Complete spatial randomness (CSR) describes a point process whereby point events occur within a given study area in a completely random fashion. It is synonymous with a homogeneous spatial Poisson process.[1] Such a process is modeled using only one parameter
\rho
Data in the form of a set of points, irregularly distributed within a region of space, arise in many different contexts; examples include locations of trees in a forest, of nests of birds, of nuclei in tissue, of ill people in a population at risk. We call any such data-set a spatial point pattern and refer to the locations as events, to distinguish these from arbitrary points of the region in question. The hypothesis of complete spatial randomness for a spatial point pattern asserts that the number of events in any region follows a Poisson distribution with given mean count per uniform subdivision. The events of a pattern are independently and uniformly distributed over space; in other words, the events are equally likely to occur anywhere and do not interact with each other.
"Uniform" is used in the sense of following a uniform probability distribution across the study region, not in the sense of “evenly” dispersed across the study region.[2] There are no interactions amongst the events, and the intensity of events does not vary over the plane. For example, the independence assumption would be violated if the existence of one event either encouraged or inhibited the occurrence of other events in the neighborhood.
The probability of finding exactly
k
V
\rho
P(k,\rho,V)=
| (V\rho)ke-(V\rho) | |
| k! |
.
The first moment of which, the average number of points in the area, is simply
\rhoV
The probability of locating the
Nth
r
PN(r)=
| D | |
| (N-1)! |
{λ}NrDN-1
| -λrD | |
| e |
,
where
D
λ
λ=
| ||||||||||
|
\Gamma
\Gamma(n+1)=n!
n
The expected value of
PN(r)
D
The study of CSR is essential for the comparison of measured point data from experimental sources. As a statistical testing method, the test for CSR has many applications in the social sciences and in astronomical examinations.[3] CSR is often the standard against which data sets are tested. Roughly described one approach to test the CSR hypothesis is the following:[4]
In cases where computing test statistics analytically is difficult, numerical methods, such as the Monte Carlo method simulation are employed, by simulating a stochastic process a large number of times.[4]