Zhibin Zhao , Jingyao Wu , Tianfu Li , Chuang Sun , Ruqiang Yan , Xuefeng Chen . Challenges and Opportunities of AI-Enabled Monitoring, Diagnosis & Prognosis: A Review[J]. Chinese Journal of Mechanical Engineering, 2021 , 34(3) : 56 -56 . DOI: 10.1186/s10033-021-00570-7

[1] O Fink, Q Wang, M Svensen, et al. Potential, challenges and future directions for deep learning in prognostics and health management applications. Engineering Applications of Artificial Intelligence, 2020, 92: 103678.
[2] R Zhao, R Yan, Z Chen, et al. Deep learning and its applications to machine health monitoring. Mechanical Systems and Signal Processing, 2019, 115: 213-237.
[3] Z Zhao, S Wu, B Qiao, et al. Enhanced sparse period-group lasso for bearing fault diagnosis. IEEE Transactions on Industrial Electronics, 2018, 66(3): 2143-2153.
[4] Z Zhao, B Qiao, S Wang, et al. A weighted multi-scale dictionary learning model and its applications on bearing fault diagnosis. Journal of Sound and Vibration, 2019, 446: 429-452.
[5] S Wang, X Chen, C Tong, et al. Matching synchrosqueezing wavelet transform and application to aeroengine vibration monitoring. IEEE Transactions on Instrumentation and Measurement, 2016, 66(2): 360-372.
[6] G E Hinton, R R Salakhutdinov. Reducing the dimensionality of data with neural networks. science, 2006, 313(5786): 504-507.
[7] Y LeCun, Y Bengio, G Hinton. Deep learning. Nature, 2015, 521(7553): 436-444.
[8] M Hamadache, J H Jung, J Park, et al. A comprehensive review of artificial intelligence-based approaches for rolling element bearing PHM: shallow and deep learning. JMST Advances, 2019, 1(1): 125-151.
[9] J Lee, F Wu, W Zhao, et al. Prognostics and health management design for rotary machinery systems—Reviews, methodology and applications. Mechanical Systems and Signal Processing, 2014, 42(1-2): 314-334.
[10] A L Ellefsen, V Æsøy, S Ushakov, et al. A comprehensive survey of prognostics and health management based on deep learning for autonomous ships. IEEE Transactions on Reliability, 2019, 68(2): 720-740.
[11] R Liu, B Yang, E Zio, et al. Artificial intelligence for fault diagnosis of rotating machinery: A review. Mechanical Systems and Signal Processing, 2018, 108: 33-47.
[12] Y Lei, B Yang, X Jiang, et al. Applications of machine learning to machine fault diagnosis: A review and roadmap. Mechanical Systems and Signal Processing, 2020, 138: 106587.
[13] Y Lei, N Li, L Guo, et al. Machinery health prognostics: A systematic review from data acquisition to RUL prediction. Mechanical Systems and Signal Processing, 2018, 104: 799-834.
[14] Z Zhang, X Si, C Hu, et al. Degradation data analysis and remaining useful life estimation: A review on Wiener-process-based methods. European Journal of Operational Research, 2018, 271(3): 775-796.
[15] S Khan, T Yairi. A review on the application of deep learning in system health management. Mechanical Systems and Signal Processing, 2018, 107: 241-265.
[16] M Strozzi, R Rubini, M Cocconcelli. Condition monitoring techniques of ball bearings in non-stationary conditions. International Conference on Design, Simulation, Manufacturing: The Innovation Exchange, Springer, Cham, 2019: 565–576.
[17] A Mauricio, S Sheng, K Gryllias. Condition monitoring of wind turbine planetary gearboxes under different operating conditions. Journal of Engineering for Gas Turbines and Power, 2020, 142(3): GTP-19-1317.
[18] S Schmidt, P S Heyns. Normalisation of the amplitude modulation caused by time-varying operating conditions for condition monitoring. Measurement, 2020, 149: 106964.
[19] P S Ambika, P K Rajendrakumar, R Ramchand. Vibration signal based condition monitoring of mechanical equipment with scattering transform. Journal of Mechanical Science and Technology, 2019, 33(7): 3095-3103.
[20] M Zhao, J Jiao, J Lin. A data-driven monitoring scheme for rotating machinery via self-comparison approach. IEEE Transactions on Industrial Informatics, 2018, 15(4): 2435-2445.
[21] B W Harris, M W Milo, M J Roan. A general anomaly detection approach applied to rolling element bearings via reduced-dimensionality transition matrix analysis. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2016, 230(13): 2169-2180.
[22] X M Tao, W H Chen, B X Du, et al. A novel model of one-class bearing fault detection using SVDD and genetic algorithm. 2007 2nd IEEE Conference on Industrial Electronics and Applications. IEEE, 2007: 802–807.
[23] C Liu, K Gryllias. A semi-supervised Support Vector Data Description-based fault detection method for rolling element bearings based on cyclic spectral analysis. Mechanical Systems and Signal Processing, 2020, 140: 106682.
[24] P Zhao, M Kurihara, J Tanaka, et al. Advanced correlation-based anomaly detection method for predictive maintenance. 2017 IEEE International Conference on Prognostics and Health Management (ICPHM), IEEE, 2017: 78–83.
[25] J Tian, M H Azarian, M Pecht. Anomaly detection using self-organizing maps-based k-nearest neighbor algorithm. Proceedings of the European Conference of the Prognostics and Health Management Society, Citeseer, 2014: 1–9.
[26] D A Clifton, P R Bannister, L Tarassenko. Application of an intuitive novelty metric for jet engine condition monitoring. International Conference on Industrial, Engineering and Other Applications of Applied Intelligent Systems. Springer, Berlin, Heidelberg, 2006: 1149–1158.
[27] J A Cariño-Corrales, J J Saucedo-Dorantes, D Zurita-Millán, et al. Vibration-based adaptive novelty detection method for monitoring faults in a kinematic chain. Shock and Vibration, 2016, 2016: 2417856.
[28] Z Li, J Li, Y Wang, et al. A deep learning approach for anomaly detection based on SAE and LSTM in mechanical equipment. The International Journal of Advanced Manufacturing Technology, 2019, 103(1): 499-510.
[29] S Plakias, Y S Boutalis. Exploiting the generative adversarial framework for one-class multi-dimensional fault detection. Neurocomputing, 2019, 332: 396-405.
[30] D Li, D Chen, J Goh, et al. Anomaly detection with generative adversarial networks for multivariate time series. arXiv preprint, 2018, arXiv: 1809.04758.
[31] D Li, D Chen, B Jin, et al. MAD-GAN: Multivariate anomaly detection for time series data with generative adversarial networks. International Conference on Artificial Neural Networks, Springer, Cham, 2019: 703–716.
[32] W Jiang, Y Hong, B Zhou, et al. A GAN-based anomaly detection approach for imbalanced industrial time series. IEEE Access, 2019, 7: 143608-143619.
[33] L Martí, N Sanchez-Pi, J M Molina, et al. Anomaly detection based on sensor data in petroleum industry applications. Sensors, 2015, 15(2): 2774-2797.
[34] L Martí, N Sanchez-Pi, J M López, et al. On the combination of support vector machines and segmentation algorithms for anomaly detection: A petroleum industry comparative study. Journal of Applied Logic, 2017, 24: 71-84.
[35] J Inoue, Y Yamagata, Y Chen, et al. Anomaly detection for a water treatment system using unsupervised machine learning. 2017 IEEE International Conference on Data Mining Workshops (ICDMW), IEEE, 2017: 1058–1065.
[36] A Nanduri, L Sherry. Anomaly detection in aircraft data using Recurrent Neural Networks (RNN). 2016 Integrated Communications Navigation and Surveillance (ICNS), IEEE, 2016: 5C2-1-5C2-8.
[37] M Sakurada, T Yairi. Anomaly detection using autoencoders with nonlinear dimensionality reduction. Proceedings of the MLSDA 2014 2nd Workshop on Machine Learning for Sensory Data Analysis, 2014: 4–11.
[38] T H Dwiputranto, N A Setiawan, T B Aji. Machinery equipment early fault detection using Artificial Neural Network based Autoencoder. 2017 3rd International Conference on Science and Technology-Computer (ICST), IEEE, 2017: 66–69.
[39] C Y Lin, C P Weng, L C Wang, et al. Edge-based RNN anomaly detection platform in machine tools. Smart Science, 2019, 7(2): 139-146.
