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radlsw.F90 @ 3942

Last change on this file since 3942 was 2089, checked in by Laurent Fairhead, 10 years ago

Inclusion de la physique de MAR

Integration of MAR physics

File size: 47.8 KB

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1	SUBROUTINE RADLSW &
2	&( KIDIA, KFDIA , KLON , KTDIA, KLEV , KMODE, KAER, KBOX, NBOX &
3	&, NDUMP, KLWRAD &
4	&, PRII0 &
5	&, PAER , PALBD , PALBP, PAPH , PAP &
6	&, PCCO2, PFRCL , PDP , PEMIS, PEMIW , PLSM , PMU0, POZON &
7	&, PQ , PQIWP , PQLWP, PSQIW, PSQLW , PQS , PQRAIN, PRAINT &
8	&, PRLVRI,PRLVRL, PTH , PT , PTS , PNBAS, PNTOP &
9	&, PEMIT, PFCT , PFLT , PFCS , PFLS , PFRSOD, PSUDU, PUVDF, PPARF &
10	&, PFDCT, PFUCT , PFDLT, PFULT, PFDCS , PFUCS , PFDLS, PFULS &
11	&, ZTAU , ZTAUINT &
12	&, ASWBOX, OLRBOX, SLWBOX, SSWBOX, TAUBOX, PCLBX &
13	! #DB &, k2iii, k2jjj &
14	&)
15
16	!**** RADLSW - INTERFACE TO ECMWF LW AND SW RADIATION SCHEMES
17
18	! PURPOSE.
19	! --------
20	! CONTROLS RADIATION COMPUTATIONS
21
22	!** INTERFACE.
23	! ----------
24
25	! EXPLICIT ARGUMENTS :
26	! --------------------
27	! PAER : (KLON,6,KLEV) ; OPTICAL THICKNESS OF THE AEROSOLS
28	! PALBD : (KLON,NSW) ; SURF. SW ALBEDO FOR DIFFUSE RADIATION
29	! PALBP : (KLON,NSW) ; SURF. SW ALBEDO FOR PARALLEL RADIATION
30	! PAPH : (KLON,KLEV+1) ; HALF LEVEL PRESSURE
31	! PAP : (KLON,KLEV) ; FULL LEVEL PRESSURE
32	! PCCO2 : ; CONCENTRATION IN CO2 (PA/PA)
33	! PFRCL : (KLON,KLEV) ; CLOUD FRACTIONAL COVER
34	! PDP : (KLON,KLEV) ; LAYER PRESSURE THICKNESS
35	! PEMIS : (KLON) ; SURFACE LW EMISSIVITY
36	! PEMIW : (KLON) ; SURFACE LW WINDOW EMISSIVITY
37	! PLSM : (KLON) ; LAND-SEA MASK
38	! PMU0 : (KLON) ; SOLAR ANGLE
39	! PNBAS : (KLON) ; INDEX OF BASE OF CONVECTIVE LAYER
40	! PNTOP : (KLON) ; INDEX OF TOP OF CONVECTIVE LAYER
41	! POZON : (KLON,KLEV) ; CONCENTRATION IN OZONE (PA/PA)
42	! PQ : (KLON,KLEV) ; SPECIFIC HUMIDITY PA/PA
43	! PQIWP : (KLON,KLEV) ; SOLID WATER KG/KG
44	! PQLWP : (KLON,KLEV) ; LIQUID WATER KG/KG
45	! PQS : (KLON,KLEV) ; SATURATION WATER VAPOR KG/KG
46	! PQRAIN : (KLON,KLEV) ; RAIN WATER KG/KG
47	! PRAINT : (KLON,KLEV) ; RAIN RATE (m/s)
48	! PRLVRI : (KLON,KLEV) ; RELATIVE VARIANCE OF ICE WATER
49	! PRLVRL : (KLON,KLEV) ; RELATIVE VARIANCE OF LIQUID WATER
50	! PTH : (KLON,KLEV+1) ; HALF LEVEL TEMPERATURE
51	! PT : (KLON,KLEV) ; FULL LEVEL TEMPERATURE
52	! PTS : (KLON) ; SURFACE TEMPERATURE
53	! ==== OUTPUTS ===
54	! PFCT : (KLON,KLEV+1) ; CLEAR-SKY LW NET FLUXES
55	! PFLT : (KLON,KLEV+1) ; TOTAL LW NET FLUXES
56	! PFCS : (KLON,KLEV+1) ; CLEAR-SKY SW NET FLUXES
57	! PFLS : (KLON,KLEV+1) ; TOTAL SW NET FLUXES
58	! PFRSOD : (KLON) ; TOTAL-SKY SURFACE SW DOWNWARD FLUX
59	! PEMIT : (KLON) ; SURFACE TOTAL LONGWAVE EMISSIVITY
60	! PSUDU : (KLON) ; SOLAR RADIANCE IN SUN'S DIRECTION
61	! PUVDF : (KLON) ; SURFACE DOWNWARD U.V. RADIATION
62	! PPARF : (KLON) ; PHOTOSYNTHETICALLY ACTIVE RADIATION
63
64	! IMPLICIT ARGUMENTS : NONE
65	! --------------------
66
67	! METHOD.
68	! -------
69	! SEE DOCUMENTATION
70
71	! EXTERNALS.
72	! ----------
73
74	! REFERENCE.
75	! ----------
76	! ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS
77
78	! AUTHORS.
79	! --------
80	! J.-J. MORCRETTE ECMWF
81
82	! MODIFICATIONS.
83	! --------------
84	! ORIGINAL : 88-02-04
85	! J.-J. MORCRETTE 94-11-15 DIRECT/DIFFUSE SURFACE ALBEDO
86	! 08/96: J.-J. Morcrette/Ph. Dandin: tests of eff. radius param.
87	! 9909 : JJMorcrette effect.radius + inhomogeneity factors
88	! JJMorcrette 990128 : sunshine duration
89	! JJMorcrette : 990831 RRTM-140gp
90	!-----------------------------------------------------------------------
91
92	#include "tsmbkind.h"
93
94	!USE YOMCT3 , ONLY : NSTEP
95	USE YOMCST , ONLY : RG ,RD ,RTT ,RPI
96	USE YOERAD , ONLY : NSW ,LRRTM ,LINHOM, &
97	&LOIFUEC, LTEMPDS, LOWASYF, LOWHSSS, NRADIP, NRADLP, &
98	&NICEOPT, NLIQOPT, NOVLP , NHOWINH, RMINICE
99	USE YOELW , ONLY : NSIL ,NTRA ,NUA ,TSTAND ,XP
100	USE YOESW , ONLY : RYFWCA ,RYFWCB ,RYFWCC ,RYFWCD ,&
101	&RYFWCE ,RYFWCF ,REBCUA ,REBCUB ,REBCUC ,&
102	&REBCUD ,REBCUE ,REBCUF ,REBCUI ,REBCUJ ,&
103	&REBCUG ,REBCUH ,RHSAVI ,RFULIO ,RFLAA0 ,&
104	&RFLAA1 ,RFLBB0 ,RFLBB1 ,RFLBB2 ,RFLBB3 ,&
105	&RFLCC0 ,RFLCC1 ,RFLCC2 ,RFLCC3 ,RFLDD0 ,&
106	&RFLDD1 ,RFLDD2 ,RFLDD3 ,RFUAA0 ,RFUAA1 ,&
107	&RFUBB0 ,RFUBB1 ,RFUBB2 ,RFUBB3 ,RFUCC0 ,&
108	&RFUCC1 ,RFUCC2 ,RFUCC3 ,RFUETA ,RASWCA ,&
109	&RASWCB ,RASWCC ,RASWCD ,RASWCE ,RASWCF ,&
110	&RLINLI
111	USE YOERDU , ONLY : NUAER ,NTRAER ,REPLOG ,REPSC ,DIFF
112	USE YOERDI , ONLY : REPCLC
113	USE YOETHF , ONLY : RTICE
114	USE YOEPHLI , ONLY : LPHYLIN
115	USE YOERRTWN , ONLY : NG ,NSPA ,NSPB ,WAVENUM1 ,&
116	&WAVENUM2 ,DELWAVE ,TOTPLNK ,TOTPLK16
117	USE YOEDBUG , ONLY : LDEBUG
118
119
120	IMPLICIT NONE
121
122
123	! DUMMY INTEGER SCALARS
124	INTEGER_M :: KAER
125	INTEGER_M :: KFDIA
126	INTEGER_M :: KIDIA
127	INTEGER_M :: KLEV
128	INTEGER_M :: KLON
129	INTEGER_M :: KMODE
130	INTEGER_M :: KTDIA
131	INTEGER_M :: KBOX
132	INTEGER_M :: NBOX
133	INTEGER_M :: NDUMP, KLWRAD
134
135	! DUMMY REAL SCALARS
136	REAL_B :: PRII0
137
138
139
140	! -----------------------------------------------------------------
141
142	!* 0.1 ARGUMENTS.
143	! ----------
144	REAL_B :: PALBD(KLON,NSW) , PALBP(KLON,NSW)
145	REAL_B :: PEMIS(KLON) , PEMIW(KLON)
146	REAL_B :: PLSM(KLON) , PMU0(KLON)
147	REAL_B :: PCCO2 , POZON(KLON,KLEV)
148	REAL_B :: PTS(KLON) , PNBAS(KLON) , PNTOP(KLON)
149	REAL_B :: PT (KLON,KLEV) , PAP (KLON,KLEV)
150	REAL_B :: PTH(KLON,KLEV+1), PAPH(KLON,KLEV+1)
151	REAL_B :: PDP(KLON,KLEV)
152	REAL_B :: PQ (KLON,KLEV) , PQS(KLON,KLEV)
153	REAL_B :: PQIWP(KLON,KLEV), PQLWP(KLON,KLEV), PQRAIN(KLON,KLEV)
154	REAL_B :: PRAINT(KLON,KLEV)
155	REAL_B :: PRLVRI(KLON,KLEV),PRLVRL(KLON,KLEV)
156	REAL_B :: PSQIW(KLON,KLEV), PSQLW(KLON,KLEV)
157	REAL_B :: PFRCL(KLON,KLEV), PCLFR(KLON,KLEV), PCLBX(KLON,100,KLEV)
158	REAL_B :: PAER (KLON,6,KLEV)
159
160	! #DB integer :: k2iii(KLON),k2jjj(KLON),kio,kjo
161
162	! ==== COMPUTED IN RADLSW ===
163	REAL_B :: PFCS(KLON,KLEV+1), PFCT(KLON,KLEV+1)
164	REAL_B :: PFLS(KLON,KLEV+1), PFLT(KLON,KLEV+1)
165	REAL_B :: PFRSOD(KLON) , PEMIT(KLON)
166	REAL_B :: PSUDU(KLON) , PUVDF(KLON) , PPARF(KLON)
167	REAL_B :: PFDCT(KLON,KLEV+1), PFUCT(KLON,KLEV+1)
168	REAL_B :: PFDLT(KLON,KLEV+1), PFULT(KLON,KLEV+1)
169	REAL_B :: PFDCS(KLON,KLEV+1), PFUCS(KLON,KLEV+1)
170	REAL_B :: PFDLS(KLON,KLEV+1), PFULS(KLON,KLEV+1)
171
172	REAL_B :: ASWBOX(KLON, 100), OLRBOX(KLON, 100)
173	REAL_B :: SLWBOX(KLON, 100), SSWBOX(KLON, 100), TAUBOX(KLON, 100)
174
175	! -----------------------------------------------------------------
176
177	!* 0.2 LOCAL ARRAYS.
