English

Connecting the Random Connection Model

Probability 2015-10-20 v1

Abstract

Consider the random graph G(Pn,r)G({\mathcal P}_{n},r) whose vertex set Pn{\mathcal P}_{n} is a Poisson point process of intensity nn on (12,12]d(- \frac{1}{2}, \frac{1}{2}]^d, d2d \geq 2. Any two vertices Xi,XjPnX_i,X_j \in {\mathcal P}_{n} are connected by an edge with probability g(d(Xi,Xj)r)g\left( \frac{d(X_i,X_j)}{r} \right), independently of all other edges, and independent of the other points of Pn{\mathcal P}_{n}. dd is the toroidal metric, r>0r > 0 and g:[0,)[0,1]g:[0,\infty) \to [0,1] is non-increasing and α=Rdg(x)dx<\alpha = \int_{\mathbb{R}^d} g(|x|) dx < \infty. Under suitable conditions on gg, almost surely, the critical parameter dnd_n for which G(Pn,)G({\mathcal P}_{n}, \cdot) does not have any isolated nodes satisfies limnαndndlogn=1\lim_{n \to \infty} \frac{\alpha n d_n^d}{\log n} = 1. Let β=inf{x>0:xg(αxθ)>1}\beta = \inf\{x > 0: x g\left( \frac{\alpha}{x \theta} \right) > 1 \}, and θ\theta be the volume of the unit ball in Rd\mathbb{R}^d. Then for all γ>β\gamma > \beta, G(Pn,(γlognαn)1d)G\left({\mathcal P}_{n}, \left( \frac{\gamma \log n}{\alpha n} \right)^{\frac{1}{d}}\right) is connected with probability approaching one as nn \to \infty. The bound can be seen to be tight for the usual random geometric graph obtained by setting g=1[0,1]g = 1_{[0,1]}. We also prove some useful results on the asymptotic behaviour of the length of the edges and the degree distribution in the {\it connectivity regime}.

Keywords

Cite

@article{arxiv.1510.05440,
  title  = {Connecting the Random Connection Model},
  author = {Srikanth K. Iyer},
  journal= {arXiv preprint arXiv:1510.05440},
  year   = {2015}
}
R2 v1 2026-06-22T11:23:31.689Z