A comprehensive study of deep learning for soil moisture prediction

A comprehensive study of deep learning for soil moisture prediction

Soil moisture plays a crucial role in the hydrological cycle, but accurately predicting soil moisture presents challenges due to the nonlinearity of soil water transport and the variability of boundary conditions. Deep learning has emerged as a promising approach for simulating soil moisture dynamic...

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Bibliographic Details
Published in:Hydrology and earth system sciences Vol. 28; no. 4; pp. 917 - 943
Main Authors: Wang, Yanling, Shi, Liangsheng, Hu, Yaan, Hu, Xiaolong, Song, Wenxiang, Wang, Lijun
Format: Journal Article
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 27-02-2024
Copernicus Publications
Subjects:
Additives
Agricultural production
Analysis
Boundary conditions
Correlation analysis
Deep learning
Design
Dynamic structural analysis
Embedding
Feature extraction
Hybrid structures
Hydrologic cycle
Hydrological cycle
Hydrology
Long short-term memory
Machine learning
Moisture content
Network design
Neural networks
Nonlinear systems
Nonlinearity
Performance evaluation
Precipitation
Predictions
Radiation
Soil
Soil dynamics
Soil moisture
Soil moisture dynamics
Soil texture
Soil water
Stochasticity
Time series
Water transport
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Summary:Soil moisture plays a crucial role in the hydrological cycle, but accurately predicting soil moisture presents challenges due to the nonlinearity of soil water transport and the variability of boundary conditions. Deep learning has emerged as a promising approach for simulating soil moisture dynamics. In this study, we explore 10 different network structures to uncover their data utilization mechanisms and to maximize the potential of deep learning for soil moisture prediction, including three basic feature extractors and seven diverse hybrid structures, six of which are applied to soil moisture prediction for the first time. We compare the predictive abilities and computational costs of the models across different soil textures and depths systematically. Furthermore, we exploit the interpretability of the models to gain insights into their workings and attempt to advance our understanding of deep learning in soil moisture dynamics. For soil moisture forecasting, our results demonstrate that the temporal modeling capability of long short-term memory (LSTM) is well suited. Furthermore, the improved accuracy achieved by feature attention LSTM (FA-LSTM) and the generative-adversarial-network-based LSTM (GAN-LSTM), along with the Shapley (SHAP) additive explanations analysis, help us discover the effectiveness of attention mechanisms and the benefits of adversarial training in feature extraction. These findings provide effective network design principles. The Shapley values also reveal varying data leveraging approaches among different models. The t-distributed stochastic neighbor embedding (t-SNE) visualization illustrates differences in encoded features across models. In summary, our comprehensive study provides insights into soil moisture prediction and highlights the importance of the appropriate model design for specific soil moisture prediction tasks. We also hope this work serves as a reference for deep learning studies in other hydrology problems. The codes of 3 machine learning and 10 deep learning models are open source.
ISSN:1607-7938
1027-5606
1607-7938
DOI:10.5194/hess-28-917-2024