Litcius/Paper detail

Fault Detection for Nonlinear Dynamic Systems With Consideration of Modeling Errors: A Data-Driven Approach

Hongtian Chen, Linlin Li, Chao Shang, Biao Huang

2022IEEE Transactions on Cybernetics81 citationsDOI

Abstract

This article is concerned with data-driven realization of fault detection (FD) for nonlinear dynamic systems. In order to identify and parameterize nonlinear Hammerstein models using dynamic input and output data, a stacked neural network-aided canonical variate analysis (SNNCVA) method is proposed, based on which a data-driven residual generator is formed. Then, the threshold used for FD purposes is obtained via quantiles-based learning, where both estimation errors and approximation errors are considered. Compared with the existing work, the main novelties of this study include: 1) SNNCVA provides a new parameterization strategy for nonlinear Hammerstein systems by utilizing input and output data only; 2) the associated residual generator can ensure FD performance where both the system model and its nonlinearity are unknown; and 3) with consideration of modeling-induced errors, the quantiles are invoked and used to provide a reliable FD threshold in situations where only limited samples are available. Studies on a nonlinear hot rolling mill process demonstrate the effectiveness of the proposed method.

Topics & Concepts

Nonlinear systemFault detection and isolationResidualControl theory (sociology)Generator (circuit theory)Computer scienceProcess (computing)Realization (probability)Parametric statisticsFault (geology)Artificial neural networkControl engineeringQuantileSystem dynamicsAlgorithmEngineeringStochastic processMathematicsProcess controlEstimation theoryFault Detection and Control SystemsControl Systems and IdentificationMachine Fault Diagnosis Techniques
Fault Detection for Nonlinear Dynamic Systems With Consideration of Modeling Errors: A Data-Driven Approach | Litcius