I am trying to generate uniform random points on the surface of a unit sphere for a Monte Carlo ray tracing program. When I say uniform I mean the points are uniformly distributed with respect to surface area. My current methodology is to calculate uniform random points on a hemisphere pointing in the positive z axis and base in the x-y plane.

The random point on the hemisphere represents the direction of emission of thermal radiation for a diffuse grey emitter.

**I achieve the correct result when I use the following calculation :**

**Note : dsfmt* is will return a random number between 0 and 1.**

```
azimuthal = 2*PI*dsfmt_genrand_close_open(&dsfmtt);
zenith = asin(sqrt(dsfmt_genrand_close_open(&dsfmtt)));
// Calculate the cartesian point
osRay.c._x = sin(zenith)*cos(azimuthal);
osRay.c._y = sin(zenith)*sin(azimuthal);
osRay.c._z = cos(zenith);
```

However this is quite slow and profiling suggests that it takes up a large proportion of run time. Therefore I sought out some alternative methods:

**The Marsaglia 1972 rejection method**

```
do {
x1 = 2.0*dsfmt_genrand_open_open(&dsfmtt)-1.0;
x2 = 2.0*dsfmt_genrand_open_open(&dsfmtt)-1.0;
S = x1*x1 + x2*x2;
} while(S > 1.0f);
osRay.c._x = 2.0*x1*sqrt(1.0-S);
osRay.c._y = 2.0*x2*sqrt(1.0-S);
osRay.c._z = abs(1.0-2.0*S);
```

**Analytical cartesian coordinate calculation**

```
azimuthal = 2*PI*dsfmt_genrand_close_open(&dsfmtt);
u = 2*dsfmt_genrand_close_open(&dsfmtt) -1;
w = sqrt(1-u*u);
osRay.c._x = w*cos(azimuthal);
osRay.c._y = w*sin(azimuthal);
osRay.c._z = abs(u);
```

While these last two methods run serval times faster than the first, when I use them I get results which indicate that they are not generating uniform random points on the surface of a sphere but rather are giving a distribution which favours the equator.

Additionally the last two methods give identical final results however I am certain that they are incorrect as I am comparing against an analytical solution.

Every reference I have found indicates that these methods do produce uniform distributions however I do not achieve the correct result.

Is there an error in my implementation or have I missed a fundamental idea in the second and third methods?

`sin(asin(x))`

is equivalent to using`x`

with possible sign changes. When you know`cos(z)`

, you can calculate`sin(z)`

from the equality cos(z)^2 + sin(z)^2 = 1. – quant_dev Sep 2 '11 at 7:46