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rrtm_taumol1.F90 @ 2056

Last change on this file since 2056 was 2056, checked in by Laurent Fairhead, 10 years ago
Merged trunk changes r1997:2055 into testing branch
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

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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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