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srtm_setcoef.F90 @ 4190

Last change on this file since 4190 was 3908, checked in by idelkadi, 3 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: 8.9 KB

Line
1	SUBROUTINE SRTM_SETCOEF &
2	& ( KIDIA , KFDIA , KLEV ,&
3	& PAVEL , PTAVEL ,&
4	& PCOLDRY , PWKL ,&
5	& KLAYTROP,&
6	& PCOLCH4 , PCOLCO2 , PCOLH2O , PCOLMOL , PCOLO2 , PCOLO3 ,&
7	& PFORFAC , PFORFRAC , KINDFOR , PSELFFAC, PSELFFRAC, KINDSELF ,&
8	& PFAC00 , PFAC01 , PFAC10 , PFAC11 ,&
9	& KJP , KJT , KJT1 , PRMU0 &
10	& )
11
12	! J. Delamere, AER, Inc. (version 2.5, 02/04/01)
13
14	! Modifications:
15	! JJMorcrette 030224 rewritten / adapted to ECMWF F90 system
16	! M.Hamrud 01-Oct-2003 CY28 Cleaning
17	! D.Salmond 31-Oct-2007 Vector version in the style of RRTM from Meteo France & NEC
18
19	! Purpose: For a given atmosphere, calculate the indices and
20	! fractions related to the pressure and temperature interpolations.
21
22	USE PARKIND1 , ONLY : JPIM, JPRB
23	USE YOMHOOK , ONLY : LHOOK, DR_HOOK
24	USE YOESRTWN , ONLY : PREFLOG, TREF
25	!! USE YOESWN , ONLY : NDBUG
26
27	IMPLICIT NONE
28
29	!-- Input arguments
30
31	INTEGER(KIND=JPIM),INTENT(IN) :: KIDIA, KFDIA
32	INTEGER(KIND=JPIM),INTENT(IN) :: KLEV
33	REAL(KIND=JPRB) ,INTENT(IN) :: PAVEL(KIDIA:KFDIA,KLEV)
34	REAL(KIND=JPRB) ,INTENT(IN) :: PTAVEL(KIDIA:KFDIA,KLEV)
35	REAL(KIND=JPRB) ,INTENT(IN) :: PCOLDRY(KIDIA:KFDIA,KLEV)
36	REAL(KIND=JPRB) ,INTENT(IN) :: PWKL(KIDIA:KFDIA,35,KLEV)
37	INTEGER(KIND=JPIM),INTENT(OUT) :: KLAYTROP(KIDIA:KFDIA)
38	REAL(KIND=JPRB) ,INTENT(OUT) :: PCOLCH4(KIDIA:KFDIA,KLEV)
39	REAL(KIND=JPRB) ,INTENT(OUT) :: PCOLCO2(KIDIA:KFDIA,KLEV)
40	REAL(KIND=JPRB) ,INTENT(OUT) :: PCOLH2O(KIDIA:KFDIA,KLEV)
41	REAL(KIND=JPRB) ,INTENT(OUT) :: PCOLMOL(KIDIA:KFDIA,KLEV)
42	REAL(KIND=JPRB) ,INTENT(OUT) :: PCOLO2(KIDIA:KFDIA,KLEV)
43	REAL(KIND=JPRB) ,INTENT(OUT) :: PCOLO3(KIDIA:KFDIA,KLEV)
44	REAL(KIND=JPRB) ,INTENT(OUT) :: PFORFAC(KIDIA:KFDIA,KLEV)
45	REAL(KIND=JPRB) ,INTENT(OUT) :: PFORFRAC(KIDIA:KFDIA,KLEV)
46	INTEGER(KIND=JPIM),INTENT(OUT) :: KINDFOR(KIDIA:KFDIA,KLEV)
47	REAL(KIND=JPRB) ,INTENT(OUT) :: PSELFFAC(KIDIA:KFDIA,KLEV)
48	REAL(KIND=JPRB) ,INTENT(OUT) :: PSELFFRAC(KIDIA:KFDIA,KLEV)
