基于深度学习的多元时间序列虚拟计量

2023 IEEE International Conference on Prognostics and Health Management (ICPHM) Pub Date : 2023-06-05 DOI:10.1109/ICPHM57936.2023.10194015

Siho Han, Jihwan Min, Jui Ma, Gyuil Hwang, Taeyeong Heo, Young Eun Kim, Sungjin Kang, Hyojun Kim, Sangjong Park, Kisuk Sung

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引用次数: 0

摘要

在预测和健康管理中，虚拟计量对先进的过程控制至关重要，它反映了制造机械的状况。传统上，虚拟计量已经使用统计和机器学习方法来解决，这需要广泛的领域知识和特征工程。此外，复杂工业系统的高维性质使得计量结果的解释越来越困难。在这项工作中，我们引入了PIE-VM，这是一个基于注意力的多元时间序列回归模型，包含了原子层蚀刻虚拟计量的过程信息。通过对PSK公司(一家位于韩国的大型半导体制造设备公司)收集和提供的真实数据进行实验，我们通过经验证明，我们的方法比基线方法更准确地预测蚀刻深度。此外，我们还表明，基于其固有的可解释性，我们的模型为高级过程控制提供了有用的信息。

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Deep Learning-Based Virtual Metrology in Multivariate Time Series

In Prognostics and Health Management, virtual metrology is crucial for advanced process control, accounting for the condition of manufacturing machinery. Traditionally, virtual metrology has been tackled using statistical and machine learning approaches, which require extensive domain knowledge and feature engineering. Moreover, the high-dimensional nature of complex industrial systems renders the interpretation of metrology results increasingly difficult. In this work, we introduce PIE-VM, an attention-based multivariate time series regression model incorporating process information for virtual metrology in atomic layer etching. Experimenting on real-world data collected and provided by PSK Inc., a large semiconductor manufacturing equipment company based in South Korea, we empirically demonstrate that our method predicts etch depths more accurately than baseline approaches. Also, we show that our model provides useful information for advanced process control based on its inherent interpretability.

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来源期刊

2023 IEEE International Conference on Prognostics and Health Management (ICPHM)

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