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inidissip.F @ 664

Last change on this file since 664 was 334, checked in by aslmd, 13 years ago

LMDZ.MARS:

28/10/11 == FL + AS

ADDED THE NEW FRAMEWORK FOR PHOTOCHEMISTRY
This is not the last version. A new rewritten version of calchim.F [using LAPACK] is yet to be committed.
--> A new version for photochemistry routines : *_B.F no longer exists, new routines in aeronomars
D 333 libf/aeronomars/photochemist_B.F
D 333 libf/aeronomars/init_chimie_B.F
A 0 libf/aeronomars/read_phototable.F
M 333 libf/aeronomars/calchim.F
A 0 libf/aeronomars/photochemistry.F
M 333 libf/aeronomars/chimiedata.h
--> Changed calls to calchim and watercloud [surfdust and surfice needed] in physiq.F
--> Left commented code for outputs in physiq.F [search for FL]
--> Added settings which works for 35 levels in inidissip.F according to FL. Commented for the moment.
--> Checked compilation and run, looks fine. Note that 'jmars.20101220' is needed.

File size: 8.9 KB

Rev	Line
[38]	1	SUBROUTINE inidissip ( lstardis,nitergdiv,nitergrot,niterh ,
	2	* tetagdiv,tetagrot,tetatemp )
	3	c=======================================================================
	4	c initialisation de la dissipation horizontale
	5	c=======================================================================
	6	c-----------------------------------------------------------------------
	7	c declarations:
	8	c -------------
	9
	10	IMPLICIT NONE
	11	#include "dimensions.h"
	12	#include "paramet.h"
	13	#include "comdissipn.h"
	14	#include "comconst.h"
	15	#include "comvert.h"
	16	#include "control.h"
	17
	18	LOGICAL lstardis
	19	INTEGER nitergdiv,nitergrot,niterh
	20	REAL tetagdiv,tetagrot,tetatemp
	21	REAL zvert(llm),zz
	22	REAL zh(ip1jmp1),zu(ip1jmp1),zv(ip1jm),deltap(ip1jmp1,llm)
	23	REAL ullm,vllm,umin,vmin,zhmin,zhmax
	24	REAL zllm,z1llm
	25
	26	INTEGER l,ij,idum,ii
	27	REAL tetamin
	28
	29	EXTERNAL ran1
	30	REAL ran1
	31	real sig_s(llm)
	32	save sig_s
	33	logical firstcall
	34	data firstcall/.true./
	35	save firstcall
	36
	37	REAL fac_mid
	38	REAL fac_up
	39	REAL delta
	40	REAL middle,startalt
	41	SAVE fac_mid, fac_up, delta, startalt, middle
	42
	43	c ------------------------------------------------------
	44	if (firstcall) then
	45	firstcall=.false.
	46	do l=1,llm
	47	sig_s(l)=aps(l)/preff + bps(l)
	48	enddo
	49
	50	c COMPUTING THE VARIATION OF DISSIPATION AS A FUNCTION OF MODEL TOP :
	51	c FF 2004
	52	if (pseudoalt(llm).lt.160.) then
	53	fac_mid=2 ! coeff pour dissipation aux basses/moyennes altitudes
[64]	54	fac_up=30 ! coeff multiplicateur pour dissipation hautes altitudes
	55	startalt=70. ! altitude en Km de la transition mid / up
[38]	56	delta=20.! Intervalle (km) pour le changement mid / up
	57	else ! thermosphere model
	58	fac_mid=2 ! coeff pour dissipation aux basses/moyennes altitudes
	59	fac_up=25 ! coeff multiplicateur pour dissipation hautes altitudes
	60	c startalt: 95 OK for MY24
	61	startalt=95. ! altitude en Km de la transition mid / up
	62	delta=30.! Intervalle (km) pour le changement mid /up
	63	end if
[334]	64
	65	!!!!! reglages 35 niveaux FL
	66	!fac_mid=3
	67	!fac_up=30
	68	!startalt=70.
	69	!delta=20.
