Litcius/Paper detail

Deep Canonical Correlation Analysis Using Sparsity-Constrained Optimization for Nonlinear Process Monitoring

Xianchao Xiu, Zhonghua Miao, Ying Yang, Wanquan Liu

2021IEEE Transactions on Industrial Informatics39 citationsDOI

Abstract

This article proposes an efficient nonlinear process monitoring method (DCCA-SCO) by integrating canonical correlation analysis (CCA), deep autoencoder neural networks (DAENNs), and sparsity-constrained optimization (SCO). Specifically, DAENNs are first used to learn a nonlinear function automatically, which characterizes intrinsic features of the original process data. Then, the CCA is performed in that low-dimensional representation space to extract the most correlated variables. In addition, the SCO is imposed to reduce the redundancy of the hidden representation. Unlike other deep CCA methods, the DCCA-SCO provides a new nonlinear method that is able to learn a nonlinear mapping with a sparse prior. The validity of the proposed DCCA-SCO is extensively demonstrated on the benchmark Tennessee Eastman (TE) process and the diesel generator process. In particular, compared with the classical CCA, the fault detection rate is increased by 8.00% for the fault IDV(11) in the TE process.

Topics & Concepts

Canonical correlationAutoencoderNonlinear systemRedundancy (engineering)Fault detection and isolationComputer scienceArtificial intelligencePattern recognition (psychology)Representation (politics)Process (computing)Benchmark (surveying)Artificial neural networkAlgorithmOperating systemGeodesyQuantum mechanicsGeographyPhysicsActuatorPoliticsPolitical scienceLawFault Detection and Control SystemsMineral Processing and GrindingMachine Fault Diagnosis Techniques