Higher-Order Cheeger Inequality for Partitioning with Buffers

Abstract

We prove a new generalization of the higher-order Cheeger inequality for partitioning with buffers. Consider a graph G=(V,E). The buffered expansion of a set S ⊂eq V with a buffer B ⊂eq V S is the edge expansion of S after removing all the edges from set S to its buffer B. An -buffered k-partitioning is a partitioning of a graph into disjoint components Pi and buffers Bi, in which the size of buffer Bi for Pi is small relative to the size of Pi: |Bi| |Pi|. The buffered expansion of a buffered partition is the maximum of buffered expansions of the k sets Pi with buffers Bi. Let hk,G be the buffered expansion of the optimal -buffered k-partitioning, then for every δ>0, hGk, Oδ(1) · ( k ) · λ (1+δ) k, where λ (1+δ)k is the (1+δ)k-th smallest eigenvalue of the normalized Laplacian of G. Our inequality is constructive and avoids the ``square-root loss'' that is present in the standard Cheeger inequalities (even for k=2). We also provide a complementary lower bound, and a novel generalization to the setting with arbitrary vertex weights and edge costs. Moreover our result implies and generalizes the standard higher-order Cheeger inequalities and another recent Cheeger-type inequality by Kwok, Lau, and Lee (2017) involving robust vertex expansion.