English

VC-dimension and pseudo-random graphs

Combinatorics 2023-03-15 v1

Abstract

Let GG be a graph and UV(G)U\subset V(G) be a set of vertices. For each vUv\in U, let hv ⁣:U{0,1}h_v\colon U\to \{0, 1\} be the function defined by hv(u)={1 \mboxif uv,uU0 \mboxif u≁v,uU,h_v(u)=\begin{cases} &1 ~\mbox{if}~u\sim v, u\in U\\&0 ~\mbox{if}~u\not\sim v, u\in U\end{cases}, and set H(U):={hv ⁣:vU}\mathcal{H}(U):=\{h_v\colon v\in U\}. The first purpose of this paper is to study the following question: What families of graphs GG and what conditions on UU do we need so that the VC-dimension of H(U)\mathcal{H}(U) can be determined? We show that if GG is a pseudo-random graph, then under some mild conditions, the VC dimension of H(U)\mathcal{H}(U) can be bounded from below. Specific cases of this theorem recover and improve previous results on VC-dimension of functions defined by the well-studied distance and dot-product graphs over a finite field.

Keywords

Cite

@article{arxiv.2303.07878,
  title  = {VC-dimension and pseudo-random graphs},
  author = {Thang Pham and Steven Senger and Michael Tait and Nguyen Thu-Huyen},
  journal= {arXiv preprint arXiv:2303.07878},
  year   = {2023}
}
R2 v1 2026-06-28T09:16:24.082Z