Boundary stabilization of wave equation with velocity recirculation

Lingling Su; Wei Guo; Jun Min Wang; Miroslav Krstic

doi:10.1109/TAC.2017.2688128

Boundary stabilization of wave equation with velocity recirculation

Lingling Su, Wei Guo^*, Jun Min Wang, Miroslav Krstic

^*Corresponding author for this work

School of Mathematics and Statistics

Research output: Contribution to journal › Article › peer-review

44 Citations (Scopus)

Abstract

Nonlocal terms have been the mainstay of the applications of partial differential equation (PDE) backstepping methods to parabolic PDEs. The problem of similar nonlocal terms for wave equations is still open. For wave equations, similar nonlocal terms have not been studied. In this paper, we open the topic of exploration of control of wave PDEs with nonlocal terms. This paper is concerned with the wave equation with in-domain feedback/recirculation of a boundary velocity with a spatially constant coefficient. Due to this nonlocal term, the passivity of the wave equation is destroyed. We first design an explicit state feedback controller to achieve exponential stability for the closed-loop system. Then, we design the output feedback by using infinite-dimensional observer. The backstepping approach is adopted in investigation. It is shown that by using two measurements only, the output feedback makes the closed-loop system exponentially stable.

Original language	English
Article number	7887741
Pages (from-to)	4760-4767
Number of pages	8
Journal	IEEE Transactions on Automatic Control
Volume	62
Issue number	9
DOIs	https://doi.org/10.1109/TAC.2017.2688128
Publication status	Published - Sept 2017

Keywords

Backstepping
hyperbolic
nonlocal term
wave equation

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10.1109/TAC.2017.2688128

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title = "Boundary stabilization of wave equation with velocity recirculation",

abstract = "Nonlocal terms have been the mainstay of the applications of partial differential equation (PDE) backstepping methods to parabolic PDEs. The problem of similar nonlocal terms for wave equations is still open. For wave equations, similar nonlocal terms have not been studied. In this paper, we open the topic of exploration of control of wave PDEs with nonlocal terms. This paper is concerned with the wave equation with in-domain feedback/recirculation of a boundary velocity with a spatially constant coefficient. Due to this nonlocal term, the passivity of the wave equation is destroyed. We first design an explicit state feedback controller to achieve exponential stability for the closed-loop system. Then, we design the output feedback by using infinite-dimensional observer. The backstepping approach is adopted in investigation. It is shown that by using two measurements only, the output feedback makes the closed-loop system exponentially stable.",

keywords = "Backstepping, hyperbolic, nonlocal term, wave equation",

author = "Lingling Su and Wei Guo and Wang, {Jun Min} and Miroslav Krstic",

note = "Publisher Copyright: {\textcopyright} 1963-2012 IEEE.",

year = "2017",

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AU - Su, Lingling

AU - Guo, Wei

AU - Wang, Jun Min

AU - Krstic, Miroslav

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N2 - Nonlocal terms have been the mainstay of the applications of partial differential equation (PDE) backstepping methods to parabolic PDEs. The problem of similar nonlocal terms for wave equations is still open. For wave equations, similar nonlocal terms have not been studied. In this paper, we open the topic of exploration of control of wave PDEs with nonlocal terms. This paper is concerned with the wave equation with in-domain feedback/recirculation of a boundary velocity with a spatially constant coefficient. Due to this nonlocal term, the passivity of the wave equation is destroyed. We first design an explicit state feedback controller to achieve exponential stability for the closed-loop system. Then, we design the output feedback by using infinite-dimensional observer. The backstepping approach is adopted in investigation. It is shown that by using two measurements only, the output feedback makes the closed-loop system exponentially stable.

AB - Nonlocal terms have been the mainstay of the applications of partial differential equation (PDE) backstepping methods to parabolic PDEs. The problem of similar nonlocal terms for wave equations is still open. For wave equations, similar nonlocal terms have not been studied. In this paper, we open the topic of exploration of control of wave PDEs with nonlocal terms. This paper is concerned with the wave equation with in-domain feedback/recirculation of a boundary velocity with a spatially constant coefficient. Due to this nonlocal term, the passivity of the wave equation is destroyed. We first design an explicit state feedback controller to achieve exponential stability for the closed-loop system. Then, we design the output feedback by using infinite-dimensional observer. The backstepping approach is adopted in investigation. It is shown that by using two measurements only, the output feedback makes the closed-loop system exponentially stable.

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KW - hyperbolic

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KW - wave equation

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Boundary stabilization of wave equation with velocity recirculation

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