Novel imbalanced fault diagnosis method based on generative adversarial networks with balancing serial CNN and Transformer (BCTGAN)

• Published in: Expert systems with applications Vol. 258; p. 125171
• Main Authors: Chen, Hualin, Wei, Jianan, Huang, Haisong, Wen, Long, Yuan, Yage, Wu, Jinxing
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 15.12.2024
• Subjects: CNN-Transformer architecture; Fault diagnosis; Generative adversarial networks; Imbalanced data; Small samples; Fault diagnosis; CNN-Transformer architecture; Imbalanced data; Generative adversarial networks; Small samples
• ISSN: 0957-4174
• DOI: 10.1016/j.eswa.2024.125171

In industrial production engineering, machines cannot sustain faults for extended periods, resulting in limited fault data collection. This scarcity of data impedes the advancement of accurate fault diagnosis models, particularly in the context of small-sample, extremely imbalanced fault modeling, which poses a significant and challenging problem. In this paper, we introduce an innovative data augmentation approach for addressing the small-sample imbalanced problem: the balanced conditioning CNN (Convolutional Neural Networks)-Transformer architecture based Generative Adversarial Network (BCTGAN). Firstly, we employ a serial CNN and Transformer architecture as the foundation of the generator. Secondly, we introduce micro-enhancement and SMOTE (Synthetic Minority Oversampling Technique) enhancement of samples to facilitate model training. Micro-enhancement simply augments the sample size, while SMOTE enhancement enhances diversity. Together, these techniques balance the training process by introducing new loss function terms. Finally, outlier samples are mitigated through a designed multi-domain feature screening method. Despite the added time cost and computational complexity, results from three instances demonstrate that the proposed method holds superior diagnostic results with great potential compared to traditional and general GAN-based fault diagnosis methods. Our work provides theoretical and practical insights for modeling the field of small-sample blended disequilibrium fault diagnosis.