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\section{Introduction} |
\section{Introduction} |
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\label{sec:intro} |
\label{sec:intro} |
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In the past five years, oceanographic state estimation has matured to the |
In recent years, oceanographic state estimation has matured to the |
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extent that estimates of the evolving circulation of the ocean constrained by |
extent that estimates of the evolving circulation of the ocean constrained by |
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in-situ and remotely sensed global observations are now routinely available |
in-situ and remotely sensed global observations are now routinely available |
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and being applied to myriad scientific problems \citep{wun07}. Ocean state |
and being applied to myriad scientific problems \citep{wun07}. Ocean state |
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estimation is the process of fitting an ocean general circulation model (GCM) |
estimation is the process of fitting an ocean General Circulation Model (GCM) |
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to a multitude of observations. As formulated by the consortium Estimating |
to a multitude of observations. As formulated by the consortium for Estimating |
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the Circulation and Climate of the Ocean (ECCO), an automatic differentiation |
the Circulation and Climate of the Ocean (ECCO), an automatic differentiation |
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tool is used to calculate the so-called adjoint code of a GCM. The method of |
tool is used to calculate the so-called adjoint code of a GCM. The method of |
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Lagrange multipliers is then used to render the problem one of unconstrained |
Lagrange multipliers is then used to render the problem one of unconstrained |
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least-squares minimization. Although much has been achieved, the existing |
least-squares minimization. Although much has been achieved, the existing |
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ECCO estimates lack intercative sea ice. This limits the ability of ECCO to |
ECCO estimates lack interactive sea ice. This limits the ability to |
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utilize satellite data constraints over sea-ice covered regions. This also |
utilize satellite data constraints over sea-ice covered regions. This also |
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limits the usefulness of the ECCO ocean state estimates for describing and |
limits the usefulness of the derived ocean state estimates for describing and |
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studying polar-subpolar interactions. |
studying polar-subpolar interactions. This paper is a first step towards |
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adding sea-ice capability to the ECCO estimates. That is, we describe a |
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dynamic and thermodynamic sea ice model that has been coupled to the |
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Massachusetts Institute of Technology general circulation model |
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\citep[MITgcm][]{mar97a} and that has been modified to permit efficient and |
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accurate automatic differentiation. |
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The availability of an adjoint model as a powerful research tool |
The availability of an adjoint model as a powerful research tool |
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complementary to an ocean model was a major design requirement early |
complementary to an ocean model was a major design requirement early |
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on in the development of the MIT general circulation model (MITgcm) |
on in the development of the MITgcm \citep{marotzke99}. It |
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[Marshall et al. 1997a, Marotzke et al. 1999, Adcroft et al. 2002]. It |
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was recognized that the adjoint model permitted computing the |
was recognized that the adjoint model permitted computing the |
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gradients of various scalar-valued model diagnostics, norms or, |
gradients of various scalar-valued model diagnostics, norms or, |
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generally, objective functions with respect to external or independent |
generally, objective functions with respect to external or independent |
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