-
Notifications
You must be signed in to change notification settings - Fork 14
/
README
318 lines (278 loc) · 18.5 KB
/
README
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
! path: $Source$
! author: $Author: mike $
! revision: $Revision: 11661 $
! created: $Date: 2009-05-22 18:22:22 -0400 (Fri, 22 May 2009) $
!------------------------------------------------------------------------
RRTMG_SW: Shortwave Radiative Transfer Model for GCMs
Atmospheric and Environmental Research,
131 Hartwell Avenue, Lexington, MA 02421
Original version: Eli. J. Mlawer, J. S. Delamere, et al. (AER)
Revision for GCMs: Michael J. Iacono (AER)
Contact: Michael J. Iacono (E-mail: miacono@aer.com)
Web Sites: https://github.com/AER-RC/RRTMG_SW
https://www.rtweb.aer.com
References (RRTMG_SW/RRTM_SW):
Iacono, M.J., J.S. Delamere, E.J. Mlawer, M.W. Shephard,
S.A. Clough, and W.D. Collins, Radiative forcing by long-
lived greenhouse gases: Calculations with the AER radiative
transfer models, J. Geophys. Res., 113, D13103, doi:
10.1029/2008JD009944, 2008.
Clough, S.A., M.W. Shephard, E.J. Mlawer, J.S. Delamere,
M.J. Iacono, K. Cady-Pereira, S. Boukabara, and P.D. Brown,
Atmospheric radiative transfer modeling: a summary of the
AER codes, J. Quant. Spectrosc. Radiat. Transfer, 91,
233-244, 2005.
Reference (McICA):
Pincus, R., H. W. Barker, and J.-J. Morcrette, A fast, flexible,
approximation technique for computing radiative transfer in
inhomogeneous cloud fields, J. Geophys. Res., 108(D13), 4376,
doi:10.1029/2002JD003322, 2003.
Reference (Latitude-Varying Decorrelation Length):
Oreopoulos, L., D. Lee, Y.C. Sud, and M.J. Suarez, Radiative
impacts of cloud heterogeneity and overlap in an atmospheric
General Circulation Model, Atmos. Chem. Phys., 12, 9097-9111,
doi:10.5194/acp-12-9097-2012, 2012.
******************************************************************************
This package contains the source code and sample makefiles necessary to run the
latest version of RRTMG_SW, a correlated k-distribution shortwave radiative transfer
model developed at AER for application to GCMs. This version of RRTMG_SW
utilizes a two-stream radiative transfer method as implemented at ECMWF. This
code has also been modified to utilize updated FORTRAN coding features. Two modes
of operation are possible: 1) RRTMG_SW can be run as a column model using the
input files and source modules described below, or 2) it can be implemented as a
subroutine into an atmospheric general circulation model or single column model.
The version of RRTMG_SW provided here utilizes a reduced complement of 112
g-points, which is half of the 224 g-points used in the standard RRTM_SW, and
a two-stream method for radiative transfer. Additional minor changes have been
made to enhance computational performance. Total fluxes are accurate to within
1-2 W/m2 relative to the standard RRTM_SW (using DISORT) in clear sky and in the
presence of aerosols and within 6 W/m2 in overcast sky. RRTM_SW with DISORT is
itself accurate to within 2 W/m2 of the data-validated multiple scattering
model, CHARTS. Required absorption coefficient input data can be read in either
from data stored within the code or from a netCDF file as selected in the makefile.
This model can also utilize McICA, the Monte-Carlo Independent Column
Approximation, to represent sub-grid scale cloud variability such as cloud
fraction and cloud overlap. If the McICA option is selected to model a cloudy
profile in column mode, then the model will run stochastically, and the output
fluxes and heating rates will be an average over 200 samples. In GCM mode,
the code will calcualte a single column per profile, and the statistical basis
is provided by the spatial and temporal dimensions of the 3-D calculations.
Several cloud overlap methods are available for partial cloudiness including
maximum-random, exponential, and exponential-random. Without McICA, RRTMG_SW
is limited to clear sky or overcast cloud conditions.
