Abstract
This study proposes an effective bearing fault diagnosis model based on an optimized approach for feature selection. The measured signal of the electric motor is processed by envelope analysis and Hilbert-Huang transform techniques to extract the potential features. An enhancement of the binary particle swarm optimization algorithm through population initialization strategy based on feature weights, new updating mechanism, and the screening and replacing process create a new and effective feature selection method that improves classification accuracy and reduces data size. The optimal feature subset is provided separately for artificial neural networks, and support vector machine classifier for the final recognition task. In multiple case studies, the proposed feature selection method is evaluated against the benchmark data sets and shows performance comparable to that of other peer competitors. The effectiveness of the proposed bearing fault diagnosis model is verified on different testbeds and achieves high accuracy and robustness under noise conditions. In addition, experimental results are compared with existing fault diagnostic models, showing the high possibility of the proposed bearing fault diagnosis model.
Highlights
Electrical machines still play an important role in the manufacturing industry
Through the analysis of the characteristics of binary particle swarm optimization (BPSO) and related works, this study proposes an improved version of BPSO with the desire to overcome the limitations and improve the efficiency of BPSO for feature selection in bearing fault diagnosis model, it is named enhanced BPSO (E-BPSO)
The feature selection methods are adopted on the bearing dataset including the proposed and three comparison algorithms (BPSO, GA, and binary state transition algorithm (BSTA))
Summary
How to make the electrical machine work stably, which can detect faults early to avoid serious damage is still a big challenge for researchers [1]. According to Electric Power Research Institute (EPRI) statistics, 41% of electric motor failures occur due to bearing damage which is one of the mechanical faults that account for the highest proportion of problems with electrical machines [2], [3]. A model capable of detecting and classifying bearing failures was investigated in this paper. There are two trends that have been in the common investigation in recent years. The first trend of the fault diagnostic model that has received a lot of attention from researchers was to use the deep learning network, because of its ability to
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