[1992] | 1 | |
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[524] | 2 | ! $Header$ |
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| 3 | |
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[1992] | 4 | SUBROUTINE diagphy(airephy, tit, iprt, tops, topl, sols, soll, sens, evap, & |
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| 5 | rain_fall, snow_fall, ts, d_etp_tot, d_qt_tot, d_ec_tot, fs_bound, & |
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| 6 | fq_bound) |
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| 7 | ! ====================================================================== |
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[524] | 8 | |
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[1992] | 9 | ! Purpose: |
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| 10 | ! Compute the thermal flux and the watter mass flux at the atmosphere |
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| 11 | ! boundaries. Print them and also the atmospheric enthalpy change and |
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| 12 | ! the atmospheric mass change. |
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[524] | 13 | |
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[1992] | 14 | ! Arguments: |
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| 15 | ! airephy-------input-R- grid area |
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| 16 | ! tit---------input-A15- Comment to be added in PRINT (CHARACTER*15) |
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| 17 | ! iprt--------input-I- PRINT level ( <=0 : no PRINT) |
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| 18 | ! tops(klon)--input-R- SW rad. at TOA (W/m2), positive up. |
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| 19 | ! topl(klon)--input-R- LW rad. at TOA (W/m2), positive down |
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| 20 | ! sols(klon)--input-R- Net SW flux above surface (W/m2), positive up |
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| 21 | ! (i.e. -1 * flux absorbed by the surface) |
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| 22 | ! soll(klon)--input-R- Net LW flux above surface (W/m2), positive up |
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| 23 | ! (i.e. flux emited - flux absorbed by the surface) |
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| 24 | ! sens(klon)--input-R- Sensible Flux at surface (W/m2), positive down |
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| 25 | ! evap(klon)--input-R- Evaporation + sublimation watter vapour mass flux |
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| 26 | ! (kg/m2/s), positive up |
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| 27 | ! rain_fall(klon) |
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| 28 | ! --input-R- Liquid watter mass flux (kg/m2/s), positive down |
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| 29 | ! snow_fall(klon) |
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| 30 | ! --input-R- Solid watter mass flux (kg/m2/s), positive down |
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| 31 | ! ts(klon)----input-R- Surface temperature (K) |
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| 32 | ! d_etp_tot---input-R- Heat flux equivalent to atmospheric enthalpy |
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| 33 | ! change (W/m2) |
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| 34 | ! d_qt_tot----input-R- Mass flux equivalent to atmospheric watter mass |
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| 35 | ! change (kg/m2/s) |
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| 36 | ! d_ec_tot----input-R- Flux equivalent to atmospheric cinetic energy |
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| 37 | ! change (W/m2) |
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[524] | 38 | |
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[1992] | 39 | ! fs_bound---output-R- Thermal flux at the atmosphere boundaries (W/m2) |
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| 40 | ! fq_bound---output-R- Watter mass flux at the atmosphere boundaries |
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| 41 | ! (kg/m2/s) |
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[524] | 42 | |
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[1992] | 43 | ! J.L. Dufresne, July 2002 |
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| 44 | ! Version prise sur |
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| 45 | ! ~rlmd833/LMDZOR_201102/modipsl/modeles/LMDZ.3.3/libf/phylmd |
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| 46 | ! le 25 Novembre 2002. |
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| 47 | ! ====================================================================== |
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[524] | 48 | |
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[1992] | 49 | USE dimphy |
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| 50 | IMPLICIT NONE |
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| 51 | |
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| 52 | include "YOMCST.h" |
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| 53 | include "YOETHF.h" |
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| 54 | |
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| 55 | ! Input variables |
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| 56 | REAL airephy(klon) |
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| 57 | CHARACTER *15 tit |
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| 58 | INTEGER iprt |
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| 59 | REAL tops(klon), topl(klon), sols(klon), soll(klon) |
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| 60 | REAL sens(klon), evap(klon), rain_fall(klon), snow_fall(klon) |
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| 61 | REAL ts(klon) |
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| 62 | REAL d_etp_tot, d_qt_tot, d_ec_tot |
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| 63 | ! Output variables |
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| 64 | REAL fs_bound, fq_bound |
