Simple Length-Constrained Expander Decompositions

Abstract

Length-constrained expander decompositions are a new graph decomposition that has led to several recent breakthroughs in fast graph algorithms. Roughly, an (h, s)-length φ-expander decomposition is a small collection of length increases to a graph so that nodes within distance h can route flow over paths of length hs while using each edge to an extent at most 1/φ. Prior work showed that every n-node and m-edge graph admits an (h, s)-length φ-expander decomposition of size n · s nO(1/s) · φ m. In this work, we give a simple proof of the existence of (h, s)-length φ-expander decompositions with an improved size of s nO(1/s)· φ m. Our proof is a straightforward application of the fact that the union of sparse length-constrained cuts is itself a sparse length-constrained cut. In deriving our result, we improve the loss in sparsity when taking the union of sparse length-constrained cuts from 3 n· s3 nO(1/s) to s· nO(1/s).

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