Context Navigation

cdrag_mod.F90 @ 3999

Last change on this file since 3999 was 3851, checked in by dcugnet, 4 years ago
Update the branch to the current trunk.
Property svn:executable set to ``*
File size: 24.5 KB

Rev	Line
[3817]	1	!
	2	MODULE cdrag_mod
	3	!
	4	! This module contains some procedures for calculation of the cdrag
	5	! coefficients for turbulent diffusion at surface
	6	!
	7	IMPLICIT NONE
	8
	9	CONTAINS
	10	!
	11	!****************************************************************************************
	12	!
	13	!r original routine svn3623
	14	!
	15	SUBROUTINE cdrag(knon, nsrf, &
	16	speed, t1, q1, zgeop1, &
	17	psol, tsurf, qsurf, z0m, z0h, &
	18	cdm, cdh, zri, pref)
	19
	20	USE dimphy
	21	USE indice_sol_mod
	22	USE print_control_mod, ONLY: lunout, prt_level
	23	USE ioipsl_getin_p_mod, ONLY : getin_p
	24
	25	IMPLICIT NONE
	26	! ================================================================= c
	27	!
	28	! Objet : calcul des cdrags pour le moment (pcfm) et
	29	! les flux de chaleur sensible et latente (pcfh) d'apr??s
	30	! Louis 1982, Louis 1979, King et al 2001
	31	! ou Zilitinkevich et al 2002 pour les cas stables, Louis 1979
	32	! et 1982 pour les cas instables
	33	!
	34	! Modified history:
	35	! writting on the 20/05/2016
	36	! modified on the 13/12/2016 to be adapted to LMDZ6
	37	!
	38	! References:
	39	! Louis, J. F., 1979: A parametric model of vertical eddy fluxes in the
	40	! atmosphere. Boundary-Layer Meteorology. 01/1979; 17(2):187-202.
	41	! Louis, J. F., Tiedtke, M. and Geleyn, J. F., 1982: `A short history of the
	42	! operational PBL parametrization at ECMWF'. Workshop on boundary layer
	43	! parametrization, November 1981, ECMWF, Reading, England.
	44	! Page: 19. Equations in Table 1.
	45	! Mascart P, Noilhan J, Giordani H 1995.A MODIFIED PARAMETERIZATION OF FLUX-PROFILE RELATIONSHIPS
	46	! IN THE SURFACE LAYER USING DIFFERENT ROUGHNESS LENGTH VALUES FOR HEAT AND MOMENTUM
	47	! Boundary-Layer Meteorology 72: 331-344
	48	! Anton Beljaars. May 1992. The parametrization of the planetary boundary layer.
	49	! European Centre for Medium-Range Weather Forecasts.
	50	! Equations: 110-113. Page 40.
	51	! Miller,M.J., A.C.M.Beljaars, T.N.Palmer. 1992. The sensitivity of the ECMWF
	52	! model to the parameterization of evaporation from the tropical oceans. J.
	53	! Climate, 5:418-434.
	54	! King J.C, Connolley, W.M ad Derbyshire S.H. 2001, Sensitivity of Modelled Antarctic climate
	55	! to surface and boundary-layer flux parametrizations
	56	! QJRMS, 127, pp 779-794
	57	!
	58	! ================================================================= c
	59	! ================================================================= c
	60	! On choisit le couple de fonctions de correction avec deux flags:
	61	! Un pour les cas instables, un autre pour les cas stables
	62	!
	63	! iflag_corr_insta:
	64	! 1: Louis 1979 avec les modifications de Mascart 1995 (z0/= z0h)
	65	! 2: Louis 1982
	66	! 3: Laurent Li
	67	!
	68	! iflag_corr_sta:
	69	! 1: Louis 1979 avec les modifications de Mascart 1995 (z0/= z0h)
	70	! 2: Louis 1982
	71	! 3: Laurent Li
	72	! 4: King 2001 (SHARP)
	73	! 5: MO 1st order theory (allow collapse of turbulence)
	74	!
	75	!
