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一种带有光学隧道测量换能器的微型微机电光加速度计的设计、建模与实验研究。

The Design, Modeling and Experimental Investigation of a Micro-G Microoptoelectromechanical Accelerometer with an Optical Tunneling Measuring Transducer.

作者信息

Barbin Evgenii, Nesterenko Tamara, Koleda Aleksej, Shesterikov Evgeniy, Kulinich Ivan, Kokolov Andrey, Perin Anton

机构信息

Research Institute of Microelectronic Systems, The Tomsk State University of Control Systems and Radioelectronics, 634050 Tomsk, Russia.

Laboratory of Radiophotonics, V.E. Zuev Institute of Atmospheric Optics SB RAS, 634055 Tomsk, Russia.

出版信息

Sensors (Basel). 2024 Jan 24;24(3):765. doi: 10.3390/s24030765.

DOI:10.3390/s24030765
PMID:38339482
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10856817/
Abstract

This treatise studies a microoptoelectromechanical accelerometer (MOEMA) with an optical measuring transducer built according to the optical tunneling principle (evanescent coupling). The work discusses the design of the accelerometer's microelectromechanical sensing element (MSE) and states the requirements for the design to achieve a sensitivity threshold of 1 µg m/s at a calculated eigenvalue of the MSE. The studies cover the selection of the dimensions, mass, eigenfrequency and corresponding stiffness of the spring suspension, gravity-induced cross-displacements. The authors propose and experimentally test an optical transducer positioning system represented by a capacitive actuator. This approach allows avoiding the restrictions in the fabrication of the transducer conditioned by the extremely high aspect ratio of deep silicon etching (more than 100). The designed MOEMA is tested on three manufactured prototypes. The experiments show that the sensitivity threshold of the accelerometers is 2 µg. For the dynamic range from minus 0.01 g to plus 0.01 g, the average nonlinearity of the accelerometers' characteristics ranges from 0.7% to 1.62%. For the maximum dynamic range from minus 0.015 g to plus 0.05 g, the nonlinearity ranges from 2.34% to 2.9%, having the maximum deviation at the edges of the regions. The power gain of the three prototypes of accelerometers varies from 12.321 mW/g to 26.472 mW/g. The results provide broad prospects for the application of the proposed solutions in integrated inertial devices.

摘要

本论文研究了一种带有根据光学隧道原理(倏逝耦合)构建的光学测量换能器的微光机电加速度计(MOEMA)。该工作讨论了加速度计的微机电传感元件(MSE)的设计,并说明了在MSE的计算本征值下实现1µg m/s灵敏度阈值的设计要求。研究内容包括弹簧悬架的尺寸、质量、本征频率和相应刚度的选择,重力引起的横向位移。作者提出并通过实验测试了一种以电容式致动器为代表的光学换能器定位系统。这种方法可以避免由于深硅蚀刻的极高纵横比(超过100)而对换能器制造造成的限制。所设计的MOEMA在三个制造的原型上进行了测试。实验表明,加速度计的灵敏度阈值为2µg。对于从-0.01g到+0.01g的动态范围,加速度计特性的平均非线性范围为0.7%至1.62%。对于从-0.015g到+0.05g的最大动态范围,非线性范围为2.34%至2.9%,在区域边缘处偏差最大。三个加速度计原型的功率增益在12.321mW/g至26.472mW/g之间变化。研究结果为所提出的解决方案在集成惯性器件中的应用提供了广阔前景。

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