晶圆测试失败数的统计建模与分析

H. Melzner
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引用次数: 8

摘要

本文提出了一种基于试验失效数的良率分析技术,因为这些是可用的最全面和最基本的良率数据。显然,这需要对大量数据进行分析。利用强大的统计技术,如主成分分析(PCA)和多元线性回归(MLR),实现了有效的数据约简。提出了缺陷相关失效和参数失效建模的基本概念。结合实例,分析了试验失败次数的均值、方差和协方差。由于协方差发挥了重要作用,我们进一步使用PCA对其进行分析,找出主要的独立变异源。然后将MLR应用于划分总产量损失,从而仅通过几个相关模式就可以完整地表示实际产量数据。从而大大简化和加速了物理根源的识别,从而快速解决问题和提高成品率。
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Statistical modeling and analysis of wafer test fail counts
This paper presents a yield analysis technique based on test fail counts, as these are the most comprehensive and fundamental yield data available. Obviously, this requires the analysis of large volumes of data. Using powerful statistical techniques, such as Principal Component Analysis (PCA) and Multiple Linear Regression (MLR), efficient data reduction is achieved. A basic concept for the modeling of both defect related and parametric fails is presented. Based on a real life examples, means, variances, and covariances of test fail counts are analyzed. As covariance turns out to play a significant role, it is further analyzed using PCA to work out major independent sources of variation. MLR is then applied to partition total yield loss, resulting in the complete representation of actual yield data by just a few relevant patterns. Identification of physical root causes is consequently greatly simplified and accelerated, leading to fast problem solving and yield improvement.
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