Abstract
Bearings are nonlinear systems that can be used in several industrial applications. In this study, the combination of a strict-feedback backstepping digital twin and machine learning algorithm was developed for bearing crack type/size diagnosis. Acoustic emission sensors were used to collect normal and abnormal data for various crack sizes and motor speeds. The proposed method has three main steps. In the first step, the strict-feedback backstepping digital twin is designed for acoustic emission signal modeling and estimation. After that, the acoustic emission residual signal is generated. Finally, a support vector machine is recommended for crack type/size classification. The proposed digital twin is presented in two steps, (a) AE signal modeling and (b) AE signal estimation. The AE signal in normal conditions is modeled using an autoregressive technique, the Laguerre algorithm, a support vector regression technique and a Gaussian process regression procedure. To design the proposed digital twin, a strict-feedback backstepping observer, an integral term, a support vector regression and a fuzzy logic algorithm are suggested for AE signal estimation. The Ulsan Industrial Artificial Intelligence (UIAI) Lab’s bearing dataset was used to test the efficiency of the combined strict-feedback backstepping digital twin and machine learning technique for bearing crack type/size diagnosis. The average accuracies of the crack type diagnosis and crack size diagnosis of acoustic emission signals for the bearings used in the proposed algorithm were 97.13% and 96.9%, respectively.
Highlights
The Ulsan Industrial Artificial Intelligence (UIAI) Lab acoustic emission (AE) dataset was used to test the power of proposed digital twin (PDT) for crack diagnosis in the bearing
The first layer is for Acoustic Emission (AE) signal modeling in normal conditions using the proposed hybrid
Gaussian support vector autoregressive Laguerre technique, while the subsequent layer is used for AE signal estimation using the proposed hybrid fuzzy strict-feedback backstepping observer
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Apart from the applications of linear observers for fault diagnosis, these techniques suffer from reliability, robustness and nonlinear signal estimation issues [15]. Diverse algorithms have been recommended to accomplish the decision-making procedure, which are distributed into two principal groups, (a) classical techniques and (b) machine learning-based approaches. An intelligent signal identification algorithm for modeling, hybrid-based AE signal observation and the support vector machine (SVM). In the proposed algorithm (digital twin), first, the AE signal in normal condition is modelled using the combination of proposed linear regression, a nonlinear regressor and a Laguerre filter. Design of a strict-feedback backstepping digital twin using the proposed signal modeling, strict-feedback backstepping observer, integral term, support vector machine and fuzzy algorithm for normal and abnormal AE signal estimation.
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