Graph Convolutional Recurrent Neural Networks for Water Demand Forecasting

Zanfei, Ariele; Brentan, Bruno Melo; Menapace, Andrea; Righetti, Maurizio; Herrera, Manuel

doi:10.1029/2022wr032299

Cited by 35 publications

(16 citation statements)

References 49 publications

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“…A WDS can be represented by a graph considering the nodes as the vertices and the edges as the pipes. The weights of the edges can be the flow rates, head losses, or roughness of the pipes [32,33].…”

Section: Graph Theory and Shortest Pathmentioning

confidence: 99%

An Investigation on the Effect of Leakages on the Water Quality Parameters in Distribution Networks

Barros

Almeida

Zanfei

et al. 2023

Water

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Leakages in distribution networks reach more than 30% of the water supplied, entailing important risks for the water infrastructure with water contamination issues. Therefore, it is necessary to develop new methods to mitigate the amount of water wastes. This study proposes to seek new sources of information that can help for a more sustainable water use. Hence, an analysis of the network is presented, showing the hydraulic behavior during leaks occurrence, placing emphasis on how these events affect and modify water quality parameters, such as water age and chlorine concentration. The study enhances that water quality data can be an effective source of information in the case of leaks, being a possible source of information for future detection systems. In addition, this study proposes to use graph theory on the water network. The results highlight how an analysis of the shortest path between the leak location and the reservoir could provide meaningful information for future detection systems.

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Section: Graph Theory and Shortest Pathmentioning

confidence: 99%

An Investigation on the Effect of Leakages on the Water Quality Parameters in Distribution Networks

Barros

Almeida

Zanfei

et al. 2023

Water

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“…Wang et al [26] identified complex relationships between various meteorological factors at different sites and dissolved oxygen (DO) concentration levels, demonstrating that the integration of graph-based learning and time transformers in environmental modeling is a promising direction for future research. Zanfei et al [27] developed a novel graph convolutional recurrent neural network (GCRNN) to analyze the spatial and temporal dependencies among different water-demand time series within the same geographical area. Wang et al [28] presented an LSTM model integrating spatiotemporal attention, focusing on more valuable time and spatial features, to predict water levels in the middle and lower reaches of the Han River.…”

Section: Introductionmentioning

confidence: 99%

Urban Water Demand Prediction Based on Attention Mechanism Graph Convolutional Network-Long Short-Term Memory

Liu,

Yuan

et al. 2024

Water

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Predicting short-term urban water demand is essential for water resource management and directly impacts urban water resource planning and supply–demand balance. As numerous factors impact the prediction of short-term urban water demand and present complex nonlinear dynamic characteristics, the current water demand prediction methods mainly focus on the time dimension characteristics of the variables, while ignoring the potential influence of spatial characteristics on the temporal characteristics of the variables. This leads to low prediction accuracy. To address this problem, a short-term urban water demand prediction model which integrates both spatial and temporal characteristics is proposed in this paper. Firstly, anomaly detection and correction are conducted using the Prophet model. Secondly, the maximum information coefficient (MIC) is used to construct an adjacency matrix among variables, which is combined with a graph convolutional neural network (GCN) to extract spatial characteristics among variables, while a multi-head attention mechanism is applied to enhance key features related to water use data, reducing the influence of unnecessary factors. Finally, the prediction of short-term urban water demand is made through a three-layer long short-term memory (LSTM) network. Compared with existing prediction models, the hybrid model proposed in this study reduces the average absolute percentage error by 1.868–2.718%, showing better prediction accuracy and prediction effectiveness. This study can assist cities in rationally allocating water resources and lay a foundation for future research.

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“…Water demand modeling is key for better managing the water resource. In fact, adopting datadriven algorithms that can learn from the demand data is the basis for many applications that are fundamental for the proper water management [13]. For instance, developing a short-term model able to accurately predict the following hours of demand can help for the anomaly detection task [14].…”

Section: Introductionmentioning

confidence: 99%

An artificial intelligence approach for managing water demand in water supply systems

Zanfei

Menapace

Righetti

2023

IOP Conf. Ser.: Earth Environ. Sci.

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Water demand management is essential for water utilities, which have the critical task of supplying drinking water from water sources to end-users through the distribution network. Therefore, the water utilities have to make decisions for the current and future functioning of the water distribution system. In this context, the artificial intelligence approach with data-driven methods can be used to develop powerful tools to improve overall water management. In fact, data-driven methods can model water demands for plenty of tasks and applications such as demand forecasting or anomaly detection. In this work, we propose and discuss a practical application of an artificial neural network to model the urban water demand of a water supply system. The flexibility of the proposed method allows the prediction of water demand on different horizons. Moreover, this developed model can effectively support water utilities on different operational schedules and decision tasks.

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Graph Convolutional Recurrent Neural Networks for Water Demand Forecasting

Cited by 35 publications

References 49 publications

An Investigation on the Effect of Leakages on the Water Quality Parameters in Distribution Networks

An Investigation on the Effect of Leakages on the Water Quality Parameters in Distribution Networks

Urban Water Demand Prediction Based on Attention Mechanism Graph Convolutional Network-Long Short-Term Memory

An artificial intelligence approach for managing water demand in water supply systems

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