A sharper Ramsey theorem for constrained drawings

Abstract

Given a graph G and a collection C of subsets of Rd indexed by the subsets of vertices of G, a constrained drawing of G is a drawing, where each edge is drawn inside some set from C, in such a way that non-adjacent edges are drawn in sets with disjoint indices. In this paper we prove a Ramsey type result for such drawings. Furthermore we show how the result can be used to obtain Helly type theorems. More precisely, we prove the following. For each n and b, there is N=O(b2n-3) with the following properties: If G is a drawing of a graph on N vertices and C is a collection of sets of Rd such that each (b+1)-tuple T of vertices lies in a set indexed by T and contains at least one edge in T, then in G, we can find a constrained copy of the complete graph Kn. As a direct consequence we obtain the following Helly type result: For each d, there is a polynomial h(b) of degree at most 2d+3 such that the following holds. For every family F of sets in Rd, its Helly number is at most h(b), provided that the intersection of any non-empty subfamily has at most b path-connected components, and trivial homology groups H1, H2, .... H d/2-1. This dramatically improves the original theorem by Matousek which had stronger assumption and a tower-like bound on h(b). Under the same assumptions, our technique can also be used to bound Radon numbers.