Supervised process monitoring and fault diagnosis based on machine learning methods

• Published in: International journal of advanced manufacturing technology Vol. 102; no. 5-8; pp. 2321 - 2337
• Main Authors: Lahdhiri, Hajer, Said, Maroua, Abdellafou, Khaoula Ben, Taouali, Okba, Harkat, Mohamed Faouzi
• Format: Journal Article
• Language: English
• Published: London Springer London 01.06.2019; Springer Nature B.V
• Subjects: Air monitoring; Air quality; CAE) and Design; Computer-Aided Engineering (CAD; Engineering; Environmental monitoring; Fault detection; Fault diagnosis; Industrial and Production Engineering; Kernels; Machine learning; Mechanical Engineering; Media Management; Methods; Nonlinear systems; Original Article; Principal components analysis; Nonlinear process monitoring; Fault isolation; Air quality monitoring; Fault detection; Reduced rank KPCA; Tabu search algorithm
• ISSN: 0268-3768; 1433-3015
• DOI: 10.1007/s00170-019-03306-z

Data-driven techniques have been receiving considerable attention in the industrial process monitoring field due to their major advantages of easy implementation and less requirement for the prior knowledge and process mechanism. Principal component analysis (PCA) method is known as a popular method for monitoring and fault detection in industrial systems but as it is basically a linear method. However, most practical systems are nonlinear. To make the extension to nonlinear systems, kernel PCA (KPCA) method has been proposed for process modeling and monitoring. We present in this paper an online reduced rank optimized KPCA (RR-KPCA) technique for fault detection in order to extend the advantages of the KPCA models to online processes. Following the fault detection, the identification of the variables correlated to the fault occurred is of great importance. For this purpose, it is proposed to extend the approaches of localization by partial PCA and by elimination in the linear case to the nonlinear case, by exploiting the solution of reduction of the dimension of the kernel matrix in the feature space. The partial RR-KPCA and the elimination sensor identification (ESI-RRKPCA) are generated based on the static RR-KPCA and the online RR-KPCA methods. The idea of these approaches is to generate partial RR-KPCA models with reduced sets of variables. In other words, their goal is to generate indices of fault detection sensitive to certain faults and insensitive to others. The proposed fault isolation methods are applied for monitoring an air quality monitoring network (AIRLOR) data.