Abstract's details
Impact of the assimilation of high-frequency data in a regional model with high resolution
CoAuthors
Event: 2017 Ocean Surface Topography Science Team Meeting
Session: Science III: Mesoscale and sub-mesoscale oceanography
Presentation type: Type Poster
Contribution: not provided
Abstract:
Impact of the assimilation of high-frequency data in a regional model with high resolution
Mounir Benkiran, Elisabeth Rémy and Guillaume Reffray
MERCATOR Ocean 8-10 Rue Hermes 31526 Ramonville St Agne Cedex
Abstract
Mercator-Ocean has developed a regional forecasting system at 1/36° (~3km) resolution over the North East Atlantic (IBI: Iberia, Biscay and Irish), taking advantage of the recent developments in NEMO. The model was forced by ERA-interim products (every 3 hours) including the atmospheric pressure. In addition to atmospheric forcing, the model includes astronomical tidal forcing. This regional forecasting system uses boundary conditions from the Mercator-Ocean regional system (with data assimilation, 1/12° resolution, PSY4). The assimilation component of the Mercator Ocean system, is based on a reduced-order Kalman filter (the SEEK or Singular Extended Evolutive Kalman filter). An IAU method (Incremental Analysis Updates) is used to apply the increments in the system. A 3D-Var scheme corrects for the slowly evolving large-scale biases in temperature and salinity. The data assimilation system allows to constrain the model in a multivariate way with Sea Surface Temperature (AVHRR + Multi-satellite High resolution), together with all available satellite Sea Level Anomalies, and with in situ observations from the CORA-04 data base, including ARGO floats temperature and salinity measurements. The background SLA field accounts for the high frequency signal determined by the model and the forcing by atmospheric pressure.
In this study we show the impact of the assimilation of altimetry data unfiltered and uncorrected from fast atmospheric frequencies. Altimetry data assimilated contain the effect of atmospheric pressure and wind unlike conventional data used in operational systems.
Mounir Benkiran, Elisabeth Rémy and Guillaume Reffray
MERCATOR Ocean 8-10 Rue Hermes 31526 Ramonville St Agne Cedex
Abstract
Mercator-Ocean has developed a regional forecasting system at 1/36° (~3km) resolution over the North East Atlantic (IBI: Iberia, Biscay and Irish), taking advantage of the recent developments in NEMO. The model was forced by ERA-interim products (every 3 hours) including the atmospheric pressure. In addition to atmospheric forcing, the model includes astronomical tidal forcing. This regional forecasting system uses boundary conditions from the Mercator-Ocean regional system (with data assimilation, 1/12° resolution, PSY4). The assimilation component of the Mercator Ocean system, is based on a reduced-order Kalman filter (the SEEK or Singular Extended Evolutive Kalman filter). An IAU method (Incremental Analysis Updates) is used to apply the increments in the system. A 3D-Var scheme corrects for the slowly evolving large-scale biases in temperature and salinity. The data assimilation system allows to constrain the model in a multivariate way with Sea Surface Temperature (AVHRR + Multi-satellite High resolution), together with all available satellite Sea Level Anomalies, and with in situ observations from the CORA-04 data base, including ARGO floats temperature and salinity measurements. The background SLA field accounts for the high frequency signal determined by the model and the forcing by atmospheric pressure.
In this study we show the impact of the assimilation of altimetry data unfiltered and uncorrected from fast atmospheric frequencies. Altimetry data assimilated contain the effect of atmospheric pressure and wind unlike conventional data used in operational systems.