A Robust Finite-Difference Model Reduction for the Boundary Feedback Stabilization of Fully-dynamic Piezoelectric Beams
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Piezoelectric materials exhibit electric responses to mechanical stress, and mechanical responses to electric stress. The PDE model, describing the longitudinal oscillations on the beam, with two boundary feedback controllers is known to have exponentially stable solutions. However, the reduced model by the semi-discretized Finite Elements is shown to lack of exponential stability uniformly as the discretization parameter tends to zero. This is due to the loss of uniform gap among the high-frequency eigenvalues. In this paper, an alternate Finite-Difference based model reduction is investigated by cleverly reducing the order of the model together with the consideration of equidistant grid points and averaging operators. This new model reduction successfully retains the exponential stability uniformly as the discretization parameter tends to zero. Moreover, it does not need a further numerical Fourier filtering. Our results are based on a careful construction of a Lyapunov function. The numerical simulations are provided to compare reduced models and to show the strength of introduced results.
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