Global Minimization of Polynomial Integral Functionals

IF 3 2区数学 Q1 MATHEMATICS, APPLIED

SIAM Journal on Scientific Computing Pub Date : 2024-07-01 DOI:10.1137/23m1592584

Giovanni Fantuzzi, Federico Fuentes

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引用次数: 0

Abstract

SIAM Journal on Scientific Computing, Volume 46, Issue 4, Page A2123-A2149, August 2024.
Abstract. We describe a “discretize-then-relax” strategy to globally minimize integral functionals over functions [math] in a Sobolev space subject to Dirichlet boundary conditions. The strategy applies whenever the integral functional depends polynomially on [math] and its derivatives, even if it is nonconvex. The “discretize” step uses a bounded finite element scheme to approximate the integral minimization problem with a convergent hierarchy of polynomial optimization problems over a compact feasible set, indexed by the decreasing size [math] of the finite element mesh. The “relax” step employs sparse moment-sum-of-squares relaxations to approximate each polynomial optimization problem with a hierarchy of convex semidefinite programs, indexed by an increasing relaxation order [math]. We prove that, as [math] and [math], solutions of such semidefinite programs provide approximate minimizers that converge in a suitable sense (including in certain [math] norms) to the global minimizer of the original integral functional if it is unique. We also report computational experiments showing that our numerical strategy works well even when technical conditions required by our theoretical analysis are not satisfied.

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多项式积分函数的全局最小化

SIAM 科学计算期刊》，第 46 卷第 4 期，第 A2123-A2149 页，2024 年 8 月。摘要。我们描述了一种 "离散-松弛 "策略，用于全局最小化受 Dirichlet 边界条件限制的 Sobolev 空间中函数 [math] 的积分函数。只要积分函数多项式地依赖于[math]及其导数，即使是非凸函数，该策略也适用。离散化 "步骤使用有界有限元方案，在一个紧凑的可行集上用收敛的多项式优化问题层次来逼近积分最小化问题，并以有限元网格的[数学]大小递减为索引。松弛 "步骤采用稀疏的矩平方和松弛，用一个凸半有限元程序层次来逼近每个多项式优化问题，并以递增的松弛阶数[数学]为索引。我们证明，与[math]和[math]一样，如果原始积分函数的全局最小值是唯一的，那么这种半定量程序的解提供的近似最小值会在适当的意义上（包括在某些[math]规范中）收敛到原始积分函数的全局最小值。我们还报告了计算实验，结果表明即使理论分析所需的技术条件无法满足，我们的数值策略也能很好地发挥作用。

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

SIAM Journal on Scientific Computing 数学-应用数学

CiteScore

5.50

自引率

3.20%

发文量

209

审稿时长

1 months

期刊介绍： The purpose of SIAM Journal on Scientific Computing (SISC) is to advance computational methods for solving scientific and engineering problems. SISC papers are classified into three categories: 1. Methods and Algorithms for Scientific Computing: Papers in this category may include theoretical analysis, provided that the relevance to applications in science and engineering is demonstrated. They should contain meaningful computational results and theoretical results or strong heuristics supporting the performance of new algorithms. 2. Computational Methods in Science and Engineering: Papers in this section will typically describe novel methodologies for solving a specific problem in computational science or engineering. They should contain enough information about the application to orient other computational scientists but should omit details of interest mainly to the applications specialist. 3. Software and High-Performance Computing: Papers in this category should concern the novel design and development of computational methods and high-quality software, parallel algorithms, high-performance computing issues, new architectures, data analysis, or visualization. The primary focus should be on computational methods that have potentially large impact for an important class of scientific or engineering problems.