	76	!*****************************************************************
	77	! Parametres d'entree
	78	!*****************************************************************
	79
	80	INTEGER, INTENT(IN) :: knon, nsrf ! nombre de points de grille sur l'horizontal + type de surface
	81	REAL, DIMENSION(klon), INTENT(IN) :: speed ! module du vent au 1er niveau du modele
	82	REAL, DIMENSION(klon), INTENT(IN) :: zgeop1! geopotentiel au 1er niveau du modele
	83	REAL, DIMENSION(klon), INTENT(IN) :: tsurf ! Surface temperature (K)
	84	REAL, DIMENSION(klon), INTENT(IN) :: qsurf ! Surface humidity (Kg/Kg)
	85	REAL, DIMENSION(klon), INTENT(IN) :: z0m, z0h ! Rugosity at surface (m)
	86	REAL, DIMENSION(klon), INTENT(IN) :: t1 ! Temperature au premier niveau (K)
	87	REAL, DIMENSION(klon), INTENT(IN) :: q1 ! humidite specifique au premier niveau (kg/kg)
	88	REAL, DIMENSION(klon), INTENT(IN) :: psol ! pression au sol
	89
	90
	91
	92	! Parametres de sortie
	93	!******************************************************************
	94	REAL, DIMENSION(klon), INTENT(OUT) :: cdm ! Drag coefficient for momentum
	95	REAL, DIMENSION(klon), INTENT(OUT) :: cdh ! Drag coefficient for heat flux
	96	REAL, DIMENSION(klon), INTENT(OUT) :: zri ! Richardson number
	97	REAL, DIMENSION(klon), INTENT(OUT) :: pref ! Pression au niveau zgeop/RG
	98
	99	! Variables Locales
	100	!******************************************************************
	101
	102
	103	INCLUDE "YOMCST.h"
	104	INCLUDE "YOETHF.h"
	105	INCLUDE "clesphys.h"
	106
	107
	108	REAL, PARAMETER :: CKAP=0.40, CKAPT=0.42
	109	REAL CEPDU2
	110	REAL ALPHA
	111	REAL CB,CC,CD,C2,C3
	112	REAL MU, CM, CH, B, CMstar, CHstar
	113	REAL PM, PH, BPRIME
	114	REAL C
	115	INTEGER ng_q1 ! Number of grids that q1 < 0.0
	116	INTEGER ng_qsurf ! Number of grids that qsurf < 0.0
	117	INTEGER i
	118	REAL zdu2, ztsolv
	119	REAL ztvd, zscf
	120	REAL zucf, zcr
	121	REAL friv, frih
	122	REAL, DIMENSION(klon) :: FM, FH ! stability functions
	123	REAL, DIMENSION(klon) :: cdmn, cdhn ! Drag coefficient in neutral conditions
	124	REAL zzzcd
	125
	126	LOGICAL, SAVE :: firstcall = .TRUE.
	127	!$OMP THREADPRIVATE(firstcall)
	128	INTEGER, SAVE :: iflag_corr_sta
	129	!$OMP THREADPRIVATE(iflag_corr_sta)
	130	INTEGER, SAVE :: iflag_corr_insta
	131	!$OMP THREADPRIVATE(iflag_corr_insta)
	132
	133	!===================================================================c
	134	! Valeurs numeriques des constantes
	135	!===================================================================c
	136
	137
	138	! Minimum du carre du vent
	139
	140	CEPDU2 = (0.1)**2
	141
	142	! Louis 1982
	143
	144	CB=5.0
	145	CC=5.0
	146	CD=5.0
	147
	148
	149	! King 2001
	150
	151	C2=0.25
	152	C3=0.0625
	153
	154
	155	! Louis 1979
	156
	157	BPRIME=4.7
	158	B=9.4
	159
	160
	161	!MO
	162
	163	ALPHA=5.0
	164
	165
	166	! ================================================================= c
	167	! Tests avant de commencer
	168	! Fuxing WANG, 04/03/2015
	169	! To check if there are negative q1, qsurf values.
	170	!====================================================================c
	171	ng_q1 = 0 ! Initialization
	172	ng_qsurf = 0 ! Initialization
	173	DO i = 1, knon
	174	IF (q1(i).LT.0.0) ng_q1 = ng_q1 + 1
	175	IF (qsurf(i).LT.0.0) ng_qsurf = ng_qsurf + 1
	176	ENDDO
	177	IF (ng_q1.GT.0 .and. prt_level > 5) THEN
	178	WRITE(lunout,)" ** Warning: Negative q1(humidity at 1st level) values in cdrag.F90 !"
	179	WRITE(lunout,*)" The total number of the grids is: ", ng_q1
	180	WRITE(lunout,*)" The negative q1 is set to zero "
	181	! abort_message="voir ci-dessus"
	182	! CALL abort_physic(modname,abort_message,1)
	183	ENDIF
	184	IF (ng_qsurf.GT.0 .and. prt_level > 5) THEN
	185	WRITE(lunout,)" ** Warning: Negative qsurf(humidity at surface) values in cdrag.F90 !"
	186	WRITE(lunout,*)" The total number of the grids is: ", ng_qsurf
	187	WRITE(lunout,*)" The negative qsurf is set to zero "
	188	! abort_message="voir ci-dessus"
	189	! CALL abort_physic(modname,abort_message,1)
	190	ENDIF
	191
	192
	193
	194	!=============================================================================c
	195	! Calcul du cdrag
	196	!=============================================================================c
	197
	198	! On choisit les fonctions de stabilite utilisees au premier appel
	199	!**************************************************************************
	200	IF (firstcall) THEN
	201	iflag_corr_sta=2
	202	iflag_corr_insta=2
	203
	204	CALL getin_p('iflag_corr_sta',iflag_corr_sta)
	205	CALL getin_p('iflag_corr_insta',iflag_corr_insta)
	206
	207	firstcall = .FALSE.
