Covering the Euclidean Plane by a Pair of Trees

Abstract

A t-stretch tree cover of a metric space M = (X,δ), for a parameter t 1, is a collection of trees such that every pair of points has a t-stretch path in one of the trees. Tree covers provide an important sketching tool that has found various applications over the years. The celebrated Dumbbell Theorem by Arya et al. [STOC'95] states that any set of points in the Euclidean plane admits a (1+ε)-stretch tree cover with Oε(1) trees. This result extends to any (constant) dimension and was also generalized for arbitrary doubling metrics by Bartal et al. [ICALP'19]. Although the number of trees provided by the Dumbbell Theorem is constant, this constant is not small, even for a stretch significantly larger than 1+ε. At the other extreme, any single tree on the vertices of a regular n-polygon must incur a stretch of (n). Using known results of ultrametric embeddings, one can easily get a stretch of O(n) using two trees. The question of whether a low stretch can be achieved using two trees has remained illusive, even in the Euclidean plane. In this work, we resolve this fundamental question in the affirmative by presenting a constant-stretch cover with a pair of trees, for any set of points in the Euclidean plane. Our main technical contribution is a surprisingly simple Steiner construction, for which we provide a tight stretch analysis of 26. The Steiner points can be easily pruned if one is willing to increase the stretch by a small constant. Moreover, we can bound the maximum degree of the construction by a constant. Our result thus provides a simple yet effective reduction tool -- for problems that concern approximate distances -- from the Euclidean plane to a pair of trees. To demonstrate the potential power of this tool, we present some applications [...]