Resolution of the Detection Threshold Conjecture for Random Geometric Graphs in the d>n Regime
Abstract
A random geometric graph (RGG) is generated by first sampling latent points x1,…,xn independently and uniformly from the unit sphere in Rd, and then connecting each pair (i,j) if xi,xj exceeds some threshold τ. We study the sharp detection threshold -- the largest dimension at which the RGG can be statistically distinguished from the Erdős--Rényi graph with the same edge density p. This threshold is conjectured to be d (nh(p))3, where h(p)=p 1p + (1-p) 11-p is the binary entropy function. Previous works proved this conjecture for dense graphs with constant p and, up to polylogarithmic factors, very sparse graphs with p=Θ(1/n). In this paper, we prove that detection is impossible when d (nh(p))3 and d (1+ε) n for any constant ε>0, thereby resolving the conjecture in the regime p n-2/3/ n and improving upon the state of the art in the regime 1/n p n-2/3/ n. The key to our proof is a sharp analysis of the posterior distribution of the latent points given the observed graph, obtained through an information-theoretic comparison argument combined with strong log-concavity.
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