Title: Transforming Spatial Point Processes into Poisson Processes Using Random Superposition
Abstract: Most finite spatial point process models specified by a density are locally stable, implying that the Papangelou intensity is bounded by some integrable function β defined on the space for the points of the process. It is possible to superpose a locally stable spatial point process X with a complementary spatial point process Y to obtain a Poisson process X ⋃ Y with intensity function β . Underlying this is a bivariate spatial birth-death process ( X t , Y t ) which converges towards the distribution of ( X , Y ). We study the joint distribution of X and Y , and their marginal and conditional distributions. In particular, we introduce a fast and easy simulation procedure for Y conditional on X . This may be used for model checking: given a model for the Papangelou intensity of the original spatial point process, this model is used to generate the complementary process, and the resulting superposition is a Poisson process with intensity function β if and only if the true Papangelou intensity is used. Whether the superposition is actually such a Poisson process can easily be examined using well-known results and fast simulation procedures for Poisson processes. We illustrate this approach to model checking in the case of a Strauss process.