Covering Planar Metrics (and Beyond): O(1) Trees Suffice

TL;DR

This paper proves that any planar metric space can be efficiently covered by a constant number of trees with low distortion, extending known results from Euclidean and doubling metrics to planar graphs.

Contribution

It establishes that planar metrics admit a constant number of low-distortion tree covers, using a novel framework involving shortcut partitions and grid-like structures.

Findings

Planar metrics can be covered by O(1) trees with (1+ε) distortion.

Introduces the concept of shortcut partitions for planar graphs.

Connects planar graph structure to low-distortion tree covers.

Abstract

While research on the geometry of planar graphs has been active in the past decades, many properties of planar metrics remain mysterious. This paper studies a fundamental aspect of the planar graph geometry: covering planar metrics by a small collection of simpler metrics. Specifically, a \emph{tree cover} of a metric space $(X, \delta)$ is a collection of trees, so that every pair of points $u$ and $v$ in $X$ has a low-distortion path in at least one of the trees. The celebrated "Dumbbell Theorem" [ADMSS95] states that any low-dimensional Euclidean space admits a tree cover with $O(1)$ trees and distortion $1+\varepsilon$, for any fixed $\varepsilon \in (0,1)$. This result has found numerous algorithmic applications, and has been generalized to the wider family of doubling metrics [BFN19]. Does the same result hold for planar metrics? A positive answer would add another evidence to the well-observed connection between Euclidean/doubling metrics and planar metrics. In this work, we answer this fundamental question affirmatively. Specifically, we show that for any given fixed $\varepsilon \in (0,1)$, any planar metric can be covered by $O(1)$ trees with distortion $1+\varepsilon$. Our result for planar metrics follows from a rather general framework: First we reduce the problem to constructing tree covers with \emph{additive distortion}. Then we introduce the notion of \emph{shortcut partition}, and draw connection between shortcut partition and additive tree cover. Finally we prove the existence of shortcut partition for any planar metric, using new insights regarding the grid-like structure of planar graphs. [...]