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| 65 | |
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| 66 | ! Local variables |
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| 67 | REAL stops, stopl, ssols, ssoll |
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| 68 | REAL ssens, sfront, slat |
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| 69 | REAL airetot, zcpvap, zcwat, zcice |
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| 70 | REAL rain_fall_tot, snow_fall_tot, evap_tot |
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| 71 | |
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| 72 | INTEGER i |
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| 73 | |
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| 74 | INTEGER pas |
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| 75 | SAVE pas |
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| 76 | DATA pas/0/ |
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| 77 | !$OMP THREADPRIVATE(pas) |
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| 78 | |
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| 79 | pas = pas + 1 |
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| 80 | stops = 0. |
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| 81 | stopl = 0. |
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| 82 | ssols = 0. |
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| 83 | ssoll = 0. |
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| 84 | ssens = 0. |
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| 85 | sfront = 0. |
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| 86 | evap_tot = 0. |
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| 87 | rain_fall_tot = 0. |
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| 88 | snow_fall_tot = 0. |
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| 89 | airetot = 0. |
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| 90 | |
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| 91 | ! Pour les chaleur specifiques de la vapeur d'eau, de l'eau et de |
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| 92 | ! la glace, on travaille par difference a la chaleur specifique de l' |
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| 93 | ! air sec. En effet, comme on travaille a niveau de pression donne, |
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| 94 | ! toute variation de la masse d'un constituant est totalement |
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| 95 | ! compense par une variation de masse d'air. |
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| 96 | |
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| 97 | zcpvap = rcpv - rcpd |
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| 98 | zcwat = rcw - rcpd |
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| 99 | zcice = rcs - rcpd |
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| 100 | |
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| 101 | DO i = 1, klon |
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| 102 | stops = stops + tops(i)*airephy(i) |
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| 103 | stopl = stopl + topl(i)*airephy(i) |
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| 104 | ssols = ssols + sols(i)*airephy(i) |
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| 105 | ssoll = ssoll + soll(i)*airephy(i) |
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| 106 | ssens = ssens + sens(i)*airephy(i) |
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| 107 | sfront = sfront + (evap(i)*zcpvap-rain_fall(i)*zcwat-snow_fall(i)*zcice)* & |
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| 108 | ts(i)*airephy(i) |
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| 109 | evap_tot = evap_tot + evap(i)*airephy(i) |
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| 110 | rain_fall_tot = rain_fall_tot + rain_fall(i)*airephy(i) |
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| 111 | snow_fall_tot = snow_fall_tot + snow_fall(i)*airephy(i) |
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| 112 | airetot = airetot + airephy(i) |
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| 113 | END DO |
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| 114 | stops = stops/airetot |
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| 115 | stopl = stopl/airetot |
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| 116 | ssols = ssols/airetot |
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| 117 | ssoll = ssoll/airetot |
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| 118 | ssens = ssens/airetot |
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| 119 | sfront = sfront/airetot |
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| 120 | evap_tot = evap_tot/airetot |
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| 121 | rain_fall_tot = rain_fall_tot/airetot |
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| 122 | snow_fall_tot = snow_fall_tot/airetot |
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| 123 | |
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| 124 | slat = rlvtt*rain_fall_tot + rlstt*snow_fall_tot |
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| 125 | ! Heat flux at atm. boundaries |
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| 126 | fs_bound = stops - stopl - (ssols+ssoll) + ssens + sfront + slat |
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| 127 | ! Watter flux at atm. boundaries |
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| 128 | fq_bound = evap_tot - rain_fall_tot - snow_fall_tot |
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| 129 | |
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| 130 | IF (iprt>=1) WRITE (6, 6666) tit, pas, fs_bound, d_etp_tot, fq_bound, & |
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| 131 | d_qt_tot |
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| 132 | |
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| 133 | IF (iprt>=1) WRITE (6, 6668) tit, pas, d_etp_tot + d_ec_tot - fs_bound, & |
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| 134 | d_qt_tot - fq_bound |
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| 135 | |
