A review of research on fault detection and diagnosis of chemical process based on deep learning

Abstract The fault detection and diagnosis of the chemical process is of great significance to the reliability and safety of modern industrial systems. As an emerging technology, deep learning has attracted intense attention from academia and industry in the last ten years, because of the automated feature learning, powerful feature representation capability and excellent classification performance in solving complex problems. From the perspective of methodology, this review divides the fault detection and diagnosis technology of chemical process based on deep learning into autoencoder-based method, deep belief network-based method, convolutional neural network-based method and recurrent neural network-based method. After a brief introduction to the several deep learning models, this paper reviewed and summarized the latest research progress using the four methods systematically. Finally, some major challenges are summarized from the perspective of industrial application, and the future development directions are prospected from the three aspects of "data", "model" and "visualization".

	Service

	Email this article
	Add to my bookshelf
	Add to citation manager
	Email Alert
	RSS
	Articles by authors
	BAO Yu
	CHENG Shuo
	WANG Jingtao

Keywords： chemical process； fault detection and diagnosis； deep learning

Received 2021-03-30;

About author:

Cite this article:

BAO Yu, CHENG Shuo, WANG Jingtao.A review of research on fault detection and diagnosis of chemical process based on deep learning[J] Chemcial Industry and Engineering, 2022,V39(2): 9-22

