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lwc.F90 @ 3981

Last change on this file since 3981 was 2089, checked in by Laurent Fairhead, 10 years ago

Inclusion de la physique de MAR

Integration of MAR physics

File size: 9.7 KB

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1	SUBROUTINE LWC &
2	&( KIDIA , KFDIA, KLON , KLEV &
3	&, PBINT , PBSUI, PCLDLD, PCLDLU &
4	&, PCNTRB, PEMIT, PFLUC &
5	&, PFLUX &
6	&)
7
8	!**** LWC - LONGWAVE RADIATION, CLOUD EFFECTS
9
10	! PURPOSE.
11	! --------
12	! INTRODUCES CLOUD EFFECTS ON LONGWAVE FLUXES OR
13	! RADIANCES
14
15	!** INTERFACE.
16	! ----------
17
18	! EXPLICIT ARGUMENTS :
19	! --------------------
20	! ==== INPUTS ===
21	! PBINT : (KLON,KLEV+1) ; HALF LEVEL PLANCK FUNCTION
22	! PBSUI : (KLON) ; SURFACE PLANCK FUNCTION
23	! PCLDLD : (KLON,KLEV) ; DOWNWARD EFFECTIVE CLOUD FRACTION
24	! PCLDLU : (KLON,KLEV) ; UPWARD EFFECTIVE CLOUD FRACTION
25	! PCNTRB : (KLON,KLEV+1,KLEV+1); CLEAR-SKY ENERGY EXCHANGE MATRIX
26	! PEMIT : (KLON) ; SURFACE TOTAL LW EMISSIVITY
27	! PFLUC : (KLON,2,KLEV+1) ; CLEAR-SKY LW RADIATIVE FLUXES
28	! ==== OUTPUTS ===
29	! PFLUX : (KLON,2,KLEV+1) ; TOTAL SKY LW RADIATIVE FLUXES :
30	! 1 ==> UPWARD FLUX TOTAL
31	! 2 ==> DOWNWARD FLUX TOTAL
32
33	! IMPLICIT ARGUMENTS : NONE
34	! --------------------
35
36	! METHOD.
37	! -------
38
39	! 1. INITIALIZES ALL FLUXES TO CLEAR-SKY VALUES
40	! 2. EFFECT OF ONE OVERCAST UNITY EMISSIVITY CLOUD LAYER
41	! 3. EFFECT OF SEMI-TRANSPARENT, PARTIAL OR MULTI-LAYERED
42	! CLOUDS
43
44	! EXTERNALS.
45	! ----------
46
47	! NONE
48
49	! REFERENCE.
50	! ----------
51
52	! SEE RADIATION'S PART OF THE MODEL'S DOCUMENTATION AND
53	! ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS
54
55	! AUTHOR.
56	! -------
57	! JEAN-JACQUES MORCRETTE ECMWF
58
59	! MODIFICATIONS.
60	! --------------
61	! ORIGINAL : 89-07-14
62	! JJ Morcrette 97-04-18 Cleaning
63
64	!-----------------------------------------------------------------------
65
66	#include "tsmbkind.h"
67
68	USE YOERAD , ONLY : NOVLP
69	USE YOERDI , ONLY : REPCLC
70	USE YOEOVLP , ONLY : RA1OVLP
71
72
73	IMPLICIT NONE
74
75
76	! DUMMY INTEGER SCALARS
77	INTEGER_M :: KFDIA
78	INTEGER_M :: KIDIA
79	INTEGER_M :: KLEV
80	INTEGER_M :: KLON
81
82
83
84	!-----------------------------------------------------------------------
85
86	!* 0.1 ARGUMENTS
87	! ---------
88
89	REAL_B ::&
90	&PBINT(KLON,KLEV+1), PBSUI(KLON) &
91	&, PCLDLD(KLON,KLEV) , PCLDLU(KLON,KLEV)&
92	&, PCNTRB(KLON,KLEV+1,KLEV+1)&
93	&, PEMIT(KLON)&
