English

The $\epsilon$-$t$-Net Problem

Discrete Mathematics 2024-03-26 v1 Computational Geometry Combinatorics

Abstract

We study a natural generalization of the classical ϵ\epsilon-net problem (Haussler--Welzl 1987), which we call the "ϵ\epsilon-tt-net problem": Given a hypergraph on nn vertices and parameters tt and ϵtn\epsilon\geq \frac t n, find a minimum-sized family SS of tt-element subsets of vertices such that each hyperedge of size at least ϵn\epsilon n contains a set in SS. When t=1t=1, this corresponds to the ϵ\epsilon-net problem. We prove that any sufficiently large hypergraph with VC-dimension dd admits an ϵ\epsilon-tt-net of size O((1+logt)dϵlog1ϵ)O(\frac{ (1+\log t)d}{\epsilon} \log \frac{1}{\epsilon}). For some families of geometrically-defined hypergraphs (such as the dual hypergraph of regions with linear union complexity), we prove the existence of O(1ϵ)O(\frac{1}{\epsilon})-sized ϵ\epsilon-tt-nets. We also present an explicit construction of ϵ\epsilon-tt-nets (including ϵ\epsilon-nets) for hypergraphs with bounded VC-dimension. In comparison to previous constructions for the special case of ϵ\epsilon-nets (i.e., for t=1t=1), it does not rely on advanced derandomization techniques. To this end we introduce a variant of the notion of VC-dimension which is of independent interest.

Keywords

Cite

@article{arxiv.2003.07061,
  title  = {The $\epsilon$-$t$-Net Problem},
  author = {Noga Alon and Bruno Jartoux and Chaya Keller and Shakhar Smorodinsky and Yelena Yuditsky},
  journal= {arXiv preprint arXiv:2003.07061},
  year   = {2024}
}

Comments

This is the full version of the paper to appear in the Proceedings of the 36th International Symposium on Computational Geometry (SoCG 2020)

R2 v1 2026-06-23T14:15:49.060Z