Spectral-coherence guided variational mode extraction and its application in rolling bearing fault diagnosis

Abstract

Abstract Variational mode extraction (VME), inspired by variational mode decomposition (VMD), is a novel fault diagnosis technique that can efficiently extract narrowband modes from multi-component signals. Compared with VMD, VME is more accurate and faster when extracting the narrowband component. However, the preset center frequency ω c and balance factor α seriously affect the performance of VME. Therefore, spectral-coherence guided VME (SCVME), capable of determining the hyper-parameters automatically, is proposed for fault diagnosis of rolling bearings. First, by considering the advantages of spectral coherence (SCoh) for characterizing the cyclostationarity of bearing faults, its energy spectrum is constructed. The energy spectrum of SCoh can intuitively reveal the fault information energy hidden in each frequency, which provides sufficient support for the determination of the center frequency ωc. Subsequently, a novel signal evaluation index named cyclic pulse intensity (CPI) is proposed to adaptively optimize the balance factor α. It is verified that the proposed CPI index is superior to common metrics, such as kurtosis, spectral kurtosis and l 2/l 1 norm, used for identifying periodic pulses. Finally, the modes containing fault information are accurately extracted by VME according to the optimal parameters (ωc , α). The effectiveness of the proposed method is demonstrated by simulations and experiments. In addition, comparisons with the VMD and Autogram methods are carried out to highlight the superiority of the SCVME method.