TScatNet: An Interpretable Cross-Domain Intelligent Diagnosis Model With Antinoise and Few-Shot Learning Capability

被引:42
作者
Liu, Chao [1 ]
Qin, Chengjin [1 ]
Shi, Xi [1 ]
Wang, Zengwei [1 ]
Zhang, Gang [1 ]
Han, Yunting [1 ]
机构
[1] Shanghai Jiao Tong Univ, Sch Mech Engn, Shanghai 200240, Peoples R China
来源
IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT | 2021年 / 70卷
关键词
Antinoise; cross-domain diagnosis; domain shift; few-shot learning; interpretability; working condition variation; CONVOLUTIONAL NEURAL-NETWORK; BEARING FAULT-DIAGNOSIS; ADVERSARIAL NETWORKS; MACHINERY;
D O I
10.1109/TIM.2020.3041905
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
In a real industrial scenario, domain shift frequently occurred due to working loads variation, operation speeds variation, and environmental noise interference, severely degrading intelligent fault diagnosis models' performance. Currently, domain adaptation-based models eliminate domain shift by calibrating unlabeled target-domain data using labeled source-domain data. Nevertheless, these models may fail when encountering unseen working conditions, lacking unlabeled target-domain data for learning domain-invariant features. Besides, the existing deep domain adaptation-based models lack a few-shot learning capability and interpretability. This article develops a cross-domain diagnosis model named time-scattering convolutional network (TScatNet) to remedy these gaps. TScatNet extracts domain-invariant features using Morlet wavelet as the predefined convolutional kernel, modulus as nonlinearity, and scaling averaging as pooling layer. This predefined architecture eliminates domain shift without any domain adaptation, endows TScatNet few-shot learning capability, simplifies the hyperparameter tuning process, and brings interpretability. Both the CWRU and DDS data sets are used to verify the proposed model, which shows that TScatNet could stably realize 100% accuracy on transfer tasks across working loads and 100% accuracy across operation speeds. Moreover, even though the SNR value descends to -4, TScatNet achieved 96% accuracy on ten categories tasks and 99.8% accuracy on four categories tasks. Besides, TScatNet achieved nearly 100% accuracy both under training samples' sparsity and sparsity of working conditions.
引用
收藏
页数:10
相关论文
共 32 条
[21]   Rolling element bearing diagnostics-A tutorial [J].
Randall, Robert B. ;
Antoni, Jerome .
MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2011, 25 (02) :485-520
[22]   A novel model with the ability of few-shot learning and quick updating for intelligent fault diagnosis [J].
Ren, Zhijun ;
Zhu, Yongsheng ;
Yan, Ke ;
Chen, Kaida ;
Kang, Wei ;
Yue, Yi ;
Gao, Dawei .
MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2020, 138
[23]   Generative adversarial networks for data augmentation in machine fault diagnosis [J].
Shao, Siyu ;
Wang, Pu ;
Yan, Ruqiang .
COMPUTERS IN INDUSTRY, 2019, 106 :85-93
[24]   Bearing Fault Diagnosis Under Variable Working Conditions Based on Domain Adaptation Using Feature Transfer Learning [J].
Tong, Zhe ;
Li, Wei ;
Zhang, Bo ;
Jiang, Fan ;
Zhou, Gongbo .
IEEE ACCESS, 2018, 6 :76187-76197
[25]   A New Deep Transfer Learning Based on Sparse Auto-Encoder for Fault Diagnosis [J].
Wen, Long ;
Gao, Liang ;
Li, Xinyu .
IEEE TRANSACTIONS ON SYSTEMS MAN CYBERNETICS-SYSTEMS, 2019, 49 (01) :136-144
[26]   Transfer learning with convolutional neural networks for small sample size problem in machinery fault diagnosis [J].
Xiao, Dengyu ;
Huang, Yixiang ;
Qin, Chengjin ;
Liu, Zhiyu ;
Li, Yanming ;
Liu, Chengliang .
PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART C-JOURNAL OF MECHANICAL ENGINEERING SCIENCE, 2019, 233 (14) :5131-5143
[27]   A novel convolutional transfer feature discrimination network for unbalanced fault diagnosis under variable rotational speeds [J].
Xu, Kun ;
Li, Shunming ;
Wang, Jinrui ;
An, Zenghui ;
Qian, Weiwei ;
Ma, Huijie .
MEASUREMENT SCIENCE AND TECHNOLOGY, 2019, 30 (10)
[28]   A Deep Transfer Model With Wasserstein Distance Guided Multi-Adversarial Networks for Bearing Fault Diagnosis Under Different Working Conditions [J].
Zhang, Ming ;
Wang, Duo ;
Lu, Weining ;
Yang, Jun ;
Li, Zhiheng ;
Liang, Bin .
IEEE ACCESS, 2019, 7 :65303-65318
[29]   Machinery fault diagnosis with imbalanced data using deep generative adversarial networks [J].
Zhang, Wei ;
Li, Xiang ;
Jia, Xiao-Dong ;
Ma, Hui ;
Luo, Zhong ;
Li, Xu .
MEASUREMENT, 2020, 152
[30]   A deep convolutional neural network with new training methods for bearing fault diagnosis under noisy environment and different working load [J].
Zhang, Wei ;
Li, Chuanhao ;
Peng, Gaoliang ;
Chen, Yuanhang ;
Zhang, Zhujun .
MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2018, 100 :439-453
1234