[40] F Pittino, M Puggl, T Moldaschl, et al. Automatic anomaly detection on in-production manufacturing machines using statistical learning methods. Sensors, 2020, 20(8): 2344.
[41] M Schlechtingen, I F Santos. Comparative analysis of neural network and regression based condition monitoring approaches for wind turbine fault detection. Mechanical Systems and Signal Processing, 2011, 25(5): 1849-1875.
[42] P Arpaia, U Cesaro, M Chadli, et al. Fault detection on fluid machinery using Hidden Markov Models. Measurement, 2020, 151: 107126.
[43] X Wang, G Lu, P Yan. Multiple regression analysis based approach for condition monitoring of industrial rotating machinery using multi-sensors. 2019 Prognostics and System Health Management Conference (PHM-Qingdao), IEEE, 2019: 1–5.
[44] T Wang, G Lu, P Yan. Multi-sensors based condition monitoring of rotary machines: An approach of multidimensional time-series analysis. Measurement, 2019, 134: 326-335.
[45] G R Garcia, G Michau, M Ducoffe, et al. Time series to images: Monitoring the condition of industrial assets with deep learning image processing algorithms. arXiv preprint, 2020, arXiv: 2005.07031.
[46] Y Zhang, P Hutchinson, N Lieven, et al. Adaptive event-triggered anomaly detection in compressed vibration data. Mechanical Systems and Signal Processing, 2019, 122: 480-501.
[47] H Luo, S Zhong. Gas turbine engine gas path anomaly detection using deep learning with Gaussian distribution. 2017 Prognostics and System Health Management Conference (PHM-Harbin), IEEE, 2017: 1–6.
[48] D Toshkova, M Asher, P Hutchinson, et al. Automatic alarm setup using extreme value theory. Mechanical Systems and Signal Processing, 2020, 139: 106417.
[49] G Lu, J Liu, P Yan. Graph-based structural change detection for rotating machinery monitoring. Mechanical Systems and Signal Processing, 2018, 99: 73-82.
[50] T Krogerus, M Hyvönen, P Multanen, et al. Joint probability distributions of correlation coefficients in the diagnostics of mobile work machines. Mechatronics, 2016, 35: 82-90.
[51] G Li, Y Hu, H Chen, et al. An improved fault detection method for incipient centrifugal chiller faults using the PCA-R-SVDD algorithm. Energy and Buildings, 2016, 116: 104-113.
[52] H Shi, L Guo, S Tan, et al. Rolling bearing initial fault detection using long short-term memory recurrent network. IEEE Access, 2019, 7: 171559-171569.
[53] J Wu, Z Zhao, C Sun, et al. Fault-attention generative probabilistic adversarial autoencoder for machine anomaly detection. IEEE Transactions on Industrial Informatics, 2020, 16(12): 7479-7488.
[54] N N Thi, N A Le-Khac. One-class collective anomaly detection based on LSTM-RNNs. Transactions on Large-Scale Data-and Knowledge-Centered Systems XXXVI. Springer, Berlin, Heidelberg, 2017: 73–85.
[55] T Ko, J H Lee, H Cho, et al. Machine learning-based anomaly detection via integration of manufacturing, inspection and after-sales service data. Industrial Management & Data Systems, 2017, 117(5): 927-945.
[56] S Ahmad, A Lavin, S Purdy, et al. Unsupervised real-time anomaly detection for streaming data. Neurocomputing, 2017, 262: 134-147.
[57] K Hendrickx, W Meert, Y Mollet, et al. A general anomaly detection framework for fleet-based condition monitoring of machines. Mechanical Systems and Signal Processing, 2020, 139: 106585.
[58] S B Kim, T Sukchotrat, S K Park. A nonparametric fault isolation approach through one-class classification algorithms. IIE Transactions, 2011, 43(7): 505-517.
[59] G Lu, Y Zhou, C Lu, et al. A novel framework of change-point detection for machine monitoring. Mechanical Systems and Signal Processing, 2017, 83: 533-548.
[60] D A Clifton, L Tarassenko. Novelty detection in jet engine vibration spectra. International Journal of Condition Monitoring, 2015, 5(2): 2-7.
[61] K Yan, Z Ji, W Shen. Online fault detection methods for chillers combining extended Kalman filter and recursive one-class SVM. Neurocomputing, 2017, 228: 205-212.
[62] S Martin-del-Campo, F Sandin. Online feature learning for condition monitoring of rotating machinery. Engineering Applications of Artificial Intelligence, 2017, 64: 187-196.
[63] W Yang, R Court, J Jiang. Wind turbine condition monitoring by the approach of SCADA data analysis. Renewable Energy, 2013, 53: 365-376.
[64] A Bzymek. Application of selected method of anomaly detection in signals acquired during welding process monitoring. International Journal of Materials and Product Technology, 2017, 54(4): 249-258.
[65] Case Western Reserve University (CWRU) Bearing Data Center, [online]. (Accessed on August 1, 2020). https://csegroups.case.edu/ Zhibin Zhao et al. Page 23 of 29 bearingdatacenter/pages/download-data-file/.
[66] Tennessee Eastman Process Datasets, [online]. (Accessed on August 1, 2020). https://ieee-dataport.org/documents/tennessee-eastman-simulation-dataset.
[67] SEU Gearbox Datasets, [online]. (Accessed on August 1, 2020). https://github.com/cathysiyu/Mechanical-datasets.
[68] IMS Bearing Datasets, [online]. (Accessed on August 1, 2020). https://ti.arc.nasa.gov/tech/dash/groups/pcoe/prognostic-data-repository.
[69] PHM IEEE 2012 Data Challenge, [online]. (Accessed on August 1, 2020). https://github.com/wkzs111/phm-ieee-2012-data-challenge-dataset.
[70] Airbus Helicopter Accelerometer Dataset, [online]. (Accessed on August 1, 2020. https://www.research-collection.ethz.ch/handle/20.500.11850/415151.
[71] Numenta Anomaly Benchmark, [online]. (Accessed on August 1, 2020). https://github.com/numenta/NAB.
[72] Secure Water Treatment Datasets, [online]. (Accessed on August 1, 2020). https://itrust.sutd.edu.sg/testbeds/secure-water-treatment-swat/.
[73] Fault-Attention Generative Probabilistic Adversarial Autoencoder, [online]. (Accessed on August 1, 2020). https://github.com/a1018680161/FGPAA.
[74] Numenta Platform for Intelligent Computing, [online]. (Accessed on August 1, 2020). https://github.com/numenta/nupic.
[75] GAN-AD, [online]. (Accessed on August 1, 2020). https://github.com/LiDan456/GAN-AD.
[76] J R Jiang, J E Lee, Y M Zeng. Time series multiple channel convolutional neural network with attention-based long short-term memory for predicting bearing remaining useful life. Sensors, 2020, 20(1): 166.
[77] S B Jiang, P K Wong, Y C Liang. A fault diagnostic method for induction motors based on feature incremental broad learning and singular value decomposition. IEEE Access, 2019, 7: 157796-157806.
[78] T Lobato, R da Silva, E da Costa, et al. An integrated approach to rotating machinery fault diagnosis using, EEMD, SVM, and augmented data. Journal of Vibration Engineering & Technologies, 2020, 8: 403-408.
[79] A K Panda, J S Rapur, R Tiwari. Prediction of flow blockages and impending cavitation in centrifugal pumps using Support Vector Machine (SVM) algorithms based on vibration measurements. Measurement, 2018, 130: 44-56.
[80] R Razavi-Far, E Hallaji, M Farajzadeh-Zanjani, et al. Information fusion and semi-supervised deep learning scheme for diagnosing gear faults in induction machine systems. IEEE Transactions on Industrial Electronics, 2018, 66(8): 6331-6342.
[81] Y Wang, Q Jin, G Sun, et al. Planetary gearbox fault feature learning using conditional variational neural networks under noise environment. Knowledge-Based Systems, 2019, 163: 438-449.
[82] Z Chen, A Mauricio, W Li, et al. A deep learning method for bearing fault diagnosis based on cyclic spectral coherence and convolutional neural networks. Mechanical Systems and Signal Processing, 2020, 140: 106683.
[83] L Kou, Y Qin, X Zhao. A multi-dimension end-to-end CNN model for rotating devices fault diagnosis on high-speed train bogie. IEEE Transactions on Vehicular Technology, 2019, 69(3): 2513-2524.