[1] 吴春磊. 基于改进深度学习模型的过程故障识别研究[D]. 南昌:华东交通大学, 2019 WU Chunlei. Research on process fault identification based on improved depth learning model[D]. Nanchang:East China Jiaotong University, 2019(in Chinese)
[2] 孙旭, 李晓光, 李嘉锋, 等. 基于深度学习的图像超分辨率复原研究进展[J]. 自动化学报, 2017, 43(5):697-709 SUN Xu, LI Xiaoguang, LI Jiafeng, et al. Review on deep learning based image super-resolution restoration algorithms[J]. Acta Automatica Sinica, 2017, 43(5):697-709(in Chinese)
[3] ZHANG Q, ZHU S. Visual interpretability for deep learning:A survey[J]. Frontiers of Information Technology & Electronic Engineering, 2018, 19(1):27-39
[4] REN X, ZHOU Y, HUANG Z, et al. A novel text structure feature extractor for Chinese scene text detection and recognition[J]. IEEE Access, 2017, 5:3193-3204
[5] 奚雪峰, 周国栋. 面向自然语言处理的深度学习研究[J]. 自动化学报, 2016, 42(10):1445-1465 XI Xuefeng, ZHOU Guodong. A survey on deep learning for natural language processing[J]. Acta Automatica Sinica, 2016, 42(10):1445-1465(in Chinese)
[6] DRUZHKOV P N, KUSTIKOVA V D. A survey of deep learning methods and software tools for image classification and object detection[J]. Pattern Recognition and Image Analysis, 2016, 26(1):9-15
[7] HAN J, ZHANG D, CHENG G, et al. Advanced deep-learning techniques for salient and category-specific object detection:A survey[J]. IEEE Signal Processing Magazine, 2018, 35(1):84-100
[8] JIA F, LEI Y, LU N, et al. Deep normalized convolutional neural network for imbalanced fault classification of machinery and its understanding via visualization[J]. Mechanical Systems and Signal Processing, 2018, 110:349-367
[9] MAO W, FENG W, LIANG X. A novel deep output kernel learning method for bearing fault structural diagnosis[J]. Mechanical Systems and Signal Processing, 2019, 117:293-318
[10] SHAO H, JIANG H, ZHANG H, et al. Rolling bearing fault feature learning using improved convolutional deep belief network with compressed sensing[J]. Mechanical Systems and Signal Processing, 2018, 100:743-765
[11] LI F, PANG X, YANG Z. Motor current signal analysis using deep neural networks for planetary gear fault diagnosis[J]. Measurement, 2019, 145:45-54
[12] QIU G, GU Y, CAI Q. A deep convolutional neural networks model for intelligent fault diagnosis of a gearbox under different operational conditions[J]. Measurement, 2019, 145:94-107
[13] WANG S, XIANG J, ZHONG Y, et al. A data indicator-based deep belief networks to detect multiple faults in axial piston pumps[J]. Mechanical Systems and Signal Processing, 2018, 112:154-170
[14] LI Y, YANG Y, LI G, et al. A fault diagnosis scheme for planetary gearboxes using modified multi-scale symbolic dynamic entropy and mRMR feature selection[J]. Mechanical Systems and Signal Processing, 2017, 91:295-312
[15] GUO Y, TAN Z, CHEN H, et al. Deep learning-based fault diagnosis of variable refrigerant flow air-conditioning system for building energy saving[J]. Applied Energy, 2018, 225:732-745
[16] GE Z, SONG Z, GAO F. Review of recent research on data-based process monitoring[J]. Industrial & Engineering Chemistry Research, 2013, 52(10):3543-3562
[17] YOON S, MACGREGOR J F. Fault diagnosis with multivariate statistical models part I:Using steady state fault signatures[J]. Journal of Process Control, 2001, 11(4):387-400
[18] WANG Y, JIANG Q. Data-driven nonlinear chemical process fault diagnosis based on hierarchical representation learning[J]. The Canadian Journal of Chemical Engineering, 2020, 98(10):2150-2165
[19] GHOLIZADEH M, YAZDIZADEH A, MOHAMMAD-BAGHERPOUR H. Fault detection and identification using combination of EKF and neuro-fuzzy network applied to a chemical process (CSTR)[J]. Pattern Analysis and Applications, 2019, 22(2):359-373
[20] DOWNS J J, VOGEL E F. A plant-wide industrial process control problem[J]. Computers & Chemical Engineering, 1993, 17(3):245-255
[21] BATHELT A, RICKER N L, JELALI M. Revision of the Tennessee Eastman process model[J]. IFAC-PapersOnLine, 2015, 48(8):309-314
[22] MCAVOY T J, YE N. Base control for the Tennessee Eastman problem[J]. Computers & Chemical Engineering, 1994, 18(5):383-413
[23] SHAMS M B, BUDMAN H, DUEVER T. Fault detection using CUSUM based techniques with application to the Tennessee Eastman process[J]. IFAC Proceedings Volumes, 2010, 43(5):109-114
[24] YIN S, DING S X, HAGHANI A, et al. A comparison study of basic data-driven fault diagnosis and process monitoring methods on the benchmark Tennessee Eastman process[J]. Journal of Process Control, 2012, 22(9):1567-1581
[25] GE X, WANG B, YANG X, et al. Fault detection and diagnosis for reactive distillation based on convolutional neural network[J]. Computers & Chemical Engineering, 2021, doi:10.1016/j.compchemeng.2020.107172
[26] LI C, ZHAO D, MU S, et al. Fault diagnosis for distillation process based on CNN-DAE[J]. Chinese Journal of Chemical Engineering, 2019, 27(3):598-604
[27] ZHENG S, ZHAO J. A new unsupervised data mining method based on the stacked autoencoder for chemical process fault diagnosis[J]. Computers & Chemical Engineering, 2020, doi:10.1016/j.compchemeng.2020.106755
[28] PENG J, HU Z, LIU J, et al. Fault diagnosis based on chemical sensor data with an active deep neural network[J]. Sensors, 2016, doi:10.3390/s16101695
