Hybrid Attention Networks for Flow and Pressure Forecasting in Water Distribution Systems

Multivariate geo-sensory time series prediction is challenging because of the complex spatial and temporal correlations. In urban water distribution systems (WDSs), numerous spatial-correlated sensors have been deployed to continuously collect hydraulic data. Forecasts of the monitored flow and pres...

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Bibliographic Details
Published in:IEEE geoscience and remote sensing letters 2022, Vol.19, p.1-5
Main Authors: Ma, Ziqing, Liu, Shuming, Guo, Guancheng, Yu, Xipeng
Format: Article
Language:English
Subjects:
Anomalies
Coders
Correlation
Decision making
Decoding
Deep learning
Distribution
Forecasting
Mathematical models
Monitoring
Neural networks
Predictive models
Pressure
Recurrent neural networks
Sensors
spatial–temporal attention networks
Time series
Time series analysis
time series prediction
Water distribution
Water distribution systems
water distribution systems (WDSs)
Water engineering
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Summary:Multivariate geo-sensory time series prediction is challenging because of the complex spatial and temporal correlations. In urban water distribution systems (WDSs), numerous spatial-correlated sensors have been deployed to continuously collect hydraulic data. Forecasts of the monitored flow and pressure time series are of vital importance for operational decision making, alerts, and anomaly detection. To address this issue, we proposed a hybrid dual-stage spatial-temporal attention-based recurrent neural networks (hDS-RNN). Our model consists of two stages: a spatial attention-based encoder and a temporal attention-based decoder. Specifically, a hybrid spatial attention mechanism that employs inputs along the temporal and spatial axes is proposed. Experiments on a real-world data set are conducted, which demonstrate that our model outperformed seven baseline models in flow and pressure predictions in WDS.
ISSN:1545-598X
1558-0571
DOI:10.1109/LGRS.2020.3030839