[84] Z He, H Shao, P Wang, et al. Deep transfer multi-wavelet auto-encoder for intelligent fault diagnosis of gearbox with few target training samples. Knowledge-Based Systems, 2020, 191: 105313.
[85] G Jiang, H He, J Yan, et al. Multiscale convolutional neural networks for fault diagnosis of wind turbine gearbox. IEEE Transactions on Industrial Electronics, 2018, 66(4): 3196-3207.
[86] C Lu, Z Y Wang, W L Qin, et al. Fault diagnosis of rotary machinery components using a stacked denoising autoencoder-based health state identification. Signal Processing, 2017, 130: 377-388.
[87] H Liu, L Li, J Ma. Rolling bearing fault diagnosis based on STFT-deep learning and sound signals. Shock and Vibration, 2016, 2016: 6127479.
[88] M Ma, C Sun, X Chen. Deep coupling autoencoder for fault diagnosis with multimodal sensory data. IEEE Transactions on Industrial Informatics, 2018, 14(3): 1137-1145.
[89] P Shi, X Guo, D Han, et al. A sparse auto-encoder method based on compressed sensing and wavelet packet energy entropy for rolling bearing intelligent fault diagnosis. Journal of Mechanical Science and Technology, 2020, 34: 1445-1458.
[90] D Han, N Zhao, P Shi. A new fault diagnosis method based on deep belief network and support vector machine with Teager-Kaiser energy operator for bearings. Advances in Mechanical Engineering, 2017, 9(12): 1687814017743113.
[91] H Jiang, H Shao, X Chen, et al. A feature fusion deep belief network method for intelligent fault diagnosis of rotating machinery. Journal of Intelligent & Fuzzy Systems, 2018, 34(6): 3513-3521.
[92] H Shao, H Jiang, X Li, et al. Rolling bearing fault detection using continuous deep belief network with locally linear embedding. Computers in Industry, 2018, 96: 27-39.
[93] X Wang, Y Qin, A Zhang. An intelligent fault diagnosis approach for planetary gearboxes based on deep belief networks and uniformed features. Journal of Intelligent & Fuzzy Systems, 2018, 34(6): 3619-3634.
[94] S Gao, L Xu, Y Zhang, et al. Rolling bearing fault diagnosis based on intelligent optimized self-adaptive deep belief network. Measurement Science and Technology, 2020, 31(5): 055009.
[95] C Zhang, Y Zhang, C Hu, et al. A novel intelligent fault diagnosis method based on variational mode decomposition and ensemble deep belief network. IEEE Access, 2020, 8: 36293-36312.
[96] J C Sumba, I R Quinde, L E Ochoa, et al. Intelligent fault diagnosis for rotating machines using deep learning. Smart and Sustainable Manufacturing Systems, 2019, 3(2): 27-40.
[97] L Eren, T Ince, S Kiranyaz. A generic intelligent bearing fault diagnosis system using compact adaptive 1D CNN classifier. Journal of Signal Processing Systems, 2019, 91(2): 179-189.
[98] A González-Muñiz, I Díaz, A A Cuadrado. DCNN for condition monitoring and fault detection in rotating machines and its contribution to the understanding of machine nature. Heliyon, 2020, 6(2): 03395.
[99] G Li, C Deng, J Wu, et al. Sensor data-driven bearing fault diagnosis based on deep convolutional neural networks and S-transform. Sensors, 2019, 19(12): 2750.
[100] Y Wang, S Huang, J Dai, et al. A novel bearing fault diagnosis methodology based on SVD and one-dimensional convolutional neural network. Shock and Vibration, 2020, 2020: 17.
[101] H Yin, Z Li, J Zuo, et al. Wasserstein generative adversarial network and convolutional neural network (WG-CNN) for bearing fault diagnosis. Mathematical Problems in Engineering, 2020: 1850286.
[102] C Zhang, J Feng, C Hu, et al. An intelligent fault diagnosis method of rolling bearing under variable working loads using 1-D stacked dilated convolutional neural network. IEEE Access, 2020, 8: 63027-63042.
[103] W Gong, H Chen, Z Zhang, et al. A novel deep learning method for intelligent fault diagnosis of rotating machinery based on improved CNN-SVM and multichannel data fusion. Sensors, 2019, 19(7): 1693.
[104] S Guo, B Zhang, T Yang, et al. Multitask convolutional neural network with information fusion for bearing fault diagnosis and localization. IEEE Transactions on Industrial Electronics, 2019, 67(9): 8005-8015.
[105] T Huang, S Fu, H Feng, et al. Bearing fault diagnosis based on shallow multi-scale convolutional neural network with attention. Energies, 2019, 12(20): 3937.
[106] A Y Khodja, N Guersi, M N Saadi, et al. Rolling element bearing fault diagnosis for rotating machinery using vibration spectrum imaging and convolutional neural networks. The International Journal of Advanced Manufacturing Technology, 2020, 106(5): 1737-1751.
[107] G Li, C Deng, J Wu, et al. Rolling bearing fault diagnosis based on wavelet packet transform and convolutional neural network. Applied Sciences, 2020, 10(3): 770.
[108] H Wang, J Xu, R Yan, et al. A new intelligent bearing fault diagnosis method using SDP representation and SE-CNN. IEEE Transactions on Instrumentation and Measurement, 2019, 69(5): 2377-2389.
[109] J Wang, Z Mo, H Zhang, et al. A deep learning method for bearing fault diagnosis based on time-frequency image. IEEE Access, 2019, 7: 42373-42383.
[110] Y Wang, J Yan, Q Sun, et al. Bearing intelligent fault diagnosis in the industrial Internet of Things context: A lightweight convolutional neural network. IEEE Access, 2020, 8: 87329-87340.
[111] G Xu, M Liu, Z Jiang, et al. Bearing fault diagnosis method based on deep convolutional neural network and random forest ensemble learning. Sensors, 2019, 19(5): 1088.
[112] J Zhang, S Yi, G Liang, et al. A new bearing fault diagnosis method based on modified convolutional neural networks. Chinese Journal of Aeronautics, 2020, 33(2): 439-447.
[113] M M Islam, J M Kim. Automated bearing fault diagnosis scheme using 2D representation of wavelet packet transform and deep convolutional neural network. Computers in Industry, 2019, 106: 142-153.
[114] A Kumar, Y Zhou, C Gandhi, et al. Bearing defect size assessment using wavelet transform based Deep Convolutional Neural Network (DCNN). Alexandria Engineering Journal, 2020, 59(2): 999-1012.
[115] P Liang, C Deng, J Wu, et al. Compound fault diagnosis of gearboxes via multi-label convolutional neural network and wavelet transform. Computers in Industry, 2019, 113: 103132.
[116] C Wu, P Jiang, C Ding, et al. Intelligent fault diagnosis of rotating machinery based on one-dimensional convolutional neural network. Computers in Industry, 2019, 108: 53-61.
[117] D Zhao, T Wang, F Chu. Deep convolutional neural network based planet bearing fault classification. Computers in Industry, 2019, 107: 59-66.
[118] T Li, Z Zhao, C Sun, et al. Multi-scale CNN for multi-sensor feature fusion in helical gear fault detection. Procedia Manufacturing, 2020, 49: 89-93.
[119] H Chen, N Hu, Z Cheng, et al. A deep convolutional neural network based fusion method of two-direction vibration signal data for health state identification of planetary gearboxes. Measurement, 2019, 146: 268-278.
[120] R Chen, X Huang, L Yang, et al. Intelligent fault diagnosis method of planetary gearboxes based on convolution neural network and discrete wavelet transform. Computers in Industry, 2019, 106: 48-59.
[121] Y Han, B Tang, L Deng. An enhanced convolutional neural network with enlarged receptive fields for fault diagnosis of planetary gearboxes. Computers in Industry, 2019, 107: 50-58.
[122] X Li, J Li, Y Qu, et al. Gear pitting fault diagnosis using integrated CNN and GRU network with both vibration and acoustic emission signals. Applied Sciences, 2019, 9(4): 768.
[123] G Qiu, Y Gu, Q Cai. A deep convolutional neural networks model for intelligent fault diagnosis of a gearbox under different operational conditions. Measurement, 2019, 145: 94-107.
[124] Y Xin, S Li, J Wang, et al. Intelligent fault diagnosis method for rotating machinery based on vibration signal analysis and hybrid multi-object deep CNN. IET Science, Measurement & Technology, 14(4): 407-415.
