Two simple criterion to obtain exact controllability and stabilization of a linear family of dispersive PDE's on a periodic domain

IF 1.3 4区数学 Q1 MATHEMATICS Evolution Equations and Control Theory Pub Date : 2021-10-05 DOI:10.3934/eect.2021062

F. V. Leal, A. Pastor

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引用次数: 4

Abstract

In this work, we use the classical moment method to find a practical and simple criterion to determine if a family of linearized Dispersive equations on a periodic domain is exactly controllable and exponentially stabilizable with any given decay rate in \begin{document}$ H_{p}^{s}(\mathbb{T}) $\end{document} with \begin{document}$ s\in \mathbb{R}. $\end{document} We apply these results to prove that the linearized Smith equation, the linearized dispersion-generalized Benjamin-Ono equation, the linearized fourth-order Schrödinger equation, and the Higher-order Schrödinger equations are exactly controllable and exponentially stabilizable with any given decay rate in \begin{document}$ H_{p}^{s}(\mathbb{T}) $\end{document} with \begin{document}$ s\in \mathbb{R}. $\end{document}

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在周期域上得到色散PDE线性族精确可控性和稳定性的两个简单判据

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来源期刊

Evolution Equations and Control Theory MATHEMATICS, APPLIED-MATHEMATICS

CiteScore

3.10

自引率

6.70%

发文量

期刊介绍： EECT is primarily devoted to papers on analysis and control of infinite dimensional systems with emphasis on applications to PDE''s and FDEs. Topics include: * Modeling of physical systems as infinite-dimensional processes * Direct problems such as existence, regularity and well-posedness * Stability, long-time behavior and associated dynamical attractors * Indirect problems such as exact controllability, reachability theory and inverse problems * Optimization - including shape optimization - optimal control, game theory and calculus of variations * Well-posedness, stability and control of coupled systems with an interface. Free boundary problems and problems with moving interface(s) * Applications of the theory to physics, chemistry, engineering, economics, medicine and biology