Optimization of a Radiative Transfer Forward Operator for Simulating SMOS Brightness Temperatures over the Upper Mississippi Basin

The Soil Moisture Ocean Salinity (SMOS) satellite mission routinely provides global multiangular observations of brightness temperature TB at both horizontal and vertical polarization with a 3-day repeat period. The assimilation of such data into a land surface model (LSM) may improve the skill of o...

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Bibliographic Details
Published in:Journal of hydrometeorology 2015-06, Vol.16 (3), p.1109-1134
Main Authors: Lievens, H., Al Bitar, A., Verhoest, N. E. C., Cabot, F., De Lannoy, G. J. M., Drusch, M., Dumedah, G., Franssen, H.-J. Hendricks, Kerr, Y., Tomer, S. K., Martens, B., Merlin, O., Pan, M., van den Berg, M. J., Vereecken, H., Walker, J. P., Wood, E. F., Pauwels, V. R. N.
Format: Article
Language:English
Subjects:
Atmospheric models
Bias
Brightness
Brightness temperature
Calibration
Civil engineering
Climate
Climatology
Computer simulation
Data
Data assimilation
Data collection
Datasets
Distribution functions
Flood forecasting
Global temperatures
Horizontal polarization
Hydrometeorology
Infiltration
Infiltration capacity
Laboratories
Land cover
Land surface models
Mathematical models
Microwave emission
Modeling
Modelling
Optimization
Parameters
Radiative transfer
Remote sensing
Rescaling
Satellite observation
Satellites
Scaling
Simulation
Simulations
Soil
Soil improvement
Soil moisture
Soil water
Soils
Studies
Surface radiation temperature
Surface roughness
Vegetation
Vertical polarization
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Summary:The Soil Moisture Ocean Salinity (SMOS) satellite mission routinely provides global multiangular observations of brightness temperature TB at both horizontal and vertical polarization with a 3-day repeat period. The assimilation of such data into a land surface model (LSM) may improve the skill of operational flood forecasts through an improved estimation of soil moisture SM. To accommodate for the direct assimilation of the SMOS TB data, the LSM needs to be coupled with a radiative transfer model (RTM), serving as a forward operator for the simulation of multiangular and multipolarization top of the atmosphere TBs. This study investigates the use of the Variable Infiltration Capacity model coupled with the Community Microwave Emission Modelling Platform for simulating SMOS TB observations over the upper Mississippi basin, United States. For a period of 2 years (2010–11), a comparison between SMOS TBs and simulations with literature-based RTM parameters reveals a basin-averaged bias of 30 K. Therefore, time series of SMOS TB observations are used to investigate ways for mitigating these large biases. Specifically, the study demonstrates the impact of the LSM soil moisture climatology in the magnitude of TB biases. After cumulative distribution function matching the SM climatology of the LSM to SMOS retrievals, the average bias decreases from 30 K to less than 5 K. Further improvements can be made through calibration of RTM parameters related to the modeling of surface roughness and vegetation. Consequently, it can be concluded that SM rescaling and RTM optimization are efficient means for mitigating biases and form a necessary preparatory step for data assimilation.
ISSN:1525-755X
1525-7541
DOI:10.1175/JHM-D-14-0052.1