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利用感官数据的无监督学习进行半导体制造的设备异常检测。

Equipment Anomaly Detection for Semiconductor Manufacturing by Exploiting Unsupervised Learning from Sensory Data.

机构信息

Department of Electrical Engineering, National Taiwan University, Taipei 10617, Taiwan, China.

Straight & Up Intelligent Innovations Group Co., San Jose, CA 95113, USA.

出版信息

Sensors (Basel). 2020 Oct 2;20(19):5650. doi: 10.3390/s20195650.

DOI:10.3390/s20195650
PMID:33023191
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7582566/
Abstract

In-line anomaly detection (AD) not only identifies the needs for semiconductor equipment maintenance but also indicates potential line yield problems. Prompt AD based on available equipment sensory data (ESD) facilitates proactive yield and operations management. However, ESD items are highly diversified and drastically scale up along with the increased use of sensors. Even veteran engineers lack knowledge about ESD items for automated AD. This paper presents a novel Spectral and Time Autoencoder Learning for Anomaly Detection (STALAD) framework. The design consists of four innovations: (1) identification of cycle series and spectral transformation (CSST) from ESD, (2) unsupervised learning from CSST of ESD by exploiting Stacked AutoEncoders, (3) hypothesis test for AD based on the difference between the learned normal data and the tested sample data, (4) dynamic procedure control enabling periodic and parallel learning and testing. Applications to ESD of an HDP-CVD tool demonstrate that STALAD learns normality without engineers' prior knowledge, is tolerant to some abnormal data in training input, performs correct AD, and is efficient and adaptive for fab applications. Complementary to the current practice of using control wafer monitoring for AD, STALAD may facilitate early detection of equipment anomaly and assessment of impacts to process quality.

摘要

在线异常检测 (AD) 不仅可以确定半导体设备维护的需求,还可以指出潜在的生产线产量问题。基于可用设备感应数据 (ESD) 的及时 AD 有助于主动进行产量和运营管理。然而,ESD 项目高度多样化,并且随着传感器使用的增加而大幅增加。即使是经验丰富的工程师,对于自动化 AD 的 ESD 项目也缺乏了解。本文提出了一种新颖的光谱和时间自动编码器学习异常检测 (STALAD) 框架。该设计包括四项创新:(1)从 ESD 中识别周期序列和光谱变换 (CSST),(2)通过利用堆叠自动编码器对 ESD 的 CSST 进行无监督学习,(3)基于正常数据和测试样本数据之间的差异进行 AD 的假设检验,(4)动态过程控制,实现周期性和并行学习和测试。在 HDP-CVD 工具的 ESD 中的应用表明,STALAD 可以在工程师没有先验知识的情况下学习正常情况,对训练输入中的一些异常数据具有容忍性,能够正确进行 AD,并且对于 fab 应用程序高效且具有适应性。作为当前使用控制晶片监测进行 AD 的补充,STALAD 可以促进对设备异常的早期检测以及对工艺质量影响的评估。

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