Back to Search Start Over

Considering combined or separated roughness and vegetation effects in soil moisture retrievals.

Authors :
Parrens, Marie
Wigneron, Jean-Pierre
Richaume, Philippe
Al Bitar, Ahmad
Mialon, Arnaud
Fernandez-Moran, Roberto
Al-Yaari, Amen
O’Neill, Peggy
Kerr, Yann
Source :
International Journal of Applied Earth Observation & Geoinformation; Mar2017, Vol. 55, p73-86, 14p
Publication Year :
2017

Abstract

For more than six years, the Soil Moisture and Ocean Salinity (SMOS) mission has provided multi angular and full-polarization brightness temperature (TB) measurements at L-band. Geophysical products such as soil moisture (SM) and vegetation optical depth at nadir ( τ nad ) are retrieved by an operational algorithm using TB observations at different angles of incidence and polarizations. However, the quality of the retrievals depends on several surface effects, such as vegetation, soil roughness and texture, etc. In the microwave forward emission model used in the retrievals (L-band Microwave Emission Model, L-MEB), soil roughness is modelled with a semi-empirical equation using four main parameters ( Q r , H r , N rp , with p = H or V polarizations). At present, these parameters are calibrated with data provided by airborne studies and in situ measurements made at a local scale that is not necessarily representative of the large SMOS footprints (43 km on average) at global scale. In this study, we evaluate the impact of the calibrated values of N rp and H r on the SM and τ nad retrievals based on SMOS TB measurements (SMOS Level 3 product) over the Soil Climate Analysis Network (SCAN) network located in North America over five years (2011–2015). In this study, Q r was set equal to zero and we assumed that N rH = N rV . The retrievals were performed by varying N rp from −1 to 2 by steps of 1 and H r from 0 to 0.6 by steps of 0.1. At satellite scale, the results show that combining vegetation and roughness effects in a single parameter provides the best results in terms of soil moisture retrievals, as evaluated against the in situ SM data. Even though our retrieval approach was very simplified, as we did not account for pixel heterogeneity, the accuracy we obtained in the SM retrievals was almost systematically better than those of the Level 3 product. Improved results were also obtained in terms of optical depth retrievals. These new results may have key consequences in terms of calibration of roughness effects within the algorithms of the SMOS (ESA) and the SMAP (NASA) space missions. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
15698432
Volume :
55
Database :
Supplemental Index
Journal :
International Journal of Applied Earth Observation & Geoinformation
Publication Type :
Academic Journal
Accession number :
119604729
Full Text :
https://doi.org/10.1016/j.jag.2016.11.001