Description
LST DSSF DSLF ALBEDO SC
Land Surface Temperature (15 mins)

Product Documentation
   Documents:
           (Product User Manual)
           (Product Output Format)
           (Validation Report)
           (Algorithm Theoretical Basis Document)
Introduction
Product Description
Algorithm Description
Data Characteristics
Product Uncertainties
References
Example of Product
User comments for this product
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Product Time Line Versions
  Year: 2014
Date:  
Vers:  
7.7
Today
Product Documentation
This product is operational status. It is documented in the Algorithm Theoretical Basis Document (ATBD) Product User Manual document (PUM) and the Product Output Format document (POF) The validation documentation for this product is available in the (VR) document.
 
Introduction
Land Surface Temperature (LST) is the radiative skin temperature over land. LST plays an important role in the physics of land surface as it is involved in the processes of energy and water exchange with the atmosphere. LST is useful for the scientific community, namely for those dealing with meteorological and climate models. Accurate values of LST are also of special interest in a wide range of areas related to land surface processes, including meteorology, hydrology, agrometeorology, climatology and environmental studies. Land Surface Emissivity (EM), a crucial parameter for LST retrieval from space, is independently estimated as a function of (satellite derived) Fraction of Vegetation Cover (FVC) and land cover classification.
 
Product Description
The retrieval of LST is based on clear-sky measurements from MSG system in the thermal infrared window (MSG/SEVIRI?channels IR10.8 and IR12.0). Theoretically, LST values can be determined 96 times per day from MSG but in practice less observations are available due to cloud cover. The identification of cloudy pixels is based on the cloud mask generated by the Nowcasting and Very Short Range Forecasting Satellite Application Facility (NWC SAF) software.
 
Algorithm Description
The Generalised Split-Window (GSW) algorithm (Wan and Dozier, 1996) was chosen to retrieve LST. The GSW performs corrections for atmospheric effects based on the differential absorption in adjacent IR bands and requires EM as input data; a look-up table of optimal coefficients is previously determined at individual classes of satellite viewing angles, and covering different ranges of water vapour and near-surface air temperature. The retrieval of EM is based on the Vegetation Cover Method (VCM; Caselles et al., 1997) that relies on the use of a geometrical model to compute an effective emissivity based on the knowledge of the Fractional Vegetation Cover (FVC), also retrieved by the LSA SAF.
 
Data Characteristics
The LST MSG product is computed within the area covered by the MSG disk, over 4 specific geographical regions (Europe, Africa - N_Africa and S_Africa- and South America), every 15 minutes. . For each time-slot and geographical region, the LST field and respective Quality Control (QC) data are disseminated in HDF5 format; the relevant information concerning the data fields is included in the HDF5 attributes.
 
Product Uncertainties
The quality of LST MSG product depends on sensor performance (stability of the spectral response function, signal-to-noise ratio, radiometric resolution and calibration accuracy), accuracy of cloudy pixels identification, accuracy of atmospheric corrections, and spectral variation in emissivities of different land-surface elements. The land surface heterogeneity and three-dimensional structure can produce significant variation in LST measurements as a function of view zenith angle. An automatic Quality Control (QC) is performed on LST data, and the quality information is provided on a pixel-by-pixel basis. The LST confidence level was defined based on the following parameters: viewing angle; atmospheric characteristics (i.e. surface temperature and column water vapour); EM confidence level. The three considered levels of confidence (above nominal, nominal and below nominal) correspond to estimated uncertainties of LST values (respectively less than 1K, between 1 and 2K and above 2K).
 
References

Caselles V., E. Valor, C. Coll and E. Rubio, 1997. ?Thermal band selection for the PRISM instrument 1.Analysis of emissivity-temperature separation algorithms?, J. Geophs. Res., 102, D10, 11145-11164.

Wan. Z., J. Dozier, 1996. ?A generalised split-window algorithm for retrieving land-surface temperature from space?, IEEE Trans. Geosci. Remote Sens., vol. 34 no. 34, pp. 892-905.


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