Adaptive Class Center Generalization Network: A Sparse Domain-Regressive Framework for Bearing Fault Diagnosis Under Unknown Working Conditions
Wang Bin, Long Wen, Xinyu Li, Liang Gao
Abstract
Fault diagnosis is essential to ensure the bearing safety in the smart manufacturing. As the rotating bearings usually work under the variable working conditions, there may exist the differences between the data distributions of the training and test domains. Domain adaptation fault diagnosis (DAFD) has been adopted to handle with this domain shift phenomenon. But DAFD relies on the target domain heavily during its training process, while the target domain is always unavailable in real-world scenarios. To handle with this situation, this paper proposed a new adaptive class center generalization network (ACCGN). ACCGN is used to learn invariant feature representations of orientation signals from multiple source domains. First, ACCGN is used to learn the discriminative invariant fault feature from multi-source domains, and it combines the sparse domain regression framework and central loss to optimize the data features from inter- and intra-class simultaneously. Second, a new adaptive method is proposed to update the center in central loss and it can diminish the effect on the initialization center location. Third, a sparse domain regression framework is used to learn the inter-class invariant features. The proposed ACCGN has been tested on two famous bearing datasets, and the results have shown the effectiveness of the proposed ACCGN on the CWRU and JNU datasets.