*************************
RRTMG_SW : Column Version
*************************
DOCUMENTATION:
The following text files (some in the /doc directory) provide information
on release updates and on using and running RRTMG_SW:
README : Basic code package information (this file)
release_notes.txt : Code archive update information
rrtmg_sw_instructions.txt : Input instructions for files INPUT_RRTM, IN_CLD_RRTM
and IN_AER_RRTM
SOURCE CODE:
The following source files (in the /src directory) must be used to run
RRTMG_SW in stand-alone mode as a column model (the utility files are stored
separately in the /aer_rt_utils directory):
rrtmg_sw.1col.f90 : Main module
rrtmg_sw_cldprop.f90 : Calculation of cloud optical properties
rrtmg_sw_cldprmc.f90 : Calculation of cloud optical properties (McICA)
rrtmg_sw_init.f90 : RRTMG_SW initialization routine; reduces g-intervals
from 224 to 112
rrtmg_sw_k_g.f90 : Absorption coefficient data file
rrtmg_sw_read_nc.f90 : Optional absorption coefficient data netCDF input
rrtmg_sw_reftra.f90 : Calculation of two-stream reflectivities and
transmissivities
rrtmg_sw_setcoef.f90 : Set up routine
rrtmg_sw_spcvrt.f90 : Top subroutine for two-stream model
rrtmg_sw_spcvmc.f90 : Top subroutine for two-stream model (McICA)
rrtmg_sw_taumol.f90 : Calculation of optical depths and Planck fractions for
each spectral band
rrtmg_sw_vrtqdr.f90 : Two-stream vertical quadrature
mcica_random_numbers.f90 : Random number generator for McICA
mcica_subcol_gen_sw.1col.f90 : Sub-column generator for McICA
rrtatm.f : Process user-defined input data files
extra.f : Process input data files
util_**.f : Utilities (available for multiple platforms)
The following module files (in the /modules directory) must be used to run
RRTMG_SW in stand-alone mode as a column model (these must be compiled before the
source code files):
parkind.f90 : real and integer kind type parameters
parrrsw.f90 : main configuration parameters
rrsw_aer.f90 : aerosol property coefficients
rrsw_cld.f90 : cloud property coefficients
rrsw_con.f90 : constants
rrsw_kg**.f90 : absorption coefficient arrays for 16 spectral bands
rrsw_ncpar.f90 : parameters for netCDF input data option
rrsw_ref.f90 : reference atmosphere data arrays
rrsw_tbl.f90 : exponential lookup table arrays
rrsw_vsn.f90 : version number information
rrsw_wvn.f90 : spectral band and g-interval array information
INPUT DATA:
The following file (in the /data directory) is the optional netCDF input file
containing absorption coefficient and other input data for the model.
The file is used if keyword KGSRC is set for netCDF input in the makefile.
rrtmg_sw.nc : Optional netCDF input data file
MAKEFILES:
The following files (in /build/makefiles directory) can be used to compile
RRTMG_SW in stand-alone mode as a column model on various platforms. Link
one of these into the /build directory to compile.
make_rrtmg_sw_sgi : Sample makefile for SGI
make_rrtmg_sw_sun : Sample makefile for SUN
make_rrtmg_sw_linux_pgi : Sample makefile for LINUX (PGI compiler)
make_rrtmg_sw_aix_xlf90 : Sample makefile for AIX (XLF90 compiler)
make_rrtmg_sw_OS_X_g95 : Sample makefile for OS_X (G95 compiler)
make_rrtmg_sw_OS_X_ibm_xl : Sample makefile for OS_X (IBM XL compiler)
SAMPLE INPUT/OUTPUT:
Several sample input (and output) files are included in the /runs_std_atm directory.
Note that user-defined profiles may be used for as many as 200 layers.
