Abstract
Accurate forecasting of hourly water demand is essential for effective and sustainable operation, and the cost-effective management of water distribution networks. Unlike monthly or yearly water demand, hourly water demand has more fluctuations and is easily affected by short-term abnormal events. An effective preprocessing method is needed to capture the hourly water demand patterns and eliminate the interference of abnormal data. In this study, an innovative preprocessing framework, including a novel local outlier detection and correction method Isolation Forest (IF), an adaptive signal decomposition technique Complete Ensemble Empirical Mode Decomposition with Adaptive Noise (CEEMDAN), and basic forecasting models have been developed. In order to compare a promising deep learning method Gated Recurrent Unit (GRU) as a basic forecasting model with the conventional forecasting models, Support Vector Regression (SVR) and Artificial Neural Network (ANN) have been used. The results show that the proposed hybrid method can utilize the complementary advantages of the preprocessing methods to improve the accuracy of the forecasting models. The root-mean-square error of the SVR, ANN, and GRU models has been reduced by 57.5%, 27.8%, and 30.0%, respectively. Further, the GRU-based models developed in this study are superior to the other models, and the IF-CEEMDAN-GRU model has the highest accuracy. Hence, it is promising that this preprocessing framework can improve the performance of the water demand forecasting models.
Highlights
Due to phenomena such as climate change, overpopulation, groundwater depletion, and energy tension, many water utilities around the world face stresses from societies and nature [1,2,3]
Isolation Forest, and the adaptive signal decomposition technique CEEMDAN have been introduced to water demand forecasting
The results have been compared with those of Artificial Neural Network (ANN) and Support Vector Regression (SVR) to investigate the efficiency of the proposed preprocessing framework on different models
Summary
Due to phenomena such as climate change, overpopulation, groundwater depletion, and energy tension, many water utilities around the world face stresses from societies and nature [1,2,3]. To address these problems, accurate water demand forecasting and effective operation of water distribution networks are essential. With the development of smart water, the high-frequency measuring system of District Metering Areas (DMAs) is becoming mature [8,9] That makes it possible to obtain high-frequency data for hourly water demand forecasting. It is a great challenge to improve the accuracy of hourly water demand forecasting
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