Essential Constraints of Edge-Constrained Proximity Graphs
DOI:
https://doi.org/10.7155/jgaa.00422Keywords:
proximity graphs , constraints , visibility , MST , Delaunay , beta-skeletonAbstract
Given a plane forest $F = (V, E)$ of $|V| = n$ points, we find the minimum set $S \subseteq E$ of edges such that the edge-constrained minimum spanning tree over the set $V$ of vertices and the set $S$ of constraints contains $F$. We present an $O(n \log n )$-time algorithm that solves this problem. We generalize this to other proximity graphs in the constraint setting, such as the relative neighbourhood graph, Gabriel graph, $\beta$-skeleton and Delaunay triangulation. We present an algorithm that identifies the minimum set $S\subseteq E$ of edges of a given plane graph $I=(V,E)$ such that $I \subseteq CG_\beta(V, S)$ for $1 \leq \beta \leq 2$, where $CG_\beta(V, S)$ is the constraint $\beta$-skeleton over the set $V$ of vertices and the set $S$ of constraints. The running time of our algorithm is $O(n)$, provided that the constrained Delaunay triangulation of $I$ is given.Downloads
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Published
2017-02-01
How to Cite
Bose, P., De Carufel, J.-L., Shaikhet, A., & Smid, M. (2017). Essential Constraints of Edge-Constrained Proximity Graphs. Journal of Graph Algorithms and Applications, 21(4), 389–415. https://doi.org/10.7155/jgaa.00422
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Copyright (c) 2017 Prosenjit Bose, Jean-Lou De Carufel, Alina Shaikhet, Michiel Smid
This work is licensed under a Creative Commons Attribution 4.0 International License.
