Publication Date
12-2024
Advisor(s) - Committee Chair
Ahmet Ozer, Mark Robinson, Mikhail Khenner, Dominic Lanphier
Degree Program
Department of Mathematics
Degree Type
Master of Science
Abstract
This study investigates a strongly coupled system of partial differential equations (PDEs) governing heat transfer in a copper rod, longitudinal vibrations, and charge accumulation at electrodes within a magnetizable piezoelectric beam, analyzed within a transmission line framework. Our analysis reveals significant interactions at the contact point between traveling electromagnetic and mechanical waves in magnetizable piezoelectric beams, despite disparities in wave velocities. Findings indicate that, in an open-loop configuration, the coupling between heat dynamics and beam vibrations alone does not ensure exponential stability when only thermal effects are considered. To address this, we propose two boundary feedback control designs at the right end of the piezoelectric beam: (i) a pair of static feedback controllers and (ii) a hybrid design combining a dynamic electrical controller with a static mechanical feedback controller for enhanced system performance. We first construct an energy-equivalent Lyapunov function that satisfies Grönwall’s inequality, supported by rigorous functional-analytic estimates. System parameters are carefully chosen to ensure exponential stability with an explicit decay rate.
Transitioning from the continuous PDE model, we introduce a novel order-reductionbased Finite Difference (FD) approximation that incorporates midpoint discretization and average operators. This approach enables us to construct a discrete analog of the Lyapunov function used in the PDE model. By leveraging this discrete Lyapunov function, we demonstrate exponential stability for the FD-approximated systems, preserving the exact decay rate of the original PDE model. Notably, our proof technique avoids the exhaustive spectral approach, which typically requires constructing the system’s eigenvalues asymptotically or analytically. Instead, by mirroring the structure of the PDE model’s stability proof, this framework provides a rigorous basis for verifying the exponential stability of Finite Difference-based model reductions as the discretization parameter approaches zero. This method advances both theoretical understanding and practical applications for complex piezoelectric systems.
Disciplines
Applied Mathematics | Control Theory | Engineering | Physical Sciences and Mathematics
Recommended Citation
Khalilullah, Sk Md Ibrahim, "EXPONENTIAL STABILITY OF THE PDE MODEL FOR HEAT AND PIEZOELECTRIC BEAM INTERACTIONS WITH STATIC OR HYBRID FEEDBACK CONTROLLERS AND ITS STABILITY-PRESERVING FINITE-DIFFERENCE MODEL REDUCTIONS" (2024). Masters Theses & Specialist Projects. Paper 3787.
https://digitalcommons.wku.edu/theses/3787