English

Local Routing in Sparse and Lightweight Geometric Graphs

Computational Geometry 2022-01-11 v2

Abstract

Online routing in a planar embedded graph is central to a number of fields and has been studied extensively in the literature. For most planar graphs no O(1)O(1)-competitive online routing algorithm exists. A notable exception is the Delaunay triangulation for which Bose and Morin [Online routing in triangulations. SIAM Journal on Computing, 33(4):937-951, 2004] showed that there exists an online routing algorithm that is O(1)O(1)-competitive. However, a Delaunay triangulation can have Ω(n)\Omega(n) vertex degree and a total weight that is a linear factor greater than the weight of a minimum spanning tree. We show a simple construction, given a set VV of nn points in the Euclidean plane, of a planar geometric graph on VV that has small weight (within a constant factor of the weight of a minimum spanning tree on VV), constant degree, and that admits a local routing strategy that is O(1)O(1)-competitive. Moreover, the technique used to bound the weight works generally for any planar geometric graph whilst preserving the admission of an O(1)O(1)-competitive routing strategy.

Keywords

Cite

@article{arxiv.1909.10215,
  title  = {Local Routing in Sparse and Lightweight Geometric Graphs},
  author = {Vikrant Ashvinkumar and Joachim Gudmundsson and Christos Levcopoulos and Bengt J. Nilsson and André van Renssen},
  journal= {arXiv preprint arXiv:1909.10215},
  year   = {2022}
}
R2 v1 2026-06-23T11:22:56.558Z