English

On Zarankiewicz's Problem for Intersection Hypergraphs of Geometric Objects

Combinatorics 2025-09-12 v2 Computational Geometry

Abstract

The hypergraph Zarankiewicz's problem, introduced by Erd\H{o}s in 1964, asks for the maximum number of hyperedges in an rr-partite hypergraph with nn vertices in each part that does not contain a copy of Kt,t,,tK_{t,t,\ldots,t}. Erd\H{o}s obtained a near optimal bound of O(nr1/tr1)O(n^{r-1/t^{r-1}}) for general hypergraphs. In recent years, several works obtained improved bounds under various algebraic assumptions -- e.g., if the hypergraph is semialgebraic. In this paper we study the problem in a geometric setting -- for rr-partite intersection hypergraphs of families of geometric objects. Our main results are essentially sharp bounds for families of axis-parallel boxes in Rd\mathbb{R}^d and families of pseudo-discs. For axis-parallel boxes, we obtain the sharp bound Od,r(tnr1(lognloglogn)d1)O_{d,r}(tn^{r-1}(\frac{\log n}{\log \log n})^{d-1}). The best previous bound was larger by a factor of about (logn)d(2r12)(\log n)^{d(2^{r-1}-2)}. For pseudo-discs, we obtain the bound Or(tnr1(logn)r2)O_r(tn^{r-1}(\log n)^{r-2}), which is sharp up to logarithmic factors. As this hypergraph has no algebraic structure, no improvement of Erd\H{o}s' 60-year-old O(nr1/tr1)O(n^{r-1/t^{r-1}}) bound was known for this setting. Futhermore, even in the special case of discs for which the semialgebraic structure can be used, our result improves the best known result by a factor of Ω~(n2r23r2)\tilde{\Omega}(n^{\frac{2r-2}{3r-2}}). To obtain our results, we use the recently improved results for the graph Zarankiewicz's problem in the corresponding settings, along with a variety of combinatorial and geometric techniques, including shallow cuttings, biclique covers, transversals, and planarity.

Keywords

Cite

@article{arxiv.2412.06490,
  title  = {On Zarankiewicz's Problem for Intersection Hypergraphs of Geometric Objects},
  author = {Timothy M. Chan and Chaya Keller and Shakhar Smorodinsky},
  journal= {arXiv preprint arXiv:2412.06490},
  year   = {2025}
}

Comments

25 pages. The revised version includes improvement of both main results to make the dependence on $t$ sharp

R2 v1 2026-06-28T20:27:53.349Z