178	! -------------
179	! -----------------------------------------------------------------
180
181	!-- ARRAYS FOR LOCAL VARIABLES -----------------------------------------
182
183	INTEGER_M :: IBAS(KLON) , ITOP(KLON)
184
185	! #DB integer :: jkjllw, jkjlsw, JAERmin, JAERmax, jTAUCLDmin, jTAUCLDmax
186	! #DB real :: PAERmin, PAERmax, TAUCLDmin, TAUCLDmax
187
188	REAL_B ::&
189	&ZALBD(KLON,NSW) , ZALBP(KLON,NSW)&
190	&, ZCG(KLON,NSW,KLEV) , ZOMEGA(KLON,NSW,KLEV)&
191	&, ZTAU (KLON,NSW,KLEV) &
192	&, ZTAUCLD(KLON,KLEV,16), ZTCLEAR(KLON)
193	REAL_B ::&
194	&ZCLDLD(KLON,KLEV) , ZCLDLU(KLON,KLEV)&
195	&, ZCLDSW(KLON,KLEV) , ZCLD0(KLON,KLEV)&
196	&, ZDT0(KLON) &
197	&, ZEMIS(KLON) , ZEMIW(KLON)&
198	&, ZFLUX (KLON,2,KLEV+1) , ZFLUC(KLON,2,KLEV+1)&
199	&, ZFIWP(KLON) , ZFLWP(KLON) , ZFRWP(KLON)&
200	&, ZIWC(KLON) , ZLWC(KLON)&
201	&, ZBICFU(KLON) , ZKICFU1(KLON) , ZKICFU2(KLON)&
202	!cc , ZRWC(KLON)
203	&, ZMU0(KLON) , ZOZ(KLON,KLEV) , ZOZN(KLON,KLEV)&
204	&, ZOZON(KLON,KLEV) , ZPMB(KLON,KLEV+1), ZPSOL(KLON)&
205	&, ZTAVE (KLON,KLEV) , ZTL(KLON,KLEV+1)&
206	&, ZVIEW(KLON)
207	REAL_B ::&
208	&ZFCDWN(KLON,KLEV+1), ZFCUP(KLON,KLEV+1)&
209	&, ZFSDWN(KLON,KLEV+1), ZFSUP(KLON,KLEV+1)&
210	&, ZFSUPN(KLON) , ZFSUPV(KLON)&
211	&, ZFCUPN(KLON) , ZFCUPV(KLON)&
212	&, ZFSDNN(KLON) , ZFSDNV(KLON)&
213	&, ZFCDNN(KLON) , ZFCDNV(KLON)&
214	&, ZCOOLR(KLON,KLEV) , ZCOOLC(KLON,KLEV)&
215	&, ZHEATR(KLON,KLEV) , ZHEATC(KLON,KLEV)
216	REAL_B ::&
217	&ZALFICE(KLON) , ZGAMICE(KLON) , ZBICE(KLON), ZDESR(KLON) &
218	&, ZRADIP(KLON) , ZRADLP(KLON) , ZCFUDG(KLON)&
219	!cc , ZRADRD(KLON)
220	&, ZRAINT(KLON) , ZRES(KLON)&
221	&, ZTICE(KLON) , ZEMIT(KLON) , ZTAUINT(KLON)
222	REAL_B :: ZSUDU(KLON) , ZUVDF(KLON) , ZPARF(KLON), ZCOL(KLON) &
223	&, ZTCC(KLON) , ZTCA(KLON)
224
225	!-- box-type arrays
226
227	REAL_B :: CPFCS(KLON,KLEV+1) , CPFCT(KLON,KLEV+1)
228	REAL_B :: CPFLS(KLON,KLEV+1) , CPFLT(KLON,KLEV+1)
229	REAL_B :: CPFRSOD(KLON) , CPEMIT(KLON)
230	REAL_B :: CPSUDU(KLON) , CPUVDF(KLON) , CPPARF(KLON)
231	REAL_B :: CPFDCT(KLON,KLEV+1), CPFUCT(KLON,KLEV+1)
232	REAL_B :: CPFDLT(KLON,KLEV+1), CPFULT(KLON,KLEV+1)
233	REAL_B :: CPFDCS(KLON,KLEV+1), CPFUCS(KLON,KLEV+1)
234	REAL_B :: CPFDLS(KLON,KLEV+1), CPFULS(KLON,KLEV+1)
235
236	! LOCAL INTEGER SCALARS
237	INTEGER_M :: IKL, JAE, JK, JKL, JKLP1, JKP1, JL, JNU, JRTM, JSW &
238	&, NBOXL, ICBOX, IMOV, INDLAY
239
240	! LOCAL LOGICAL SCALARS
241	LOGICAL :: LLINTRP
242
243	! LOCAL REAL SCALARS
244	REAL_B :: ZASYMX, ZDIFFD, ZGI, ZGL, ZGR, ZIWGKG, ZLWGKG,&
245	&ZMSAID, ZMSAIU, ZMSALD, ZMSALU, ZMTCONV, &
246	&ZMTFUDG, ZLWFUDG, ZSWFUDG, ZMULTL, ZOI, ZOL, ZOMGMX, ZOR, &
247	&ZRMUZ, ZRWGKG, ZTAUD, ZTAUMX, ZTEMPC, &
248	&ZTOI, ZTOL, ZTOR, ZZFIWP, ZZFLWP, ZDPOG, ZPODT
249	REAL_B :: ZALND, ZASEA, ZD, ZDEN, ZNTOT, ZNUM, ZRATIO, ZCOEFF, Z1RADI,&
250	&Z1RADL, ZBETAI, ZOMGI, ZOMGP, ZFDEL, ZWGHT, ZVI, ZVL, ZVR
251	REAL_B :: ZASW, ZOLR, ZSLW, ZSSW, ZMULTI, ZAIWC, ZBIWC,&
252	&ZDICE, ZFSR, ZLGIWC, ZTCELS, ZTBLAY, ZADDPLK, ZPLANCK
253	REAL_B :: ZTOL1, ZTOI1, ZTOR1
254
255
256	! -----------------------------------------------------------------
257
258	! #DB kio = 66
259	! #DB kjo = 53
260
261	!if (NDUMP.LE.3) then
262	! JL=KIDIA
263	! DO jk=1,klev
264	! print 9104,jk,PAPH(JL,JK),PTH(JL,JK),PAP(JL,JK),PT(JL,JK)&
265	! & ,PDP(JL,JK)&
266	! & ,PQ(JL,JK),PFRCL(JL,JK),PQIWP(JL,JK),PQLWP(JL,JK)&
267	! & ,POZON(JL,JK),PQS(JL,JK)
268	9104 format(1x,i3,f9.1,f8.2,f9.1,f8.2,f9.1,e10.3,f7.4,4e10.3)
269	! ENDDO
270	! jk=klev+1
271	! print 9104,jk,PAPH(JL,JK),PTH(JL,JK)
272	! print 9105,PTS(JL),(PALBD(JL,JSW),PALBP(JL,JSW),JSW=1,NSW)
273	9105 FORMAT(13X,f8.2,12f8.4)
