Efficient model for predictive mems microphone design: Model derivation and experimental verification

J. Oberndörfer; G. Schrag; G. Wachutkaa

doi:10.1016/j.proeng.2012.09.400

Efficient model for predictive mems microphone design: Model derivation and experimental verification

J. Oberndörfer
, G. Schrag
, G. Wachutkaa

Associate Professorship of Microsensors and Actuators

Technical University of Munich

Research output: Contribution to journal › Conference article › peer-review

1 Scopus citations

Abstract

We present a FEM-based, strongly problem-adapted model of a capacitive MEMS microphone that enables a fast and efficient simulation of basic device characteristics (reduction in simulation time from several hours to some minutes). Complex geometrical features (perforation holes, stack of thin material layers with large aspect ratios) as well as couplings between different energy domains have been taken into account by introducing effective or weighted material and stress parameters and easy-to-use semi-analytical, but yet physics-based simplifications. Thus, the model yields accurate results with reference to experimental data obtained from laser Doppler vibrometer measurements. Since the model is parameterized and scales with respect to the most relevant design and material parameters, it provides a proper basis for fast and efficient design and optimization studies.

Original language	English
Pages (from-to)	1327-1330
Number of pages	4
Journal	Procedia Engineering
Volume	47
DOIs	https://doi.org/10.1016/j.proeng.2012.09.400
State	Published - 2012
Event	26th European Conference on Solid-State Transducers, EUROSENSOR 2012 - Krakow, Poland Duration: 9 Sep 2012 → 12 Sep 2012

Keywords

Capacitive mems microphone
Experimental verification
Modeling

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10.1016/j.proeng.2012.09.400

Cite this

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title = "Efficient model for predictive mems microphone design: Model derivation and experimental verification",

abstract = "We present a FEM-based, strongly problem-adapted model of a capacitive MEMS microphone that enables a fast and efficient simulation of basic device characteristics (reduction in simulation time from several hours to some minutes). Complex geometrical features (perforation holes, stack of thin material layers with large aspect ratios) as well as couplings between different energy domains have been taken into account by introducing effective or weighted material and stress parameters and easy-to-use semi-analytical, but yet physics-based simplifications. Thus, the model yields accurate results with reference to experimental data obtained from laser Doppler vibrometer measurements. Since the model is parameterized and scales with respect to the most relevant design and material parameters, it provides a proper basis for fast and efficient design and optimization studies.",

keywords = "Capacitive mems microphone, Experimental verification, Modeling",

author = "J. Obernd{\"o}rfer and G. Schrag and G. Wachutkaa",

year = "2012",

doi = "10.1016/j.proeng.2012.09.400",

language = "English",

volume = "47",

pages = "1327--1330",

journal = "Procedia Engineering",

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note = "26th European Conference on Solid-State Transducers, EUROSENSOR 2012 ; Conference date: 09-09-2012 Through 12-09-2012",

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TY - JOUR

T1 - Efficient model for predictive mems microphone design

T2 - 26th European Conference on Solid-State Transducers, EUROSENSOR 2012

AU - Oberndörfer, J.

AU - Schrag, G.

AU - Wachutkaa, G.

PY - 2012

Y1 - 2012

N2 - We present a FEM-based, strongly problem-adapted model of a capacitive MEMS microphone that enables a fast and efficient simulation of basic device characteristics (reduction in simulation time from several hours to some minutes). Complex geometrical features (perforation holes, stack of thin material layers with large aspect ratios) as well as couplings between different energy domains have been taken into account by introducing effective or weighted material and stress parameters and easy-to-use semi-analytical, but yet physics-based simplifications. Thus, the model yields accurate results with reference to experimental data obtained from laser Doppler vibrometer measurements. Since the model is parameterized and scales with respect to the most relevant design and material parameters, it provides a proper basis for fast and efficient design and optimization studies.

AB - We present a FEM-based, strongly problem-adapted model of a capacitive MEMS microphone that enables a fast and efficient simulation of basic device characteristics (reduction in simulation time from several hours to some minutes). Complex geometrical features (perforation holes, stack of thin material layers with large aspect ratios) as well as couplings between different energy domains have been taken into account by introducing effective or weighted material and stress parameters and easy-to-use semi-analytical, but yet physics-based simplifications. Thus, the model yields accurate results with reference to experimental data obtained from laser Doppler vibrometer measurements. Since the model is parameterized and scales with respect to the most relevant design and material parameters, it provides a proper basis for fast and efficient design and optimization studies.

KW - Capacitive mems microphone

KW - Experimental verification

KW - Modeling

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U2 - 10.1016/j.proeng.2012.09.400

DO - 10.1016/j.proeng.2012.09.400

M3 - Conference article

AN - SCOPUS:84891705379

SN - 1877-7058

VL - 47

SP - 1327

EP - 1330

JO - Procedia Engineering

JF - Procedia Engineering

Y2 - 9 September 2012 through 12 September 2012

ER -

Efficient model for predictive mems microphone design: Model derivation and experimental verification

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Keywords

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