On the components of random geometric graphs in the dense limit

Abstract

Consider the geometric graph on n independent uniform random points in a connected compact region A of Rd, d ≥ 2, with C2 boundary, or in the unit square, with distance parameter rn. Let Kn be the number of components of this graph, and Rn the number of vertices not in the giant component. Let Sn be the number of isolated vertices. We show that if rn is chosen so that nrnd tends to infinity but slowly enough that E[Sn] also tends to infinity, then Kn, Rn and Sn are all asymptotic to μn in probability as n ∞ where (with |A|, θd and |∂ A| denoting the volume of A, of the unit d-ball, and the perimeter of A respectively) μn := ne-π n (rn)d/|A| if d=2 and μn := ne-θd n (rn)d/|A| + θd-1-1 |∂ A| (rn)1-d e- θd n (rn)d/(2|A|) if d≥ 3. We also give variance asymptotics and central limit theorems for Kn and Rn in this limiting regime when d ≥ 3, and for Poisson input with d ≥ 2. We extend these results (substituting E[Sn] for μn) to a class of non-uniform distributions on A.