On the Entropy of a Random Geometric Graph

Abstract

In this paper, we study the entropy of a hard random geometric graph (RGG), a commonly used model for spatial networks, where the connectivity is governed by the distances between the nodes. Formally, given a connection range r, a hard RGG Gm on m vertices is formed by drawing m random points from a spatial domain, and then connecting any two points with an edge when they are within a distance r from each other. The two domains we consider are the d-dimensional unit cube [0,1]d and the d-dimensional unit torus Td. We derive upper bounds on the entropy H(Gm) for both these domains and for all possible values of r. In a few cases, we obtain an exact asymptotic characterization of the entropy by proving a tight lower bound. Our main results are that H(Gm) dm 2m for 0 < r ≤ 1/4 in the case of Td and that the entropy of a one-dimensional RGG on [0,1] behaves like m m for all 0<r<1. As a consequence, we can infer that the asymptotic structural entropy of an RGG on Td, which is the entropy of an unlabelled RGG, is ((d-1)m 2m) for 0 < r ≤ 1/4. For the rest of the cases, we conjecture that the entropy behaves asymptotically as the leading order terms of our derived upper bounds.