論文ID: 2018-048
Background error covariance (BEC) is one of the key components in the data assimilation systems for numerical weather prediction. Recently, a scheme of using an inhomogeneous and anisotropic BEC estimated from historical forecast error samples has been tested by employing the extended alpha control variable approach (BEC-CVA) in the framework of the Variational Data Assimilation system for the Weather Research and Forecasting model (WRFDA). In this paper, the BEC-CVA approach is further examined by conducting single observation assimilation experiments and continuously cycling data assimilation and forecasting experiments covering a 3-weeks period. Moreover, additional benefits of using a blending approach (BEC-BLD), which combines a static, homogeneous BEC with an inhomogeneous and anisotropic BEC, are also assessed.
Single observation experiments indicate that the noises in the increments in BEC-CVA can be somehow reduced by using BEC-BLD, while the inhomogeneous and multivariable correlations from the BEC-CVA are still taken into account. The impact of BEC-CVA and BEC-BLD on short-term weather forecasts is compared with three-dimensional variational data assimilation scheme (3DVar), and compared with the hybrid ensemble transform Kalman filter and 3DVar (ETKF-3DVar) in WRFDA also. Results show that the BEC-CVA and BEC-BLD outperform the use of 3DVar. It is shown that BEC-CVA and BEC-BLD underperform ETKF-3DVar as expected, however the computational cost of BEC-CVA and BEC-BLD is considerably less expensive since no ensemble forecasts are required.
