Aluminum nitride piezoelectric microphones as zero-power passive acoustic filters

Robert W. Reger, P. Clews, Gwendolyn M. Bryan, Casey Keane, M. Henry, B. Griffin
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引用次数: 13

Abstract

With the advent of the internet-of-things, sensors that are constantly alert yet consuming near-zero power are desired. Remote sensing applications where sensor replacement is costly or hazardous would also benefit. Piezoelectric micro-electro-mechanical systems (MEMS) convert mechanical or acoustic energy into electrical signals while consuming zero power. When coupled with low-power complementary metal-oxide-semiconductor (CMOS) circuits, a near-zero power sensing system is formed. This work describes piezoelectric MEMS microphones based on aluminum nitride (AlN). The microphones operate as passive acoustic filters by placing their resonant response within bandwidths of interest. Devices are demonstrated with operational frequencies from 430 Hz to greater than 10 kHz with quality factors as large as 3,000 and open-circuit voltages exceeding 600 mV/Pa.
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氮化铝压电麦克风作为零功率无源声滤波器
随着物联网的出现,传感器需要时刻保持警觉,但功耗接近于零。传感器更换成本高或有危险的遥感应用也将受益。压电微机电系统(MEMS)是一种将机械能或声能转换为电信号而不消耗任何功率的系统。当与低功耗互补金属氧化物半导体(CMOS)电路耦合时,形成近零功率传感系统。本文描述了基于氮化铝(AlN)的压电MEMS麦克风。麦克风通过将其谐振响应放置在感兴趣的带宽内,作为无源声滤波器工作。器件的工作频率从430 Hz到大于10 kHz,质量因数高达3000,开路电压超过600 mV/Pa。
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