Threshold Pressure Sensing Using Parametric Resonance in Electrostatic MEMS

M. Hasan, Mark Pallay, Shahrzad Towfighian
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引用次数: 2

Abstract

This study illustrates the concept of threshold pressure sensing using the parametric resonance of an electrostatic levitation mechanism. The electrostatic levitation allows the oscillations in the opposite direction of the substrate, thereby not limited to small gaps. The pressure sensor detects the pressure drop below a threshold value by triggering the parametric resonance with significant peak to peak dynamic amplitude changes (~ 25 μm). This detection relies on the fact that the instability region expands when the pressure drop forces the amplitude jump up to the higher oscillation branch. This significant change in the resonator amplitude can be related to a large capacitance variation indicating the threshold pressure. A mathematical model of the resonator is presented to show the working principle of the sensor through frequency response. Our experimental results show that the threshold pressure the sensor detects, can be adjusted by the AC voltage it receives.
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基于参数共振的静电MEMS阈值压力传感
本研究说明了阈值压力传感的概念,利用静电悬浮机构的参数共振。静电悬浮允许在基材的相反方向上振荡,从而不限于小的间隙。压力传感器通过触发参数共振来检测压力降低于阈值,峰值到峰值的动态幅度变化显著(~ 25 μm)。这种检测依赖于这样一个事实,即当压降迫使振幅上升到更高的振荡分支时,不稳定区域会扩大。谐振腔振幅的显著变化可能与指示阈值压力的大电容变化有关。建立了谐振腔的数学模型,通过频率响应来说明传感器的工作原理。实验结果表明,传感器检测到的阈值压力可以通过接收到的交流电压进行调节。
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