Add to ORKGWith the focus on the Southern Ocean, results of the assimilation of multi-mission-altimeter data and the GRACE/GOCE gravity data into a finite element ocean model are investigated. We use the geodetic method to obtain the dynamical ocean topography from only the satellite measurements and an ensemble Kalman filter approach for assimilation of this data set into the finite element ocean model. The data assimilation scheme corrects all the ocean fields, although only the geodetic DOT is assimilated. Properties of the data assimilation algorithm, particularly with respect to the resolution of the data, are discussed in detail. By assimilating only absolute dynamical topography data, we were able to improve the model fields. The results of the...
The altimetric satellite signal is the sum of the geoid and the dynamic topography, but only the lat...
We will use data from the GOCE satellite missions in order to determine structure and transport of t...
International audienceThe altimetric satellite signal is the sum of the geoid and the dynamic topogr...
With the focus on the Southern Ocean circulation, results of assimilation of multi-mission-altimeter...
Results of assimilation of multi‐mission‐altimeter data and the GRACE/GOCE gravity data into the fi...
We aim at the determination of the absolute, but temporally changing ocean circulation flow field a...
General ocean circulation models are not perfect. Forced with observed atmospheric fluxes they gradu...
The response of an eddy-permitting ocean model to changes imposed by the use of Q1 different mean dy...
We review the procedures and challenges that must be considered when using geoid data derived from t...
Presented here are three mean dynamic topography maps derived with different methodologies. The firs...
This study focuses on an estimation of ocean circulation via assimilationof satellite measurements o...
Absolute dynamic topography, i.e. the difference between time dependent multi-mission altimetric sea...
An eddy-permitting (44 km at 50°S) numerical model of the open ocean south of Australia is combined...
In anticipation of the future observations of the gravity mission Gravity Field and Steady-State Oce...
The altimetric satellite signal is the sum of the geoid and the dynamic topography, but only the lat...
We will use data from the GOCE satellite missions in order to determine structure and transport of t...
International audienceThe altimetric satellite signal is the sum of the geoid and the dynamic topogr...
With the focus on the Southern Ocean circulation, results of assimilation of multi-mission-altimeter...
Results of assimilation of multi‐mission‐altimeter data and the GRACE/GOCE gravity data into the fi...
We aim at the determination of the absolute, but temporally changing ocean circulation flow field a...
General ocean circulation models are not perfect. Forced with observed atmospheric fluxes they gradu...
The response of an eddy-permitting ocean model to changes imposed by the use of Q1 different mean dy...
We review the procedures and challenges that must be considered when using geoid data derived from t...
Presented here are three mean dynamic topography maps derived with different methodologies. The firs...
This study focuses on an estimation of ocean circulation via assimilationof satellite measurements o...
Absolute dynamic topography, i.e. the difference between time dependent multi-mission altimetric sea...
An eddy-permitting (44 km at 50°S) numerical model of the open ocean south of Australia is combined...
In anticipation of the future observations of the gravity mission Gravity Field and Steady-State Oce...
The altimetric satellite signal is the sum of the geoid and the dynamic topography, but only the lat...
We will use data from the GOCE satellite missions in order to determine structure and transport of t...
International audienceThe altimetric satellite signal is the sum of the geoid and the dynamic topogr...