References
- Chen S. H. Sun W. Y. The applications of the multigrid method and a flexible hybrid coordinate in a nonhydrostatic model. Mon. Weather Rev. 2001; 129: 2660–2676.
- Gadd, A. J. 1978. Meteor. Office Tech. Note 48, 8. pp.
- Haines, P. A, Grove, D. J, Sun, W. Y, Hsu, W.-R and Tcheng, S. C. 2003. High resolution results and scalability of numerical modeling of wind flow at white sand missile range. BACIMO (DOD atmospheric science and effects) Conference, September 2003 in Monterey, CA.
- Hsieh, M.-E, Hsu, W. R and Sun, W. Y. 2010. Applications of a three-dimensional nonhydrostatic atmospheric model on uniform flows over an idealized mountain. 2010 Computational Fluid Dynamics Taiwan, Chung-Li, Taiwan, July 29–31. Reprint. P.1–12.
- Hsu W.-R. Sun W. Y. A time-split, forward-backward numerical model for solving a nonhydrostatic and compressible system of equations. Tellus. 2001; 53A: 279–299.
- Klemp J. B. Wilhelmson R. B. The simulation of three-dimensional convective storm dynamics. J. Atmos. Sci. 1978; 35: 1070–1096.
- MacDonald A. E. Lee J. L. Xie Y. The use of quasi-nonhydrostatic models for mesoscale weather prediction. J. Atmos. Sci. 2000; 57: 2493–2517.
- Mesinger, F and Arakawa, A. 1976. Numerical methods used in atmospheric models. GARP Publication Series No. 14, WMO/ICSU Joint Organizing Committee, 64. pp.
- Robert A. Bubble convection experiment with a semi-implicit formation of the Euler equations. J. Atmos. Sci. 1993; 50: 1865–1973.
- Saito K. Nonhydrostatic atmospheric models and operational development at JMA. J. Meteo. Soc. Japan. 2007; 85B: 271–304.
- Sun W. Y. A forward-backward time integration scheme to treat internal gravity waves. Mon. Weather Rev. 1980; 108: 402–407.
- Sun W. Y. Numerical analysis for hydrostatic and nonhydrostatic equations of inertial-internal gravity waves. Mon. Weather Rev. 1984; 112: 259–268.
- Sun W. Y. Conserved semi-Lagrangian scheme applied to one-dimensional shallow water equations. Terrestrial Atmos. Ocean. Sci. 2007; 18(4): 777–803.
- Sun W. Y. Instability in leapfrog and forward-backward schemes: part II: numerical simulation of dam break. J. Comput. Fluids. 2011; 45: 70–76.
- Sun W. Y. Chern J. D. Numerical experiments of vortices in the wake of idealized large mountains. J. Atmos. Sci. 1994; 51: 191–209.
- Sun W. Y. Hsu W. R. Effect of surface friction on downslope wind and mountain waves. Terrestrial Atmos. Ocean. Sci. 2005; 16: 393–418.
- Sun W. Y. Sun M. T. Mass correction applied to semi-Lagrangian advection scheme. Mon. Weather Rev. 2004; 132(4): 975–984.
- Sun W. Y. Sun O. M. T. A modified leapfrog scheme for shallow water equations. J. Comput. Fluids. 2011; 52: 69–72.
- Sun, W. Y, Hsu, W.-R, Chern, J.-D, Chen, S.-H, Wu, C.-C and co-authors. 2009. Purdue atmospheric models and applications. In: Recent Progress in Atmospheric Sciences: Applications to the Asia-Pacific Region. (eds. K. N. Liao and M. D. Chou), World Scientific: Singapore, 496 pp. pp. 200–230.
- Tsuboki, K and Sakakibara, A. 2002. Large-scale parallel computing of Cloud Resolving Storm Simulator. In High Performance Computing. (eds. H. P. Zima et al.), Springer, pp. 243–259.
- Tsuboki, K and Sakakibara, A. 2007. The Seventeenth IHP Training Course (International Hydrological Program). Numerical Prediction of High-Impact Weather Systems. 2 15 December 2007, Nagoya: Japan, 273. pp.