Poisson Approximation and Connectivity in a Scale-free Random Connection Model

Abstract

We study an inhomogeneous random connection model in the connectivity regime. The vertex set of the graph is a homogeneous Poisson point process Ps of intensity s>0 on the unit cube S=(-12,12]d, d ≥ 2 . Each vertex is endowed with an independent random weight distributed as W, where P(W>w)=w-β1[1,∞)(w), β>0. Given the vertex set and the weights an edge exists between x,y∈ Ps with probability (1 - ( - η WxWy(d(x,y)/r)α )), independent of everything else, where η, α > 0, d(·, ·) is the toroidal metric on S and r > 0 is a scaling parameter. We derive conditions on α, β such that under the scaling rs()d= 1c0 s ( s +(k-1) s ++(αβk!d )), ∈ R, the number of vertices of degree k converges in total variation distance to a Poisson random variable with mean e- as s ∞, where c0 is an explicitly specified constant that depends on α, β, d and η but not on k. In particular, for k=0 we obtain the regime in which the number of isolated nodes stabilizes, a precursor to establishing a threshold for connectivity. We also derive a sufficient condition for the graph to be connected with high probability for large s. The Poisson approximation result is derived using the Stein's method.