Lower bounds for piercing and coloring boxes

Abstract

Given a family B of axis-parallel boxes in Rd, let τ denote its piercing number, and its independence number. It is an old question whether τ/ can be arbitrarily large for given d≥ 2. Here, for every , we construct a family of axis-parallel boxes achieving τ≥ d()·( )d-2. This not only answers the previous question for every d≥ 3 positively, but also matches the best known upper bound up to double-logarithmic factors. Our main construction has further implications about the Ramsey and coloring properties of configurations of boxes as well. We show the existence of a family of n boxes in Rd, whose intersection graph has clique and independence number Od(n1/2)· ( n n)-(d-2)/2. This is the first improvement over the trivial upper bound Od(n1/2), and matches the best known lower bound up to double-logarithmic factors. Finally, for every ω satisfying n n ω n1-, we construct an intersection graph of n boxes with clique number at most ω, and chromatic number d,(ω)· ( n n)d-2. This matches the best known upper bound up to a factor of Od(( w)( n)d-2).