Overlap properties of geometric expanders

Abstract

The overlap number of a finite (d+1)-uniform hypergraph H is defined as the largest constant c(H)∈ (0,1] such that no matter how we map the vertices of H into d, there is a point covered by at least a c(H)-fraction of the simplices induced by the images of its hyperedges. In~Gro2, motivated by the search for an analogue of the notion of graph expansion for higher dimensional simplicial complexes, it was asked whether or not there exists a sequence \Hn\n=1∞ of arbitrarily large (d+1)-uniform hypergraphs with bounded degree, for which ∈fn 1 c(Hn)>0. Using both random methods and explicit constructions, we answer this question positively by constructing infinite families of (d+1)-uniform hypergraphs with bounded degree such that their overlap numbers are bounded from below by a positive constant c=c(d). We also show that, for every d, the best value of the constant c=c(d) that can be achieved by such a construction is asymptotically equal to the limit of the overlap numbers of the complete (d+1)-uniform hypergraphs with n vertices, as n→∞. For the proof of the latter statement, we establish the following geometric partitioning result of independent interest. For any d and any ε>0, there exists K=K(ε,d) d+1 satisfying the following condition. For any k K, for any point q ∈ Rd and for any finite Borel measure μ on Rd with respect to which every hyperplane has measure 0, there is a partition Rd=A1 … Ak into k measurable parts of equal measure such that all but at most an ε-fraction of the (d+1)-tuples Ai1,…,Aid+1 have the property that either all simplices with one vertex in each Aij contain q or none of these simplices contain q.