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| 136 | IF (iprt>=2) WRITE (6, 6667) tit, pas, stops, stopl, ssols, ssoll, ssens, & |
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| 137 | slat, evap_tot, rain_fall_tot + snow_fall_tot |
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| 138 | |
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| 139 | RETURN |
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| 140 | |
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| 141 | 6666 FORMAT ('Phys. Flux Budget ', A15, 1I6, 2F8.2, 2(1PE13.5)) |
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| 142 | 6667 FORMAT ('Phys. Boundary Flux ', A15, 1I6, 6F8.2, 2(1PE13.5)) |
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| 143 | 6668 FORMAT ('Phys. Total Budget ', A15, 1I6, F8.2, 2(1PE13.5)) |
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| 144 | |
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| 145 | END SUBROUTINE diagphy |
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| 146 | |
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| 147 | ! ====================================================================== |
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| 148 | SUBROUTINE diagetpq(airephy, tit, iprt, idiag, idiag2, dtime, t, q, ql, qs, & |
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| 149 | u, v, paprs, pplay, d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) |
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| 150 | ! ====================================================================== |
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| 151 | |
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| 152 | ! Purpose: |
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| 153 | ! Calcul la difference d'enthalpie et de masse d'eau entre 2 appels, |
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| 154 | ! et calcul le flux de chaleur et le flux d'eau necessaire a ces |
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| 155 | ! changements. Ces valeurs sont moyennees sur la surface de tout |
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| 156 | ! le globe et sont exprime en W/2 et kg/s/m2 |
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| 157 | ! Outil pour diagnostiquer la conservation de l'energie |
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| 158 | ! et de la masse dans la physique. Suppose que les niveau de |
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| 159 | ! pression entre couche ne varie pas entre 2 appels. |
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| 160 | |
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| 161 | ! Plusieurs de ces diagnostics peuvent etre fait en parallele: les |
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| 162 | ! bilans sont sauvegardes dans des tableaux indices. On parlera |
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| 163 | ! "d'indice de diagnostic" |
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| 164 | |
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| 165 | |
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| 166 | ! ====================================================================== |
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| 167 | ! Arguments: |
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| 168 | ! airephy-------input-R- grid area |
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| 169 | ! tit-----imput-A15- Comment added in PRINT (CHARACTER*15) |
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| 170 | ! iprt----input-I- PRINT level ( <=1 : no PRINT) |
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| 171 | ! idiag---input-I- indice dans lequel sera range les nouveaux |
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| 172 | ! bilans d' entalpie et de masse |
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| 173 | ! idiag2--input-I-les nouveaux bilans d'entalpie et de masse |
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| 174 | ! sont compare au bilan de d'enthalpie de masse de |
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| 175 | ! l'indice numero idiag2 |
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| 176 | ! Cas parriculier : si idiag2=0, pas de comparaison, on |
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| 177 | ! sort directement les bilans d'enthalpie et de masse |
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| 178 | ! dtime----input-R- time step (s) |
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| 179 | ! t--------input-R- temperature (K) |
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| 180 | ! q--------input-R- vapeur d'eau (kg/kg) |
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| 181 | ! ql-------input-R- liquid watter (kg/kg) |
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| 182 | ! qs-------input-R- solid watter (kg/kg) |
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| 183 | ! u--------input-R- vitesse u |
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| 184 | ! v--------input-R- vitesse v |
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| 185 | ! paprs----input-R- pression a intercouche (Pa) |
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| 186 | ! pplay----input-R- pression au milieu de couche (Pa) |
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| 187 | |
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| 188 | ! the following total value are computed by UNIT of earth surface |
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| 189 | |
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| 190 | ! d_h_vcol--output-R- Heat flux (W/m2) define as the Enthalpy |
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| 191 | ! change (J/m2) during one time step (dtime) for the whole |
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| 192 | ! atmosphere (air, watter vapour, liquid and solid) |
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| 193 | ! d_qt------output-R- total water mass flux (kg/m2/s) defined as the |
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| 194 | ! total watter (kg/m2) change during one time step (dtime), |