49	INTEGER(KIND=JPIM),INTENT(OUT) :: KINDSELF(KIDIA:KFDIA,KLEV)
50	REAL(KIND=JPRB) ,INTENT(OUT) :: PFAC00(KIDIA:KFDIA,KLEV)
51	REAL(KIND=JPRB) ,INTENT(OUT) :: PFAC01(KIDIA:KFDIA,KLEV)
52	REAL(KIND=JPRB) ,INTENT(OUT) :: PFAC10(KIDIA:KFDIA,KLEV)
53	REAL(KIND=JPRB) ,INTENT(OUT) :: PFAC11(KIDIA:KFDIA,KLEV)
54	INTEGER(KIND=JPIM),INTENT(OUT) :: KJP(KIDIA:KFDIA,KLEV)
55	INTEGER(KIND=JPIM),INTENT(OUT) :: KJT(KIDIA:KFDIA,KLEV)
56	INTEGER(KIND=JPIM),INTENT(OUT) :: KJT1(KIDIA:KFDIA,KLEV)
57	REAL(KIND=JPRB) ,INTENT(IN) :: PRMU0(KIDIA:KFDIA)
58	!-- Output arguments
59
60	!-- local integers
61
62	INTEGER(KIND=JPIM) :: I_NLAYERS, JK, JL, JP1
63
64	!-- local reals
65
66	REAL(KIND=JPRB) :: Z_STPFAC, Z_PLOG
67	REAL(KIND=JPRB) :: Z_FP, Z_FT, Z_FT1, Z_WATER, Z_SCALEFAC
68	REAL(KIND=JPRB) :: Z_FACTOR, Z_CO2REG, Z_COMPFP
69	!REAL(KIND=JPRB) :: Z_TBNDFRAC, Z_T0FRAC
70	REAL(KIND=JPRB) :: ZHOOK_HANDLE
71
72
73
74
75	ASSOCIATE(NFLEVG=>KLEV)
76	IF (LHOOK) CALL DR_HOOK('SRTM_SETCOEF',0,ZHOOK_HANDLE)
77
78	Z_STPFAC = 296._JPRB/1013._JPRB
79	I_NLAYERS = KLEV
80
81	DO JL = KIDIA, KFDIA
82	IF (PRMU0(JL) > 0.0_JPRB) THEN
83	KLAYTROP(JL) = 0
84	ENDIF
85	ENDDO
86
87	DO JK = 1, I_NLAYERS
88	DO JL = KIDIA, KFDIA
89	IF (PRMU0(JL) > 0.0_JPRB) THEN
90	! Find the two reference pressures on either side of the
91	! layer pressure. Store them in JP and JP1. Store in FP the
92	! fraction of the difference (in ln(pressure)) between these
93	! two values that the layer pressure lies.
94
95	Z_PLOG = LOG(PAVEL(JL,JK))
96	KJP(JL,JK) = INT(36._JPRB - 5._JPRB*(Z_PLOG+0.04_JPRB))
97	IF (KJP(JL,JK) < 1) THEN
98	KJP(JL,JK) = 1
99	ELSEIF (KJP(JL,JK) > 58) THEN
100	KJP(JL,JK) = 58
101	ENDIF
102	JP1 = KJP(JL,JK) + 1
103	Z_FP = 5. * (PREFLOG(KJP(JL,JK)) - Z_PLOG)
104
105	! Determine, for each reference pressure (JP and JP1), which
106	! reference temperature (these are different for each
107	! reference pressure) is nearest the layer temperature but does
108	! not exceed it. Store these indices in JT and JT1, resp.
109	! Store in FT (resp. FT1) the fraction of the way between JT
110	! (JT1) and the next highest reference temperature that the
111	! layer temperature falls.
