动力学方程的自然模型还原

IF 1.2 3区数学 Q1 MATHEMATICS

Research in the Mathematical Sciences Pub Date : 2024-08-03 DOI:10.1007/s40687-024-00466-7

Zeyu Jin, Ruo Li

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引用次数: 0

摘要

研究高维问题的一个有前途的方法是识别其内在的低维特征，这可以通过最近开发的有效低维函数表示技术（如机器学习）来实现。基于现有的有限维近似解流形，本文提出了一种新颖的动力学方程模型还原框架。该方法利用投影到近似流形的切线束，自然产生一阶双曲系统。在近似流形的某些条件下，还原模型保留了几个关键性质，包括双曲性、守恒定律、熵耗散、有限传播速度和线性稳定性。本文首次严格讨论了动力学方程 H 定理与还原系统线性稳定性条件之间的关系，确定了模型还原所涉及的黎曼度量的选择。该框架广泛适用于动力学理论中许多模型的模型还原。

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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Natural model reduction for kinetic equations

A promising approach to investigating high-dimensional problems is to identify their intrinsically low-dimensional features, which can be achieved through recently developed techniques for effective low-dimensional representation of functions such as machine learning. Based on available finite-dimensional approximate solution manifolds, this paper proposes a novel model reduction framework for kinetic equations. The method employs projections onto tangent bundles of approximate manifolds, naturally resulting in first-order hyperbolic systems. Under certain conditions on the approximate manifolds, the reduced models preserve several crucial properties, including hyperbolicity, conservation laws, entropy dissipation, finite propagation speed, and linear stability. For the first time, this paper rigorously discusses the relation between the H-theorem of kinetic equations and the linear stability conditions of reduced systems, determining the choice of Riemannian metrics involved in the model reduction. The framework is widely applicable for the model reduction of many models in kinetic theory.

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来源期刊

Research in the Mathematical Sciences Mathematics-Computational Mathematics

CiteScore

2.00

自引率

8.30%

发文量

期刊介绍： Research in the Mathematical Sciences is an international, peer-reviewed hybrid journal covering the full scope of Theoretical Mathematics, Applied Mathematics, and Theoretical Computer Science. The Mission of the Journal is to publish high-quality original articles that make a significant contribution to the research areas of both theoretical and applied mathematics and theoretical computer science. This journal is an efficient enterprise where the editors play a central role in soliciting the best research papers, and where editorial decisions are reached in a timely fashion. Research in the Mathematical Sciences does not have a length restriction and encourages the submission of longer articles in which more complex and detailed analysis and proofing of theorems is required. It also publishes shorter research communications (Letters) covering nascent research in some of the hottest areas of mathematical research. This journal will publish the highest quality papers in all of the traditional areas of applied and theoretical areas of mathematics and computer science, and it will actively seek to publish seminal papers in the most emerging and interdisciplinary areas in all of the mathematical sciences. Research in the Mathematical Sciences wishes to lead the way by promoting the highest quality research of this type.