Context Navigation

readaerosol_interp.F90 @ 2242

Last change on this file since 2242 was 1403, checked in by Laurent Fairhead, 14 years ago

Merged LMDZ4V5.0-dev branch changes r1292:r1399 to trunk.

Validation:
Validation consisted in compiling the HEAD revision of the trunk,
LMDZ4V5.0-dev branch and the merged sources and running different
configurations on local and SX8 machines comparing results.

Local machine: bench configuration, 32x24x11, gfortran

IPSLCM5A configuration (comparison between trunk and merged sources):
- numerical convergence on dynamical fields over 3 days
- start files are equivalent (except for RN and PB fields)
- daily history files equivalent

MH07 configuration, new physics package (comparison between LMDZ4V5.0-dev branch and merged sources):
- numerical convergence on dynamical fields over 3 days
- start files are equivalent (except for RN and PB fields)
- daily history files equivalent

SX8 machine (brodie), 96x95x39 on 4 processors:

IPSLCM5A configuration:
- start files are equivalent (except for RN and PB fields)
- monthly history files equivalent

MH07 configuration:
- start files are equivalent (except for RN and PB fields)
- monthly history files equivalent

Changes to the makegcm and create_make_gcm scripts to take into account
main programs in F90 files

Fusion de la branche LMDZ4V5.0-dev (r1292:r1399) au tronc principal

Validation:
La validation a consisté à compiler la HEAD de le trunk et de la banche
LMDZ4V5.0-dev et les sources fusionnées et de faire tourner le modéle selon
différentes configurations en local et sur SX8 et de comparer les résultats

En local: 32x24x11, config bench/gfortran

pour une config IPSLCM5A (comparaison tronc/fusion):
- convergence numérique sur les champs dynamiques après 3 jours
- restart et restartphy égaux (à part sur RN et Pb)
- fichiers histoire égaux

pour une config nlle physique (MH07) (comparaison LMDZ4v5.0-dev/fusion):
- convergence numérique sur les champs dynamiques après 3 jours
- restart et restartphy égaux
- fichiers histoire équivalents

Sur brodie, 96x95x39 sur 4 proc:

pour une config IPSLCM5A:
- restart et restartphy égaux (à part sur RN et PB)
- pas de différence dans les fichiers histmth.nc

pour une config MH07
- restart et restartphy égaux (à part sur RN et PB)
- pas de différence dans les fichiers histmth.nc

Changement sur makegcm et create_make-gcm pour pouvoir prendre en compte des
programmes principaux en *F90

