INTERNAL STABILIZATION OF INTERCONNECTED HEAT-WAVE EQUATIONS

Xiu Fang Yu; Jun Min Wang; Han Wen Zhang

INTERNAL STABILIZATION OF INTERCONNECTED HEAT-WAVE EQUATIONS

Xiu Fang Yu, Jun Min Wang, Han Wen Zhang

School of Mathematics and Statistics

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

Abstract

This article concerns the internal stabilization problem of 1-D interconnected heat-wave equations, where information exchange and the two actuators occur at the adjacent side of the two equations. By designing an inverse back-stepping transformation, the original system is converted into a dissipative target system. Moreover, we investigate the eigenvalues distribution and the corresponding eigenfunctions of the closed-loop system by an asymptotic analysis method. This shows that the spectrum of the system can be divided into two families: one distributed along the a line parallel to the left side of the imaginary axis and symmetric to the real axis, and the other on the left half real axis. Then we work on the properties of the resolvent operator and we verify that the root subspace is complete. Finally, we prove that the closed-loop system is exponentially stable.

Original language	English
Article number	3
Journal	Electronic Journal of Differential Equations
Volume	2023
Publication status	Published - 2023

Keywords

Heat-wave equation
boundary control
exponential stability
root subspace
spectrum

Cite this

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title = "INTERNAL STABILIZATION OF INTERCONNECTED HEAT-WAVE EQUATIONS",

abstract = "This article concerns the internal stabilization problem of 1-D interconnected heat-wave equations, where information exchange and the two actuators occur at the adjacent side of the two equations. By designing an inverse back-stepping transformation, the original system is converted into a dissipative target system. Moreover, we investigate the eigenvalues distribution and the corresponding eigenfunctions of the closed-loop system by an asymptotic analysis method. This shows that the spectrum of the system can be divided into two families: one distributed along the a line parallel to the left side of the imaginary axis and symmetric to the real axis, and the other on the left half real axis. Then we work on the properties of the resolvent operator and we verify that the root subspace is complete. Finally, we prove that the closed-loop system is exponentially stable.",

keywords = "Heat-wave equation, boundary control, exponential stability, root subspace, spectrum",

author = "Yu, {Xiu Fang} and Wang, {Jun Min} and Zhang, {Han Wen}",

year = "2023",

language = "English",

volume = "2023",

journal = "Electronic Journal of Differential Equations",

issn = "1072-6691",

publisher = "Texas State University - San Marcos",

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TY - JOUR

T1 - INTERNAL STABILIZATION OF INTERCONNECTED HEAT-WAVE EQUATIONS

AU - Yu, Xiu Fang

AU - Wang, Jun Min

AU - Zhang, Han Wen

PY - 2023

Y1 - 2023

N2 - This article concerns the internal stabilization problem of 1-D interconnected heat-wave equations, where information exchange and the two actuators occur at the adjacent side of the two equations. By designing an inverse back-stepping transformation, the original system is converted into a dissipative target system. Moreover, we investigate the eigenvalues distribution and the corresponding eigenfunctions of the closed-loop system by an asymptotic analysis method. This shows that the spectrum of the system can be divided into two families: one distributed along the a line parallel to the left side of the imaginary axis and symmetric to the real axis, and the other on the left half real axis. Then we work on the properties of the resolvent operator and we verify that the root subspace is complete. Finally, we prove that the closed-loop system is exponentially stable.

AB - This article concerns the internal stabilization problem of 1-D interconnected heat-wave equations, where information exchange and the two actuators occur at the adjacent side of the two equations. By designing an inverse back-stepping transformation, the original system is converted into a dissipative target system. Moreover, we investigate the eigenvalues distribution and the corresponding eigenfunctions of the closed-loop system by an asymptotic analysis method. This shows that the spectrum of the system can be divided into two families: one distributed along the a line parallel to the left side of the imaginary axis and symmetric to the real axis, and the other on the left half real axis. Then we work on the properties of the resolvent operator and we verify that the root subspace is complete. Finally, we prove that the closed-loop system is exponentially stable.

KW - Heat-wave equation

KW - boundary control

KW - exponential stability

KW - root subspace

KW - spectrum

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M3 - Article

AN - SCOPUS:85146338734

SN - 1072-6691

VL - 2023

JO - Electronic Journal of Differential Equations

JF - Electronic Journal of Differential Equations

M1 - 3

ER -

INTERNAL STABILIZATION OF INTERCONNECTED HEAT-WAVE EQUATIONS

Abstract

Keywords

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