EGU23-1846
https://doi.org/10.5194/egusphere-egu23-1846
EGU General Assembly 2023
© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Hybrid covariance super-resolution data assimilation

Sébastien Barthélémy1,3, Julien Brajard2,3,4, Laurent Bertino2,3, and François Counillon1,2,3
Sébastien Barthélémy et al.
  • 1University of Bergen, Geophysical Institute, Norway
  • 2Nansen Environmental and Remote Sensing Center, Bergen, Norway
  • 3Bjerknes Center for Climate Research, Bergen, Norway
  • 4Sorbonnes Université, Paris, France

This work extends the concept of "Super-resolution data assimilation" (SRDA, Barthélémy et al. 2022)) to the case of mixed-resolution ensembles pursuing two goals: (1) emulate the Ensemble Kalman Filter while (2) benefit from high-resolution observations. The forecast step is performed by two ensembles at two different resolutions, high and low-resolution. Before the assimilation step the low-resolution ensemble is downscaled to the high-resolution space, then both ensembles are updated with high-resolution observations. After the assimilation step, the low-resolution ensemble is upscaled back to its low-resolution grid for the next forecast. The downscaling step before the data assimilation step is performed either with a neural network, or with a simple cubic spline interpolation operator. The background error covariance matrix used for the update of both ensembles is a hybrid matrix between the high and low resolution background error covariance matrices. This flavor of the SRDA is called "Hybrid covariance super-resolution data assimilation" (Hybrid SRDA). We test the method with a quasi-geostrophic model in the context of twin-experiments with the low-resolution model being twice and four times coarser than the high-resolution one. The Hybrid SRDA with neural network performs equally or better than its counterpart with cubic spline interpolation, and drastically reduces the errors of the low-resolution ensemble. At equivalent computational cost, the Hybrid SRDA outperforms both the SRDA (8.4%) and the standard EnKF (14%). Conversely, for a given value of the error, the Hybrid SRDA requires as little as  50% of the computational resources of  the EnKF. Finally, the Hybrid SRDA can be formulated as a low-resolution scheme, in the sense that the assimilation is performed in the low-resolution space, encouraging the application of the scheme with realistic ocean models.

How to cite: Barthélémy, S., Brajard, J., Bertino, L., and Counillon, F.: Hybrid covariance super-resolution data assimilation, EGU General Assembly 2023, Vienna, Austria, 24–28 Apr 2023, EGU23-1846, https://doi.org/10.5194/egusphere-egu23-1846, 2023.