[29] LV F, WEN C, BAO Z, et al. Fault diagnosis based on deep learning[C]//2016 American Control Conference (ACC). Boston, MA, USA:IEEE, 2016:6851-6856
[30] LV F, WEN C, LIU M, et al. Weighted time series fault diagnosis based on a stacked sparse autoencoder[J]. Journal of Chemometrics, 2017, doi:10.1002/cem.2912
[31] GUO C, HU W, YANG F, et al. Deep learning technique for process fault detection and diagnosis in the presence of incomplete data[J]. Chinese Journal of Chemical Engineering, 2020, 28(9):2358-2367
[32] YAN W, GUO P, GONG L, et al. Nonlinear and robust statistical process monitoring based on variant autoencoders[J]. Chemometrics and Intelligent Laboratory Systems, 2016, 158:31-40
[33] YIN J, YAN X. Mutual information-dynamic stacked sparse autoencoders for fault detection[J]. Industrial & Engineering Chemistry Research, 2019, 58(47):21614-21624
[34] YIN J, YAN X. Stacked sparse autoencoders monitoring model based on fault-related variable selection[J]. Soft Computing, 2021, 25(5):3531-3543
[35] ZHANG Z, JIANG T, LI S, et al. Automated feature learning for nonlinear process monitoring-An approach using stacked denoising autoencoder and k-nearest neighbor rule[J]. Journal of Process Control, 2018, 64:49-61
[36] 张祥, 崔哲, 董玉玺, 等. 基于VAE-DBN的故障分类方法在化工过程中的应用[J]. 过程工程学报, 2018, 18(3):590-594 ZHANG Xiang, CUI Zhe, DONG Yuxi, et al. Application of fault classification method based on VAE-DBN in chemical process[J]. The Chinese Journal of Process Engineering, 2018, 18(3):590-594(in Chinese)
[37] LEE Y S, CHEN J. Enhancing monitoring performance of data sparse nonlinear processes through information sharing among different grades using Gaussian mixture prior variational autoencoders[J]. Chemometrics and Intelligent Laboratory Systems, 2021, doi:j.chemolab.2020.104219
[38] YANG Z, GE Z. Monitoring and prediction of big process data with deep latent variable models and parallel computing[J]. Journal of Process Control, 2020, 92:19-34
[39] LI J, YAN X. Process monitoring using principal component analysis and stacked autoencoder for linear and nonlinear coexisting industrial processes[J]. Journal of the Taiwan Institute of Chemical Engineers, 2020, 112:322-329
[40] JIANG L, GE Z, SONG Z. Semi-supervised fault classification based on dynamic Sparse Stacked auto-encoders model[J]. Chemometrics and Intelligent Laboratory Systems, 2017, 168:72-83
[41] WANG Y, YANG H, YUAN X, et al. Deep learning for fault-relevant feature extraction and fault classification with stacked supervised auto-encoder[J]. Journal of Process Control, 2020, 92:79-89
[42] YU J, LIU X, YE L. Convolutional long short-term memory autoencoder-based feature learning for fault detection in industrial processes[J]. IEEE Transactions on Instrumentation and Measurement, 2021, 70:1-15
[43] LI Z, TIAN L, JIANG Q, et al. Fault diagnostic method based on deep learning and multimodel feature fusion for complex industrial processes[J]. Industrial & Engineering Chemistry Research, 2020, 59(40):18061-18069
[44] HINTON G E, SALAKHUTDINOV R R. Reducing the dimensionality of data with neural networks[J]. Science, 2006, 313(5786):504-507
[45] TAMILSELVAN P, WANG P F. Failure diagnosis using deep belief learning based health state classification[J]. Reliability Engineering & System Safety, 2013, 115:124-135
[46] TRAN V T, ALTHOBIANI F, BALL A. An approach to fault diagnosis of reciprocating compressor valves using Teager-Kaiser energy operator and deep belief networks[J]. Expert Systems With Applications, 2014, 41(9):4113-4122
[47] ZHANG Z, ZHAO J. A deep belief network based fault diagnosis model for complex chemical processes[J]. Computers & Chemical Engineering, 2017, 107:395-407
[48] WANG Y, ZHANG J, DENG F. A method of fault diagnosis based on DE-DBN[M]//Lecture Notes in Electrical Engineering. Singapore:Springer Singapore, 2017:209-217
[49] WANG Y, PAN Z, YUAN X, et al. A novel deep learning based fault diagnosis approach for chemical process with extended deep belief network[J]. ISA Transactions, 2020, 96:457-467
[50] WEI Y, WENG Z. Research on TE process fault diagnosis method based on DBN and dropout[J]. The Canadian Journal of Chemical Engineering, 2020, 98(6):1293-1306
[51] 程换新, 王建庆. 改进深度置信网络对TE过程故障诊断研究[J]. 电子测量技术, 2019, 42(9):117-120 CHENG Huanxin, WANG Jianqing. Improved DBN for TE process fault diagnosis[J]. Electronic Measurement Technology, 2019, 42(9):117-120(in Chinese)
[52] YU J, YAN X. Whole process monitoring based on unstable neuron output information in hidden layers of deep belief network[J]. IEEE Transactions on Cybernetics, 2020, 50(9):3998-4007
[53] TANG Q, CHAI Y, QU J, et al. Fisher discriminative sparse representation based on DBN for fault diagnosis of complex system[J]. Applied Sciences, 2018, doi:10.3390/app8050795
[54] TANG P, PENG K, ZHANG K, et al. A deep belief network-based fault detection method for nonlinear processes[J]. IFAC-PapersOnLine, 2018, 51(24):9-14
[55] YU J, YAN X. Active features extracted by deep belief network for process monitoring[J]. ISA Transactions, 2019, 84:247-261
[56] JIANG Q, YAN X. Learning deep correlated representations for nonlinear process monitoring[J]. IEEE Transactions on Industrial Informatics, 2019, 15(12):6200-6209
