Imbalanced fault diagnosis of rolling bearing using improved MsR-GAN and feature enhancement-driven CapsNet

Traditional fault diagnosis approaches of rolling bearing often need abundant labeled data in advance while some certain fault data are difficult to be acquired in engineering scenarios. This imbalanced fault data problem limits the diagnostic performance. To solve it, an imbalanced fault diagnosis approach based on improved multi-scale residual generative adversarial network (GAN) and feature enhancement-driven capsule network is proposed in this paper. Firstly, frequency slicing wavelet transform is utilized to extract two-dimensional time-frequency features from original vibration signals. By designing multi-scale residual network structure and hybrid loss function, original GAN model is improved, generating high-quality fake time-frequency features to balance fault data distribution. To increase the attention of the diagnostic model to faultsensitive features and suppress irrelevant features, a feature enhancement network is designed to dynamically weight the fault features by modeling the feature importance. On this basis, enhanced performance of imbalanced fault classification is achieved. Verification experiments demonstrate that it performs well in processing the imbalanced fault data, and has better stability and diagnostic accuracy than state-of-the-art methods.