1 / 61

The Nonhydrostatic Icosahedral (NIM) Model: Description and Potential Use in Climate Prediction

The Nonhydrostatic Icosahedral (NIM) Model: Description and Potential Use in Climate Prediction Alexander E. MacDonald Earth System Research Lab Climate Test Bed Seminar June 3, 2009 World Weather Building NIM Design: Jin Luen Lee and Alexander E. MacDonald. X-section location.

kina
Download Presentation

The Nonhydrostatic Icosahedral (NIM) Model: Description and Potential Use in Climate Prediction

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. The Nonhydrostatic Icosahedral (NIM) Model: Description and Potential Use in Climate Prediction Alexander E. MacDonald Earth System Research Lab Climate Test Bed Seminar June 3, 2009 World Weather Building NIM Design: Jin Luen Lee and Alexander E. MacDonald

  2. X-section location Flow-following- finite-volume Icosahedral Model FIM Temp at lowest level

  3. NIM Talk Summary 1. NIM equations. 2. NIM grid, numerical and computational formulation. 3. NIM test cases. 4. Cloud resolving global models and 100 day prediction. 3. NIM schedule.

  4. NIM 3-D finite volume nonhydrostatic equations on Z-coordinate:

  5. NIM Talk Summary 1. NIM equations. 2. NIM grid, numerical and computational formulation. 3. NIM test cases. 4. Cloud resolving global models and 100 day prediction. 5. NIM schedule.

  6. FIM/NIM model characteristics: • Horizontal discretization on Icosahedral grid. • Computations: Single loop, table described, indirect addressed (Scalable to 100,000 CPUs). • Explicit 3rd-order Adams-Bashforth (AB3) time differencing. • Model variables defined on a non-staggered A-grid. • Finite-Volume line integration on local coordinate. • AB3-multistep Flux Conserving Transport: extend Zalesak’s (1979) two-time level to multiple time levels. • FIM: ALE in vertical (sigma-theta hybrid) GFS physics, GSI Initialization + ……. • NIM: 3-D finite-volume formulated on control volume, height-coordinate, GFS physics, + …… Lee and MacDonald (2009): A Finite-Volume Icosahedral Shallow Water Model in Local Coordinate, MWR, 2009, in press (on-line early release)

  7. Icosahedral Grid Generation n=0 n=1 n=2 n=3 N=((2**n)**2)*10 + 2 ; 5th level – n=5  N=10242 ~ 240km; max(d)/min(d)~1.2 6th level – n=6 N=N=40962 ~ 120km; 7th level – n=7N=163842 ~60km 8th level – n=8N=655,362 ~30km; 9th level – n=9N=2,621,442 ~15km 10th level ~7.km; 11th level ~3.5km , 12th level ~1.7km

  8. Finite Volume Numerical Weather Prediction: Represent fields as “total over volume”, using integral relations: Advantage over finite difference: Perfectly conservative.

  9. Nonhydrostatic • Icosahedral • Model • Finite Volume • Control volume coordinate • Full conservative form • Characteristic vert. sound waves • Designed for GPU • Fourth order time accuracy • Piecewise Parabolic space (3rd order) 3-D finite volume

  10. Local coordinate: Every point (and its neighbors) are mapped to a local stereographic coordinate.

  11. Graphic Processing Units: On a Steep Performance Curve

  12. 2011: GPU 4 KM NIM 1 Day Forecast Projected

  13. NIM Talk Summary 1. NIM equations. 2. NIM grid, numerical and computational formulation. 3. NIM test cases. 4. Cloud resolving global models and 100 day prediction. 5. NIM schedule.

  14. Preliminary NIM 2-D test cases:1. Mountain waves.2. Warm bubble.3. Heating forced vertically propagating acoustic waves.

  15. Numerical experiment on mountain waves

  16. Warm Bubble simulation: A rising thermal in an isentropic atmosphere.

  17. t= 0.5 min

  18. t= 0.5 min

  19. t= 1.0 min

  20. t= 1.5 min

  21. t= 2.0 min

  22. t= 2.5 min

  23. t= 3.0 min

  24. t= 3.5 min

  25. t= 4.0 min

  26. t= 4.5 min

  27. t= 5.0 min

  28. t= 5.5 min

  29. t= 6.0 min

  30. t= 6.5 min

  31. t= 7.0 min

  32. t= 7.5 min

  33. t= 8.0 min

  34. t= 8.5 min

  35. t= 9.0 min

  36. t= 9.5 min

  37. t=10.0 min

  38. t=10.5 min

  39. t=11.0 min

  40. t=11.5 min

  41. t=12.0 min

  42. t=12.5 min

  43. t=13.0 min

  44. t=13.5 min

  45. t=14.0 min

  46. t=14.5 min

  47. t=15.0 min

More Related