source: trunk/LMDZ.VENUS/libf/phyvenus/sw_venus_ve.F @ 3094

Last change on this file since 3094 was 1621, checked in by emillour, 8 years ago

Further work on full dynamics/physics separation.

LMDZ.COMMON:

  • added phy_common/vertical_layers_mod.F90 to store information on vertical grid. This is where routines in the physics should get the information.
  • The contents of vertical_layers_mod intialized via dynphy_lonlat/inigeomphy_mod.F90.

LMDZ.MARS:

  • physics now completely decoupled from dynamics; the physics package may now be compiled as a library (-libphy option of makelmdz_fcm).
  • created an "ini_tracer_mod" routine in module "tracer_mod" for a cleaner initialization of the later.
  • removed some purely dynamics-related outputs (etot0, zoom parameters, etc.) from diagfi.nc and stats.nc outputs as these informations are not available in the physics.

LMDZ.GENERIC:

  • physics now completely decoupled from dynamics; the physics package may now be compiled as a library (-libphy option of makelmdz_fcm).
  • added nqtot to tracer_h.F90.
  • removed some purely dynamics-related outputs (etot0, zoom parameters, etc.) from diagfi.nc and stats.nc outputs as these informations are not available in the physics.

LMDZ.VENUS:

  • physics now completely decoupled from dynamics; the physics package may now be compiled as a library (-libphy option of makelmdz_fcm).
  • added infotrac_phy.F90 to store information on tracers in the physics. Initialized via iniphysiq.
  • added cpdet_phy_mod.F90 to store t2tpot etc. functions to be used in the physics. Initialized via iniphysiq. IMPORTANT: there are some hard-coded constants! These should match what is in cpdet_mod.F90 in the dynamics.
  • got rid of references to moyzon_mod module within the physics. The required variables (tmoy, plevmoy) are passed to the physics as arguments to physiq.

LMDZ.TITAN:

  • added infotrac_phy.F90 to store information on tracers in the physics. Initialized via iniphysiq.
  • added cpdet_phy_mod.F90 to store t2tpot etc. functions to be used in the physics.
  • Extra work required to completely decouple physics and dynamics: moyzon_mod should be cleaned up and information passed from dynamics to physics as as arguments. Likewise moyzon_ch and moyzon_mu should not be queried from logic_mod (which is in the dynamics).