274	!end if
275
276	!print *,'NICEOPT, NLIQOPT, NRADIP, NRADLP',NICEOPT,NLIQOPT,NRADIP,NRADLP
277
278	!-- compute total cloud cover
279	DO JL=KIDIA,KFDIA
280	ZTCC(JL)=1.-PFRCL(JL,1)
281	ZTCA(JL)=0.
282	END DO
283	DO JK=2,KLEV
284	DO JL=KIDIA,KFDIA
285	ZTCC(JL)=ZTCC(JL)*(1.-MAX(PFRCL(JL,JK),PFRCL(JL,JK-1))) &
286	& /(1.-MIN(PFRCL(JL,JK-1),1.-REPCLC))
287	END DO
288	END DO
289	DO JL=KIDIA,KFDIA
290	ZTCC(JL)=1.-ZTCC(JL)
291	END DO
292
293	!JL=KIDIA
294	!print 9106,ZTCC(JL)
295	9106 format(1x,'TCC :',F7.4)
296	!print 9107,LINHOM,NHOWINH
297	9107 format(1x,'LINHOM=',L8,' NHOWINH=',I2)
298
299
300
301
302
303
304	!* 1. SET-UP INPUT QUANTITIES FOR RADIATION
305	! -------------------------------------
306
307	IF (.NOT.LINHOM) THEN
308	ZMTFUDG=1.0_JPRB
309	ZMTCONV=1.0_JPRB
310	ZSWFUDG=1.0_JPRB
311	ZLWFUDG=1.0_JPRB
312	ELSE IF (LINHOM) THEN
313	IF (NHOWINH.EQ.1) THEN
314	ZMTFUDG=0.7_JPRB
315	ZMTCONV=0.7_JPRB
316	ZSWFUDG=0.7_JPRB
317	ZLWFUDG=0.7_JPRB
318	ELSE
319	ZMTFUDG=1.0_JPRB
320	ZMTCONV=1.0_JPRB
321	ZSWFUDG=1.0_JPRB
322	ZLWFUDG=1.0_JPRB
323	ENDIF
324	ENDIF
325	!print 9108,LINHOM,NHOWINH,ZSWFUDG
326	9108 format(1x,'LINHOM=',L8,' NHOWINH=',I2,' FUDG=',f4.2)
327
328	DO JL = KIDIA,KFDIA
329	ZFCUP(JL,KLEV+1) = _ZERO_
330	ZFCDWN(JL,KLEV+1) = REPLOG
331	ZFSUP(JL,KLEV+1) = _ZERO_
332	ZFSDWN(JL,KLEV+1) = REPLOG
333	ZFLUX(JL,1,KLEV+1) = _ZERO_
334	ZFLUX(JL,2,KLEV+1) = _ZERO_
335	ZFLUC(JL,1,KLEV+1) = _ZERO_
336	ZFLUC(JL,2,KLEV+1) = _ZERO_
337	ZFSDNN(JL) = _ZERO_
338	ZFSDNV(JL) = _ZERO_
339	ZFCDNN(JL) = _ZERO_
340	ZFCDNV(JL) = _ZERO_
341	ZFSUPN(JL) = _ZERO_
342	ZFSUPV(JL) = _ZERO_
343	ZFCUPN(JL) = _ZERO_
344	ZFCUPV(JL) = _ZERO_
345	ZPSOL(JL) = PAPH(JL,KLEV+1)
346	ZPMB(JL,1) = ZPSOL(JL) / 100._JPRB
347	ZDT0(JL) = PTS(JL) - PTH(JL,KLEV+1)
348	PSUDU(JL) = _ZERO_
349	PUVDF(JL) = _ZERO_
350	PPARF(JL) = _ZERO_
351	ZSUDU(JL) = _ZERO_
352	IBAS(JL) = INT ( 0.01_JPRB + PNBAS(JL) )
353	ITOP(JL) = INT ( 0.01_JPRB + PNTOP(JL) )
354	ENDDO
355
356	DO JK=1,KLEV+1
357	DO JL=KIDIA,KFDIA
358	CPFLS(JL,JK) = _ZERO_
359	CPFLT(JL,JK) = _ZERO_
360	CPFCS(JL,JK) = _ZERO_
361	CPFCT(JL,JK) = _ZERO_
362	CPFDCT(JL,JK) = _ZERO_
363	CPFUCT(JL,JK) = _ZERO_
364	CPFDLT(JL,JK) = _ZERO_
365	CPFULT(JL,JK) = _ZERO_
366	CPFDCS(JL,JK) = _ZERO_
367	CPFUCS(JL,JK) = _ZERO_
368	CPFDLS(JL,JK) = _ZERO_
369	CPFULS(JL,JK) = _ZERO_
370	ENDDO
371	ENDDO
372
373	DO JL = KIDIA,KFDIA
374	CPFRSOD(JL) = _ZERO_
375	CPEMIT (JL) = _ZERO_
376	CPSUDU (JL) = _ZERO_
377	CPUVDF (JL) = _ZERO_
378	CPPARF (JL) = _ZERO_
379	END DO
380
381
382	!* 1.1 INITIALIZE VARIOUS FIELDS
383	! -------------------------
384
385
386	DO JSW=1,NSW
387	DO JL = KIDIA,KFDIA
388	ZALBD(JL,JSW)=PALBD(JL,JSW)
389	ZALBP(JL,JSW)=PALBP(JL,JSW)
390	ENDDO
391	ENDDO
392	DO JL = KIDIA,KFDIA
393	ZEMIS(JL) =PEMIS(JL)
394	ZEMIW(JL) =PEMIW(JL)
395	ZMU0(JL) =PMU0(JL)
396	ZUVDF(JL) = _ZERO_
397	ZSUDU(JL) = _ZERO_
398	ZPARF(JL) = _ZERO_
399	ENDDO
400
401	DO JK = 1 , KLEV
402	JKP1 = JK + 1
403	JKL = KLEV+ 1 - JK
404	JKLP1 = JKL + 1
405	DO JL = KIDIA,KFDIA
406	ZPMB(JL,JK+1)=PAPH(JL,JKL)/100._JPRB
407	ZOZ(JL,JK) = POZON(JL,JKL) * 46.6968_JPRB / RG
408	ZOZON(JL,JK) = POZON(JL,JKL)
409	ZCLD0(JL,JK) = _ZERO_
410	ZFCUP(JL,JK) = _ZERO_
411	ZFCDWN(JL,JK) = _ZERO_
412	ZFSUP(JL,JK) = _ZERO_
413	ZFSDWN(JL,JK) = _ZERO_
414	ZFLUX(JL,1,JK) = _ZERO_
415	ZFLUX(JL,2,JK) = _ZERO_
416	ZFLUC(JL,1,JK) = _ZERO_
417	ZFLUC(JL,2,JK) = _ZERO_
418	ENDDO
419	ENDDO
420
421
422	!** INPUTS ARE FULL LEVEL TEMPERATURES + SURFACE TEMPERATURE
423	! INTERPOLATION TO GET HALF-LEVEL TEMPERATURES FOLLOWS
424	! WHAT IS DONE IN RADINT AND RADHEAT
425
426	!* LLINTRP=.T. Half-level temperatures on the coarse grid are
427	! vertically interpolated linearly with horizontal
428	! sampled pressure from the full-level temperatures
429	! of the sampled grid.
430
431	!* LLINTRP=.F. Half-level temperatures are those horizontally
432	! sampled on the coarse grid
433
434	LLINTRP=.FALSE.
435	IF (LLINTRP) THEN
436	DO JK=2,KLEV
437	DO JL=KIDIA,KFDIA
438	PTH(JL,JK)=(PT (JL,JK-1)*PAP (JL,JK-1)&
439	&*(PAP (JL,JK)-PAPH (JL,JK))&
440	&+PT (JL,JK)PAP (JL,JK)(PAPH (JL,JK)-PAP (JL,JK-1)))&
441	&(_ONE_/(PAPH (JL,JK)(PAP (JL,JK)-PAP (JL,JK-1))))
442	ENDDO
443	ENDDO
444	IF (LTEMPDS) THEN
445	DO JL=KIDIA,KFDIA
446	PTH(JL,1)= PT (JL,1)-PAP (JL,1)*(PT (JL,1)-PTH(JL,2))&
447	&/(PAP (JL,1)-PAPH (JL,2))
448	PTH(JL,KLEV+1)=PT(JL,KLEV)&
449	& +(PAPH(JL,KLEV+1)-PAP(JL,KLEV))&
450	& *(PT(JL,KLEV)-PTH(JL,KLEV))&
451	& /(PAP(JL,KLEV)-PAPH(JL,KLEV))
452	ENDDO
453	ELSE
454	DO JL=KIDIA,KFDIA
455	PTH(JL,1)= PT (JL,1)-PAP (JL,1)*(PT (JL,1)-PTH(JL,2))&
456	&/(PAP (JL,1)-PAPH (JL,2))
457	PTH(JL,KLEV+1)= PTS(JL)
458	ENDDO
459	ENDIF
460	ENDIF
461
462	DO JK=1,KLEV
463	JKL=KLEV+1-JK
464	JKLP1=JKL+1
465	DO JL=KIDIA,KFDIA
466	ZTL(JL,JK)=PTH(JL,JKLP1)
467	ZTAVE(JL,JK)=PT(JL,JKL)
468	ENDDO
469	ENDDO
470	DO JL=KIDIA,KFDIA
471	ZTL(JL,KLEV+1)= PTH(JL,1)
472	ZPMB(JL,KLEV+1) = PAPH(JL,1)/100._JPRB
473	ENDDO
474	!***
475
476	! ------------------------------------------------------------------
477
478	!* 2. CLOUD AND AEROSOL PARAMETERS
479	! ----------------------------
480
481	NBOXL=1
482	IF (KBOX.EQ.1) THEN
483	CALL COL2BOX &
484	& ( KIDIA, KFDIA, KLON, KLEV, NBOX, NOVLP &
485	& , PFRCL, PCLBX &
486	& )
487	NBOXL=NBOX
488	END IF
489	ZWGHT=1./FLOAT(NBOXL)
490
491	!-- initialise box-type outputs OLR, ASW, SDLW, SDSW, TAU
492	DO ICBOX=1,NBOXL
493	DO JL=KIDIA,KFDIA
494	OLRBOX(JL,ICBOX)=_ZERO_
495	ASWBOX(JL,ICBOX)=_ZERO_
496	SLWBOX(JL,ICBOX)=_ZERO_
497	SSWBOX(JL,ICBOX)=_ZERO_
498	TAUBOX(JL,ICBOX)=_ZERO_
499	END DO
500	END DO
501
502	DO ICBOX=1,NBOXL
503	IF (KBOX.EQ.1) THEN
504	DO JK=1,KLEV
505	DO JL=KIDIA,KFDIA
506	PCLFR(JL,JK)=PCLBX(JL,ICBOX,JK)
507	END DO
508	END DO
509
510	ELSE
511	DO JK=1,KLEV
512	DO JL=KIDIA,KFDIA
513	PCLFR(JL,JK)=PFRCL(JL,JK)
514	END DO
515	END DO
516	END IF
517	DO JL=KIDIA,KFDIA
518	PSUDU(JL) = _ZERO_
519	ZTAUINT(JL) = _ZERO_
520	END DO
521
522	!-- compute total cloud cover for that particular calculation
523	DO JL=KIDIA,KFDIA
524	ZCOL(JL)=1.-PCLFR(JL,1)
525	END DO
526	DO JK=2,KLEV
527	DO JL=KIDIA,KFDIA
528	ZCOL(JL)=ZCOL(JL)*(1.-MAX(PCLFR(JL,JK),PCLFR(JL,JK-1))) &
529	& /(1.-MIN(PCLFR(JL,JK-1),1.-REPCLC))
530	END DO
531	END DO
532	DO JL=KIDIA,KFDIA
533	ZCOL(JL)=1.-ZCOL(JL)
534	END DO
535
536
537
538
539
540
541	DO JK = 1 , KLEV
542	IKL = KLEV + 1 - JK
543
544	! 2.1 INITIALIZE OPTICAL PROPERTIES TO CLEAR SKY VALUES
545	! -------------------------------------------------
546
547	DO JSW = 1,NSW
548	DO JL = KIDIA,KFDIA
549	ZTAU(JL,JSW,JK) = _ZERO_
550	ZOMEGA(JL,JSW,JK)= _ONE_
551	ZCG(JL,JSW,JK) = _ZERO_
552	ENDDO
553	ENDDO
554	DO JL = KIDIA,KFDIA
555	ZCLDSW(JL,JK) = _ZERO_
556	ZCLDLD(JL,JK) = _ZERO_
557	ZCLDLU(JL,JK) = _ZERO_
558	ENDDO
559
560
561	! 2.2 CLOUD ICE AND LIQUID CONTENT AND PATH
562	! -------------------------------------
563
564	DO JL = KIDIA,KFDIA
565	! PCLFR(JL,IKL)=MAX(REPSC,MIN(PCLFR(JL,IKL),_ONE_-REPSC))
566	PCLFR(JL,IKL)=MAX( _ZERO_ ,MIN( PCLFR(JL,IKL), _ONE_ ))
567
568	! --- LIQUID WATER CONTENT (g.m-3) AND LIQUID WATER PATH (g.m-2)
569	ZLWGKG=MAX(PQLWP(JL,IKL)*1000._JPRB,_ZERO_)
570	ZIWGKG=MAX(PQIWP(JL,IKL)*1000._JPRB,_ZERO_)
571	!! IF (PCLFR(JL,IKL) > (_TWO_*REPCLC)) THEN
572	!! ZLWGKG=ZLWGKG/PCLFR(JL,IKL)
573	!! ZIWGKG=ZIWGKG/PCLFR(JL,IKL)
574	!! IF (PCLFR(JL,IKL) > REPCLC) THEN
575	IF (PCLFR(JL,IKL) > 15.E-06_JPRB) THEN
576	ZLWGKG=ZLWGKG/PFRCL(JL,IKL)
577	ZIWGKG=ZIWGKG/PFRCL(JL,IKL)
578	ELSE
579	ZLWGKG=_ZERO_
580	ZIWGKG=_ZERO_
581	ENDIF
582
583	! --- RAIN LIQUID WATER CONTENT (g.m-3) AND LIQUID WATER PATH (g.m-2)
584	! IF (PRAINT(JL,IKL).GT.(2.*REPCLC)) THEN
585	! ZRWGKG=MAX(PQRAIN(JL,IKL)*1000., 0.0)
586	! ZRAINT(JL)=PRAINT(JL,IKL)3600.1000.