[125] W You, C Shen, D Wang, et al. An intelligent deep feature learning method with improved activation functions for machine fault diagnosis. IEEE Access, 2019, 8: 1975-1985.
[126] S Tang, S Yuan, Y Zhu. Convolutional neural network in intelligent fault diagnosis toward rotatory machinery. IEEE Access, 2020, 8: 86510-86519.
[127] T Ince. Real-time broken rotor bar fault detection and classification by shallow 1D convolutional neural networks. Electrical Engineering, 2019, 101(2): 599-608.
[128] I H Kao, W J Wang, Y H Lai, et al. Analysis of permanent magnet synchronous motor fault diagnosis based on learning. IEEE Transactions on Instrumentation and Measurement, 2018, 68(2): 310-324.
[129] Y M Hsueh, V R Ittangihal, W B Wu, et al. Fault diagnosis system for induction motors by CNN using empirical wavelet transform. Symmetry, 2019, 11(10): 1212
[130] J H Lee, J H Pack, I S Lee. Fault diagnosis of induction motor using convolutional neural network. Applied Sciences, 2019, 9(15): 2950.
[131] Y Yang, H Zheng, Y Li, et al. A fault diagnosis scheme for rotating machinery using hierarchical symbolic analysis and convolutional neural network. ISA transactions, 2019, 91: 235-252.
[132] R Liu, F Wang, B Yang, et al. Multiscale kernel based residual convolutional neural network for motor fault diagnosis under nonstationary conditions. IEEE Transactions on Industrial Informatics, 2019, 16(6): 3797-3806.
[133] L Wen, X Li, L Gao. A transfer convolutional neural network for fault diagnosis based on ResNet-50. Neural Computing and Applications, 2019, 32: 6111-6124.
[134] S Shao, R Yan, Y Lu, et al. DCNN-based multi-signal induction motor fault diagnosis. IEEE Transactions on Instrumentation and Measurement, 2019, 69(6): 2658-2669.
[135] S S Zhong, S Fu, L Lin. A novel gas turbine fault diagnosis method based on transfer learning with CNN. Measurement, 2019, 137: 435-453.
[136] Y Chang, J Chen, C Qu, et al. Intelligent fault diagnosis of wind turbines via a deep learning network using parallel convolution layers with multi-scale kernels. Renewable Energy, 2020, 153: 205-213.
[137] J Fu, J Chu, P Guo, et al. Condition monitoring of wind turbine gearbox bearing based on deep learning model. IEEE Access, 2019, 7: 57078-57087.
[138] W Liu, P Guo, L Ye. A low-delay lightweight recurrent neural network (LLRNN) for rotating machinery fault diagnosis. Sensors, 2019, 19(14): 3109.
[139] W J Lee, K Xia, N L Denton, et al. Development of a speed invariant deep learning model with application to condition monitoring of rotating machinery. Journal of Intelligent Manufacturing, 2020, 32: 393-406.
[140] M Rao, Q Li, D Wei, et al. A deep bi-directional long short-term memory model for automatic rotating speed extraction from raw vibration signals. Measurement, 2020, 158: 107719.
[141] S Haidong, C Junsheng, J Hongkai, et al. Enhanced deep gated recurrent unit and complex wavelet packet energy moment entropy for early fault prognosis of bearing. Knowledge-Based Systems, 2020, 188: 105022.
[142] W Zhang, D Yang, H Wang, et al. An attention-based temporal correlation approach for end-to-end machine health perception. IEEE Access, 2019, 7: 141487-141497.
[143] N V Chawla, K W Bowyer, L O Hall, et al. SMOTE: synthetic minority over-sampling technique. Journal of Artificial Intelligence Research, 2002, 16: 321-357.
[144] C Drummond, R C Holte. C4. 5, class imbalance, and cost sensitivity: why under-sampling beats over-sampling. Workshop on Learning from Imbalanced Datasets II, Aug. 21, 2003, Washington DC: Citeseer, 2003, 11: 1-8.
[145] R Razavi-Far, M Farajzadeh-Zanjani, M Saif. An integrated class-imbalanced learning scheme for diagnosing bearing defects in induction motors. IEEE Transactions on Industrial Informatics, 2017, 13(6): 2758-2769.
[146] Y Zhang, X Li, L Gao, et al. Imbalanced data fault diagnosis of rotating machinery using synthetic oversampling and feature learning. Journal of Manufacturing Systems, 2018, 48: 34-50.
[147] M Salvaris, D Dean, W H Tok. Generative adversarial networks. Deep Learning with Azure, Apress, Berkeley, CA, 2018: 187-208.
[148] S Shao, P Wang, R Yan. Generative adversarial networks for data augmentation in machine fault diagnosis. Computers in Industry, 2019, 106: 85-93.
[149] J Wu, Z Zhao, C Sun, et al. Ss-InfoGAN for class-imbalance classification of bearing faults. Procedia Manufacturing, 2020, 49: 99-104.
[150] W Mao, Y Liu, L Ding, Li, et al. Imbalanced fault diagnosis of rolling bearing based on generative adversarial network: A comparative study. IEEE Access, 2019, 7: 9515-9530.
[151] J. Luo, J Huang, H Li. A case study of conditional deep convolutional generative adversarial networks in machine fault diagnosis. Journal of Intelligent Manufacturing, 2020, 32: 407-425.
[152] W Zhang, X Li, X D Jia, et al. Machinery fault diagnosis with imbalanced data using deep generative adversarial networks. Measurement, 2020, 152: 107377
[153] J Wang, W Zhang, J Zhou. Fault detection with data imbalance conditions based on the improved bilayer convolutional neural network. Industrial & Engineering Chemistry Research, 2020, 59(13): 5891-5904.
[154] T Zheng, L Song, J Wang, et al. Data synthesis using dual discriminator conditional generative adversarial networks for imbalanced fault diagnosis of rolling bearings. Measurement, 2020, 158: 107741.
[155] Q Zhou, Y Li, Y Tian, et al. A novel method based on nonlinear auto-regression neural network and convolutional neural network for imbalanced fault diagnosis of rotating machinery. Measurement, 2020, 161: 107880.
[156] B Zhao, X Zhang, H Li, et al. Intelligent fault diagnosis of rolling bearings based on normalized CNN considering data imbalance and variable working conditions. Knowledge-Based Systems, 2020, 199: 105971.
[157] F Jia, Y Lei, N Lu, et al. Deep normalized convolutional neural network for imbalanced fault classification of machinery and its understanding via visualization. Mechanical Systems and Signal Processing, 2018, 110: 349-367.
[158] X Zhao, M Jia, M Lin. Deep Laplacian auto-encoder and its application into imbalanced fault diagnosis of rotating machinery. Measurement, 2020, 152: 107320.
[159] Y Lan, X Han, W Zong, et al. Two-step fault diagnosis framework for rolling element bearings with imbalanced data based on GSA-WELM and GSA-ELM. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2018, 232(16): 2937-2947.
[160] T Li, Z Zhao, C Sun, et al. Adaptive channel weighted CNN with multi-sensor fusion for condition monitoring of helicopter transmission system. IEEE Sensors Journal, 2020, 20(15): 8364-8373.
[161] X Dong, H Gao, L Guo, et al. Deep cost adaptive convolutional network: A classification method for imbalanced mechanical data. IEEE Access, 2020, 8: 71486-71496.
[162] D Peng, H Wang, Z Liu, et al. Multibranch and multiscale CNN for fault diagnosis of wheelset bearings under strong noise and variable load condition. IEEE Transactions on Industrial Informatics, 2020, 16(7): 4949-4960.
[163] H Qiao, T Wang, P Wang, et al. An adaptive weighted multiscale convolutional neural network for rotating machinery fault diagnosis under variable operating conditions. IEEE Access, 2019, 7: 118954-118964.
[164] Y Cheng, B Zhou, C Lu, et al. Fault diagnosis for rolling bearings under variable conditions based on visual cognition. Materials, 2017, 10(6): 582.
[165] S Guo, T Yang, W Gao, et al. An intelligent fault diagnosis method for bearings with variable rotating speed based on pythagorean spatial pyramid pooling CNN. Sensors, 2018, 18(11): 3857.
[166] Z Xiang, X Zhang, W Zhang, et al. Fault diagnosis of rolling bearing under fluctuating speed and variable load based on TCO Spectrum and Stacking Auto-encoder. Measurement, 2019, 138: 162-174.
[167] Z Zhao, Q Zhang, X Yu, et al. Unsupervised deep transfer learning for intelligent fault diagnosis: An open source and comparative study. arXiv preprint, 2019, arXiv: 1912.12528.
