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

• URL: http://arxiv.org/abs/2004.05828v2
• Date: Tue, 14 Apr 2020 03:48:28 GMT
• Title: Hybrid Attention Networks for Flow and Pressure Forecasting in Water Distribution Systems
• Authors: Ziqing Ma and Shuming Liu and Guancheng Guo and Xipeng Yu
• Abstract summary: We propose a hybrid dual-stage spatial-temporal attention-based recurrent neural networks (hDS-RNN) model. Our model consists of two stages: a spatial attention-based encoder and a temporal attention-based decoder. Experiments on a real-world dataset are conducted and demonstrate that our model outperformed 9 baseline models in flow and pressure series prediction.
• Score: 3.6704226968275258
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Multivariate geo-sensory time series prediction is challenging because of the complex spatial and temporal correlation. In urban water distribution systems (WDS), numerous spatial-correlated sensors have been deployed to continuously collect hydraulic data. Forecasts of 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 temporal and spatial axes is proposed. Experiments on a real-world dataset are conducted and demonstrate that our model outperformed 9 baseline models in flow and pressure series prediction in WDS.

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