Stein’s method, Palm theory and Poisson process approximation

Stein’s method, Palm theory and Poisson process approximation

Louis H. Y. Chen and Aihua Xia

Source: Ann. Probab. Volume 32, Number 3B (2004), 2545-2569.

Abstract

The framework of Stein’s method for Poisson process approximation is presented from the point of view of Palm theory, which is used to construct Stein identities and define local dependence. A general result (Theorem 2.3) in Poisson process approximation is proved by taking the local approach. It is obtained without reference to any particular metric, thereby allowing wider applicability. A Wasserstein pseudometric is introduced for measuring the accuracy of point process approximation. The pseudometric provides a generalization of many metrics used so far, including the total variation distance for random variables and the Wasserstein metric for processes as in Barbour and Brown [Stochastic Process. Appl. 43 (1992) 9–31]. Also, through the pseudometric, approximation for certain point processes on a given carrier space is carried out by lifting it to one on a larger space, extending an idea of Arratia, Goldstein and Gordon [Statist. Sci. 5 (1990) 403–434]. The error bound in the general result is similar in form to that for Poisson approximation. As it yields the Stein factor 1/λ as in Poisson approximation, it provides good approximation, particularly in cases where λ is large. The general result is applied to a number of problems including Poisson process modeling of rare words in a DNA sequence.

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Primary Subjects: 60G55

Secondary Subjects: 60E15, 60E05

Keywords: Stein’s method; point process; Poisson process approximation; Palm process; Wasserstein pseudometric; local approach; local dependence

Full-text: Open access

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Links and Identifiers

Permanent link to this document: http://projecteuclid.org/euclid.aop/1091813623
Digital Object Identifier: doi:10.1214/009117904000000027
Mathematical Reviews number (MathSciNet): MR2078550
Zentralblatt MATH identifier: 1057.60051

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