Data assimilation applications with large-scale numerical models
exhibit extreme requirements on computational resources. Good
scalability of the assimilation system is necessary to make these
applications feasible. Sequential data assimilation methods based on
ensemble forecasts, like ensemble-based Kalman filters, provide such
good scalability, because the forecast of each ensemble member can be
performed independently. However, this parallelism has to be combined
with the parallelization of both the numerical model and the data
assimilation algorithm. In order to simplify the implementation of
scalable data assimilation systems based on existing numerical models,
the Parallel Data Assimilation Framework PDAF (http://pdaf.awi.de) has
been developed. PDAF provides support for implementing a data
assimilation system with parallel ensemble forecasts and parallel
numerical models. Further, it includes several optimized parallel
filter algorithms, like the Ensemble Transform Kalman Filter.
We will discuss the philosophy behind PDAF as well as features and
scalability of data assimilation systems based on PDAF on the example
of data assimilation with the finite element ocean model FEOM.
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