Detection of L∞ Geometry in Random Geometric Graphs: Suboptimality of Triangles and Cluster Expansion

Abstract

In this paper we study the random geometric graph RGG(n,Td,Unif,σqp,p) with Lq distance where each vertex is sampled uniformly from the d-dimensional torus and where the connection radius is chosen so that the marginal edge probability is p. In addition to results addressing other questions, we make progress on determining when it is possible to distinguish RGG(n,Td,Unif,σqp,p) from the Endos-R\'enyi graph G(n,p). Our strongest result is in the extreme setting q = ∞, in which case RGG(n,Td,Unif,σ∞p,p) is the AND of d 1-dimensional random geometric graphs. We derive a formula similar to the cluster-expansion from statistical physics, capturing the compatibility of subgraphs from each of the d 1-dimensional copies, and use it to bound the signed expectations of small subgraphs. We show that counting signed 4-cycles is optimal among all low-degree tests, succeeding with high probability if and only if d = o(np). In contrast, the signed triangle test is suboptimal and only succeeds when d = o((np)3/4). Our result stands in sharp contrast to the existing literature on random geometric graphs (mostly focused on L2 geometry) where the signed triangle statistic is optimal.

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