	208	ENDIF
	209
	210	!xxxxxxxxxxxxxxxxxxxxxxx
	211	DO i = 1, knon ! Boucle sur l'horizontal
	212	!xxxxxxxxxxxxxxxxxxxxxxx
	213
	214
	215	! calculs preliminaires:
	216	!***********************
	217
	218
	219	zdu2 = MAX(CEPDU2, speed(i)**2)
	220	pref(i) = EXP(LOG(psol(i)) - zgeop1(i)/(RDt1(i) &
	221	(1.+ RETV * max(q1(i),0.0)))) ! negative q1 set to zero
	222	ztsolv = tsurf(i) * (1.0+RETV*max(qsurf(i),0.0)) ! negative qsurf set to zero
	223	ztvd = (t1(i)+zgeop1(i)/RCPD/(1.+RVTMP2*max(q1(i),0.0))) &
	224	(1.+RETVmax(q1(i),0.0)) ! negative q1 set to zero
	225	zri(i) = zgeop1(i)(ztvd-ztsolv)/(zdu2ztvd)
	226
	227
	228	! Coefficients CD neutres : k^2/ln(z/z0) et k^2/(ln(z/z0)*ln(z/z0h)):
	229	!********************************************************************
	230
	231	zzzcd=CKAP/LOG(1.+zgeop1(i)/(RG*z0m(i)))
	232	cdmn(i) = zzzcd*zzzcd
	233	cdhn(i) = zzzcd(CKAP/LOG(1.+zgeop1(i)/(RGz0h(i))))
	234
	235
	236	! Calcul des fonctions de stabilit?? FMs, FHs, FMi, FHi :
	237	!*******************************************************
	238
	239	!''''''''''''''
	240	! Cas instables
	241	!''''''''''''''
	242
	243	IF (zri(i) .LT. 0.) THEN
	244
	245
	246	SELECT CASE (iflag_corr_insta)
	247
	248	CASE (1) ! Louis 1979 + Mascart 1995
	249
	250	MU=LOG(MAX(z0m(i)/z0h(i),0.01))
	251	CMstar=6.8741+2.6933MU-0.3601(MU*2)+0.0154(MU**3)
	252	PM=0.5233-0.0815MU+0.0135(MU*2)-0.001(MU**3)
	253	CHstar=3.2165+4.3431MU+0.536(MU*2)-0.0781(MU**3)
	254	PH=0.5802-0.1571MU+0.0327(MU*2)-0.0026(MU**3)
	255	CH=CHstarBCKAP/LOG(z0m(i)+zgeop1(i)/(RG*z0m(i))) &
	256	& * CKAPT/LOG(z0h(i)+zgeop1(i)/(RG*z0h(i))) &
	257	& * ((zgeop1(i)/(RGz0h(i)))*PH)
	258	CM=CMstarBCKAP/LOG(z0m(i)+zgeop1(i)/(RG*z0m(i))) &
	259	& CKAP/LOG(z0m(i)+zgeop1(i)/(RGz0m(i))) &
	260	& * ((zgeop1(i)/(RGz0m(i)))*PM)
	261
	262
	263
	264
	265	FM(i)=1.-Bzri(i)/(1.+CMSQRT(ABS(zri(i))))
	266	FH(i)=1.-Bzri(i)/(1.+CHSQRT(ABS(zri(i))))
	267
	268	CASE (2) ! Louis 1982
	269
	270	zucf = 1./(1.+3.0CBCCcdmn(i)SQRT(ABS(zri(i)) &
	271	(1.0+zgeop1(i)/(RGz0m(i)))))
	272	FM(i) = AMAX1((1.-2.0CBzri(i)*zucf),f_ri_cd_min)
	273	FH(i) = AMAX1((1.-3.0CBzri(i)*zucf),f_ri_cd_min)
	274
	275
	276	CASE (3) ! Laurent Li
	277
	278
	279	FM(i) = MAX(SQRT(1.0-18.0*zri(i)),f_ri_cd_min)
	280	FH(i) = MAX(SQRT(1.0-18.0*zri(i)),f_ri_cd_min)
	281
	282
	283
	284	CASE default ! Louis 1982
	285
	286	zucf = 1./(1.+3.0CBCCcdmn(i)SQRT(ABS(zri(i)) &
	287	(1.0+zgeop1(i)/(RGz0m(i)))))
	288	FM(i) = AMAX1((1.-2.0CBzri(i)*zucf),f_ri_cd_min)
	289	FH(i) = AMAX1((1.-3.0CBzri(i)*zucf),f_ri_cd_min)
	290
	291
	292	END SELECT
	293
	294
	295
	296	! Calcul des drags
	297
	298
	299	cdm(i)=cdmn(i)*FM(i)
	300	cdh(i)=f_cdrag_tercdhn(i)FH(i)
	301
	302
	303	! Traitement particulier des cas oceaniques
	304	! on applique Miller et al 1992 en l'absence de gustiness
	305
	306	IF (nsrf == is_oce) THEN
	307	! cdh(i)=f_cdrag_ocecdhn(i)FH(i)
	308
	309	IF(iflag_gusts==0) THEN
	310	zcr = (0.0016/(cdmn(i)SQRT(zdu2)))ABS(ztvd-ztsolv)**(1./3.)