	70	!!!! avec dans run.def
	71	!!- mode_sponge=3
	72	!!- idissip/tetagdiv/tetagrot/tetagtemp = 1/2000/3000/3000
	73
[38]	74	middle=startalt+delta/2
	75	write(,) 'Dissipation : '
	76	write(,) 'Multiplication de la dissipation en altitude :',
	77	& ' fac_mid, fac_up =', fac_mid, fac_up
	78	write(,) 'Transition mid /up : startalt, delta =',
	79	& startalt, delta , '(km)'
	80	endif
	81
	82	c-----------------------------------------------------------------------
	83	c
	84	c calcul des valeurs propres des operateurs par methode iterrative:
	85	c -----------------------------------------------------------------
	86
	87	crot = -1.
	88	cdivu = -1.
	89	cdivh = -1.
	90
	91	c calcul de la valeur propre de divgrad:
	92	c --------------------------------------
	93	idum = 0
	94	DO l = 1, llm
	95	DO ij = 1, ip1jmp1
	96	deltap(ij,l) = 1.
	97	ENDDO
	98	ENDDO
	99
	100	idum = -1
	101	zh(1) = RAN1(idum)-.5
	102	idum = 0
	103	DO ij = 2, ip1jmp1
	104	zh(ij) = RAN1(idum) -.5
	105	ENDDO
	106
	107	CALL filtreg (zh,jjp1,1,2,1,.TRUE.,1)
	108
	109	CALL minmax(iip1*jjp1,zh,zhmin,zhmax )
	110
	111	IF ( zhmin .GE. zhmax ) THEN
	112	PRINT*,' Inidissip zh min max ',zhmin,zhmax
	113	STOP'probleme generateur alleatoire dans inidissip'
	114	ENDIF
	115
	116	zllm = ABS( zhmax )
	117	DO l = 1,50
	118	IF(lstardis) THEN
	119	CALL divgrad2(1,zh,deltap,niterh,zh)
	120	ELSE
	121	CALL divgrad (1,zh,niterh,zh)
	122	ENDIF
	123
	124	CALL minmax(iip1*jjp1,zh,zhmin,zhmax )
	125
	126	zllm = ABS( zhmax )
	127	z1llm = 1./zllm
	128	DO ij = 1,ip1jmp1
	129	zh(ij) = zh(ij)* z1llm
	130	ENDDO
	131	ENDDO
	132
	133	IF(lstardis) THEN
	134	cdivh = 1./ zllm
	135	ELSE
	136	cdivh = zllm ** ( -1./niterh )
	137	ENDIF
	138
	139	c calcul des valeurs propres de gradiv (ii =1) et nxgrarot(ii=2)
	140	c -----------------------------------------------------------------
	141	print*,'calcul des valeurs propres'
	142
	143	DO 20 ii = 1, 2
	144	c
	145	DO ij = 1, ip1jmp1
	146	zu(ij) = RAN1(idum) -.5
	147	ENDDO
	148	CALL filtreg (zu,jjp1,1,2,1,.TRUE.,1)
	149	DO ij = 1, ip1jm
	150	zv(ij) = RAN1(idum) -.5
	151	ENDDO
	152	CALL filtreg (zv,jjm,1,2,1,.FALSE.,1)
	153
	154	CALL minmax(iip1*jjp1,zu,umin,ullm )
	155	CALL minmax(iip1*jjm, zv,vmin,vllm )
	156
	157	ullm = ABS ( ullm )
	158	vllm = ABS ( vllm )
	159
	160	DO 5 l = 1, 50
	161	IF(ii.EQ.1) THEN
	162	IF(lstardis) THEN
	163	CALL gradiv2( 1,zu,zv,nitergdiv,zu,zv )
	164	ELSE
	165	CALL gradiv ( 1,zu,zv,nitergdiv,zu,zv )
	166	ENDIF
	167	ELSE
	168	IF(lstardis) THEN
	169	CALL nxgraro2( 1,zu,zv,nitergrot,zu,zv )
	170	ELSE
	171	CALL nxgrarot( 1,zu,zv,nitergrot,zu,zv )
	172	ENDIF
	173	ENDIF
	174
	175	CALL minmax(iip1*jjp1,zu,umin,ullm )
	176	CALL minmax(iip1*jjm, zv,vmin,vllm )
	177
	178	ullm = ABS ( ullm )
	179	vllm = ABS ( vllm )
	180
	181	zllm = MAX( ullm,vllm )
	182	z1llm = 1./ zllm
	183	DO ij = 1, ip1jmp1
	184	zu(ij) = zu(ij)* z1llm
	185	ENDDO
	186	DO ij = 1, ip1jm
	187	zv(ij) = zv(ij)* z1llm
	188	ENDDO
	189	5 CONTINUE
	190
	191	IF ( ii.EQ.1 ) THEN
	192	IF(lstardis) THEN
	193	cdivu = 1./zllm
	194	ELSE
	195	cdivu = zllm **( -1./nitergdiv )
	196	ENDIF
	197	ELSE
	198	IF(lstardis) THEN
	199	crot = 1./ zllm
	200	ELSE
	201	crot = zllm **( -1./nitergrot )