587	!- no radiative effect of rain (for the moment)
588	! ZRWGKG=0.
589	! ZRAINT(JL)=0.
590	! ===========================================================
591
592	! Modifications Martin et al.
593	! ELSE
594	ZRWGKG=_ZERO_
595	ZRAINT(JL)=_ZERO_
596	! END IF
597
598	IF (IBAS(JL) /= 1.AND. ITOP(JL) /= 1 ) THEN
599	ZCFUDG(JL)=ZMTCONV
600	ELSE
601	ZCFUDG(JL)=ZMTFUDG
602	ENDIF
603
604	ZDPOG=PDP(JL,IKL)/RG
605	ZFLWP(JL)= ZLWGKG*ZDPOG
606	ZFIWP(JL)= ZIWGKG*ZDPOG
607	ZFRWP(JL)= ZRWGKG*ZDPOG
608	ZPODT=PAP(JL,IKL)/(RD*PT(JL,IKL))
609	ZLWC(JL)=ZLWGKG*ZPODT
610	ZIWC(JL)=ZIWGKG*ZPODT
611	! ZRWC(JL)=ZRWGKG*ZPODT
612
613	! --- EFFECTIVE RADIUS FOR WATER, ICE AND RAIN PARTICLES
614
615	IF (NRADLP.EQ.0) THEN
616	! very old parametrization as f(pressure)
617	ZRADLP(JL)=10._JPRB + (100000._JPRB-PAP(JL,IKL))*3.5E-04_JPRB
618
619	ELSE IF (NRADLP.EQ.1) THEN
620	! old simple distinction between land (10) and ocean (13)
621	IF (PLSM(JL) < _HALF_) THEN
622	ZRADLP(JL)=13._JPRB
623	ELSE
624	ZRADLP(JL)=10._JPRB
625	ENDIF
626
627	ELSE IF (NRADLP.EQ.2) THEN
628	!-- based on Martin et al., 1994, JAS
629	IF (PLSM(JL) < _HALF_) THEN
630	ZASEA=150._JPRB
631	ZD=0.33_JPRB
632	ZNTOT=-1.15E-03_JPRBZASEAZASEA+0.963_JPRB*ZASEA+5.30_JPRB
633	ELSE
634	ZALND=900._JPRB
635	! ZALND=600._JPRB
636	! ZALND=300._JPRB
637	! ZALND=1200._JPRB
638	ZD=0.43_JPRB
639	ZNTOT=-2.10E-04_JPRBZALNDZALND+0.568_JPRB*ZALND-27.9_JPRB
640	ENDIF
641
642	ZNUM=3._JPRBZLWC(JL)(1._JPRB+3._JPRBZDZD)**2
643	ZDEN=4._JPRBRPIZNTOT(1._JPRB+ZDZD)**3
644	ZRADLP(JL)=100.(ZNUM/ZDEN)*0.333_JPRB
645
646	! 9001 format(1x,I3,1E13.5,F5.0,F5.2,f8.2,3E13.5)
647	ZRADLP(JL)=MAX(ZRADLP(JL), 4._JPRB)
648	ZRADLP(JL)=MIN(ZRADLP(JL),16._JPRB)
649	END IF
650	! print *,'ZRADLP(JL) for JK=',JK,ZRADLP(JL)
651
652	! ===========================================================
653	! ___________________________________________________________
654
655	! rain drop from : unused as ZRAINT is 0.
656	! ZRADRD(JL)=500._JPRBZRAINT(JL)*0.22_JPRB
657	! IF (ZFLWP(JL).GT.0.) THEN
658	! ZRADRD(JL)=ZRADLP(JL)+ZRADRD(JL)
659	! END IF
660
661	!- ice particle effective radius =f(T) from Liou and Ou (1994)
662
663	IF (PT(JL,IKL) < RTICE) THEN
664	ZTEMPC=PT(JL,IKL)-RTT
665	ELSE
666	ZTEMPC=RTICE-RTT
667	ENDIF
668
669	ZRADIP(JL)=326.3_JPRB+ZTEMPC(12.42_JPRB + ZTEMPC(0.197_JPRB + ZTEMPC*&
670	&0.0012_JPRB))
671	ZDESR(JL)=2._JPRB*ZRADIP(JL)
672	! print *,'ZRADIP(JL) for JK=',JK,ZRADIP(JL),ZDESR(JL)
673
674	IF (NRADIP.EQ. 0) THEN
675	ZRADIP(JL)= 40._JPRB
676	ZDESR(JL)=2._JPRB*ZRADIP(JL)
677	! print *,'ZRADIP(JL) for JK=',JK,ZRADIP(JL),ZDESR(JL)
678
679	ELSE IF (NRADIP.EQ. 1) THEN
680	!-- old formulation based on temperature (40-130microns)
681	ZRADIP(JL)=MAX(ZRADIP(JL),40._JPRB)
682	ZDESR(JL)=2._JPRB*ZRADIP(JL)
683	! print *,'ZRADIP(JL) for JK=',JK,ZRADIP(JL),ZDESR(JL)
684
685	ELSE IF (NRADIP.EQ. 2) THEN
686	!-- formulation following Jakob, Klein modifications to ice content
687	ZRADIP(JL)=MAX(ZRADIP(JL),30._JPRB)
688	ZRADIP(JL)=MIN(ZRADIP(JL),60._JPRB)
689	ZDESR(JL)=2._JPRB*ZRADIP(JL)
690	! print *,'ZRADIP(JL) for JK=',JK,ZRADIP(JL),ZDESR(JL)
691
692	!-- new Sun and Rikus, 1999 D_ice = f(T, IWC)
693	ELSE IF (NRADIP.EQ. 3 .AND. ZIWC(JL).GT. _ZERO_ ) THEN
694	ZTEMPC=PT(JL,IKL)-83.15_JPRB
695	ZTCELS=PT(JL,IKL)-RTT
696	ZFSR = 1.2351_JPRB +0.0105_JPRB * ZTCELS
697	! Sun & Rikus, 1999
698	! ZLGIWC=LOG10( REPCLC + ZIWC(JL))
699	! ZAIWC=26.1571_JPRB / ( ABS(ZLGIWC) **0.5995_JPRB )
700	! ZBIWC=0.6402_JPRB + 0.1810_JPRB * ZLGIWC
701	! Sun, 2001
702	ZAIWC = 45.8966_JPRB * ZIWC(JL)**0.2214_JPRB
703	ZBIWC = 0.7957_JPRB * ZIWC(JL)**0.2535_JPRB
704	ZDESR(JL) = ZFSR * (ZAIWC + ZBIWC*ZTEMPC)
705	ZDESR(JL) = MIN ( MAX( ZDESR(JL), RMINICE ), 350._JPRB)
706	ZRADIP(JL)= 0.5 * ZDESR(JL)
707	! print *,'ZRADIP(JL) for JK=',JK,ZRADIP(JL),ZDESR(JL)
708	END IF
709
710	!-- ERA-15 definition of effective radii
711	IF (KLWRAD.EQ.2 .AND. NSW.EQ.2) THEN
712	ZRADIP(JL)=40._JPRB
713	ZRADLP(JL)=10._JPRB + (100000._JPRB-PAP(JL,IKL))*3.5_JPRB
714	! ZSWFUDG=1._JPRB
715	! ZLWFUDG=1._JPRB
716	LOWASYF=.FALSE.
717	LOIFUEC=.FALSE.
718	LRRTM=.FALSE.
719	ZDESR(JL)=2._JPRB*ZRADIP(JL)
720	! print *,'ZRADIP(JL) for JK=',JK,ZRADIP(JL),ZDESR(JL)
721	END IF
722
723	ENDDO
724
725
726
727	! 2.3 CLOUD SHORTWAVE OPTICAL PROPERTIES
728	! ----------------------------------
729
730	! -------------------------
731	! --+ SW OPTICAL PARAMETERS + Water clouds after Fouquart (1987)
732	! ------------------------- Ice clouds (Ebert, Curry, 1992)
733
734	DO JSW=1,NSW
735	DO JL = KIDIA,KFDIA
736	ZTOL=_ZERO_
737	ZGL =_ZERO_
738	ZOL =_ZERO_
739	ZTOI=_ZERO_
740	ZGI =_ZERO_
741	ZOI =_ZERO_
742	ZTOR=_ZERO_
743	ZGR =_ZERO_
744	ZOR =_ZERO_
745	IF (ZFLWP(JL)+ZFIWP(JL)+ZFRWP(JL) /= _ZERO_) THEN
746	IF (ZFLWP(JL) /= _ZERO_) THEN
747	IF (NLIQOPT.NE.0 ) THEN
748	!-- SW: Slingo, 1989
749	ZTOL = ZFLWP(JL)*(RASWCA(JSW)+RASWCB(JSW)/ZRADLP(JL))
750	ZGL = RASWCE(JSW)+RASWCF(JSW)*ZRADLP(JL)
751	ZOL = 1. - RASWCC(JSW)-RASWCD(JSW)*ZRADLP(JL)
752	ELSE
753	!-- SW: Fouquart, 1991
754	ZTOL = ZFLWP(JL)*(RYFWCA(JSW)+RYFWCB(JSW)/ZRADLP(JL))
755	ZGL = RYFWCF(JSW)
756	ZOL = RYFWCC(JSW)-RYFWCD(JSW)EXP(-RYFWCE(JSW)ZTOL)
757	ENDIF
758	ENDIF
759
760	IF (ZFIWP(JL) /= _ZERO_) THEN
761	IF (NICEOPT.LE.1) THEN
762	!-- SW: Ebert-Curry
763	ZTOI = ZFIWP(JL)*(REBCUA(JSW)+REBCUB(JSW)/ZRADIP(JL))
764	ZGI = REBCUE(JSW)+REBCUF(JSW)*ZRADIP(JL)
765	ZOI = _ONE_ - REBCUC(JSW)-REBCUD(JSW)*ZRADIP(JL)
766
767	ELSE IF (NICEOPT.EQ.2) THEN
768	!-- SW: Fu-Liou, 1993
769	Z1RADI = 0.5 / ZRADIP(JL)
770	ZBETAI = RFLAA0(JSW)+Z1RADI* RFLAA1(JSW)
771	ZTOI = ZFIWP(JL) * ZBETAI
772	ZOMGI= RFLBB0(JSW)+ZRADIP(JL)*(RFLBB1(JSW) + ZRADIP(JL) &
773	& (RFLBB2(JSW)+ZRADIP(JL) RFLBB3(JSW) ))
774	ZOI = _ONE_ - ZOMGI
775	ZOMGP= RFLCC0(JSW)+ZRADIP(JL)*(RFLCC1(JSW) + ZRADIP(JL) &
776	& (RFLCC2(JSW)+ZRADIP(JL) RFLCC3(JSW) ))
777	ZFDEL= RFLDD0(JSW)+ZRADIP(JL)*(RFLDD1(JSW) + ZRADIP(JL) &
778	& (RFLDD2(JSW)+ZRADIP(JL) RFLDD3(JSW) ))
