# Sampling with multidimensional transformations

Technical Mathematics Question For Ray Tracing... (I am not sure if I have the title right, but here is my problem) I am writing a raytracer and I need to shoot a rays in a random direction. I have a ray which 'should be' shot vertically from a point p, but depending on the situation it can: 1) either be shot in any direction in the hemisphere above p 2) shot with an angle of no more than σ off the vertical 3) shot with an angle of no more than σ off the vertical by with a Gaussian distribution (See http://imgur.com/BMqWjoQ)

---First--- I wish to generate a point uniformly distributed on a hemisphere. I did some derivations and I came up with:

`````` θ = acos(R1);
∅= 2∏R2;
x = sinθcos∅=cos(2∏R2)sqrt(1-R1^2);
y = sinθsin∅=sin(2∏R2)sqrt(1-R1^2);
z=cosθ=R1;
``````

I confirmed this with a text book, So Im pretty sure its right--- Second--- I want to generate a point uniformly but only within a small solid angle subtended by angle σ Similar derivation as before but the values for theta and phi are

θ=acos(1-(1-cos(σ)*R1))

∅= 2∏R2

Im pretty sure this is also right

Third: (now this is where I need help) Instead of using a uniform distribution I would like to use a Gaussian distribution. I know Box Muller is one way of generating random number with a normal distribution (given a set of canonical numbers) but how do I use that now to generate ray directions that are normally distributed? Can I simply just use Z1 and Z2 in place of R1 and R2 (where Z1 and Z2 are random numbers generated with Box Muller). If so, why is that possible? Is it because the multidimensional densities are separable?