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Water Resources Management

Erschienen in:

28.08.2020

Novel Leakage Detection and Localization Method Based on Line Spectrum Pair and Cubic Interpolation Search

verfasst von: Guancheng Guo, Xipeng Yu, Shuming Liu, Xiyan Xu, Ziqing Ma, Xiaoting Wang, Yujun Huang, Kate Smith

Erschienen in: Water Resources Management | Ausgabe 12/2020

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Abstract

Leakage detection in water distribution systems (WDS) is critical to ensuring the security of urban water supplies. Acoustic detection methods have been used for leakage detection in water utilities, but ambient noise in real cases interferes with their detection accuracy, and the localization process in meshed or looped pipe networks requires significant computational costs. To increase the effectiveness of acoustic detection methods in practical applications, the current work proposes a novel leakage detection and localization method. This method extracts line spectrum pairs (LSP) of leakage signals and uses a random forest (RF) model to detect leaks; then, a cubic interpolation search (CIS) algorithm is developed to locate leaks. The LSP-based leakage detection method shows a clear advantage over the detection methods based on linear prediction coefficients (LPC) and time or frequency domain features. The proposed leakage detection method achieves 99.45% accuracy. In the case of −5 dB, the detection accuracy reaches 93.89%. The CIS algorithm is found to be more stable and shows a faster convergence speed than a commonly used graph-based search algorithm. The localization error is low (i.e., 2.22 m to 9.99 m). The LSP-CIS combined algorithm provides a more effective solution for leakage detection and localization.

Vorheriger Artikel FingerPro: an R Package for Tracking the Provenance of Sediment

Nächster Artikel Stochastic Simulation of Daily Suspended Sediment Concentration Using Multivariate Copulas

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Titel: Novel Leakage Detection and Localization Method Based on Line Spectrum Pair and Cubic Interpolation Search
verfasst von: Guancheng Guo
Xipeng Yu
Shuming Liu
Xiyan Xu
Ziqing Ma
Xiaoting Wang
Yujun Huang
Kate Smith
Publikationsdatum: 28.08.2020
Verlag: Springer Netherlands
Erschienen in: Water Resources Management / Ausgabe 12/2020
Print ISSN: 0920-4741
Elektronische ISSN: 1573-1650
DOI: https://doi.org/10.1007/s11269-020-02651-z

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