# How to randomize points on a sphere surface evenly?

Im trying to make stars on the sky, but the stars distribution isnt even.

This is what i tried:

``````rx = rand(0.0f, PI*2.0f);
ry = rand(0.0f, PI);
x = sin(ry)*sin(rx)*range;
y = sin(ry)*cos(rx)*range;
z = cos(ry)*range;
``````

Which results to:

And:

``````rx = rand(-1.0f, 1.0f);
ry = rand(-1.0f, 1.0f);
rz = rand(-1.0f, 1.0f);
x = rx*range;
y = ry*range;
z = rz*range;
``````

Which results to:

(doesnt make a sphere, but opengl will not tell a difference, though).

As you can see, there is always some "corner" where are more points in average. How can i create random points on a sphere where the points will be distributed evenly?

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One of those is surely a duplicate... –  AakashM Jan 12 '12 at 17:09

you can do

``````z = rand(-1, 1)
rxy = sqrt(1 - z*z)
phi = rand(0, 2*PI)
x = rxy * cos(phi)
y = rxy * sin(phi)
``````

Here rand(u,v) draws a uniform random from interal [u,v]

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I think that will concentrate the results near Z's poles, no? –  Drew Dormann Jan 12 '12 at 17:10
No. It can be derived mathematically. –  icando Jan 12 '12 at 17:14
this works perfectly! accepting in 2mins... –  Rookie Jan 12 '12 at 17:15
@icando: If Z is a mathematically even distribution from `-1` to `1`, then points near z:0 will be much more spread out than points near z:1 or z:-1 –  Drew Dormann Jan 12 '12 at 17:20
@Drew, no. Suppose z = sin(t) and we choose z evenly distributed, so the probability a point is in [t, t+dt] is dP = 0.5dz = 0.5cos(t)dt. The surface area of the band [t, d+dt] is dS = 2PIcos(t)dt, so the density is dP/dS=(4PI)^-1, which is not a function of t. –  icando Jan 12 '12 at 17:30

You don't need trigonometry if you can generate random gaussian variables, you can do (pseudocode)

``````x <- gauss()
y <- gauss()
z <- gauss()
norm <- sqrt(x^2 + y^2 + z^2)

result = (x / norm, y / norm, z / norm)
``````

Or draw points inside the unit cube until one of them is inside the unit ball, then normalize:

``````double x, y, z;

do
{
x = rand(-1, 1);
y = rand(-1, 1);
z = rand(-1, 1);
} while (x * x + y * y + z * z > 1);

double norm = sqrt(x * x + y * y + z * z);
x / norm; y /= norm; z /= norm;
``````
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i thought about that latter, but i also thought that is quite slow: half of calculations are wasted because they get outside of sphere. im using icando's method now, and it really seems to work perfectly and is very fast too. –  Rookie Jan 12 '12 at 17:34
@Rookie: Since trigonometric functions are expensive, and you can get cheap `rand` functions (the rand functions I use on a daily basis take less than 10 cycles, compared to ~100 cycles for each call to `cos`). I'd suggest profiling to see which is slower. Remember premature optimization blah blah. –  Alexandre C. Jan 12 '12 at 20:44
I benchmarked just for you: 88.3ms with icando's method, 128.5ms with yours! i calculated 500k points. doesnt the CPU's have sin/cos somehow optimized these days...? oh, and i used mersenne rand. –  Rookie Jan 13 '12 at 13:29
@Rookie: Mersenne is heavy and 15 years old. A simple Marsiglia XOR-Shift is many times superior. Also, sine and cosine are not that fast (around 100 cycles). –  Alexandre C. Jan 13 '12 at 15:03
i thought mersenne was the best... PHP uses it for example and they call it best etc. –  Rookie Jan 13 '12 at 16:38