source: LMDZ6/branches/LMDZ_cdrag_LSCE/libf/phylmd/ecrad/radiation_setup.F90 @ 5423

Last change on this file since 5423 was 4489, checked in by lguez, 21 months ago

Merge LMDZ_ECRad branch back into trunk!

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1MODULE RADIATION_SETUP
2
3! RADIATION_SETUP - Setting up modular radiation scheme
4!
5! (C) Copyright 2015- ECMWF.
6!
7! This software is licensed under the terms of the Apache Licence Version 2.0
8! which can be obtained at http://www.apache.org/licenses/LICENSE-2.0.
9!
10! In applying this licence, ECMWF does not waive the privileges and immunities
11! granted to it by virtue of its status as an intergovernmental organisation
12! nor does it submit to any jurisdiction.
13!
14! PURPOSE
15! -------
16!   The modular radiation scheme is contained in a separate
17!   library. SETUP_RADIATION_SCHEME in this module sets up a small
18!   number of global variables needed to store the information for it.
19!
20!   Lower case is used for variables and types taken from the
21!   radiation library
22!
23! INTERFACE
24! ---------
25!   SETUP_RADIATION_SCHEME is called from SUECRAD.  The radiation
26!   scheme is actually run using the RADIATION_SCHEME routine (not in
27!   this module).
28!
29! AUTHOR
30! ------
31!   Robin Hogan, ECMWF
32!   Original: 2015-09-16
33!
34! MODIFICATIONS
35! -------------
36!
37!-----------------------------------------------------------------------
38
39  USE PARKIND1,         ONLY : JPRB
40  USE radiation_config, ONLY : config_type, &
41       &                       ISolverMcICA, ISolverSpartacus, &
42       &                       ILiquidModelSlingo, ILiquidModelSOCRATES, &
43       &                       IIceModelFu, IIceModelBaran, &
44       &                       IOverlapExponentialRandom
45
46  IMPLICIT NONE
47
48  ! Store configuration information for the radiation scheme in a
49  ! global variable
50  type(config_type) :: rad_config
51
52  ! Ultraviolet weightings
53  INTEGER         :: NWEIGHT_UV
54  INTEGER         :: IBAND_UV(100)
55  REAL(KIND=JPRB) :: WEIGHT_UV(100)
56  ! Photosynthetically active radiation weightings
57  INTEGER         :: NWEIGHT_PAR
58  INTEGER         :: IBAND_PAR(100)
59  REAL(KIND=JPRB) :: WEIGHT_PAR(100)
60
61  ! Background aerosol is specified in an ugly way: using the old
62  ! Tegen fields that are in terms of optical depth, and converted to
63  ! mass mixing ratio via the relevant mass-extinction coefficient
64  INTEGER, PARAMETER :: ITYPE_TROP_BG_AER = 8 ! hydrophobic organic
65  INTEGER, PARAMETER :: ITYPE_STRAT_BG_AER=12 ! non-absorbing sulphate
66  REAL(KIND=JPRB)    :: TROP_BG_AER_MASS_EXT
67  REAL(KIND=JPRB)    :: STRAT_BG_AER_MASS_EXT
68
69CONTAINS
70
71  ! This routine copies information between the LMDZ radiation
72  ! configuration (stored in global variables) and the radiation
73  ! configuration of the modular radiation scheme (stored in
74  ! rad_config).  The optional input logical LOUTPUT controls whether
75  ! to print lots of information during the setup stage (default is
76  ! no).
77! AI At the end of the routine, the parameters are read in namelist
78!   
