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rrtm_taumol1.F90 @ 2003

Last change on this file since 2003 was 2003, checked in by Laurent Fairhead, 10 years ago

Nouvelle version qui inclut les effets des aérosols et propose les mêmes diagnostics des effets
directs et indirects que l'ancienne version du rayonnement.
OB

New RRTM version that includes the effects of aerosols and outputs the same direct and indirect effects
diagnostics as the old version
OB

Property copyright set to
Name of program: LMDZ
Creation date: 1984
Version: LMDZ5
License: CeCILL version 2
Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539
See the license file in the root directory

File size: 13.4 KB

Line
1	!******************************************************************************
2	! *
3	! Optical depths developed for the *
4	! *
5	! RAPID RADIATIVE TRANSFER MODEL (RRTM) *
6	! *
7	! ATMOSPHERIC AND ENVIRONMENTAL RESEARCH, INC. *
8	! 840 MEMORIAL DRIVE *
9	! CAMBRIDGE, MA 02139 *
10	! *
11	! ELI J. MLAWER *
12	! STEVEN J. TAUBMAN *
13	! SHEPARD A. CLOUGH *
14	! *
15	! email: mlawer@aer.com *
16	! *
17	! The authors wish to acknowledge the contributions of the *
18	! following people: Patrick D. Brown, Michael J. Iacono, *
19	! Ronald E. Farren, Luke Chen, Robert Bergstrom. *
20	! *
21	!******************************************************************************
22	! Modified by: *
23	! JJ Morcrette 980714 ECMWF for use on ECMWF's Fujitsu VPP770 *
24	! Reformatted for F90 by JJMorcrette, ECMWF *
25	! - replacing COMMONs by MODULEs *
26	! - changing labelled to unlabelled DO loops *
27	! - creating set-up routines for all block data statements *
28	! - reorganizing the parameter statements *
29	! - passing KLEV as argument *
30	! - suppressing some equivalencing *
31	! *
32	! D Salmond 9907 ECMWF Speed-up modifications *
33	! D Salmond 000515 ECMWF Speed-up modifications *
34	!******************************************************************************
35	! TAUMOL *
36	! *
37	! This file contains the subroutines TAUGBn (where n goes from *
38	! 1 to 16). TAUGBn calculates the optical depths and Planck fractions *
39	! per g-value and layer for band n. *
40	! *
41	! Output: optical depths (unitless) *
42	! fractions needed to compute Planck functions at every layer *
43	! and g-value *
44	! *
45	! COMMON /TAUGCOM/ TAUG(MXLAY,MG) *
46	! COMMON /PLANKG/ FRACS(MXLAY,MG) *
47	! *
48	! Input *
49	! *
50	! COMMON /FEATURES/ NG(NBANDS),NSPA(NBANDS),NSPB(NBANDS) *
51	! COMMON /PRECISE/ ONEMINUS *
52	! COMMON /PROFILE/ NLAYERS,PAVEL(MXLAY),TAVEL(MXLAY), *
53	! & PZ(0:MXLAY),TZ(0:MXLAY),TBOUND *
54	! COMMON /PROFDATA/ LAYTROP,LAYSWTCH,LAYLOW, *
55	! & COLH2O(MXLAY),COLCO2(MXLAY), *
56	! & COLO3(MXLAY),COLN2O(MXLAY),COLCH4(MXLAY), *
57	! & COLO2(MXLAY),CO2MULT(MXLAY) *
58	! COMMON /INTFAC/ FAC00(MXLAY),FAC01(MXLAY), *
59	! & FAC10(MXLAY),FAC11(MXLAY) *
60	! COMMON /INTIND/ JP(MXLAY),JT(MXLAY),JT1(MXLAY) *
61	! COMMON /SELF/ SELFFAC(MXLAY), SELFFRAC(MXLAY), INDSELF(MXLAY) *
62	! *
63	! Description: *
64	! NG(IBAND) - number of g-values in band IBAND *
65	! NSPA(IBAND) - for the lower atmosphere, the number of reference *
66	! atmospheres that are stored for band IBAND per *
67	! pressure level and temperature. Each of these *
68	! atmospheres has different relative amounts of the *
69	! key species for the band (i.e. different binary *
70	! species parameters). *