INPUT_RRTM : Required input file for (clear sky) atmospheric
specification
IN_CLD_RRTM : Required input file for cloud specification if clouds
are present
IN_AER_RRTM : Required input file for aerosol specification if aerosols
are present
OUTPUT_RRTM : Main output file for atmospheric fluxes and heating rates
input_rrtm.MLS-clr : Sample 51 layer mid-latitude summer standard atmosphere
input_rrtm.MLS-cld-imca0-icld2
: Sample 51 layer mid-latitude summer standard atmosphere
with cloud flag turned on and maximum-random cloud
overlap selected (without McICA)
input_rrtm.MLS-cld-imca1-icld2
: Sample 51 layer mid-latitude summer standard atmosphere
with cloud flag turned on and maximum-random cloud
overlap selected (with McICA)
input_rrtm.MLS-cld-imca1-icld5-idcor0
: Sample 51 layer mid-latitude summer standard atmosphere
with cloud flag turned on and exponential-random cloud overlap
and constant decorrelation length selected (with McICA)
input_rrtm.MLS-cld-imca1-icld5-idcor1
: Sample 51 layer mid-latitude summer standard atmosphere
with cloud flag turned on and exponential-random cloud overlap
and varying decorrelation length selected (with McICA)
input_rrtm.MLS-clr-aer12 : Sample 51 layer mid-latitude summer standard atmosphere
with aerosol flag set
input_rrtm.MLS-clr-sza45-isolvar0_tsi_avg
: Sample 51 layer mid-latitude summer standard atmosphere
with solar zenith angle set to 45 degrees and using the
NRLSSI2 solar source function with total solar irradiance
for the mean solar cycle with no solar variability
input_rrtm.MLS-clr-sza45-isolvar1_tsi_max
: Sample 51 layer mid-latitude summer standard atmosphere
with solar zenith angle set to 45 degrees and using the
NRLSSI2 solar source function with solar variability
active and with total solar irradiance near the maximum
in the mean solar cycle
input_rrtm.MLS-clr-sza45-isolvar1_tsi_min
: Sample 51 layer mid-latitude summer standard atmosphere
with solar zenith angle set to 45 degrees and using the
NRLSSI2 solar source function with solar variability
active and with total solar irradiance near the minimum
in the mean solar cycle
input_rrtm.MLS-clr-sza45-isolvar2_01Jan1950
: Sample 51 layer mid-latitude summer standard atmosphere
with solar zenith angle set to 45 degrees and using the
NRLSSI2 solar source function with solar variability
active and with total solar irradiance specified with
facular and sunspot indices for 1 January 1950
input_rrtm.MLS-clr-sza45-isolvar3_bndscl_tsi_max
: Sample 51 layer mid-latitude summer standard atmosphere
with solar zenith angle set to 45 degrees and using the
NRLSSI2 solar source function with solar variability
active and with total solar irradiance near the maximum
in the mean solar cycle scaled to a different value
with individual band scaling factors
input_rrtm.MLW-clr : Sample 51 layer mid-latitude winter standard atmosphere
input_rrtm.SAW-clr : Sample 51 layer sub-arctic winter standard atmosphere
input_rrtm.TROP-clr : Sample 51 layer tropical standard atmosphere
in_cld_rrtm-cld5 : Sample cloud input file
in_cld_rrtm-cld6 : Sample cloud input file
in_cld_rrtm-cld7 : Sample cloud input file
in_aer_rrtm-aer12 : Sample aerosol input file
script.run_std_atm : UNIX script for running the full suite of example cases,
which will put the output into similarly named files
prefixed with output_rrtm*
INSTRUCTIONS FOR COMPILING AND RUNNING THE COLUMN MODEL:
1) In the /build directory, link one of the makefiles from the /makefile sub-directory
into /build/make.build. To use the optional netCDF input file, switch the keyword
"KGSRC" in the makefile from "dat" to "nc". Compile the model with "make -f make.build"
2) Link the executable to, for example, "rrtmg_sw" in the /runs_std_atm directory
3) If the optional netCDF input file was selected when compiling, link the file
/data/rrtmg_sw.nc into the /runs_std_atm directory.
4) In the /runs_std_atm directory, run the UNIX script "./script.run_std_atm" to run
the full suite of example cases. To run a single case, modify INPUT_RRTM following the
instructions in /doc/rrtmg_sw_instructions.txt", or copy one of the example input_rrtm*
files into INPUT_RRTM. If clouds are selected (ICLD > 0), then modify IN_CLD_RRTM or
copy one of the in_cld_rrtm* files into IN_CLD_RRTM. If aerosols are selected
(IAER > 0), then modify IN_AER_RRTM or set it to the sample file in_aer_rrtm-aer12.
5) In column mode, if McICA is selected (IMCA=1) with partial cloudiness defined, then
RRTMG_SW will run the case 200 times to derive adequate statistics, and the average
of the 200 samples will be written to the output file, OUTPUT_RRTM.