94	&, PFLUC(KLON,2,KLEV+1)
95
96	REAL_B :: PFLUX(KLON,2,KLEV+1)
97
98	!-----------------------------------------------------------------------
99
100	!* 0.2 LOCAL ARRAYS
101	! ------------
102
103	REAL_B :: ZCLEAR(KLON) , ZCLOUD(KLON)&
104	&, ZCLM(KLON,KLEV+1,KLEV+1), ZDNF(KLON,KLEV+1,KLEV+1)&
105	&, ZFD(KLON) , ZFU(KLON)&
106	&, ZUPF(KLON,KLEV+1,KLEV+1)
107
108	! LOCAL INTEGER SCALARS
109	INTEGER_M :: IKCP1, IKM1, IKP1, IMAXC, IMXM1, IMXP1, JCLOUD,&
110	&JK, JK1, JK2, JKJ, JL
111
112	! LOCAL REAL SCALARS
113	REAL_B :: ZALPHA1, ZCFRAC
114
115
116	! ------------------------------------------------------------------
117
118	!* 1. INITIALIZATION
119	! --------------
120
121	!100 CONTINUE
122
123	!print *,' Enter LWC '
124	DO JL = KIDIA,KFDIA
125	ZCLOUD(JL) = _ZERO_
126	ENDDO
127
128	DO JK = 1 , KLEV+1
129	DO JL = KIDIA,KFDIA
130	PFLUX(JL,1,JK) = PFLUC(JL,1,JK)
131	PFLUX(JL,2,JK) = PFLUC(JL,2,JK)
132	ENDDO
133	ENDDO
134
135	!GM*******
136	IMAXC=KLEV
137	!GM*******
138
139
140	! ------------------------------------------------------------------
141
142	!* 2. EFFECT OF CLOUDINESS ON LONGWAVE FLUXES
143	! ---------------------------------------
144
145
146	IMXP1 = IMAXC + 1
147	IMXM1 = IMAXC - 1
148
149	!* 2.0 INITIALIZE TO CLEAR-SKY FLUXES
150	! ------------------------------
151
152	!200 CONTINUE
153
154	DO JK1=1,KLEV+1
155	DO JK2=1,KLEV+1
156	DO JL = KIDIA,KFDIA
157	ZUPF(JL,JK2,JK1)=PFLUC(JL,1,JK1)
158	ZDNF(JL,JK2,JK1)=PFLUC(JL,2,JK1)
159	ENDDO
160	ENDDO
161	ENDDO
162	!print *,' LWC after Initialisation to clear-sky fluxes'
163
164	!* 2.1 FLUXES FOR ONE OVERCAST UNITY EMISSIVITY CLOUD
165	! ----------------------------------------------
166
167	!210 CONTINUE
168
169	DO JCLOUD = 1 , IMAXC
170	IKCP1=JCLOUD+1
171
172	!* 2.1.1 ABOVE THE CLOUD
173	! ---------------
174
175	!2110 CONTINUE
176
177	DO JK=IKCP1,KLEV+1
178	IKM1=JK-1
179	DO JL = KIDIA,KFDIA
180	ZFU(JL)=_ZERO_
181	ENDDO
182
183	IF (JK > IKCP1) THEN
184	DO JKJ=IKCP1,IKM1
185	DO JL = KIDIA,KFDIA
186	ZFU(JL) = ZFU(JL) + PCNTRB(JL,JK,JKJ)
187	ENDDO
188	ENDDO
189	ENDIF
190
191	DO JL = KIDIA,KFDIA
192	ZUPF(JL,IKCP1,JK)=PBINT(JL,JK)-ZFU(JL)
193	ENDDO
194	ENDDO
195
196	!* 2.1.2 BELOW THE CLOUD
197	! ---------------
198
199	!2120 CONTINUE
200
201	DO JK=1,JCLOUD
202	IKP1=JK+1
203	DO JL = KIDIA,KFDIA
204	ZFD(JL)=_ZERO_
205	ENDDO
206
207	IF (JK < JCLOUD) THEN
208	DO JKJ=IKP1,JCLOUD
209	DO JL = KIDIA,KFDIA
210	ZFD(JL) = ZFD(JL) + PCNTRB(JL,JK,JKJ)
211	ENDDO
212	ENDDO
213	ENDIF
214
215	DO JL = KIDIA,KFDIA
216	ZDNF(JL,IKCP1,JK)=-PBINT(JL,JK)-ZFD(JL)