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| 195 | ! d_qw------output-R- same, for the watter vapour only (kg/m2/s) |
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| 196 | ! d_ql------output-R- same, for the liquid watter only (kg/m2/s) |
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| 197 | ! d_qs------output-R- same, for the solid watter only (kg/m2/s) |
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| 198 | ! d_ec------output-R- Cinetic Energy Budget (W/m2) for vertical air column |
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| 199 | |
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| 200 | ! other (COMMON...) |
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| 201 | ! RCPD, RCPV, .... |
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| 202 | |
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| 203 | ! J.L. Dufresne, July 2002 |
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| 204 | ! ====================================================================== |
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| 205 | |
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| 206 | USE dimphy |
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| 207 | IMPLICIT NONE |
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| 208 | |
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| 209 | include "YOMCST.h" |
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| 210 | include "YOETHF.h" |
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| 211 | |
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| 212 | ! Input variables |
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| 213 | REAL airephy(klon) |
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| 214 | CHARACTER *15 tit |
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| 215 | INTEGER iprt, idiag, idiag2 |
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| 216 | REAL dtime |
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| 217 | REAL t(klon, klev), q(klon, klev), ql(klon, klev), qs(klon, klev) |
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| 218 | REAL u(klon, klev), v(klon, klev) |
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| 219 | REAL paprs(klon, klev+1), pplay(klon, klev) |
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| 220 | ! Output variables |
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| 221 | REAL d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec |
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| 222 | |
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| 223 | ! Local variables |
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| 224 | |
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| 225 | REAL h_vcol_tot, h_dair_tot, h_qw_tot, h_ql_tot, h_qs_tot, qw_tot, ql_tot, & |
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| 226 | qs_tot, ec_tot |
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| 227 | ! h_vcol_tot-- total enthalpy of vertical air column |
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| 228 | ! (air with watter vapour, liquid and solid) (J/m2) |
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| 229 | ! h_dair_tot-- total enthalpy of dry air (J/m2) |
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| 230 | ! h_qw_tot---- total enthalpy of watter vapour (J/m2) |
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| 231 | ! h_ql_tot---- total enthalpy of liquid watter (J/m2) |
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| 232 | ! h_qs_tot---- total enthalpy of solid watter (J/m2) |
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| 233 | ! qw_tot------ total mass of watter vapour (kg/m2) |
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| 234 | ! ql_tot------ total mass of liquid watter (kg/m2) |
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| 235 | ! qs_tot------ total mass of solid watter (kg/m2) |
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| 236 | ! ec_tot------ total cinetic energy (kg/m2) |
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| 237 | |
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| 238 | REAL zairm(klon, klev) ! layer air mass (kg/m2) |
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| 239 | REAL zqw_col(klon) |
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| 240 | REAL zql_col(klon) |
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| 241 | REAL zqs_col(klon) |
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| 242 | REAL zec_col(klon) |
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| 243 | REAL zh_dair_col(klon) |
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| 244 | REAL zh_qw_col(klon), zh_ql_col(klon), zh_qs_col(klon) |
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| 245 | |
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| 246 | REAL d_h_dair, d_h_qw, d_h_ql, d_h_qs |
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| 247 | |
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| 248 | REAL airetot, zcpvap, zcwat, zcice |
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| 249 | |
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| 250 | INTEGER i, k |
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| 251 | |
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| 252 | INTEGER ndiag ! max number of diagnostic in parallel |
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| 253 | PARAMETER (ndiag=10) |
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| 254 | INTEGER pas(ndiag) |
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| 255 | SAVE pas |
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| 256 | DATA pas/ndiag*0/ |
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| 257 | !$OMP THREADPRIVATE(pas) |
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| 258 | |
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| 259 | REAL h_vcol_pre(ndiag), h_dair_pre(ndiag), h_qw_pre(ndiag), & |
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| 260 | h_ql_pre(ndiag), h_qs_pre(ndiag), qw_pre(ndiag), ql_pre(ndiag), & |
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| 261 | qs_pre(ndiag), ec_pre(ndiag) |
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| 262 | SAVE h_vcol_pre, h_dair_pre, h_qw_pre, h_ql_pre, h_qs_pre, qw_pre, ql_pre, & |
