Detection of local geometry in random graphs: information-theoretic and computational limits

TL;DR

This paper investigates the fundamental limits of detecting local geometric structures in random graphs, establishing thresholds for detection and revealing a computational-statistical gap using advanced probabilistic and algorithmic techniques.

Contribution

It introduces a new random graph model with local geometry, derives sharp detection thresholds, and demonstrates a computational-statistical gap using the low-degree polynomial framework.

Findings

Detection threshold at d = (k^2  k^6/n^3) for fixed p

Global and scan tests effectively detect geometric structure

Evidence of a computational-statistical gap via low-degree polynomial analysis

Abstract

We study the problem of detecting local geometry in random graphs. We introduce a model $\mathcal{G}(n, p, d, k)$, where a hidden community of average size $k$ has edges drawn as a random geometric graph on $\mathbb{S}^{d-1}$, while all remaining edges follow the Erd\H{o}s--R\'enyi model $\mathcal{G}(n, p)$. The random geometric graph is generated by thresholding inner products of latent vectors on $\mathbb{S}^{d-1}$, with each edge having marginal probability equal to $p$. This implies that $\mathcal{G}(n, p, d, k)$ and $\mathcal{G}(n, p)$ are indistinguishable at the level of the marginals, and the signal lies entirely in the edge dependencies induced by the local geometry. We investigate both the information-theoretic and computational limits of detection. On the information-theoretic side, our upper bounds follow from three tests based on signed triangle counts: a global test, a scan test, and a constrained scan test; our lower bounds follow from two complementary methods: truncated second moment via Wishart--GOE comparison, and tensorization of KL divergence. These results together settle the detection threshold at $d = \widetilde{\Theta}(k^2 \vee k^6/n^3)$ for fixed $p$, and extend the state-of-the-art bounds from the full model (i.e., $k = n$) for vanishing $p$. On the computational side, we identify a computational--statistical gap and provide evidence via the low-degree polynomial framework, as well as the suboptimality of signed cycle counts of length $\ell \geq 4$.