Development of soil moisture profiles through coupled microwave–thermal infrared observations in the southeastern United States

The principle of maximum entropy (POME) can be used to develop vertical soil moisture (SM) profiles. The minimal inputs required by the POME model make it an excellent choice for remote sensing applications. Two of the major input requirements of the POME model are the surface boundary condition and...

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Bibliographic Details
Published in:Hydrology and earth system sciences 2018-09, Vol.22 (9), p.4935-4957
Main Authors: Mishra, Vikalp, Cruise, James F, Hain, Christopher R, Mecikalski, John R, Anderson, Martha C
Format: Article
Language:English
Subjects:
Analysis
Boundary conditions
Climatic analysis
Correlation coefficient
Correlation coefficients
Disaggregation
Energy balance
Entropy
Estimates
In situ measurement
Infrared radiometers
Land surface models
Maximum entropy
Microwave radiometers
Moisture content
Moisture profiles
Natural resources
Profiles
Radiometers
Remote sensing
Resolution
Resource conservation
Soil
Soil analysis
Soil conservation
Soil moisture
Soil profiles
Soil research
Surface energy
Surface energy balance
Surface properties
Thermal properties
Water content
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Summary:The principle of maximum entropy (POME) can be used to develop vertical soil moisture (SM) profiles. The minimal inputs required by the POME model make it an excellent choice for remote sensing applications. Two of the major input requirements of the POME model are the surface boundary condition and profile-mean moisture content. Microwave-based SM estimates from the Advanced Microwave Scanning Radiometer (AMSR-E) can supply the surface boundary condition whereas thermal infrared-based moisture estimated from the Atmospheric Land EXchange Inverse (ALEXI) surface energy balance model can provide the mean moisture condition. A disaggregation approach was followed to downscale coarse-resolution (∼25 km) microwave SM estimates to match the finer resolution (∼5 km) thermal data. The study was conducted over multiple years (2006–2010) in the southeastern US. Disaggregated soil moisture estimates along with the developed profiles were compared with the Noah land surface model (LSM), as well as in situ measurements from 10 Natural Resource Conservation Services (NRCS) Soil Climate Analysis Network (SCAN) sites spatially distributed within the study region. The overall disaggregation results at the SCAN sites indicated that in most cases disaggregation improved the temporal correlations with unbiased root mean square differences (ubRMSD) in the range of 0.01–0.09 m3 m−3. The profile results at SCAN sites showed a mean bias of 0.03 and 0.05 (m3 m−3); ubRMSD of 0.05 and 0.06 (m3 m−3); and correlation coefficient of 0.44 and 0.48 against SCAN observations and Noah LSM, respectively. Correlations were generally highest in agricultural areas where values in the 0.6–0.7 range were achieved.
ISSN:1607-7938
1027-5606
1607-7938
DOI:10.5194/hess-22-4935-2018