# Generating a random displacement on the unit sphere

Given a unit vector n, I need to generate, as fast as possible, another random unit vector m. The deviation of m from n should be on the order of a positive parameter `sigma`, and the distribution of m on the unit sphere should be symmetrical around n.

I have no specific requirements on the representation of unit vectors, so you can use spherical angles, Cartesian coordinates, or whatever turns out to be convenient. Also, there are no precise requirements on the probability distributions used, as long as it decays when m deviates more than `sigma` from n.

I am working with `gsl` and `C`. I have come up with a somewhat convoluted method using Cartesian coordinates. I will post it later if it is useful, but I would like to see people's ideas.

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To clarify: does `The deviation of m from n should be on the order of a positive parameter sigma` mean `The angle between m and n should be normally distributed with mean 0 and standard deviation sigma`? – japreiss Sep 10 '12 at 21:40
@japreiss Something like that. But since I don't want place any restrictions on the coordinates used, perhaps someone finds it more convenient to use the distance between m and n instead of the angle. That's why I wasn't precise. – becko Sep 11 '12 at 11:03

You probably know that vectors with each dimension uniformly distributed about `0` result in a cube of points with more values concentrated in the corners. But vectors with each dimension normally distributed about `0` are much nicer. The points' polar angles are uniformly distributed on the unit sphere, and their radii are concentrated near the origin. You can generate vectors like this, changing the standard deviation based on your parameter `sigma`. Add the vectors to `n`, normalize the result, and call it good.