[168] M J Hasan, M M M Islam, J Kim. Acoustic spectral imaging and transfer learning for reliable bearing fault diagnosis under variable speed conditions. Measurement, 2019, 138: 620-631.
[169] Y Du, A Wang, S Wang, et al. Fault diagnosis under variable working conditions based on STFT and transfer deep residual network. Shock and Vibration. 2020, 2020: 1274380.
[170] Z He, H Shao, X Zhang, et al. Improved deep transfer auto-encoder for fault diagnosis of gearbox under variable working conditions with small training samples. IEEE Access, 2019, 7: 115368-115377.
[171] J Wu, Z Zhao, C Sun, et al. Few-shot transfer learning for intelligent fault diagnosis of machine. Measurement, 2020, 166: 108202.
[172] S Shao, S McAleer, R Yan, et al. Highly accurate machine fault diagnosis using deep transfer learning. IEEE Transactions on Industrial Informatics, 2018, 15(4): 2446-2455.
[173] W Zhang, G Peng, C Li, et al. A new deep learning model for fault diagnosis with good anti-noise and domain adaptation ability on raw vibration signals. Sensors, 2017, 17(2): 425.
[174] D Xiao, Y Huang, C Qin, et al. Transfer learning with convolutional neural networks for small sample size problem in machinery fault diagnosis. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2019, 233(14): 5131-5143.
[175] M Azamfar, J Singh, X Li, et al. Cross-domain gearbox diagnostics under variable working conditions with deep convolutional transfer learning. Journal of Vibration and Control, 2020, 27(7-8): 854-864.
[176] J Singh, M Azamfar, A Ainapure, et al. Deep learning-based cross-domain adaptation for gearbox fault diagnosis under variable speed conditions. Measurement Science and Technology, 2020, 31(5): 055601.
[177] C Che, H Wang, Q Fu, et al. Deep transfer learning for rolling bearing fault diagnosis under variable operating conditions. Advances in Mechanical Engineering, 2019, 11(12): 1-11.
[178] Z An, S Li, J Wang, et al. Generalization of deep neural network for bearing fault diagnosis under different working conditions using multiple kernel method. Neurocomputing, 2019, 352: 42-53.
[179] W Qian, S Li, P Yi, et al. A novel transfer learning method for robust fault diagnosis of rotating machines under variable working conditions. Measurement, 2019, 138: 514-525.
[180] X Li, W Zhang, Q Ding. A robust intelligent fault diagnosis method for rolling element bearings based on deep distance metric learning. Neurocomputing, 2018, 310: 77-95.
[181] Q Li, C Shen, L Chen, et al. Knowledge mapping-based adversarial domain adaptation: A novel fault diagnosis method with high generalizability under variable working conditions. Mechanical Systems and Signal Processing, 2021, 147: 107095.
[182] Y Ganin, E Ustinova, H Ajakan, et al. Domain-adversarial training of neural networks. The Journal of Machine Learning Research, 2016, 17(1): 2096-2030.
[183] T Li, Z Zhao, C Sun, et al. Domain adversarial graph convolutional network for fault diagnosis under variable working conditions. IEEE Transactions on Instrumentation and Measurement, 2021, 70: 3515010.
[184] W Lu, B Liang, Y Cheng, et al. Deep model based domain adaptation for fault diagnosis. IEEE Transactions on Industrial Electronics, 2016, 64(3): 2296-2305.
[185] T Han, C Liu, W Yang, et al. A novel adversarial learning framework in deep convolutional neural network for intelligent diagnosis of mechanical faults. Knowledge-Based Systems, 2019, 165: 474-487.
[186] K Xu, S Li, J Wang, et al. A novel convolutional transfer feature discrimination network for unbalanced fault diagnosis under variable rotational speeds. Measurement Science and Technology, 2019, 30(10): 105107.
[187] R Chen, S Chen, M He, et al. Rolling bearing fault severity identification using deep sparse auto-encoder network with noise added sample expansion. Proceedings of the Institution of Mechanical Engineers, Part O: Journal of Risk and Reliability, 2017, 231(6): 666-679.
[188] X Guo, C Shen, L Chen. Deep fault recognizer: An integrated model to denoise and extract features for fault diagnosis in rotating machinery. Applied Sciences, 2017, 7(1): 41.
[189] G Jiang, H He, P Xie, et al. Stacked multilevel-denoising autoencoders: A new representation learning approach for wind turbine gearbox fault diagnosis. IEEE Transactions on Instrumentation and Measurement, 2017, 66(9): 2391-2402.
[190] C Shen, Y Qi, J Wang, et al. An automatic and robust features learning method for rotating machinery fault diagnosis based on contractive autoencoder. Engineering Applications of Artificial Intelligence, 2018, 76: 170-184.
[191] Z Wang, J Wang, Y Wang. An intelligent diagnosis scheme based on generative adversarial learning deep neural networks and its application to planetary gearbox fault pattern recognition. Neurocomputing, 2018, 310: 213-222.
[192] X Liu, Q Zhou, J Zhao, et al. Fault diagnosis of rotating machinery under noisy environment conditions based on a 1-D convolutional autoencoder and 1-D convolutional neural network. Sensors, 2019, 19(4): 972.
[193] Y Qi, C Shen, J Zhu, et al. A new deep fusion network for automatic mechanical fault feature learning. IEEE Access, 2019, 7: 152552-152563.
[194] Y Zhang, X Li, L Gao, et al. Ensemble deep contractive auto-encoders for intelligent fault diagnosis of machines under noisy environment. Knowledge-Based Systems, 2020, 196: 105764.
[195] M Gan, C Wang. Construction of hierarchical diagnosis network based on deep learning and its application in the fault pattern recognition of rolling element bearings. Mechanical Systems and Signal Processing, 2016, 72: 92-104.
[196] H Shao, H Jiang, H Zhang, et al. Rolling bearing fault feature learning using improved convolutional deep belief network with compressed sensing. Mechanical Systems and Signal Processing, 2018, 100: 743-765.
[197] W You, C Shen, X Guo, et al. A hybrid technique based on convolutional neural network and support vector regression for intelligent diagnosis of rotating machinery. Advances in Mechanical Engineering, 2017, 9(6): 1-17.
[198] W Zhang, C Li, G Peng, et al. A deep convolutional neural network with new training methods for bearing fault diagnosis under noisy environment and different working load. Mechanical Systems and Signal Processing, 2018, 100: 439-453.
[199] D Peng, Z Liu, H Wang, et al. A novel deeper one-dimensional CNN with residual learning for fault diagnosis of wheelset bearings in high-speed trains. IEEE Access, 2018, 7: 10278-10293.
[200] P Peng, J Wang. NOSCNN: A robust method for fault diagnosis of RV reducer. Measurement, 2019, 138: 652-658.
[201] T Zan, H Wang, M Wang, et al. Application of multi-dimension input convolutional neural network in fault diagnosis of rolling bearings. Applied Sciences, 2019, 9(13): 2690.
[202] G Jin, T Zhu, M W Akram, et al. An adaptive anti-noise neural network for bearing fault diagnosis under noise and varying load conditions. IEEE Access, 2020, 8: 74793-74807.
[203] E Bechhoefer. Society for Machinery Failure Prevention Technology, [Online]. Available: https://mfpt.org/fault-data-sets/ (accessed on August 1, 2020).
[204] C Lessmeier, J K Kimotho, D Zimmer, et al. KAt-DataCenter, Chair of Design and Drive Technology, Paderborn University. https://mb.uni-paderborn.de/kat/forschung/datacenter/bearing-datacenter/ (accessed on August 1, 2020).
[205] K Li. School of Mechanical Engineering, Jiangnan University. http://mad-net.org:8765/explore.html?t=0.5831516555847212. (accessed on August 1, 2020).
[206] P Cao, S Zhang, J Tang. Gear fault data, [Online]. Available: https://doi.org/10.6084/m9.figshare.6127874.v1 (accessed on August 1, 2020).
[207] W Zhang, G Peng, C Li. Rolling element bearings fault intelligent diagnosis based on convolutional neural networks using raw sensing signal. Advances in Intelligent Information Hiding and Multimedia Signal Processing, Springer, Cham, 2017: 77-84.
[208] M Zhang, Z Jiang, K Feng. Research on variational mode decomposition in rolling bearings fault diagnosis of the multistage centrifugal pump. Mechanical Systems and Signal Processing, 2017, 93: 460-493.