	311	cdh(i) =f_cdrag_oce* cdhn(i)(1.0+zcr1.25)*(1./1.25)
	312	ENDIF
	313
	314
	315	cdm(i)=MIN(cdm(i),cdmmax)
	316	cdh(i)=MIN(cdh(i),cdhmax)
	317
	318	END IF
	319
	320
	321
	322	ELSE
	323
	324	!'''''''''''''''
	325	! Cas stables :
	326	!'''''''''''''''
	327	zri(i) = MIN(20.,zri(i))
	328
	329	SELECT CASE (iflag_corr_sta)
	330
	331	CASE (1) ! Louis 1979 + Mascart 1995
	332
	333	FM(i)=MAX(1./((1+BPRIMEzri(i))*2),f_ri_cd_min)
	334	FH(i)=FM(i)
	335
	336
	337	CASE (2) ! Louis 1982
	338
	339	zscf = SQRT(1.+CD*ABS(zri(i)))
	340	FM(i)= AMAX1(1. / (1.+2.CBzri(i)/zscf), f_ri_cd_min)
	341	FH(i)= AMAX1(1./ (1.+3.CBzri(i)*zscf), f_ri_cd_min )
	342
	343
	344	CASE (3) ! Laurent Li
	345
	346	FM(i)=MAX(1.0 / (1.0+10.0zri(i)(1+8.0*zri(i))),f_ri_cd_min)
	347	FH(i)=FM(i)
	348
	349
	350	CASE (4) ! King 2001
	351
	352	if (zri(i) .LT. C2/2.) then
	353	FM(i)=MAX((1.-zri(i)/C2)**2,f_ri_cd_min)
	354	FH(i)= FM(i)
	355
	356
	357	else
	358	FM(i)=MAX(C3((C2/zri(i))*2),f_ri_cd_min)
	359	FH(i)= FM(i)
	360	endif
	361
	362
	363	CASE (5) ! MO
	364
	365	if (zri(i) .LT. 1./alpha) then
	366
	367	FM(i)=MAX((1.-alphazri(i))*2,f_ri_cd_min)
	368	FH(i)=FM(i)
	369
	370	else
	371
	372
	373	FM(i)=MAX(1E-7,f_ri_cd_min)
	374	FH(i)=FM(i)
	375
	376	endif
	377
	378
	379
	380
	381
	382	CASE default ! Louis 1982
	383
	384	zscf = SQRT(1.+CD*ABS(zri(i)))
	385	FM(i)= AMAX1(1. / (1.+2.CBzri(i)/zscf), f_ri_cd_min)
	386	FH(i)= AMAX1(1./ (1.+3.CBzri(i)*zscf), f_ri_cd_min )
	387
	388
	389
	390	END SELECT
	391
	392	! Calcul des drags
	393
	394
	395	cdm(i)=cdmn(i)*FM(i)
	396	cdh(i)=f_cdrag_tercdhn(i)FH(i)
	397
	398	IF(nsrf.EQ.is_oce) THEN
	399
	400	cdh(i)=f_cdrag_ocecdhn(i)FH(i)
	401	cdm(i)=MIN(cdm(i),cdmmax)
	402	cdh(i)=MIN(cdh(i),cdhmax)
	403
	404	ENDIF
	405
	406
	407	ENDIF
	408
	409	!xxxxxxxxxxx
	410	END DO ! Fin de la boucle sur l'horizontal
	411	!xxxxxxxxxxx
	412	! ================================================================= c
	413
	414	END SUBROUTINE cdrag
	415
	416	!