	202	ENDIF
	203	ENDIF
	204
	205	20 CONTINUE
	206
	207	c petit test pour les operateurs non star:
	208	c ----------------------------------------
	209
	210	c IF(.NOT.lstardis) THEN
	211	c fac_mid = rad*24./float(jjm)
	212	c fac_mid = fac_mid*fac_mid
	213	c PRINT*,'coef u ', fac_mid/cdivu, 1./cdivu
	214	c PRINT*,'coef r ', fac_mid/crot , 1./crot
	215	c PRINT*,'coef h ', fac_mid/cdivh, 1./cdivh
	216	c ENDIF
	217
	218	c-----------------------------------------------------------------------
	219	c variation verticale du coefficient de dissipation:
	220	c --------------------------------------------------
	221
	222	DO l=1,llm
	223	zvert(l)=1.
	224	ENDDO
	225
	226	c
	227	DO l = 1, llm
	228	zz = 1. -1./sig_s(l)
	229	zvert(l)= fac_mid -( fac_mid-1.)/( 1.+zz*zz )
	230
	231	c ---------------------------------------------------------------
	232	c Utilisation de la fonction tangente hyperbolique pour augmenter
	233	c arbitrairement la dissipation et donc la stabilite du modele a
	234	c partir d'une certaine altitude.
	235
	236	c Le facteur multiplicatif de basse atmosphere etant deja pris
	237	c en compte, il faut diviser le facteur multiplicatif de haute
	238	c atmosphere par celui-ci.
	239	c ============================================================
	240
	241	zvert(l)= zvert(l)*(1.0+((fac_up/fac_mid-1)
	242	& (1-(0.5(1+tanh(-6./delta*
	243	& (10.*(-log(sig_s(l)))-middle)))))
	244	& ))
	245	ENDDO
	246
	247	c -----------------------------------------------------------------------------
	248
	249	c
	250
	251	PRINT*,'Constantes de temps de la diffusion horizontale'
	252
	253	tetamin = 1.e+6
	254
	255
	256	DO l=1,llm
	257	tetaudiv(l) = zvert(l)/tetagdiv
	258	tetaurot(l) = zvert(l)/tetagrot
	259	tetah(l) = zvert(l)/tetatemp
	260
	261	IF( tetamin.GT. (1./tetaudiv(l)) ) tetamin = 1./ tetaudiv(l)
	262	IF( tetamin.GT. (1./tetaurot(l)) ) tetamin = 1./ tetaurot(l)
	263	IF( tetamin.GT. (1./ tetah(l)) ) tetamin = 1./ tetah(l)
	264	ENDDO
	265
	266	c Calcul automatique de idissip
	267	c -----------------------------
	268	c :::::::::::::::::::::
	269	c A Commenter pour garder la valeur de run.def :
	270	c idissip = INT( tetamin/( 2.dtvriperiod) ) * iperiod
	271	c idissip = MAX(iperiod,idissip)
	272	c :::::::::::::::::::::
	273	dtdiss = idissip * dtvr
	274
	275	PRINT *,' INIDI tetamin dtvr ',tetamin,dtvr,iperiod
	276	PRINT *,' INIDI tetamin idissip ',tetamin,idissip
	277	PRINT *,' INIDI idissip dtdiss ',idissip,dtdiss
	278
	279	PRINT*,'pseudoZ(km) zvert dt(tetagdiv) dt(tetagrot) dt(divgrad)'
	280	DO l = 1,llm
	281	PRINT,pseudoalt(l),zvert(l),dtdisstetaudiv(l),
	282	* dtdisstetaurot(l),dtdisstetah(l)
	283	if ( (dtdiss*tetaudiv(l).gt.1.9).or.
	284	& (dtdiss*tetaurot(l).gt.1.9).or.
	285	& (dtdiss*tetah(l).gt.1.9)) then
	286	PRINT *,'STOP : your dissipation is too intense for the '
	287	PRINT *,'dissipation timestep : unstable model !'
	288	PRINT *,'in run.def, you must increase tetagdiv,'
	289	PRINT *,'(or tetagrot and tetatemp if they are smaller than'
	290	PRINT *,'tetagdiv) OR decrease idissip OR increase day_step)'
	291	stop
	292	end if
	293
	294	ENDDO
	295	c
	296	RETURN
	297	END

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