Dynamic Maintenance in semiconductor manufacturing using Bayesian networks

2011 IEEE International Conference on Automation Science and Engineering Pub Date : 2011-10-13 DOI:10.1109/CASE.2011.6042404

D. Kurz, Johannes Kaspar, J. Pilz

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引用次数: 7

Abstract

In semiconductor manufacturing, in order to guarantee an optimal production flow it is necessary to perform a quick and correct equipment repair when an error message occurs. Since most equipment types are very complex, maintenance engineers are provided with manuals of troubleshooting flow charts. These manuals offer guidelines for finding the cause of the problem. Since such manuals are often static, clumsy and difficult to extend, it might be hard for maintenance engineers to efficiently perform cause-effect testing. For this reason, we employed a Bayesian network model that is developed from troubleshooting flow charts, which is able to overcome these deficiencies. The network is built as a self-learning diagnostic system. Troubleshooting sessions are used to train the network, so that the order of potential root causes is dynamically updated by actual maintenance experience. An Expectation Maximization (EM) algorithm is used to update the network. Furthermore, by ordering symptoms according to a mutual information criterion, it is possible to provide maintenance engineers with a ranking of the most informative and efficient tests to run.

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基于贝叶斯网络的半导体制造动态维护

在半导体制造中，为了保证最佳的生产流程，有必要在出现错误信息时执行快速和正确的设备维修。由于大多数设备类型非常复杂，维护人员通常会提供故障处理流程图的手册。这些手册提供了查找问题原因的指导方针。由于此类手册通常是静态的、笨拙的且难以扩展，因此维护工程师可能很难有效地执行因果测试。因此，我们采用了由故障排除流程图发展而来的贝叶斯网络模型，能够克服这些不足。该网络被构建为一个自学习诊断系统。故障排除会话用于训练网络，以便根据实际维护经验动态更新潜在根本原因的顺序。采用期望最大化(EM)算法对网络进行更新。此外，通过根据共同信息标准对症状进行排序，可以为维护工程师提供信息最丰富、最有效的测试排序。

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2011 IEEE International Conference on Automation Science and Engineering

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