Enumerating combinatorial resultant trees

IF 0.4 4区计算机科学 Q4 MATHEMATICS Computational Geometry-Theory and Applications Pub Date : 2023-10-31 DOI:10.1016/j.comgeo.2023.102064

Goran Malić , Ileana Streinu

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Abstract

A 2D rigidity circuit is a minimal graph $G = (V, E)$ supporting a non-trivial stress in any generic placement of its vertices in the Euclidean plane. All 2D rigidity circuits can be constructed from $K_{4}$ graphs using combinatorial resultant (CR) operations. A combinatorial resultant tree (CR-tree) is a rooted binary tree capturing the structure of such a construction.

The CR operation has a specific algebraic interpretation, where an essentially unique circuit polynomial is associated to each circuit graph. Performing Sylvester resultant operations on these polynomials is in one-to-one correspondence with CR operations on circuit graphs. This mixed combinatorial/algebraic approach led recently to an effective algorithm for computing circuit polynomials. Its complexity analysis remains an open problem, but it is known to be influenced by the depth and shape of CR-trees in ways that have only partially been investigated.

In this paper, we present an effective algorithm for enumerating all the CR-trees of a given circuit with n vertices. Our algorithm has been fully implemented in Mathematica and allows for computational experimentation with various optimality criteria in the resulting, potentially exponentially large collections of CR-trees.

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枚举组合结果树

二维刚性电路是一个极小图G=(V,E)，它在欧几里得平面上的顶点的任意一般位置上支持一个非平凡应力。所有的二维刚性电路都可以用组合结运算从K4图构造出来。组合结树(CR-tree)是一种有根的二叉树，它捕获了这种结构的结构。CR操作具有特定的代数解释，其中本质上唯一的电路多项式与每个电路图相关联。在这些多项式上执行Sylvester结式运算与在电路图上执行CR运算是一一对应的。这种混合组合/代数方法最近导致了一种计算电路多项式的有效算法。它的复杂性分析仍然是一个悬而未决的问题，但已知它受到cr树的深度和形状的影响，而这些影响只在一定程度上得到了研究。在本文中，我们提出了一种有效的算法来枚举给定电路的所有n个顶点的cr树。我们的算法已经在Mathematica中完全实现，并允许在结果中使用各种最优性标准进行计算实验，可能是指数级大的cr树集合。

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

Computational Geometry-Theory and Applications 数学-数学

CiteScore

1.60

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： Computational Geometry is a forum for research in theoretical and applied aspects of computational geometry. The journal publishes fundamental research in all areas of the subject, as well as disseminating information on the applications, techniques, and use of computational geometry. Computational Geometry publishes articles on the design and analysis of geometric algorithms. All aspects of computational geometry are covered, including the numerical, graph theoretical and combinatorial aspects. Also welcomed are computational geometry solutions to fundamental problems arising in computer graphics, pattern recognition, robotics, image processing, CAD-CAM, VLSI design and geographical information systems. Computational Geometry features a special section containing open problems and concise reports on implementations of computational geometry tools.

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