13 |
USE conf_gcm_m, ONLY : iapp_tracvl |
USE conf_gcm_m, ONLY : iapp_tracvl |
14 |
USE dimens_m, ONLY : iim, jjm, llm, nqmx |
USE dimens_m, ONLY : iim, jjm, llm, nqmx |
15 |
USE iniadvtrac_m, ONLY : iadv |
USE iniadvtrac_m, ONLY : iadv |
16 |
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use massbar_m, only: massbar |
17 |
USE paramet_m, ONLY : iip1, iip2, ijmllm, ijp1llm, ip1jm, ip1jmp1, jjp1, & |
USE paramet_m, ONLY : iip1, iip2, ijmllm, ijp1llm, ip1jm, ip1jmp1, jjp1, & |
18 |
llmp1 |
llmp1 |
19 |
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use vlsplt_m, only: vlsplt |
20 |
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use vlspltqs_m, only: vlspltqs |
21 |
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22 |
REAL, intent(in):: pbaru(ip1jmp1, llm), pbarv(ip1jm, llm) |
REAL, intent(in):: pbaru(ip1jmp1, llm), pbarv(ip1jm, llm) |
23 |
REAL, intent(in):: p(ip1jmp1, llmp1) |
REAL, intent(in):: p(ip1jmp1, llmp1) |
34 |
REAL, save:: massem(ip1jmp1, llm) |
REAL, save:: massem(ip1jmp1, llm) |
35 |
real zdp(ip1jmp1) |
real zdp(ip1jmp1) |
36 |
REAL pbarug(ip1jmp1, llm), pbarvg(ip1jm, llm), wg(ip1jmp1, llm) |
REAL pbarug(ip1jmp1, llm), pbarvg(ip1jm, llm), wg(ip1jmp1, llm) |
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REAL cpuadv(nqmx) |
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37 |
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38 |
INTEGER:: iadvtr = 0 |
INTEGER:: iadvtr = 0 |
39 |
INTEGER ij, l, iq |
INTEGER ij, l, iq |
52 |
REAL qppm(iim*jjp1, llm, nqmx) |
REAL qppm(iim*jjp1, llm, nqmx) |
53 |
REAL fluxwppm(iim, jjp1, llm) |
REAL fluxwppm(iim, jjp1, llm) |
54 |
REAL apppm(llmp1), bpppm(llmp1) |
REAL apppm(llmp1), bpppm(llmp1) |
55 |
LOGICAL:: dum = .TRUE., fill = .TRUE. |
LOGICAL:: fill = .TRUE. |
56 |
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57 |
!----------------------------------------------------------- |
!----------------------------------------------------------- |
58 |
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83 |
! 1. calcul de w |
! 1. calcul de w |
84 |
! 2. groupement des mailles pres du pole. |
! 2. groupement des mailles pres du pole. |
85 |
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86 |
CALL groupe(massem, pbaruc, pbarvc, pbarug, pbarvg, wg) |
CALL groupe(pbaruc, pbarvc, pbarug, pbarvg, wg) |
87 |
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88 |
! test sur l'eventuelle creation de valeurs negatives de la masse |
! test sur l'eventuelle creation de valeurs negatives de la masse |
89 |
DO l = 1, llm - 1 |
DO l = 1, llm - 1 |
105 |
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106 |
! Advection proprement dite |
! Advection proprement dite |
107 |
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108 |
! Calcul des moyennes basées sur la masse |
! Calcul des moyennes bas\'ees sur la masse |
109 |
CALL massbar(massem, massebx, masseby) |
CALL massbar(massem, massebx, masseby) |
110 |
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111 |
! Appel des sous programmes d'advection |
! Appel des sous programmes d'advection |
112 |
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113 |
DO iq = 1, nqmx |
DO iq = 1, nqmx |
114 |
IF (iadv(iq)==0) CYCLE |
select case (iadv(iq)) |
115 |
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case (10) |
116 |
! Schema de Van Leer I MUSCL |
! Schema de Van Leer I MUSCL |
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IF (iadv(iq)==10) THEN |
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117 |
CALL vlsplt(q(:, :, iq), 2., massem, wg, pbarug, pbarvg, dtvr) |
CALL vlsplt(q(:, :, iq), 2., massem, wg, pbarug, pbarvg, dtvr) |
118 |
! Schema "pseudo amont" + test sur humidite specifique |
case (12) |
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! pour la vapeur d'eau. F. Codron |
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ELSE IF (iadv(iq)==14) THEN |
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CALL vlspltqs(q(1, 1, 1), 2., massem, wg, pbarug, pbarvg, dtvr, & |
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p, pk, teta) |
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119 |
! Schema de Frederic Hourdin |
! Schema de Frederic Hourdin |
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ELSE IF (iadv(iq)==12) THEN |
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120 |
! Pas de temps adaptatif |
! Pas de temps adaptatif |
121 |
CALL adaptdt(iadv(iq), dtbon, n, pbarug, massem) |
CALL adaptdt(dtbon, n, pbarug, massem) |
122 |
IF (n>1) THEN |
IF (n>1) THEN |
123 |
WRITE (*, *) 'WARNING horizontal dt=', dtbon, 'dtvr=', dtvr, & |
WRITE (*, *) 'WARNING horizontal dt=', dtbon, 'dtvr=', dtvr, & |
124 |
'n=', n |
'n=', n |
126 |
DO indice = 1, n |
DO indice = 1, n |
127 |
CALL advn(q(1, 1, iq), massem, wg, pbarug, pbarvg, dtbon, 1) |
CALL advn(q(1, 1, iq), massem, wg, pbarug, pbarvg, dtbon, 1) |
128 |
END DO |
END DO |
129 |
ELSE IF (iadv(iq)==13) THEN |
case (13) |
130 |
! Pas de temps adaptatif |
! Pas de temps adaptatif |
131 |
CALL adaptdt(iadv(iq), dtbon, n, pbarug, massem) |
CALL adaptdt(dtbon, n, pbarug, massem) |
132 |
IF (n>1) THEN |
IF (n>1) THEN |
133 |
WRITE (*, *) 'WARNING horizontal dt=', dtbon, 'dtvr=', dtvr, & |
WRITE (*, *) 'WARNING horizontal dt=', dtbon, 'dtvr=', dtvr, & |
134 |
'n=', n |
'n=', n |
136 |
DO indice = 1, n |
DO indice = 1, n |
137 |
CALL advn(q(1, 1, iq), massem, wg, pbarug, pbarvg, dtbon, 2) |
CALL advn(q(1, 1, iq), massem, wg, pbarug, pbarvg, dtbon, 2) |
138 |
END DO |
END DO |
139 |
! Schema de pente SLOPES |
case (14) |
140 |
ELSE IF (iadv(iq)==20) THEN |
! Schema "pseudo amont" + test sur humidite specifique |
141 |
CALL pentes_ini(q(1, 1, iq), wg, massem, pbarug, pbarvg, 0) |
! pour la vapeur d'eau. F. Codron |
142 |
! Schema de Prather |
