基于支持向量回归和模糊学习机制的化学气相沉积质量预测系统

J. Su, Ching-Shun Chen
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引用次数: 0

摘要

在先进的半导体制造中,为了获得高稳定性和高良率,需要对制程晶圆进行定期监控。然而,实际的测量通常是在同一批次的所有工件都被加工后才得到的。生产设备的参数漂移或移位无法实时检测,增加了生产成本。为了克服这一问题,我们提出了一种基于支持向量回归和模糊学习机制的质量预测系统(QPS)。SVR为预测提供了良好的泛化性能,嵌入式FLM意味着在不断变化的环境中系统性能的持续改进或至少不退化。通过化学气相沉积(CVD)工艺在实际12英寸晶圆制造中的测试,验证了所提出的QPS的有效性。结果表明,所提出的QPS不仅可以实现对每片晶圆的实时质量测量,而且可以从制造过程的信息中检测出相应机器的性能退化。
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Chemical vapor deposition quality prediction system based on support vector regression and fuzzy learning mechanism
In advanced semiconductor manufacturing, the in-process wafers need to be monitored periodically in order to obtain high stability and high yield rate. However, the actual measurement is usually obtained after all the work-pieces of the same lot have been processed. The parameter drift or shift of the production equipment could not be detected in real-time thereby increasing the production cost. We proposed a quality prediction system (QPS) based on support vector regression (SVR) and fuzzy learning mechanism (FLM) to overcome this problem. The SVR provided good generalization performance for prediction, and the embedded FLM implied a continuous improvement or at least non-degradation of the system performance in an ever changing environment. The effectiveness of the proposed QPS was validated by test on chemical vapor deposition (CVD) process in practical 12-inch wafer fabrication. The results show that the proposed QPS not only fulfills real-time quality measurement of each wafer, but also detects the performance degradation of the corresponding machines from the information of manufacturing process.
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