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Main Authors: Jin, Zeyu, Li, Ruo
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2310.12799
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author Jin, Zeyu
Li, Ruo
author_facet Jin, Zeyu
Li, Ruo
contents 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.
format Preprint
id arxiv_https___arxiv_org_abs_2310_12799
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Natural Model Reduction for Kinetic Equations
Jin, Zeyu
Li, Ruo
Analysis of PDEs
Mathematical Physics
76P05, 82C03, 35F20
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.
title Natural Model Reduction for Kinetic Equations
topic Analysis of PDEs
Mathematical Physics
76P05, 82C03, 35F20
url https://arxiv.org/abs/2310.12799