Automated extraction of multi-energy domain reduced-order models demonstrated on capacitive MEMS microphones

W. Bedyk; M. Niessner; G. Schrag; G. Wachutka; B. Margesin; A. Faes

doi:10.1016/j.sna.2008.01.009

Automated extraction of multi-energy domain reduced-order models demonstrated on capacitive MEMS microphones

W. Bedyk, M. Niessner, G. Schrag, G. Wachutka, B. Margesin, A. Faes

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

6 Scopus citations

Abstract

We present a methodology to systematically extract efficient and physically-based reduced-order models based on a mixed-level simulation approach and demonstrate its practicality for the design of a capacitive MEMS microphone. The method has been implemented in a MATLAB toolbox. Starting from a FEM discretization, it enables the automated generation of mixed-level VHDL-AMS based macromodels, which can be straightforwardly fed into a standard circuit simulator. The whole model generation process is described in all details. The resulting macromodels are highly efficient and moreover, in contrast to other equivalent network approaches, physically-based. Therefore they allow for the predictive simulation of microstructures with complex geometry, as it is demonstrated by the numerical analysis of a capacitive microphone.

Original language	English
Pages (from-to)	263-270
Number of pages	8
Journal	Sensors and Actuators, A: Physical
Volume	145-146
Issue number	1-2
DOIs	https://doi.org/10.1016/j.sna.2008.01.009
State	Published - Jul 2008

Keywords

Capacitive microphone
Modal superposition
Reduced-order modeling
System-level modeling

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10.1016/j.sna.2008.01.009

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abstract = "We present a methodology to systematically extract efficient and physically-based reduced-order models based on a mixed-level simulation approach and demonstrate its practicality for the design of a capacitive MEMS microphone. The method has been implemented in a MATLAB toolbox. Starting from a FEM discretization, it enables the automated generation of mixed-level VHDL-AMS based macromodels, which can be straightforwardly fed into a standard circuit simulator. The whole model generation process is described in all details. The resulting macromodels are highly efficient and moreover, in contrast to other equivalent network approaches, physically-based. Therefore they allow for the predictive simulation of microstructures with complex geometry, as it is demonstrated by the numerical analysis of a capacitive microphone.",

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T1 - Automated extraction of multi-energy domain reduced-order models demonstrated on capacitive MEMS microphones

AU - Bedyk, W.

AU - Niessner, M.

AU - Schrag, G.

AU - Wachutka, G.

AU - Margesin, B.

AU - Faes, A.

PY - 2008/7

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N2 - We present a methodology to systematically extract efficient and physically-based reduced-order models based on a mixed-level simulation approach and demonstrate its practicality for the design of a capacitive MEMS microphone. The method has been implemented in a MATLAB toolbox. Starting from a FEM discretization, it enables the automated generation of mixed-level VHDL-AMS based macromodels, which can be straightforwardly fed into a standard circuit simulator. The whole model generation process is described in all details. The resulting macromodels are highly efficient and moreover, in contrast to other equivalent network approaches, physically-based. Therefore they allow for the predictive simulation of microstructures with complex geometry, as it is demonstrated by the numerical analysis of a capacitive microphone.

AB - We present a methodology to systematically extract efficient and physically-based reduced-order models based on a mixed-level simulation approach and demonstrate its practicality for the design of a capacitive MEMS microphone. The method has been implemented in a MATLAB toolbox. Starting from a FEM discretization, it enables the automated generation of mixed-level VHDL-AMS based macromodels, which can be straightforwardly fed into a standard circuit simulator. The whole model generation process is described in all details. The resulting macromodels are highly efficient and moreover, in contrast to other equivalent network approaches, physically-based. Therefore they allow for the predictive simulation of microstructures with complex geometry, as it is demonstrated by the numerical analysis of a capacitive microphone.

KW - Capacitive microphone

KW - Modal superposition

KW - Reduced-order modeling

KW - System-level modeling

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Automated extraction of multi-energy domain reduced-order models demonstrated on capacitive MEMS microphones

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Keywords

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