Reliability of MEMS devices under multiple environments

P. Lall, A. Abrol, Lee Simpson, J. Glover
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引用次数: 6

Abstract

Micro-electro-mechanical systems (MEMS) devices are used in a variety of applications for sensing acceleration, translation, rotation, pressure and sound in addition to actuation and signal generation. The MEMS devices have been applied to varied fields including healthcare and automotive applications. Data on reliability degradation of MEMS devices in harsh environment applications including combined environments of high temperature exposure, and high-g shock loading is scarce. In this paper, a test vehicle with a MEMS Accelerometers has been studied under high-temperature exposure followed by high-g mechanical shock. Test boards have been designed to assemble all the sensor types. The boards have been subjected to mechanical shocks using the method 2002.5, condition G, under the standard MIL-STD-883H test. Shock pulse amplitudes have been ramped from 500 to 30,000g with pulse duration between 0.1 to 1 millisecond. Full field effect on the components has been extracted using high speed cameras operating at 100,000 fps in conjunction with digital image correlation. The degradation of the MEMS response has been studied using statistical pattern recognition. The failure mechanisms have been characterized. The deterioration of the components has been extracted using non-destructive evaluation with micro-CT scans and X-ray. Further, the degradation of the MEMS response has been studied using statistical pattern recognition. The failure mechanisms have been characterized.
MEMS器件在多种环境下的可靠性
微机电系统(MEMS)设备用于各种应用中,除驱动和信号产生外,还用于感应加速度,平移,旋转,压力和声音。MEMS器件已应用于各种领域,包括医疗保健和汽车应用。关于MEMS器件在恶劣环境下可靠性退化的数据很少,包括高温暴露和高g冲击负载的组合环境。本文研究了一辆装有MEMS加速度计的测试车在高温暴露和高重力机械冲击下的性能。测试板的设计是为了装配所有类型的传感器。在MIL-STD-883H标准测试下,采用2002.5方法,条件G进行机械冲击。冲击脉冲振幅从500 g增加到30000 g,脉冲持续时间在0.1毫秒到1毫秒之间。使用高速相机以100,000 fps的速度结合数字图像相关提取组件的全场效果。利用统计模式识别研究了MEMS响应的退化。对失效机制进行了表征。使用micro-CT扫描和x射线进行无损评估,提取了部件的劣化。此外,利用统计模式识别研究了MEMS响应的退化。对失效机制进行了表征。
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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