[1] Currently, two satellite gravimetric missions (CHAMP, GRACE) are dedicated to the improvement of our knowledge of the geoid, and one (GOCE) is planned in the near future. This will allow the absolute altimeter ocean height measurements to be exploited, instead of only sea level variations. In this paper, we evaluate the impact of the GRACE mission on ocean data assimilation. The new approach is to directly assimilate the full altimetric signal relative to the first release of a GRACE geoid. The response of an eddy-permitting ocean model of the North Atlantic to the assimilation of this altimetric signal is analysed. The results are compared to that obtained using the usual approach, i.e., the assimilation of the dynamic topography deriv...
Recently released global gravity field models generated solely from CHAMP and GRACE satellite observ...
This chapter outlines satellite altimetry: the mean geoid and the mass component of sea level, or oc...
Recent advances in our knowledge of the earth geoid have made it possible to exploit absolute sea su...
Currently, two satellite gravimetric missions (CHAMP, GRACE) are dedicated to the improvement of our...
The availability of gravity data from recent satellite missions (CHAMP, GRACE) and the future GOCE m...
International audienceThe altimetric satellite signal is the sum of the geoid and the dynamic topogr...
The altimetric satellite signal is the sum of the geoid and the dynamic topography, but only the lat...
International audienceWe review the procedures and challenges that must be considered when using geo...
With the focus on the Southern Ocean circulation, results of assimilation of multi-mission-altimeter...
Recent advances in our knowledge of the earth geoid have made it possible to exploit absolute sea su...
[1] We discuss the ocean circulation derived from the temporally averaged sea surface height, which ...
Sea level rises and falls as the temperature and salinity of the water column varies, which is known...
The objective of this work is to evaluate the contribution of a Mean Dynamic Topography (MDT) deduce...
The impact of assimilating global ocean bottom pressure (OBP) information from the Gravity Recovery ...
Recently released global gravity field models generated solely from CHAMP and GRACE satellite observ...
This chapter outlines satellite altimetry: the mean geoid and the mass component of sea level, or oc...
Recent advances in our knowledge of the earth geoid have made it possible to exploit absolute sea su...
Currently, two satellite gravimetric missions (CHAMP, GRACE) are dedicated to the improvement of our...
The availability of gravity data from recent satellite missions (CHAMP, GRACE) and the future GOCE m...
International audienceThe altimetric satellite signal is the sum of the geoid and the dynamic topogr...
The altimetric satellite signal is the sum of the geoid and the dynamic topography, but only the lat...
International audienceWe review the procedures and challenges that must be considered when using geo...
With the focus on the Southern Ocean circulation, results of assimilation of multi-mission-altimeter...
Recent advances in our knowledge of the earth geoid have made it possible to exploit absolute sea su...
[1] We discuss the ocean circulation derived from the temporally averaged sea surface height, which ...
Sea level rises and falls as the temperature and salinity of the water column varies, which is known...
The objective of this work is to evaluate the contribution of a Mean Dynamic Topography (MDT) deduce...
The impact of assimilating global ocean bottom pressure (OBP) information from the Gravity Recovery ...
Recently released global gravity field models generated solely from CHAMP and GRACE satellite observ...
This chapter outlines satellite altimetry: the mean geoid and the mass component of sea level, or oc...
Recent advances in our knowledge of the earth geoid have made it possible to exploit absolute sea su...
Add to ORKG