	417	SUBROUTINE cdragn_ri1(knon, nsrf, &
	418	speed, t1, q1, zgeop1, &
	419	psol, tsurf, qsurf, z0m, z0h, &
	420	ri1, iri1, &
	421	cdm, cdh, zri, pref)
	422
	423	USE dimphy
	424	USE indice_sol_mod
	425	USE print_control_mod, ONLY: lunout, prt_level
	426	USE ioipsl_getin_p_mod, ONLY : getin_p
	427
	428	IMPLICIT NONE
	429	! ================================================================= c
	430	!
	431	! Objet : calcul des cdrags pour le moment (pcfm) et
	432	! les flux de chaleur sensible et latente (pcfh) d'apr??s
	433	! Louis 1982, Louis 1979, King et al 2001
	434	! ou Zilitinkevich et al 2002 pour les cas stables, Louis 1979
	435	! et 1982 pour les cas instables
	436	!
	437	! Modified history:
	438	! writting on the 20/05/2016
	439	! modified on the 13/12/2016 to be adapted to LMDZ6
	440	!
	441	! References:
	442	! Louis, J. F., 1979: A parametric model of vertical eddy fluxes in the
	443	! atmosphere. Boundary-Layer Meteorology. 01/1979; 17(2):187-202.
	444	! Louis, J. F., Tiedtke, M. and Geleyn, J. F., 1982: `A short history of the
	445	! operational PBL parametrization at ECMWF'. Workshop on boundary layer
	446	! parametrization, November 1981, ECMWF, Reading, England.
	447	! Page: 19. Equations in Table 1.
	448	! Mascart P, Noilhan J, Giordani H 1995.A MODIFIED PARAMETERIZATION OF FLUX-PROFILE RELATIONSHIPS
	449	! IN THE SURFACE LAYER USING DIFFERENT ROUGHNESS LENGTH VALUES FOR HEAT AND MOMENTUM
	450	! Boundary-Layer Meteorology 72: 331-344
	451	! Anton Beljaars. May 1992. The parametrization of the planetary boundary layer.
	452	! European Centre for Medium-Range Weather Forecasts.
	453	! Equations: 110-113. Page 40.
	454	! Miller,M.J., A.C.M.Beljaars, T.N.Palmer. 1992. The sensitivity of the ECMWF
	455	! model to the parameterization of evaporation from the tropical oceans. J.
	456	! Climate, 5:418-434.
	457	! King J.C, Connolley, W.M ad Derbyshire S.H. 2001, Sensitivity of Modelled Antarctic climate
	458	! to surface and boundary-layer flux parametrizations
	459	! QJRMS, 127, pp 779-794
	460	!
	461	! ================================================================= c
	462	! ================================================================= c
	463	! On choisit le couple de fonctions de correction avec deux flags:
	464	! Un pour les cas instables, un autre pour les cas stables
	465	!
	466	! iflag_corr_insta:
	467	! 1: Louis 1979 avec les modifications de Mascart 1995 (z0/= z0h)
	468	! 2: Louis 1982
	469	! 3: Laurent Li
	470	!
	471	! iflag_corr_sta:
	472	! 1: Louis 1979 avec les modifications de Mascart 1995 (z0/= z0h)
	473	! 2: Louis 1982
	474	! 3: Laurent Li
	475	! 4: King 2001 (SHARP)
	476	! 5: MO 1st order theory (allow collapse of turbulence)
	477	!
	478	!
