Jesus-Pablo Toledo-Zucco , Denis Matignon , Charles Poussot-Vassal , Yann Le Gorrec
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We show that if the initial PDE is <em>passive</em> (or <em>Impedance Energy Preserving</em>), the discretized model also is. In addition and since the discretized model or Full Order Model (FOM) can be of large dimension, we recall the standard Loewner framework for the Model Order Reduction (MOR) using frequency domain interpolation. We recall the main steps to produce a Reduced Order Model (ROM) that approaches the FOM in a given range of frequencies. We summarize the steps to follow in order to obtain a ROM that preserves the passive structure as well. Finally, we provide a constructive way to build a projector that allows to recover the physical meaning of the state variables from the ROM to the FOM. 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We summarize the steps to follow in order to obtain a ROM that preserves the passive structure as well. Finally, we provide a constructive way to build a projector that allows to recover the physical meaning of the state variables from the ROM to the FOM. 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引用次数: 0
摘要
本文提出了一种系统方法,用于离散化和还原一类输入和输出均位于空间边界的一维偏微分方程(PDEs)。我们考虑的这一类系统被称为 "边界控制端口-哈密顿系统(BC-PHSs)",涵盖了一大类具有大量边界输入和输出的双曲 PDEs。例如,具有 Neumann、Dirichlet 或混合边界条件的波和梁就是这种情况。基于分区有限元法(PFEM),我们开发了一种用于一维 BC-PHS 的结构保持空间离散化的数值方案。我们证明,如果初始 PDE 是被动的(或阻抗能量守恒),离散化模型也是被动的。此外,由于离散化模型或全阶模型(FOM)的维度可能很大,我们回顾了使用频域插值进行模型阶次缩减(MOR)的标准 Loewner 框架。我们回顾了在给定频率范围内生成接近全阶模型(FOM)的降阶模型(ROM)的主要步骤。我们还总结了获得保留被动结构的 ROM 所需的步骤。最后,我们提供了一种建立投影器的建设性方法,该投影器可将状态变量的物理意义从 ROM 恢复到 FOM。我们以一维波方程和季莫申科光束为例,展示了所提方法的多功能性。
Structure-preserving discretization and model order reduction of boundary-controlled 1D port-Hamiltonian systems
This paper presents a systematic methodology for the discretization and reduction of a class of one-dimensional Partial Differential Equations (PDEs) with inputs and outputs collocated at the spatial boundaries. The class of system that we consider is known as Boundary-Controlled Port-Hamiltonian Systems (BC-PHSs) and covers a wide class of Hyperbolic PDEs with a large type of boundary inputs and outputs. This is, for instance, the case of waves and beams with Neumann, Dirichlet, or mixed boundary conditions. Based on a Partitioned Finite Element Method (PFEM), we develop a numerical scheme for the structure-preserving spatial discretization for the class of one-dimensional BC-PHSs. We show that if the initial PDE is passive (or Impedance Energy Preserving), the discretized model also is. In addition and since the discretized model or Full Order Model (FOM) can be of large dimension, we recall the standard Loewner framework for the Model Order Reduction (MOR) using frequency domain interpolation. We recall the main steps to produce a Reduced Order Model (ROM) that approaches the FOM in a given range of frequencies. We summarize the steps to follow in order to obtain a ROM that preserves the passive structure as well. Finally, we provide a constructive way to build a projector that allows to recover the physical meaning of the state variables from the ROM to the FOM. We use the one-dimensional wave equation and the Timoshenko beam as examples to show the versatility of the proposed approach.
期刊介绍:
Founded in 1981 by two of the pre-eminent control theorists, Roger Brockett and Jan Willems, Systems & Control Letters is one of the leading journals in the field of control theory. The aim of the journal is to allow dissemination of relatively concise but highly original contributions whose high initial quality enables a relatively rapid review process. All aspects of the fields of systems and control are covered, especially mathematically-oriented and theoretical papers that have a clear relevance to engineering, physical and biological sciences, and even economics. Application-oriented papers with sophisticated and rigorous mathematical elements are also welcome.
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