779	ZGI = ((1.-ZFDEL)ZOMGP + ZFDEL3.) / 3.
780
781	ELSE IF (NICEOPT.EQ.3) THEN
782	!-- SW: Fu 1996
783	Z1RADI = _ONE_ / ZDESR(JL)
784	ZBETAI = RFUAA0(JSW)+Z1RADI* RFUAA1(JSW)
785	ZTOI = ZFIWP(JL) * ZBETAI
786	ZOMGI= RFUBB0(JSW)+ZDESR(JL)*(RFUBB1(JSW) + ZDESR(JL) &
787	& (RFUBB2(JSW)+ZDESR(JL) RFUBB3(JSW) ))
788	ZOI = _ONE_ - ZOMGI
789	ZGI = RFUCC0(JSW)+ZDESR(JL)*(RFUCC1(JSW) + ZDESR(JL) &
790	& (RFUCC2(JSW)+ZDESR(JL) RFUCC3(JSW) ))
791
792	ENDIF
793	ENDIF
794
795	! IF (ZFRWP(JL) .NE. 0.) THEN
796	! ZTOR= ZFRWP(JL)0.003_JPRB_JPRBZRAINT(JL)**(-0.22_JPRB)
797	! ZOR = 1._JPRB - RROMA(JSW)ZRAINT(JL)*RROMB(JSW)
798	! ZGR = RRASY(JSW)
799	! END IF
800
801	! - MIX of WATER and ICE CLOUDS
802	! ZTAUMX= ZTOL + ZTOI + ZTOR
803	! ZOMGMX= ZTOLZOL + ZTOIZOI + ZTOR*ZOR
804	! ZASYMX= ZTOLZOLZGL + ZTOIZOIZGI + ZTORZORZGR
805	!
806	! ZASYMX= ZASYMX/ZOMGMX
807	! ZOMGMX= ZOMGMX/ZTAUMX
808
809	IF (.NOT.LINHOM .OR. (LINHOM .AND. NHOWINH.EQ.1) ) THEN
810	ZVL=ZSWFUDG
811	ZVI=ZSWFUDG
812	ZVR=0.
813	ZTAUMX= ZTOLZVL + ZTOIZVI + ZTOR*ZVR
814	ZOMGMX= ZTOLZVLZOL + ZTOIZVIZOI + ZTORZVRZOR
815	ZASYMX= ZTOLZVLZOLZGL + ZTOIZVIZOIZGI + ZTORZVRZOR*ZGR
816	ZASYMX= ZASYMX/ZOMGMX
817	ZOMGMX= ZOMGMX/ZTAUMX
818	ELSE IF (LINHOM .AND. NHOWINH.EQ.2) THEN
819	ZVL=PSQLW(JL,IKL)
820	ZVI=PSQIW(JL,IKL)
821	ZVR=0.
822	ZTAUMX= ZTOLZVL + ZTOIZVI + ZTOR*ZVR
823	ZOMGMX= ZTOLZVLZOL + ZTOIZVIZOI + ZTORZVRZOR
824	ZASYMX= ZTOLZVLZOLZGL + ZTOIZVIZOIZGI + ZTORZVRZOR*ZGR
825	ZASYMX= ZASYMX/ZOMGMX
826	ZOMGMX= ZOMGMX/ZTAUMX
827	ELSE IF (LINHOM .AND. NHOWINH.EQ.3) THEN
828	ZVL=PRLVRL(JL,IKL)
829	ZVI=PRLVRI(JL,IKL)
830	ZVR=0.
831	ZTOL1 = ZTOL/(1.+ZVL)
832	ZTOI1 = ZTOI/(1.+ZVI)
833	ZTOR1 = ZTOR/(1.+ZVR)
834	ZTAUMX= ZTOL1 + ZTOI1 + ZTOR1
835	ZOI=ZOI/(1.+ZVI*(1.-ZOI))
836	ZGI=ZGI(1.+ZVI(1.-ZOI))/(1.+ZVI(1.-ZOIZGI))
837	ZOL=ZOL/(1.+ZVL*(1.-ZOL))
838	ZGL=ZGL(1.+ZVL(1.-ZOL))/(1.+ZVL(1.-ZOLZGL))
839
840	ZOMGMX= ZTOL1ZOL + ZTOI1ZOI + ZTOR1*ZOR
841	ZASYMX= ZTOL1ZOLZGL + ZTOI1ZOIZGI + ZTOR1ZORZGR
842	ZASYMX= ZASYMX/ZOMGMX
843	ZOMGMX= ZOMGMX/ZTAUMX
844	END IF
845	! print 9009,JK,JL,JSW,ZSWFUDG,PSQLW(JL,IKL),PSQIW(JL,IKL) &
846	! & , PRLVRL(JL,IKL),PRLVRI(JL,IKL),ZTOL,ZOL,ZGL,ZTOI,ZOI,ZGI &
847	! & , ZTAUMX,ZOMGMX,ZASYMX
848	9009 format(1x,3I3,14E13.6)
849
850	! --- SW FINAL CLOUD OPTICAL PARAMETERS
851
852	ZCLDSW(JL,JK) = PCLFR(JL,IKL)
853	ZTAU(JL,JSW,JK) = ZTAUMX
854	ZOMEGA(JL,JSW,JK)= ZOMGMX
855	ZCG(JL,JSW,JK) = ZASYMX
856	ENDIF
857
858	! #DB jkjlsw = 0
859	! #DB IF (ZTAU(JL,JSW,JK) .LT.00..OR.ZTAU(JL,JSW,JK) .GT.75. .OR. &
860	! #DB & (k2iii(JL) .EQ.kio.AND.k2jjj(JL) .EQ.kjo) ) THEN
861	! #DB IF (mod(jkjlsw,20).EQ.0) &
862	! #DB & write(6,575) NLIQOPT,NICEOPT
863	! #DB 575 format('IN RADLSW: CLOUD SHrtWAVE OPTICAL PROPERTIES ' &
864	! #DB & ,3x,' NLIQOPT =',I3,' NICEOPT =',I3,/ &
865	! #DB & ,' i j JL JK',7x,'ZTAU',5x,'ZCLDSW',6x,'ZDESR' &
866	! #DB & ,5x,'PRLVRL',5x,'PRLVRI',6x,'PQIWP',6x,'PQLWP',3x,'JSW')
867	! #DB jkjlsw=jkjlsw+1
868	! #DB write(6,603) k2iii(JL),k2jjj(JL),JL,IKL,ZTAU(JL,JSW,JK) ,ZCLDSW(JL,JK) , ZDESR(JL) &
869	! #DB & ,PRLVRL(JL,IKL),PRLVRI(JL,IKL) &
870	! #DB & ,PQIWP(JL,IKL), PQLWP(JL,IKL),JSW
871	! #DB 603 format(4i5,7e11.3,I6)
872	! #DB ENDIF
873
874	ENDDO
875	ENDDO
876
877	DO JL=KIDIA,KFDIA
878	ZTAUINT(JL)=ZTAUINT(JL)+ZTAU(JL,1,JK)
879	END DO
880
881
882	!JL=KIDIA
883	!print 9109,JK,ZCLDSW(JL,JK),ZRADLP(JL),ZRADIP(JL) &
884	! & , (ZTAU(JL,JSW,JK),ZOMEGA(JL,JSW,JK),ZCG(JL,JSW,JK),JSW=1,NSW)
885	9109 format(1x,'ClOptProp: ',I2,f7.4,2f6.1,6(1x,F7.2,1x,F7.4,1x,f6.3))
886	!print *,'Radlsw after SW cloud optical properties for level JK=',JK
887
888
889
890	! 2.4 CLOUD LONGWAVE OPTICAL PROPERTIES FOR EC-OPE
891	! --------------------------------------------
892
893	! -------------------------
894	! --+ LW OPTICAL PARAMETERS + Water (and Ice) from Smith and Shi (1992)
895	! ------------------------- Ice clouds (Ebert, Curry, 1992)
896
897	IF (.NOT.LRRTM) THEN
898
899	DO JL = KIDIA,KFDIA
900	ZALFICE(JL)=_ZERO_
901	ZGAMICE(JL)=_ZERO_
902	ZBICE(JL)=_ZERO_
903	ZTICE(JL)=(PT(JL,IKL)-TSTAND)/TSTAND
904	ZBICFU(JL)=_ZERO_
905	ZKICFU1(JL)=_ZERO_
906	ZKICFU2(JL)=_ZERO_
907	ENDDO
908
909	DO JNU= 1,NSIL
910	DO JL = KIDIA,KFDIA
911	ZRES(JL) = XP(1,JNU)+ZTICE(JL)(XP(2,JNU)+ZTICE(JL)(XP(3,&
912	&JNU)&
913	&+ZTICE(JL)(XP(4,JNU)+ZTICE(JL)(XP(5,JNU)+ZTICE(JL)*(XP(6,&
914	&JNU)&
915	&)))))
916	ZBICE(JL) = ZBICE(JL) + ZRES(JL)
917	ZGAMICE(JL) = ZGAMICE(JL) + REBCUI(JNU)*ZRES(JL)
918	ZALFICE(JL) = ZALFICE(JL) + REBCUJ(JNU)*ZRES(JL)
919	ENDDO
920	ENDDO
921
922	!-- Fu et al. (1998) with M'91 LW scheme
923	DO JRTM=1,16
924	DO JL=KIDIA,KFDIA
925	IF (PT(JL,IKL) < 339._JPRB .AND. PT(JL,IKL) >= 160._JPRB) THEN
926	INDLAY=PT(JL,IKL)-159._JPRB
927	ZTBLAY =PT(JL,IKL)-INT(PT(JL,IKL))
928	ELSE IF (PT(JL,IKL) >= 339._JPRB ) THEN
929	INDLAY=180
930	ZTBLAY =PT(JL,IKL)-339._JPRB
931	ELSE IF (PT(JL,IKL) < 160._JPRB) THEN
932	INDLAY=1
933	ZTBLAY =PT(JL,IKL)-160._JPRB
934	END IF
935	ZADDPLK = TOTPLNK(INDLAY+1,JRTM)-TOTPLNK(INDLAY,JRTM)
936	ZPLANCK = DELWAVE(JRTM) * (TOTPLNK(INDLAY,JRTM) + ZTBLAY*ZADDPLK)
937	ZBICFU(JL) = ZBICFU(JL) + ZPLANCK
938
939	IF (ZIWC(JL) > _ZERO_ ) THEN
940	! ice cloud spectral emissivity a la Fu & Liou (1993)
941	ZRATIO= 0.5 / ZRADIP(JL)
942	ZMSAID = RFULIO(JRTM,1) + ZRATIO&
943	&(RFULIO(JRTM,2) + ZRATIORFULIO(JRTM,3))
944	ZKICFU1(JL) = ZKICFU1(JL)+ ZMSAID*ZPLANCK
945
946	! ice cloud spectral emissivity a la Fu et al (1998)
947	Z1RADI = _ONE_ / ZDESR(JL)
948	ZMSAID = RFUETA(JRTM,1) + Z1RADI&
949	&(RFUETA(JRTM,2) + Z1RADIRFUETA(JRTM,3))
950	ZKICFU2(JL) = ZKICFU2(JL)+ ZMSAID*ZPLANCK
951	END IF
952	END DO
953	END DO
954
955	DO JL = KIDIA,KFDIA
956	ZGAMICE(JL) = ZGAMICE(JL) / ZBICE(JL)
957	ZALFICE(JL) = ZALFICE(JL) / ZBICE(JL)
