应用ADC技术表征短回路过程测试仪上e测试/检测数据叠加识别的产量限制缺陷

10th Annual IEEE/SEMI. Advanced Semiconductor Manufacturing Conference and Workshop. ASMC 99 Proceedings (Cat. No.99CH36295) Pub Date : 1999-09-08 DOI:10.1109/ASMC.1999.798258

T. Henry, O. Patterson, G. Brown

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引用次数: 3

摘要

结合CRS IMPACT/sup TM/ ADC和基于4300+ SEM ADC的方法，自动缺陷分类可以显著提高数据完整性和成品率限制缺陷表征率。ADC的实现可以提高良率学习率，因为它可以提高缺陷分类的速度和结果的准确性。数据表明，光学和SEM ADC方法都有其独特的优势。光学ADC提供了一种更快、更便宜、精度更低的解决方案。基于扫描电镜的方法获得了更高的分类精度，因为更高的放大倍率加上仅在倾斜图像中可用的附加z信息。最终的方法将包括结合光学和基于扫描电镜的方法，以利用每个系统的优势。

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Application of ADC techniques to characterize yield-limiting defects identified with the overlay of E-test/inspection data on short loop process testers

Automatic defect classification, using a combination of CRS IMPACT/sup TM/ ADC and 4300+ SEM ADC based approaches, can significantly improve data integrity and the rate of yield-limiting defect characterization. Implementation of ADC can enhance yield learning rates since it can improve the defect classification speed and improve the accuracy of the results. The data shows that both optical and SEM ADC approaches offer their own unique advantages. Optical ADC offers a faster significantly cheaper solution with less accuracy. Higher classification accuracy is obtained from the SEM based approach due to the higher magnifications coupled with the additional Z-information available only with tilted images. The ultimate approach would involve combination of the optical and SEM based approaches to take advantage of the strengths of each system.

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10th Annual IEEE/SEMI. Advanced Semiconductor Manufacturing Conference and Workshop. ASMC 99 Proceedings (Cat. No.99CH36295)

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