Hydrostatic Response of Piezoresistive Stress Sensors

Applications of Experimental Mechanics to Electronic Packaging Pub Date : 1997-11-16 DOI:10.1115/imece1997-1224

Y. Kang, A. Mian, J. Suhling, R. Jaeger, K. Liechti, S. Liu

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引用次数: 19

Abstract

The (111) surface of silicon offers unique advantages for fabrication of piezoresistive stress sensors. Resistive sensor elements fabricated on this particular surface respond to all six components comprising the state of stress. Hence, a multi-element rosette has the capability of measuring the complete stress state at a point in the material. To extract the stress state at points on the die from the resistance changes measured with the sensor rosettes, it is necessary to have accurately calibrated values of six piezoresistive coefficients. Four-point bending and wafer-level calibration methods can measure four out of six piezoresistive coefficients for both p- and n-type resistors. To measure the other two coefficients, a hydrostatic test method has been developed where a high capacity pressure vessel is used to apply triaxial load on a single die. During the test procedure, resistance changes of resistors on the die are monitored. The slopes of the adjusted resistance change versus pressure plots are then used to calculate the desired last two coefficients. A step-by-step hydrostatic test procedure is demonstrated and sample data are presented.

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压阻式应力传感器的流体静力响应

硅的(111)表面为压阻式应力传感器的制造提供了独特的优势。在这种特殊表面上制造的电阻传感器元件对构成应力状态的所有六个组件作出响应。因此，一个多单元玫瑰花有能力在材料的一点上测量完整的应力状态。为了从传感器花环测量的电阻变化中提取模具上各点的应力状态，有必要精确校准六个压阻系数的值。四点弯曲和晶圆级校准方法可以测量p型和n型电阻器的六个压阻系数中的四个。为了测量其他两个系数，已经开发了一种流体静力试验方法，其中使用高容量压力容器在单个模具上施加三轴载荷。在测试过程中，监测模具上电阻的电阻变化。调整后的阻力变化与压力图的斜率然后用于计算所需的最后两个系数。一步一步的流体静力测试程序演示和样品数据提出。

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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Applications of Experimental Mechanics to Electronic Packaging

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