Abstract
The fault diagnosis of slewing bearings is crucial for modern industry. However, operational constraints and high signal acquisition costs limit the number of available diagnostic samples, leading to decreased diagnostic accuracy. This study proposes a novel fault diagnosis method for slewing bearings based on audible sound signals, termed Time Generative Adversarial Network (Time GAN)–Tabular Prior-Data Fit Network (TabPFN). It is a hybrid approach that integrates the capabilities of Time GANs and the TabPFN. The method leverages the feature enhancement capabilities of Time GAN and the probabilistic modeling strengths of TabPFN to improve fault diagnosis accuracy. This method utilizes low-cost, easily obtainable audible sound signals as input. By employing Time GAN, the original data features are enhanced, generating new training samples. Subsequently, the TabPFN framework constructs a substantial amount of synthetic data with causal relationships, facilitating Bayesian inference. Experimental results demonstrate that the proposed method effectively identifies various fault types with small-sample sizes, achieving an accuracy of 96.5%, approximately 10% higher than existing algorithms. Furthermore, this method exhibits high diagnostic accuracy and strong generalization capabilities, making it a robust solution for slewing-bearing fault diagnosis.
References
1.
Li
, W.
, Zhang
, L.
, and Liang
, W.
, 2017
, “An Accident Causation Analysis and Taxonomy (ACAT) Model of Complex Industrial System From Both System Safety and Control Theory Perspectives
,” Saf. Sci.
, 92
, pp. 94
–103
. 2.
Guo
, C.
, Khan
, F.
, and Imtiaz
, S.
, 2018
, “Risk Assessment of Process System Considering Dependencies
,” J. Loss Prevent. Process Ind.
, 55
, pp. 204
–212
. 3.
Wang
, Y.
, Xiang
, J.
, Markert
, R.
, and Liang
, M.
, 2016
, “Spectral Kurtosis for Fault Detection, Diagnosis and Prognostics of Rotating Machines: A Review With Applications
,” Mech. Syst. Signal Process.
, 66–67
, pp. 679
–698
. 4.
Wang
, F.
, Liu
, C.
, Su
, W.
, Xue
, Z.
, Li
, H.
, and Han
, Q.
, 2017
, “Condition Monitoring and Fault Diagnosis Methods for Low-Speed and Heavy-Load Slewing Bearings: A Literature Review
,” J. Vibroeng.
, 19
(5
), pp. 3429
–3444
. 5.
Caesarendra
, W.
, Kosasih
, P. B.
, Tieu
, A. K.
, Moodie
, C. A. S.
, and Choi
, B.-K.
, 2013
, “Condition Monitoring of Naturally Damaged Slow Speed Slewing Bearing Based on Ensemble Empirical Mode Decomposition
,” J. Mech. Sci. Technol.
, 27
(8
), pp. 2253
–2262
. 6.
Caesarendra
, W.
, Kosasih
, B.
, Tieu
, A. K.
, and Moodie
, C. A. S.
, 2014
, “Circular Domain Features Based Condition Monitoring for Low Speed Slewing Bearing
,” Mech. Syst. Signal Process.
, 45
(1
), pp. 114
–138
. 7.
Žvokelj
, M.
, Zupan
, S.
, and Prebil
, I.
, 2016
, “EEMD-Based Multiscale ICA Method for Slewing Bearing Fault Detection and Diagnosis
,” J. Sound Vib.
, 370
, pp. 394
–423
. 8.
Mishra
, C.
, Samantaray
, A. K.
, and Chakraborty
, G.
, 2017
, “Rolling Element Bearing Fault Diagnosis Under Slow Speed Operation Using Wavelet de-Noising
,” Measurement
, 103
, pp. 77
–86
. 9.
Wang
, F.
, Liu
, C.
, Su
, W.
, Xue
, Z.
, Han
, Q.
, and Li
, H.
, 2018
, “Combined Failure Diagnosis of Slewing Bearings Based on MCKD-CEEMD-ApEn
,” Shock Vib.
, 2018
(1
), p. 6321785
. 10.
Xiong
, C.
, and Dai
, P.
, 2019
, “Fault Diagnosis of Caster Ladle Turret Based on Fuzzy Decision
,” 2019 14th International Conference on Computer Science & Education (ICCSE)
, Toronto, Ontario, Canada
, Aug. 19–21
, Vol. 27, pp. 948
–953
.11.
Wang
, Y.
, Yang
, Y.
, and He
, Z.
, 2022
, “Signal Processing Method for Condition Monitoring of Portal Crane
,” 2022 International Symposium on Sensing and Instrumentation in 5G and IoT Era (ISSI)
, Shanghai, China
, Nov. 17–18
, Vol. 45, pp. 191
–197
.12.
Liu
, Y.
, Jin
, Y.
, Cui
, G.
, and Shen
, G.
