Mapping and pseudoinverse algorithms for ocean data assimilation

Among existing ocean data assimilation methodologies, reduced-state Kalman filters are a widely studied compromise between resolution, optimality, error specification, and computational feasibility. In such reduced-state filters, the measurement update takes place on a coarser grid than that of the general circulation model (GCM); therefore, these filters require mapping operators from the GCM grid to the reduced state and vice versa. The general requirements are that the state-reduction and interpolation operators be pseudoinverses of each other, that the coarse state define a closed dynamical system, that the mapping operations be insensitive to noise, and that they be appropriate for regions with irregular coastlines and bathymetry. In this paper, we describe three efficient algorithms for computing the pseudoinverse: a fast Fourier transform algorithm that serves for illustration purposes, an exact implicit method that is recommended for most applications, and an efficient iterative algorithm that can be used for the largest problems. The mapping performance of 11 interpolation kernels is evaluated. Surprisingly, common kernels such as bilinear, exponential, Gaussian, and sinc perform only moderately well. We recommend instead three kernels, smooth, thin-plate, and optimal interpolation, which have superior properties. This study removes the computational bottleneck of mapping and pseudoinverse algorithms and makes possible the application of reduced-state filters to global problems at state-of-the-art resolutions.

[1]  Alexey Kaplan,et al.  Mapping tropical Pacific sea level : Data assimilation via a reduced state space Kalman filter , 1996 .

[2]  T. M. Chin,et al.  Spatial regression and multiscale approximations for sequential data assimilation in ocean models , 1999 .

[3]  John B. Shoven,et al.  I , Edinburgh Medical and Surgical Journal.

[4]  P. Malanotte‐Rizzoli,et al.  An approximate Kaiman filter for ocean data assimilation: An example with an idealized Gulf Stream model , 1995 .

[5]  Carl Wunsch,et al.  Basin-scale ocean circulation from combined altimetric, tomographic and model data , 1997, Nature.

[6]  Ichiro Fukumori,et al.  Chapter 5 Data Assimilation by Models , 2001 .

[7]  Carl Wunsch,et al.  Linearization of an Oceanic General Circulation Model for Data Assimilation and Climate Studies , 1997 .

[8]  Ichiro Fukumori,et al.  Assimilation of TOPEX/POSEIDON Altimeter Data with a Reduced Gravity Model of the Japan Sea , 1999 .

[9]  Ichiro Fukumori,et al.  A Partitioned Kalman Filter and Smoother , 2002 .

[10]  W. Press,et al.  Numerical Recipes in Fortran: The Art of Scientific Computing.@@@Numerical Recipes in C: The Art of Scientific Computing. , 1994 .

[11]  Jacques Verron,et al.  An extended Kalman filter to assimilate satellite altimeter data into a nonlinear numerical model of the tropical Pacific Ocean: Method and validation , 1999 .

[12]  Jacques Verron,et al.  A singular evolutive extended Kalman filter for data assimilation in oceanography , 1998 .

[13]  Carl Wunsch,et al.  Ocean climate change : Comparison of acoustic tomography, satellite altimetry, and modeling , 1998 .

[14]  Ichiro Fukumori,et al.  Assimilation of TOPEX sea level measurements with a reduced‐gravity, shallow water model of the tropical Pacific Ocean , 1995 .

[15]  Ichiro Fukumori,et al.  Assimilation of TOPEX/Poseidon altimeter data into a global ocean circulation model: How good are the results? , 1999 .