The MST of Symmetric Disk Graphs (in Arbitrary Metrics) is Light

Abstract

Consider an n-point metric M = (V,delta), and a transmission range assignment r: V → R+ that maps each point v in V to the disk of radius r(v) around it. The symmetric disk graph (henceforth, SDG) that corresponds to M and r is the undirected graph over V whose edge set includes an edge (u,v) if both r(u) and r(v) are no smaller than delta(u,v). SDGs are often used to model wireless communication networks. Abu-Affash, Aschner, Carmi and Katz (SWAT 2010, AACK10) showed that for any 2-dimensional Euclidean n-point metric M, the weight of the MST of every connected SDG for M is O(log n) w(MST(M)), and that this bound is tight. However, the upper bound proof of AACK10 relies heavily on basic geometric properties of 2-dimensional Euclidean metrics, and does not extend to higher dimensions. A natural question that arises is whether this surprising upper bound of AACK10 can be generalized for wider families of metrics, such as 3-dimensional Euclidean metrics. In this paper we generalize the upper bound of Abu-Affash et al. AACK10 for Euclidean metrics of any dimension. Furthermore, our upper bound extends to arbitrary metrics and, in particular, it applies to any of the normed spaces ellp. Specifically, we demonstrate that for any n-point metric M, the weight of the MST of every connected SDG for M is O(log n) w(MST(M)).