79  SUBROUTINE SETUP_RADIATION_SCHEME(LOUTPUT)
80
81    USE YOMHOOK,  ONLY : LHOOK, DR_HOOK
82! AI (propre a IFS)   
83!    USE YOMLUN,   ONLY : NULNAM, NULOUT, NULERR
84    USE YOMLUN,   ONLY : NULOUT, NULERR
85    USE YOESRTWN, ONLY : NMPSRTM
86! AI ATTENTION (propre a IFS)
87!    USE YOERAD,   ONLY : YRERAD
88
89    USE radiation_interface,      ONLY : setup_radiation
90!    USE radiation_aerosol_optics, ONLY : dry_aerosol_sw_mass_extinction
91
92! AI (propre a IFS)   
93!#include "posname.intfb.h"
94
95    ! Whether or not to provide information on the radiation scheme
96    ! configuration
97    LOGICAL, INTENT(IN), OPTIONAL :: LOUTPUT
98
99    ! Verbosity of configuration information 0=none, 1=warning,
100    ! 2=info, 3=progress, 4=detailed, 5=debug
101    INTEGER :: IVERBOSESETUP
102    INTEGER :: ISTAT
103
104    REAL(KIND=JPRB) :: ZHOOK_HANDLE
105
106    character(len=512) :: file_name
107
108    logical :: lprint_setp=.TRUE.
109
110    IF (LHOOK) CALL DR_HOOK('RADIATION_SETUP:SETUP_RADIATION_SCHEME',0,ZHOOK_HANDLE)
111
112    ! *** GENERAL SETUP ***
113
114    ! Configure verbosity of setup of radiation scheme
115 
116    print*,'********** Dans radiation_setup *****************'
117
118    IVERBOSESETUP = 4 ! Provide plenty of information
119    IF (PRESENT(LOUTPUT)) THEN
120      IF (.NOT. LOUTPUT) THEN
121        IVERBOSESETUP = 1 ! Warnings and errors only
122      ENDIF
123    ENDIF
124    rad_config%iverbosesetup = IVERBOSESETUP
125    if (lprint_setp) then
126      print*,'Dans radiation_setup '
127      print*,'rad_config%iverbosesetup =', rad_config%iverbosesetup
128    endif
129
130    IF (IVERBOSESETUP > 1) THEN
131      WRITE(NULOUT,'(a)') '-------------------------------------------------------------------------------'
132      WRITE(NULOUT,'(a)') 'RADIATION_SETUP'
133    ENDIF
134
135    ! Normal operation of the radiation scheme displays only errors
136    ! and warnings
137    rad_config%iverbose = 5
138    if (lprint_setp) then
139      print*,'rad_config%iverbose =', rad_config%iverbose
140    endif
141    ! For the time being, ensure a valid default directory name
142    rad_config%directory_name = 'data'
143    if (lprint_setp) then
144      print*,'rad_config%directory_name =', rad_config%directory_name
145    endif
146
147    ! Do we do Hogan and Bozzo (2014) approximate longwave updates?
148! AI ATTENTION (ifs : )
149     ! AI (propre a IFS)
150!    rad_config%do_lw_derivatives = YRERAD%LAPPROXLWUPDATE
151    rad_config%do_lw_derivatives = .false.
152    if (lprint_setp) then
153      print*,'rad_config%do_lw_derivatives =', rad_config%do_lw_derivatives   
154    endif
155
156    ! Surface spectral fluxes are needed for spectral shortwave albedo
157    ! calculation
158! AI ATTENTION test (ifs : T)
159!    rad_config%do_save_spectral_flux = .FALSE.
160    rad_config%do_surface_sw_spectral_flux = .TRUE.
161    if (lprint_setp) then
162      print*,'rad_config%do_surface_sw_spectral_flux =', &
163            rad_config%do_surface_sw_spectral_flux
164    endif
165
166    ! *** SETUP GAS OPTICS ***
167
168! routine below does not have to (ifs : F)
169    print*,'i_gas_model =',rad_config%i_gas_model
170    rad_config%do_setup_ifsrrtm = .TRUE.