File size: 22.0 KB

Rev	Line
[1179]	1	! $Id$
	2	!
[1337]	3	SUBROUTINE readaerosol_interp(id_aero, itap, pdtphys, r_day, first, pplay, paprs, t_seri, mass_out, pi_mass_out, load_src)
[1179]	4	!
	5	! This routine will return the mass concentration at actual day(mass_out) and
	6	! the pre-industrial values(pi_mass_out) for aerosol corresponding to "id_aero".
	7	! The mass concentrations for all aerosols are saved in this routine but each
	8	! call to this routine only treats the aerosol "id_aero".
	9	!
	10	! 1) Read in data for the whole year, only at first time step
	11	! 2) Interpolate to the actual day, only at new day
	12	! 3) Interpolate to the model vertical grid (target grid), only at new day
	13	! 4) Test for negative mass values
	14
[1265]	15	USE ioipsl
[1179]	16	USE dimphy, ONLY : klev,klon
	17	USE mod_phys_lmdz_para, ONLY : mpi_rank
	18	USE readaerosol_mod
[1183]	19	USE aero_mod, ONLY : naero_spc, name_aero
[1179]	20	USE write_field_phy
[1237]	21	USE phys_cal_mod
[1179]	22
	23	IMPLICIT NONE
	24
	25	INCLUDE "YOMCST.h"
	26	INCLUDE "chem.h"
	27	INCLUDE "temps.h"
	28	INCLUDE "clesphys.h"
	29	INCLUDE "iniprint.h"
	30	INCLUDE "dimensions.h"
	31	INCLUDE "comvert.h"
	32	!
	33	! Input:
	34	!****************************************************************************************
	35	INTEGER, INTENT(IN) :: id_aero! Identity number for the aerosol to treat
[1237]	36	INTEGER, INTENT(IN) :: itap ! Physic step count
	37	REAL, INTENT(IN) :: pdtphys! Physic day step
[1179]	38	REAL, INTENT(IN) :: r_day ! Day of integration
	39	LOGICAL, INTENT(IN) :: first ! First model timestep
	40	REAL, DIMENSION(klon,klev), INTENT(IN) :: pplay ! pression at model mid-layers
	41	REAL, DIMENSION(klon,klev+1),INTENT(IN):: paprs ! pression between model layers
[1216]	42	REAL, DIMENSION(klon,klev), INTENT(IN) :: t_seri ! air temperature
[1179]	43	!
	44	! Output:
	45	!****************************************************************************************
	46	REAL, INTENT(OUT) :: mass_out(klon,klev) ! Mass of aerosol (monthly mean data,from file) [ug AIBCM/m3]
	47	REAL, INTENT(OUT) :: pi_mass_out(klon,klev) ! Mass of preindustrial aerosol (monthly mean data,from file) [ug AIBCM/m3]
[1337]	48	REAL, INTENT(OUT) :: load_src(klon) ! Load of aerosol (monthly mean data,from file) [kg/m3]
[1179]	49	!
	50	! Local Variables:
	51	!****************************************************************************************
	52	INTEGER :: i, k, ierr
[1237]	53	INTEGER :: iday, iyr, lmt_pas
[1265]	54	! INTEGER :: im, day1, day2, im2
	55	INTEGER :: im, im2
	56	REAL :: day1, day2
[1179]	57	INTEGER :: pi_klev_src ! Only for testing purpose
	58	INTEGER, SAVE :: klev_src ! Number of vertical levles in source field
	59	!$OMP THREADPRIVATE(klev_src)
	60
[1216]	61	REAL :: zrho ! Air density [kg/m3]
	62	REAL :: volm ! Volyme de melange [kg/kg]
[1179]	63	REAL, DIMENSION(klon) :: psurf_day, pi_psurf_day
[1337]	64	REAL, DIMENSION(klon) :: pi_load_src ! Mass load at source grid
[1179]	65	REAL, DIMENSION(klon) :: load_tgt, load_tgt_test
	66	REAL, DIMENSION(klon,klev) :: delp ! pressure difference in each model layer
	67
