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Development of an incremental 4D-VAR system for ocean model downscaling

Development of an incremental 4D-VAR system for ocean model downscaling. Yoichi Ishikawa 1 , Toshiyuki Awaji 1,2 , Teiji In 3 , Satoshi Nakada 2 , Tsuyoshi Wakamatsu 1 , Yoshimasa Hiyoshi 1 , Yuji Sasaki 1 1 DrC, JAMSTEC 2 Kyoto University 3 Japan Marine Science Foundation .

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Development of an incremental 4D-VAR system for ocean model downscaling

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  1. Development of an incremental 4D-VAR system for ocean model downscaling Yoichi Ishikawa1, Toshiyuki Awaji1,2, Teiji In3, Satoshi Nakada2, Tsuyoshi Wakamatsu1, Yoshimasa Hiyoshi1, Yuji Sasaki1 1DrC, JAMSTEC 2Kyoto University 3Japan Marine Science Foundation

  2. Introduction • 4DVAR data assimilation system with Eddy-Resolving OGCM have been successfully developed (e.g. Ishikawa et al., 2009) • Strong Western Boundary Currents, meso-scale eddies, strong flows through narrow channels. • Estimate initial conditions with 1month assimilation window

  3. Introduction • Eddy resolving/permitting OGCM with 1/6x1/8 resolution • limitation of computational resources • limitation of available observation data • Resolution is not enough for • detailed processes for eddy activities, detachment, junction, deformation, etc. • detailed processes associated with narrow channel, Tsushima strait, Tsugaru strait. • Higher resolution is required but cannot execute. • Down scaling approach is often adopted.

  4. Introduction • Downscaling approach is very effective to obtain high-resolution data set. • Initial & boundary conditions are realistic because they are taken from reanalysis dataset. • However, the quality of downscaled dataset is not guaranteed • different physical processes, different topography, different parameterization • There differences sometimes leads serious biases downscaling dataset • To obtain realistic high-resolution dataset,data assimilation and downscaling systems are integrated. • make reanalysis dataset suitable for downscaling.

  5. Kyoto Univ. Ocean General Circulation Model OGCM & data assimilation system is based on Ishikawa et al., 2009. • σ-z hybrid vertical coordinate Equation of Motion Takano-Onishi scheme (Ishizaki and Motoi, 1999) Equation of Tracer • Mixed layer sheme based on turbulence closure(Noh, 2005) • Isopycnal diffusion and eddy parameterization • (Gent and McWillams, 1990; Griffies, 1998) • 3rd-Order advection scheme (Hasumi, 2000)

  6. 1/6x1/8 deg. Parent model Configuration of system 1/18x1/24 deg child model

  7. Observation data • Sea surface temperature :OSTIA (Operational Sea Surface Temperature and Sea Ice Analysis) by NCOF, 1/20deg. • Sea surface height : Ssalto/Ducacusgrided absolute dynamic topography by AVISO, 1/3 deg. • In-situ data : GTSPP (global temperature-salinity profile program) XBT and CTD data by NOAA/NODC.

  8. Variational adjoint method Cost function : constraint for observational data and intial guess of control variables Control variables : initial conditions of model variables Gradient descent method :Popular scheme (Fujii and Kamachi, 2003), which can utilize non-diagonal part of the error covariance matrix for initial guess. This method is modified in this study for combining downscaling system

  9. Assimilation & downscaling Classical framework Low resolution Parent model: High resolution child model High resolution data assimilation in future High resolution model

  10. Assimilation & downscaling new approach in this study Low resolution Parent model: High resolution child model Solving optimization problems to minimize the difference between high resolution model & observation data by estimating the initial condition of low resolution model

  11. Incremental approach Make new formulation using increment: parent model: Child model: Outer Loop: Inner Loop: Approximate: Bias (Constant in Inner Loop):

  12. Calculation Procedure • forecast Parent & Child model • calculate bias • optimized initial condition • forecast Parent & Child model

  13. Experimental setting • Assimilation period: 28day • observation data are averaged every 1day • Start from Jan.5 2011 • currently, 1 year integration • Compare new approach with classical downscaling

  14. Snapshot of SST Apr. 1st, 2011 Classical Downscaling New incremental 4DVAR Observation data Reduce warm biases appears in classical Downscaling

  15. RMSD with observation of SST Classical Downscaling New incremental 4DVAR

  16. Time series of RMSD of SST Classical Downscaling New incremental 4DVAR Seasonal change of RMSD is due to the change of mixed layer depth. Summer:thin mixed layer & heat flux is effective Winter: thick mixed layer & advection is effective

  17. Vertical profile of RMSD Classical Downscaling New incremental 4DVAR

  18. SST and surface velocity Classical Downscaling New incremental 4DVAR

  19. Temperature at 100m depth Classical Downscaling New incremental 4DVAR

  20. Velocity at 100m Classical Downscaling New incremental 4DVAR

  21. Tsushima strait (child model) Classical Downscaling New incremental 4DVAR

  22. Tsushima strait (parent model) Classical Downscaling New incremental 4DVAR

  23. Tsugaru strait (child model) Classical Downscaling New incremental 4DVAR

  24. Tsugaru strait (parent model) Classical Downscaling New incremental 4DVAR

  25. Along 41N Classical Downscaling New incremental 4DVAR

  26. Along 40.5N Classical Downscaling New incremental 4DVAR

  27. Summary • To obtain high resolution analysis, incremental approach is introduced in 4DVAR system, considering the biases in downscaling. • Associating strong flows through the narrow channel, significant improvement can be recognized. • Topographic effect and nonlinear behavior is important. • Configuration of Inner-Outer loop will be examined for better estimation.

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