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| 263 | qs_pre, ec_pre |
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| 264 | !$OMP THREADPRIVATE(h_vcol_pre, h_dair_pre, h_qw_pre, h_ql_pre) |
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| 265 | !$OMP THREADPRIVATE(h_qs_pre, qw_pre, ql_pre, qs_pre , ec_pre) |
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| 266 | ! ====================================================================== |
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| 267 | |
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| 268 | DO k = 1, klev |
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| 269 | DO i = 1, klon |
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| 270 | ! layer air mass |
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| 271 | zairm(i, k) = (paprs(i,k)-paprs(i,k+1))/rg |
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| 272 | END DO |
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| 273 | END DO |
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| 274 | |
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| 275 | ! Reset variables |
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| 276 | DO i = 1, klon |
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| 277 | zqw_col(i) = 0. |
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| 278 | zql_col(i) = 0. |
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| 279 | zqs_col(i) = 0. |
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| 280 | zec_col(i) = 0. |
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| 281 | zh_dair_col(i) = 0. |
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| 282 | zh_qw_col(i) = 0. |
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| 283 | zh_ql_col(i) = 0. |
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| 284 | zh_qs_col(i) = 0. |
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| 285 | END DO |
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| 286 | |
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| 287 | zcpvap = rcpv |
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| 288 | zcwat = rcw |
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| 289 | zcice = rcs |
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| 290 | |
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| 291 | ! Compute vertical sum for each atmospheric column |
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| 292 | ! ================================================ |
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| 293 | DO k = 1, klev |
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| 294 | DO i = 1, klon |
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| 295 | ! Watter mass |
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| 296 | zqw_col(i) = zqw_col(i) + q(i, k)*zairm(i, k) |
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| 297 | zql_col(i) = zql_col(i) + ql(i, k)*zairm(i, k) |
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| 298 | zqs_col(i) = zqs_col(i) + qs(i, k)*zairm(i, k) |
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| 299 | ! Cinetic Energy |
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| 300 | zec_col(i) = zec_col(i) + 0.5*(u(i,k)**2+v(i,k)**2)*zairm(i, k) |
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| 301 | ! Air enthalpy |
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| 302 | zh_dair_col(i) = zh_dair_col(i) + rcpd*(1.-q(i,k)-ql(i,k)-qs(i,k))* & |
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| 303 | zairm(i, k)*t(i, k) |
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| 304 | zh_qw_col(i) = zh_qw_col(i) + zcpvap*q(i, k)*zairm(i, k)*t(i, k) |
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| 305 | zh_ql_col(i) = zh_ql_col(i) + zcwat*ql(i, k)*zairm(i, k)*t(i, k) - & |
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| 306 | rlvtt*ql(i, k)*zairm(i, k) |
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| 307 | zh_qs_col(i) = zh_qs_col(i) + zcice*qs(i, k)*zairm(i, k)*t(i, k) - & |
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| 308 | rlstt*qs(i, k)*zairm(i, k) |
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| 309 | |
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| 310 | END DO |
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| 311 | END DO |
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| 312 | |
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| 313 | ! Mean over the planete surface |
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| 314 | ! ============================= |
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| 315 | qw_tot = 0. |
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| 316 | ql_tot = 0. |
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| 317 | qs_tot = 0. |
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| 318 | ec_tot = 0. |
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| 319 | h_vcol_tot = 0. |
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| 320 | h_dair_tot = 0. |
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| 321 | h_qw_tot = 0. |
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| 322 | h_ql_tot = 0. |
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| 323 | h_qs_tot = 0. |
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| 324 | airetot = 0. |
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| 325 | |
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| 326 | DO i = 1, klon |
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| 327 | qw_tot = qw_tot + zqw_col(i)*airephy(i) |
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| 328 | ql_tot = ql_tot + zql_col(i)*airephy(i) |
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| 329 | qs_tot = qs_tot + zqs_col(i)*airephy(i) |
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| 330 | ec_tot = ec_tot + zec_col(i)*airephy(i) |
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| 331 | h_dair_tot = h_dair_tot + zh_dair_col(i)*airephy(i) |
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| 332 | h_qw_tot = h_qw_tot + zh_qw_col(i)*airephy(i) |
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| 333 | h_ql_tot = h_ql_tot + zh_ql_col(i)*airephy(i) |
