Gravity, Geoid and Height Systems

Part I Gravimetry and Gravity Networks.- 1. Towards the establishment of new gravity control in Poland.- 2. Testing the suitability of the A10-020 absolute gravimeter for the establishment of new gravity control in Poland.- Part II Global Gravity Field Modeling, Assessments and Applications.- 3. GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach.- 4. Use of high performance computing for the rigorous estimation of very high degree spherical harmonic gravity field models.- 5. Time variable gravity: Contributions of GOCE satellite data to monthly and bi-monthly GRACE gravity field estimates.- 6. Application of Wavelets for Along-Track Multi-Resolution Analysis of GOCE SGG Data.- 7. Assessment of high-resolution global gravity field models and their application in quasigeoid modelling in Finland.- 8. Comparison of GOCE global gravity field models to te st fields in southern Norway.- 9. Evaluation of Recent GRACE and GOCE Satellite Gravity Models and Combined Models Using GPS/Leveling and Gravity Data in China. -10. Evaluation of GOCE/GRACE derived Global Geopotential Models over Argentina with collocated GPS/Levelling observations.- 11. Evaluation of GOCE/GRACE Global Geopotential Models over Greece with collocated GPS/Levelling observations and local gravity data.- 12. Evaluation of the GOCE-based Gravity Field Models in Turkey.- 13. A Stokesian approach for the comparative analysis of satellite gravity models and terrestrial gravity data.- Part III : Future Gravity Field Missions.- 14. New approach to estimate time variable gravity fields from high-low satellite tracking data.- 15. Status of the GRACE Follow-on Mission.- 16. Feasibility Study of a Future Satellite Gravity Mission using GEO-LEO Line-of-Sight Observations.- Part IV: Advances in Precise Local and Regional High-Resolution Geoid Modeling.- 17. GOCE data for l ocal geoid enhancement.- 18. Investigation of gravity data requirem nts for a 5 mm-quasigeoid model over Sweden.- 19. Consistent combination of satellite and terrestrial gravity field observations in regional geoid modeling a case study for Austria.- 20. Modelling the influence of terraced landforms to the Earth's gravity field.- 21. Accurate Geoid Height Differences Computation from GNSS Data and Modern Astrogeodetic Observation.- 22. Improving the Swedish quasigeoid by gravity observations on the ice of Lake Vän.- 23. Geoid Model and Altitude at Mount Aconcagua Region (Argentina) from Airborne Gravity Survey.- 24. HRG2009 - New high resolution geoid model for Croatia.- 25. Validation of Regional Geoid Models for Saudi Arabia usingGPS/Levelling Data and GOCE Models.- Part V : Establishment and Unification of Vertical Reference Systems.- 26. W0 estimates in the frame of the GGOS Working Group on Vertical Datum Standardisation.- 27. Realization of WHS based on the static gravity field observed by GOCE.- 28. First Results on Height Sys tem Unification in North America Using GOCE.- 29. Using GOCE to straighten and sew European local geoids: preliminary study and first results.- 30. Combination of geometric and orthometric heights in the presence of geoid and quasi-geoid models.- 31. Contribution of Tide Gauges for the Determination of W0 in Canada.- 31. Estimation of the reference geopotential value for the local vertical datum of continental Greece using EGM08 and GPS/leveling data.- 32. Tidal Systems and Reductions for Improvement of the Bulgarian National Vertical Reference System.- Part VI : Gravity Field and Mass Transport Modeling.- 33. Consistent Combination of Gravity Field, Altimetry and Hydrographic Data.- 34. Local hydrological effects on gravity at Metsähovi, Finland: implications for comparing observations by the superconducting gravimeter with global hydrological models and with GRACE.- 35. Global groundwater cycles and extreme events responses observed by satellite gravimetry.- Part VII : Mo deling and Inversion of Gravity-SolidEarth Coupling.- 36. Sensitiv ty of GOCE gravity gradients to crustal thickness and density variations - Case study for the Northeast Atlantic Region.- 37. Detecting the elevated crust to mantle section in the Kohistan-Ladakh Arc, Himalaya, from GOCE observations.- 38. Daniele Tenze, Carla Braitenberg, Eva Sincich, Patrizia Mariani.- 39. A grip on geological units with GOCE.- 40.- Basement structure of the Santos Basin from Gravity data.- Part VIII : Gravity Field of Planetary Bodies.- 41. Observing the gravity field of different planets and moons by space-borne techniques: predictions by fast error propagation tools.- 42. Sensitivity of simulated LRO tracking data to the lunar gravity field.