According to this article in Wikipedia: A billiard is a dynamical system in which a particle alternates between motion in a straight line and specular reflections from a boundary. When the particle hits the boundary it reflects from it without loss of speed. Billiard dynamical systems are Hamiltonian idealizations of the game of billiards, but where the region contained by the boundary can have shapes other than rectangular and even be multidimensional.
My question is motivated by a videogame I've been playing lately, which can be seen at http://www.youtube.com/watch?v=LLLmfwxNJYU.
Essentially, the "physics" of the game involves several billiards in a polygon, and the player has to slash off pieces of the polygon while avoiding the billiards. Also, the removed piece has to be void of billiards.
I've been assuming that the distribution of billiards is in the long run uniform, in some hand waving sense. That's assuming that initial distributions and velocities are random. Is that true, or can the polygon be shaped in various ways to make that distribution non-uniform? In other words, are certain regions of a polygon are more likely to be void than other regions?
(I believe that a term like "ergodic" applies to this, but I'm not confident using it).
A periodic billiard path is one which returns to a point with the same direction it had before at that point. A dense billiard path is one that covers the whole region. (A periodic billiard path is not dense and thus cannot be uniformly distributed.)
Many polygons have periodic billiard paths. (For example, every acute triangle and every right triangle has a periodic billiard path. But it is not yet known whether every obtuse triangle has a periodic billiard path.) So it is possible for a polygon to have a path that is not dense and thus not uniformly distributed.
It is possible for a billiard path to be dense and yet not be uniformly distributed. This is true for the triangle with angles $0.4\pi,0.3\pi,0.3\pi$. (See, for example, theorem 1.3 of http://homepages.math.uic.edu/~demarco/billiards.pdf.)
You might also want to visit https://mathoverflow.net/questions/53641/dense-orbits-in-billiards.