Improved Accuracy of On-Wafer Measurements Using the MMAVERIC Calibration Technique

34th ARFTG Conference Digest Pub Date : 1989-11-01 DOI:10.1109/ARFTG.1989.323958

H. Sequeira, M. Trippe

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引用次数: 1

Abstract

Besides calculating the usual coefficients of a 3-term (one-port) or 12-term (two-port) error model, the MMAVERIC technique provides 1) a corruption factor, 2) the phase and loss of the transmission line in which the calibration is performed, and 3) the reflection coefficient of one of the terminations used in the procedure. Each of these outputs is a valuable tool for analyzing and minimizing residual calibration errors. The corruption factor is a sensitive measure of the aggregate contributions of all departures from the ideal situation. For example, if one of the calibration standards is a short, we can determine how closely it approaches the ideal magnitude, |Γ|= 1, and phase, argΓ = 180/°. Our experimental evidence has shown that, at 40 GHz, |Γ| for a coplanar short directly contacted by the probe is about 0.7 dB smaller than that for a short seen through a length of coplanar line on the substrate. Thus, lower corruption and residual calibration errors are obtained if the reference plane is defined on the substrate at some distance away from the probe tips. We have corroborated the work of others(4) by modeling the short as a small reactance and shown how further improvements are achieved by separating the substrate from the wafer chuck by a low-dielectric spacer.

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使用MMAVERIC校准技术提高晶圆上测量的精度

除了计算3项(单端口)或12项(双端口)误差模型的通常系数外，MMAVERIC技术还提供1)损坏因子，2)执行校准的传输线的相位和损耗，以及3)过程中使用的其中一个终端的反射系数。这些输出中的每一个都是分析和最小化剩余校准误差的宝贵工具。腐败因素是衡量所有偏离理想情况的总贡献的一个敏感指标。例如，如果其中一个校准标准是短的，我们可以确定它与理想星等的接近程度，|Γ|= 1，相位argΓ = 180/°。我们的实验证据表明，在40 GHz时，探头直接接触的共面短线的|Γ|比通过衬底上的一段共面线看到的短线的|小0.7 dB左右。因此，如果参考平面定义在基板上，在远离探针尖端的一段距离上，则可以获得较低的损坏和残余校准误差。我们已经证实了其他人(4)的工作，通过将短路建模为一个小电抗，并展示了如何通过低介电间隔将衬底与晶圆夹头分离来实现进一步的改进。

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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34th ARFTG Conference Digest

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