English

The Quantitative Fractional Helly theorem

Combinatorics 2024-05-22 v2 Computational Geometry Metric Geometry

Abstract

Two celebrated extensions of Helly's theorem are the Fractional Helly theorem of Katchalski and Liu (1979) and the Quantitative Volume theorem of B\'ar\'any, Katchalski, and Pach (1982). Improving on several recent works, we prove an optimal combination of these two results. We show that given a family F\mathcal{F} of nn convex sets in Rd\mathbb{R}^d such that at least α(nd+1)\alpha \binom{n}{d+1} of the (d+1)(d+1)-tuples of F\mathcal{F} have an intersection of volume at least 1, then one can select Ωd,α(n)\Omega_{d,\alpha}(n) members of F\mathcal{F} whose intersection has volume at least Ωd(1)\Omega_d(1). Furthermore, with the help of this theorem, we establish a quantitative version of the (p,q)(p,q) theorem of Alon and Kleitman. Let pqd+1p\geq q\geq d+1 and let F\mathcal{F} be a finite family of convex sets in Rd\mathbb{R}^d such that among any pp elements of F\mathcal{F}, there are qq that have an intersection of volume at least 11. Then, we prove that there exists a family TT of Op,q(1)O_{p,q}(1) ellipsoids of volume Ωd(1)\Omega_d(1) such that every member of F\mathcal{F} contains at least one element of TT. Finally, we present extensions about the diameter version of the Quantitative Helly theoerm.

Keywords

Cite

@article{arxiv.2402.12268,
  title  = {The Quantitative Fractional Helly theorem},
  author = {Nóra Frankl and Attila Jung and István Tomon},
  journal= {arXiv preprint arXiv:2402.12268},
  year   = {2024}
}

Comments

11 pages, extended with the diameter version of the Fractional Helly theorem

R2 v1 2026-06-28T14:53:20.695Z