Litcius/Paper detail

A hybrid rainfall-runoff model: integrating initial loss and LSTM for improved forecasting

Wei Wang, Jie Gao, Zheng Liu, Chuanqi Li

2023Frontiers in Environmental Science23 citationsDOIOpen Access PDF

Abstract

Accurate rainfall-runoff modeling is crucial for disaster prevention, mitigation, and water resource management. This study aims to enhance precision and reliability in predicting runoff patterns by integrating physical-based models like HEC-HMS with data-driven models, such as LSTM. We present a novel hybrid model, Ia-LSTM, which combines the strengths of HEC-HMS and LSTM to improve hydrological modeling. By optimizing the “initial loss” (Ia) with HEC-HMS and utilizing LSTM to capture the effective rainfall-runoff relationship, the model achieves a substantial improvement in precision. Tested in the Yufuhe basin in Jinan City, Shandong province, the Ia-LSTM consistently outperforms individual HEC-HMS and LSTM models, achieving notable average Nash-Sutcliffe Efficiency ( NSE ) values of 0.873 and 0.829, and average R 2 values of 0.916 and 0.870 for calibration and validation, respectively. The study shows the potential of integrating physical mechanisms to enhance the efficiency of data-driven rainfall-runoff modeling. The Ia-LSTM model holds promise for more accurate runoff estimation, with wide applications in flood forecasting, water resource management, and infrastructure planning.

Topics & Concepts

Surface runoffEnvironmental scienceCalibrationComputer scienceFlood mythHydrology (agriculture)Reliability (semiconductor)Water resourcesStatisticsGeologyMathematicsGeotechnical engineeringPower (physics)BiologyPhysicsEcologyQuantum mechanicsPhilosophyTheologyHydrology and Watershed Management StudiesHydrological Forecasting Using AIFlood Risk Assessment and Management