Abstract
The covariance matrix estimated from the ensemble data assimilation always suffers from filter collapse because of the spurious correlations induced by the finite ensemble size. The localization technique is applied to ameliorate this issue, which has been suggested to be effective. In this paper, an adaptive scheme for Schur product covariance localization is proposed, which is easy and efficient to implement in the ensemble data assimilation frameworks. A Gaussian-shaped taper function is selected as the localization taper function for the Schur product in the adaptive localization scheme, and the localization radius is obtained adaptively through a certain criterion of correlations with the background ensembles. An idealized Lorenz96 model with an ensemble Kalman filter is firstly examined, showing that the adaptive localization scheme helps to significantly reduce the spurious correlations in the small ensemble with low computational cost and provides accurate covariances that are similar to those derived from a much larger ensemble. The investigations of adaptive localization radius reveal that the optimal radius is model-parameter-dependent, vertical-level-dependent and nearly flow-dependent with weather scenarios in a realistic model; for example, the radius of model parameter zonal wind is generally larger than that of temperature. The adaptivity of the localization scheme is also illustrated in the ensemble framework and shows that the adaptive scheme has a positive effect on the assimilated analysis as the well-tuned localization.
Highlights
We focus on the implementation of the adaptive localization for the ensemblebased background error covariances with two difficulties: which taper function is used for determining the localization weighting coefficient and how the localization radius can be updated with the weather scenario
The ensemble-based covariances estimated from the short-term forecast ensembles are a reduced-rank representation of the background error covariance and always suffer from spurious correlation problems
In order to ameliorate the spurious correlations in the ensemble-based covariances, an adaptive localization scheme is presented in this study
Summary
Background error covariances play an important role in determining the influence of assimilated observations on the multivariate analysis of model states [1]. For the practical implementation in oceanic or atmospheric systems, the ensemble size is typically many orders of magnitude smaller than the dimension of the model states, considering the affordable computational load in the operational system This phenomenon means that the sample covariance matrix is rank-deficient due to the finite ensemble size, which can lead. The consequence of the spurious correlations is that a state variable may be incorrectly impacted by an observation that is physically remote, and filter divergence occurs when the analysis adjusted by observation information is unable to more accurately represent the true state For this reason, the localization technique has been developed to overcome this problem [11,12,13,14].
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