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Abstract

To address the problem of the weak anti-noise capability of domain adaptation methods in transfer learning tasks for bearing fault diagnosis, this study proposes a domain adaptation-based bearing fault diagnosis method with strong anti-noise ability. In this method, a one-dimensional multi-scale efficient channel attention residual network (1D-MS-ECA-ResNet) is first designed. The 1D-MS-ECA-ResNet features a multi-scale structure and an efficient channel attention residual structure. The multi-scale structure employs large-kernel convolutions, which can cover a longer time window of the input signal, enabling smoother feature extraction of the input signal and reducing the interference of high-frequency noise. The channel attention residual structure can effectively screen out the bearing fault features from the features extracted by the multi-scale structure, further minimizing the impact of noise on the process of fault feature extraction. Subsequently, an improved discriminative joint probability maximum mean discrepancy (IDJP-MMD) mechanism is proposed. In the IDJP-MMD mechanism, to mitigate the interference of noise on domain adaptation, the discriminative joint probability maximum mean discrepancy (DJP-MMD) and the deep domain adaptation correlation alignment (CORAL) used for measuring second-order statistics are combined through a dynamic balance parameter to form a new distribution difference indicator. In addition, adversarial domain adaptation and IDJP-MMD are simultaneously applied to the adaptation process of features from the two domains, so as to achieve the alignment of features from the two domains from multiple perspectives. Finally, cross-condition transfer learning experiments are conducted using two different datasets under various noise backgrounds. The results indicate that, even in the presence of noise interference, the method proposed in this paper can effectively enable a good adaptation of features from the two domains, which holds potential value for practical engineering applications.

Keywords

Cross working conditions transfer learning domain adaptation 1D-MS-ECA-ResNet IDJP-MMD

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References

Che

Wang

, et al. (2020) Domain adaptive deep belief network for rolling bearing fault diagnosis. Computers & Industrial Engineering 143: 106427.

Cui

Dong

, et al. (2024) Triplet attention-enhanced residual tree-inspired decision network: A hierarchical fault diagnosis model for unbalanced bearing datasets. Advanced Engineering Informatics 59: 102322.

Ding

Qin

Wang

, et al. (2023a) An elastic expandable fault diagnosis method of three-phase motors using continual learning for class-added sample accumulations. IEEE Transactions on Industrial Electronics 71(7): 7896–7905.

Ding

Jia

Zhuang

, et al. (2023b) Deep imbalanced domain adaptation for transfer learning fault diagnosis of bearings under multiple working conditions. Reliability Engineering & System Safety 230: 108890.

Dong

Jiang

Jiao

, et al. (2025) Double attention-guided tree-inspired grade decision network: A method for bearing fault diagnosis of unbalanced samples under strong noise conditions. Advanced Engineering Informatics 64: 103004.

Feng

Zhang

(2024) A small sample rolling bearing fault diagnosis based on PSD-VME and DS evidence theory enhanced mRVM. Computers and Electrical Engineering 118: 109458.

Liu

Ping

, et al. (2024) TRA-ACGAN: A motor bearing fault diagnosis model based on an auxiliary classifier generative adversarial network and transformer network. ISA Transactions 149: 381–393.

Ganin

Ustinova

Ajakan

, et al. (2016) Domain-adversarial training of neural networks. Journal of Machine Learning Research 17(59): 1–35.

Ghorvei

Kavianpour

Beheshti

MTH

, et al. (2023) Spatial graph convolutional neural network via structured subdomain adaptation and domain adversarial learning for bearing fault diagnosis. Neurocomputing 517: 44–61.

10.

Zhang

Ren

, et al. (2016) Deep residual learning for image recognition. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, Las Vegas, NV, 27–30 June, pp. 770–778.

11.

Hou

Zhou

Tian

, et al. (2022) Acoustic feature enhancement in rolling bearing fault diagnosis using sparsity-oriented multipoint optimal minimum entropy deconvolution adjusted method. Applied Acoustics 201: 109105.

12.

Jiang

Qiu

Zheng

, et al. (2025) Recursive prototypical network with coordinate attention: A model for few-shot cross-condition bearing fault diagnosis. Applied Acoustics 231: 110442.

13.

Jiao

Lin

Zhao

, et al. (2020) Double-level adversarial domain adaptation network for intelligent fault diagnosis. Knowledge-based Systems 205: 106236.

14.

Lee

Kim

, et al. (2024) Domain adaptation with label-aligned sampling (DALAS) for cross-domain fault diagnosis of rotating machinery under class imbalance. Expert Systems with Applications 243: 122910.

15.

Gao

, et al. (2024) Fault transfer diagnosis of rolling bearings across different devices via multi-domain information fusion and multi-kernel maximum mean discrepancy. Applied Soft Computing 159: 111620.

16.

Sun

, et al. (2023) Multilayer Grad-CAM: An effective tool towards explainable deep neural networks for intelligent fault diagnosis. Journal of Manufacturing Systems 69: 20–30.

17.

