Multi‐Sensor Fusion for Transient‐Based Pipeline Leak Localization in the Dempster‐Shafer Evidence Framework

Lin, Jingrong; Wang, Xun; Ghidaoui, Mohamed Salah

doi:10.1029/2021wr029926

“…The urban water distribution systems tend to be complicated and riddled with various natural (e.g., turbulence) and artificial (e.g., traffic) noise and uncertainties with large amplitude (Alawadhi et al., 2018; Alawadhi & Tartakovsky, 2020; Ferrante et al., 2014; Lin et al., 2021; X. Wang, 2021a; X. Wang, Waqar, et al., 2020; Waqar et al., 2021). To address the noise problem, the matched‐field processing (MFP), which is a parameter estimation technique that is based on the principle of maximum signal‐to‐noise ratio and thus robust in noisy and uncertain environments, was first adopted by X. Wang and Ghidaoui (2018b) for leak localization in a single pipe.…”

Section: Introductionmentioning

confidence: 99%

“…The urban water distribution systems tend to be complicated and riddled with various natural (e.g., turbulence) and artificial (e.g., traffic) noise and uncertainties with large amplitude (Alawadhi et al, 2018;Alawadhi & Tartakovsky, 2020;Ferrante et al, 2014;Lin et al, 2021;X. Wang, 2021a;X.…”

mentioning

confidence: 99%

Leak Localization in Looped Pipe Networks Based on a Factorized Transient Wave Model: Theoretical Framework

Chuan

¹

,

Wang

²

,

Ghidaoui

³

2022

Water Resources Research

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“…Although the transient wave‐based methods in the literature (Duan, 2017; Kim, 2020; Liggett & Chen, 1994) have shown their potential for leak localization in looped pipe networks (hereinafter called looped networks), these existing methods are mainly suited for pipe systems in relatively quiet environments where the amplitude of desired wave signals is an order of magnitude larger than that of background noise. Urban water distribution systems are usually exposed to a myriad of natural and artificial noise sources, such as turbulent fluctuations, ground traffic flows, and air bubble collapse (Dubey et al., 2019; Lin et al., 2021; Wang, 2021a). The generated background noise would easily result in the inaccuracy or even invalidity of the existing leak localization methods.…”

Section: Introductionmentioning

confidence: 99%

Leak Localization in Looped Pipe Networks Based on a Factorized Transient Wave Model: 2. Regularization of Ill‐Conditioned Problems

Chuan

¹

,

Wang

²

,

Louati

³

et al. 2022

Water Resources Research

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1

0

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“…The leak or burst detection is a potential use of transient waves (Lin et al., 2021; X. Wang, 2021). During wave propagation, the interaction between the wave and defects will modify the signal, and based on the modification, a defect can be localized (Che et al., 2021; Duan et al., 2020; Louati et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

Efficient Pipe Burst Detection in Tree‐Shape Water Distribution Networks Using Forward‐Backward Transient Analysis

Pan

¹

,

Duan

²

,

Keramat

³

et al. 2022

Water Resources Research

8

0

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Transient‐based leak/burst detection has received more and more attentions in the operation and management of water distribution networks. However, with the increase in pipe network complexity, it is hard to detect and locate the potential pipe defects and water losses efficiently. Recently, we proposed an efficient leak/burst localization strategy in single pipelines based on the forward and backward transient analysis, and in this work, this effective approach is customized for the more realistic branched (tree‐shaped) pipe networks. Unlike traditional transient‐based methods which rely on tedious optimization procedures, the proposed method uses a mismatch property between forward and backward analyses of transient signals for the pipe burst detection during the water supply process. Compared with other developed methods, this method can directly calculate the defect location, so it is expected to have high efficiency and wide applicability. To fulfill this goal, a framework for burst detection in a tree‐shaped pipe network is developed in this paper. Using the mass conservation and energy relations at the branched junctions, the forward and backward transient analysis is extended from one pipe to another until the burst is found and then located in the network. Both experimental and numerical tests show the effectiveness of the proposed method, and further analysis has shown that the method is also valid for leak detection in both transient and steady conditions, confirming the robustness and practicality of this proposed method. At last, this paper discusses the influence of transient sources and the potential combination of the method with other methods.

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Multi‐Sensor Fusion for Transient‐Based Pipeline Leak Localization in the Dempster‐Shafer Evidence Framework

Cited by 9 publications

References 69 publications

Leak Localization in Looped Pipe Networks Based on a Factorized Transient Wave Model: Theoretical Framework

Leak Localization in Looped Pipe Networks Based on a Factorized Transient Wave Model: Theoretical Framework

Leak Localization in Looped Pipe Networks Based on a Factorized Transient Wave Model: 2. Regularization of Ill‐Conditioned Problems

Efficient Pipe Burst Detection in Tree‐Shape Water Distribution Networks Using Forward‐Backward Transient Analysis

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