217	ENDDO
218	ENDDO
219
220	ENDDO
221	!print *,' LWC after 213: Fluxes for unity emissivity'
222
223
224	!* 2.2 CLOUD COVER MATRIX
225	! ------------------
226
227	!* ZCLM(JK1,JK2) IS THE OBSCURATION FACTOR BY CLOUD LAYERS BETWEEN
228	! HALF-LEVELS JK1 AND JK2 AS SEEN FROM JK1
229
230	!220 CONTINUE
231
232	DO JK1 = 1 , KLEV+1
233	DO JK2 = 1 , KLEV+1
234	DO JL = KIDIA,KFDIA
235	ZCLM(JL,JK1,JK2) = _ZERO_
236	ENDDO
237	ENDDO
238	ENDDO
239	!print *,' LWC after Initialisation CC matrix'
240
241
242
243	!* 2.4 CLOUD COVER BELOW THE LEVEL OF CALCULATION
244	! ------------------------------------------
245
246	!240 CONTINUE
247
248	DO JK1 = 2 , KLEV+1
249	DO JL = KIDIA,KFDIA
250	ZCLEAR(JL)=_ONE_
251	ZCLOUD(JL)=_ZERO_
252	ENDDO
253
254	DO JK = JK1 - 1 , 1 , -1
255	DO JL = KIDIA,KFDIA
256	IF (NOVLP == 1) THEN
257	!* maximum-random
258	ZCLEAR(JL)=ZCLEAR(JL)*(_ONE_-MAX(PCLDLU(JL,JK),ZCLOUD(JL)))&
259	&/(_ONE_-MIN(ZCLOUD(JL),_ONE_-REPCLC))
260	ZCLM(JL,JK1,JK) = _ONE_ - ZCLEAR(JL)
261	ZCLOUD(JL) = PCLDLU(JL,JK)
262	ELSEIF (NOVLP == 2) THEN
263	!* maximum
264	ZCLOUD(JL) = MAX(ZCLOUD(JL) , PCLDLU(JL,JK))
265	ZCLM(JL,JK1,JK) = ZCLOUD(JL)
266	ELSEIF (NOVLP == 3) THEN
267	!* random
268	ZCLEAR(JL) = ZCLEAR(JL)*(_ONE_ - PCLDLU(JL,JK))
269	ZCLOUD(JL) = _ONE_ - ZCLEAR(JL)
270	ZCLM(JL,JK1,JK) = ZCLOUD(JL)
271	ELSEIF (NOVLP == 4) THEN
272	!** Hogan & Illingworth (2001)
273	ZALPHA1=RA1OVLP(KLEV+1-JK)
274	ZCLEAR(JL)=ZCLEAR(JL)*( &
275	& ZALPHA1*(_ONE_-MAX(PCLDLU(JL,JK),ZCLOUD(JL))) &
276	& /(_ONE_-MIN(ZCLOUD(JL),_ONE_-REPCLC)) &
277	& +(_ONE_-ZALPHA1)*(_ONE_-PCLDLU(JL,JK)) )
278	ZCLM(JL,JK1,JK) = _ONE_ - ZCLEAR(JL)
279	ZCLOUD(JL) = PCLDLU(JL,JK)
280	ENDIF
281	ENDDO
282	ENDDO
283
284	ENDDO
285	!print *,' LWC after 244: CC below level of calculation'
286
287
288	!* 2.5 CLOUD COVER ABOVE THE LEVEL OF CALCULATION
289	! ------------------------------------------
290
291	!250 CONTINUE
292
293	DO JK1 = 1 , KLEV
294	DO JL = KIDIA,KFDIA
295	ZCLEAR(JL)=_ONE_
296	ZCLOUD(JL)=_ZERO_
297	ENDDO
298
299	DO JK = JK1 , KLEV
300	DO JL = KIDIA,KFDIA
301	IF (NOVLP == 1) THEN
302	!* maximum-random
303	ZCLEAR(JL)=ZCLEAR(JL)*(_ONE_-MAX(PCLDLD(JL,JK),ZCLOUD(JL)))&
304	&/(_ONE_-MIN(ZCLOUD(JL),_ONE_-REPCLC))
305	ZCLM(JL,JK1,JK) = _ONE_ - ZCLEAR(JL)
306	ZCLOUD(JL) = PCLDLD(JL,JK)
307	ELSEIF (NOVLP == 2) THEN
308	!* maximum
309	ZCLOUD(JL) = MAX(ZCLOUD(JL) , PCLDLD(JL,JK))
310	ZCLM(JL,JK1,JK) = ZCLOUD(JL)
311	ELSEIF (NOVLP == 3) THEN
312	!* random
313	ZCLEAR(JL) = ZCLEAR(JL)*(_ONE_ - PCLDLD(JL,JK))
314	ZCLOUD(JL) = _ONE_ - ZCLEAR(JL)
