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ENVISAT Land Surface ProcessesThis is a progress report of the 2nd phase of the project ENVISAT- Land Surface Processes, which has a 3-year scope. In this project, preparative research is carried out aiming at the retrieval of land surface characteristics from the ENVISAT sensors MERIS and AATSR, for assimilation into a system for Numerical Weather Prediction (NWP). Where in the 1st phase a number of first shot experiments were carried out (aiming at gaining experience with the retrievals and data assimilation procedures), the current 2nd phase has put more emphasis on the assessment and improvement of the quality of the retrieved products. The forthcoming phase will be devoted mainly to the data assimilation experiments and the assessment of the added value of the future ENVISAT products for NWP forecast skill. Referring to the retrieval of albedo, leaf area index and atmospheric corrections, preliminary radiative transfer calculations have been carried out that should enable the retrieval of these parameters once AATSR and MERIS data become available. However, much of this work is still to be carried out. An essential part of work in this area is the design and implementation of software that enables an efficient use of MODTRAN(sub 4) radiative transfer code, and during the current project phase familiarization with these new components has been achieved. Significant progress has been made with the retrieval of component temperatures from directional ATSR-images, and the calculation of surface turbulent heat fluxes from these data. The impact of vegetation cover on the retrieved component temperatures appears manageable, and preliminary comparison of foliage temperature to air temperatures were encouraging. The calculation of surface fluxes using the SEBI concept,which includes a detailed model of the surface roughness ratio, appeared to give results that were in reasonable agreement with local measurements with scintillometer devices. The specification of the atmospheric boundary conditions appears a crucial component, and the use of first guess estimates from the RACMO models partially explains the success. Earlier data assimilation experiments with directional surface temperatures have been analysed a bit further and were also compared to results obtained from directly modeling the surface roughness ratio. Results between these calculations and the data assimilation results appeared well comparable, but a full test in which the surface roughness model is allowed to play a free role during the data assimilation process has yet to be carried out. A considerable number of tasks that have yet to be carried out during Phase 3 has been formulated.
Document ID
Document Type
vandenHurk, B. J. J. M. (Royal Netherlands Meteorological Inst. De Bilt, Netherlands)
Su, Z. (Alterra Wageningen, Netherlands)
Verhoef, W. (National Aerospace Lab. Marknesse, Netherlands)
Menenti, M. (Pasteur (Louis) Univ. Illkrich, France)
Li, Z.-L. (Pasteur (Louis) Univ. Illkrich, France)
Wan, Z. (California Univ. Santa Barbara, CA, United States)
Moene, A. F. (Wageningen Univ. Wageningen, Netherlands)
Roerink, G.
Jia, I.
Date Acquired
August 21, 2013
Publication Date
January 1, 2002
Publication Information
ISSN: 0169-1651
ISBN: 0169-1651
Subject Category
Instrumentation and Photography
Report/Patent Number
Funding Number(s)
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