Minimum Weight Euclidean (1+)-Spanners

Abstract

Given a set S of n points in the plane and a parameter >0, a Euclidean (1+)-spanner is a geometric graph G=(S,E) that contains, for all p,q∈ S, a pq-path of weight at most (1+)\|pq\|. We show that the minimum weight of a Euclidean (1+)-spanner for n points in the unit square [0,1]2 is O(-3/2\,n), and this bound is the best possible. The upper bound is based on a new spanner algorithm in the plane. It improves upon the baseline O(-2n), obtained by combining a tight bound for the weight of a Euclidean minimum spanning tree (MST) on n points in [0,1]2, and a tight bound for the lightness of Euclidean (1+)-spanners, which is the ratio of the spanner weight to the weight of the MST. Our result generalizes to Euclidean d-space for every constant dimension d∈ N: The minimum weight of a Euclidean (1+)-spanner for n points in the unit cube [0,1]d is Od((1-d2)/dn(d-1)/d), and this bound is the best possible. For the n× n section of the integer lattice in the plane, we show that the minimum weight of a Euclidean (1+)-spanner is between (-3/4· n2) and O(-1(-1)· n2). These bounds become (-3/4· n) and O(-1(-1)· n) when scaled to a grid of n points in the unit square. In particular, this shows that the integer grid is not an extremal configuration for minimum weight Euclidean (1+)-spanners.