Silicon Micro-mechanics For Solid State Sensors

Thirteenth IEEE/CHMT International Electronics Manufacturing Technology Symposium Pub Date : 1992-09-28 DOI:10.1109/IEMT.1992.639878

J. Haviland

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Abstract

Since even before the first successful demonstration of the transistor in 1947, evolving semiconductor processing technology has lent itself well toward use in sensing of various physical phenomena. The first record of silicon used as a sensor was in 1940, when Robert Oh1 of Bell Labs discovered the photoelectric effect in silicon. In 1953, Philco was already using chemical micromachining to shape semiconductors. This paper explores the history of the semiconductor developments which have led to today's state of the art monolithic silicon sensors with on-chip self test, self calibration, and signal conditioning. These devices are part of the continuing evolution of smart monolithic sensors which have been and will continue to be made possible and economical by the continuing development of silicon manufacturing technology. Sensor Backaround There are two classes of silicon sensors considered here. The first utilizes only the electrical properties of silicon, and is included here primarily for reference. The second class of sensors utilizes the mechanical, and sometimes the electrical properties, and is the real subject of the discussion. Within each of these classes, there are several different sensing techniques (piezoresistive, capacitive, etc.), as well as various stimuli (pressure, acceleration, etc.) that may be sensed with each sensing technique. Silicon Sensors Utilizina Electrical ProDerties This class of sensors utilizes the Hall effect for measuring magnetic fields, and the band gap of silicon for measuring heat and light. Although they often utilize special layouts or modified manufacturing processes to enhance the sensitivity to the desired stimulus, these sensors historically have relied upon integrated circuit processing without further machining or mechanical enhancements. As such, they are typically very economically produced, and can inherently combine the functions of circuit and sensor, making them inexpensive and elegant solutions for many sensing and control problems.

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用于固态传感器的硅微力学

甚至在1947年晶体管首次成功演示之前，不断发展的半导体处理技术就已经很好地应用于各种物理现象的感知。硅作为传感器的第一个记录是在1940年，当时贝尔实验室的Robert Oh1发现了硅的光电效应。1953年，飞科公司已经开始使用化学微加工来塑造半导体。本文探讨了半导体发展的历史，这导致了今天具有片上自检，自校准和信号调理的最先进的单片硅传感器。这些设备是智能单片传感器持续发展的一部分，硅制造技术的持续发展已经并将继续使其成为可能和经济。这里考虑了两类硅传感器。第一种方法只利用了硅的电学性质，这里主要是作为参考。第二类传感器利用机械特性，有时也利用电学特性，这是我们讨论的真正主题。在这些类别中，有几种不同的传感技术(压阻式，电容式等)，以及各种各样的刺激(压力，加速度等)，可以用每种传感技术来感应。硅传感器利用电学特性这类传感器利用霍尔效应来测量磁场，利用硅的带隙来测量热和光。虽然它们经常利用特殊的布局或改进的制造工艺来提高对所需刺激的灵敏度，但这些传感器历来依赖于集成电路处理，而没有进一步的加工或机械增强。因此，它们通常非常经济地生产，并且可以固有地结合电路和传感器的功能，使它们成为许多传感和控制问题的廉价和优雅的解决方案。

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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Thirteenth IEEE/CHMT International Electronics Manufacturing Technology Symposium

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