The geometry of the giant component of random geometric graphs

Abstract

Consider a random geometric graph GM(n;r) whose vertex set consists of n points chosen independently and uniformly from a Riemannian manifold M, with edges joining pairs of vertices whose distance in the metric dM is at most r. Let Δ denote the expected average degree of the graph. As is the case for Erdős-Rényi graphs, there is a critical value Δc, depending only on the dimension of M, such that if Δ> Δc then GM(n;r) has a giant component. We show that whenever Δ> Δc, the giant component of GM(n;r), equipped with the graph distance, converges to the underlying manifold M in the Gromov-Hausdorff distance after rescaling by an appropriate deterministic factor. Our result holds for Δ depending on n as well, provided Δ= o(n) and Δ≥ Δc + for any fixed > 0. As a consequence, we show that for any pair of non-isometric compact Riemannian manifolds M1 and M2, there is a polynomial-time algorithm that distinguishes random geometric graphs on M1 and M2 throughout this regime of Δ. In the thermodynamic regime -- i.e.\ when Δ is constant -- our results appear to be new even in the classical cases where M is a sphere or a torus. Our proof makes use of techniques from first-passage percolation which allow us to understand the long-range behavior of the graph distance on small, approximately Euclidean patches of M, together with global arguments that glue these local estimates into a global description.