71	! NSPB(IBAND) - same for upper atmosphere *
72	! ONEMINUS - since problems are caused in some cases by interpolation *
73	! parameters equal to or greater than 1, for these cases *
74	! these parameters are set to this value, slightly < 1. *
75	! PAVEL - layer pressures (mb) *
76	! TAVEL - layer temperatures (degrees K) *
77	! PZ - level pressures (mb) *
78	! TZ - level temperatures (degrees K) *
79	! LAYTROP - layer at which switch is made from one combination of *
80	! key species to another *
81	! COLH2O, COLCO2, COLO3, COLN2O, COLCH4 - column amounts of water *
82	! vapor,carbon dioxide, ozone, nitrous ozide, methane, *
83	! respectively (molecules/cm*2)
84	! CO2MULT - for bands in which carbon dioxide is implemented as a *
85	! trace species, this is the factor used to multiply the *
86	! band's average CO2 absorption coefficient to get the added *
87	! contribution to the optical depth relative to 355 ppm. *
88	! FACij(LAY) - for layer LAY, these are factors that are needed to *
89	! compute the interpolation factors that multiply the *
90	! appropriate reference k-values. A value of 0 (1) for *
91	! i,j indicates that the corresponding factor multiplies *
92	! reference k-value for the lower (higher) of the two *
93	! appropriate temperatures, and altitudes, respectively. *
94	! JP - the index of the lower (in altitude) of the two appropriate *
95	! reference pressure levels needed for interpolation *
96	! JT, JT1 - the indices of the lower of the two appropriate reference *
97	! temperatures needed for interpolation (for pressure *
98	! levels JP and JP+1, respectively) *
99	! SELFFAC - scale factor needed to water vapor self-continuum, equals *
100	! (water vapor density)/(atmospheric density at 296K and *
101	! 1013 mb) *
102	! SELFFRAC - factor needed for temperature interpolation of reference *
103	! water vapor self-continuum data *
104	! INDSELF - index of the lower of the two appropriate reference *
105	! temperatures needed for the self-continuum interpolation *
106	! *
107	! Data input *
108	! COMMON /Kn/ KA(NSPA(n),5,13,MG), KB(NSPB(n),5,13:59,MG), SELFREF(10,MG) *
109	! (note: n is the band number) *
110	! *
111	! Description: *
112	! KA - k-values for low reference atmospheres (no water vapor *
113	! self-continuum) (units: cm*2/molecule)
114	! KB - k-values for high reference atmospheres (all sources) *
115	! (units: cm*2/molecule)
116	! SELFREF - k-values for water vapor self-continuum for reference *
117	! atmospheres (used below LAYTROP) *
118	! (units: cm*2/molecule)
119	! *
120	! DIMENSION ABSA(65NSPA(n),MG), ABSB(235NSPB(n),MG) *
121	! EQUIVALENCE (KA,ABSA),(KB,ABSB) *
122	! *
123	!******************************************************************************
124
125	SUBROUTINE RRTM_TAUMOL1 (KLEV,P_TAU,&
126	& P_TAUAERL,P_FAC00,P_FAC01,P_FAC10,P_FAC11,P_FORFAC,K_JP,K_JT,K_JT1,&
127	& P_COLH2O,K_LAYTROP,P_SELFFAC,P_SELFFRAC,K_INDSELF,PFRAC)
128
129	! Written by Eli J. Mlawer, Atmospheric & Environmental Research.
130	! Revised by Michael J. Iacono, Atmospheric & Environmental Research.
131
132	! BAND 1: 10-250 cm-1 (low - H2O; high - H2O)
133
134	! Modifications
135	! M.Hamrud 01-Oct-2003 CY28 Cleaning
136
137	! D Salmond 2000-05-15 speed-up
138	! JJMorcrette 2000-05-17 speed-up
139
140	USE PARKIND1 ,ONLY : JPIM ,JPRB
141	USE YOMHOOK ,ONLY : LHOOK, DR_HOOK
142
143	USE PARRRTM , ONLY : JPLAY ,JPBAND ,JPGPT ,NG1
