Evaluation and improvement of temporal robustness and transfer performance of surface soil moisture estimated by machine learning regression algorithms
•Upper and lower limits on the accuracy of soil moisture estimation are evaluated using advanced regression models with multi-source data.•The three proposed strategies can improve the temporal transfer performance of soil moisture.•Soil parameters are crucial for the temporal robustness and transfe...
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| Veröffentlicht in: | Computers and electronics in agriculture Jg. 217; S. 108518 |
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| Hauptverfasser: | , , , , , |
| Format: | Journal Article |
| Sprache: | Englisch |
| Veröffentlicht: |
Elsevier B.V
01.02.2024
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| Schlagworte: | |
| ISSN: | 0168-1699, 1872-7107 |
| Online-Zugang: | Volltext |
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| Zusammenfassung: | •Upper and lower limits on the accuracy of soil moisture estimation are evaluated using advanced regression models with multi-source data.•The three proposed strategies can improve the temporal transfer performance of soil moisture.•Soil parameters are crucial for the temporal robustness and transferability of soil moisture estimation.•Factors affecting the accuracy of soil moisture in heterogeneous regions are analyzed.
The accurate monitoring of the spatio-temporal distribution of surface soil moisture (SSM) is crucial to understanding Earth's water cycle. The machine learning regression (MLR) algorithm has brought a new breakthrough to SSM remote sensing estimation due to its powerful nonlinear fitting ability. However, the high-precision estimation of temporal SSM still faces challenges. In this study, we evaluated the temporal robustness and transfer performance of six MLR algorithms for SSM estimation and conducted a universality experiment in agricultural areas with abundant land cover types. First, the factors affecting the estimation accuracy of SSM were analyzed from the perspectives of dynamic variables (backscattering, multi-spectrum, and brightness temperature [TB]) and steady variables (soil texture [ST] and soil roughness [SR]). Results showed that radar incidence angle (RIA) is the key factor for estimating SSM accurately from dual polarization backscattering (dual-pol σ) data. The introduction of multi-spectrum data can considerably improve the estimation accuracy of SSM and is better than that of TB data. The physical measures (ST) or geometric measures (SR) can be used as auxiliary features for multi-spectrum or TB data, which improve the accuracy of SSM estimated from dual-pol σ data, with similar improvement effects. Multi-source data can effectively reduce the adverse effects of surface heterogeneity on SSM estimation. Ensemble learning and kernel learning algorithms have similar performance in the case of low-dimensional features and small samples. However, the neural network algorithms can correctly reflect the temporal variation of SSM only in the case of multi-dimensional features and large samples. The optimal accuracy of multi-temporal SSM is estimated by the Gaussian process regression algorithm (RMSE = 0.028 cm3/cm3). Moreover, to address poor transfer performance of temporal SSM in MLR models (RMSE > 0.060 cm3/cm3), this study proposed three strategies including the constraint of target domain samples, scattering model, and clustering model. The optimal error (RMSE) of multi-temporal SSM estimated by the three strategies is 0.032, 0.045, and 0.045 cm3/cm3. Overall, the strategies proposed can mitigate the issue of overestimation or underestimation resulting from the inconsistent distribution of SSM and RIAs at various phases. The soil parameters, acting as the medium across different phases, can notably enhance the temporal transfer performance of SSM regression models. This study introduces a novel framework for achieving high estimation accuracy and transfer performance of temporal SSM at a regional scale. |
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| ISSN: | 0168-1699 1872-7107 |
| DOI: | 10.1016/j.compag.2023.108518 |