A Single-Exponential Erdős--Hajnal Bound for Graphs of Bounded VC-Dimension
Abstract
A homogeneous set in a graph is a clique or a stable set. The Erdős--Hajnal conjecture states that, for every graph H, there exists c>0 such that every H-free graph on n vertices has a homogeneous set of size at least nc. Nguyen, Scott and Seymour proved that for every d>0, graphs of VC-dimension at most d have the Erdős--Hajnal property, confirming a conjecture of Fox, Pach and Suk. In particular, they showed that every such n-vertex graph contains a homogeneous set of size at least nηd for some ηd 2-2O(d). In this paper, we give a sharper quantitative bound on the homogeneous sets in graphs of VC-dimension at most d, showing that one may take ηd (Cd)-d, where C is an absolute constant. Equivalently, every graph G of VC-dimension at most d satisfies \[ \ω(G),α(G)\ |G|(Cd)-d. \] Our proof refines the iterative sparsification method of Nguyen, Scott and Seymour. The main enhancement is to apply the VC-dimension assumption directly, which gives a more efficient induction and thus improves the dependence on d. We also derive quantitative consequences for polynomial Rödl subgraphs, hypergraph Ramsey bounds under bounded VC-dimension, induced-free and viral formulations, tournaments, NIP and semi-algebraic graphs, Boolean combinations of relations of bounded VC-dimension, graphs whose adjacency matrices have bounded rank, graphs of bounded sign-rank, and graphs defined by dot-product threshold representations.
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