Les Vents de Surface Diffusiométriques

1. Atelier Moment Cinetique Paris 26 Novembre 2012 Les Vents de Surface Diffusiométriques

2. Atelier Moment Cinetique Paris 26 Novembre 2012 Les Vents de Surface Diffusiométriques • Bentamy, A., D. Croize-Fillon, and C. Perigaud, 2008: Characterization of ASCAT measurements based on buoy and QuikSCAT wind vector observations, Ocean Sci., 4, 265–274. • Bentamy, A.; D. Croize-Fillon, P. Queffeulou; C. Liu, H. Roquet, 2009: Evaluation of high-resolution surface wind products at global and regional scales. Journal of Operational Oceanography, vol. 2, 15-27(13). • Bentamy, A., S. A. Grodsky, J. A. Carton, D. Croizé-Fillon, and B. Chapron, 2012: Matching ASCAT and QuikSCAT Winds, J. Geoph. Res., doi:10.1029/2011JC007479 • Grodsky S. A., V. N. Kudryavtsev, A. Bentamy, J. A. Carton, and B. Chapron, 2012: Does direct impact of SST on short wind waves matter for scatterometry?, Geophys. Res. Letters, doi:10.1029/2012GL052091

3. Atelier Moment Cinetique Paris 26 Novembre 2012 Scatterometer measurement • Scatterometers are active microwave sensors: they send out a signal and measure how much of that signal returns after interacting with the target. Microwaves are Bragg scattered by short water waves; the fraction of energy returned to the satellite (backscatter) is a function of wind speed and wind direction. • The main scatterometer measurements are the backscatter coefficients calculated as a ratio between the emitted power Pe and the received one Pr :  : the wavelength, G the antenna gain, A the radar footprint, R the distance between the sensor and the reached target.

4. Atelier Moment Cinetique Paris 26 Novembre 2012 Scatterometer Calibration • Retrieving Surface Winds from Backscatter Coefficient Measurements is not Trivial • Calibration Procedure: Determination of Geophysical Model Function (GMF): • ° = f(U,, , P,fc, ….)

5. PORSEC 2012 Kochi Tutorial Scatterometer Geophysical Relationships GMF : Buoy Wind Speed Range 8m/s

6. PORSEC 2012 Kochi Tutorial Scatterometer Geophysical Relationships GMF : Buoy Wind Speed Range 3m/s

7. PORSEC 2012 Kochi Tutorial Scatterometer Geophysical Relationships GMF : Buoy Wind Speed Range 12m/s

8. Atelier Moment Cinetique Paris 26 Novembre 2012 ASCAT / QuikSCAT (Bentamy et al, 2011) • Study Period: April 2007 – November 2009 • Focus : November 2008 – November 2009 ASCAT • Data Source: OSI SAF / KNMI • Products: L1b & L2b 25 & L2b 12.5 • GMF : CMOD5 and CMOD5n • Wind retrieval: Selected solution • Data selection: • All WVC • Wind Speed : 0 – 50m/s • Wind direction : 0° – 360° • Quality flags QuikSCAT / QuikSCAT V3 • Data Source: PODAAC / JPL • Products: L1b & L2b 25 / L2b 12.5 • GMF : QSCAT-1/F13 / QuikSCAT (Ku2011)‏ • Wind retrieval: Selected solution • Data selection: • All WVC • Wind Speed : 0 – 50m/s • Wind direction : 0° – 360° • Quality flags / New Rain flags

9. Atelier Moment Cinetique Paris 26 Novembre 2012 Local Assessment for ASCAT/QSCAT Collocated Data • Comparisonswith NDBC buoyhourlymeasurements • Comparisons with NDBC buoy hourly measurements

10. Atelier Moment Cinetique Paris 26 Novembre 2012 Global Comparisons • Bias (top), STD (middle), and Correlation (bottom) of collocated QuikScat and ASCAT winds.

11. Atelier Moment Cinetique Paris 26 Novembre 2012 Analysis of ASCAT and QSCAT Differences • Wind speed difference. QuikSCAT rain flag and MRP<0.05 are applied • Wind speed difference after applying the correction function • Spatial distribution of the time mean • Histogram of wind speed difference before (gray bar) and after (empty bar) applying of dW

12. Atelier Moment Cinetique Paris 26 Novembre 2012 Mean Difference of Wind Speeds: QSCAT / ASCAT / ECMWF / ERA Interim ECMWF ERAI QSCAT ASCAT

13. Atelier Moment Cinetique Paris 26 Novembre 2012 Mean Difference of Wind Components : QSCAT / ASCAT / ECMWF Zonal Meridional | QSCAT | - | ASCAT | | QSCAT | - | ECMWF | | ASCAT | - | ECMWF |

14. Atelier Moment Cinetique Paris 26 Novembre 2012 Mean Difference of Wind Components: QSCAT / ASCAT / ERA Interim Zonal Meridional |QSCAT| - | ASCAT | | QSCAT | - | ERAI | | ASCAT | - | ERAI |

15. Atelier Moment Cinetique Paris 26 Novembre 2012 Zonal Means of Wind Components Within 3 degree of 140°W

16. High Wind Field Spatial and Temporal Resolution Atelier Moment Cinetique Paris 26 Novembre 2012 QuikSCAT E.U. MyOcean-1/2 Projects METOP SSMI Objectives • Estimation of high spatial and temporal resolution of surface wind fields (wind vector and wind stress) using ECMWF Numerical Weather analysis outputs with high remotely sensed surface parameters. • Set-up and carry-out a demonstration experiment, to produce in near real-timemerged wind fields : 6-hourly, 0.25° x 0.25° • Assess the quality of derived blended wind fields at near shore and offshore areas. SSMI TMI SSMI Jason AMSR-E Operational ECMWF Analysis 16

17. Objective Method Atelier Moment Cinetique Paris 26 Novembre 2012 • Objective Method : External Drift • Wind Observations (U) are from NRT Scatterometer and SSM/I • External Data (S) are from ECMWF analysis. • Assumption : E(U(X,t)) = a + b*S(X,t) • The space and time correlation is parameterized by 17

18. Blended Surface Wind Fields Atelier Moment Cinetique Paris 26 Novembre 2012 • Method : Objective OI (Bentamy et al, 2007; 2009) May 4th 2008. 00h:00 Results : 6-hourly global wind vector 0.25°×0.25° May 4th 2008. 06h:00 AMS Conference 20 - 24 August 2007 Portland 18

19. Atelier Moment Cinetique Paris 26 Novembre 2012 Evaluation Versus QuikSCAT (off-line) Wind ObservationsJanuary 2005 (Bentamy et al, 2009) QuikSCAT – Blended Bias Rms QuikSCAT – ECMWF Bias Rms W U V