GOCE Gravity Gradients in Instrument and Terrestrial Frames

1. GOCE Gravity Gradients in Instrument and Terrestrial Frames J. Bouman, Th. Gruber, S. Rispens, E. Schrama, C.C. Tscherning, M.Veicherts, P. Visser

2. This presentation • Analysis of GOCE gravity gradients • Instrument and Earth related frames • Data: 31 October 2009 – 11 January 2010 • First GOCE gravity field solutions use same data period (next three presentations)

3. Frame trafo EGG_TRF_2 Temporal corrections EGG_NOM_2 Outliers, data gaps External calibration Gravity Gradient Preprocessing

4. EGG_NOM_2 & EGG_TRF_2 • EGG_NOM_2: • Given in instrument frame (GRF) • Accurate: VXX, VYY, VZZ, VXZ; less accurate: VXY, VYZ • Error increase at long wavelengths • Used in gravity field recovery • EGG_TRF_2: • Given in Local North-Oriented Frame • GGs VXY, VYZ: GOCE gravity model • Long wavelength GG signal: GOCE gravity model • GG error expected to be more homogeneous

5. EGG_NOM_2 & EGG_TRF_2 • EGG_NOM_2: • Given in instrument frame (GRF) • Accurate: VXX, VYY, VZZ, VXZ; less accurate: VXY, VYZ • Error increase at long wavelengths • EGG_TRF_2: • Given in Local North-Oriented Frame • GGs VXY, VYZ: GOCE gravity model • Long wavelength GG signal: GOCE gravity model • GG error expected to be more homogeneous

6. EGG_NOM_2:3 revolutions November 1, 2009

7. Temporal gravity field variations VZZtime series, 1 day SD VZZ, 1 day  SDs VZZtemporal corrections, 1 day 

8. External calibration • Three methods for GG calibration: • Global gravity field models • GOCE GPS data • Terrestrial gravity data • GG scale factors 10-2 – 10-3 • See Poster 014-D3:External Calibration of the GOCE Gravity Gradients at the High-Level Processing Facility (Wednesday)

9. Estimated GG error SDsVXX, VYY, VZZ • GOCE QL gravity model: • GGs and GPS tracking • Data from November and December 2009 • SH degree 200 • Error assessment usingGG residuals Measurement Band (MB) (Pail & Mayrhofer 2010) • VXX and VYY same noise level in MB, VZZ 2x larger • Noise reduction in upper MB is “work in progress” (see Fehringeret al, Floberghagen, this morning)

10. EGG_NOM_2 & EGG_TRF_2 • EGG_NOM_2: • Given in instrument frame (GRF) • Accurate: VXX, VYY, VZZ, VXZ; less accurate: VXY, VYZ • Error increase at long wavelengths • EGG_TRF_2: • Given in Local North-Oriented Frame • GGs VXY, VYZ: GOCE QL gravity field model • Long wavelength GG signal: GOCE gravity model • GG error expected to be more homogeneous

11. EGG_NOM_2 & EGG_TRF_2:3 revolutions November 1, 2009 EGG_NOM_2 EGG_TRF_2

12. EGG_TRF_2: VXX GOCE - EIGEN5C (N=360) Binned averages31 October 2009 - 11 January 2010 Color scale: -15 mE to +15 mE GOCE - EGM2008 (N=360)Binned averages 31 October 2009 - 11 January 2010

13. EGG_TRF_2: VYY GOCE - EIGEN5C (N=360) Binned averages31 October 2009 - 11 January 2010 Color scale: -15 mE to +15 mE GOCE - EGM2008 (N=360)Binned averages 31 October 2009 - 11 January 2010

14. EGG_TRF_2: VZZ GOCE - EIGEN5C (N=360) Binned averages31 October 2009 - 11 January 2010 Color scale: -15 mE to +15 mE GOCE - EGM2008 (N=360)Binned averages 31 October 2009 - 11 January 2010

15. GOCE gravity gradients in GRF and LNOF (EGG_NOM_2 & EGG_TRF_2) November 2009 – January 2010 timeframe Differences with EIGEN5C & EGM2008(Africa, Himalaya, …) Error level VZZ about 2x that of VXX, VYY in MB Spurious tracks VYY close to magnetic poles: Not well understood Very likely related to interaction between attitude control and magnetic field Seems to diminish after in-flight calibration 11/12 January 2010 Overall, GG data look very good Summary