English

Evasive sets, covering by subspaces, and point-hyperplane incidences

Combinatorics 2022-07-29 v2

Abstract

Given positive integers kdk\leq d and a finite field F\mathbb{F}, a set SFdS\subset\mathbb{F}^{d} is (k,c)(k,c)-subspace evasive if every kk-dimensional affine subspace contains at most cc elements of SS. By a simple averaging argument, the maximum size of a (k,c)(k,c)-subspace evasive set is at most cFdkc |\mathbb{F}|^{d-k}. When kk and dd are fixed, and cc is sufficiently large, the matching lower bound Ω(Fdk)\Omega(|\mathbb{F}|^{d-k}) is proved by Dvir and Lovett. We provide an alternative proof of this result using the random algebraic method. We also prove sharp upper bounds on the size of (k,c)(k,c)-evasive sets in case dd is large, extending results of Ben-Aroya and Shinkar. The existence of optimal evasive sets has several interesting consequences in combinatorial geometry. We show that the minimum number of kk-dimensional linear hyperplanes needed to cover the grid [n]dRd[n]^{d}\subset \mathbb{R}^{d} is Ωd(nd(dk)d1)\Omega_{d}\big(n^{\frac{d(d-k)}{d-1}}\big), which matches the upper bound proved by Balko, Cibulka, and Valtr, and settles a problem proposed by Brass, Moser, and Pach. Furthermore, we improve the best known lower bound on the maximum number of incidences between points and hyperplanes in Rd\mathbb{R}^{d} assuming their incidence graph avoids the complete bipartite graph Kc,cK_{c,c} for some large constant c=c(d)c=c(d).

Keywords

Cite

@article{arxiv.2207.13077,
  title  = {Evasive sets, covering by subspaces, and point-hyperplane incidences},
  author = {Benny Sudakov and István Tomon},
  journal= {arXiv preprint arXiv:2207.13077},
  year   = {2022}
}

Comments

13 pages

R2 v1 2026-06-25T01:15:00.471Z