315	ZCLM(JL,JK1,JK) = ZCLOUD(JL)
316	ELSEIF (NOVLP == 4) THEN
317	!** Hogan & Illingworth (2001)
318	ZALPHA1=RA1OVLP(KLEV+1-JK)
319	ZCLEAR(JL)=ZCLEAR(JL)*( &
320	& ZALPHA1*(_ONE_-MAX(PCLDLD(JL,JK),ZCLOUD(JL))) &
321	& /(_ONE_-MIN(ZCLOUD(JL),_ONE_-REPCLC)) &
322	& +(_ONE_-ZALPHA1)*(_ONE_ - PCLDLD(JL,JK)) )
323	ZCLM(JL,JK1,JK) = _ONE_ - ZCLEAR(JL)
324	ZCLOUD(JL) = PCLDLD(JL,JK)
325	ENDIF
326	ENDDO
327	ENDDO
328	ENDDO
329	!print *,' LWC after 254: CC above level of calculation'
330
331
332
333	!* 3. FLUXES FOR PARTIAL/MULTIPLE LAYERED CLOUDINESS
334	! ----------------------------------------------
335
336	!300 CONTINUE
337
338	!* 3.1 DOWNWARD FLUXES
339	! ---------------
340
341	!310 CONTINUE
342
343	DO JL = KIDIA,KFDIA
344	PFLUX(JL,2,KLEV+1) = _ZERO_
345	ENDDO
346
347	DO JK1 = KLEV , 1 , -1
348
349	!* CONTRIBUTION FROM CLEAR-SKY FRACTION
350
351	DO JL = KIDIA,KFDIA
352	ZFD (JL) = (_ONE_ - ZCLM(JL,JK1,KLEV)) * ZDNF(JL,1,JK1)
353
354	!* CONTRIBUTION FROM ADJACENT CLOUD
355
356	ZFD(JL) = ZFD(JL) + ZCLM(JL,JK1,JK1) * ZDNF(JL,JK1+1,JK1)
357	ENDDO
358
359	!* CONTRIBUTION FROM OTHER CLOUDY FRACTIONS
360
361	DO JK = KLEV-1 , JK1 , -1
362	DO JL = KIDIA,KFDIA
363	ZCFRAC = ZCLM(JL,JK1,JK+1) - ZCLM(JL,JK1,JK)
364	ZFD(JL) = ZFD(JL) + ZCFRAC * ZDNF(JL,JK+2,JK1)
365	ENDDO
366	ENDDO
367
368	DO JL = KIDIA,KFDIA
369	PFLUX(JL,2,JK1) = ZFD (JL)
370	ENDDO
371
372	ENDDO
373	! print *,' LWC after 317: Downward fluxes'
374
375
376
377
378	!* 3.2 UPWARD FLUX AT THE SURFACE
379	! --------------------------
380
381	!320 CONTINUE
382
383	DO JL = KIDIA,KFDIA
384	PFLUX(JL,1,1) = PEMIT(JL)PBSUI(JL)-(_ONE_-PEMIT(JL))PFLUX(JL,2,1)
385	ENDDO
386
387
388
389	!* 3.3 UPWARD FLUXES
390	! -------------
391
392	!330 CONTINUE
393
394	DO JK1 = 2 , KLEV+1
395
396	!* CONTRIBUTION FROM CLEAR-SKY FRACTION
397
398	DO JL = KIDIA,KFDIA
399	ZFU (JL) = (_ONE_ - ZCLM(JL,JK1,1)) * ZUPF(JL,1,JK1)
400
401	!* CONTRIBUTION FROM ADJACENT CLOUD
402
403	ZFU(JL) = ZFU(JL) + ZCLM(JL,JK1,JK1-1) * ZUPF(JL,JK1,JK1)
404	ENDDO
405
406	!* CONTRIBUTION FROM OTHER CLOUDY FRACTIONS
407
408	DO JK = 2 , JK1-1
409	DO JL = KIDIA,KFDIA
410	ZCFRAC = ZCLM(JL,JK1,JK-1) - ZCLM(JL,JK1,JK)
411	ZFU(JL) = ZFU(JL) + ZCFRAC * ZUPF(JL,JK ,JK1)
412	ENDDO
413	ENDDO
414
415	DO JL = KIDIA,KFDIA
416	PFLUX(JL,1,JK1) = ZFU (JL)
417	ENDDO
418
419	ENDDO
420	! print *,' LWC after 337: Upward fluxes'
421
422	!-----------------------------------------------------------------------
423
424	RETURN
425	END SUBROUTINE LWC

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