Modeling and Optimization of Electrode Configurations for Piezoelectric Material
Author | : Veronika Schulze |
Publisher | : |
Total Pages | : 0 |
Release | : 2023* |
ISBN-10 | : OCLC:1408414048 |
ISBN-13 | : |
Rating | : 4/5 (48 Downloads) |
Book excerpt: Englische Version: Piezoelectrics have a wide range of applications in industry, everyday life and research. This requires an accurate knowledge of the material behavior, which implies the solution of simulation-based inverse identification problems. This thesis focuses on the optimal design of experiments addressing this problem. Piezoelectric materials exhibit the property of mechanical or electrical changes in response to applied potentials or forces (direct and indirect piezoelectric effect). To apply voltage and to exploit the indirect piezoelectric effect, electrodes are attached whose configura- tion have a significant influence on possible system responses. Therefore, the potential, the number and the size of the electrodes are initially optimized in the two-dimensional case. The piezoelectric behavior in the considered small signal range is based on a time dependent linear partial differential equation system. The derivation as well as the exis- tence, uniqueness and regularity of the solutions of the equations are shown. Time- and frequency-dependent simulations based on the finite element method (FEM) with the FEM simulation tool FEniCS are performed to calculate the electric charge and the impedance, which are relevant for the material identification problem and thus for the experimental design. Drawbacks in the derivative calculations are pointed out and a first set of adjoint equations is formulated. The modeling of the optimal experimental design (OED) prob- lem is done mainly by controlling the potential of the Dirichlet boundary conditions of the boundary value problem. Several numerical examples are used to show the resulting configurations and to address the difficulties encountered. Further electrode modeling ap- proaches for example by controlling the material properties are then discussed. Finally, possible extensions of the presented OED problem are pointed out.