Stable Delaunay Graphs
Abstract
Let be a set of points in , and let denote its Euclidean Delaunay triangulation. We introduce the notion of an edge of being {\it stable}. Defined in terms of a parameter , a Delaunay edge is called -stable, if the (equal) angles at which and see the corresponding Voronoi edge are at least . A subgraph of is called {\it -stable Delaunay graph} ( in short), for some constant , if every edge in is -stable and every -stable of is in . We show that if an edge is stable in the Euclidean Delaunay triangulation of , then it is also a stable edge, though for a different value of , in the Delaunay triangulation of under any convex distance function that is sufficiently close to the Euclidean norm, and vice-versa. In particular, a -stable edge in is -stable in the Delaunay triangulation under the distance function induced by a regular -gon for , and vice-versa. Exploiting this relationship and the analysis in~\cite{polydel}, we present a linear-size kinetic data structure (KDS) for maintaining an - as the points of move. If the points move along algebraic trajectories of bounded degree, the KDS processes nearly quadratic events during the motion, each of which can processed in time. Finally, we show that a number of useful properties of are retained by of .
Keywords
Cite
@article{arxiv.1504.06851,
title = {Stable Delaunay Graphs},
author = {Pankaj K. Agarwal and Jie Gao and Leonidas J. Guibas and Haim Kaplan and Natan Rubin and Micha Sharir},
journal= {arXiv preprint arXiv:1504.06851},
year = {2015}
}
Comments
This is a revision of the paper arXiv:1104.0622 presented in SoCG 2010. The revised analysis relies on results reported in the companion paper arXiv:1404.4851