**********************
RRTMG_SW : GCM version
**********************
DOCUMENTATION:
README : Basic code package information (this file)
SOURCE CODE:
The following source files (in the /src directory) must be used to run RRTMG_SW
as a callable subroutine:
NOTE: Only one of rrtmg_sw_k_g.f90 or rrtmg_sw_read_nc.f90 is required.
rrtmg_sw_rad.f90 : RRTMG_SW main module (with McICA)
rrtmg_sw_rad.nomcica.f90 : Optional RRTMG_SW main module (without McICA only)
rrtmg_sw_cldprop.f90 : Calculation of cloud optical properties
rrtmg_sw_cldprmc.f90 : Calculation of cloud optical properties (McICA)
rrtmg_sw_init.f90 : RRTMG_SW initialization routine; reduces g-intervals
from 224 to 112; (This has to run only once and should
be installed in the GCM initialization section)
rrtmg_sw_k_g.f90 : Absorption coefficient data file
rrtmg_sw_read_nc.f90 : Alternate absorption coefficient data netCDF input
rrtmg_sw_reftra.f90 : Calculation of two-stream reflectivities and
transmissivities
rrtmg_sw_setcoef.f90 : Set up routine
rrtmg_sw_spcvrt.f90 : Top subroutine for two-stream model
rrtmg_sw_spcvmc.f90 : Top subroutine for two-stream model (McICA)
rrtmg_sw_taumol.f90 : Calculation of optical depths and Planck fractions for
each spectral band
rrtmg_sw_vrtqdr.f90 : Two-stream vertical quadrature
mcica_random_numbers.f90 : Random number generator for McICA
mcica_subcol_gen_sw.f90 : Sub-column generator for McICA
The following module files (in the /modules directory) must be used to run
RRTMG_SW as a callable subroutine (these must be compiled before the source code)
parkind.f90 : real and integer kind type parameters
parrrsw.f90 : main configuration parameters
rrsw_aer.f90 : aerosol property coefficients
rrsw_cld.f90 : cloud property coefficients
rrsw_con.f90 : constants
rrsw_kg**.f90 : absorption coefficient arrays for 16 spectral bands
rrsw_ncpar.f90 : parameters for netCDF input data option
rrsw_ref.f90 : reference atmosphere data arrays
rrsw_tbl.f90 : exponential lookup table arrays
rrsw_vsn.f90 : version number information
rrsw_wvn.f90 : spectral band and g-interval array information
INPUT DATA:
The following file (in the /data directory) is the optional netCDF file
containing absorption coefficient and other input data for the model.
The file is used if source file rrtmg_sw_read_nc.f90 is used in place
of rrtmg_sw_k_g.f90 (only one or the other is required).
rrtmg_sw.nc : Optional netCDF input data file
NOTES ON RUNNING THE GCM (SUBROUTINE) VERSION OF THE CODE:
1) The module rrtmg_sw_init.f90 is the initialization routine that has to be
called only once. The call to this subroutine should be moved to the
initialization section of the host model if RRTMG_SW is called by a GCM or SCM.
2) The number of model layers and the number of columns to be looped over should
be passed into RRTMG_SW through the subroutine call along with the other model
profile arrays.
3) To utilize McICA, the sub-column generator (mcica_subcol_gen_sw.f90) must be
implemented in the GCM so that it is called just before RRTMG_SW. The cloud
overlap method is selected using the input flag, icld. If either exponential
(ICLD=4) or exponential-random (ICLD=5) cloud overlap is selected, then the
subroutine "get_alpha" must be called prior to calling "mcica_subcol_sw" to
define the vertical correlation parameter, alpha, needed for those overlap
methods. Also for those methods, use the input flag "idcor" to select the use
of either a constant or latitude-varying decorrelation length.
If McICA is utilized, this will run only a single statistical sample per
model grid box. There are two options for the random number generator used
with McICA, which is selected with the variable irnd in mcica_subcol_gen_sw.f90.
When using McICA, then the main module is rrtmg_sw_rad.f90. If McICA is not used,
then the main module is rrtmg_sw_rad.nomcica.f90, though the cloud specification
is limited to overcast clouds.