[209] T Li, Z Zhao, C Sun, et al. WaveletKernelNet: An interpretable deep neural network for industrial intelligent diagnosis. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 2021. doi: https://doi.org/10.1109/TSMC.2020.3048950.
[210] T Li, Z Zhao, C Sun, et al. Multi-receptive field graph convolutional networks for machine fault diagnosis. IEEE Transactions on Industrial Electronics, 2020. doi: https://doi.org/10.1109/TIE.2020.3040669.
[211] Z Zhao, T Li, J Wu, et al. Deep learning algorithms for rotating machinery intelligent diagnosis: An open source benchmark study. ISA Transactions, 2020, 107: 224-255.
[212] L Wen, X Li, L Gao, et al. A new convolutional neural network-based data-driven fault diagnosis method. IEEE Transactions on Industrial Electronics, 2017, 65(7): 5990-5998.
[213] K Gregor, Y LeCun. Learning fast approximations of sparse coding. Proceedings of the 27th International Conference on International Conference on Machine Learning, 2010: 399-406.
[214] G W Bartram, S Mahadevan. Integrating heterogeneous information in diagnosis and prognosis. 54th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, 2013: 1941.
[215] P C C Berri, M D L Dalla Vedova, L Mainini. Real-time fault detection and prognostics for aircraft actuation systems. AIAA Scitech 2019 Forum, 2019: 2210.
[216] J B Ali, B Chebel-Morello, L Saidi, et al. Accurate bearing remaining useful life prediction based on Weibull distribution and artificial neural network. Mechanical Systems and Signal Processing, 2015, 56: 150-172.
[217] Q Tong, J Hu. Bearing performance degradation assessment based on information-theoretic metric learning and fuzzy C-means clustering. Measurement Science and Technology, 2020, 31(7): 075001.
[218] G Liu, J Zhao, H Li, et al. Bearing degradation assessment based on entropy with time parameter and fuzzy c-means clustering. Journal of Vibroengineering, 2019, 21(5): 1322-1329.
[219] J Zhou, C Zhang, L Zhang, et al. Rolling bearing performance degradation assessment based on AANN-FCM. Machine Design and Research, 2019, 35(1): 96-99. (in Chinese)
[220] J Zhou, Q Xu, L Zhang, et al. Rolling bearing performance degradation assessment based on the wavelet packet Tsallis entropy and FCM. Journal of Mechanical Transmission, 2016, 40(5): 110-113. (in Chinese)
[221] H Jiang, J Chen, G Dong, et al. An intelligent performance degradation assessment method for bearings. Journal of Vibration and Control, 2017, 23(18): 3023-3040.
[222] H Jiang, J Yuan, Q Zhao, et al. A robust performance degradation modeling approach based on Student's T-HMM and nuisance attribute projection. IEEE Access, 2020, 8: 49629-49644.
[223] Y Hu, S Liu, H Lu, et al. Remaining useful life model and assessment of mechanical products: a brief review and a note on the state space model method. Chinese Journal of Mechanical Engineering, 2019, 32(1): 1-20.
[224] H Wang, Y Zhou, J Qu, et al. A prognostic method of mechanical equipment based on HDP-HMM. Journal of Vibration and Shock, 2019, 38(8): 173-179. (in Chinese)
[225] L Li, T Ming, S Liu, et al. An effective health indicator based on two dimensional hidden Markov model. Journal of Mechanical Science and Technology, 2017, 31(4): 1543-1550.
[226] T Liu, X Wu, Y Guo, et al. Bearing performance degradation assessment by orthogonal local preserving projection and continuous hidden Markov model. Transactions of the Canadian Society for Mechanical Engineering, 2016, 40(5): 1019-1030.
[227] Y Pan, R Hong, J Chen, et al. Performance degradation assessment of a wind turbine gearbox based on multi-sensor data fusion. Mechanism and Machine Theory, 2019, 137: 509-526.
[228] Y Ma, J Chen, R Hong, et al. Performance degradation assessment of wind turbine generator gearbox based on multi-sensor information fusion. Computer Integrated Manufacturing Systems, 2019, 25(2): 318-325. (in Chinese)
[229] Y Feng, X Huang, R Hong, et al. : A multi-dimensional data-driven method for large-size slewing bearings performance degradation assessment. Journal of Central South University (Science and Technology), 2017, 48(03): 684-693. (in Chinese)
[230] F Wang, L Fang, Y Zhao, et al. Rolling bearing early weak fault detection and performance degradation assessment based on VMD and SVDD. Journal of Vibration and Shock, 2019, 38(22): 224-230+256. (in Chinese)
[231] J Zhou, H Guo, L Zhang, et al. Bearing performance degradation assessment using lifting wavelet packet symbolic entropy and SVDD. Shock and Vibration, 2016, 2016: 3086454.
[232] X Ding, L Wang, W Huang, et al. Feature clustering analysis using reference model towards rolling bearing performance degradation assessment. Shock and Vibration, 2020, 2020: 6306087.
[233] W Mao, L He, Y Yan, et al. Online sequential prediction of bearings imbalanced fault diagnosis by extreme learning machine. Mechanical Systems and Signal Processing, 2017, 83: 450-473.
[234] Y Lu, R Xie, S Y Liang. CEEMD-assisted bearing degradation assessment using tight clustering. The International Journal of Advanced Manufacturing Technology, 2019, 104(1): 1259-1267.
[235] L Zhang, C Song, C Wang, et al. Bearing performance degradation assessment based on a combination of multi-scale entropy and K-medoids clustering. 2019 Prognostics and System Health Management Conference (PHM-Qingdao), IEEE, 2019: 1-6.
[236] B Wang, X Hu, D Sun, et al. Bearing condition degradation assessment based on basic scale entropy and Gath-Geva fuzzy clustering. Advances in Mechanical Engineering, 2018, 10(10): 1-11.
[237] A Rai, S H Upadhyay. Bearing performance degradation assessment based on a combination of empirical mode decomposition and k-medoids clustering. Mechanical Systems and Signal Processing, 2017, 93: 16-29.
[238] J Zhou, C Zhang, F Wang. A method for performance degradation assessment of wind turbine bearings based on hidden Markov model and fuzzy C-means model. 2019 Prognostics and System Health Management Conference (PHM-Qingdao), IEEE, 2019: 1-5.
[239] P Tiwari, S H Upadhyay. Degradation assessment of ball bearings utilizing curvilinear component analysis. Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-Body Dynamics, 2019, 233(3): 714-730.
[240] A Rai, S H Upadhyay. Intelligent bearing performance degradation assessment and remaining useful life prediction based on self-organising map and support vector regression. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2018, 232(6): 1118-1132.
[241] K Zhu, X Jiang, L Chen, et al. Performance degradation assessment of rolling element bearings using improved fuzzy entropy. Measurement Science Review, 2017, 17(5): 219.
[242] Y Qin, D Wang, X Zhao, et al. Performance degradation assessment of train rolling bearings based on SVM and segmented vote method. 2016 Prognostics and System Health Management Conference (PHM-Chengdu), IEEE, 2016: 1-6.
[243] D Zhang, E Stewart, J Ye, et al. Roller bearing degradation assessment based on a deep MLP convolution neural network considering outlier regions. IEEE Transactions on Instrumentation and Measurement, 2019, 69(6): 2996-3004.
[244] S Dong, W Wu, K He, et al. Rolling bearing performance degradation assessment based on improved convolutional neural network with anti-interference. Measurement, 2020, 151: 107219.
[245] D Zhang, E Stewart, M Entezami, et al. Degradation assessment of bearings using deep convolutional inner-ensemble learning with outlier removal. 2019 Prognostics and System Health Management Conference (PHM-Paris), IEEE, 2019: 315-319.
[246] L Guo, Y Lei, N Li, et al. Deep convolution feature learning for health indicator construction of bearings. 2017 Prognostics and System Health Management Conference (PHM-Harbin), IEEE, 2017: 1-6.
[247] U Akpudo, J W Hur. A deep learning approach to prognostics of rolling element bearings. International Journal of Integrated Engineering, 2020, 12(3): 178-186.
[248] B Zhang, S Zhang, W Li. Bearing performance degradation assessment using long short-term memory recurrent network. Computers in Industry, 2019, 106: 14-29.
[249] Y Cheng, H Zhu, J Wu, et al. Machine health monitoring using adaptive kernel spectral clustering and deep long short-term memory recurrent neural networks. IEEE Transactions on Industrial Informatics, 2018, 15(2): 987-997.
