Abstract
Data assimilation methods are an invaluable tool for operational ocean models. These methods are often based on a variational approach and require the knowledge of the spatial covariances of the background errors (differences between the numerical model and the true values) and the observation errors (differences between true and measured values). Since the true values are never known in practice, the error covariance matrices containing values of the covariance functions at different locations, are estimated approximately. Several methods have been devised to compute these matrices, one of the most widely used is the one developed by Hollingsworth and Lönnberg (H-L). This method requires to bin (combine) the data points separated by similar distances, compute covariances in each bin and then to find a best fit covariance function. While being a helpful tool, the H-L method has its limitations. We have developed a new mathematical method for computing the background and observation error covariance functions and therefore the error covariance matrices. The method uses functional analysis which allows to overcome some shortcomings of the H-L method, for example, the assumption of statistical isotropy. It also eliminates the intermediate steps used in the H-L method such as binning the innovations (differences between observations and the model), and the computation of innovation covariances for each bin, before the best-fit curve can be found. We show that the new method works in situations where the standard H-L method experiences difficulties, especially when observations are scarce. It gives a better estimate than the H-L in a synthetic idealised case where the true covariance function is known. We also demonstrate that in many cases the new method allows to use the separable convolution mathematical algorithm to increase the computational speed significantly, up to an order of magnitude. The Projection Method (PROM) also allows computing 2D and 3D covariance functions in addition to the standard 1D case.
Highlights
Due to intrinsic inaccuracies in the model equations, numerical schemes and quality of input data streams, even the best ocean models gradually deviate from reality and can only be considered an estimate of the true ocean state [1]
We show that the new method works in situations where the standard Hollingsworth and Lönnberg (H-L) method experiences difficulties, especially when observations are scarce
A curve is fitted through the covariance points to produce a covariance function which is used to calculate the diagonal element of R related to that grid node, and a row of elements for the B matrix, both diagonal and non-diagonal
Summary
Due to intrinsic inaccuracies in the model equations, numerical schemes and quality of input data streams, even the best ocean models gradually deviate from reality and can only be considered an estimate of the true ocean state [1]. The introduction of Data Assimilation (DA) techniques allowed to reduce the deviation of models from the true state, vastly improving the accuracy of ocean forecasting [2]. The cost function includes a combination of the model forecasts and the observational data, weighted by the relative correctness of each component as represented by their error covariance matrices (ECM). This DA technique allows to compute a more accurate state called the analysis, which is used as an initial condition for a new forecasting cycle
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