EM

File size: 5.5 KB
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1      SUBROUTINE SW_venus_ve( PRMU0, PFRAC,
2     S              PPB, pt, pz,
3     S              PHEAT,
4     S              PTOPSW,PSOLSW,ZFSNET)
5     
6      use dimphy
7      use cpdet_phy_mod, only: cpdet
8      IMPLICIT none
9
10#include "YOMCST.h"
11C
12C     ------------------------------------------------------------------
13C
14C     PURPOSE.
15C     --------
16C
17c      this routine loads and interpolates the shortwave radiation
18c     fluxes and heating rates computed from Vincent Eymet 3D MC code
19C
20C     AUTHOR.
21C     -------
22C        Sebastien Lebonnois
23C
24C     MODIFICATIONS.
25C     --------------
26C        ORIGINAL : 06/2014
27C     ------------------------------------------------------------------
28C
29C* ARGUMENTS:
30C
31c inputs
32
33      REAL   PRMU0  ! COSINE OF ZENITHAL ANGLE
34      REAL   PFRAC  ! fraction de la journee
35      REAL   PPB(klev+1)  ! inter-couches PRESSURE (bar)
36      REAL   pt(klev)     ! mid-layer temperature
37      REAL   pz(klev+1)   ! inter-couches altitude (m)
38C
39c output
40
41      REAL   PHEAT(klev) ! SHORTWAVE HEATING (K/VENUSDAY) within each layer
42      REAL   PTOPSW       ! SHORTWAVE FLUX AT T.O.A. (net)
43      REAL   PSOLSW       ! SHORTWAVE FLUX AT SURFACE (net)
44      REAL   ZFSNET(klev+1) ! net solar flux at ppb levels
45
46C
47C* LOCAL VARIABLES:
48C
49      integer nlve,nszave
50      parameter (nlve=78)   ! fichiers planet_EMC
51      parameter (nszave=20) ! fichiers planet_EMC
52     
53      integer i,j,nsza,nsza0,nl0
54      real   solarrate               ! solar heating rate (K/earthday)
55      real   zsnet(nlve,nszave)      ! net solar flux (W/m**2) (+ vers bas)
56      real   zheat(nlve-1,nszave)    ! rad budget (W/m**2)
57      real   zsdn,zsup               ! downward/upward solar flux (W/m**2)
58      real   solza(nszave)           ! solar zenith angles in table (rad)
59      real   altve(nlve)             ! altitude in table (m)
60      real   zsolnet(nlve)           ! for testing mean net solar flux
61      character*22 nullchar
62      real   sza0,factsza,factflux,alt
63      logical firstcall
64      data    firstcall/.true./
65      save   solza,zsnet,altve,zheat
66      save   firstcall
67     
68c ------------------------
69c Loading the files
70c ------------------------
71
72      if (firstcall) then
73
74! FLUXES (W/m2)
75
76       open(11,file='solar_fluxes_GCM.dat')
77       read(11,*) nullchar
78       read(11,*) nullchar
79       read(11,*) nullchar
80       read(11,*) nullchar
81     
82       do nsza=1,nszave
83        read(11,*) nullchar
84        read(11,*) solza(nsza)
85        read(11,*) nullchar
86        read(11,*) nullchar
87        do j=1,nlve
88           read(11,'(4(2x,F12.5))')
89     .          altve(j),zsdn,zsup,zsnet(j,nsza)
90        enddo
91       enddo
92
93       close(11)
94
95! HEATING RATES (W/m2)
96
97       open(12,file='solar_budgets_GCM.dat')
98       read(12,*) nullchar
99       read(12,*) nullchar
100       read(12,*) nullchar
101       read(12,*) nullchar
102     
103       do nsza=1,nszave
104        read(12,*) nullchar
105        read(12,*) solza(nsza)
106        read(12,*) nullchar
107        read(12,*) nullchar
108        do j=1,nlve-1
109           read(12,'(2(2x,F12.5))')
110     .          alt,zheat(j,nsza)
111        enddo
112       enddo
113
114       close(12)
115
116       firstcall=.false.
117      endif
118
119c --------------------------------------
120c Interpolation in the GCM vertical grid
121c --------------------------------------
122
123c Zenith angle
124c ------------
125     
126      sza0 = acos(PRMU0)  ! in radians
127c        print*,'Angle Zenithal =',sza0,' PFRAC=',PFRAC
128
129      nsza0=1
130      do nsza=1,nszave
131         if (solza(nsza).le.sza0) then
132              nsza0 = nsza+1
133         endif
134      enddo
135     
136      if ((nsza0.ne.1).and.(nsza0.ne.nszave+1)) then
137          factsza = (sza0-solza(nsza0-1))/(solza(nsza0)-solza(nsza0-1))
138      endif
139
140c Pressure levels
141c ---------------
142
143      do j=1,klev+1
144        nl0 = 2
145        do i=1,nlve-1
146           if (altve(i).le.pz(j)) then
147                nl0 = i+1
148           endif
149        enddo
150       
151        factflux = (min(pz(j),altve(nlve))
152     .                          -altve(nl0-1))
153     .            /(altve(nl0)-altve(nl0-1))
154
155! FLUXES
156
157        ZFSNET(j) = 0.
158        if ((nsza0.ne.1).and.(nsza0.ne.nszave+1)) then
159          ZFSNET(j) =  factflux   *  factsza   *zsnet(nl0,nsza0)
160     .             +   factflux   *(1.-factsza)*zsnet(nl0,nsza0-1)
161     .             + (1.-factflux)*  factsza   *zsnet(nl0-1,nsza0)
162     .             + (1.-factflux)*(1.-factsza)*zsnet(nl0-1,nsza0-1)
163        else if (nsza0.eq.1) then
164          ZFSNET(j) =  factflux   *zsnet(nl0,1)
165     .             + (1.-factflux)*zsnet(nl0-1,1)
166        endif
167        ZFSNET(j) = ZFSNET(j)*PFRAC
168
169! HEATING RATES
170
171        if (j.ne.klev+1) then
172          PHEAT(j) = 0.
173
174          if ((nsza0.ne.1).and.(nsza0.ne.nszave+1)) then
175            PHEAT(j) =  factflux   *  factsza   *zheat(nl0,nsza0)
176     .             +   factflux   *(1.-factsza)*zheat(nl0,nsza0-1)
177     .             + (1.-factflux)*  factsza   *zheat(nl0-1,nsza0)
178     .             + (1.-factflux)*(1.-factsza)*zheat(nl0-1,nsza0-1)
179          else if (nsza0.eq.1) then
180            PHEAT(j) =  factflux   *zheat(nl0,1)
181     .              + (1.-factflux)*zheat(nl0-1,1)
182          endif
183          PHEAT(j) = PHEAT(j)*PFRAC
184        endif
185
186      enddo
187
188      PTOPSW = ZFSNET(klev+1)
189      PSOLSW = ZFSNET(1)
190     
191c Heating rates
192c -------------
193c Conversion from W/m2 to K/s:
194c   heat(K/s) = d(fluxnet)  (W/m2)
195c              *g           (m/s2)
196c              /(-dp)  (epaisseur couche, en Pa=kg/m/s2)
197c              /cp  (J/kg/K)
198
199      do j=1,klev
200! ADAPTATION GCM POUR CP(T)
201        PHEAT(j) = PHEAT(j)
202     .            *RG/cpdet(pt(j)) / ((PPB(j)-PPB(j+1))*1.e5)
203      enddo
204
205      return
206      end
207
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