[250] Z Wang, H Ma, H Chen, et al. Performance degradation assessment of rolling bearing based on convolutional neural network and deep long-short term memory network. International Journal of Production Research, 2020, 58(13): 3931-3943.
[251] F Xu, Z Fang, R Tang, et al. An unsupervised and enhanced deep belief network for bearing performance degradation assessment. Measurement, 2020, 162: 107902.
[252] Y Pan, R Hong, J Chen, et al. A hybrid dbn-som-pf-based prognostic approach of remaining useful life for wind turbine gearbox. Renewable Energy, 2020, 152: 138-154.
[253] W Tu, T Liu, H Liu. Application of bp and ar model in performance degradation assessment and prediction of bearings. Journal of Electronic Measurement and Instrument, 2019, 33(11): 79-88.
[254] J Gai, Y Hu, J Shen. A bearing performance degradation modeling method based on EMD-SVD and fuzzy neural network. Shock and Vibration, 2019, DOI: https://doi.org/https://doi.org/10.1155/2019/5738465.
[255] Z Li, Y Wang, K Wang. A deep learning driven method for fault classi_cation and degradation assessment in mechanical equipment. Computers in industry, 2019, 104: 1-10.
[256] K Aggarwal, O Atan, A Farahat, et al. Two birds with one network: Unifying failure event prediction and time-to-failure modeling. 2018 IEEE International Conference on Big Data (Big Data), IEEE, 2018: 1308-1317.
[257] C Byington, M Roemer, T Galie. Prognostic enhancements to diagnostic systems for improved condition-based maintenance [military aircraft]. Proceedings, IEEE Aerospace Conference, IEEE, 2002, 6: 6-6.
[258] A Muller, M Suhner, B Iung. Formalisation of a new prognosis model for supporting proactive maintenance implementation on industrial system. Reliability Engineering & System Safety, 2008, 93(2): 234-253.
[259] W Yu, I Kim, C Mechefske. Remaining useful life estimation using a bidirectional recurrent neural network based autoencoder scheme. Mechanical Systems and Signal Processing, 2019, 129: 764-780.
[260] C Che, H Wang, Q Fu, et al. Combining multiple deep learning algorithms for prognostic and health management of aircraft. Aerospace Science and Technology, 2019, 94: 105423.
[261] D Belmiloud, T Benkedjouh, M Lachi, et al. Deep convolutional neural networks for bearings failure predictionand temperature correlation. Journal of Vibroengineering, 2018, 20(8): 2878-2891.
[262] Y Li, H Li, B Wang, et al. Research on the feature selection of rolling bearings' degradation features. Shock and Vibration, 2019, 22: 6450719.
[263] D She, M Jia. Health indicator construction of rolling bearings based on deep convolutional neural network considering phase degradation. 2019 Prognostics and System Health Management Conference (PHM-Paris), IEEE, 2019: 373-378.
[264] Y Yoo, J Baek. A novel image feature for the remaining useful lifetime prediction of bearings based on continuous wavelet transform and convolutional neural network. Applied Sciences, 2018, 8(7): 1102.
[265] X Li, W Zhang, H Ma, et al. Data alignments in machinery remaining useful life prediction using deep adversarial neural networks. Knowledge-Based Systems, 2020, 197: 105843.
[266] J Zhu, N Chen, C Shen. A new data-driven transferable remaining useful life prediction approach for bearing under different working conditions. Mechanical Systems and Signal Processing, 2020, 139: 106602.
[267] A Elsheikh, S Yacout, M Ouali. Bidirectional handshaking LSTM for remaining useful life prediction. Neurocomputing, 2019, 323: 148-156.
[268] M Souto, M Moura, I Lins. Particle swarm-optimized support vector machines and pre-processing techniques for remaining useful life estimation of bearings. Eksploatacja i Niezawodność, 2019, 21(4): 610-619.
[269] C Ordónez, F Lasheras, F Roca-Pardinas, et al. A hybrid ARIMA-SVM model for the study of the remaining useful life of aircraft engines. Journal of Computational and Applied Mathematics, 2019, 346: 184-191.
[270] A Rai, S Upadhyay. Intelligent bearing performance degradation assessment and remaining useful life prediction based on self-organising map and support vector regression. Proceedings of the Institution of Mechanical Engineers. Journal of Mechanical Engineering Science, 2018, 232(6): 1118-1132.
[271] D Tobon-Mejia, K Medjaher, N Zerhouni, et al. A data-driven failure prognostics method based on mixture of Gaussians hidden Markov models. IEEE Transactions on Reliability, 2012, 61(2): 491-503.
[272] Z Wu, H Luo, Y Yang, et al. K-pdm: Kpi-oriented machinery deterioration estimation framework for predictive maintenance using cluster-based hidden Markov model. IEEE Access, 2018, 6: 41676-41687.
[273] S Laddada, T Benkedjouh, M Si-Chaib, et al. A data-driven prognostic approach based on wavelet transform and extreme learning machine. 2017 5th International Conference on Electrical Engineering-Boumerdes (ICEE-B), IEEE, 2017: 1-4.
[274] K Javed, R Gouriveau, N Zerhouni. Novel failure prognostics approach with dynamic thresholds for machine degradation. IECON 2013-39th Annual Conference of the IEEE Industrial Electronics Society, IEEE, 2013: 4404-4409.
[275] Z Li, Z Zheng, R Outbib. A prognostic methodology for power mosfets under thermal stress using echo state network and particle filter. Microelectronics Reliability, 2018, 88: 350-354.
[276] P Lim, C Goh, K Tan. A time window neural network based framework for remaining useful life estimation. 2016 International Joint Conference on Neural Networks (IJCNN), IEEE, 2016: 1746-1753.
[277] Y Fan, S Nowaczyk, T Rögnvaldsson. Transfer learning for remaining useful life prediction based on consensus self-organizing models. Reliability Engineering & System Safety, 2020, 203: 107098.
[278] Z Zhang, F Dong, L Xie. Data-driven fault prognosis based on incomplete time slice dynamic Bayesian network. IFAC-PapersOnLine, 2018, 51(18): 239-244.
[279] Y Wang, Y Zhao, S Addepalli. Remaining useful life prediction using deep learning approaches: A review. Procedia Manufacturing, 2020, 49: 81-88.
[280] X Li, G Xie, H Liu, et al. Predicting remaining useful life of industrial equipment based on multivariable monitoring data analysis. 2018 Chinese Automation Congress (CAC), IEEE, 2018: 1861–1866.
[281] X Li, Q Ding, J Sun. Remaining useful life estimation in prognostics using deep convolution neural networks. Reliability Engineering & System Safety, 2018, 172: 1-11.
[282] A Ellefsen, S Ushakov, V Æsøy, et al.: Validation of data-driven labeling approaches using a novel deep network structure for remaining useful life predictions. IEEE Access, 2019, 7: 71563-71575.
[283] R Zhao, R Yan, J Wang, et al. Learning to monitor machine health with convolutional bi-directional LSTM networks. Sensors, 2017, 17(2): 273.
[284] J Li, X Li, D He. A directed acyclic graph network combined with CNN and LSTM for remaining useful life prediction. IEEE Access, 2019, 7: 75464-75475.
[285] R Zhao, D Wang, R Yan, et al. Machine health monitoring using local feature-based gated recurrent unit networks. IEEE Transactions on Industrial Electronics, 2017, 65(2): 1539-1548.
[286] P Shan, P Hou, H Ge, et al. Image feature-based for bearing health monitoring with deep-learning method. 2019 Prognostics and System Health Management Conference (PHM-Qingdao), IEEE, 2019: 1-6.
[287] J Hong, Q Wang, X Qiu, et al. Remaining useful life prediction using time-frequency feature and multiple recurrent neural networks. 2019 24th IEEE International Conference on Emerging Technologies and Factory Automation (ETFA), IEEE, 2019: 916-923.
[288] J Zhu, N Chen, W Peng. Estimation of bearing remaining useful life based on multiscale convolutional neural network. IEEE Transactions on Industrial Electronics, 2018: 66(4): 3208-3216.
[289] X Li, W Zhang, Q Ding. Deep learning-based remaining useful life estimation of bearings using multi-scale feature extraction. Reliability Engineering & System Safety, 2019, 182: 208-218.
