用于优化蚀刻工具操作的工业数据驱动型机器学习软传感技术

IF 3 Q2 ENGINEERING, CHEMICAL
Feiyang Ou , Henrik Wang , Chao Zhang , Matthew Tom , Sthitie Bom , James F. Davis , Panagiotis D. Christofides
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引用次数: 0

摘要

近几十年来,随着物联网(IoT)与信息技术(IT)的融合,智能制造(或称工业 4.0)获得了极大关注。随着现代生产方法的复杂性不断提高,人们更需要考虑哪些变量可以进行物理测量。这种进步要求使用物理传感器来全面、直接地收集工业流程的可测量数据;具体而言,这些传感器收集的数据可以重新组合为新的流程信息。例如,基于人工智能(AI)机器学习的软传感器可以提高操作生产力和机床性能,同时还能确保满足关键的产品规格要求。半导体行业是一个劳动密集型、耗时长、成本高的行业。人工智能机器学习方法可以通过接收操作数据并提取满足该行业高产品规格所需的特定流程信息来应对这些挑战。然而,一个关键的挑战是如何获得涵盖整个操作范围(包括日常差异)的高质量数据。本文研究了软传感方法对五台工业蚀刻机运行数据的适用性。数据是从安装在工具上的易于获取且经济高效的物理传感器中收集的,这些传感器负责管理和控制工具的运行条件。操作数据随后被用于一种智能数据聚合方法,该方法通过创建更大的训练数据集(由具有更大操作范围和流程变化的高价值数据组成)来增加软传感器的总体范围和鲁棒性。然后,可以针对特定机器对通用软传感器进行微调和验证。在本文中,我们测试了数据聚合对高性能前馈神经网络 (FNN) 模型的影响,这些模型以两种方式构建:第一种是作为分类器来估计产品的 PASS/FAIL 结果,第二种是作为回归器来定量估计氧化层厚度。针对 PASS/FAIL 分类,开发了一种数据聚合方法,以提高模型在更大训练数据集上的预测性能。此外,还引入了一种统计分析方法,通过点-阶梯相关性和平均绝对误差(MAE)差异得分来选择最佳的候选数据集进行聚合,从而进一步提高了数据聚合的有效性。对于具有高质量数据的大型数据集,可以进行更复杂任务的模型训练,还开发了预测产品氧化层厚度的回归模型。测试了具有不同损失函数的两类模型,以比较平均平方误差 (MSE) 和平均绝对百分比误差 (MAPE) 损失函数对模型性能的影响。分类和回归模型都可以应用于工业环境,因为它们提供了有关过程结果的额外信息。单独来看,这些模型可以减少半导体工厂的计量步骤,进一步开发后,还能增强先进过程控制策略的开发能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Industrial data-driven machine learning soft sensing for optimal operation of etching tools
Smart Manufacturing, or Industry 4.0, has gained significant attention in recent decades with the integration of Internet of Things (IoT) and Information Technologies (IT). As modern production methods continue to increase in complexity, there is a greater need to consider what variables can be physically measured. This advancement necessitates the use of physical sensors to comprehensively and directly gather measurable data on industrial processes; specifically, these sensors gather data that can be recontextualized into new process information. For example, artificial intelligence (AI) machine learning-based soft sensors can increase operational productivity and machine tool performance while still ensuring that critical product specifications are met. One industry that has a high volume of labor-intensive, time-consuming, and expensive processes is the semiconductor industry. AI machine learning methods can meet these challenges by taking in operational data and extracting process-specific information needed to meet the high product specifications of the industry. However, a key challenge is the availability of high quality data that covers the full operating range, including the day-to-day variance. This paper examines the applicability of soft sensing methods to the operational data of five industrial etching machines. Data is collected from readily accessible and cost-effective physical sensors installed on the tools that manage and control the operating conditions of the tool. The operational data are then used in an intelligent data aggregation approach that increases the scope and robustness for soft sensors in general by creating larger training datasets comprised of high value data with greater operational ranges and process variation. The generalized soft sensor can then be fine-tuned and validated for a particular machine. In this paper, we test the effects of data aggregation for high performing Feedforward Neural Network (FNN) models that are constructed in two ways: first as a classifier to estimate product PASS/FAIL outcomes and second as a regressor to quantitatively estimate oxide thickness. For PASS/FAIL classification, a data aggregation method is developed to enhance model predictive performance with larger training datasets. A statistical analysis method involving point-biserial correlation and the Mean Absolute Error (MAE) difference score is introduced to select the optimal candidate datasets for aggregation, further improving the effectiveness of data aggregation. For large datasets with high quality data that enable model training for more complex tasks, regression models that predict the oxide thickness of the product are also developed. Two types of models with different loss functions are tested to compare the effects of the Mean Squared Error (MSE) and Mean Absolute Percentage Error (MAPE) loss functions on model performance. Both the classification and regression models can be applied in industrial settings as they provide additional information regarding the process outcome. Individually, these models can reduce the number of metrology steps in semiconductor factories, and when developed further, can empower the development of advanced process control strategies.
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