	68	REAL, ALLOCATABLE, DIMENSION(:,:) :: pplay_src ! pression mid-layer at source levels
	69	REAL, ALLOCATABLE, DIMENSION(:,:) :: tmp1, tmp2 ! Temporary variables
	70	REAL, ALLOCATABLE, DIMENSION(:,:,:,:), SAVE :: var_year ! VAR in right dimension for the total year
	71	REAL, ALLOCATABLE, DIMENSION(:,:,:,:), SAVE :: pi_var_year ! pre-industrial VAR, -"-
	72	!$OMP THREADPRIVATE(var_year,pi_var_year)
	73	REAL, ALLOCATABLE, DIMENSION(:,:,:),SAVE :: var_day ! VAR interpolated to the actual day and model grid
	74	REAL, ALLOCATABLE, DIMENSION(:,:,:),SAVE :: pi_var_day ! pre-industrial VAR, -"-
	75	!$OMP THREADPRIVATE(var_day,pi_var_day)
	76	REAL, ALLOCATABLE, DIMENSION(:,:,:), SAVE :: psurf_year, pi_psurf_year ! surface pressure for the total year
	77	!$OMP THREADPRIVATE(psurf_year, pi_psurf_year)
	78	REAL, ALLOCATABLE, DIMENSION(:,:,:), SAVE :: load_year, pi_load_year ! load in the column for the total year
	79	!$OMP THREADPRIVATE(load_year, pi_load_year)
	80
	81	REAL, DIMENSION(:,:,:), POINTER :: pt_tmp ! Pointer allocated in readaerosol
	82	REAL, POINTER, DIMENSION(:), SAVE :: pt_ap, pt_b ! Pointer for describing the vertical levels
	83	!$OMP THREADPRIVATE(pt_ap, pt_b)
[1265]	84	INTEGER, SAVE :: nbr_tsteps ! number of time steps in file read
	85	REAL, DIMENSION(14), SAVE :: month_len, month_start, month_mid
[1270]	86	!$OMP THREADPRIVATE(nbr_tsteps, month_len, month_start, month_mid)
[1265]	87	REAL :: jDay
[1179]	88
	89	LOGICAL :: lnewday ! Indicates if first time step at a new day
[1237]	90	LOGICAL :: OLDNEWDAY
[1179]	91	LOGICAL,SAVE :: vert_interp ! Indicates if vertical interpolation will be done
[1181]	92	LOGICAL,SAVE :: debug=.FALSE.! Debugging in this subroutine
[1179]	93	!$OMP THREADPRIVATE(vert_interp, debug)
	94
	95
	96	!****************************************************************************************
	97	! Initialization
	98	!
	99	!****************************************************************************************
	100
	101	! Calculation to find if it is a new day
[1237]	102
[1249]	103	IF(mpi_rank == 0 .AND. debug )then
[1237]	104	PRINT*,'CONTROL PANEL REGARDING TIME STEPING'
	105	ENDIF
	106
	107	! Use phys_cal_mod
[1273]	108	iday= day_cur
	109	iyr = year_cur
	110	im = mth_cur
[1237]	111
[1273]	112	! iday = INT(r_day)
	113	! iyr = iday/360
	114	! iday = iday-iyr*360 ! day of the actual year
	115	! iyr = iyr + annee_ref ! year of the run
	116	! im = iday/30 +1 ! the actual month
[1265]	117	CALL ymds2ju(iyr, im, iday, 0., jDay)
[1273]	118	! CALL ymds2ju(iyr, im, iday-(im-1)*30, 0., jDay)
[1179]	119
[1273]	120
[1237]	121	IF(MOD(itap-1,NINT(86400./pdtphys)) == 0)THEN
	122	lnewday=.TRUE.
[1249]	123	ELSE
	124	lnewday=.FALSE.
[1237]	125	ENDIF
[1179]	126
[1249]	127	IF(mpi_rank == 0 .AND. debug)then
[1237]	128	! 0.02 is about 0.5/24, namly less than half an hour
[1403]	129	OLDNEWDAY = (r_day-REAL(iday) < 0.02)
[1237]	130	! Once per day, update aerosol fields
	131	lmt_pas = NINT(86400./pdtphys)
[1403]	132	PRINT*,'r_day-REAL(iday) =',r_day-REAL(iday)
[1237]	133	PRINT*,'itap =',itap
	134	PRINT*,'pdtphys =',pdtphys
	135	PRINT*,'lmt_pas =',lmt_pas
	136	PRINT*,'iday =',iday
