SMOS L2 OS ATBD - ARGANS

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79 ICM-CSIC LOCEAN/SA/CETP IFREMER SMOS L2 OS Algorithm Theoretical Baseline Document Doc: SO-TN-ARG-GS-0007 Issue: 3 Rev: 9 Date: 25 January 2013 Page: 79 Finally, it should be noted, as discussed in the section describing the theoretical model, that there may be a dependence of the roughness emission on relative angle between emission direction and wind direction, but we have not been able to see a consistent azimuthal signal in the SMOS data as of this writing, and so we current set all azimuthal harmonic coefficients to zero identically. 4.3.2.2. Quality control and diagnostics As explained in section 4.3.3 below, the SSA/SPM model is not expected to provide correct results for wind seas generated by winds less than about 2 m/s and larger than 15 m/s . This corresponds roughly to wind friction velocity u* less than 0.6 cm/s and larger than 0.5 m/s. The model can be applied as it is at launch for conditions out of this range however, we expect that the CAL/VAL activities will provide after commissioning phase a variability estimate at low winds and a residual foam impact at high winds which will be used to correctly tune the model. 4.3.2.3. Exception handling There is no particular exception handling in the mathematical algorithm except if the following auxiliary data are not provided by the processor or exceed the ranges anticipated: the neutral equaivalent wind speed [m/s], (which can be estimated fromthe wind speed magnitude at 10 meter height, the roughness length, and the auxiliary parameter “Coefficient of drag with waves Cd “defined by : u*= Cd U10 ) the inverse wave age parameter for the wind sea (which can be deduced from 2U 10 estimates of both U 10 and the mean period of wind waves Tp: ), gT the incidence angles i at SMOS pixel, the sea surface temperature Ts, the prior sea surface salinity SSS, and, the azimuth angle at SMOS pixel relative to wind direction i . If one of the prior values of the retrieved geophysical parameters is out of the LUT range, or if any retrieved geophysical parameter goes out of LUT range during the retrieval, different flags (Fg_OoR_Rough_dim1, Fg_OoR_Rough_dim2, Fg_OoR_Rough_dim3, Fg_OoR_Rough_dim4, Fg_OoR_Rough_dim5) are raised. No extrapolation is done and the boundary value is taken. 4.3.3. Assumption and limitations As discussed above, the empirical model described above is expected to fail in strong storm and frontal conditions (strong wave-wave, wave-current or wind-wave interaction conditions). Furthermore, we do not expect the model to perform well in presence of either strong swells, strong currents, very small and unsteady winds where the link between surface p
80 ICM-CSIC LOCEAN/SA/CETP IFREMER SMOS L2 OS Algorithm Theoretical Baseline Document Doc: SO-TN-ARG-GS-0007 Issue: 3 Rev: 9 Date: 25 January 2013 Page: 80 roughness and wind speed is not direct. We expect however that accounting for the impact of waves on the drag coefficients will better characterize impact of these parameters on roughness. References [1] S. H. Yueh, R. Kwok, F. K. Li, S. V. Nghiem, and W. J. Wilson, “Polarimetric passive remote sensing of ocean wind vectors,” Radio Sci., vol. 29, pp. 799–814, 1994. [2] L. Tsang, J. A. Kong, and R. T. Shin, Theory of Microwave Remote Sensing. New York: Wiley, 1985. [3] G. S. E. Lagerloef, C. T. Swift, and David M. Le Vine, Sea surface salinity : The next remote sensing challenge, Oceanography, vol. 8, no. 2, pp. 44-49, 1995. [4] S. H. Yueh, R. West, W. J. Wilson, Fuk K. Li, E. G. Njoku, and Y. Rahmat-Samii, Error sources and feasibility for microwave remote sensing of ocean surface salinity, IEEE Trans. Geosci. and Remote Sens., vol. 39, no. 5, pp. 1049-1060, 2001. [5] E. P. Dinnat, J. Boutin, G. Caudal, J. Etcheto, and A. Camps, Issues concerning the sea emissivity modeling in L-band for retrieving surface salinity, Radio Sci., vol. 38, no. 4, 2003. [6] S. H. Yueh, “Modeling of wind direction signals in polarimetric sea surface brightness temperatures,” IEEE Trans. Geosci. Remote Sensing, vol. 35, pp. 1400–1418, 1997. [7] D. B. Kunkee and A. J. Gasiewski, “Simulation of passive microwave wind direction signatures over the ocean using an asymmetric-wave geometrical optics model,” Radio Sci., vol. 32, p. 59, 1997. [8] V. G. Irisov, “Small-slope expansion for thermal and reflected radiation from a rough surface,” Waves Random Media, vol. 7, pp. 1–10, 1997. [9] J. T. Johnson, ``A study of rough surface thermal emission and reflection using Voronovich's small slope approximation," IEEE Trans. Geosc. Rem. Sens., Feb 2005. [10] A. B. Isers, A. Puzenko, and I. M. Fuks, The local perturbation method for solving the problem of di_raction from a surface with small slope irregularities," J. Electromagn. Waves Appl., vol. 5, no. 12, 1991. [11] V. G. Irisov, “Microwave radiation from a weakly nongaussian surface,” in Proc. IGARSS’98 vol. 5, pp. 2329–2332. [12] J. P. Hollinger, Passive microwave measurements of sea surface roughness, IEEE Trans. Geosci. Electron., vol. GE-9, no. 3, pp. 165-169, 1971. [13] C. T. Swift, Microwave radiometer measurements of the Cape Cod Cannal, Radio Sci., vol. 9, no. 7, pp. 641-653, 1976. [14] A. G. Voronovich, Wave Scattering from Rough Surfaces. Berlin, Germany: Springer- Verlag, 1994. [15] M. Zhang and J. T. Johnson, “Theoretical studies of ocean polarimetric brightness signatures,” in Proc. IGARSS’98, vol. 5, pp. 2333–2335. [16] J. T. Johnson and Y. Cai, ``A theoretical study of sea surface up/down wind brightness emperature differences,'' IEEE Trans. Geosc. Remote Sens, 2002. [17] J. T. Johnson, ``Comparison of the physical optics and small slope theories for polarimetric thermal emission from the sea surface,'' IEEE Trans. Geosc. Remote Sens, 2002. [18] M. Zhang and J. T. Johnson, ``Comparison of modeled and measured second azimuthal harmonics of ocean surface brightness temperatures," IEEE Trans. Geosc. Remote Sens, 2001.
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