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Held and Suarez (1994) dynamcal core experiment

A method to perform dynamical core experiment proposed by Held and Suarez (1994) is described.

Following physical processes are used in this experiment.


  1. Overview
  2. Preparation of a directory for experiments
  3. Create initial data file
  4. Run the experiment
  5. Visualization of result
  6. References

Overview

This experiment does not require additional data. So, the experiment is performed with the following 3 steps:

Preparation of a directory for experiments

Move to "practice" directory.

$ cd practice

In the directory, execute 'make' command. The execution files and the NAMELIST files will be automatically copied. Input directory name after inputting 'make' command. (It is assumed "hs94-exp" in the following example). Input 'Enter' to the question after that.

$ make

****** Setup a directory for a experiment ******

  Enter directory name [testXX]: hs94-exp
  Directory in which executable files are prepared
    [../src/main]:
  Directory in which NAMELIST files are prepared
    [../src/main]:
  Save F90/95 source code files? [y/N]: 

                :

*** Setup of "hs94-exp" is complete ***

Then a directory 'hs94-exp' is created, and executable files, NAMELIST files, and source code files are copied to the directory. Move the 'hs94-exp'.

$ cd hs94-exp

Note that you can perform an experiment in any directory by using executable files and configuration (namelist) files.

Create initial data file

Create initial data file "init_T21L20.nc" using "init_data" and "init_data_hs94_T21L20.nml"

$ ./init_data -N=init_data_hs94_T21L20.nml

                       : 
 *** MESSAGE [restart_file_io] ***  ----- Initialization Messages -----
 *** MESSAGE [restart_file_io] ***  Input::
 *** MESSAGE [restart_file_io] ***    InputFile  =
 *** MESSAGE [restart_file_io] ***  Output::
 *** MESSAGE [restart_file_io] ***    OutputFile = init_T21L20.nc
 *** MESSAGE [restart_file_io] ***    IntTime    = 1. [day]

 *** MESSAGE [HistoryCreate3] ***  "init_T21L20.nc" is created (origin=0. [day])
 *** MESSAGE [initial_data] ***  NAMELIST group "initial_data_nml" is loaded from "init_data_T21L16.nml".
 *** MESSAGE [initial_data] ***  NAMELIST group "initial_data_nml" is loaded from "init_data_T21L16.nml".
 *** MESSAGE [initial_data] ***  ----- Initialization Messages -----
 *** MESSAGE [initial_data] ***    Pattern = Small Disturbance of Temperature
 *** MESSAGE [initial_data] ***    TempAvr = 280.
 *** MESSAGE [initial_data] ***    PsAvr   = 100000.
 *** MESSAGE [initial_data] ***    QVapAvr = 0.1E-09

 *** MESSAGE [HistoryClose] ***  "init_T21L20.nc" is closed

Run the experiment

Using an executable files 'dcpam_main' and a NAMELIST file dcpam_hs94_T21L20.nml, execute 'dcpam_main' as follows. This program will be finished in few minutes - tens of minutes.

$ ./dcpam_main -N=dcpam_hs94_T21L20.nml | tee hs94.log

 *** MESSAGE [dcpam_main] ***  Run: Held and Suarez (1994) benchmark test
                   :
 *** MESSAGE [timeset] ***  ----- Initialization Messages -----
 *** MESSAGE [timeset] ***    StartTime  = 0. [day]
 *** MESSAGE [timeset] ***    EndTime    = 10. [day]
 *** MESSAGE [timeset] ***    DelTime    = 30. [min]
 *** MESSAGE [timeset] ***               = 1800. [sec]
                   :
                   :
 *** MESSAGE [fileset] ***  ----- Initialization Messages -----
 *** MESSAGE [fileset] ***    FileTitle       = Held and Suarez (1994) benchmark test
 *** MESSAGE [fileset] ***    FileSource      = dcpam5 (http://www.gfd-dennou.org/library/dcpam)
 *** MESSAGE [fileset] ***    FileInstitution = GFD Dennou Club (http://www.gfd-dennou.org)
 *** MESSAGE [fileset] ***  -- version = ....
 *** MESSAGE [gridset] ***  ----- Initialization Messages -----
 *** MESSAGE [gridset] ***    nmax = 21
 *** MESSAGE [gridset] ***    imax = 64
 *** MESSAGE [gridset] ***    jmax = 32
 *** MESSAGE [gridset] ***    kmax = 20
 *** MESSAGE [gridset] ***  -- version = ....
                   : 

 ########## PREDICTION OF CALCULATION ###########
 Start Date             2009-03-06T08:26:41+09:00
 Current Date           2009-03-06T08:26:45+09:00
 Progress     20.00%  [*****                    ]
 Remaining CPU TIME      0.160000E+02
 Completion Date        2009-03-06T08:27:01+09:00

                   :

 ############## CPU TIME SUMMARY ################
 held_suarez_1994       0.165611E+01
 dynamics_hspl_vas83    0.191452E+02
 timefilter_asselin19   0.264027E+00
 others                 0.896038E+00
 ------------------------------------------------
        TOTAL TIME =    0.219614E+02

In this case, 10 days integration is performed. Resolution is T21L20 (Number of grid points of longitude, latitude is 64, 32, and number of vertical layer is 20). History data are output to 'U.nc' and 'Temp.nc' etc., and a restart data is output to 'restart.nc'.

Visualization of result

Zonal mean temperature at 10 day is shown in following figures.

images/hs94_irb_temp_meanlon_time11day.png

This figure is drawn by using Gphys, as follows:

Please type irb. 

$ irb

Following prompt of irb is shown. 

irb(main):001:0>

Type following lines. Please note that the left-most number is line number, and it has not been typed. 

1: require "numru/ggraph"
2: include NumRu
3: gphys = GPhys::IO.open('Temp.nc', 'Temp')
4: DCL.gropn(1)
5: DCL.sgpset('lcntl', false) ; DCL.uzfact(0.7)
6: GGraph.tone( gphys.mean('lon').cut('time'=>11) )
7: GGraph.color_bar
8: DCL.grcls

Type quit to exit irb. 

In Held and Suarez (1994), integration period is 1200 days and resolution is T63L20 (Number of grid points of longitude, latitude is 192, 96, and number of vertical layer is 20). The result of such integration by using the dcpam is shown here (Japanese page only).

References


$Id: exp-hs94.rd,v 1.6 2011-04-08 03:57:26 yot Exp $
DCPAM Development Group / GFD Dennou Staff dcstaff@gfd-dennou.org