On the construction of problem-specific basis functions for modelling the massloading effects in micro-acoustic devices

On the construction of problem-specific basis functions for modelling the massloading effects in micro-acoustic devices

This paper presents an efficient algorithm for modelling the massloading effect in 3D models of micro-acoustic devices, utilizing mesh-less Legendre, Jacobi-Galerkin approximations. The efficacy and utility of the proposed method rely on the construction of a set of problem-specific orthogonal basis...

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Hauptverfasser: Vagh, H., Baghai-Wadji, A.
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Acoustic waves
Boundary conditions
Electrodes
FEM
Finite difference methods
Finite element methods
Jacobi-Galerkin Formulation
Jacobian matrices
Mathematical analysis
Mesh Free Methods
Microacoustic Devices
Orthogonal-Jacobi Polynomials
Polynomials
Protection
Surface acoustic wave devices
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Beschreibung
Zusammenfassung:This paper presents an efficient algorithm for modelling the massloading effect in 3D models of micro-acoustic devices, utilizing mesh-less Legendre, Jacobi-Galerkin approximations. The efficacy and utility of the proposed method rely on the construction of a set of problem-specific orthogonal basis functions, and the series expansion of non-separable field functions in terms of these functions. The ability to permit parallelization along with construction of closed-form formulae for the derivatives and definite integrals of the basis functions are further key features of our method. The feasibility of the method is demonstrated by obtaining numerical results for homogeneous boundary conditions for 2D and 3D problems. Our results are compared against available numerical data obtained by conventional finite element method implementations. Excellent agreement has been achieved.
ISSN:2325-0631