A continuous analogue of Erdos' k-Sperner theorem

Abstract

A chain in the unit n-cube is a set C⊂ [0,1]n such that for every x=(x1,…,xn) and y=(y1,…,yn) in C we either have xi yi for all i∈ [n], or xi yi for all i∈ [n]. We show that the 1-dimensional Hausdorff measure of a chain in the unit n-cube is at most n, and that the bound is sharp. Given this result, we consider the problem of maximising the n-dimensional Lebesgue measure of a measurable set A⊂ [0,1]n subject to the constraint that it satisfies H1(A C) for all chains C⊂ [0,1]n, where is a fixed real number from the interval (0,n]. We show that the measure of A is not larger than the measure of the following optimal set: \[ A = \ (x1,…,xn)∈ [0,1]n : n-2 Σi=1nxi n+ 2 \ \, . \] Our result may be seen as a continuous counterpart to a theorem of Erdos, regarding k-Sperner families of finite sets.