958	ZKICFU1(JL) = ZKICFU1(JL) / ZBICFU(JL)
959	ZKICFU2(JL) = ZKICFU2(JL) / ZBICFU(JL)
960
961	IF (ZFLWP(JL)+ZFIWP(JL) /= _ZERO_) THEN
962
963	IF (KLWRAD.EQ.2) THEN
964	! ice cloud emissivity a la Smith-Shi
965	ZMULTI=1.2_JPRB-0.006_JPRB*ZRADIP(JL)
966	ZMSAID= 0.113_JPRB*ZMULTI
967	ZMSAIU= 0.093_JPRB*ZMULTI
968	ZMULTL=1.2_JPRB-0.006_JPRB*ZRADLP(JL)
969	ZMSALD= 0.158_JPRB*ZMULTL
970	ZMSALU= 0.130_JPRB*ZMULTL
971	ZZFLWP= ZFLWP(JL)
972	ZZFIWP= ZFIWP(JL)
973
974	ELSE IF (KLWRAD.EQ.0) THEN
975
976	IF (NLIQOPT.EQ.0) THEN
977	! water cloud emissivity a la Smith & Shi (1992)
978	ZMULTL=1.2_JPRB-0.006_JPRB*ZRADLP(JL)
979	ZMSALD= 0.158_JPRB*ZMULTL
980	ZMSALU= 0.130_JPRB*ZMULTL
981
982	ELSE
983	! water cloud emissivity a la Savijarvi (1997)
984	ZMSALU= 0.2441_JPRB-0.0105_JPRB*ZRADLP(JL)
985	ZMSALD= 1.2154_JPRB*ZMSALU
986
987	END IF
988
989	IF (NICEOPT.EQ.0) THEN
990	! ice cloud emissivity a la Smith & Shi (1992)
991	ZMULTI=1.2_JPRB-0.006_JPRB*ZRADIP(JL)
992	ZMSAID= 0.113_JPRB*ZMULTI
993	ZMSAIU= 0.093_JPRB*ZMULTI
994
995	ELSE IF (NICEOPT.EQ.1) THEN
996	! ice cloud emissivity a la Ebert & Curry (1992)
997	ZMSAID= 1.66_JPRB*(ZALFICE(JL)+ZGAMICE(JL)/ZRADIP(JL))
998	ZMSAIU= ZMSAID
999
1000	ELSE IF (NICEOPT.EQ.2) THEN
1001	! ice cloud emissivity a la Fu & Liou (1993)
1002	ZMSAID= 1.66_JPRB*ZKICFU1(JL)
1003	ZMSAIU= ZMSAID
1004
1005	ELSE IF (NICEOPT.EQ.3) THEN
1006	! ice cloud emissivity a la Fu et al. (1998)
1007	ZMSAID= 1.66_JPRB*ZKICFU2(JL)
1008	ZMSAIU= ZMSAID
1009	END IF
1010
1011	! introduce inhomogeneity factor also in LW
1012	ZZFLWP= ZFLWP(JL) * ZLWFUDG
1013	ZZFIWP= ZFIWP(JL) * ZLWFUDG
1014	END IF
1015
1016	! effective cloudiness accounting for condensed water
1017	ZCLDLD(JL,JK) = PCLFR(JL,IKL)(_ONE_-EXP(-ZMSALDZZFLWP-ZMSAID* &
1018	&ZZFIWP))
1019	ZCLDLU(JL,JK) = PCLFR(JL,IKL)(_ONE_-EXP(-ZMSALUZZFLWP-ZMSAIU* &
1020	&ZZFIWP))
1021
1022	END IF
1023	ENDDO
1024
1025	! print *,'Radlsw after LW0 cloud optical properties for level JK=',JK
1026
1027	ELSE
1028
1029	! 2.5 CLOUD LONGWAVE OPTICAL PROPERTIES FOR RRTM
1030	! ------------------------------------------
1031
1032	! -------------------------
1033	! --+ LW OPTICAL PARAMETERS + Water (and Ice) from Savijarvi (1998)
1034	! ------------------------- Ice clouds (Ebert, Curry, 1992)
1035
1036	! No need for a fixed diffusivity factor, accounted for spectrally below
1037	! The detailed spectral structure does not require defining upward and
1038	! downward effective optical properties
1039
1040	! #DB jkjllw=0
1041
1042	DO JRTM=1,16
1043	DO JL = KIDIA,KFDIA
1044	ZTAUCLD(JL,JK,JRTM) = _ZERO_
1045	ZMSALD = _ZERO_
1046	ZMSAID = _ZERO_
1047
1048	IF (ZFLWP(JL)+ZFIWP(JL) /= _ZERO_) THEN
1049
1050	IF (NLIQOPT.EQ.0) THEN
1051	! water cloud total emissivity a la Smith and Shi (1992)
1052	ZMULTL=1.2_JPRB-0.006_JPRB*ZRADLP(JL)
1053	ZMSALD= 0.144_JPRB*ZMULTL / 1.66_JPRB
1054
1055	ELSE IF (NLIQOPT.EQ.1) THEN
1056	! water cloud spectral emissivity a la Savijarvi (1997)
1057	ZMSALD= RHSAVI(JRTM,1) + ZRADLP(JL)&
1058	&(RHSAVI(JRTM,2) + ZRADLP(JL)RHSAVI(JRTM,3))
1059
1060	ELSE IF (NLIQOPT.EQ.2) THEN
1061	! water cloud spectral emissivity a la Lindner and Li (2000)
1062	Z1RADL = _ONE_ / ZRADLP(JL)
1063	! ZMSALD = RLINLI(JRTM,1) + Z1RADL(RLINLI(JRTM,2) + Z1RADL&
1064	! & (RLINLI(JRTM,3) + Z1RADL(RLINLI(JRTM,4) + Z1RADL&
1065	! & RLINLI(JRTM,5) )))
1066
1067	ZMSALD = RLINLI(JRTM,1)+ZRADLP(JL)RLINLI(JRTM,2)+ Z1RADL&
1068	& (RLINLI(JRTM,3) + Z1RADL(RLINLI(JRTM,4) + Z1RADL&
1069	& RLINLI(JRTM,5) ))
1070
1071	END IF
1072
1073	IF (NICEOPT.EQ.0) THEN
1074	! ice cloud emissivity a la Smith & Shi (1992)
1075	ZMULTI=1.2_JPRB-0.006_JPRB*ZRADIP(JL)
1076	ZMSAID= 0.108_JPRB*ZMULTI / 1.66_JPRB
1077
1078	ELSE IF (NICEOPT.EQ.1) THEN
1079	! ice cloud spectral emissivity a la Ebert-Curry (1992)
1080	ZMSAID= REBCUH(JRTM)+REBCUG(JRTM)/ZRADIP(JL)
1081
1082	ELSE IF (NICEOPT.EQ.2) THEN
1083	! ice cloud spectral emissivity a la Fu & Liou (1993)
1084	ZRATIO= 0.5 / ZRADIP(JL)
1085	ZMSAID = RFULIO(JRTM,1) + ZRATIO&
1086	&(RFULIO(JRTM,2) + ZRATIORFULIO(JRTM,3))
1087
1088	ELSE IF (NICEOPT.EQ.3) THEN
1089	! ice cloud spectral emissivity a la Fu et al (1998)
1090	Z1RADI = _ONE_ / ZDESR(JL)
1091	ZMSAID = RFUETA(JRTM,1) + Z1RADI&
1092	&(RFUETA(JRTM,2) + Z1RADIRFUETA(JRTM,3))
1093
1094	END IF
1095
1096	IF (.NOT.LINHOM .OR. (LINHOM .AND. NHOWINH.EQ.1) ) THEN
1097	ZVL=ZLWFUDG
1098	ZVI=ZLWFUDG
1099	ELSE IF (LINHOM .AND. NHOWINH.EQ.2) THEN
1100	ZVL=PSQLW(JL,IKL)
1101	ZVI=PSQIW(JL,IKL)
1102	ELSE IF (LINHOM .AND. NHOWINH.EQ.3) THEN
1103	ZVL=_ONE_/(_ONE_+PRLVRL(JL,IKL))
1104	ZVI=_ONE_/(_ONE_+PRLVRI(JL,IKL))
1105	END IF
1106
1107	ZTAUD = ZVLZMSALDZFLWP(JL)+ZVIZMSAIDZFIWP(JL)
1108
1109	! #DB write(30,333) ZTAUD,ZVL,ZMSALD,ZFLWP(JL),ZVI,ZMSAID,ZFIWP(JL),PQIWP(JL,IKL),PQLWP(JL,IKL)
1110	! #DB 333 format(9e14.6)
1111
1112	! Diffusivity correction within clouds a la Savijarvi
1113	! ZDIFFD=MIN(MAX(1.517_JPRB-0.156_JPRB*LOG(ZTAUD) , _ONE_) , _TWO_)
1114
1115	ZDIFFD=1.66_JPRB
1116	ZTAUCLD(JL,JK,JRTM) = max(_ZERO_,ZTAUD*ZDIFFD)
1117	ENDIF
1118
1119	! #DB IF (ZTAUCLD(JL,JK,JRTM).LT.00..OR.ZTAUCLD(JL,JK,JRTM).GT.75. .OR. &
1120	! #DB & (k2iii(JL) .EQ.kio.AND.k2jjj(JL) .EQ.kjo) ) THEN
1121	! #DB IF (mod(jkjllw,20).EQ.0) &
1122	! #DB & write(6,600) JRTM,NLIQOPT,NICEOPT
1123	! #DB 600 format('IN RADLSW: CLOUD LONGWAVE OPTICAL PROPERTIES FOR RRTM, JRTM =',I3 &
1124	! #DB & ,' NLIQOPT =',I3,' NICEOPT =',I3,/ &
1125	! #DB & ,' i j JL JK',7x,'ZTAU' ,6x,'ZFLWP' ,6x,'ZFIWP' &
1126	! #DB & , 5x,'ZRADLP',5x,'ZRADIP',6x,'PQIWP',6x,'PQLWP')
1127	! #DB jkjllw=jkjllw+1
1128	! #DB write(6,601) k2iii(JL),k2jjj(JL),JL,IKL,ZTAUCLD(JL,JK,JRTM), ZFLWP(JL) , ZFIWP(JL) &
1129	! #DB & ,ZRADLP(JL) ,ZRADIP(JL) &
1130	! #DB & ,PQIWP(JL,IKL), PQLWP(JL,IKL)
