Maximizing the Sum of Radii of Disjoint Balls or Disks

Q4 Mathematics

International Journal of Computational Geometry & Applications Pub Date : 2016-07-07 DOI:10.20382/jocg.v8i1a12

D. Eppstein

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引用次数: 3

Abstract

Finding nonoverlapping balls with given centers in any metric space, maximizing the sum of radii of the balls, can be expressed as a linear program. Its dual linear program expresses the problem of finding a minimum-weight set of cycles (allowing 2-cycles) covering all vertices in a complete geometric graph. For points in a Euclidean space of any finite dimension~$d$, with any convex distance function on this space, this graph can be replaced by a sparse subgraph obeying a separator theorem. This graph structure leads to an algorithm for finding the optimum set of balls in time $O(n^{2-1/d})$, improving the $O(n^3)$ time of a naive cycle cover algorithm. As a subroutine, we provide an algorithm for weighted bipartite matching in graphs with separators, which speeds up the best previous algorithm for this problem on planar bipartite graphs from $O(n^{3/2}\log n)$ to $O(n^{3/2})$ time. We also show how to constrain the balls to all have radius at least a given threshold value, and how to apply our radius-sum optimization algorithms to the problem of embedding a finite metric space into a star metric minimizing the average distance to the hub.

查看原文本刊更多论文

最大化不相交的球或盘的半径总和

在任意度量空间中寻找具有给定中心的非重叠球，使球的半径和最大化，可以表示为一个线性规划。它的对偶线性规划表达了寻找覆盖完整几何图中所有顶点的最小权值环集(允许2个环)的问题。对于任意有限维欧几里得空间上的点，在该空间上具有任意凸距离函数，该图可以被服从分隔定理的稀疏子图所代替。这种图结构导致了在$O(n^{2-1/d})$时间内找到最优球集的算法，改进了朴素循环覆盖算法的$O(n^3)$时间。作为子程序，我们提供了一种带分隔符的二部图的加权匹配算法，该算法将平面二部图的最佳匹配算法从$O(n^{3/2}\log n)$缩短到$O(n^{3/2})$。我们还展示了如何约束所有球的半径至少具有给定的阈值，以及如何将我们的半径和优化算法应用于将有限度量空间嵌入到最小化到轮毂的平均距离的星形度量的问题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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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.