English

Lower bounds for piercing and coloring boxes

Combinatorics 2022-10-12 v2

Abstract

Given a family B\mathcal{B} of axis-parallel boxes in Rd\mathbb{R}^d, let τ\tau denote its piercing number, and ν\nu its independence number. It is an old question whether τ/ν\tau/\nu can be arbitrarily large for given d2d\geq 2. Here, for every ν\nu, we construct a family of axis-parallel boxes achieving τΩd(ν)(logνloglogν)d2.\tau\geq \Omega_d(\nu)\cdot\left(\frac{\log \nu}{\log\log \nu}\right)^{d-2}. This not only answers the previous question for every d3d\geq 3 positively, but also matches the best known upper bound up to double-logarithmic factors. Our main construction has further implications about the Ramsey and coloring properties of configurations of boxes as well. We show the existence of a family of nn boxes in Rd\mathbb{R}^{d}, whose intersection graph has clique and independence number Od(n1/2)(lognloglogn)(d2)/2.O_d(n^{1/2})\cdot \left(\frac{\log n}{\log\log n}\right)^{-(d-2)/2}. This is the first improvement over the trivial upper bound Od(n1/2)O_d(n^{1/2}), and matches the best known lower bound up to double-logarithmic factors. Finally, for every ω\omega satisfying lognloglognωn1ε\frac{\log n}{\log\log n}\ll \omega\ll n^{1-\varepsilon}, we construct an intersection graph of nn boxes with clique number at most ω\omega, and chromatic number Ωd,ε(ω)(lognloglogn)d2.\Omega_{d,\varepsilon}(\omega)\cdot \left(\frac{\log n}{\log\log n}\right)^{d-2}. This matches the best known upper bound up to a factor of Od((logw)(loglogn)d2)O_d((\log w)(\log \log n)^{d-2}).

Keywords

Cite

@article{arxiv.2209.09887,
  title  = {Lower bounds for piercing and coloring boxes},
  author = {István Tomon},
  journal= {arXiv preprint arXiv:2209.09887},
  year   = {2022}
}

Comments

11 pages, improved presentation

R2 v1 2026-06-28T01:45:38.089Z