Abstract

AbstractAt the Canadian Meteorological Center (CMC), we are currently developing the future global forecasting Yin‐Yang model. In the horizontal we use spherical coordinates on the overset Yin‐Yang grid, while in the vertical we use a log‐hydrostatic‐pressure coordinate on the Charney–Phillips grid. The parametrization of physical processes is kept the same as in the current Global Environmental Multiscale (GEM) operational model. The Yin‐Yang global forecast is performed by considering a domain decomposition (a two‐way coupling method) between two limited‐area models (LAMs) discretized on the two panels of the Yin‐Yang grid and using the same time step. Each panel of the Yin‐Yang grid system is extended by a static halo region and uses the same fully implicit semi‐Lagrangian method as in the GEM operational model to solve its own dynamic core. The spatial and time discretizations are implemented independently on each quasi‐uniform latitude–longitude subgrid. The static halo region plays the same role as the piloting region in limited‐area modelling. Since the two subgrids of the Yin‐Yang grid do not match, the update of the variables in the pilot region is done by cubic Lagrange interpolation. For our model validation, we ran 42 winter and 42 summer cases using analysis from 2008–2009 and we compared five‐day forecast results against observations. No noise is seen in the overlap regions during the simulations. Preliminary results presented in this article are encouraging and demonstrate that in comparison with observations the new Yin‐Yang system performs as well as the GEM global model. © 2011 Crown in the right of Canada. Published by John Wiley & Sons Ltd.

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