机构地区:[1]School of Atmospheric Sciences,Nanjing University of Information Science&Technology,Nanjing 210044,China [2]Chinese Academy of Meteorological Sciences,Beijing 100081,China [3]CMA Earth System Modeling and Prediction Centre(CEMC),Beijing 100081,China [4]Key Laboratory of Earth System Modeling and Prediction of China Meteorological Administration,Beijing 100081,China [5]Tianjin Meteorological Observatory,Tianjin 300074,China [6]China Meteorological Administration Xiong’an Atmospheric Boundary Layer Key Laboratory,Hebei 071799,China
出 处:《Advances in Atmospheric Sciences》2024年第3期545-563,共19页大气科学进展(英文版)
基 金:supported by the Joint Funds of the Chinese National Natural Science Foundation (NSFC)(Grant No.U2242213);the National Key Research and Development (R&D)Program of the Ministry of Science and Technology of China(Grant No. 2021YFC3000902);the National Science Foundation for Young Scholars (Grant No. 42205166)。
摘 要:Ensemble prediction is widely used to represent the uncertainty of single deterministic Numerical Weather Prediction(NWP) caused by errors in initial conditions(ICs). The traditional Singular Vector(SV) initial perturbation method tends only to capture synoptic scale initial uncertainty rather than mesoscale uncertainty in global ensemble prediction. To address this issue, a multiscale SV initial perturbation method based on the China Meteorological Administration Global Ensemble Prediction System(CMA-GEPS) is proposed to quantify multiscale initial uncertainty. The multiscale SV initial perturbation approach entails calculating multiscale SVs at different resolutions with multiple linearized physical processes to capture fast-growing perturbations from mesoscale to synoptic scale in target areas and combining these SVs by using a Gaussian sampling method with amplitude coefficients to generate initial perturbations. Following that, the energy norm,energy spectrum, and structure of multiscale SVs and their impact on GEPS are analyzed based on a batch experiment in different seasons. The results show that the multiscale SV initial perturbations can possess more energy and capture more mesoscale uncertainties than the traditional single-SV method. Meanwhile, multiscale SV initial perturbations can reflect the strongest dynamical instability in target areas. Their performances in global ensemble prediction when compared to single-scale SVs are shown to(i) improve the relationship between the ensemble spread and the root-mean-square error and(ii) provide a better probability forecast skill for atmospheric circulation during the late forecast period and for short-to medium-range precipitation. This study provides scientific evidence and application foundations for the design and development of a multiscale SV initial perturbation method for the GEPS.
关 键 词:multiscale uncertainty singular vector initial perturbation global ensemble prediction system
分 类 号:P45[天文地球—大气科学及气象学]
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