Energy-based Control and Observer Design for higher-order infinite-dimensional Port-Hamiltonian Systems <ce:cross-ref refid='fn1'> <ce:sup loc='post'>?</ce:sup> </ce:cross-ref>

Tobias Malzer; Lukas Ecker; Markus Sch?berl

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Energy-based Control and Observer Design for higher-order infinite-dimensional Port-Hamiltonian Systems ?

机译：基于能量的控制和观测器设计高级无限维端口 - Hamiltonian Systems ？

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In this paper, we present a control-design strategy based on the energy-Casimir method for infinite-dimensional, boundary-actuated port-Hamiltonian systems with two-dimensional spatial domain and second-order Hamiltonian. The resulting control law depends on distributed system states that cannot be measured, and therefore, we additionally design an infinite-dimensional observer by exploiting the port-Hamiltonian system representation. A Kirchhoff-Love plate serves as an example in order to demonstrate the proposed approaches.

机译：在本文中，我们介绍了一种基于具有二维空间域和二阶哈密顿的无限维度，边界致动的端口系统系统的能量 - Casimir方法的控制设计策略。由此产生的控制法取决于无法测量的分布式系统状态，因此，我们通过利用端口汉密尔顿系统表示，我们另外设计无限维观察者。一款Kirchhoff-Love板用作示例，以便展示所提出的方法。

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《IFAC PapersOnLine》 |2021年第19期|共8页
作者
Tobias Malzer; Lukas Ecker; Markus Sch?berl;
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infinite-dimensional systemspartial differential equationsboundary actuationport-Hamiltonian systemsstructural invariantsobserver design;

机译：无限尺寸系统分区差分方程界面驱动 - Hamiltonian Systemsstructure InvariantSobserver设计;

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Energy-based Control and Observer Design for higher-order infinite-dimensional Port-Hamiltonian Systems ?

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