Polychromatic Coloring of Tuples in Hypergraphs

Abstract

A hypergraph H consists of a set V of vertices and a set E of hyperedges that are subsets of V. A t-tuple of H is a subset of t vertices of V. A t-tuple k-coloring of H is a mapping of its t-tuples into k colors. A coloring is called (t,k,f)-polychromatic if each hyperedge of E that has at least f vertices contains tuples of all the k colors. Let fH(t,k) be the minimum f such that H has a (t,k,f)-polychromatic coloring. For a family of hypergraphs H let fH(t,k) be the maximum fH(t,k) over all hypergraphs H in H. We present several bounds on fH(t,k) for t 2. - Let H be the family of hypergraphs H that is obtained by taking any set P of points in 2, setting V:=P and E:=\d P d is a disk in 2\. We prove that fH(2,k) 3.7k, that is, the pairs of points (2-tuples) can be k-colored such that any disk containing at least 3.7k points has pairs of all colors. - For the family H of shrinkable hypergraphs of VC-dimension at most d we prove that fH(d+1,k) ≤ ck for some constant c=c(d). We also prove that every hypergraph with n vertices and with VC-dimension at most d has a (d+1)-tuple T of depth at least nc, i.e., any hyperedge that contains T also contains nc other vertices. - For the relationship between t-tuple coloring and vertex coloring in any hypergraph H we establish the inequality 1e· tk1t fH(t,k) fH(1,tk1t). For the special case of k=2, we prove that t+1 fH(t,2)\fH(1,2), t+1\; this improves upon the previous best known upper bound. - We generalize some of our results to higher dimensions, other shapes, pseudo-disks, and also study the relationship between tuple coloring and epsilon nets.

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