Improved polytope volume calculations based on Hamiltonian Monte Carlo with boundary reflections and sweet arithmetics

Q4 Mathematics

International Journal of Computational Geometry & Applications Pub Date : 2020-12-14 DOI:10.20382/jocg.v13i1a3

F. Cazals, Augustin Chevallier, Sylvain Pion

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引用次数: 6

Abstract

Computing the volume of a high dimensional polytope is a fundamental problem in geometry, also connected to the calculation of densities of states in statistical physics, and a central building block of such algorithms is the method used to sample a target probability distribution. This paper studies Hamiltonian Monte Carlo (HMC) with reflections on the boundary of a domain, providing an enhanced alternative to Hit-and-run (HAR) to sample a target distribution restricted to the polytope. We make three contributions. First, we provide a convergence bound, paving the way to more precise mixing time analysis. Second, we present a robust implementation based on multi-precision arithmetic-a mandatory ingredient to guarantee exact predicates and robust constructions. We however allow controlled failures to happen, introducing the Sweeten Exact Geometric Computing (SEGC) paradigm. Third, we use our HMC random walk to perform H-polytope volume calculations, using it as an alternative to HAR within the volume algorithm by Cousins and Vempala. The tests, conducted up to dimension 50, show that the HMC random walk outperforms HAR.

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基于边界反射和甜蜜算法的改进哈密顿蒙特卡罗多面体体积计算

计算高维多面体的体积是几何中的一个基本问题，也与统计物理中状态密度的计算有关，这种算法的一个中心组成部分是用于对目标概率分布进行采样的方法。本文研究了具有域边界反射的哈密顿蒙特卡罗算法(HMC)，提供了一种增强的替代方法来对限制在多面体中的目标分布进行采样。我们有三个贡献。首先，我们提供了一个收敛界，为更精确的混合时间分析铺平了道路。其次，我们提出了一种基于多精度算法的鲁棒实现，多精度算法是保证精确谓词和鲁棒构造的必要条件。然而，我们允许可控故障发生，引入Sweeten精确几何计算(SEGC)范式。第三，我们使用我们的HMC随机漫步来执行h -多面体体积计算，使用它作为在Cousins和Vempala的体积算法中HAR的替代方案。在维度达到50的情况下进行的测试表明，HMC随机漫步优于HAR。

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.