	137	PRINT*,'r_day =',r_day
[1246]	138	PRINT*,'day_cur =',day_cur
	139	PRINT*,'mth_cur =',mth_cur
	140	PRINT*,'year_cur =',year_cur
[1237]	141	PRINT*,'NINT(86400./pdtphys) =',NINT(86400./pdtphys)
	142	PRINT*,'MOD(0,1) =',MOD(0,1)
	143	PRINT*,'lnewday =',lnewday
	144	PRINT*,'OLDNEWDAY =',OLDNEWDAY
	145	ENDIF
	146
[1179]	147	IF (.NOT. ALLOCATED(var_day)) THEN
[1181]	148	ALLOCATE( var_day(klon, klev, naero_spc), stat=ierr)
[1179]	149	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 1',1)
[1181]	150	ALLOCATE( pi_var_day(klon, klev, naero_spc), stat=ierr)
[1179]	151	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 2',1)
	152
[1270]	153	ALLOCATE( psurf_year(klon, 12, naero_spc), pi_psurf_year(klon, 12, naero_spc), stat=ierr)
	154	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 3',1)
[1179]	155
[1270]	156	ALLOCATE( load_year(klon, 12, naero_spc), pi_load_year(klon, 12, naero_spc), stat=ierr)
	157	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 4',1)
	158
[1179]	159	lnewday=.TRUE.
	160
	161	NULLIFY(pt_ap)
	162	NULLIFY(pt_b)
	163	END IF
	164
	165	!****************************************************************************************
	166	! 1) Read in data : corresponding to the actual year and preindustrial data.
	167	! Only for the first day of the year.
	168	!
	169	!****************************************************************************************
[1246]	170	IF ( (first .OR. iday==0) .AND. lnewday ) THEN
[1179]	171	NULLIFY(pt_tmp)
	172
	173	! Reading values corresponding to the closest year taking into count the choice of aer_type.
	174	! For aer_type=scenario interpolation between 2 data sets is done in readaerosol.
	175	CALL readaerosol(name_aero(id_aero), aer_type, iyr, klev_src, pt_ap, pt_b, pt_tmp, &
[1270]	176	psurf_year(:,:,id_aero), load_year(:,:,id_aero))
[1179]	177	IF (.NOT. ALLOCATED(var_year)) THEN
[1270]	178	ALLOCATE(var_year(klon, klev_src, 12, naero_spc), stat=ierr)
	179	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 5',1)
[1179]	180	END IF
	181	var_year(:,:,:,id_aero) = pt_tmp(:,:,:)
	182
	183	! Reading values corresponding to the preindustrial concentrations.
	184	CALL readaerosol(name_aero(id_aero), 'preind', iyr, pi_klev_src, pt_ap, pt_b, pt_tmp, &
[1270]	185	pi_psurf_year(:,:,id_aero), pi_load_year(:,:,id_aero))
[1179]	186
	187	! klev_src must be the same in both files.
	188	! Also supposing pt_ap and pt_b to be the same in the 2 files without testing.
	189	IF (pi_klev_src /= klev_src) THEN
	190	WRITE(lunout,*) 'Error! All forcing files for the same aerosol must have the same vertical dimension'
	191	WRITE(lunout,*) 'Aerosol : ', name_aero(id_aero)
	192	CALL abort_gcm('readaerosol_interp','Differnt vertical axes in aerosol forcing files',1)
	193	END IF
	194
	195	IF (.NOT. ALLOCATED(pi_var_year)) THEN
[1270]	196	ALLOCATE(pi_var_year(klon, klev_src, 12, naero_spc), stat=ierr)
	197	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 6',1)
[1179]	198	END IF
	199	pi_var_year(:,:,:,id_aero) = pt_tmp(:,:,:)
	200
	201	IF (debug) THEN
[1270]	202	CALL writefield_phy('var_year_jan',var_year(:,:,1,id_aero),klev_src)