171    if (lprint_setp) then
172      print*,'rad_config%do_setup_ifsrrtm =', rad_config%do_setup_ifsrrtm
173    endif
174
175    ! *** SETUP CLOUD OPTICS ***
176
177    ! Setup liquid optics
178! AI ATTENTION
179! Choix offline : liquid_model_name = "SOCRATES"
180      rad_config%i_liq_model = ILiquidModelSOCRATES
181      if (lprint_setp) then
182        print*,'rad_config%i_liq_model =',rad_config%i_liq_model
183      endif
184
185    ! Setup ice optics
186! Choix offline : ice_model_name    = "Fu-IFS"
187      rad_config%i_ice_model = IIceModelFu
188      if (lprint_setp) then
189        print*,'rad_config%i_ice_model =', rad_config%i_ice_model
190      endif
191
192! AI (propre a IFS)     
193    ! For consistency with earlier versions of the IFS radiation
194    ! scheme, we perform shortwave delta-Eddington scaling *after* the
195    ! merge of the cloud, aerosol and gas optical properties.  Set
196    ! this to "false" to do the scaling on the cloud and aerosol
197    ! properties separately before merging with gases. Note that this
198    ! is not compatible with the SPARTACUS solver.
199    rad_config%do_sw_delta_scaling_with_gases = .FALSE.
200    if (lprint_setp) then
201      print*,'rad_config%do_sw_delta_scaling_with_gases =', &
202            rad_config%do_sw_delta_scaling_with_gases
203    endif
204
205! AI (propre a IFS)   
206    ! Use Exponential-Exponential cloud overlap to match original IFS
207    ! implementation of Raisanen cloud generator
208    rad_config%i_overlap_scheme = IOverlapExponentialRandom
209    if (lprint_setp) then
210      print*,'rad_config%i_overlap_scheme =', rad_config%i_overlap_scheme
211    endif
212
213    ! *** SETUP AEROSOLS ***
214! AI ATTENTION
215!    rad_config%use_aerosols = .TRUE. !(ifs)
216    rad_config%use_aerosols = .FALSE.
217    if (lprint_setp) then
218      print*,'rad_config%use_aerosols =', rad_config%use_aerosols
219    endif
220
221! *** SETUP SOLVER ***
222
223    ! 3D effects are off by default (ifs)
224    rad_config%do_3d_effects = .TRUE.
225    if (lprint_setp) then
226      print*,'rad_config%do_3d_effects=', rad_config%do_3d_effects
227    endif
228
229    ! Select longwave solver
230! AI ATTENTION
231      rad_config%i_solver_lw = ISolverSpartacus
232      if (lprint_setp) then
233        print*,'rad_config%i_solver_lw =', rad_config%i_solver_lw
234      endif
235
236      rad_config%i_solver_sw = ISolverSpartacus
237      if (lprint_setp) then
238        print*,'rad_config%i_solver_sw =', rad_config%i_solver_sw
239      endif
240
241    ! SPARTACUS solver requires delta scaling to be done separately
242    ! for clouds & aerosols
243    IF (rad_config%i_solver_sw == ISolverSpartacus) THEN
244      rad_config%do_sw_delta_scaling_with_gases = .FALSE.
245    ENDIF
246
247    ! Do we represent longwave scattering?
248    rad_config%do_lw_cloud_scattering = .TRUE.
249    rad_config%do_lw_aerosol_scattering = .TRUE.
250    if (lprint_setp) then
251      print*,'rad_config%do_lw_cloud_scattering =', &
252           rad_config%do_lw_cloud_scattering
253      print*,'rad_config%do_lw_aerosol_scattering =', &
254           rad_config%do_lw_aerosol_scattering
255    endif
256
257    ! *** IMPLEMENT SETTINGS ***
258
259    ! For advanced configuration, the configuration data for the
260    ! "radiation" project can specified directly in the namelist.
261    ! However, the variable naming convention is not consistent with
262    ! the rest of the IFS.  For basic configuration there are specific
263    ! variables in the NAERAD namelist available in the YRERAD
264    ! structure.
265
266! AI ATTENTION (parameters read in namelist file)
267    file_name="namelist_ecrad"
268    call rad_config%read(file_name=file_name)
269
270    ! Use configuration data to set-up radiation scheme, including
271    ! reading scattering datafiles
272    CALL setup_radiation(rad_config)
273
274    ! Populate the mapping between the 14 RRTM shortwave bands and the
275    ! 6 albedo inputs. The mapping according to the stated wavelength
276    ! ranges of the 6-band model does not match the hard-wired mapping
277    ! in NMPSRTM, but only the hard-wired values produce sensible
278    ! results...
