Climate Change Research

Climate Change Research

Evaluation of the integration of LSTM Recurrent Neural Network with deep learning metaheuristic algorithms for flood modeling in the Taleghan watershed

Document Type : Original Article

Authors
Ramtin Tavoosi Rad 1
Mohammad Ansari ghojghar 2
1 Master Candidate, Department of Reclamation of Arid and Mountainous regions Engineering, Faculty of Natural Resources, University of Tehran, Karaj, Iran
2 Assistant Professor, Department of Reclamation of Arid and Mountainous regions Engineering, Faculty of Natural Resources, University of Tehran, Karaj, Iran
10.30488/ccr.2026.562118.1317
Abstract
Accurate river flow forecasting is a fundamental challenge in water resources management and flood warning system design. In this study, aiming to evaluate the efficiency of new deep learning models in predicting daily maximum flow, four models including LSTM, GRU-LSTM, ConvLSTM and S-LSTM were compared in five hydrometric stations of the Taleghan watershed. After data pre-processing and extraction of time-lag scenarios, the models were evaluated based on RMSE, MAE, NSE, and correlation coefficient indices in the training and test sets. The results showed that the time-memory-based models LSTM and GRU-LSTM provided significantly more accurate performance than the spatiotemporal models and developed versions. The GRU-LSTM model recorded the best accuracy with NSE higher than 0.95 and very low error, but statistical analysis showed that its difference with the LSTM model is not significant, so that the LSTM algorithm offers almost the same level of accuracy with less computational cost. In contrast, ConvLSTM and S-LSTM performed weaker and the greater dispersion of points in the correlation diagrams indicated their limitations in modeling univariate time series. Visual analysis of the correlation diagrams also showed that LSTM and GRU-LSTM had the most matching with the correlation line and were able to reconstruct temporal patterns of flow, especially peaks and troughs. Considering the balance between accuracy, stability and computational cost, the LSTM model is proposed as the final and optimal option for predicting daily maximum flow in the Taleghan watershed
Keywords
Flow forecasting
Water resources management
Flood warning systems
Novel models

Subjects

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