English

Zarankiewicz's problem via $\epsilon$-t-nets

Combinatorics 2024-09-04 v2 Computational Geometry

Abstract

The classical Zarankiewicz's problem asks for the maximum number of edges in a bipartite graph on nn vertices which does not contain the complete bipartite graph Kt,tK_{t,t}. In one of the cornerstones of extremal graph theory, K\H{o}v\'ari S\'os and Tur\'an proved an upper bound of O(n21t)O(n^{2-\frac{1}{t}}). In a celebrated result, Fox et al. obtained an improved bound of O(n21d)O(n^{2-\frac{1}{d}}) for graphs of VC-dimension dd (where d<td<t). Basit, Chernikov, Starchenko, Tao and Tran improved the bound for the case of semilinear graphs. At SODA'23, Chan and Har-Peled further improved Basit et al.'s bounds and presented (quasi-)linear upper bounds for several classes of geometrically-defined incidence graphs, including a bound of O(nloglogn)O(n \log \log n) for the incidence graph of points and pseudo-discs in the plane. In this paper we present a new approach to Zarankiewicz's problem, via ϵ\epsilon-t-nets - a recently introduced generalization of the classical notion of ϵ\epsilon-nets. We show that the existence of `small'-sized ϵ\epsilon-t-nets implies upper bounds for Zarankiewicz's problem. Using the new approach, we obtain a sharp bound of O(n)O(n) for the intersection graph of two families of pseudo-discs, thus both improving and generalizing the result of Chan and Har-Peled from incidence graphs to intersection graphs. We also obtain a short proof of the O(n21d)O(n^{2-\frac{1}{d}}) bound of Fox et al., and show improved bounds for several other classes of geometric intersection graphs, including a sharp O(nlognloglogn)O(n\frac{\log n}{\log \log n}) bound for the intersection graph of two families of axis-parallel rectangles.

Keywords

Cite

@article{arxiv.2311.13662,
  title  = {Zarankiewicz's problem via $\epsilon$-t-nets},
  author = {Chaya Keller and Shakhar Smorodinsky},
  journal= {arXiv preprint arXiv:2311.13662},
  year   = {2024}
}

Comments

A section on follow-up work added. 20 pages, 3 figures

R2 v1 2026-06-28T13:28:59.227Z