Dictionary-based online-adaptive structure-preserving model order reduction for parametric Hamiltonian systems

IF 1.7 3区数学 Q2 MATHEMATICS, APPLIED

Advances in Computational Mathematics Pub Date : 2024-02-05 DOI:10.1007/s10444-023-10102-7

Robin Herkert, Patrick Buchfink, Bernard Haasdonk

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引用次数: 0

Abstract

Classical model order reduction (MOR) for parametric problems may become computationally inefficient due to large sizes of the required projection bases, especially for problems with slowly decaying Kolmogorov n-widths. Additionally, Hamiltonian structure of dynamical systems may be available and should be preserved during the reduction. In the current presentation, we address these two aspects by proposing a corresponding dictionary-based, online-adaptive MOR approach. The method requires dictionaries for the state-variable, non-linearities, and discrete empirical interpolation (DEIM) points. During the online simulation, local basis extensions/simplifications are performed in an online-efficient way, i.e., the runtime complexity of basis modifications and online simulation of the reduced models do not depend on the full state dimension. Experiments on a linear wave equation and a non-linear Sine-Gordon example demonstrate the efficiency of the approach.

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基于字典的参数哈密顿系统在线自适应结构保全模型阶次缩减

参数问题的经典模型阶次还原（MOR）可能会因为所需的投影基数过大而导致计算效率低下，尤其是对于具有缓慢衰减的 Kolmogorov n 宽的问题。此外，动态系统的哈密顿结构可能存在，并应在还原过程中予以保留。在本报告中，我们针对这两个方面提出了一种相应的基于字典的在线自适应 MOR 方法。该方法需要状态变量、非线性和离散经验插值（DEIM）点的字典。在在线仿真过程中，局部基础扩展/简化以在线高效的方式进行，即基础修改的运行时间复杂度和简化模型的在线仿真不依赖于完整的状态维度。一个线性波方程和一个非线性正弦-戈登例子的实验证明了这种方法的效率。

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

Advances in Computational Mathematics 数学-应用数学

CiteScore

3.00

自引率

5.90%

发文量

审稿时长

3 months

期刊介绍： Advances in Computational Mathematics publishes high quality, accessible and original articles at the forefront of computational and applied mathematics, with a clear potential for impact across the sciences. The journal emphasizes three core areas: approximation theory and computational geometry; numerical analysis, modelling and simulation; imaging, signal processing and data analysis. This journal welcomes papers that are accessible to a broad audience in the mathematical sciences and that show either an advance in computational methodology or a novel scientific application area, or both. Methods papers should rely on rigorous analysis and/or convincing numerical studies.