Zhao

Sun

, et al. (2021) Domain adversarial graph convolutional network for fault diagnosis under variable working conditions. IEEE Transactions on Instrumentation and Measurement 70: 3515010.

18.

Liu

Yan

Liu

, et al. (2024) ISEANet: An interpretable subdomain enhanced adaptive network for unsupervised cross-domain fault diagnosis of rolling bearing. Advanced Engineering Informatics 62: 102610.

19.

Liu

Jiang

, et al. (2022) Data synthesis using deep feature enhanced generative adversarial networks for rolling bearing imbalanced fault diagnosis. Mechanical Systems and Signal Processing 163: 108139.

20.

Long

Wang

Ding

, et al. (2013) Transfer feature learning with joint distribution adaptation. In: Proceedings of the IEEE International Conference on Computer Vision, Sydney, NSW, Australia, 1–8 December, pp. 2200–2207.

21.

Qian

Qin

Luo

, et al. (2023) Deep discriminative transfer learning network for cross-machine fault diagnosis. Mechanical Systems and Signal Processing 186: 109884.

22.

Qiao

Chen

Lai

, et al. (2023a) Harmonic-Gaussian double-well potential stochastic resonance with its application to enhance weak fault characteristics of machinery. Nonlinear Dynamics 111(8): 7293–7307.

23.

Qiao

Liao

, et al. (2023b) Noise-boosted weak signal detection in fractional nonlinear systems enhanced by increasing potential-well width and its application to mechanical fault diagnosis. Chaos, Solitons & Fractals 175: 113960.

24.

Xiangyu

Ren

Yong

Qin

Bin

, et al. (2024) A core space gradient projection-based continual learning framework for remaining useful life prediction of machinery under variable operating conditions. Reliability Engineering & System Safety 252: 110428.

25.

Sun

Saenko

(2016) Deep coral: Correlation alignment for deep domain adaptation. In: Computer Vision—ECCV 2016 Workshops, Amsterdam, The Netherlands, 8–10 October, pp. 443–450.

26.

Szegedy

Liu

Jia

, et al. (2015) Going deeper with convolutions. In: Proceedings of the IEEE conference on computer vision and pattern recognition, Boston, MA, 7–12 June 2015, pp. 1–9.

27.

Tong

Zhang

, et al. (2018) Bearing fault diagnosis based on domain adaptation using transferable features under different working conditions. Shock and Vibration 2018(1): 6714520.

28.

Wang

Qiu

, et al. (2024a) A rolling bearing fault diagnosis technique based on recurrence quantification analysis and Bayesian optimization SVM. Applied Soft Computing 156: 111506.

29.

Wang

Zhou

Zhang

, et al. (2023a) Multiscale deep attention Q network: a new deep reinforcement learning method for imbalanced fault diagnosis in gearboxes. IEEE Transactions on Instrumentation and Measurement 73: 3503512.

30.

Wang

Shao

Yan

, et al. (2023b) C-ECAFormer: a new lightweight fault diagnosis framework towards heavy noise and small samples. Engineering Applications of Artificial Intelligence 126: 107031.

31.

Wang

Shao

Peng

, et al. (2024b) PSparseFormer: enhancing fault feature extraction based on parallel sparse self-attention and multiscale broadcast feed-forward block. IEEE Internet of Things Journal 11(13): 22982–22991.

32.

Wang

Zhu

, et al. (2020) ECA-Net: efficient channel attention for deep convolutional neural networks. In: Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition, Seattle, WA, 13–19 June 2020, pp. 11534–11542.

33.

Wang

Yan

, et al. (2024c) Joint Wasserstein distance matching under conditional probability distribution for cross-domain fault diagnosis of rotating machinery. Mechanical Systems and Signal Processing 210: 111121.

34.

Yan

Shao

Wang

, et al. (2024) Few-shot class-incremental learning for system-level fault diagnosis of wind turbine. IEEE/ASME Transactions on Mechatronics 145: 1–10.

35.

Yang

Qiao

Zhu

, et al. (2023) An intelligent fault diagnosis method enhanced by noise injection for machinery. IEEE Transactions on Instrumentation and Measurement 72: 1–11.

36.

Zhang

(2020) Discriminative joint probability maximum mean discrepancy (DJP-MMD) for domain adaptation. In: 2020 International Joint Conference on Neural Networks (IJCNN), Glasgow, 19–24 July 2020, pp. 1–8.

37.

Zhao

Jia

Shao

(2023) A novel conditional weighting transfer Wasserstein auto-encoder for rolling bearing fault diagnosis with multi-source domains. Knowledge-based Systems 262: 110203.

38.

Zhong

Lin

Gao

, et al. (2024) Fault diagnosis of rolling bearings under variable conditions based on unsupervised domain adaptation method. Mechanical Systems and Signal Processing 215: 111430.

39.

Zhu

Zhuang

Wang

, et al. (2020) Deep subdomain adaptation network for image classification. IEEE Transactions on Neural Networks and Learning Systems 32(4): 1713–1722.

A domain adaptation bearing fault diagnosis method with strong noise resistance

Abstract

Keywords

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