Point processes are mathematical objects that are defined on some underlying mathematical space. Since these processes are often used to represent collections of points randomly scattered in space, time or both, the underlying space is usually d-dimensional Euclidean space denoted here by, but they can be defined on more abstract mathematical spaces. Point processes have a number of interpretations, which is reflected by the various types of point process notation. For example, if a point belongs to or is a member of a point process, denoted by, then this can be written as: and represents the point process being interpreted as a random set. Alternatively, the number of points of located in some Borel set is often written as: which reflects a random measure interpretation for point processes. These two notations are often used in parallel or interchangeably.
Definitions
Spherical contact distribution function
The spherical contact distribution function is defined as: where b is a ball with radius r centered at the origin o. In other words, spherical contact distribution function is the probability there are no points from the point process located in a hyper-sphere of radius r.
Contact distribution function
The spherical contact distribution function can be generalized for sets other than the sphere in. For some Borel set with positive volume, the contact distribution function for is defined by the equation:
For a Poisson point process on with intensity measure this becomes which for the homogeneous case becomes where denotes the volume of the ball of radius. In the plane, this expression simplifies to
In general, the spherical contact distribution function and the corresponding nearest neighbour function are not equal. However, these two functions are identical for Poisson point processes. In fact, this characteristic is due to a unique property ofPoisson processes and their Palm distributions, which forms part of the result known as the Slivnyak-Mecke or Slivnyak's theorem.
-function
The fact that the spherical distribution function and nearest neighbour function are identical for the Poisson point process can be used to statistically test if point process data appears to be that of a Poisson point process. For example, in spatial statistics the -function is defined for all ≥ 0 as: For a Poisson point process, the function is simply =1, hence why it is used as a non-parametric test for whether data behaves as though it were from a Poisson process. It is, however, thought possible to construct non-Poisson point processes for which =1, but such counterexamples are viewed as somewhat 'artificial' by some and exist for other statistical tests. More generally, -function serves as one way to measure the interaction between points in a point process.