Design, Fabrication and Characterization of a Biologically Inspired MEMS Directional Microphone

2018 IEEE SENSORS Pub Date : 2018-10-01 DOI:10.1109/ICSENS.2018.8630304

V. S. Nagaraja, K. J. Rudresha, S. Pinjare

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引用次数: 6

Abstract

A Directional Microphone is a special type of acoustic sensor which has the capability of sensing the direction of acoustic pressure. In this paper a capacitive sensing Directional MEMS Microphone is presented. The design of the Directional MEMS Microphone is inspired by the parasitoid Ormia Ochracea. The capacitive sensing is achieved by using comb drives on either side of the microphone membrane. The Directional Microphone has been fabricated using SOIMUMPs process. The characterized results have been verified analytically and simulated using COMSOL Multiphysics and Coventorware. The measured frequencies of Rocking and Bending modes were found to be around 3.4 kHz and 7.9 kHz respectively which matches with the simulated results. The base capacitance on either side of the interdigital fingers was found to be 1.5pF. The sensitivity of the microphone was estimated to 0.7pF/ Pa. The novelty of the design lies in the fact that the microphone structure has been modified by splitting the middleA beams and improving the sensitivity by the spring action, thereby increasing the sensitivity from 0.lpF/ Pa as reported earlier to 0.7pF/ Pa. The device has also been tested with the readout circuitry based on MS3110. A voltage sensitivity of 0.04mV/Pa was obtained.

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仿生MEMS定向麦克风的设计、制造与表征

定向传声器是一种特殊的声传感器，具有声压方向感知能力。本文提出了一种电容式感应定向MEMS传声器。定向MEMS麦克风的设计灵感来自于寄生虫Ormia Ochracea。电容感应是通过在传声器膜的两侧使用梳状驱动器来实现的。采用SOIMUMPs工艺制备了定向传声器。利用COMSOL Multiphysics和Coventorware对表征结果进行了分析和仿真验证。振动模态和弯曲模态的测量频率分别在3.4 kHz和7.9 kHz左右，与仿真结果吻合。发现手指间两侧的基极电容为1.5pF。麦克风的灵敏度估计为0.7pF/ Pa。该设计的新颖之处在于对传声器结构进行了修改，通过中间波束的分裂，并通过弹簧作用提高了灵敏度，从而使灵敏度从0提高。lpF/ Pa之前报道为0.7pF/ Pa。该器件还通过基于MS3110的读出电路进行了测试。电压灵敏度为0.04mV/Pa。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 IEEE SENSORS

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