4.0 Article

A Stacked Machine Learning Algorithm for Multi-Step Ahead Prediction of Soil Moisture

Journal

HYDROLOGY
Volume 10, Issue 1, Pages -

Publisher

MDPI
DOI: 10.3390/hydrology10010001

Keywords

machine learning models; soil moisture content; stacked model; statistical measures

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A reliable assessment of soil moisture content is crucial for irrigation planning and controlling natural disasters. This study applies a stacked model (SM) consisting of multilayer perceptron (MLP), random forest (RF), and support vector regression (SVR) to estimate daily volumetric soil water content. The results show that the SM model performs best (R-2 = 0.962) compared to MLP (R-2 = 0.957), RF (R-2 = 0.956), and SVR (R-2 = 0.951) models under different input variables. Overall, the SM model can overcome the weaknesses of basic algorithms while maintaining a limited number of parameters and short calculation times, leading to more accurate predictions of soil water content than commonly employed MLMs.
A trustworthy assessment of soil moisture content plays a significant role in irrigation planning and in controlling various natural disasters such as floods, landslides, and droughts. Various machine learning models (MLMs) have been used to increase the accuracy of soil moisture content prediction. The present investigation aims to apply MLMs with novel structures for the estimation of daily volumetric soil water content, based on the stacking of the multilayer perceptron (MLP), random forest (RF), and support vector regression (SVR). Two groups of input variables were considered: the first (Model A) consisted of various meteorological variables (i.e., daily precipitation, air temperature, humidity, and wind speed), and the second (Model B) included only daily precipitation. The stacked model (SM) had the best performance (R-2 = 0.962) in the prediction of daily volumetric soil water content for both categories of input variables when compared with the MLP (R-2 = 0.957), RF (R-2 = 0.956) and SVR (R-2 = 0.951) models. Overall, the SM, which, in general, allows the weaknesses of the individual basic algorithms to be overcome while still maintaining a limited number of parameters and short calculation times, can lead to more accurate predictions of soil water content than those provided by more commonly employed MLMs.

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