source: LMDZ6/trunk/libf/phylmd/ecrad.v1.5.1/srtm_kgb27.F90 @ 5450

Last change on this file since 5450 was 3908, checked in by idelkadi, 4 years ago

Online implementation of the radiative transfer code ECRAD in the LMDZ model.

  • Inclusion of the ecrad directory containing the sources of the ECRAD code
    • interface routine : radiation_scheme.F90
  • Adaptation of compilation scripts :
    • compilation under CPP key CPP_ECRAD
    • compilation with option "-rad ecard" or "-ecard true"
    • The "-rad old/rtm/ecran" build option will need to replace the "-rrtm true" and "-ecrad true" options in the future.
  • Runing LMDZ simulations with ecrad, you need :
    • logical key iflag_rrtm = 2 in physiq.def
    • namelist_ecrad (DefLists?)
    • the directory "data" containing the configuration files is temporarily placed in ../libfphylmd/ecrad/
  • Compilation and execution are tested in the 1D case. The repository under svn would allow to continue the implementation work: tests, verification of the results, ...
File size: 4.5 KB
Line 
1SUBROUTINE SRTM_KGB27
2
3!     Originally by J.Delamere, Atmospheric & Environmental Research.
4!     Revision: 2.4
5!     BAND 16: 29000-38000 cm-1 (low - O3; high - O3)
6!     Reformatted for F90 by JJMorcrette, ECMWF
7!     G.Mozdzynski March 2011 read constants from files
8!     T. Wilhelmsson and K. Yessad (Oct 2013) Geometry and setup refactoring.
9!     ------------------------------------------------------------------
10
11USE PARKIND1  , ONLY : JPRB
12USE YOMHOOK   , ONLY : LHOOK, DR_HOOK
13USE YOMLUN    , ONLY : NULRAD
14USE YOMMP0    , ONLY : NPROC, MYPROC
15USE MPL_MODULE, ONLY : MPL_BROADCAST
16USE YOMTAG    , ONLY : MTAGRAD
17USE YOESRTA27 , ONLY : KA, KB, KA_D, KB_D, SFLUXREF, RAYL, SCALEKUR, LAYREFFR 
18
19!     ------------------------------------------------------------------
20
21IMPLICIT NONE
22
23! KURUCZ
24!     The following values were obtained using the "low resolution"
25!     version of the Kurucz solar source function.  For unknown reasons,
26!     the total irradiance in this band differs from the corresponding
27!     total in the "high-resolution" version of the Kurucz function.
28!     Therefore, below these values are scaled by the factor SCALEKUR.
29REAL(KIND=JPRB) :: ZHOOK_HANDLE
30
31#include "abor1.intfb.h"
32
33IF (LHOOK) CALL DR_HOOK('SRTM_KGB27',0,ZHOOK_HANDLE)
34
35IF( MYPROC==1 )THEN
36 READ(NULRAD,ERR=1001) KA_D,KB_D
37  KA = REAL(KA_D,JPRB)
38  KB = REAL(KB_D,JPRB)
39ENDIF
40IF( NPROC>1 )THEN
41  CALL MPL_BROADCAST (KA,MTAGRAD,1,CDSTRING='SRTM_KGB27:')
42  CALL MPL_BROADCAST (KB,MTAGRAD,1,CDSTRING='SRTM_KGB27:')
43ENDIF
44
45SFLUXREF = (/ &
46 & 14.0526_JPRB    , 11.4794_JPRB    , 8.72590_JPRB    , 5.56966_JPRB    , &
47 & 3.80927_JPRB    , 1.57690_JPRB    , 1.15099_JPRB    , 1.10012_JPRB    , &
48 & 0.658212_JPRB   , 5.86859E-02_JPRB, 5.56186E-02_JPRB, 4.68040E-02_JPRB, &
49 & 3.64897E-02_JPRB, 3.58053E-02_JPRB, 1.38130E-02_JPRB, 1.90193E-03_JPRB /) 
50
51!     Rayleigh extinction coefficient at v = 2925 cm-1.
52RAYL = (/ &
53 & 3.44534E-06_JPRB,4.14480E-06_JPRB,4.95069E-06_JPRB,5.81204E-06_JPRB, &
54 & 6.69748E-06_JPRB,7.56488E-06_JPRB,8.36344E-06_JPRB,9.04135E-06_JPRB, &
55 & 9.58324E-06_JPRB,9.81542E-06_JPRB,9.75119E-06_JPRB,9.74533E-06_JPRB, &
56 & 9.74139E-06_JPRB,9.73525E-06_JPRB,9.73577E-06_JPRB,9.73618E-06_JPRB /) 
57
58SCALEKUR = 50.15_JPRB/48.37_JPRB
59
60LAYREFFR = 32
61
62!     ------------------------------------------------------------------
63
64!     The array KA contains absorption coefs at the 16 chosen g-values
65!     for a range of pressure levels> ~100mb, temperatures, and binary
66!     species parameters (see taumol.f for definition).  The first
67!     index in the array, JS, runs from 1 to 9, and corresponds to
68!     different values of the binary species parameter.  For instance,
69!     JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8,
70!     JS = 3 corresponds to the parameter value 2/8, etc.  The second index
71!     in the array, JT, which runs from 1 to 5, corresponds to different
72!     temperatures.  More specifically, JT = 3 means that the data are for
73!     the reference temperature TREF for this  pressure level, JT = 2 refers
74!     to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
75!     is for TREF+30.  The third index, JP, runs from 1 to 13 and refers
76!     to the JPth reference pressure level (see taumol.f for these levels
77!     in mb).  The fourth index, IG, goes from 1 to 16, and indicates
78!     which g-interval the absorption coefficients are for.
79!     -----------------------------------------------------------------
80
81!     -----------------------------------------------------------------
82!     The array KB contains absorption coefs at the 16 chosen g-values
83!     for a range of pressure levels < ~100mb and temperatures. The first
84!     index in the array, JT, which runs from 1 to 5, corresponds to
85!     different temperatures.  More specifically, JT = 3 means that the
86!     data are for the reference temperature TREF for this pressure
87!     level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
88!     TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30. 
89!     The second index, JP, runs from 13 to 59 and refers to the JPth
90!     reference pressure level (see taumol.f for the value of these
91!     pressure levels in mb).  The third index, IG, goes from 1 to 16,
92!     and tells us which g-interval the absorption coefficients are for.
93!     -----------------------------------------------------------------
94 
95     
96!     -----------------------------------------------------------------
97IF (LHOOK) CALL DR_HOOK('SRTM_KGB27',1,ZHOOK_HANDLE)
98RETURN
99
1001001 CONTINUE
101CALL ABOR1("SRTM_KGB27:ERROR READING FILE RADSRTM")
102
103END SUBROUTINE SRTM_KGB27
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