Abstract
Fault diagnosis of rotating machinery is vital to identify incipient failures and avoid unexpected downtime in industrial systems. This paper proposes a new rolling bearing fault diagnosis method by integrating the fine-to-coarse multiscale permutation entropy (F2CMPE), Laplacian score (LS) and support vector machine (SVM). A novel entropy measure, named F2CMPE, was proposed by calculating permutation entropy via multiple-scale fine-grained and coarse-grained signals based on the wavelet packet decomposition. The entropy measure estimates the complexity of time series from both low- and high-frequency components. Moreover, the F2CMPE mitigates the drawback of producing time series with sharply reduced data length via the coarse-grained procedure in the conventional composite multiscale permutation entropy (CMPE). The comparative performance of the F2CMPE and CMPE is investigated by analyzing the synthetic and experimental signals for entropy-based feature extraction. In the proposed bearing fault diagnosis method, the F2CMPE is first used to extract the entropy-based features from bearing vibration signals. Then, LS and SVM are used for selection of features and fault classification, respectively. Finally, the effectiveness of the proposed method is verified for rolling bearing fault diagnosis using experimental vibration data sets, and the results have demonstrated the capability of the proposed method to recognize and identify the bearing fault patterns under different fault states and severity levels.
Highlights
In industrial manufacturing plants, rolling bearings are usually operated under harsh and complicated working environment for pursuing higher profits and are inevitably subjected to incipient defects, which can potentially lead to energy waste and performance degradation of the whole industrial system [1]–[3]
In this paper, a new rolling bearing fault diagnosis method is proposed based on the F2CMPE, Laplacian score (LS) and support vector machine (SVM)
A comparative performance study was carried out to investigate the F2CMPE and composite multiscale permutation entropy (CMPE) features for analyzing synthetic signals
Summary
In industrial manufacturing plants, rolling bearings are usually operated under harsh and complicated working environment for pursuing higher profits and are inevitably subjected to incipient defects, which can potentially lead to energy waste and performance degradation of the whole industrial system [1]–[3]. The performance of PE might be limited by analyzing time series with one single scale, which may neglect potential useful information associated with primary symptoms hidden in multiple scales For overcoming this shortcoming, Multiscale Permutation Entropy (MPE) was first proposed by Aziz and Arif [16], inspired by the concept of the coarse-grained procedure proposed in Multiscale Entropy (MSE) [17]. The original time series is divided into non-overlapping fragments by the coarse-grained procedure, the results of which may yield inappropriate PE measure in the MPE Concerning this limitation, Composite Multiscale Permutation Entropy (CMPE) was later proposed in [19] and [20] by integrating information of multiple coarse-grained time series in one same scale. The smaller the PE value is, the more regular the time series is
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
