Real-time pipeline leak detection and localization using an attention-based LSTM approach

Long short-term memory (LSTM) has been widely applied to real-time automated natural gas leak detection and localization. However, LSTM approach could not provide the interpretation that this leak position is localized instead of other positions. This study proposes a leakage detection and localizat...

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Bibliographic Details
Published inProcess safety and environmental protection Vol. 174; pp. 460 - 472
Main Authors Zhang, Xinqi, Shi, Jihao, Yang, Ming, Huang, Xinyan, Usmani, Asif Sohail, Chen, Guoming, Fu, Jianmin, Huang, Jiawei, Li, Junjie
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.06.2023
Subjects
Attention mechanism
Leakage localization
Long short-term memory
Pipeline fault diagnosis
ANN
LSTM
DPS
ROC
Long short-term memory
KNN
SVM
AM
BiLSTM
Pipeline fault diagnosis
LSTM-AE
AUC
PCA
CNNs
Leakage localization
Adam
Attention mechanism
EKFs
RNN
AM-LSTM
WDNs
SCADA
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Summary:Long short-term memory (LSTM) has been widely applied to real-time automated natural gas leak detection and localization. However, LSTM approach could not provide the interpretation that this leak position is localized instead of other positions. This study proposes a leakage detection and localization approach by integrating the attention mechanism (AM) with the LSTM network. In this hybrid network, a fully-connected neural network behaving as AM is first applied to assign initial weights to time-series data. LSTM is then used to discover the complex correlation between the weighted data and leakage positions. A labor-scale pipeline leakage experiment of an urban natural gas distribution network is conducted to construct the benchmark dataset. A comparison between the proposed approach and the state-of-the-arts is also performed. The results demonstrate our proposed approach exhibits higher accuracy with AUC = 0.99. Our proposed approach assigns a higher attention weight to the sensor close to the leakage position, indicating the variation of data from the sensor has a significant influence on leakage localization. It corresponds that the closer to the leakage position, the larger variation of monitoring pressure after leakage, which enhances the detection results’ trustiness. This study provides a transparent and robust alternative for real-time automatic pipeline leak detection and localization, which contributes to constructing a digital twin of emergency management of urban pipeline leakage.
ISSN:0957-5820
1744-3598
DOI:10.1016/j.psep.2023.04.020