Internal and Boundary Control of Piezoelectric Beams with Magnetic Effects and Voltage Controller: Exponential and Polynomial Decay Rates

Adel M. Al-Mahdi

doi:10.1007/s40819-024-01816-3

Internal and Boundary Control of Piezoelectric Beams with Magnetic Effects and Voltage Controller: Exponential and Polynomial Decay Rates

Adel M. Al-Mahdi^*

^*Corresponding author for this work

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

1 Scopus citations

Abstract

This paper investigates a one-dimensional piezoelectric beam model that incorporates magnetic effects, significantly influencing the stability of the control system. We demonstrate that the system achieves exponential and polynomial stability using an entirely single electrical feedback (voltage control) alongside a single localized nonlinear damping mechanism of variable exponent type applied to the displacement. Various cases are discussed, and we prove that the stability outcomes depend on these variable exponents’ values. The proof method primarily employs the multiplier technique, alongside inequalities and embedding properties. Our findings provide a new contribution to the theoretical understanding of the asymptotic behavior in nonlinear models of piezoelectric beams affected by magnetic effects.

Original language	English
Article number	5
Journal	International Journal of Applied and Computational Mathematics
Volume	11
Issue number	1
DOIs	https://doi.org/10.1007/s40819-024-01816-3
State	Published - Feb 2025

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature India Private Limited 2024.

Keywords

Embedding properties
Multiplier method
Piezoelectric beam
Stability
Variable exponents

ASJC Scopus subject areas

Computational Mathematics
Applied Mathematics

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10.1007/s40819-024-01816-3

Cite this

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abstract = "This paper investigates a one-dimensional piezoelectric beam model that incorporates magnetic effects, significantly influencing the stability of the control system. We demonstrate that the system achieves exponential and polynomial stability using an entirely single electrical feedback (voltage control) alongside a single localized nonlinear damping mechanism of variable exponent type applied to the displacement. Various cases are discussed, and we prove that the stability outcomes depend on these variable exponents{\textquoteright} values. The proof method primarily employs the multiplier technique, alongside inequalities and embedding properties. Our findings provide a new contribution to the theoretical understanding of the asymptotic behavior in nonlinear models of piezoelectric beams affected by magnetic effects.",

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N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer Nature India Private Limited 2024.

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N2 - This paper investigates a one-dimensional piezoelectric beam model that incorporates magnetic effects, significantly influencing the stability of the control system. We demonstrate that the system achieves exponential and polynomial stability using an entirely single electrical feedback (voltage control) alongside a single localized nonlinear damping mechanism of variable exponent type applied to the displacement. Various cases are discussed, and we prove that the stability outcomes depend on these variable exponents’ values. The proof method primarily employs the multiplier technique, alongside inequalities and embedding properties. Our findings provide a new contribution to the theoretical understanding of the asymptotic behavior in nonlinear models of piezoelectric beams affected by magnetic effects.

AB - This paper investigates a one-dimensional piezoelectric beam model that incorporates magnetic effects, significantly influencing the stability of the control system. We demonstrate that the system achieves exponential and polynomial stability using an entirely single electrical feedback (voltage control) alongside a single localized nonlinear damping mechanism of variable exponent type applied to the displacement. Various cases are discussed, and we prove that the stability outcomes depend on these variable exponents’ values. The proof method primarily employs the multiplier technique, alongside inequalities and embedding properties. Our findings provide a new contribution to the theoretical understanding of the asymptotic behavior in nonlinear models of piezoelectric beams affected by magnetic effects.

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KW - Stability

KW - Variable exponents

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Internal and Boundary Control of Piezoelectric Beams with Magnetic Effects and Voltage Controller: Exponential and Polynomial Decay Rates

Abstract

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Keywords

ASJC Scopus subject areas

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