, 2023
, “Study and Application on the Early Damage Signal Characteristics of Ultra-Low-Speed and Heavy-Load Rolling Bearings of Large Amusement Machinery
,” Insight—Non-Destruct. Test. Cond. Monitor.
, 65
(5
), pp. 270
–277
. 13.
Pan
, Y.
, Wang
, H.
, Chen
, J.
, and Hong
, R.
, 2023
, “Fault Recognition of Large-Size Low-Speed Slewing Bearing Based on Improved Deep Belief Network
,” J. Vib. Control
, 29
(11–12
), pp. 2829
–2841
. 14.
Wang
, F.
, Tang
, T.
, Yin
, J.
, Li
, Y.
, and Ren
, F.
, 2018
, “A Signal Segmentation and Feature Fusion Based RUL Prediction Method for Railway Point System
,” 2018 21st International Conference on Intelligent Transportation Systems (ITSC)
, Maui, HI
, Nov. 4–7
, Vol. 99, pp. 2303
–2308
.15.
Sun
, Y.
, Cao
, Y.
, Xie
, G.
, and Wen
, T.
, 2020
, “Condition Monitoring for Railway Point Machines Based on Sound Analysis and Support Vector Machine
,” Chin. J. Electron.
, 29
(4
), pp. 786
–792
. 16.
Yuan
, C.
, Yuhan
, Z.
, and Yongkui
, S.
, 2021
, “Fault Diagnosis of Turnout Switch Machine Based
,” 2021 Third International Workshop on Structural Health Monitoring for Railway System (IWSHM-RS 2021)
, Qingdao, China
, Nov. 4–5
.17.
Kingma
, D. P.
, and Welling
, M.
, 2022
, “Auto-Encoding Variational Bayes,” arXiv:1312.6114.18.
Goodfellow
, I.
, Pouget-Abadie
, J.
, Mirza
, M.
, Xu
, B.
, Warde-Farley
, D.
, Ozair
, S.
, Courville
, A.
, and Bengio
, Y.
, 2014
, “Generative Adversarial Nets
,” Neural Information Processing Systems (NeurIPS)
, Montreal, Canada
, Dec. 8–13
.19.
Pan
, S. J.
, and Yang
, Q.
, 2010
, “A Survey on Transfer Learning
,” IEEE Trans. Knowl. Data Eng.
, 22
(10
), pp. 1345
–1359
. 20.
Chawla
, N. V.
, Bowyer
, K. W.
, Hall
, L. O.
, and Kegelmeyer
, W. P.
, 2002
, “SMOTE: Synthetic Minority Over-Sampling Technique
,” J. Artif. Intell. Res.
, 16
, pp. 321
–357
. 21.
Dai
, W.
, Yang
, Q.
, Xue
, G.-R.
, and Yu
, Y.
, 2007
, “Boosting for Transfer Learning
,” Proceedings of the 24th International Conference on Machine Learning. ICML ‘07 & ILP ‘07: The 24th Annual International Conference on Machine Learning Held in Conjunction with the 2007 International Conference on Inductive Logic Programming
, Corvallis, OR
, June 20–24
, pp. 193
–200
.22.
Zhang
, T.
, Chen
, J.
, Li
, F.
, Zhang
, K.
, Lv
, H.
, He
, S.
, and Xu
, E.
, 2021
, “Intelligent Fault Diagnosis of Machines With Small & Imbalanced Data: A State-of-the-Art Review and Possible Extensions
,” ISA Trans.
, 119
, pp. 157
–171
. 23.
Liang
, C.
, and P
, W.
, 2023
, “Development and Application of the Latest Generation Against the Network of GAN
,” J. Electron. Meas. Instrum.
, 34
(6
), pp. 70
–78
. 24.
Goodfellow
, I.
, Pouget-Abadie
, J.
, Mirza
, M.
, Xu
, B.
, Warde-Farley
, D.
, Ozair
, S.
, Courville
, A.
, and Bengio
, Y.
, 2020
, “Generative Adversarial Networks
,” Commun. ACM
, 63
(11
), pp. 139
–144
. 25.
Yoon
, J.
, Jarrett
, D.
, and van der Schaar
, M.
, 2019
, “Time-Series Generative Adversarial Networks
,” Neural Information Processing Systems (NeurIPS 2019)
, Vancouver, Canada
, Dec. 8–14
.26.
Hollmann
, N.
, Müller
, S.
, Eggensperger
, K.
, and Hutter
, F.
, 2023
, “TabPFN: A Transformer That Solves Small Tabular Classification Problems in a Second,” arXiv:2207.01848.27.
Müller
, S.
, Hollmann
, N.
, Arango
, S. P.
, Grabocka
, J.
, and Hutter
, F.
, 2024
, “Transformers Can Do Bayesian Inference,” arXiv:2112.10510.28.
Jefferys
, W. H.
, and Berger
, J. O.
, 1992
, “Ockham’s Razor and Bayesian Analysis
,” Am. Sci.
, 80
(1
), pp. 64
–72
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