Phase transition in noisy high-dimensional random geometric graphs

TL;DR

This paper investigates the detectability of latent geometric structure in noisy high-dimensional random graphs, identifying conditions under which geometry can be distinguished from randomness and proposing tests based on signed triangles.

Contribution

It generalizes previous work by analyzing the effect of noise on the phase transition for detecting geometry in high-dimensional random graphs.

Findings

Geometry is indistinguishable from randomness when $nq o 0$ or $d o ext{large}$ relative to $n^{3} q^{2}$.

Signed triangle statistic effectively detects geometry when $d o ext{small}$ relative to $n^{3} q^{6}$.

Results extend understanding of noise impact on geometric graph phase transitions.

Abstract

We study the problem of detecting latent geometric structure in random graphs. To this end, we consider the soft high-dimensional random geometric graph $\mathcal{G}(n,p,d,q)$, where each of the $n$ vertices corresponds to an independent random point distributed uniformly on the sphere $\mathbb{S}^{d-1}$, and the probability that two vertices are connected by an edge is a decreasing function of the Euclidean distance between the points. The probability of connection is parametrized by $q \in [0,1]$, with smaller $q$ corresponding to weaker dependence on the geometry; this can also be interpreted as the level of noise in the geometric graph. In particular, the model smoothly interpolates between the spherical hard random geometric graph $\mathcal{G}(n,p,d)$ (corresponding to $q = 1$) and the Erd\H{o}s-R\'enyi model $\mathcal{G}(n,p)$ (corresponding to $q = 0$). We focus on the dense regime (i.e., $p$ is a constant). We show that if $nq \to 0$ or $d \gg n^{3} q^{2}$, then geometry is lost: $\mathcal{G}(n,p,d,q)$ is asymptotically indistinguishable from $\mathcal{G}(n,p)$. On the other hand, if $d \ll n^{3} q^{6}$, then the signed triangle statistic provides an asymptotically powerful test for detecting geometry. These results generalize those of Bubeck, Ding, Eldan, and R\'acz (2016) for $\mathcal{G}(n,p,d)$, and give quantitative bounds on how the noise level affects the dimension threshold for losing geometry. We also prove analogous results under a related but different distributional assumption, and we further explore generalizations of signed triangles in order to understand the intermediate regime left open by our results.