	479	!*****************************************************************
	480	! Parametres d'entree
	481	!*****************************************************************
	482
	483	INTEGER, INTENT(IN) :: knon, nsrf ! nombre de points de grille sur l'horizontal + type de surface
	484	REAL, DIMENSION(klon), INTENT(IN) :: speed ! module du vent au 1er niveau du modele
	485	REAL, DIMENSION(klon), INTENT(IN) :: zgeop1! geopotentiel au 1er niveau du modele
	486	REAL, DIMENSION(klon), INTENT(IN) :: tsurf ! Surface temperature (K)
	487	REAL, DIMENSION(klon), INTENT(IN) :: qsurf ! Surface humidity (Kg/Kg)
	488	REAL, DIMENSION(klon), INTENT(IN) :: z0m, z0h ! Rugosity at surface (m)
	489	REAL, DIMENSION(klon), INTENT(IN) :: ri1 ! Richardson 1ere couche
	490	INTEGER, INTENT(IN) :: iri1 !
	491	REAL, DIMENSION(klon), INTENT(IN) :: t1 ! Temperature au premier niveau (K)
	492	REAL, DIMENSION(klon), INTENT(IN) :: q1 ! humidite specifique au premier niveau (kg/kg)
	493	REAL, DIMENSION(klon), INTENT(IN) :: psol ! pression au sol
	494
	495
	496
	497	! Parametres de sortie
	498	!******************************************************************
	499	REAL, DIMENSION(klon), INTENT(OUT) :: cdm ! Drag coefficient for heat flux
	500	REAL, DIMENSION(klon), INTENT(OUT) :: cdh ! Drag coefficient for momentum
	501	REAL, DIMENSION(klon), INTENT(OUT) :: zri ! Richardson number
	502	REAL, DIMENSION(klon), INTENT(OUT) :: pref ! Pression au niveau zgeop/RG
	503	! Variables Locales
	504	!******************************************************************
	505
	506
	507	INCLUDE "YOMCST.h"
	508	INCLUDE "YOETHF.h"
	509	INCLUDE "clesphys.h"
	510
	511
	512	REAL, PARAMETER :: CKAP=0.40, CKAPT=0.42
	513	REAL CEPDU2
	514	REAL ALPHA
	515	REAL CB,CC,CD,C2,C3
	516	REAL MU, CM, CH, B, CMstar, CHstar
	517	REAL PM, PH, BPRIME
	518	REAL C
	519	INTEGER ng_q1 ! Number of grids that q1 < 0.0
	520	INTEGER ng_qsurf ! Number of grids that qsurf < 0.0
	521	INTEGER i
	522	REAL zdu2, ztsolv
	523	REAL ztvd, zscf
	524	REAL zucf, zcr
	525	REAL friv, frih
	526	REAL, DIMENSION(klon) :: FM, FH ! stability functions
	527	REAL, DIMENSION(klon) :: cdmn, cdhn ! Drag coefficient in neutral conditions
	528	REAL zzzcd
	529
	530	LOGICAL, SAVE :: firstcall = .TRUE.
	531	!$OMP THREADPRIVATE(firstcall)
	532	INTEGER, SAVE :: iflag_corr_sta
	533	!$OMP THREADPRIVATE(iflag_corr_sta)
	534	INTEGER, SAVE :: iflag_corr_insta
	535	!$OMP THREADPRIVATE(iflag_corr_insta)
	536
	537	!===================================================================c
	538	! Valeurs numeriques des constantes
	539	!===================================================================c
	540
	541
	542	! Minimum du carre du vent
	543
	544	CEPDU2 = (0.1)**2
	545	! Louis 1982
	546
	547	CB=5.0
	548	CC=5.0
	549	CD=5.0
	550
	551
	552	! King 2001
	553
	554	C2=0.25
	555	C3=0.0625
	556
	557
	558	! Louis 1979
	559
	560	BPRIME=4.7
	561	B=9.4
	562
	563
	564	!MO
	565
	566	ALPHA=5.0
	567
	568
	569	! ================================================================= c
	570	! Tests avant de commencer
	571	! Fuxing WANG, 04/03/2015
	572	! To check if there are negative q1, qsurf values.
	573	!====================================================================c
	574	ng_q1 = 0 ! Initialization
	575	ng_qsurf = 0 ! Initialization
	576	DO i = 1, knon
	577	IF (q1(i).LT.0.0) ng_q1 = ng_q1 + 1
	578	IF (qsurf(i).LT.0.0) ng_qsurf = ng_qsurf + 1
	579	ENDDO
	580	IF (ng_q1.GT.0 .and. prt_level > 5) THEN
	581	WRITE(lunout,)" ** Warning: Negative q1(humidity at 1st level) values in cdrag.F90 !"
	582	WRITE(lunout,*)" The total number of the grids is: ", ng_q1
	583	WRITE(lunout,*)" The negative q1 is set to zero "
	584	! abort_message="voir ci-dessus"
	585	! CALL abort_physic(modname,abort_message,1)
	586	ENDIF
	587	IF (ng_qsurf.GT.0 .and. prt_level > 5) THEN
	588	WRITE(lunout,)" ** Warning: Negative qsurf(humidity at surface) values in cdrag.F90 !"
	589	WRITE(lunout,*)" The total number of the grids is: ", ng_qsurf
	590	WRITE(lunout,*)" The negative qsurf is set to zero "
	591	! abort_message="voir ci-dessus"
	592	! CALL abort_physic(modname,abort_message,1)
	593	ENDIF
	594
	595
	596
	597	!=============================================================================c
	598	! Calcul du cdrag
	599	!=============================================================================c
	600
	601	! On choisit les fonctions de stabilite utilisees au premier appel
	602	!**************************************************************************
	603	IF (firstcall) THEN
	604	iflag_corr_sta=2
	605	iflag_corr_insta=2
	606
	607	CALL getin_p('iflag_corr_sta',iflag_corr_sta)
	608	CALL getin_p('iflag_corr_insta',iflag_corr_insta)
	609
	610	firstcall = .FALSE.
