Shortest Paths, Convexity, and Treewidth in Regular Hyperbolic Tilings

Abstract

Hyperbolic tilings are natural infinite planar graphs where each vertex has degree q and each face has p edges for some 1p+1q<12. We study the structure of shortest paths in such graphs. We show that given a set of n terminals, we can compute a so-called isometric closure (closely related to the geodesic convex hull) of the terminals in near-linear time, using a classic geometric convex hull algorithm as a black box. We show that the size of the convex hull is O(N) where N is the total length of the paths to the terminals from a fixed origin. Furthermore, we prove that the geodesic convex hull of a set of n terminals has treewidth only (12,O(np + q)), a bound independent of the distance of the points involved. As a consequence, we obtain algorithms for subset TSP and Steiner tree with running time O(N N) + poly(np + q) · N.

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