Abstract
Precise soil moisture prediction is important for water management and logistics of on-farm operations. However, soil moisture is affected by various soil, crop, and meteorological factors, and it is difficult to establish ideal mathematical models for moisture prediction. We investigated various machine learning techniques for predicting soil moisture in the Red River Valley of the North (RRVN). Specifically, the evaluated machine learning techniques included classification and regression trees (CART), random forest regression (RFR), boosted regression trees (BRT), multiple linear regression (MLR), support vector regression (SVR), and artificial neural networks (ANN). The objective of this study was to determine the effectiveness of these machine learning techniques and evaluate the importance of predictor variables. The RFR and BRT algorithms performed the best, with mean absolute errors (MAE) of <0.040 m3 m−3 and root mean square errors (RMSE) of 0.045 and 0.048 m3 m−3, respectively. Similarly, RFR, SVR, and BRT showed high correlations (r2 of 0.72, 0.65 and 0.67 respectively) between predicted and measured soil moisture. The CART, RFR, and BRT models showed that soil moisture at nearby weather stations had the highest relative influence on moisture prediction, followed by 4-day cumulative rainfall and PET, subsequently followed by bulk density and Ksat.
Highlights
Soil moisture has a strong influence on the distribution of water between various components of the hydrological cycle in agricultural fields
The classification and regression trees (CART), random forest regression (RFR), and boosted regression trees (BRT) models showed that soil moisture at nearby weather stations had the highest relative influence on moisture prediction, followed by 4-day cumulative rainfall and Potential evapotranspiration (PET), subsequently followed by bulk density and Ksat
The best performance was observed under the RFR and BRT models and had mean absolute errors (MAE) values of less than 4%
Summary
Soil moisture has a strong influence on the distribution of water between various components of the hydrological cycle in agricultural fields. It helps in understanding the hydrology and climatic conditions that have high spatial and temporal variability. Precise measurement and/or prediction of soil moisture provides insights into expected infiltration and runoff generation during rainfall events and the management of water for agricultural purposes [1]. Soil moisture affects key farm activities from crop selection to timing of tilling, planting, fertilizer application, and harvesting due to infiltration, evaporation, runoff, heat, and gas fluxes [2,3]. Remote sensing tools have been used recently to predict surface soil moisture, but efficiency and models applicable to multiple landscapes are still under study [5]
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