English

Gravitational allocation to Poisson points

Probability 2017-03-14 v2

Abstract

For d>=3, we construct a non-randomized, fair and translation-equivariant allocation of Lebesgue measure to the points of a standard Poisson point process in R^d, defined by allocating to each of the Poisson points its basin of attraction with respect to the flow induced by a gravitational force field exerted by the points of the Poisson process. We prove that this allocation rule is economical in the sense that the "allocation diameter", defined as the diameter X of the basin of attraction containing the origin, is a random variable with a rapidly decaying tail. Specifically, we have the tail bound: P(X > R) < C exp[ -c R(log R)^(alpha_d) ], for all R>2, where: alpha_d = (d-2)/d for d>=4; alpha_3 can be taken as any number <-4/3; and C,c are positive constants that depend on d and alpha_d. This is the first construction of an allocation rule of Lebesgue measure to a Poisson point process with subpolynomial decay of the tail P(X>R).

Keywords

Cite

@article{arxiv.math/0611886,
  title  = {Gravitational allocation to Poisson points},
  author = {Sourav Chatterjee and Ron Peled and Yuval Peres and Dan Romik},
  journal= {arXiv preprint arXiv:math/0611886},
  year   = {2017}
}

Comments

69 pages, 6 figures; substantially revised and corrected; new proof of a part of Theorem 10 (formerly Theorem 9)