# How to plot N points on the surface of a D-dimensional sphere roughly equidistant apart?

Let's say I have a D-dimensional sphere with center, [C1, C2, C3, C4, ... CD], and a radius R. Now I want to plot N number of points evenly distributed (equidistant apart from each other) on the surface of the sphere. It doesn't matter where those points are exactly, just that they are ROUGHLY equidistant from each other. I want a function that returns an array of these points, P.

``````function plotter(D, C[1...D], R, N)
{
//code to generate the equidistant points on the sphere

return P[1...N][1...D];
}
``````

• The tag says "3D", the question says "D-dimensional sphere". Which is it? There are a number of mechanisms to spread points (somewhat) uniformly over the 2-sphere (that's a sphere in 3 dimensional space). In general there is no nice solution because even the 2-sphere does not form a topological group. The only ones that do are the 0-sphere (a pair of points), the 1-sphere (a circle), and the 3-sphere (one representation of which is the unit quaternions). Commented Oct 3, 2012 at 7:27
• @Ali solutions involving random points are just one class of solutions to this problem. I for instance would be interested in a solution that would involve creating a n-sphere as an extruded (n-1)-sphere (though I don't know if that can be done, but it seems realistic). Commented Oct 3, 2012 at 15:12
• I don't see why this is a duplicate : here, the question is to generate evenly distributed points. This is not necessarily the same as randomly distributed (although this can be an option if we have a flexible definition of "evenly"). Commented Oct 5, 2012 at 1:38
• Commented Oct 5, 2012 at 2:14
• It's easy to come up with an algorithm to do this, but whether it's practical depends on D and the total number of points. If D is small, 2 (very easy), 3 or 4, some of the answers suggesting annealing or repulsion might work. But if D is say fifty, and P is a few million, that's not the way to do it. Commented Oct 12, 2012 at 5:54

Several options :

• Randomly throw points on the sphere and use a Lloyd relaxation to make them uniformly spread : you iteratively compute their Voronoi diagram and move them toward the center of their Voronoi cell (instead of working on the sphere, you may want to use an euclidean voronoi diagram restricted to the sphere : CGAL can fo that for instance, or refer to my article).

• If a rough approximation is fine (ie., if a uniformly random distribution is good enough), you can use the formula explained on Wiki : N-Sphere . If not, you can still use this random sampling as the initialization of the method above

• For a still random but better notion of equidistant samples, you can generate a Poisson-disk distribution. Fast code in high dimension is available at Robert Bridson's homepage . You may need to adapt it for a spherical domain though.

I don't know if this has been mentioned here yet; but you could, as others have suggested draw points from the uniform distribution on the sphere. After which, flow each point according to columb energy; using a gradient descent method. This particular problem has received a lot of attention. Check out the following paper and this website

• As a plug I've written python code for generating well-ordered distributions of points on the sphere. Commented Feb 13, 2014 at 21:20
• Do you know where to find an implementation for the n-sphere? (n>2)
– gota
Commented Mar 2, 2018 at 15:09
• @gota don't know. But I don't see why one couldn't apply a technique for S^2 to higher dimensional spheres. Commented Mar 11, 2018 at 21:03

The only way I can think of that should produce good results is.

1. Generate N points on the sphere surface. The usual way to do this for high dimensions is to generate the points acording to an D-dimensional normal distribution and normalise back to the sphere. These will not be equally spaced - so we need step two
2. Next make each point repel other points using some repulsions function and use a small time-step, you adjust the direction of movement to be tangential to the D-Sphere. Move the point and then repoject back to the sphere. Keep doing this until you consider the points even enough.