	611	ENDIF
	612
	613	!xxxxxxxxxxxxxxxxxxxxxxx
	614	DO i = 1, knon ! Boucle sur l'horizontal
	615	!xxxxxxxxxxxxxxxxxxxxxxx
	616
	617
	618	! calculs preliminaires:
	619	!***********************
	620
	621
	622	zdu2 = MAX(CEPDU2, speed(i)**2)
	623	pref(i) = EXP(LOG(psol(i)) - zgeop1(i)/(RDt1(i) &
	624	(1.+ RETV * max(q1(i),0.0)))) ! negative q1 set to zero
	625	ztsolv = tsurf(i) * (1.0+RETV*max(qsurf(i),0.0)) ! negative qsurf set to zero
	626	ztvd = (t1(i)+zgeop1(i)/RCPD/(1.+RVTMP2*max(q1(i),0.0))) &
	627	(1.+RETVmax(q1(i),0.0)) ! negative q1 set to zero
	628	zri(i) = zgeop1(i)(ztvd-ztsolv)/(zdu2ztvd)
	629
	630	IF (iri1.EQ.1) THEN
	631	zri(i) = ri1(i)
	632	ENDIF
	633
	634	! Coefficients CD neutres : k^2/ln(z/z0) et k^2/(ln(z/z0)*ln(z/z0h)):
	635	!********************************************************************
	636
	637	zzzcd=CKAP/LOG(1.+zgeop1(i)/(RG*z0m(i)))
	638	cdmn(i) = zzzcd*zzzcd
	639	cdhn(i) = zzzcd(CKAP/LOG(1.+zgeop1(i)/(RGz0h(i))))
	640
	641
	642	! Calcul des fonctions de stabilit?? FMs, FHs, FMi, FHi :
	643	!*******************************************************
	644
	645	!''''''''''''''
	646	! Cas instables
	647	!''''''''''''''
	648
	649	IF (zri(i) .LT. 0.) THEN
	650
	651
	652	SELECT CASE (iflag_corr_insta)
	653
	654	CASE (1) ! Louis 1979 + Mascart 1995
	655
	656	MU=LOG(MAX(z0m(i)/z0h(i),0.01))
	657	CMstar=6.8741+2.6933MU-0.3601(MU*2)+0.0154(MU**3)
	658	PM=0.5233-0.0815MU+0.0135(MU*2)-0.001(MU**3)
	659	CHstar=3.2165+4.3431MU+0.536(MU*2)-0.0781(MU**3)
	660	PH=0.5802-0.1571MU+0.0327(MU*2)-0.0026(MU**3)
	661	CH=CHstarBCKAP/LOG(z0m(i)+zgeop1(i)/(RG*z0m(i))) &
	662	& * CKAPT/LOG(z0h(i)+zgeop1(i)/(RG*z0h(i))) &
	663	& * ((zgeop1(i)/(RGz0h(i)))*PH)
	664	CM=CMstarBCKAP/LOG(z0m(i)+zgeop1(i)/(RG*z0m(i))) &
	665	& CKAP/LOG(z0m(i)+zgeop1(i)/(RGz0m(i))) &
	666	& * ((zgeop1(i)/(RGz0m(i)))*PM)
	667
	668
	669
	670
	671	FM(i)=1.-Bzri(i)/(1.+CMSQRT(ABS(zri(i))))
	672	FH(i)=1.-Bzri(i)/(1.+CHSQRT(ABS(zri(i))))
	673
	674	CASE (2) ! Louis 1982
	675
	676	zucf = 1./(1.+3.0CBCCcdmn(i)SQRT(ABS(zri(i)) &
	677	(1.0+zgeop1(i)/(RGz0m(i)))))
	678	FM(i) = AMAX1((1.-2.0CBzri(i)*zucf),f_ri_cd_min)
	679	FH(i) = AMAX1((1.-3.0CBzri(i)*zucf),f_ri_cd_min)
	680
	681
	682	CASE (3) ! Laurent Li
	683
	684
	685	FM(i) = MAX(SQRT(1.0-18.0*zri(i)),f_ri_cd_min)
	686	FH(i) = MAX(SQRT(1.0-18.0*zri(i)),f_ri_cd_min)
	687
	688
	689
	690	CASE default ! Louis 1982
	691
	692	zucf = 1./(1.+3.0CBCCcdmn(i)SQRT(ABS(zri(i)) &
	693	(1.0+zgeop1(i)/(RGz0m(i)))))
	694	FM(i) = AMAX1((1.-2.0CBzri(i)*zucf),f_ri_cd_min)
	695	FH(i) = AMAX1((1.-3.0CBzri(i)*zucf),f_ri_cd_min)
	696
	697
	698	END SELECT
	699
	700
	701
	702	! Calcul des drags
	703
	704
	705	cdm(i)=cdmn(i)*FM(i)
	706	cdh(i)=f_cdrag_tercdhn(i)FH(i)
	707
	708
	709	! Traitement particulier des cas oceaniques
	710	! on applique Miller et al 1992 en l'absence de gustiness
	711
	712	IF (nsrf == is_oce) THEN
	713	! cdh(i)=f_cdrag_ocecdhn(i)FH(i)
	714
	715	IF(iflag_gusts==0) THEN
	716	zcr = (0.0016/(cdmn(i)SQRT(zdu2)))ABS(ztvd-ztsolv)**(1./3.)
