Satellite Retrieval of Downwelling Shortwave Surface Flux and Diffuse Fraction under All Sky Conditions in the Framework of the LSA SAF Program (Part 1: Methodology)
Abstract
:1. Introduction
2. Method
2.1. Definition of Retrieved Quantities
2.1.1. Downwelling Surface Shortwave Radiation
2.1.2. Diffuse Fraction
2.1.3. Equivalent Aerosol Optical Depth at 550 nm
2.1.4. Opacity Index
2.2. Overview of the Retrieval Method
3. Input Data
3.1. TOA Data
3.1.1. Satellite TOA Radiance
3.1.2. TOA Incoming Sun Radiation
3.2. Surface Characteristics
3.2.1. Digital Elevation Models
3.2.2. Land Surface Albedo
3.3. Atmospheric Characteristics
3.3.1. Cloudiness
3.3.2. H2O and O3 Columnar Content Modeling
3.3.3. Aerosol Optical Depth and Speciation
3.3.4. Aerosol Optical Properties (Look Up Table)
3.4. Summary of the Input Data
4. Algorithm Description
4.1. Diffuse and Direct Transmittance Contributions of the Individual Atmospheric Components
4.1.1. Gas Transmittances
4.1.2. Rayleigh Direct and Diffuse Transmittances
4.1.3. Aerosols Transmittances and Spherical Albedos
4.1.4. Total Cloud-Free Atmospheric Transmittance
4.1.5. Total Cloudy-Sky Atmospheric Transmittance
4.2. Algorithm Description: Clear-Sky Case
4.2.1. Description
4.2.2. Total DSSF for Clear-Sky Case
4.2.3. Equivalent AOD, Diffuse Fraction and Opacity Index for Clear-Sky Case
4.3. Algorithm Description: Cloudy-Sky Case
4.3.1. Description
4.3.2. Total DSSF in Cloudy Conditions
4.3.3. Equivalent AOD, Diffuse Fraction and Opacity Index for Cloudy Case
5. Results
5.1. Overview of the Output Variables
- total DSSF, named ‘DSSF_TOT’ in the MDSSFTD product;
- diffuse DSSF fraction, named ‘FRACTION_DIFFUSE’;
- equivalent spectral AOD at 550 nm for the current aerosol load, named ‘AOD’;
- the opacity of the atmosphere, named ‘OPACITY_INDEX’;
- processing quality flags, named ‘Q_FLAG’.
5.2. Comparison with the Previous LSA SAF DSSF Product Version
5.3. Known Issues and Limitations
5.4. Access to the Code Sources and Data Policy
6. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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INSO | WASO | SOOT | SSALL | MIALL | |
---|---|---|---|---|---|
Type of particles | Insoluble | Water-soluble | Soot | Sea Salt | Mineral Dust |
at 500 nm | 0.72 | 0.98 | 0.23 | 1.0 | 0.83 |
hygroscopic | No | yes | No | Yes | No |
Input Category | Input Description and Source | Clear-Sky Method | Cloudy-Sky Method |
---|---|---|---|
Atmosphere | MSG SEVIRI TOA radiances | - | X |
Geometry | Solar zenith angle (MSG ancillary data) | X | X |
Atmosphere | Cloud mask (NWC SAF) | X | X |
Atmosphere | GADS aerosols components database [52] | X | X |
Atmosphere | Atmospheric forecasts of O3 and H2O gases content from CAMS/ECMWF, interpolated to SEVIRI grid and to 15-min resolution | X | X |
Atmosphere | Atmospheric forecasts of AOD per aerosol type, from CAMS/ECMWF, interpolated to SEVIRI grid | X | X |
Surface | MSG Shortwave Daily Land Surface Albedos (MDAL, LSA SAF) | X | X |
Surface | USGS DEM interpolated to SEVIRI resolution and atmospheric fields DEM interpolated to SEVIRI resolution | X | X |
Atmosphere | Aerosol Optical Properties LUT (SIRAMix) | X | X |
Gases | |||||
---|---|---|---|---|---|
H2O | 3.0140 | 119.300 | 0.6440 | 5.8140 | Variable (see Section 3.3.2) |
O3 | 0.2554 | 6107.26 | 0.2040 | 0.4710 | Variable (see Section 3.3.2) |
CO2 | 0.0721 | 377.890 | 0.5855 | 3.1709 | 350 |
CO | 0.0062 | 243.670 | 0.4246 | 1.7222 | 0.075 |
N2O | 0.0326 | 107.413 | 0.5501 | 0.9093 | 0.28 |
CH4 | 0.0192 | 166.095 | 0.4221 | 0.7186 | 1.60 |
O2 | 0.0003 | 476.934 | 0.4892 | 0.1261 | 2.095 × 105 |
GADS Aerosol Components | INSO | WASO | SOOT | SSALL | MIALL |
---|---|---|---|---|---|
Z (km) | 8 | 8 | 8 | 1 | 2 |
HTOL (Km) | 2 | 2 | 2 | 2 | 6 |
GADS Aerosol Components | INSO | WASO | SOOT | SSALL | MIALL |
---|---|---|---|---|---|
α | 0.002 | 0.057 | 0.047 | 0.009 | 0.002 |
β | 1.022 | 0.646 | 0.711 | 0.961 | 0.977 |
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Carrer, D.; Ceamanos, X.; Moparthy, S.; Vincent, C.; C. Freitas, S.; Trigo, I.F. Satellite Retrieval of Downwelling Shortwave Surface Flux and Diffuse Fraction under All Sky Conditions in the Framework of the LSA SAF Program (Part 1: Methodology). Remote Sens. 2019, 11, 2532. https://doi.org/10.3390/rs11212532
Carrer D, Ceamanos X, Moparthy S, Vincent C, C. Freitas S, Trigo IF. Satellite Retrieval of Downwelling Shortwave Surface Flux and Diffuse Fraction under All Sky Conditions in the Framework of the LSA SAF Program (Part 1: Methodology). Remote Sensing. 2019; 11(21):2532. https://doi.org/10.3390/rs11212532
Chicago/Turabian StyleCarrer, Dominique, Xavier Ceamanos, Suman Moparthy, Chloé Vincent, Sandra C. Freitas, and Isabel F. Trigo. 2019. "Satellite Retrieval of Downwelling Shortwave Surface Flux and Diffuse Fraction under All Sky Conditions in the Framework of the LSA SAF Program (Part 1: Methodology)" Remote Sensing 11, no. 21: 2532. https://doi.org/10.3390/rs11212532
APA StyleCarrer, D., Ceamanos, X., Moparthy, S., Vincent, C., C. Freitas, S., & Trigo, I. F. (2019). Satellite Retrieval of Downwelling Shortwave Surface Flux and Diffuse Fraction under All Sky Conditions in the Framework of the LSA SAF Program (Part 1: Methodology). Remote Sensing, 11(21), 2532. https://doi.org/10.3390/rs11212532