[57] TIAN W, LIU Z, LI L, et al. Identification of abnormal conditions in high-dimensional chemical process based on feature selection and deep learning[J]. Chinese Journal of Chemical Engineering, 2020, 28(7):1875-1883
[58] LECUN Y, JACKEL L D, BOSER B, et al. Handwritten digit recognition:Applications of neural network chips and automatic learning[J]. IEEE Communications Magazine, 1989, 27(11):41-46
[59] KRIZHEVSKY A, SUTSKEVER I, HINTON G E. Imagenet classification with deep convolutional neural networks[J]. Advances in Neural Information Processing Systems, 2012, 25:1097-1105
[60] SIMONYAN K, ZISSERMAN A. Very deep convolutional networks for large-scale image recognition[EB/OL]. 2014, http://arxiv.org/abs/1409.1556
[61] GAO X, YANG F, FENG E. A process fault diagnosis method using multi-time scale dynamic feature extraction based on convolutional neural network[J]. The Canadian Journal of Chemical Engineering, 2020, 98(6):1280-1292
[62] GUO S, YANG T, GAO W, et al. A novel fault diagnosis method for rotating machinery based on a convolutional neural network[J]. Sensors (Basel, Switzerland), 2018, doi:10.3390/s18051429
[63] GUO S, YANG T, GAO W, et al. An intelligent fault diagnosis method for bearings with variable rotating speed based on Pythagorean spatial pyramid pooling CNN[J]. Sensors (Basel, Switzerland), 2018, doi:10.3390/s18113857
[64] WU H, ZHAO J. Deep convolutional neural network model based chemical process fault diagnosis[J]. Computers & Chemical Engineering, 2018, 115:185-197
[65] EOM Y H, YOO J W, HONG S B, et al. Refrigerant charge fault detection method of air source heat pump system using convolutional neural network for energy saving[J]. Energy, 2019, doi:10.1016/j.energy.2019.115877
[66] LEE K B, CHEON S, KIM C O. A convolutional neural network for fault classification and diagnosis in semiconductor manufacturing processes[J]. IEEE Transactions on Semiconductor Manufacturing, 2017, 30(2):135-142
[67] 李元, 冯成成. 基于一维卷积神经网络深度学习的工业过程故障检测[J]. 测控技术, 2019, 38(9):36-40, 61 LI Yuan, FENG Chengcheng. Fault detection of industrial process based on deep learning of one-dimensional convolution neural network[J]. Measurement & Control Technology, 2019, 38(9):36-40, 61(in Chinese)
[68] SHI S, ZHAO Z. Fluidized bed agglomeration monitoring based on convolutional neural networks[C]//201837th Chinese Control Conference (CCC). Wuhan:IEEE, 2018:5973-5978
[69] HOCHREITER S, SCHMIDHUBER J. Long short-term memory[J]. Neural Computation, 1997, 9(8):1735-1780
[70] CHO K, VAN MERRIENBOER B, GULCEHRE C, et al. Learning phrase representations using RNN encoder-decoder for statistical machine translation[EB/OL]. 2014, https://arxiv.org/abs/1406.1078
[71] KANG J. Visualization analysis for fault diagnosis in chemical processes using recurrent neural networks[J]. Journal of the Taiwan Institute of Chemical Engineers, 2020, 112:137-151
[72] ZHAO H, SUN S, JIN B. Sequential fault diagnosis based on LSTM neural network[J]. IEEE Access, 2018, 6:12929-12939
[73] ZHANG S, BI K, QIU T. Bidirectional recurrent neural network-based chemical process fault diagnosis[J]. Industrial & Engineering Chemistry Research, 2020, 59(2):824-834
[74] SUN W, PAIVA A R C, XU P, et al. Fault detection and identification using Bayesian recurrent neural networks[J]. Computers & Chemical Engineering, 2020, doi:10.1016/j.compchemeng.2020.106991
[75] REN J, NI D. A batch-wise LSTM-encoder decoder network for batch process monitoring[J]. Chemical Engineering Research and Design, 2020, 164:102-112
[76] 张清清. 基于孪生LSTM的TE过程故障诊断方法研究[D]. 成都:电子科技大学, 2020 ZHANG Qingqing. Research on fault diagnosis method of TE process based on siamese LSTM[D]. Chengdu:University of Electronic Science and Technology of China, 2020(in Chinese)
[77] SHAO B, HU X, BIAN G, et al. A multichannel LSTM-CNN method for fault diagnosis of chemical process[J]. Mathematical Problems in Engineering, 2019, 2019:1-14
[78] WANG N, YANG F, ZHANG R, et al. Intelligent fault diagnosis for chemical processes using deep learning multimodel fusion[J]. IEEE Transactions on Cybernetics, 8832, PP(99):1-15
[79] XING L, YAO W, HUANG Y. Fault diagnosis of multi-sensor signal with unknown composite fault based on deep learning[J]. Chongqing Daxue Xuebao/Journal of Chongqing University, 2020, 43(9):93-100
[80] SHAHNAZARI H. Fault diagnosis of nonlinear systems using recurrent neural networks[J]. Chemical Engineering Research and Design, 2020, 153:233-245
[81] ZHANG L, LIN J, LIU B, et al. A review on deep learning applications in prognostics and health management[J]. IEEE Access, 2019, 7:162415-162438
[82] LIU H, ZHOU J, XU Y, et al. Unsupervised fault diagnosis of rolling bearings using a deep neural network based on generative adversarial networks[J]. Neurocomputing, 2018, 315:412-424
[83] LIU J, QU F, HONG X, et al. A small-sample wind turbine fault detection method with synthetic fault data using generative adversarial nets[J]. IEEE Transactions on Industrial Informatics, 2019, 15(7):3877-3888
[84] WU H, ZHAO J. Fault detection and diagnosis based on transfer learning for multimode chemical processes[J]. Computers & Chemical Engineering, 2020, doi:10.1016/j.compchemeng.2020.106731