Highly flexible membrane systems for micromachined microphones-modeling and simulation
2009 3rd International Conference on Signals, Circuits and Systems …, 2009•ieeexplore.ieee.org
This paper presents a mechanical modeling of membrane systems applicable to
micromachined microphones requiring a low stiffness constant. We have recently developed
a single-chip electrodynamic microphone in a CMOS MEMS technology. The microphone
consists of a suspended square membrane of 1.4 mm side, 3¿ m thick and 10¿ g, and two
concentric inductors. This suspended moving membrane is fixed to the substrate with 4
attachments arms. In order to achieve a desired flat frequency response characteristic …
micromachined microphones requiring a low stiffness constant. We have recently developed
a single-chip electrodynamic microphone in a CMOS MEMS technology. The microphone
consists of a suspended square membrane of 1.4 mm side, 3¿ m thick and 10¿ g, and two
concentric inductors. This suspended moving membrane is fixed to the substrate with 4
attachments arms. In order to achieve a desired flat frequency response characteristic …
This paper presents a mechanical modeling of membrane systems applicable to micromachined microphones requiring a low stiffness constant. We have recently developed a single-chip electrodynamic microphone in a CMOS MEMS technology. The microphone consists of a suspended square membrane of 1.4 mm side, 3 ¿m thick and 10 ¿g, and two concentric inductors. This suspended moving membrane is fixed to the substrate with 4 attachments arms. In order to achieve a desired flat frequency response characteristic, covering the entire acoustic band, several attachment designs are presented, studied and compared. These designs include crab-leg, meander, U-spring and serpentine forms. We have found that for comparable dimensions, the U-spring form presents the highest compliance and the meander type is the stiffest.
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