Diagnosing non-Gaussianity of forecast and analysis errors in a convective-scale model
Legrand, Raphaël ; Michel, Yann ; Montmerle, Thibaut
<span style="color:#4b0082;">ABSTRACT.</span></p><p style="margin-bottom: 0cm; line-height: 100%" align="justify"><span style="color:#4b0082;">In numerical weather prediction, the problem of estimating initial conditions with a variational approach is usually based on a Bayesian framework associated with a Gaussianity assumption of the probability density functions of both observations and background errors. In practice, Gaussianity of errors is tied to linearity, in the sense that a nonlinear model will yield non-Gaussian probability density functions. In this context, standard methods relying on Gaussian assumption may perform poorly.</span></p><p style="margin-bottom: 0cm; line-height: 100%" align="justify"><span style="color:#4b0082;">This study aims to describe some aspects of non-Gaussianity of forecast and analysis errors in a convective-scale model using a Monte Carlo approach based on an ensemble of data assimilations.</span></p><p style="margin-bottom: 0cm; line-height: 100%" align="justify"><span style="color:#4b0082;">For this purpose, an ensemble of 90 members of cycled perturbed assimilations has been run over a highly precipitating case of interest. Non-Gaussianity is measured using the <i>K</i><sup>2</sup> statistics from the D'Agostino test, which is related to the sum of the squares of univariate skewness and kurtosis.</span></p><p style="margin-bottom: 0cm; line-height: 100%" align="justify"><span style="color:#4b0082;">Results confirm that specific humidity is the least Gaussian variable according to that measure and also that non-Gaussianity is generally more pronounced in the boundary layer and in cloudy areas.</span></p><p style="margin-bottom: 0cm; line-height: 100%" align="justify"><span style="color:#4b0082;">The dynamical control variables used in our data assimilation, namely vorticity and divergence, also show distinct non-Gaussian behaviour. It is shown that while non-Gaussianity increases with forecast lead time, it is efficiently reduced by the data assimilation step especially in areas well covered by observations. Our findings may have implication for the choice of the control variables.</span></p>
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