SMOS L2 OS ATBD - ARGANS
SMOS L2 OS ATBD - ARGANS
SMOS L2 OS ATBD - ARGANS
Create successful ePaper yourself
Turn your PDF publications into a flip-book with our unique Google optimized e-Paper software.
80<br />
ICM-CSIC<br />
LOCEAN/SA/CETP<br />
IFREMER<br />
<strong>SM<strong>OS</strong></strong> <strong>L2</strong> <strong>OS</strong><br />
Algorithm Theoretical<br />
Baseline Document<br />
Doc: SO-TN-ARG-GS-0007<br />
Issue: 3 Rev: 9<br />
Date: 25 January 2013<br />
Page: 80<br />
roughness and wind speed is not direct. We expect however that accounting for the impact of<br />
waves on the drag coefficients will better characterize impact of these parameters on<br />
roughness.<br />
References<br />
[1] S. H. Yueh, R. Kwok, F. K. Li, S. V. Nghiem, and W. J. Wilson, “Polarimetric passive<br />
remote sensing of ocean wind vectors,” Radio Sci., vol. 29, pp. 799–814, 1994.<br />
[2] L. Tsang, J. A. Kong, and R. T. Shin, Theory of Microwave Remote Sensing. New York:<br />
Wiley, 1985.<br />
[3] G. S. E. Lagerloef, C. T. Swift, and David M. Le Vine, Sea surface salinity : The next<br />
remote sensing challenge, Oceanography, vol. 8, no. 2, pp. 44-49, 1995.<br />
[4] S. H. Yueh, R. West, W. J. Wilson, Fuk K. Li, E. G. Njoku, and Y. Rahmat-Samii, Error<br />
sources and feasibility for microwave remote sensing of ocean surface salinity, IEEE Trans.<br />
Geosci. and Remote Sens., vol. 39, no. 5, pp. 1049-1060, 2001.<br />
[5] E. P. Dinnat, J. Boutin, G. Caudal, J. Etcheto, and A. Camps, Issues concerning the sea<br />
emissivity modeling in L-band for retrieving surface salinity, Radio Sci., vol. 38, no. 4, 2003.<br />
[6] S. H. Yueh, “Modeling of wind direction signals in polarimetric sea surface brightness<br />
temperatures,” IEEE Trans. Geosci. Remote Sensing, vol. 35, pp. 1400–1418, 1997.<br />
[7] D. B. Kunkee and A. J. Gasiewski, “Simulation of passive microwave wind direction<br />
signatures over the ocean using an asymmetric-wave geometrical optics model,” Radio Sci.,<br />
vol. 32, p. 59, 1997.<br />
[8] V. G. Irisov, “Small-slope expansion for thermal and reflected radiation from a rough<br />
surface,” Waves Random Media, vol. 7, pp. 1–10, 1997.<br />
[9] J. T. Johnson, ``A study of rough surface thermal emission and reflection using<br />
Voronovich's small slope approximation," IEEE Trans. Geosc. Rem. Sens., Feb 2005.<br />
[10] A. B. Isers, A. Puzenko, and I. M. Fuks, The local perturbation method for solving the<br />
problem of di_raction from a surface with small slope irregularities," J. Electromagn. Waves<br />
Appl., vol. 5, no. 12, 1991.<br />
[11] V. G. Irisov, “Microwave radiation from a weakly nongaussian surface,” in Proc.<br />
IGARSS’98 vol. 5, pp. 2329–2332.<br />
[12] J. P. Hollinger, Passive microwave measurements of sea surface roughness, IEEE Trans.<br />
Geosci. Electron., vol. GE-9, no. 3, pp. 165-169, 1971.<br />
[13] C. T. Swift, Microwave radiometer measurements of the Cape Cod Cannal, Radio Sci.,<br />
vol. 9, no. 7, pp. 641-653, 1976.<br />
[14] A. G. Voronovich, Wave Scattering from Rough Surfaces. Berlin, Germany: Springer-<br />
Verlag, 1994.<br />
[15] M. Zhang and J. T. Johnson, “Theoretical studies of ocean polarimetric brightness<br />
signatures,” in Proc. IGARSS’98, vol. 5, pp. 2333–2335.<br />
[16] J. T. Johnson and Y. Cai, ``A theoretical study of sea surface up/down wind brightness<br />
emperature differences,'' IEEE Trans. Geosc. Remote Sens, 2002.<br />
[17] J. T. Johnson, ``Comparison of the physical optics and small slope theories for<br />
polarimetric thermal emission from the sea surface,'' IEEE Trans. Geosc. Remote Sens, 2002.<br />
[18] M. Zhang and J. T. Johnson, ``Comparison of modeled and measured second azimuthal<br />
harmonics of ocean surface brightness temperatures," IEEE Trans. Geosc. Remote Sens,<br />
2001.