Sublinear-Time Approximation for Graph Frequency Vectors in Hyperfinite Graphs

Abstract

In this work, we address the problem of approximating the k-disc distribution ("frequency vector") of a bounded-degree graph in sublinear-time under the assumption of hyperfiniteness. We revisit the partition-oracle framework of Hassidim, Kelner, Nguyen, and Onak [HKNO09], and provide a concise, self-contained analysis that explicitly separates the two sources of error: (i) the cut error, controlled by hyperfiniteness parameter φ, which incurs at most /2 in 1-distance by removing at most φ |V| edges; and (ii) the sampling error, controlled by the accuracy parameter , bounded by /2 via N=(-2) random vertex queries and a Chernoff and union bound argument. Combining these yields an overall 1-error of with high probability. Algorithmically, we show that by sampling N= C-2 vertices and querying the local partition oracle, one can in time poly(d,k,-1) construct a summary graph H of size |H|=poly(dk,1/) whose k-disc frequency vector approximates that of the original graph within in 1-distance. Our approach clarifies the dependence of both runtime and summary-size on the parameter d,k, and .