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| 334 | h_qs_tot = h_qs_tot + zh_qs_col(i)*airephy(i) |
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| 335 | airetot = airetot + airephy(i) |
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| 336 | END DO |
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| 337 | |
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| 338 | qw_tot = qw_tot/airetot |
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| 339 | ql_tot = ql_tot/airetot |
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| 340 | qs_tot = qs_tot/airetot |
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| 341 | ec_tot = ec_tot/airetot |
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| 342 | h_dair_tot = h_dair_tot/airetot |
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| 343 | h_qw_tot = h_qw_tot/airetot |
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| 344 | h_ql_tot = h_ql_tot/airetot |
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| 345 | h_qs_tot = h_qs_tot/airetot |
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| 346 | |
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| 347 | h_vcol_tot = h_dair_tot + h_qw_tot + h_ql_tot + h_qs_tot |
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| 348 | |
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| 349 | ! Compute the change of the atmospheric state compare to the one |
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| 350 | ! stored in "idiag2", and convert it in flux. THis computation |
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| 351 | ! is performed IF idiag2 /= 0 and IF it is not the first CALL |
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| 352 | ! for "idiag" |
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| 353 | ! =================================== |
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| 354 | |
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| 355 | IF ((idiag2>0) .AND. (pas(idiag2)/=0)) THEN |
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| 356 | d_h_vcol = (h_vcol_tot-h_vcol_pre(idiag2))/dtime |
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| 357 | d_h_dair = (h_dair_tot-h_dair_pre(idiag2))/dtime |
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| 358 | d_h_qw = (h_qw_tot-h_qw_pre(idiag2))/dtime |
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| 359 | d_h_ql = (h_ql_tot-h_ql_pre(idiag2))/dtime |
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| 360 | d_h_qs = (h_qs_tot-h_qs_pre(idiag2))/dtime |
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| 361 | d_qw = (qw_tot-qw_pre(idiag2))/dtime |
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| 362 | d_ql = (ql_tot-ql_pre(idiag2))/dtime |
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| 363 | d_qs = (qs_tot-qs_pre(idiag2))/dtime |
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| 364 | d_ec = (ec_tot-ec_pre(idiag2))/dtime |
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| 365 | d_qt = d_qw + d_ql + d_qs |
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| 366 | ELSE |
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| 367 | d_h_vcol = 0. |
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| 368 | d_h_dair = 0. |
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| 369 | d_h_qw = 0. |
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| 370 | d_h_ql = 0. |
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| 371 | d_h_qs = 0. |
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| 372 | d_qw = 0. |
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| 373 | d_ql = 0. |
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| 374 | d_qs = 0. |
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| 375 | d_ec = 0. |
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| 376 | d_qt = 0. |
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| 377 | END IF |
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| 378 | |
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| 379 | IF (iprt>=2) THEN |
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| 380 | WRITE (6, 9000) tit, pas(idiag), d_qt, d_qw, d_ql, d_qs |
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| 381 | 9000 FORMAT ('Phys. Watter Mass Budget (kg/m2/s)', A15, 1I6, 10(1PE14.6)) |
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| 382 | WRITE (6, 9001) tit, pas(idiag), d_h_vcol |
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| 383 | 9001 FORMAT ('Phys. Enthalpy Budget (W/m2) ', A15, 1I6, 10(F8.2)) |
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| 384 | WRITE (6, 9002) tit, pas(idiag), d_ec |
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| 385 | 9002 FORMAT ('Phys. Cinetic Energy Budget (W/m2) ', A15, 1I6, 10(F8.2)) |
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| 386 | END IF |
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| 387 | |
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| 388 | ! Store the new atmospheric state in "idiag" |
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| 389 | |
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| 390 | pas(idiag) = pas(idiag) + 1 |
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| 391 | h_vcol_pre(idiag) = h_vcol_tot |
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| 392 | h_dair_pre(idiag) = h_dair_tot |
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| 393 | h_qw_pre(idiag) = h_qw_tot |
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| 394 | h_ql_pre(idiag) = h_ql_tot |
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| 395 | h_qs_pre(idiag) = h_qs_tot |
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| 396 | qw_pre(idiag) = qw_tot |
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| 397 | ql_pre(idiag) = ql_tot |
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| 398 | qs_pre(idiag) = qs_tot |
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| 399 | ec_pre(idiag) = ec_tot |
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| 400 | |
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[5105] | 401 | |
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[1992] | 402 | END SUBROUTINE diagetpq |
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