English

Improved bounds for Hadwiger's covering problem via thin-shell estimates

Metric Geometry 2022-07-12 v2 Functional Analysis

Abstract

A central problem in discrete geometry, known as Hadwiger's covering problem, asks what the smallest natural number N(n)N\left(n\right) is such that every convex body in Rn{\mathbb R}^{n} can be covered by a union of the interiors of at most N(n)N\left(n\right) of its translates. Despite continuous efforts, the best general upper bound known for this number remains as it was more than sixty years ago, of the order of (2nn)nlnn{2n \choose n}n\ln n. In this note, we improve this bound by a sub-exponential factor. That is, we prove a bound of the order of (2nn)ecn{2n \choose n}e^{-c\sqrt{n}} for some universal constant c>0c>0. Our approach combines ideas from previous work by Artstein-Avidan and the second named author with tools from Asymptotic Geometric Analysis. One of the key steps is proving a new lower bound for the maximum volume of the intersection of a convex body KK with a translate of K-K; in fact, we get the same lower bound for the volume of the intersection of KK and K-K when they both have barycenter at the origin. To do so, we make use of measure concentration, and in particular of thin-shell estimates for isotropic log-concave measures. Using the same ideas, we establish an exponentially better bound for N(n)N\left(n\right) when restricting our attention to convex bodies that are ψ2\psi_{2}. By a slightly different approach, an exponential improvement is established also for classes of convex bodies with positive modulus of convexity.

Keywords

Cite

@article{arxiv.1811.12548,
  title  = {Improved bounds for Hadwiger's covering problem via thin-shell estimates},
  author = {Han Huang and Boaz A. Slomka and Tomasz Tkocz and Beatrice-Helen Vritsiou},
  journal= {arXiv preprint arXiv:1811.12548},
  year   = {2022}
}

Comments

references updated, remark on Ehrhard's conjecture added

R2 v1 2026-06-23T06:26:20.678Z