	203	CALL writefield_phy('var_year_dec',var_year(:,:,12,id_aero),klev_src)
[1179]	204	CALL writefield_phy('psurf_src',psurf_year(:,:,id_aero),1)
	205	CALL writefield_phy('pi_psurf_src',pi_psurf_year(:,:,id_aero),1)
	206	CALL writefield_phy('load_year_src',load_year(:,:,id_aero),1)
	207	CALL writefield_phy('pi_load_year_src',pi_load_year(:,:,id_aero),1)
	208	END IF
	209
	210	! Pointer no more useful, deallocate.
	211	DEALLOCATE(pt_tmp)
	212
	213	! Test if vertical interpolation will be needed.
	214	IF (psurf_year(1,1,id_aero)==not_valid .OR. pi_psurf_year(1,1,id_aero)==not_valid ) THEN
	215	! Pressure=not_valid indicates old file format, see module readaerosol
	216	vert_interp = .FALSE.
	217
	218	! If old file format, both psurf_year and pi_psurf_year must be not_valid
	219	IF ( psurf_year(1,1,id_aero) /= pi_psurf_year(1,1,id_aero) ) THEN
	220	WRITE(lunout,*) 'Warning! All forcing files for the same aerosol must have the same structure'
	221	CALL abort_gcm('readaerosol_interp', 'The aerosol files have not the same format',1)
	222	END IF
	223
	224	IF (klev /= klev_src) THEN
	225	WRITE(lunout,*) 'Old format of aerosol file do not allowed vertical interpolation'
	226	CALL abort_gcm('readaerosol_interp', 'Old aerosol file not possible',1)
	227	END IF
	228
	229	ELSE
	230	vert_interp = .TRUE.
	231	END IF
	232
[1265]	233	! Calendar initialisation
	234	!
	235	DO i = 2, 13
[1403]	236	month_len(i) = REAL(ioget_mon_len(year_cur, i-1))
[1265]	237	CALL ymds2ju(year_cur, i-1, 1, 0.0, month_start(i))
	238	ENDDO
[1403]	239	month_len(1) = REAL(ioget_mon_len(year_cur-1, 12))
[1265]	240	CALL ymds2ju(year_cur-1, 12, 1, 0.0, month_start(1))
[1403]	241	month_len(14) = REAL(ioget_mon_len(year_cur+1, 1))
[1265]	242	CALL ymds2ju(year_cur+1, 1, 1, 0.0, month_start(14))
	243	month_mid(:) = month_start (:) + month_len(:)/2.
[1273]	244
	245	if (debug) then
	246	write(lunout,*)' month_len = ',month_len
	247	write(lunout,*)' month_mid = ',month_mid
	248	endif
[1265]	249
[1246]	250	END IF ! IF ( (first .OR. iday==0) .AND. lnewday ) THEN
[1179]	251
	252	!****************************************************************************************
	253	! - 2) Interpolate to the actual day.
	254	! - 3) Interpolate to the model vertical grid.
	255	!
	256	!****************************************************************************************
	257
	258	IF (lnewday) THEN ! only if new day
	259	!****************************************************************************************
	260	! 2) Interpolate to the actual day
	261	!
	262	!****************************************************************************************
[1265]	263	! Find which months and days to use for time interpolation
[1270]	264	nbr_tsteps = 12
[1265]	265	IF (nbr_tsteps == 12) then
	266	IF (jDay < month_mid(im+1)) THEN
	267	im2=im-1
	268	day2 = month_mid(im2+1)
	269	day1 = month_mid(im+1)
	270	IF (im2 <= 0) THEN
	271	! the month is january, thus the month before december
	272	im2=12
	273	END IF
	274	ELSE
	275	! the second half of the month
	276	im2=im+1
	277	day2 = month_mid(im+1)
	278	day1 = month_mid(im2+1)
	279	IF (im2 > 12) THEN