112
113	KJT(JL,JK) = INT(3. + (PTAVEL(JL,JK)-TREF(KJP(JL,JK)))/15.)
114	IF (KJT(JL,JK) < 1) THEN
115	KJT(JL,JK) = 1
116	ELSEIF (KJT(JL,JK) > 4) THEN
117	KJT(JL,JK) = 4
118	ENDIF
119	Z_FT = ((PTAVEL(JL,JK)-TREF(KJP(JL,JK)))/15.) - REAL(KJT(JL,JK)-3)
120	KJT1(JL,JK) = INT(3. + (PTAVEL(JL,JK)-TREF(JP1))/15.)
121	IF (KJT1(JL,JK) < 1) THEN
122	KJT1(JL,JK) = 1
123	ELSEIF (KJT1(JL,JK) > 4) THEN
124	KJT1(JL,JK) = 4
125	ENDIF
126	Z_FT1 = ((PTAVEL(JL,JK)-TREF(JP1))/15.) - REAL(KJT1(JL,JK)-3)
127
128	Z_WATER = PWKL(JL,1,JK)/PCOLDRY(JL,JK)
129	Z_SCALEFAC = PAVEL(JL,JK) * Z_STPFAC / PTAVEL(JL,JK)
130
131	! If the pressure is less than ~100mb, perform a different
132	! set of species interpolations.
133
134	IF (Z_PLOG <= 4.56_JPRB) GO TO 5300
135	KLAYTROP(JL) = KLAYTROP(JL) + 1
136
137	! Set up factors needed to separately include the water vapor
138	! foreign-continuum in the calculation of absorption coefficient.
139
140	PFORFAC(JL,JK) = Z_SCALEFAC / (1.+Z_WATER)
141	Z_FACTOR = (332.0-PTAVEL(JL,JK))/36.0
142	KINDFOR(JL,JK) = MIN(2, MAX(1, INT(Z_FACTOR)))
143	PFORFRAC(JL,JK) = Z_FACTOR - REAL(KINDFOR(JL,JK))
144
145	! Set up factors needed to separately include the water vapor
146	! self-continuum in the calculation of absorption coefficient.
147
148	PSELFFAC(JL,JK) = Z_WATER * PFORFAC(JL,JK)
149	Z_FACTOR = (PTAVEL(JL,JK)-188.0)/7.2
150	KINDSELF(JL,JK) = MIN(9, MAX(1, INT(Z_FACTOR)-7))
151	PSELFFRAC(JL,JK) = Z_FACTOR - REAL(KINDSELF(JL,JK) + 7)
152
153	! Calculate needed column amounts.
154
155	PCOLH2O(JL,JK) = 1.E-20 * PWKL(JL,1,JK)
156	PCOLCO2(JL,JK) = 1.E-20 * PWKL(JL,2,JK)
157	PCOLO3(JL,JK) = 1.E-20 * PWKL(JL,3,JK)
158	! COLO3(LAY) = 0.
159	! COLO3(LAY) = colo3(lay)/1.16
160	PCOLCH4(JL,JK) = 1.E-20 * PWKL(JL,6,JK)
161	PCOLO2(JL,JK) = 1.E-20 * PWKL(JL,7,JK)
162	PCOLMOL(JL,JK) = 1.E-20 * PCOLDRY(JL,JK) + PCOLH2O(JL,JK)
163	! colco2(lay) = 0.
164	! colo3(lay) = 0.
165	! colch4(lay) = 0.
166	! colo2(lay) = 0.
167	! colmol(lay) = 0.
168	IF (PCOLCO2(JL,JK) == 0.) PCOLCO2(JL,JK) = 1.E-32 * PCOLDRY(JL,JK)
169	IF (PCOLCH4(JL,JK) == 0.) PCOLCH4(JL,JK) = 1.E-32 * PCOLDRY(JL,JK)
170	IF (PCOLO2(JL,JK) == 0.) PCOLO2(JL,JK) = 1.E-32 * PCOLDRY(JL,JK)
171	! Using E = 1334.2 cm-1.
