Abstract
<jats:p>Abstract. High-resolution modelling of a large ocean domain requires
significant computational resources. The main purpose of this study is to
develop an efficient tool for downscaling the lower-resolution data such as those available from Copernicus Marine Environment Monitoring Service (CMEMS).
Common methods of downscaling CMEMS ocean models utilise their lower-resolution output as boundary conditions for local, higher-resolution
hydrodynamic ocean models. Such methods reveal greater details of spatial
distribution of ocean variables; however, they increase the cost of
computations and often reduce the model skill due to the so called “double
penalty” effect. This effect is a common problem for many high-resolution
models where predicted features are displaced in space or time. This paper
presents a stochastic–deterministic downscaling (SDD) method, which is an
efficient tool for downscaling of ocean models based on the combination of
deterministic and stochastic approaches. The ability of the SDD method is
first demonstrated in an idealised case when the true solution is known a
priori. Then the method is applied to create an operational Stochastic Model
of the Red Sea (SMORS), with the parent model being the Mercator Global Ocean
Analysis and Forecast System at 1/12∘ resolution. The stochastic
component of the model is data-driven rather than equation-driven, and it is
applied to the areas smaller than the Rossby radius, within which
distributions of ocean variables are more coherent than over a larger
distance. The method, based on objective analysis, is similar to what is
used for data assimilation in ocean models and stems from the philosophy of
2-D turbulence. SMORS produces finer-resolution (1/24∘
latitude mesh) oceanographic data using the output from a coarser-resolution
(1/12∘ mesh) parent model available from CMEMS. The values on
the fine-resolution mesh are computed under conditions of minimisation of the
cost function, which represents the error between the model and true
solution. SMORS has been validated against sea surface temperature
and ARGO float observations. Comparisons show that the model and
observations are in good agreement and SMORS is not subject to the “double
penalty” effect. SMORS is very fast to run on a typical desktop PC and can
be relocated to another area of the ocean.
</jats:p>
Original language | English |
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Pages (from-to) | 891-907 |
Number of pages | 0 |
Journal | Ocean Science |
Volume | 17 |
Issue number | 4 |
Early online date | 6 Jul 2021 |
DOIs | |
Publication status | Published - 6 Jul 2021 |