Abstract
Accurate runoff forecasting is of great significance for the optimization of water resource management and regulation. Given such a challenge, a novel compound approach combining time-varying filtering-based empirical mode decomposition (TVFEMD), sample entropy (SE)-based subseries recombination, and the newly developed deep sequential structure incorporating convolutional neural network (CNN) into a gated recurrent unit network (GRU) is proposed for monthly runoff forecasting. Firstly, the runoff series is disintegrated into a collection of subseries adopting TVFEMD, considering the volatility of runoff series caused by complex environmental and human factors. The subseries recombination strategy based on SE and recombination criterion is employed to reconstruct the subseries possessing the approximate complexity. Subsequently, the newly developed deep sequential structure based on CNN and GRU (CNNGRU) is applied to predict all the preprocessed subseries. Eventually, the predicted values obtained above are aggregated to deduce the ultimate prediction results. To testify to the efficiency and effectiveness of the proposed approach, eight relevant contrastive models were applied to the monthly runoff series collected from Baishan reservoir, where the experimental results demonstrated that the evaluation metrics obtained by the proposed model achieved an average index decrease of 44.35% compared with all the contrast models.
Highlights
The implementation of reliable and seasonable water resource management is of considerable significance to the hydrological system in various aspects, including water distribution, flood control, and disaster relief, while accurate forecasting and the corresponding scientific evaluation of monthly runoff play a vital role in responding to such challenges [1,2]
To construct an accurate monthly runoff forecasting approach balancing efficiency and effectiveness, a novel compound approach integrating time-varying filtering-based empirical mode decomposition (TVFEMD), sample entropy (SE)-based subseries recombination, and the newly developed CNN and GRU (CNNGRU) is proposed in this study
TVFEMD–CNNGRU was constructed based on TVFEMD and CNNGRU to test the effectiveness of the SE-based subseries recombination employed in the proposed model
Summary
College of Water Resources and Architectural Engineering, Northwest A&F University, Yanglin 712100, China. Key Laboratory of Agricultural Soil and Water Engineering in Arid and Semiarid Areas, Ministry of Education, Northwest A&F University, Yanglin 712100, China
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