172	Z_CO2REG = 3.55E-24 * PCOLDRY(JL,JK)
173	GO TO 5400
174
175	! Above LAYTROP.
176	5300 CONTINUE
177
178	! Set up factors needed to separately include the water vapor
179	! foreign-continuum in the calculation of absorption coefficient.
180
181	PFORFAC(JL,JK) = Z_SCALEFAC / (1.+Z_WATER)
182	Z_FACTOR = (PTAVEL(JL,JK)-188.0)/36.0
183	KINDFOR(JL,JK) = 3
184	PFORFRAC(JL,JK) = Z_FACTOR - 1.0
185
186	! Calculate needed column amounts.
187
188	PCOLH2O(JL,JK) = 1.E-20 * PWKL(JL,1,JK)
189	PCOLCO2(JL,JK) = 1.E-20 * PWKL(JL,2,JK)
190	PCOLO3(JL,JK) = 1.E-20 * PWKL(JL,3,JK)
191	PCOLCH4(JL,JK) = 1.E-20 * PWKL(JL,6,JK)
192	PCOLO2(JL,JK) = 1.E-20 * PWKL(JL,7,JK)
193	PCOLMOL(JL,JK) = 1.E-20 * PCOLDRY(JL,JK) + PCOLH2O(JL,JK)
194	IF (PCOLCO2(JL,JK) == 0.) PCOLCO2(JL,JK) = 1.E-32 * PCOLDRY(JL,JK)
195	IF (PCOLCH4(JL,JK) == 0.) PCOLCH4(JL,JK) = 1.E-32 * PCOLDRY(JL,JK)
196	IF (PCOLO2(JL,JK) == 0.) PCOLO2(JL,JK) = 1.E-32 * PCOLDRY(JL,JK)
197	Z_CO2REG = 3.55E-24 * PCOLDRY(JL,JK)
198
199	PSELFFAC(JL,JK) =0.0_JPRB
200	PSELFFRAC(JL,JK)=0.0_JPRB
201	KINDSELF(JL,JK) = 0
202
203	5400 CONTINUE
204
205	! We have now isolated the layer ln pressure and temperature,
206	! between two reference pressures and two reference temperatures
207	! (for each reference pressure). We multiply the pressure
208	! fraction FP with the appropriate temperature fractions to get
209	! the factors that will be needed for the interpolation that yields
210	! the optical depths (performed in routines TAUGBn for band n).
211
212	Z_COMPFP = 1. - Z_FP
213	PFAC10(JL,JK) = Z_COMPFP * Z_FT
214	PFAC00(JL,JK) = Z_COMPFP * (1. - Z_FT)
215	PFAC11(JL,JK) = Z_FP * Z_FT1
216	PFAC01(JL,JK) = Z_FP * (1. - Z_FT1)
217
218	! IF (NDBUG.LE.3) THEN
219	! print 9000,LAY,LAYTROP,JP(LAY),JT(LAY),JT1(LAY),TAVEL(LAY) &
220	! &,FAC00(LAY),FAC01(LAY),FAC10(LAY),FAC11(LAY) &
221	! &,COLMOL(LAY),COLCH4(LAY),COLCO2(LAY),COLH2O(LAY) &
222	! &,COLO2(LAY),COLO3(LAY),SELFFAC(LAY),SELFFRAC(LAY) &
223	! &,FORFAC(LAY),FORFRAC(LAY),INDSELF(LAY),INDFOR(LAY)
224	9000 format(1x,2I3,3I4,F6.1,4F7.2,12E9.2,2I5)
225	! ENDIF
226
227	ENDIF
228	ENDDO
229	ENDDO
230
231	!-----------------------------------------------------------------------
232	IF (LHOOK) CALL DR_HOOK('SRTM_SETCOEF',1,ZHOOK_HANDLE)
233	END ASSOCIATE
234	END SUBROUTINE SRTM_SETCOEF

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