Yiqiu Zhang , Shiqiu Wang , Qiqi Yang , Yonghong Qi , Minghui Zhao , Xueyong Wei
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引用次数: 0
摘要
本文介绍了具有灵敏度可调功能的硅微型机械谐振加速度计的设计和实验评估。通过将静电调谐模块集成到基本加速度计结构中,可以利用静电负稳态的软化效应来优化量程、噪声和带宽,从而实现动态灵敏度调节。值得注意的是,静电调谐模块与加速度计核心结构无缝集成,最大限度地减少了结构改动。通过对静电负稳态原理的理论分析和有限元模拟,我们设计出了一种新型的灵敏度可调式加速度计,只需相对较小的调节电压,就能提高加速度计的灵敏度并降低偏置不稳定性,同时不会增加结构的复杂性。通过开环、闭环和动态实验对加速度计的性能进行了评估,结果表明,当采用 9 V 灵敏度增强偏置电压时,在 ±1 g 的线性范围内,灵敏度从 843 Hz/g 提高到 2611 Hz/g。此外,偏压不稳定性也从 17.3 μg 降低到 6.8 μg。这种设计为微机电系统谐振加速度计的灵敏度调整提供了一条很有前景的途径。
A novel design of a MEMS resonant accelerometer with adjustable sensitivity
This paper presents the design and experimental evaluation of a silicon micro-machined resonant accelerometer featuring adjustable sensitivity. By integrating an electrostatic tuning module into the fundamental accelerometer structure, dynamic sensitivity adjustment becomes feasible, leveraging the softening effect of electrostatic negative stiffness to optimize range, noise, and bandwidth. Notably, the electrostatic tuning module integrates seamlessly with the core accelerometer structure, minimizing structural alterations. Through theoretical analysis and finite element simulation of the electrostatic negative stiffness principle, we have designed a novel accelerometer with adjustable sensitivity, which can enhance the sensitivity and reduces the bias-instability of the accelerometer with a relatively small adjustment voltage, without increasing structural complexity. The performance of the accelerometer was assessed through open-loop, closed-loop, and dynamic experiments, revealing that sensitivity increased from 843 Hz/g to 2611 Hz/g within a linear range of ±1 g when employing a sensitivity-enhancing bias voltage of 9 V. Moreover, the bias-instability is lowered down from 17.3 μg to 6.8 μg. This design offers a promising avenue for sensitivity tuning in MEMS resonant accelerometers.
期刊介绍:
ACS Applied Energy Materials is an interdisciplinary journal publishing original research covering all aspects of materials, engineering, chemistry, physics and biology relevant to energy conversion and storage. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important energy applications.
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