Vertex isoperimetry and independent set stability for tensor powers of cliques

Abstract

The tensor power of the clique on t vertices (denoted by Ktn) is the graph on vertex set \1, ..., t\n such that two vertices x, y ∈ \1, ..., t\n are connected if and only if xi ≠ yi for all i ∈ \1, ..., n\. Let the density of a subset S of Ktn to be μ(S) := |S|tn, and let the vertex boundary of a set S to be vertices which are incident to some vertex of S, perhaps including points of S. We investigate two similar problems on such graphs. First, we study the vertex isoperimetry problem. Given a density ∈ [0, 1] what is the smallest possible density of the vertex boundary of a subset of Ktn of density ? Let t() be the infimum of these minimum densities as n ∞. We find a recursive relation allows one to compute t() in time polynomial to the number of desired bits of precision. Second, we study given an independent set I ⊂eq Ktn of density μ(I) = 1t(1-ε), how close it is to a maximum-sized independent set J of density 1t. We show that this deviation (measured by μ(I J)) is at most 4ε t t - (t-1) as long as ε < 1 - 3t + 2t2. This substantially improves on results of Alon, Dinur, Friedgut, and Sudakov (2004) and Ghandehari and Hatami (2008) which had an O(ε) upper bound. We also show the exponent t t - (t-1) is optimal assuming n tending to infinity and ε tending to 0. The methods have similarity to recent work by Ellis, Keller, and Lifshitz (2016) in the context of Kneser graphs and other settings. The author hopes that these results have potential applications in hardness of approximation, particularly in approximate graph coloring and independent set problems.