1131	! #DB 601 format(4i5,10e11.3)
1132	! #DB ENDIF
1133
1134	ENDDO
1135	ENDDO
1136	! print *,'Radlsw after LW1 cloud optical properties for level JK=',JK
1137
1138	ENDIF
1139
1140	ENDDO
1141
1142	NUAER = NUA
1143	NTRAER = NTRA
1144
1145	! ------------------------------------------------------------------
1146
1147	!* 2.6 DIFFUSIVITY FACTOR OR SATELLITE VIEWING ANGLE
1148	! ---------------------------------------------
1149
1150
1151	DO JL = KIDIA,KFDIA
1152	ZVIEW(JL) = DIFF
1153	ZEMIT(JL) = _ZERO_
1154	ENDDO
1155
1156	! ------------------------------------------------------------------
1157
1158	!* 3. CALL LONGWAVE RADIATION CODE
1159	! ----------------------------
1160
1161
1162	!* 3.1 FULL LONGWAVE RADIATION COMPUTATIONS
1163	! ------------------------------------
1164
1165	!print *,'Just before calling the radiation schemes'
1166	!JL=KIDIA
1167	!DO JK=1,KLEV
1168	! IKL=KLEV+1-JK
1169	! PRINT 9311,JK,PCLFR(JL,IKL),ZCLDLD(JL,JK),ZTAUCLD(JL,JK,1) &
1170	! & ,(ZTAU(JL,JSW,JK),ZOMEGA(JL,JSW,JK),ZCG(JL,JSW,JK),JSW=1,NSW) &
1171	! & ,(PAER(JL,JAE,JK),JAE=1,6)
1172	9311 format(1x,I2,2F8.5,26E12.5)
1173	!END DO
1174	!print *,'KLWRAD=',KLWRAD,' LPHYLIN: ',LPHYLIN,' LRRTM: ',LRRTM
1175
1176	IF (.NOT.LPHYLIN) THEN
1177	IF ( .NOT. LRRTM) THEN
1178
1179
1180	IF (KLWRAD .EQ. 2) THEN
1181	CALL OLW &
1182	& ( KIDIA, KFDIA , KLON , KLEV &
1183	& , PCCO2, ZCLDLD, ZCLDLU &
1184	& , PDP , ZDT0 , ZEMIS &
1185	& , PAPH , POZON , PTH &
1186	& , PAER , PT , ZVIEW , PQ &
1187	& , ZCOOLR,ZCOOLC, ZFLUX, ZFLUC &
1188	& )
1189
1190	ELSE IF (KLWRAD .EQ. 0) THEN
1191
1192	CALL LW &
1193	&( KIDIA , KFDIA , KLON , KLEV , KMODE &
1194	&, PCCO2 , ZCLDLD, ZCLDLU &
1195	&, PDP , ZDT0 , ZEMIS , ZEMIW &
1196	&, ZPMB , POZON , ZTL &
1197	&, PAER , ZTAVE , ZVIEW , PQ &
1198	&, ZCOOLR, ZCOOLC, ZEMIT , ZFLUX, ZFLUC &
1199	&)
1200
1201	END IF
1202
1203	ELSE
1204
1205
1206	!* 3.2 FULL LONGWAVE RADIATION COMPUTATIONS - RRTM
1207	! ------------------------------------ ----
1208
1209	! i) pass POZN (ozone mmr concentration) to RRTM; remove pressure
1210	! weighting applied to POZON in driverMC (below)
1211	! ii) pass ZEMIS and ZEMIW to RRTM; return ZEMIT from RRTM
1212	! iii)pass ZTAUCLD, cloud optical depths (water+ice) to RRTM,
1213	! computed from equations above
1214	! iv) pass ECRT arrays to RRTM arrays in interface routine ECRTATM
1215	! in module rrtm_ecrt.f
1216
1217	DO JL = KIDIA,KFDIA
1218	DO JK = 1, KLEV
1219	ZOZN(JL,JK) = POZON(JL,JK)/PDP(JL,JK)
1220	ENDDO
1221	ENDDO
1222
1223	! #DB jkjllw = 0
1224	! #DB DO JL = KIDIA,KFDIA
1225	! #DB DO JK = 1, KLEV
1226	! #DB IKL = KLEV + 1 - JK
1227	! #DB JAERmin=1
1228	! #DB JAERmax=6
1229	! #DB PAERmin=1000.
1230	! #DB PAERmax=0.
1231	! #DB jTAUCLDmin=1
1232	! #DB jTAUCLDmax=16
1233	! #DB TAUCLDmin=1000.
1234	! #DB TAUCLDmax=0.
1235	! #DB DO JRTM=1,16
1236	! #DB IF (ZTAUCLD(JL,JK,JRTM).LT.TAUCLDmin) THEN
1237	! #DB jTAUCLDmin=JRTM
1238	! #DB TAUCLDmin=ZTAUCLD(JL,JK,JRTM)
1239	! #DB END IF
1240	! #DB IF (ZTAUCLD(JL,JK,JRTM).GT.TAUCLDmax) THEN
1241	! #DB jTAUCLDmax=JRTM
1242	! #DB TAUCLDmax=ZTAUCLD(JL,JK,JRTM)
1243	! #DB END IF
1244	! #DB ENDDO
1245	! #DB DO JAE =1,6
1246	! #DB IF (PAER(JL,JAE,JK).LT.PAERmin) THEN
1247	! #DB JAERmin=JAE
1248	! #DB PAERmin=PAER(JL,JAE,JK)
1249	! #DB END IF
1250	! #DB IF (PAER(JL,JAE,JK).GT.PAERmax) THEN
1251	! #DB JAERmax=JAE
1252	! #DB PAERmax=PAER(JL,JAE,JK)
1253	! #DB END IF
1254	! #DB ENDDO
1255	! #DB IF (TAUCLDmin.LT.0..OR.TAUCLDmax.GT.75.) THEN
1256	! #DB IF (mod(jkjllw,20).EQ.0) &
1257	! #DB & write(6,515)
1258	! #DB 515 format('IN RADLSW: BEFORE RRTM_RRTM_140GP CALL',/ &
1259	! #DB & ,' i j JL JK',7x,'ZOZN',5x,'ZCLDSW' &
1260	! #DB & ,4x,'ZTAUCLDmin',4x,'ZTAUCLDmax' &
1261	! #DB & ,4x,'PAERmin',4x,'PAERmax',6x,'PQIWP',6x,'PQLWP',9x,'PQ')
1262	! #DB jkjllw = jkjllw + 1
1263	! #DB write(6,602) k2iii(JL),k2jjj(JL),JL,JK,ZOZN(JL,JK),ZCLDSW(JL,JK) &
1264	! #DB & ,jTAUCLDmin,ZTAUCLD(JL,JK,jTAUCLDmin) &
1265	! #DB & ,jTAUCLDmax,ZTAUCLD(JL,JK,jTAUCLDmax) &
1266	! #DB & ,PAER(JL,JAERmin,JK),PAER(JL,JAERmax,JK) &
1267	! #DB & ,PQIWP(JL,IKL),PQLWP(JL,IKL),PQ(JL,IKL)
1268	! #DB 602 format(4i5,2e11.3,2(i3,e11.3),8e11.3)
1269	! #DB ENDIF
1270	! #DB ENDDO
1271	! #DB ENDDO
1272
1273	! print *,'Just before calling RRTM'
1274
1275	CALL RRTM_RRTM_140GP &
1276	&( KIDIA , KFDIA , KLON , KLEV &
1277	&, PAER , PAPH , PAP &
1278	&, PTS , PTH , PT &
1279	&, ZEMIS , ZEMIW &
1280	&, PQ , PCCO2 , ZOZN , ZCLDSW , ZTAUCLD &
1281	&, ZEMIT , ZFLUX , ZFLUC , ZTCLEAR &
1282	&)
1283
1284	! print *,'just after RRTM'
1285
1286	ENDIF
1287	ELSE
1288	ZCOOLR(:,:) = _ZERO_
1289	ZCOOLC(:,:) = _ZERO_
1290	ZEMIT (:) = _ZERO_
1291	ZFLUX(:,:,:)= _ZERO_
1292	ZFLUC(:,:,:)= _ZERO_
1293	ENDIF
1294
1295	! ------------------------------------------------------------------
1296
1297	!* 4. CALL SHORTWAVE RADIATION CODE
1298	! -----------------------------
1299
1300
1301	ZRMUZ=_ZERO_
1302	DO JL = KIDIA,KFDIA
1303	ZRMUZ = MAX (ZRMUZ, ZMU0(JL))
1304	ENDDO
1305
1306	IF (ZRMUZ > _ZERO_) THEN
1307	!print *,'CALL SW'
1308
1309	CALL SW &
1310	&( KIDIA , KFDIA , KLON , KLEV , KAER &
1311	&, PRII0 , PCCO2 , ZPSOL , ZALBD , ZALBP , PQ , PQS &
1312	&, ZMU0 , ZCG , ZCLDSW, PDP , ZOMEGA, ZOZ , ZPMB &
1313	&, ZTAU , ZTAVE , PAER &
1314	&, ZHEATR, ZFSDWN, ZFSUP , ZHEATC, ZFCDWN, ZFCUP &
1315	&, ZFSDNN, ZFSDNV, ZFSUPN, ZFSUPV &
1316	&, ZFCDNN, ZFCDNV, ZFCUPN, ZFCUPV &
1317	&, ZSUDU , ZUVDF , ZPARF &
1318	&)
1319
1320	! print *,'just after SW'
1321	! JL=KIDIA
1322	! print *,'just after SW UV & PAR ',ZUVDF(JL),ZPARF(JL)
1323
1324	ENDIF
1325
1326	! #DB jkjlsw = 0
1327	! #DB DO JL = KIDIA,KFDIA
1328	! #DB DO JK = 1,KLEV
1329	! #DB IF (k2iii(JL).EQ.kio.AND.k2jjj(JL).EQ.kjo) THEN
1330	! #DB IF (mod(jkjlsw,20).EQ.0) &
