中位数的形状

Q4 Mathematics

International Journal of Computational Geometry & Applications Pub Date : 2018-02-14 DOI:10.20382/jocg.v10i1a12

Yunfeng Hu, M. Hudelson, B. Krishnamoorthy, Altansuren Tumurbaatar, K. Vixie

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引用次数: 5

摘要

我们引入并开始探索用积分电流表示的有限形状集的均值和中值。中位数在实践中是可以高效地计算出来的，我们的理论和计算重点主要集中在中位数上。我们考虑中位数的存在性和规律性问题。虽然中位数可能不是在所有情况下都存在，但我们证明了质量正则化的中位数是保证存在的。当输入形状由在余维$1$中具有共享边界的积分电流建模时，我们证明了中位数是保证存在的，并且包含在输入电流的\emph{包络}中。另一方面，我们证明了中位数在这种情况下可能\emph{是}不稳定的，平滑的输入可能产生不平滑的中位数。对于更高的共维数，我们证明了\emph{书籍}对于具有共享边界的$\Bbb{R}^3$中的$1$ -电流的有限集是最小化的。作为这个证明的一部分，我们提出了图论中的一个新结果——\emph{舒适}图是\emph{舒适}的——这应该是一个独立的兴趣。进一步，我们证明了中值上的正则点在这种情况下具有类似书本的切线锥。从计算的角度出发，研究了有限简单复形条件下的中值形状。当输入形状由简单复形链表示时，我们证明了寻找中值形状的问题可以表述为一个整数线性规划。这个优化问题在实际中可以作为一个线性规划来解决，从而可以有效地计算中值形状。我们提供了实现我们的方法的开放源代码，任何人都可以用它来试验自己的想法。该软件可通过\href{https://github.com/tbtraltaa/medianshape}{https://github.com/tbtraltaa/medianshape}访问。

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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Median Shapes

We introduce and begin to explore the mean and median of finite sets of shapes represented as integral currents. The median can be computed efficiently in practice, and we focus most of our theoretical and computational attention on medians. We consider questions on the existence and regularity of medians. While the median might not exist in all cases, we show that a mass-regularized median is guaranteed to exist. When the input shapes are modeled by integral currents with shared boundaries in codimension $1$, we show that the median is guaranteed to exist, and is contained in the \emph{envelope} of the input currents. On the other hand, we show that medians can be \emph{wild} in this setting, and smooth inputs can generate non-smooth medians. For higher codimensions, we show that \emph{books} are minimizing for a finite set of $1$-currents in $\Bbb{R}^3$ with shared boundaries. As part of this proof, we present a new result in graph theory---that \emph{cozy} graphs are \emph{comfortable}---which should be of independent interest. Further, we show that regular points on the median have book-like tangent cones in this case. From the point of view of computation, we study the median shape in the settings of a finite simplicial complex. When the input shapes are represented by chains of the simplicial complex, we show that the problem of finding the median shape can be formulated as an integer linear program. This optimization problem can be solved as a linear program in practice, thus allowing one to compute median shapes efficiently. We provide open source code implementing our methods, which could also be used by anyone to experiment with ideas of their own. The software could be accessed at \href{https://github.com/tbtraltaa/medianshape}{https://github.com/tbtraltaa/medianshape}.

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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.