LARHYSS JOURNAL 1112-3680 / 2521-9782

Stream flow forecasting is essential for effective water resource management and flood prediction, but it poses significant challenges due to the complex nature of hydrological systems. Traditional methods often struggle to capture temporal dependencies and nonlinear relationships within the data, leading to inaccuracies in predictions. The specific objectives of this study are to (1) evaluate the effectiveness of long short-term memory (LSTM) networks and gradient boosting machine (GBM) in predicting stream flow in the Garudeshwar watershed of the Narmada River basin in central India, and (2) compare their performance using several evaluation metrics. This study utilizes datasets spanning training, validation, and testing phases to thoroughly examine and compare the models' performances. The evaluation metrics include Mean Absolute Error (MAE), Root Mean Square Error (RMSE), R-squared (R²), and Root Mean Square Percent Error (RMSPE). The findings demonstrate that GBM consistently outperforms LSTM across all datasets. For instance, on the training dataset, GBM achieved an MAE of 0.123, an RMSE of 0.456, and an R² of 0.96, whereas LSTM had an MAE of 0.234, an RMSE of 0.567, and an R² of 0.87. Similar trends were observed on the validation and testing datasets, with GBM maintaining superior performance metrics. By showcasing the superior performance of GBM, this research aims to enhance stream flow forecasting methods and support well-informed decision-making in water resource management and flood prediction efforts.

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