TY - GEN
T1 - A Graph Convolutional Shrinkage Network-based Fault Diagnosis Method for Industrial Process
AU - Xu, Yuan
AU - Zou, Xun
AU - Ke, Wei
AU - Zhu, Qun Xiong
AU - He, Yan Lin
AU - Zhang, Ming Qing
AU - Zhang, Yang
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - With the increasing demand of safety monitoring for industrial process, fault diagnosis is facing greater challenges. In the paper, a graph convolutional shrinkage network is proposed for fault diagnosis. First, considering the correlation between process variables, Pearson correlation coefficient is used to convert the time series to graph structure with nodes and edges. Second, a graph convolutional shrinkage layer with anti-noise ability is designed, in which Chebyshev kernel is used as convolution kernel to extract the feature information of graph structure. In addition, a soft thresholding shrinkage layer is added to help adaptively determine the filtering thresholds of graphic feature information. Third, the graph classification for fault diagnosis is performed using the readout layer, fully connected layer and softmax layer. Finally, the proposed method's effectiveness and robustness are evaluated using TE process data. The experimental results demonstrate that the proposed fault diagnostic approach is reliable and capable of correctly identifying the fault states in noisy situations.
AB - With the increasing demand of safety monitoring for industrial process, fault diagnosis is facing greater challenges. In the paper, a graph convolutional shrinkage network is proposed for fault diagnosis. First, considering the correlation between process variables, Pearson correlation coefficient is used to convert the time series to graph structure with nodes and edges. Second, a graph convolutional shrinkage layer with anti-noise ability is designed, in which Chebyshev kernel is used as convolution kernel to extract the feature information of graph structure. In addition, a soft thresholding shrinkage layer is added to help adaptively determine the filtering thresholds of graphic feature information. Third, the graph classification for fault diagnosis is performed using the readout layer, fully connected layer and softmax layer. Finally, the proposed method's effectiveness and robustness are evaluated using TE process data. The experimental results demonstrate that the proposed fault diagnostic approach is reliable and capable of correctly identifying the fault states in noisy situations.
KW - Fault Diagnosis
KW - Graph Convolutional Network
KW - Graph Convolutional Shrinkage Layer
KW - TE Process
UR - http://www.scopus.com/inward/record.url?scp=85165984530&partnerID=8YFLogxK
U2 - 10.1109/DDCLS58216.2023.10165809
DO - 10.1109/DDCLS58216.2023.10165809
M3 - Conference contribution
AN - SCOPUS:85165984530
T3 - Proceedings of 2023 IEEE 12th Data Driven Control and Learning Systems Conference, DDCLS 2023
SP - 1069
EP - 1074
BT - Proceedings of 2023 IEEE 12th Data Driven Control and Learning Systems Conference, DDCLS 2023
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 12th IEEE Data Driven Control and Learning Systems Conference, DDCLS 2023
Y2 - 12 May 2023 through 14 May 2023
ER -