Analysis of MEMS devices under temperature stress test

2021 IEEE 8th International Workshop on Metrology for AeroSpace (MetroAeroSpace) Pub Date : 2021-06-23 DOI:10.1109/MetroAeroSpace51421.2021.9511744

D. Capriglione, M. Carratù, M. Catelani, L. Ciani, G. Patrizi, A. Pietrosanto, R. Singuaroli, P. Sommella

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引用次数: 3

Abstract

The current technological process has mainly interested in integrating MEMS devices in most technological devices to offer complete control and awareness about a particular process or system. Such devices, which in most cases include gyroscope, accelerometer, and magnetometer, are fully integrated on a single chip and have a cost not higher than few dollars. Recently they have been more employed in embedded systems devoted to the autonomous driving operation for terrestrial and aeronautical vehicles. Such devices are often deployed to the market with datasheet reporting their characteristic without highlighting their behavior under particular environmental conditions. Most MEMS devices are mounted in a very harsh environment, characterized by high-temperature excursion and vibration from different sources. The authors propose a temperature stress test for such devices and evaluate their behavior under static conditions. Experimental results will evidence the accelerometer and gyroscope MEMS sensors' dependence on the temperature in a range of −10°C to 50°C.

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MEMS器件温度应力测试分析

当前的技术进程主要是将MEMS器件集成到大多数技术器件中，以提供对特定过程或系统的完全控制和感知。这种设备在大多数情况下包括陀螺仪、加速度计和磁力计，它们完全集成在一个芯片上，成本不超过几美元。最近，它们被更多地用于嵌入式系统，用于地面和航空车辆的自动驾驶操作。这类设备在投放市场时，通常只提供数据表，报告其特性，而不突出其在特定环境条件下的行为。大多数MEMS器件都安装在非常恶劣的环境中，其特点是高温偏移和来自不同来源的振动。作者提出了这种装置的温度应力测试，并评估其在静态条件下的性能。实验结果将证明加速度计和陀螺仪MEMS传感器对−10°C至50°C范围内温度的依赖性。

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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来源期刊

2021 IEEE 8th International Workshop on Metrology for AeroSpace (MetroAeroSpace)

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