	280	! the month is december, the following thus january
	281	im2=1
	282	ENDIF
	283	END IF
	284	ELSE IF (nbr_tsteps == 14) then
	285	im = im + 1
	286	IF (jDay < month_mid(im)) THEN
	287	! in the first half of the month use month before and actual month
	288	im2=im-1
	289	day2 = month_mid(im2)
	290	day1 = month_mid(im)
	291	ELSE
	292	! the second half of the month
	293	im2=im+1
	294	day2 = month_mid(im)
	295	day1 = month_mid(im2)
	296	END IF
[1179]	297	ELSE
[1265]	298	CALL abort_gcm('readaerosol_interp', 'number of months undefined',1)
	299	ENDIF
[1273]	300	if (debug) then
	301	write(lunout,*)' jDay, day1, day2, im, im2 = ', jDay, day1, day2, im, im2
	302	endif
[1265]	303
	304
[1179]	305	! Time interpolation, still on vertical source grid
	306	ALLOCATE(tmp1(klon,klev_src), tmp2(klon,klev_src),stat=ierr)
	307	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 7',1)
	308
	309	ALLOCATE(pplay_src(klon,klev_src), stat=ierr)
	310	IF (ierr /= 0) CALL abort_gcm('readaerosol_interp', 'pb in allocation 8',1)
	311
	312
	313	DO k=1,klev_src
	314	DO i=1,klon
	315	tmp1(i,k) = &
[1269]	316	var_year(i,k,im2,id_aero) - (jDay-day2)/(day1-day2) * &
[1179]	317	(var_year(i,k,im2,id_aero) - var_year(i,k,im,id_aero))
	318
	319	tmp2(i,k) = &
[1269]	320	pi_var_year(i,k,im2,id_aero) - (jDay-day2)/(day1-day2) * &
[1179]	321	(pi_var_year(i,k,im2,id_aero) - pi_var_year(i,k,im,id_aero))
	322	END DO
	323	END DO
	324
	325	! Time interpolation for pressure at surface, still on vertical source grid
	326	DO i=1,klon
	327	psurf_day(i) = &
[1269]	328	psurf_year(i,im2,id_aero) - (jDay-day2)/(day1-day2) * &
[1179]	329	(psurf_year(i,im2,id_aero) - psurf_year(i,im,id_aero))
	330
	331	pi_psurf_day(i) = &
[1269]	332	pi_psurf_year(i,im2,id_aero) - (jDay-day2)/(day1-day2) * &
[1179]	333	(pi_psurf_year(i,im2,id_aero) - pi_psurf_year(i,im,id_aero))
	334	END DO
	335
	336	! Time interpolation for the load, still on vertical source grid
	337	DO i=1,klon
	338	load_src(i) = &
[1269]	339	load_year(i,im2,id_aero) - (jDay-day2)/(day1-day2) * &
[1179]	340	(load_year(i,im2,id_aero) - load_year(i,im,id_aero))
	341
	342	pi_load_src(i) = &
[1269]	343	pi_load_year(i,im2,id_aero) - (jDay-day2)/(day1-day2) * &
[1179]	344	(pi_load_year(i,im2,id_aero) - pi_load_year(i,im,id_aero))
	345	END DO
	346
	347	!****************************************************************************************
	348	! 3) Interpolate to the model vertical grid (target grid)
	349	!
	350	!****************************************************************************************
	351
	352	IF (vert_interp) THEN
	353
	354	! - Interpolate variable tmp1 (on source grid) to var_day (on target grid)
	355	!********************************************************************************
	356	! a) calculate pression at vertical levels for the source grid using the
	357	! hybrid-sigma coordinates ap and b and the surface pressure, variables from file.
	358	DO k = 1, klev_src
	359	DO i = 1, klon
	360	pplay_src(i,k)= pt_ap(k) + pt_b(k)*psurf_day(i)
	361	END DO
	362	END DO
	363
	364	IF (debug) THEN
	365	CALL writefield_phy('psurf_day_src',psurf_day(:),1)