[290] M Ma, Z Mao. Deep recurrent convolutional neural network for remaining useful life prediction. 2019 IEEE International Conference on Prognostics and Health Management (ICPHM), IEEE, 2019: 1-4.
[291] W Mao, J He, J Tang, et al. Predicting remaining useful life of rolling bearings based on deep feature representation and long short-term memory neural network. Advances in Mechanical Engineering, 2018, 10(12): 1687814018817184.
[292] L Ren, J Cui, Y Sun, et al. Multi-bearing remaining useful life collaborative prediction: A deep learning approach. Journal of Manufacturing Systems, 2017, 43: 248-256.
[293] Q Wang, B Zhao, H Ma, et al. A method for rapidly evaluating reliability and predicting remaining useful life using two-dimensional convolutional neural network with signal conversion. Journal of Mechanical Science and Technology, 2019, 33(6): 2561-2571.
[294] J Deutsch, D He. Using deep learning-based approach to predict remaining useful life of rotating components. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 2017, 48(1): 11-20.
[295] A Ellefsen, E Bjørlykhaug, V Æsøy, et al. Remaining useful life predictions for turbofan engine degradation using semi-supervised deep architecture. Reliability Engineering & System Safety, 2019, 183, 240-251.
[296] C Sun, M Ma, Z Zhao, et al. Deep transfer learning based on sparse autoencoder for remaining useful life prediction of tool in manufacturing. IEEE Transactions on Industrial Informatics, 2018, 15(4): 2416-2425.
[297] W Mao, J He, M Zuo. Predicting remaining useful life of rolling bearings based on deep feature representation and transfer learning. IEEE Transactions on Instrumentation and Measurement, 2019, 69(4): 1594-1608.
[298] M Sadoughi, H Lu, C Hu. A deep learning approach for failure prognostics of rolling element bearings. 2019 IEEE International Conference on Prognostics and Health Management (ICPHM), IEEE, 2019: 1-7 (2019).
[299] R He, Y Dai, J Lu, et al. Developing ladder network for intelligent evaluation system: Case of remaining useful life prediction for centrifugal pumps. Reliability Engineering & System Safety, 2018, 180: 385-393.
[300] C Huang, H Huang, Y Li. A bidirectional lstm prognostics method under multiple operational conditions. IEEE Transactions on Industrial Electronics, 2019, 66(11): 8792-8802.
[301] A Al-Dulaimi, S Zabihi, A Asif, et al. A multimodal and hybrid deep neural network model for remaining useful life estimation. Computers in Industry, 2019, 108: 186-196.
[302] J Herp, N Pedersen, E Nadimi. A novel probabilistic long-term fault prediction framework beyond scada data-with applications in main bearing failure. Journal of Physics: Conference Series, 2019, 1222: 012043.
[303] A He, X Jin. Failure detection and remaining life estimation for ion mill etching process through deep-learning based multimodal data fusion. Journal of Manufacturing Science and Engineering, 2019, 141(10): 101008.
[304] H Miao, B Li, C Sun, et al. Joint learning of degradation assessment and RUL prediction for aeroengines via dual-task deep LSTM networks. IEEE Transactions on Industrial Informatics, 2019, 15(9): 5023-5032.
[305] R Liu, B Yang, A Hauptmann. Simultaneous bearing fault recognition and remaining useful life prediction using joint-loss convolutional neural network. IEEE Transactions on Industrial Informatics, 2019, 16(1): 87-96.
[306] M Xia, T Li, T Shu, et al. A two-stage approach for the remaining useful life prediction of bearings using deep neural networks. IEEE Transactions on Industrial Informatics, 2018, 15(6): 3703-3711.
[307] B Yang, R Liu, E Zio. Remaining useful life prediction based on a double-convolutional neural network architecture. IEEE Transactions on Industrial Electronics, 2019, 66(12): 9521-9530.
[308] A Zhang, H Wang, S Li, et al. Transfer learning with deep recurrent neural networks for remaining useful life estimation. Applied Sciences, 2018, 8(12): 2416.
[309] S Yu, Z Wu, X Zhu, et al. A domain adaptive convolutional LSTM model for prognostic remaining useful life estimation under variant conditions. 2019 Prognostics and System Health Management Conference (PHM-Paris), IEEE, 2019: 130-137.
[310] P Costa, A Akcay, Y Zhang, et al. Remaining useful lifetime prediction via deep domain adaptation. Reliability Engineering & System Safety, 2020, 195: 106682.
[311] S Sankararaman. Significance, interpretation, and quantification of uncertainty in prognostics and remaining useful life prediction. Mechanical Systems and Signal Processing, 2015, 25: 228-247.
[312] S Sankararaman, C Teubert. Impact of uncertainty on the diagnostics and prognostics of a current-pressure transducer. 2015 IEEE Aerospace Conference, IEEE, 2015: 1-10.
[313] M Djeziri, S Benmoussa, M Benbouzid. Data-driven approach augmented in simulation for robust fault prognosis. Engineering Applications of Artificial Intelligence, 2019, 86: 154-164.
[314] Y Deng, A Bucchianico, M Pechenizkiy. Controlling the accuracy and uncertainty trade-off in RUL prediction with a surrogate Wiener propagation model. Reliability Engineering & System Safety, 2020, 196: 106727.
[315] W Peng, Z Ye, N Chen. Bayesian deep-learning-based health prognostics toward prognostics uncertainty. IEEE Transactions on Industrial Electronics, 2019, 67(3): 2283-2293.
[316] B Wang, Y Lei, T Yan, et al. Recurrent convolutional neural network: A new framework for remaining useful life prediction of machinery. Neurocomputing, 2020, 379: 117-129.
[317] Y Gal, Z Ghahramani. Dropout as a Bayesian approximation: Representing model uncertainty in deep learning. International Conference on Machine Learning, PMLR, 2016: 1050-1059.
[318] Y Liao, L Zhang, C Liu. Uncertainty prediction of remaining useful life using long short-term memory network based on bootstrap method. 2018 IEEE International Conference on Prognostics and Health Management (ICPHM), IEEE, 2018: 1-8.
[319] V TV, P Malhotra, L Vig, G Shroff, et al. Data-driven prognostics with predictive uncertainty estimation using ensemble of deep ordinal regression models. arXiv preprint, 2019, arXiv: 1903.09795.
[320] NASA. Prognostics Center of Excellence Database. Available: https://ti.arc.nasa.gov/tech/dash/groups/pcoe/prognostic-data-repository (accessed on August 1 2020).
[321] A Saxena, K Goebel. Turbofan engine degradation simulation data set. Available: https://ti.arc.nasa.gov/c/6/ (accessed on August 1 2020).
[322] A Agogino, K Goebel. Milling data set. Available: https://ti.arc.nasa.gov/c/4/ (accessed on August 1 2020).
[323] P Nectoux, R Gouriveau, K Medjaher, et al. An experimental platform for bearings accelerated degradation tests. Proceedings of the IEEE International Conference on Prognostics and Health Management, IEEE, Beijing, China, 2012: 23-25. Available: https://ti.arc.nasa.gov/c/18/ (accessed on August 1 2020).
[324] Y Lei, B Wang. XJTU-SY bearing datasets. Available: https://mekhub.cn/machine-diagnosis/XJTU-SY_Bearing_Datasets (accessed on August 1 2020).
[325] N Oyharcabal. Convolutional recurrent neurtal networks for remaining useful life prediction in mechanical systems. 2018, Available: https://github.com/nicolasoyharcabal/ConvRNN_for_RUL_estimation (accessed on August 1 2020).
[326] L Jayasinghe, T Samarasinghe, C Yuen, et al. Temporal convolutional memory networks for remaining useful life estimation of industrial machinery. 2019 IEEE International Conference on Industrial Technology (ICIT), 2019: 915-920.
[327] L D Libera. A comparative study between Bayesian and frequentist neural networks for remaining useful life estimation in condition-based maintenance. arXiv preprint, 2019, arXiv: 1911.06256.
[328] Z Chen, M Wu, R Zhao, et al. Machine remaining useful life prediction via an attention based deep learning approach. IEEE Transactions on Industrial Electronics, 2020, 68(3): 2521-2531.
[329] Y Yucesan, F Viana. A physics-informed neural network for wind turbine main bearing fatigue. International Journal of Prognostics and Health Management, 2020, 125: 103386.
[330] J Wang, Y Li, R Zhao, et al. Physics guided neural network for machining tool wear prediction. Journal of Manufacturing Systems, 2020, 57: 298-310.