
• I am running a simulation of 16,000 + stars with both velocity and and position locations which I want to be uniform. I was hoping to have a way where I can set the amount of points to keep since I need exactly 16,000 or whatnot. Your way would work and I guess I could keep adding points 1 by 1 till we have 16,000 enclosed. Commented Mar 23, 2011 at 16:47
• @Tim McJilton: FWIW, in my (very) modest machine generating 1e5 3d uniform random points and discarding outsiders (yielding to some 5.3e4 points), takes some 35 ms. If this kind of performance is not applicable to you, please give us more details. Thanks
– eat
Commented Mar 23, 2011 at 17:02
• @Tim McJilton: now seeing dmckee's answer I think it's the correct answer for this situation (exact number of points in sphere). However in general it does not scale quite so easily to higher dimensions (, if that ever matters). Thanks
– eat
Commented Mar 23, 2011 at 17:27

Normed gaussian 3d vector is uniformly distributed on sphere, see http://mathworld.wolfram.com/SpherePointPicking.html

For example:

N = 1000
v = numpy.random.uniform(size=(3,N))
vn = v / numpy.sqrt(numpy.sum(v**2, 0))

• The uniform should be normal. uniform means uniform distribution while normal means gaussian distribution Commented Jan 7, 2019 at 7:37
import random
R = 2

def sample_circle(center):
a = random.random() * 2 * np.pi
r = R * np.sqrt(random.random())
x = center[0]+ (r * np.cos(a))
y = center[1] + (r * np.sin(a))
return x,y

ps = np.array([sample_circle((0,0)) for i in range(100)])

plt.plot(ps[:,0],ps[:,1],'.')
plt.xlim(-3,3)
plt.ylim(-3,3)
plt.show()


## Function to Sample Uniformly from a Hypersphere

The function below uniformly samples points from a hypersphere:

import numpy as np

# initial values
d = center.shape[0]

# sample n_samples points in d dimensions from a standard normal distribution
rng = np.random.default_rng(seed)
samples = rng.normal(size=(n_samples, d))

# make the samples lie on the surface of the unit hypersphere

# make the samples lie inside the hypersphere with the correct density
uniform_points = rng.uniform(size=n_samples)[:, np.newaxis]

# scale the points to have the correct radius and center
samples = samples * radius + center
return samples


This code works as follows.

First, it first generates n datapoints in d dimensions from a standard normal distribution. We specifically sample from a normal distribution because normal distributions are isotropic, meaning it is uniform in all orientations. This works great for creating a hypersphere where must be uniform/the same in all orientations.

Second, it computes the radius of each datapoint with np.linalg.norm(). (Note: np.linalg.norm() calls the Euclidean norm which equals the radius because r^2 = x^2 + y^2 in 2D and more generally r^2 = \sum_{i=1}^d x_i^2 which is the equation for Euclidean distance.) It divides each point by its radius to normalize the radius to length 1. This is equivalent to making all the datapoints lie on the surface of the unit hypersphere with radius r=1.

Third, it creates a new radius for each of the n_samples datapoints by generating n_samples points from a uniform distribution and then taking the dth root of each of these points. Why do we do this? Consider the 2D case where we want to sample points uniformly on a circle. If we divide this circle into concentric rings, then the ring right by the circle's center will have few points on it while the ring by the circumference will have many more points on it. More generally, the larger the radius, the more points we will need to generate. More precisely, achieving uniform sampling across radii of varying lengths requires a probability distribution proportional to the D-th power of the radius r. We can express this as F(r) \alpha r^d where F(r) is the number of points radius r away from the origin that give us a uniform distribution. We begin with a uniform distribution of points in uniform_points and can rearrange the equation above as F(r)^{1\d} \alpha r, meaning we must take the dth root of the uniformly distributed radii.

Fourth, this code scales all the points on the surface of the unit hypersphere by this new radius, distributing these points uniformly across the volume of the hypersphere. It then shifts these points over to have the desired center.

## Function Performance

My code is much faster than @Daniel's code which relies upon scipy's gammainc function which is quite expensive to evaluate. I benchmark the performance here:

def time_it():

# initial values
d = 20
center, radius = np.full(d, 2), 3
n_samples_list = np.logspace(3, 6, num=10).astype(int)
runtime_my_code, runtime_daniel_code = [], []

for n_samples in n_samples_list:

# time my code
start = time.perf_counter()
end = time.perf_counter()
duration = end - start
runtime_my_code.append(duration)

# time Daniel's code
start = time.perf_counter()
end = time.perf_counter()
duration = end - start
runtime_daniel_code.append(duration)

# plot the results
fig, ax = plt.subplots()
ax.scatter(n_samples_list, runtime_my_code)
ax.scatter(n_samples_list, runtime_daniel_code)
ax.plot(n_samples_list, runtime_my_code, label='my code')
ax.plot(n_samples_list, runtime_daniel_code, label='daniel\'s code')
ax.set(xlabel='n_samples',
ylabel='runtime (s)', title='runtime VS n_samples')
plt.legend()
fig.savefig('runtime_vs_n_samples.png')


This diagram makes it clear that my code is much more efficient than Daniel's.

## Other resources

Check out this helpful guide to sampling from a hypersphere here. It clearly explains why this math works.

You can just generate random points in spherical coordinates (assuming that you are working in 3D): S(r, θ, φ ), where r ∈ [0, R), θ ∈ [0, π ], φ ∈ [0, 2π ), where R is the radius of your sphere. This would also allow you directly control how many points are generated (i.e. you don't need to discard any points).

To compensate for the loss of density with the radius, you would generate the radial coordinate following a power law distribution (see dmckee's answer for an explanation on how to do this).

If your code needs (x,y,z) (i.e. cartesian) coordinates, you would then just convert the randomly generated points in spherical to cartesian coordinates as explained here.

• That is what my code is doing. The problem happens when you convert it to polar co-ordinates it has an even amount of particles at radius R, as there at radius r < R which causes the center to be more dense than the edges Commented Mar 23, 2011 at 16:46
• To make this work, you must draw the radial position non-uniformaly. Because the volume element is r^2 dr d\phi d(cos\theta). And this involves extracting a cube root and one inverse cosine, so it tend to be slower than the discarding procedure. Commented Mar 23, 2011 at 16:48
• Got it. Then discarding points is probably easier. If you still want to do it without discarding points, you need to generate the radial coordinate following a power law distribution. Unfortunately, sampling from non-trivial distributions is not easy, but if you are still interested, see the Metropolis-Hastings algorithm for a general method (any other MCMC method would also work). Commented Mar 23, 2011 at 16:52
• Do not, I repeat not use Metropolis for this! Sampling power law distributions is easy, just not trivial. Commented Mar 23, 2011 at 16:56
• @AmV: It is sometimes called the Fundamental Law of Sampling. I discuss it in other contexts in the two links in my answer here. You normalize your PDF, integrate then invert it, and use the resulting function to transform values drawn uniformly over [0,1). In this case it comes down to taking a cube root. Commented Mar 23, 2011 at 17:03

import numpy as np
import matplotlib.pyplot as plt

r= 30.*np.sqrt(np.random.rand(1000))
#r= 30.*np.random.rand(1000)
phi = 2. * np.pi * np.random.rand(1000)

x = r * np.cos(phi)
y = r * np.sin(phi)

plt.figure()
plt.plot(x,y,'.')
plt.show()

this is what you want

• You are answering this years later. There are two correct answers already mentioned here. Your example is for a uniform circle, not a uniform sphere. You have no Z Coordinate... ? Commented Feb 21, 2018 at 18:51