	366	CALL writefield_phy('pplay_src',pplay_src(:,:),klev_src)
	367	CALL writefield_phy('pplay',pplay(:,:),klev)
	368	CALL writefield_phy('day_src',tmp1,klev_src)
	369	CALL writefield_phy('pi_day_src',tmp2,klev_src)
	370	END IF
	371
	372	! b) vertical interpolation on pressure leveles
	373	CALL pres2lev(tmp1(:,:), var_day(:,:,id_aero), klev_src, klev, pplay_src, pplay, &
	374	1, klon, .FALSE.)
	375
	376	IF (debug) CALL writefield_phy('day_tgt',var_day(:,:,id_aero),klev)
	377
	378	! c) adjust to conserve total aerosol mass load in the vertical pillar
	379	! Calculate the load in the actual pillar and compare with the load
	380	! read from aerosol file.
	381
	382	! Find the pressure difference in each model layer
	383	DO k = 1, klev
	384	DO i = 1, klon
	385	delp(i,k) = paprs(i,k) - paprs (i,k+1)
	386	END DO
	387	END DO
	388
	389	! Find the mass load in the actual pillar, on target grid
	390	load_tgt(:) = 0.
	391	DO k= 1, klev
	392	DO i = 1, klon
[1216]	393	zrho = pplay(i,k)/t_seri(i,k)/RD ! [kg/m3]
	394	volm = var_day(i,k,id_aero)*1.E-9/zrho ! [kg/kg]
	395	load_tgt(i) = load_tgt(i) + 1/RG * volm *delp(i,k)
[1179]	396	END DO
	397	END DO
	398
	399	! Adjust, uniform
	400	DO k = 1, klev
	401	DO i = 1, klon
	402	var_day(i,k,id_aero) = var_day(i,k,id_aero)*load_src(i)/load_tgt(i)
	403	END DO
	404	END DO
	405
	406	IF (debug) THEN
	407	load_tgt_test(:) = 0.
	408	DO k= 1, klev
	409	DO i = 1, klon
[1216]	410	zrho = pplay(i,k)/t_seri(i,k)/RD ! [kg/m3]
	411	volm = var_day(i,k,id_aero)*1.E-9/zrho ! [kg/kg]
	412	load_tgt_test(i) = load_tgt_test(i) + 1/RG * volm*delp(i,k)
[1179]	413	END DO
	414	END DO
	415
	416	CALL writefield_phy('day_tgt2',var_day(:,:,id_aero),klev)
	417	CALL writefield_phy('load_tgt',load_tgt(:),1)
	418	CALL writefield_phy('load_tgt_test',load_tgt_test(:),1)
	419	CALL writefield_phy('load_src',load_src(:),1)
	420	END IF
	421
	422	! - Interpolate variable tmp2 (source grid) to pi_var_day (target grid)
	423	!********************************************************************************
	424	! a) calculate pression at vertical levels at source grid
	425	DO k = 1, klev_src
	426	DO i = 1, klon
	427	pplay_src(i,k)= pt_ap(k) + pt_b(k)*pi_psurf_day(i)
	428	END DO
	429	END DO
	430
	431	IF (debug) THEN
	432	CALL writefield_phy('pi_psurf_day_src',pi_psurf_day(:),1)
	433	CALL writefield_phy('pi_pplay_src',pplay_src(:,:),klev_src)
	434	END IF
	435
	436	! b) vertical interpolation on pressure leveles
	437	CALL pres2lev(tmp2(:,:), pi_var_day(:,:,id_aero), klev_src, klev, pplay_src, pplay, &
	438	1, klon, .FALSE.)
	439
	440	IF (debug) CALL writefield_phy('pi_day_tgt',pi_var_day(:,:,id_aero),klev)
	441
	442	! c) adjust to conserve total aerosol mass load in the vertical pillar
	443	! Calculate the load in the actual pillar and compare with the load
	444	! read from aerosol file.
	445
	446	! Find the load in the actual pillar, on target grid
	447	load_tgt(:) = 0.
	448	DO k = 1, klev
	449	DO i = 1, klon
[1216]	450	zrho = pplay(i,k)/t_seri(i,k)/RD ! [kg/m3]
	451	volm = pi_var_day(i,k,id_aero)*1.E-9/zrho ! [kg/kg]
	452	load_tgt(i) = load_tgt(i) + 1/RG * volm * delp(i,k)
[1179]	453	END DO
	454	END DO