	717	cdh(i) =f_cdrag_oce* cdhn(i)(1.0+zcr1.25)*(1./1.25)
	718	ENDIF
	719
	720
	721	cdm(i)=MIN(cdm(i),cdmmax)
	722	cdh(i)=MIN(cdh(i),cdhmax)
	723
	724	END IF
	725
	726
	727
	728	ELSE
	729
	730	!'''''''''''''''
	731	! Cas stables :
	732	!'''''''''''''''
	733	zri(i) = MIN(20.,zri(i))
	734
	735	SELECT CASE (iflag_corr_sta)
	736
	737	CASE (1) ! Louis 1979 + Mascart 1995
	738
	739	FM(i)=MAX(1./((1+BPRIMEzri(i))*2),f_ri_cd_min)
	740	FH(i)=FM(i)
	741
	742
	743	CASE (2) ! Louis 1982
	744
	745	zscf = SQRT(1.+CD*ABS(zri(i)))
	746	FM(i)= AMAX1(1. / (1.+2.CBzri(i)/zscf), f_ri_cd_min)
	747	FH(i)= AMAX1(1./ (1.+3.CBzri(i)*zscf), f_ri_cd_min )
	748
	749
	750	CASE (3) ! Laurent Li
	751
	752	FM(i)=MAX(1.0 / (1.0+10.0zri(i)(1+8.0*zri(i))),f_ri_cd_min)
	753	FH(i)=FM(i)
	754
	755
	756	CASE (4) ! King 2001
	757
	758	if (zri(i) .LT. C2/2.) then
	759	FM(i)=MAX((1.-zri(i)/C2)**2,f_ri_cd_min)
	760	FH(i)= FM(i)
	761
	762
	763	else
	764	FM(i)=MAX(C3((C2/zri(i))*2),f_ri_cd_min)
	765	FH(i)= FM(i)
	766	endif
	767
	768
	769	CASE (5) ! MO
	770
	771	if (zri(i) .LT. 1./alpha) then
	772
	773	FM(i)=MAX((1.-alphazri(i))*2,f_ri_cd_min)
	774	FH(i)=FM(i)
	775
	776	else
	777
	778
	779	FM(i)=MAX(1E-7,f_ri_cd_min)
	780	FH(i)=FM(i)
	781
	782	endif
	783
	784
	785
	786
	787
	788	CASE default ! Louis 1982
	789
	790	zscf = SQRT(1.+CD*ABS(zri(i)))
	791	FM(i)= AMAX1(1. / (1.+2.CBzri(i)/zscf), f_ri_cd_min)
	792	FH(i)= AMAX1(1./ (1.+3.CBzri(i)*zscf), f_ri_cd_min )
	793
	794
	795
	796	END SELECT
	797
	798	! Calcul des drags
	799
	800
	801	cdm(i)=cdmn(i)*FM(i)
	802	cdh(i)=f_cdrag_tercdhn(i)FH(i)
	803
	804	IF(nsrf.EQ.is_oce) THEN
	805
	806	cdh(i)=f_cdrag_ocecdhn(i)FH(i)
	807	cdm(i)=MIN(cdm(i),cdmmax)
	808	cdh(i)=MIN(cdh(i),cdhmax)
	809
	810	ENDIF
	811
	812
	813	ENDIF
	814
	815	!xxxxxxxxxxx
	816	END DO ! Fin de la boucle sur l'horizontal
	817	!xxxxxxxxxxx
	818	! ================================================================= c
	819
	820	END SUBROUTINE cdragn_ri1
	821
	822	END MODULE cdrag_mod

Note: See TracBrowser for help on using the repository browser.

Download in other formats:

Original Format