Computing the cut locus, Voronoi diagram, and signed distance function of polygons

IF 1.3 4区计算机科学 Q3 COMPUTER SCIENCE, SOFTWARE ENGINEERING Computer Aided Geometric Design Pub Date : 2024-09-18 DOI:10.1016/j.cagd.2024.102388

Csaba Bálint, Róbert Bán, Gábor Valasek

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Abstract

This paper presents a new method for the computation of the generalized Voronoi diagram of planar polygons. First, we show that the vertices of the cut locus can be computed efficiently. This is achieved by enumerating the tripoints of the polygon, a superset of the cut locus vertices. This is the set of all points that are of equal distance to three distinct topological entities. Then our algorithm identifies and connects the appropriate tripoints to form the cut locus vertex connectivity graph, where edges define linear or parabolic boundary segments between the Voronoi regions, resulting in the generalized Voronoi diagram. Our proposed method is validated on complex polygon soups. We apply the algorithm to represent the exact signed distance function of the polygon by augmenting the Voronoi regions with linear and radial functions, calculating the cut locus both inside and outside.

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计算多边形的切割位置、沃罗诺图和符号距离函数

本文提出了一种计算平面多边形广义沃罗诺图的新方法。首先，我们证明了切割位置的顶点可以高效计算。这是通过枚举多边形的三点（切点顶点的超集）来实现的。这是与三个不同拓扑实体距离相等的所有点的集合。然后，我们的算法识别并连接适当的三点，形成切割位置顶点连接图，其中的边定义了沃罗诺伊区域之间的线性或抛物线边界段，从而形成广义的沃罗诺伊图。我们提出的方法在复杂多边形汤上得到了验证。我们应用该算法，通过用线性和径向函数增强沃罗诺伊区域来表示多边形的精确带符号距离函数，计算内部和外部的切点。

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来源期刊

Computer Aided Geometric Design 工程技术-计算机：软件工程

CiteScore

3.50

自引率

13.30%

发文量

审稿时长

60 days

期刊介绍： The journal Computer Aided Geometric Design is for researchers, scholars, and software developers dealing with mathematical and computational methods for the description of geometric objects as they arise in areas ranging from CAD/CAM to robotics and scientific visualization. The journal publishes original research papers, survey papers and with quick editorial decisions short communications of at most 3 pages. The primary objects of interest are curves, surfaces, and volumes such as splines (NURBS), meshes, subdivision surfaces as well as algorithms to generate, analyze, and manipulate them. This journal will report on new developments in CAGD and its applications, including but not restricted to the following: -Mathematical and Geometric Foundations- Curve, Surface, and Volume generation- CAGD applications in Numerical Analysis, Computational Geometry, Computer Graphics, or Computer Vision- Industrial, medical, and scientific applications. The aim is to collect and disseminate information on computer aided design in one journal. To provide the user community with methods and algorithms for representing curves and surfaces. To illustrate computer aided geometric design by means of interesting applications. To combine curve and surface methods with computer graphics. To explain scientific phenomena by means of computer graphics. To concentrate on the interaction between theory and application. To expose unsolved problems of the practice. To develop new methods in computer aided geometry.

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