CALL vlspltqs(q(1, 1, 1), 2., massem, wg, pbarug, pbarvg, dtvr, & |
143 |
ELSE IF (iadv(iq)==30) THEN |
p, pk, teta) |
144 |
! Pas de temps adaptatif |
END select |
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CALL adaptdt(iadv(iq), dtbon, n, pbarug, massem) |
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IF (n>1) THEN |
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WRITE (*, *) 'WARNING horizontal dt=', dtbon, 'dtvr=', dtvr, & |
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'n=', n |
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END IF |
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CALL prather(q(1, 1, iq), wg, massem, pbarug, pbarvg, n, dtbon) |
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! Schemas PPM Lin et Rood |
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ELSE IF (iadv(iq)==11 .OR. (iadv(iq)>=16 .AND. iadv(iq)<=18)) THEN |
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! Test sur le flux horizontal |
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! Pas de temps adaptatif |
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CALL adaptdt(iadv(iq), dtbon, n, pbarug, massem) |
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IF (n>1) THEN |
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WRITE (*, *) 'WARNING horizontal dt=', dtbon, 'dtvr=', dtvr, & |
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'n=', n |
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END IF |
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! Test sur le flux vertical |
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cflmaxz = 0. |
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DO l = 2, llm |
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DO ij = iip2, ip1jm |
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aaa = wg(ij, l)*dtvr/massem(ij, l) |
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cflmaxz = max(cflmaxz, aaa) |
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bbb = -wg(ij, l)*dtvr/massem(ij, l-1) |
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cflmaxz = max(cflmaxz, bbb) |
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END DO |
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END DO |
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IF (cflmaxz>=1) THEN |
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WRITE (*, *) 'WARNING vertical', 'CFLmaxz=', cflmaxz |
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END IF |
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! Ss-prg interface LMDZ.4->PPM3d |
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CALL interpre(q(1, 1, iq), qppm(1, 1, iq), wg, fluxwppm, massem, & |
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apppm, bpppm, massebx, masseby, pbarug, pbarvg, unatppm, & |
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vnatppm, psppm) |
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DO indice = 1, n |
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! VL (version PPM) horiz. et PPM vert. |
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IF (iadv(iq)==11) THEN |
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! Ss-prg PPM3d de Lin |
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CALL ppm3d(1, qppm(1, 1, iq), psppm, psppm, unatppm, & |
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vnatppm, fluxwppm, dtbon, 2, 2, 2, 1, iim, jjp1, 2, & |
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llm, apppm, bpppm, 0.01, 6400000, fill, dum, 220.) |
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! Monotonic PPM |
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ELSE IF (iadv(iq)==16) THEN |
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! Ss-prg PPM3d de Lin |
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CALL ppm3d(1, qppm(1, 1, iq), psppm, psppm, unatppm, & |
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vnatppm, fluxwppm, dtbon, 3, 3, 3, 1, iim, jjp1, 2, & |
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llm, apppm, bpppm, 0.01, 6400000, fill, dum, 220.) |
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! Semi Monotonic PPM |
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ELSE IF (iadv(iq)==17) THEN |
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! Ss-prg PPM3d de Lin |
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CALL ppm3d(1, qppm(1, 1, iq), psppm, psppm, unatppm, & |
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vnatppm, fluxwppm, dtbon, 4, 4, 4, 1, iim, jjp1, 2, & |
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llm, apppm, bpppm, 0.01, 6400000, fill, dum, 220.) |
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! Positive Definite PPM |
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ELSE IF (iadv(iq)==18) THEN |
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! Ss-prg PPM3d de Lin |
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CALL ppm3d(1, qppm(1, 1, iq), psppm, psppm, unatppm, & |
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vnatppm, fluxwppm, dtbon, 5, 5, 5, 1, iim, jjp1, 2, & |
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llm, apppm, bpppm, 0.01, 6400000, fill, dum, 220.) |
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END IF |
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END DO |
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! Ss-prg interface PPM3d-LMDZ.4 |
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CALL interpost(q(1, 1, iq), qppm(1, 1, iq)) |
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END IF |
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145 |
END DO |
END DO |
146 |
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147 |
! on reinitialise a zero les flux de masse cumules |
! on reinitialise a zero les flux de masse cumules |