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Vicarious calibration by liquid cloud target
Japan Meteorological Agency Meteorological Satellite Center Arata OKUYAMA Prepared for 23 March 2011 GSICS meeting in Daejeon, Korea
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Approach and error budget
Application to other satellites and its validation Calibration monitoring Web page
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Calibration Methodology
Vicarious calibration Rebuild visible calibration table, Based on comparison of observation with simulation. Radiative transfer calculation To make simulation accurately, RT calculation is done on temporally and spatially stable area = Reference target The reference target should be over wide range of brightness to obtain reliable regression line. Cloud-free ocean : Dark target Cloud-free land : Medium brightness target Uniform liquid cloud top : Bright site (Deep convective cloud top : Brightest site) Observed Calculated Liquid cloud
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for liquid cloud target
Necessary data for liquid cloud target Tools RT model (RSTAR) Cloud property retrieval tool (CAPCOM) Input factors to RT model Sun and satellite geometry Atmospheric profile WV, Pressure, Temperature (JRA-25 or JCDAS) Ozone (TOMS) Surface condition Sea surface wind speed (JRA-25 or JCDAS) Scattering particle Cloud (retrieved from MODIS L1B) Error amounts for each factor are estimated, and summed up. 4
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Error budget for liquid cloud target
Random error Systematic error Spectral response function (MODIS and MTSAT) Stratospheric aerosol Factor RTM input parameter Typical uncertainty Radiance uncertainty [%] Solar and sensor geometry Sat zenith angle 0.2 deg 0.2 Solar zenith angle ~ 0 deg ~ 0 Relative azimuth angle Atmospheric profile Ozone 2 % 0.1 Water vapor Assumed 30 % Surface Sea surface wind speed Cloud parameters Optical thickness 8% 3.8 Effective radius 4% Total RSS MODIS L1B
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Systematic error ? Calibration coefficients based on two MODISs
MTSAT-2 Calibration coefficients by MODISs Calibration coefficients based on Aqua/MODIS and Terra/MODIS are not same. It means that cloud optical parameter retrieved from Terra or Aqua MODIS L1B contains systematic error. Dave pointed out Terra/MODIS has degradation trend relative to Aqua/MODIS. (on Dec GSICS Web meeting) slope intercept 2010 2011
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Validation by aerosol product Aqua vs Terra
Comparison of satellite retrieved aerosol with ground observation Calibrate satellite data using Terra/MODIS or Aqua/MODIS Retrieve aerosol optical thickness (AOD) from calibrated data Compare AOD with ground observation data Calibrated data based on Aqua/MODIS seems to be better than the one based on Terra/MODIS. It means calibration coefficients based on Terra/MODIS have some systematic error. But it is difficult to estimate the error amount. Based on Terra Based on Aqua Ground obs. Sat RMS 2010 Jul.-Aug.-Sep. Terra : 0.960 Aqua : 0.851
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Approach and error budget
Application to other satellites and its validation Calibration monitoring Web page
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Application to GOES and METEOSAT
GOES and METEOSAT data in 2002 is calibrated by this approach. The approach seems to work fine. September 2002 GOES-8 GOES-10 METEOSAT-5 Radiance(W/m2/sr/um) METEOSAT-7 DN 9 Collaborate research of Chiba University and JMA/MSC
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Retrieved downward SW flux at ground surface
2002/09/ Averaged Downward SW flux at ground surface Downward SW flux at the surface METEOSAT-7 METEOSAT-5 GMS-5 GOES-10 GOES-8 0 deg. 63 deg. 140 deg. 225 deg. 285 deg. EXAM SYSTEM [Takenaka et al., 2011, JGR-atmosphere] 10
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Validation of the flux by BSRN and SKYNET
METEOSAT-7(322.5E-31.5E) METEOSAT-5(31.5E-101.5E) GMS5(101.5E-182.5E) GOES-8(225E-345E) GOES-10(165E-285E)
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Approach and error budget
Application to other satellites and its validation Calibration monitoring Web page
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MTSAT-2 Calibration Monitoring page
Renewed in July 2010 Click logo MTSAT-2 IR opened in July 2010 Jump to GSICS Portal (WMO) MTSAT-2 VIS opened in Sep. 2010
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MTSAT-2 IR Calibration Monitoring page
Regression Coefficients of MTSAT Digital Counts as a function of Hyper Sounder Radiances Intercept Slope
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MTSAT-2 IR Calibration Monitoring page
TB Difference at Standard Radiance Introduced GSICS Correction (Re-Analysis Corr.) 30-day Moving Ave. Introduced
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MTSAT-2 Visible Calibration Monitoring page
Monthly statistics and time sequences Scatter plot Regression Coefficients
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MTSAT-2 Visible Calibration Monitoring page
JMA GSICS Top Page Guide Scatter plot Regression Coefficients (Time Series) 17
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Summary Error budget for the liquid cloud target is estimated.
Terra/MODIS based calibration coefficients seems to have bias. It is important to estimate systematic error amount. Vicarious calibration approach is applied to GOES and METEOSAT. The result is verified through the solar flux product as an example of validation. Calibration monitoring Web site is available on
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Thank you !
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Comments If we utilize different types of targets, how to determine weight ? If simulations on each target have different systematic error, how combine them ? How to validate calibration coefficients ? Are update of the coefficients necessary ?
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Consistency check of the approach
The radiance simulation approach is evaluated by using MODIS data. MODIS carries onboard calibrators for visible bands and it is well-calibrated. Its observations are reliable. Computation and observation show good consistency RMSE is around 1% MODIS Radiance comparison Liquid Cloud MODIS L1B Aerosol Cloud Sim. Radiance retrieve RT calc compare Atmos. prof. Simulated radiance Cloud-free Land Cloud-free Sea 23 MODIS L1B (Band-1) 23
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