Theoretical and Experimental Study of z-axis Acceleration Detection of the Micro Thermal Convective Accelerometer

2019 IEEE SENSORS Pub Date : 2019-10-01 DOI:10.1109/SENSORS43011.2019.8956737

Xiaoyi Wang, W. Xu, Huahuang Luo, Xu Zhao, Yi-Kuen Lee

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Abstract

For the first time, we conduct theoretical and experimental analysis on the z-axis (out-of-plane direction) acceleration detection of the micro thermal convective accelerometer (MTCA). Instead of using the complex assembling method to make an out-of-plane detection structure, an indirect way to measure the z-axis acceleration is proposed. The mechanism is proposed with the evidence that the sum of the upstream and downstream detectors’ temperature keeps the same under in-plane acceleration, while their differential output keeps constant with the out-of-plane (z-axis) acceleration. By means of monitoring the variation of temperature of in-plane detectors under out-of-plane acceleration, the z-axis acceleration could be indirectly sensed. Theoretically, the coupling error on z-axis induced by x-axis is quite small (less than 1%). Through this method, it could be easy to convert a single-axis (X) MTCA to a two-axis (X-Z) MTCA, which is also promising to improve the two-axis (X-Y) MTCA to a tri-axis (X-Y-Z) accelerometer. In addition, an MTCA is fabricated based on a CMOS compatible fabrication method and demonstrate the proposed detection mechanism with high sensitivity for both x-axis (1211μV/g) and z-axis (402μV/g).

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微热对流加速度计z轴加速度检测的理论与实验研究

本文首次对微热对流加速度计(MTCA)的z轴(面外方向)加速度检测进行了理论和实验分析。提出了一种间接测量z轴加速度的方法，取代了用复杂的装配方法制作面外检测结构的方法。在平面内加速度下，上游和下游探测器的温度总和保持不变，而它们的差分输出在平面外(z轴)加速度下保持不变。通过监测面内探测器在面外加速度作用下的温度变化，可以间接感知z轴加速度。理论上，由x轴引起的z轴耦合误差很小(小于1%)。通过这种方法，可以很容易地将单轴(X) MTCA转换为两轴(X- z) MTCA，这也有望将两轴(X- y) MTCA改进为三轴(X- y - z)加速度计。此外，基于CMOS兼容的制造方法制备了MTCA，并验证了所提出的检测机制在x轴(1211μV/g)和z轴(402μV/g)上都具有较高的灵敏度。

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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2019 IEEE SENSORS

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