Leak Identification Based on CS-ResNet Under Different Leakage Apertures for Water-Supply Pipeline

Considering the problem of difficulty in transmission and storage due to a large amount of data in the water-supply network monitoring system based on a wireless sensor network (WSN), we propose a sparse representation of the water-supply network monitoring data by using compressed sensing (CS) meth...

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Veröffentlicht in:	IEEE access 2022, Vol.10, p.57783-57795
Hauptverfasser:	Mei, Lin, Zhou, Jun, Li, Shuaiyong, Cai, Mengqian, Li, Tong
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Sprache:	eng
Schlagworte:	Accuracy Apertures Artificial neural networks Compressed sensing Identification methods Image reconstruction Leakage Manganese Monitoring Neural networks observation matrix Pipeline leakage Pipelines residual neural network Sparse matrices Training Water conservation Water pipelines Water resources Water supply Wireless sensor networks
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description	Considering the problem of difficulty in transmission and storage due to a large amount of data in the water-supply network monitoring system based on a wireless sensor network (WSN), we propose a sparse representation of the water-supply network monitoring data by using compressed sensing (CS) method. At the same time, aiming at the problem of low leakage identification accuracy caused by information loss under compressed sensing, we propose a leak identification method for a water-supply pipe network based on compressed sensing and deep residual neural network (ResNet). Firstly, under the condition that the observation matrix ensures the integrity of signal information, the compressed sensing theory is used to compress and observe leakage signals to obtain observation data, to reduce the redundant information and volume of the data. At the same time, the observation data is preprocessed to realize the transformation of a one-dimensional signal to a two-dimensional matrix. Then the residual neural network is trained by using the two-dimensional data to realize the automatic, efficient, and accurate leak identification under different leakage apertures. Experimental results show that the proposed method can obtain relatively high accuracy and greatly reduce the training time of ResNet by using compressed data. When the Compression rate (CR) is 70% and the observation matrix is a Gaussian random matrix, the average accuracy is 96.67% and the training time is only 50% compared to uncompressed data. The research work provides a new intelligent leak identification under different leak apertures using WSN and has important application prospects in saving water resources.
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At the same time, aiming at the problem of low leakage identification accuracy caused by information loss under compressed sensing, we propose a leak identification method for a water-supply pipe network based on compressed sensing and deep residual neural network (ResNet). Firstly, under the condition that the observation matrix ensures the integrity of signal information, the compressed sensing theory is used to compress and observe leakage signals to obtain observation data, to reduce the redundant information and volume of the data. At the same time, the observation data is preprocessed to realize the transformation of a one-dimensional signal to a two-dimensional matrix. Then the residual neural network is trained by using the two-dimensional data to realize the automatic, efficient, and accurate leak identification under different leakage apertures. 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subjects	Accuracy Apertures Artificial neural networks Compressed sensing Identification methods Image reconstruction Leakage Manganese Monitoring Neural networks observation matrix Pipeline leakage Pipelines residual neural network Sparse matrices Training Water conservation Water pipelines Water resources Water supply Wireless sensor networks
title	Leak Identification Based on CS-ResNet Under Different Leakage Apertures for Water-Supply Pipeline
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