基于量子计算的工业过程故障检测与诊断的深度学习方法

Akshay Ajagekar, F. You
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引用次数: 0

摘要

量子计算和深度学习方法有望开启一个新的计算时代,最近受到了极大的关注。本文提出了基于量子计算(QC)的深度学习故障诊断方法,该方法能够克服在经典计算机上执行的传统技术所面临的计算挑战。本文提出的基于qc的故障诊断模型解决了传统数据驱动技术的不足。采用量子计算辅助生成训练过程,然后进行有监督判别训练来训练该模型。将所提出的模型和方法应用于田纳西伊士曼(TE)过程监控,验证了其适用性。本文提出的基于qc的深度学习方法在TE过程中具有优异的性能,平均故障诊断率为80%,虚警率极低。
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A Deep Learning Approach for Fault Detection and Diagnosis of Industrial Processes using Quantum Computing
Quantum computing and deep learning methods hold great promise to open up a new era of computing and have been receiving significant attention recently. This paper presents quantum computing (QC) based deep learning methods for fault diagnosis that are capable of overcoming the computational challenges faced by conventional techniques performed on classical computers. The shortcomings of such classical data-driven techniques are addressed by the proposed QC-based fault diagnosis model. A quantum computing assisted generative training process followed by supervised discriminative training is used to train this model. The applicability of proposed model and methods is demonstrated by applying them to process monitoring of Tennessee Eastman (TE) process. The proposed QC-based deep learning approach enjoys superior performance with an average fault diagnosis rate of 80% and tremendously low false alarm rates for the TE process.
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