基于wspd的扳手中的本地路由

Q4 Mathematics

International Journal of Computational Geometry & Applications Pub Date : 2021-01-26 DOI:10.20382/JOCG.V12I1A1

J. Carufel, P. Bose, F. Paradis, V. Dujmovic

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引用次数: 2

摘要

由Callahan和Kosaraju提出的定义在$R^2$点上的完备欧几里得图的良隔对分解(WSPD) [j] [j] .计算机工程学报，42(1):67-90,1995]是一种基于长度将完备图的边划分为线性集合的技术。在wspd的许多不同应用中，Callahan和Kosaraju证明了从每个集合中选择任意一条边(称为WSPD-spanner)得到的稀疏子图是$1 + 8/(s−4)$-spanner，其中$s > 4$是用于划分边的分离比。尽管对于各种扳手(如yao -graph、$\Theta$-graph和Delaunay图的变体)存在竞争性的本地路由策略，但对于任何wspd -扳手，已知的本地路由策略很少。我们的主要贡献是一个本地路由算法，在WSPD-spanner上具有接近最优的竞争路由比$1 + O(1/s)$。具体来说，使用Callahan和Kosaraju的公平分割树，我们展示了如何构建一个具有生成比$1 + 4/s + 4/(s−2)$的wspd -扳手，这比$1 + 8/(s−4)$略有改进。然后，我们提出了该扳手上的2-local和1-local路由算法，竞争路由比分别为$1 + 6/(s−2)+ 4/s$和$1 + 8/(s−2)+ 4/s + 8/s^2$。此外，我们证明了存在一个点集，我们的WSPD-spanner的生成比至少为$1 + 8/s$，从而证明了它的生成比的近最优性和我们两种路由算法的路由比的近最优性。

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Local routing in WSPD-based spanners

The well-separated pair decomposition (WSPD) of the complete Euclidean graph defined on points in $R^2$, introduced by Callahan and Kosaraju [JACM, 42 (1): 67-90, 1995], is a technique for partitioning the edges of the complete graph based on length into a linear number of sets. Among the many different applications of WSPDs, Callahan and Kosaraju proved that the sparse subgraph that results by selecting an arbitrary edge from each set (called WSPD-spanner) is a $1 + 8/(s − 4)$-spanner, where $s > 4$ is the separation ratio used for partitioning the edges.Although competitive local-routing strategies exist for various spanners such as Yao-graphs, $\Theta$-graphs, and variants of Delaunay graphs, few local-routing strategies are known for any WSPD-spanner. Our main contribution is a local-routing algorithm with a near-optimal competitive routing ratio of $1 + O(1/s)$ on a WSPD-spanner.Specifically, using Callahan and Kosaraju’s fair split-tree, we show how to build a WSPD-spanner with spanning ratio $1 + 4/s + 4/(s − 2)$ which is a slight improvement over $1 + 8/(s − 4)$. We then present a 2-local and a 1-local routing algorithm on this spanner with competitive routing ratios of $1 + 6/(s − 2) + 4/s$ and $1 + 8/(s − 2) + 4/s + 8/s^2$, respectively. Moreover, we prove that there exists a point set for which our WSPD-spanner has a spanning ratio of at least $1 + 8/s$, thereby proving the near-optimality of its spanning ratio and the near-optimality of the routing ratio of both our routing algorithms.

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来源期刊

International Journal of Computational Geometry & Applications 数学-计算机：理论方法

CiteScore

0.80

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The International Journal of Computational Geometry & Applications (IJCGA) is a quarterly journal devoted to the field of computational geometry within the framework of design and analysis of algorithms. Emphasis is placed on the computational aspects of geometric problems that arise in various fields of science and engineering including computer-aided geometry design (CAGD), computer graphics, constructive solid geometry (CSG), operations research, pattern recognition, robotics, solid modelling, VLSI routing/layout, and others. Research contributions ranging from theoretical results in algorithm design — sequential or parallel, probabilistic or randomized algorithms — to applications in the above-mentioned areas are welcome. Research findings or experiences in the implementations of geometric algorithms, such as numerical stability, and papers with a geometric flavour related to algorithms or the application areas of computational geometry are also welcome.