故障可植入MEMS压力传感器的建模

J. Miguel, Y. Lechuga, Mar Martínez, S. Bracho
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引用次数: 2

摘要

植入式生物医学设备通常包括用于获取生理信号的mems型传感器,以及用于供电、信号调理和数据传输的CMOS电子器件。在他们的要求中,长时间的可靠性应该得到重视。因此,建模和真实故障注入对于改善其长期结果至关重要。这项工作的目标是开发MEMS电容压力传感器的故障模型,成为具有动脉阻塞检测能力的智能支架的一部分。对圆形和方形隔膜在无故障条件下的挠度曲线进行了解析建模。然而,解析模型在描述故障条件下膜片的行为是不准确的,这改变了传感器的几何形状或材料特性。在这些情况下,使用有限元分析工具是必要的,以建立一个现实的故障模型库,以及一个全面的MEMS测试方法。
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Modeling of faulty implantable MEMS pressure sensors
Implantable biomedical devices generally comprise MEMS-type sensors used to acquire physiological signals, as well as CMOS electronics to perform powering, signal conditioning and data transmission. Among their requirements, reliability over an extended period of time ought to be spotlighted. Thus, modeling and realistic fault injection is essential to improve their long-term results. This work targets the development of a fault model for MEMS capacitive pressure sensors, to be part of smart stents with arterial blockage detection capabilities. The deflection profile of circular and square-shaped diaphragms under fault-free conditions has been analytically modeled. However, analytical models are inaccurate to describe the behavior of diaphragms under faulty conditions, which alter the geometry or material properties of the sensor. In these cases, the use of FE analysis tools is necessary to build a realistic fault model library, together with a comprehensive MEMS testing approach.
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