	455
	456	DO k = 1, klev
	457	DO i = 1, klon
	458	pi_var_day(i,k,id_aero) = pi_var_day(i,k,id_aero)*pi_load_src(i)/load_tgt(i)
	459	END DO
	460	END DO
	461
	462	IF (debug) THEN
	463	load_tgt_test(:) = 0.
	464	DO k = 1, klev
	465	DO i = 1, klon
[1216]	466	zrho = pplay(i,k)/t_seri(i,k)/RD ! [kg/m3]
	467	volm = pi_var_day(i,k,id_aero)*1.E-9/zrho ! [kg/kg]
	468	load_tgt_test(i) = load_tgt_test(i) + 1/RG * volm * delp(i,k)
[1179]	469	END DO
	470	END DO
	471	CALL writefield_phy('pi_day_tgt2',pi_var_day(:,:,id_aero),klev)
	472	CALL writefield_phy('pi_load_tgt',load_tgt(:),1)
	473	CALL writefield_phy('pi_load_tgt_test',load_tgt_test(:),1)
	474	CALL writefield_phy('pi_load_src',pi_load_src(:),1)
	475	END IF
	476
	477
	478	ELSE ! No vertical interpolation done
	479
	480	var_day(:,:,id_aero) = tmp1(:,:)
	481	pi_var_day(:,:,id_aero) = tmp2(:,:)
	482
	483	END IF ! vert_interp
	484
	485
	486	! Deallocation
	487	DEALLOCATE(tmp1, tmp2, pplay_src, stat=ierr)
	488
	489	!****************************************************************************************
	490	! 4) Test for negative mass values
	491	!
	492	!****************************************************************************************
	493	IF (MINVAL(var_day(:,:,id_aero)) < 0.) THEN
	494	DO k=1,klev
	495	DO i=1,klon
	496	! Test for var_day
	497	IF (var_day(i,k,id_aero) < 0.) THEN
[1265]	498	IF (jDay-day2 < 0.) WRITE(lunout,*) 'jDay-day2=',jDay-day2
[1179]	499	IF (var_year(i,k,im2,id_aero) - var_year(i,k,im,id_aero) < 0.) THEN
	500	WRITE(lunout,*) trim(name_aero(id_aero)),'(i,k,im2)-', &
	501	trim(name_aero(id_aero)),'(i,k,im)=', &
	502	var_year(i,k,im2,id_aero) - var_year(i,k,im,id_aero)
	503	END IF
	504	WRITE(lunout,*) 'stop for aerosol : ',name_aero(id_aero)
[1273]	505	WRITE(lunout,*) 'day1, day2, jDay = ', day1, day2, jDay
[1179]	506	CALL abort_gcm('readaerosol_interp','Error in interpolation 1',1)
	507	END IF
	508	END DO
	509	END DO
	510	END IF
	511
	512	IF (MINVAL(pi_var_day(:,:,id_aero)) < 0. ) THEN
	513	DO k=1, klev
	514	DO i=1,klon
	515	! Test for pi_var_day
	516	IF (pi_var_day(i,k,id_aero) < 0.) THEN
[1265]	517	IF (jDay-day2 < 0.) WRITE(lunout,*) 'jDay-day2=',jDay-day2
[1179]	518	IF (pi_var_year(i,k,im2,id_aero) - pi_var_year(i,k,im,id_aero) < 0.) THEN
	519	WRITE(lunout,*) trim(name_aero(id_aero)),'(i,k,im2)-', &
	520	trim(name_aero(id_aero)),'(i,k,im)=', &
	521	pi_var_year(i,k,im2,id_aero) - pi_var_year(i,k,im,id_aero)
	522	END IF
	523
	524	WRITE(lunout,*) 'stop for aerosol : ',name_aero(id_aero)
	525	CALL abort_gcm('readaerosol_interp','Error in interpolation 2',1)
	526	END IF
	527	END DO
	528	END DO
	529	END IF
	530
	531	END IF ! lnewday
	532
	533	!****************************************************************************************
	534	! Copy output from saved variables
	535	!
	536	!****************************************************************************************
	537
	538	mass_out(:,:) = var_day(:,:,id_aero)
	539	pi_mass_out(:,:) = pi_var_day(:,:,id_aero)
	540
	541	END SUBROUTINE readaerosol_interp

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

Download in other formats:

Original Format