144	USE YOERRTWN , ONLY : NSPA ,NSPB
145	USE YOERRTA1 , ONLY : ABSA ,ABSB ,FRACREFA, FRACREFB,&
146	& FORREF ,SELFREF
147
148	!#include "yoeratm.h"
149
150	! REAL TAUAER(JPLAY)
151
152	IMPLICIT NONE
153
154	! Output
155	INTEGER(KIND=JPIM),INTENT(IN) :: KLEV
156	REAL(KIND=JPRB) ,INTENT(OUT) :: P_TAU(JPGPT,JPLAY)
157	REAL(KIND=JPRB) ,INTENT(IN) :: P_TAUAERL(JPLAY,JPBAND)
158	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC00(JPLAY)
159	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC01(JPLAY)
160	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC10(JPLAY)
161	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC11(JPLAY)
162	REAL(KIND=JPRB) ,INTENT(IN) :: P_FORFAC(JPLAY)
163	INTEGER(KIND=JPIM),INTENT(IN) :: K_JP(JPLAY)
164	INTEGER(KIND=JPIM),INTENT(IN) :: K_JT(JPLAY)
165	INTEGER(KIND=JPIM),INTENT(IN) :: K_JT1(JPLAY)
166	REAL(KIND=JPRB) ,INTENT(IN) :: P_COLH2O(JPLAY)
167	INTEGER(KIND=JPIM),INTENT(IN) :: K_LAYTROP
168	REAL(KIND=JPRB) ,INTENT(IN) :: P_SELFFAC(JPLAY)
169	REAL(KIND=JPRB) ,INTENT(IN) :: P_SELFFRAC(JPLAY)
170	INTEGER(KIND=JPIM),INTENT(IN) :: K_INDSELF(JPLAY)
171	REAL(KIND=JPRB) ,INTENT(OUT) :: PFRAC(JPGPT,JPLAY)
172	!- from AER
173	!- from INTFAC
174	!- from INTIND
175	!- from PRECISE
176	!- from PROFDATA
177	!- from SELF
178	!- from SP
179	INTEGER(KIND=JPIM) :: IND0(JPLAY),IND1(JPLAY),INDS(JPLAY)
180
181	INTEGER(KIND=JPIM) :: IG, I_LAY
182	REAL(KIND=JPRB) :: ZHOOK_HANDLE
183
184	! EQUIVALENCE (TAUAERL(1,1),TAUAER)
185
186	! Compute the optical depth by interpolating in ln(pressure) and
187	! temperature. Below LAYTROP, the water vapor self-continuum
188	! is interpolated (in temperature) separately.
189
190	IF (LHOOK) CALL DR_HOOK('RRTM_TAUMOL1',0,ZHOOK_HANDLE)
191	!--ajout OB
192	IF (K_LAYTROP.GT.100) THEN
193	PRINT *,'ATTENTION KLAY_TROP > 100 PROBLEME ARRAY DANS RRTM ON ARRETE'
194	STOP
195	!--fin ajout OB
196	ENDIF
197	DO I_LAY = 1, K_LAYTROP
198	IND0(I_LAY) = ((K_JP(I_LAY)-1)5+(K_JT(I_LAY)-1))NSPA(1) + 1
199	IND1(I_LAY) = (K_JP(I_LAY)5+(K_JT1(I_LAY)-1))NSPA(1) + 1
200	INDS(I_LAY) = K_INDSELF(I_LAY)
201	ENDDO
202
203	DO IG = 1, NG1
204	DO I_LAY = 1, K_LAYTROP
205	!-- DS_000515
206	P_TAU (IG,I_LAY) = P_COLH2O(I_LAY) *&
207	& (P_FAC00(I_LAY) * ABSA(IND0(I_LAY) ,IG) +&
208	& P_FAC10(I_LAY) * ABSA(IND0(I_LAY)+1,IG) +&
209	& P_FAC01(I_LAY) * ABSA(IND1(I_LAY) ,IG) +&
210	& P_FAC11(I_LAY) * ABSA(IND1(I_LAY)+1,IG) +&
211	& P_SELFFAC(I_LAY) * (SELFREF(INDS(I_LAY),IG) + &
212	& P_SELFFRAC(I_LAY) *&
213	& (SELFREF(INDS(I_LAY)+1,IG) - SELFREF(INDS(I_LAY),IG)))&
214	& + P_FORFAC(I_LAY) * FORREF(IG) ) &
215	& + P_TAUAERL(I_LAY,1)
216	PFRAC(IG,I_LAY) = FRACREFA(IG)
217	ENDDO
218	ENDDO
219
220	DO I_LAY = K_LAYTROP+1, KLEV
221	IND0(I_LAY) = ((K_JP(I_LAY)-13)5+(K_JT(I_LAY)-1))NSPB(1) + 1
222	IND1(I_LAY) = ((K_JP(I_LAY)-12)5+(K_JT1(I_LAY)-1))NSPB(1) + 1
223	ENDDO
224
225	!-- JJM000517
226	DO IG = 1, NG1
227	DO I_LAY = K_LAYTROP+1, KLEV
228	!-- JJM000517
229	P_TAU (IG,I_LAY) = P_COLH2O(I_LAY) *&
230	& (P_FAC00(I_LAY) * ABSB(IND0(I_LAY) ,IG) +&
231	& P_FAC10(I_LAY) * ABSB(IND0(I_LAY)+1,IG) +&
232	& P_FAC01(I_LAY) * ABSB(IND1(I_LAY) ,IG) +&
233	& P_FAC11(I_LAY) * ABSB(IND1(I_LAY)+1,IG)&
234	& + P_FORFAC(I_LAY) * FORREF(IG) ) &
235	& + P_TAUAERL(I_LAY,1)
236	PFRAC(IG,I_LAY) = FRACREFB(IG)
237	ENDDO
238	ENDDO
239
240	IF (LHOOK) CALL DR_HOOK('RRTM_TAUMOL1',1,ZHOOK_HANDLE)
241	END SUBROUTINE RRTM_TAUMOL1

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