Effect of size on the thermal noise and acoustic response of viscous-driven microbeams.

The Journal of the Acoustical Society of America Pub Date : 2024-04-01 DOI:10.1121/10.0025546

J. Lai, Mahdi Farahikia, Morteza Karimi, Zihan Liu, Yingchun Jiang, Changhong Ke, Ronald Miles

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Abstract

A study is presented of the thermal-mechanical noise and response to sound of microphones that are designed to be driven by the viscous forces in air rather than by sound pressure. Virtually all existing microphone designs are intended to respond to sound pressure. The structures examined here consist of thin, micro-scale, cantilever beams. The viscous forces that drive the beams are proportional to the relative velocity between the beams and fluid medium. The beams' movement in response to sound is similar to that of the air in a plane acoustic wave. The thermal-mechanical noise of these beams is found to be a very weak function of their width and length; the size of the sensing structure does not appear to significantly affect the performance. This differs from the well-known importance of the size of a pressure-sensing microphone in determining the pressure-referred noise floor. Creating microphones that sense fluid motion rather than pressure could enable a significant reduction in the size of the sensing element. Calculated results are revealed to be in excellent agreement with the measured pressure-referred thermal noise.

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尺寸对粘性驱动微梁的热噪声和声学响应的影响。

本文研究了传声器的热机械噪声和对声音的响应，传声器的设计是由空气中的粘性力而不是声压驱动的。几乎所有现有的传声器设计都旨在对声压做出响应。本文研究的结构由微型悬臂梁组成。驱动悬臂梁的粘性力与悬臂梁和流体介质之间的相对速度成正比。横梁对声音的响应运动类似于平面声波中的空气运动。研究发现，这些横梁的热机械噪声是其宽度和长度的一个非常微弱的函数；传感结构的大小似乎不会对其性能产生重大影响。这与众所周知的压力传感麦克风的尺寸对确定压力本底噪声的重要性不同。制造能够感知流体运动而非压力的传声器，可以大大减小传感元件的尺寸。结果表明，计算结果与测得的压力感应热噪声非常吻合。

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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The Journal of the Acoustical Society of America

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