English

Random Euclidean coverage from within

Probability 2022-01-12 v3

Abstract

Let X1,X2,X_1,X_2, \ldots be independent random uniform points in a bounded domain ARdA \subset \mathbb{R}^d with smooth boundary. Define the coverage threshold RnR_n to be the smallest rr such that AA is covered by the balls of radius rr centred on X1,,XnX_1,\ldots,X_n. We obtain the limiting distribution of RnR_n and also a strong law of large numbers for RnR_n in the large-nn limit. For example, if AA has volume 1 and perimeter A|\partial A|, if d=3d=3 then Pr[nπRn3logn2log(logn)x]\Pr[n\pi R_n^3 - \log n - 2 \log (\log n) \leq x] converges to exp(24π5/3Ae2x/3)\exp(-2^{-4}\pi^{5/3} |\partial A| e^{-2 x/3}) and (nπRn3)/(logn)1(n \pi R_n^3)/(\log n) \to 1 almost surely, and if d=2d=2 then Pr[nπRn2lognlog(logn)x]\Pr[n \pi R_n^2 - \log n - \log (\log n) \leq x] converges to exp(exAπ1/2ex/2)\exp(- e^{-x}- |\partial A|\pi^{-1/2} e^{-x/2}). We give similar results for general dd, and also for the case where AA is a polytope. We also generalize to allow for multiple coverage. The analysis relies on classical results by Hall and by Janson, along with a careful treatment of boundary effects. For the strong laws of large numbers, we can relax the requirement that the underlying density on AA be uniform.

Keywords

Cite

@article{arxiv.2101.06306,
  title  = {Random Euclidean coverage from within},
  author = {Mathew D. Penrose},
  journal= {arXiv preprint arXiv:2101.06306},
  year   = {2022}
}

Comments

67 pages, 4 figures

R2 v1 2026-06-23T22:13:05.111Z