1331	! #DB write(6,525)
1332	! #DB 525 format('IN RADLSW: AFTER SW CALL',/ &
1333	! #DB & ,' i j JL JK' &
1334	! #DB & ,4x,'ZFCDWN',5x,'ZFCUP' ,4x,'ZFSDNN',4x,'ZFCDNN' &
1335	! #DB & ,4x,'ZFSDNV',4x,'ZFSUPN',4x,'ZFSUPV',4x,'ZFCDNN' &
1336	! #DB & ,4x,'ZFCDNV',4x,'ZFCUPN',4x,'ZFCUPV')
1337	! #DB jkjlsw = jkjlsw + 1
1338	! #DB write(6,605) k2iii(JL),k2jjj(JL),JL,JK,ZFCDWN(JL,JK),ZFCUP(JL,JK) &
1339	! #DB & ,ZFSDNN(JL),ZFCDNN(JL),ZFSDNV(JL),ZFSUPN(JL),ZFSUPV(JL) &
1340	! #DB & ,ZFCDNN(JL),ZFCDNV(JL),ZFCUPN(JL),ZFCUPV(JL)
1341	! #DB 605 format(4i5,11e10.3)
1342	! #DB ENDIF
1343	! #DB ENDDO
1344	! #DB ENDDO
1345
1346	! ------------------------------------------------------------------
1347
1348	!* 5. FILL UP THE MODEL NET LW AND SW RADIATIVE FLUXES
1349	! ------------------------------------------------
1350
1351
1352	DO JKL = 1 , KLEV+1
1353	JK = KLEV+1 + 1 - JKL
1354	DO JL = KIDIA,KFDIA
1355	! print 9506,JK,ZFSDWN(JL,JK),ZFSUP(JL,JK),ZFLUX(JL,1,JK),ZFLUX(JL,2,JK) &
1356	! & , ZFCDWN(JL,JK),ZFCUP(JL,JK),ZFLUC(JL,1,JK),ZFLUC(JL,2,JK)
1357	9506 format(1x,I3,8f10.3)
1358
1359	CPFLS(JL,JKL) =CPFLS(JL,JKL) +ZWGHT*(ZFSDWN(JL,JK) - ZFSUP(JL,JK))
1360	CPFLT(JL,JKL) =CPFLT(JL,JKL) +ZWGHT*(- ZFLUX(JL,1,JK) - ZFLUX(JL,2,JK))
1361	CPFCS(JL,JKL) =CPFCS(JL,JKL) +ZWGHT*(ZFCDWN(JL,JK) - ZFCUP(JL,JK))
1362	CPFCT(JL,JKL) =CPFCT(JL,JKL) +ZWGHT*(- ZFLUC(JL,1,JK) - ZFLUC(JL,2,JK))
1363	CPFDCT(JL,JKL)=CPFDCT(JL,JKL)+ZWGHT*ZFLUC(JL,2,JK)
1364	CPFUCT(JL,JKL)=CPFUCT(JL,JKL)+ZWGHT*ZFLUC(JL,1,JK)
1365	CPFDLT(JL,JKL)=CPFDLT(JL,JKL)+ZWGHT*ZFLUX(JL,2,JK)
1366	CPFULT(JL,JKL)=CPFULT(JL,JKL)+ZWGHT*ZFLUX(JL,1,JK)
1367	CPFDCS(JL,JKL)=CPFDCS(JL,JKL)+ZWGHT*ZFCDWN(JL,JK)
1368	CPFUCS(JL,JKL)=CPFUCS(JL,JKL)+ZWGHT*ZFCUP(JL,JK)
1369	CPFDLS(JL,JKL)=CPFDLS(JL,JKL)+ZWGHT*ZFSDWN(JL,JK)
1370	CPFULS(JL,JKL)=CPFULS(JL,JKL)+ZWGHT*ZFSUP(JL,JK)
1371	ENDDO
1372	ENDDO
1373
1374	DO JL = KIDIA,KFDIA
1375	! print 9507,ZFSDWN(JL,1),ZSUDU(JL),ZUVDF(JL),ZPARF(JL)
1376	9507 format(1x,'SW Global Normal UV & PAR:',5f10.3)
1377
1378	CPFRSOD(JL) = CPFRSOD(JL) + ZWGHT*ZFSDWN(JL,1)
1379	CPEMIT (JL) = CPEMIT (JL) + ZWGHT*ZEMIT (JL)
1380	CPSUDU (JL) = CPSUDU (JL) + ZWGHT*ZSUDU (JL)
1381	CPUVDF (JL) = CPUVDF (JL) + ZWGHT*ZUVDF (JL)
1382	CPPARF (JL) = CPPARF (JL) + ZWGHT*ZPARF (JL)
1383
1384	ASWBOX(JL,ICBOX) = -ZFSDWN(JL,KLEV+1) + ZFSUP(JL,KLEV+1)
1385	OLRBOX(JL,ICBOX) = -ZFLUX(JL,1,KLEV+1)
1386	SLWBOX(JL,ICBOX) = -ZFLUX(JL,2,1)
1387	SSWBOX(JL,ICBOX) = -ZFSDWN(JL,1)
1388	TAUBOX(JL,ICBOX) = ZTAUINT(JL)
1389	ZTCA(JL) = ZTCA(JL) + ZWGHT*ZCOL(JL)
1390	! print 9508,ICBOX,ASWBOX(JL,ICBOX),OLRBOX(JL,ICBOX),SLWBOX(JL,ICBOX) &
1391	! & ,SSWBOX(JL,ICBOX),TAUBOX(JL,ICBOX),ZCOL(JL),ZTCA(JL),ZTCC(JL)
1392	9508 format(1x,'radlsw',I3,5F10.3,1x,3F7.4)
1393	ENDDO
1394
1395
1396	ENDDO
1397	!
1398	!-- end of box-type calculations
1399	!
1400
1401	DO JK = 1 , KLEV+1
1402	DO JL = KIDIA,KFDIA
1403	PFLS(JL,JK) = CPFLS(JL,JK)
1404	PFLT(JL,JK) = CPFLT(JL,JK)
1405	PFCS(JL,JK) = CPFCS(JL,JK)
1406	PFCT(JL,JK) = CPFCT(JL,JK)
1407	PFDCT(JL,JK) = CPFDCT(JL,JK)
1408	PFUCT(JL,JK) = CPFUCT(JL,JK)
1409	PFDLT(JL,JK) = CPFDLT(JL,JK)
1410	PFULT(JL,JK) = CPFULT(JL,JK)
1411	PFDCS(JL,JK) = CPFDCS(JL,JK)
1412	PFUCS(JL,JK) = CPFUCS(JL,JK)
1413	PFDLS(JL,JK) = CPFDLS(JL,JK)
1414	PFULS(JL,JK) = CPFULS(JL,JK)
1415	ENDDO
1416	ENDDO
1417
1418	DO JL = KIDIA,KFDIA
1419	PFRSOD(JL) = CPFRSOD(JL)
1420	PEMIT (JL) = CPEMIT (JL)
1421	PSUDU (JL) = CPSUDU (JL)
1422	PUVDF (JL) = CPUVDF (JL)
1423	PPARF (JL) = CPPARF (JL)
1424	ENDDO
1425
1426	!-- re-organize the box-tyoe output arrays in decreasing order of TAU
1427	DO JL=KIDIA,KFDIA
1428	DO ICBOX=2,NBOX
1429	ZTOI=TAUBOX(JL,ICBOX)
1430	DO IMOV=ICBOX-1,1,-1
1431	IF(TAUBOX(JL,IMOV).LE.ZTOI) GO TO 8001
1432	TAUBOX(JL,IMOV+1)=TAUBOX(JL,IMOV)
1433	END DO
1434	IMOV=0
1435	8001 CONTINUE
1436	TAUBOX(JL,IMOV+1)=ZTOI
1437	END DO
1438	END DO
1439
1440	!-- re-organize the box-type output arrays in decreasing order of ASW
1441	DO JL=KIDIA,KFDIA
1442	DO ICBOX=2,NBOX
1443	ZASW=ASWBOX(JL,ICBOX)
1444	DO IMOV=ICBOX-1,1,-1
1445	IF(ASWBOX(JL,IMOV).LE.ZASW) GO TO 8002
1446	ASWBOX(JL,IMOV+1)=ASWBOX(JL,IMOV)
1447	END DO
1448	IMOV=0
1449	8002 CONTINUE
1450	ASWBOX(JL,IMOV+1)=ZASW
1451	END DO
1452	END DO
1453
1454	!-- re-organize the box-tyoe output arrays in decreasing order of -OLR
1455	DO JL=KIDIA,KFDIA
1456	DO ICBOX=2,NBOX
1457	ZOLR=OLRBOX(JL,ICBOX)
1458	DO IMOV=ICBOX-1,1,-1
1459	IF(OLRBOX(JL,IMOV).LE.ZOLR) GO TO 8003
1460	OLRBOX(JL,IMOV+1)=OLRBOX(JL,IMOV)
1461	END DO
1462	IMOV=0
1463	8003 CONTINUE
1464	OLRBOX(JL,IMOV+1)=ZOLR
1465	END DO
1466	END DO
1467
1468	!-- re-organize the box-tyoe output arrays in decreasing order of SLW
1469	DO JL=KIDIA,KFDIA
1470	DO ICBOX=2,NBOX
1471	ZSLW=SLWBOX(JL,ICBOX)
1472	DO IMOV=ICBOX-1,1,-1
1473	IF(SLWBOX(JL,IMOV).LE.ZSLW) GO TO 8004
1474	SLWBOX(JL,IMOV+1)=SLWBOX(JL,IMOV)
1475	END DO
1476	IMOV=0
1477	8004 CONTINUE
1478	SLWBOX(JL,IMOV+1)=ZSLW
1479	END DO
1480	END DO
1481
1482	!-- re-organize the box-type output arrays in decreasing order of -SSW
1483	DO JL=KIDIA,KFDIA
1484	DO ICBOX=2,NBOX
1485	ZSSW=SSWBOX(JL,ICBOX)
1486	DO IMOV=ICBOX-1,1,-1
1487	IF(SSWBOX(JL,IMOV).LE.ZSSW) GO TO 8005
1488	SSWBOX(JL,IMOV+1)=SSWBOX(JL,IMOV)
1489	END DO
1490	IMOV=0
1491	8005 CONTINUE
1492	SSWBOX(JL,IMOV+1)=ZSSW
1493	END DO
1494	END DO
1495
1496	!-- put all arrays as positive numbers for plotting
1497	DO JL=KIDIA,KFDIA
1498	DO ICBOX=1,NBOX
1499	ASWBOX(JL,ICBOX)=-ASWBOX(JL,ICBOX)
1500	OLRBOX(JL,ICBOX)=-OLRBOX(JL,ICBOX)
1501	SSWBOX(JL,ICBOX)=-SSWBOX(JL,ICBOX)
1502	END DO
1503	END DO
1504
1505	! --------------------------------------------------------------
1506
1507	RETURN
1508	END SUBROUTINE RADLSW

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