279    ! Note that NMPSRTM(:)=(/  6, 6, 5, 5, 5, 5, 5, 4, 4, 3, 2, 2, 1, 6 /)
280! AI (6 albedo SW bands)
281    call rad_config%define_sw_albedo_intervals(6, &
282       &  [0.25e-6_jprb, 0.44e-6_jprb, 0.69e-6_jprb, &
283       &   1.19e-6_jprb, 2.38e-6_jprb], [1,2,3,4,5,6])
284    ! Likewise between the 16 RRTM longwave bands and the 2 emissivity
285    ! inputs (info taken from rrtm_ecrt_140gp_mcica.F90) representing
286    ! outside and inside the window region of the spectrum
287!     rad_config%i_emiss_from_band_lw = (/ 1,1,1,1,1,2,2,2,1,1,1,1,1,1,1,1 /)
288! AI ATTENTION ?????
289!!    call rad_config%define_lw_emiss_intervals(3, &
290!!         &  (/ 8.0e-6_jprb,13.0e-6_jprb /),  (/ 1,2,1 /))
291
292!    ! Get spectral weightings for UV and PAR
293    call rad_config%get_sw_weights(0.2e-6_jprb, 0.4415e-6_jprb, &
294         &  NWEIGHT_UV, IBAND_UV, WEIGHT_UV, 'ultraviolet')
295    call rad_config%get_sw_weights(0.4e-6_jprb, 0.7e-6_jprb, &
296         &  NWEIGHT_PAR, IBAND_PAR, WEIGHT_PAR, &
297         &  'photosynthetically active radiation, PAR')
298
299     rad_config%i_aerosol_type_map(1:13) = (/ &
300           &  -1, &  ! Sea salt, size bin 1 (OPAC)
301           &  -2, &  ! Sea salt, size bin 2 (OPAC)
302           &  -3, &  ! Sea salt, size bin 3 (OPAC)
303           &  -4, &  ! Hydrophilic organic matter (OPAC)
304           &  -5, &  ! Ammonium sulphate (OPAC)
305           &  -6, &
306           &  -7, &
307           &   1, &
308           &   2, &
309           &   3, &
310           &  -8, &
311           &  -9, &
312           &   4 /)  ! Stratospheric sulphate (hand edited from OPAC)
313   rad_config%aerosol_optics_override_file_name = 'aerosol_optics_lmdz.nc'
314
315!    IF (YRERAD%NAERMACC > 0) THEN
316      ! With the MACC aerosol climatology we need to add in the
317      ! background aerosol afterwards using the Tegen arrays.  In this
318      ! case we first configure the background aerosol mass-extinction
319      ! coefficient at 550 nm, which corresponds to the 10th RRTMG
320      ! shortwave band.
321!      TROP_BG_AER_MASS_EXT  = dry_aerosol_sw_mass_extinction(rad_config, &
322!           &                                   ITYPE_TROP_BG_AER, 10)
323!      STRAT_BG_AER_MASS_EXT = dry_aerosol_sw_mass_extinction(rad_config, &
324!           &                                   ITYPE_STRAT_BG_AER, 10)
325     
326!      WRITE(NULOUT,'(a,i0)') 'Tropospheric bacground uses aerosol type ', &
327!           &                 ITYPE_TROP_BG_AER
328!      WRITE(NULOUT,'(a,i0)') 'Stratospheric bacground uses aerosol type ', &
329!           &                 ITYPE_STRAT_BG_AER
330!    ENDIF     
331     
332    IF (IVERBOSESETUP > 1) THEN
333      WRITE(NULOUT,'(a)') '-------------------------------------------------------------------------------'
334    ENDIF
335
336    IF (LHOOK) CALL DR_HOOK('RADIATION_SETUP:SETUP_RADIATION_SCHEME',1,ZHOOK_HANDLE)
337
338  END SUBROUTINE SETUP_RADIATION_SCHEME
339
340END MODULE RADIATION_SETUP
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