Evaluating empirical and machine learning approaches for reference evapotranspiration estimation using limited climatic variables in Nepal
Erica Shrestha, Suyog Poudyal, Anup Ghimire, Shrena Maharjan, Manoj Lamichhane, Sushant Mehan
Abstract
• Empirical and ML models were evaluated for ET 0 estimation using limited data in nepal. • ML models outperformed empirical models, reducing prediction errors by 23 %. • Radiation-based input variables were more important than temperature-based and humidity-based input variables. • Clustering of weather stations further reduced prediction errors by 10 to 18 %. • ML models with clustering outperformed in simulating reference evapotranspiration, supporting water resource management with limited climatic data. Accurate estimation of reference evapotranspiration (ET 0 ) is essential for optimizing water resource management. The widely accepted Penman-Monteith (FAO-56PM) model is commonly used for ET 0 estimation but relies on numerous weather variables that are often unavailable in developing countries like Nepal. The suitability of both empirical and machine learning (ML) models with limited climatic variables for estimating ET 0 in Nepal remains unexplored. We used 19 meteorological stations across Nepal that measured climatic variables, including maximum and minimum temperatures, wind speed, relative humidity, and sunshine hours. We assessed the performance of six widely used empirical models (Hargreaves Samani, modified Hargreaves Samani, Romanenko, Schendel, Priestley-Taylor, and Makkink) and four ML models (random forest, extreme gradient boosting, deep neural network, and long short-term memory) to estimate ET 0 with limited climatic variables in Nepal. Two strategies were applied: (1) the proposed ML models were tested at each weather station using leave-one-out cross-validation (LOOCV), (2) meteorological stations were grouped into three clusters using the K-means clustering and model performance were evaluated on each cluster. Results indicate that radiation-based models outperformed humidity and temperature-based models, with R² increasing from 23 to 38 % and RMSE decreasing by 27 to 41 % across empirical and ML models. Notably, all ML models outperformed empirical models, with clustering of weather stations further reducing prediction error in ET 0 estimation by 10 to 18 %. These findings demonstrate the potential of ML models for accurate ET 0 estimation with limited data, supporting agricultural water management and enhancing resilience in water-stressed areas.