source: trunk/LMDZ.VENUS/libf/phyvenus/blendrad.F @ 2203

Last change on this file since 2203 was 1530, checked in by emillour, 9 years ago

Venus and Titan GCMs:
Updates in the physics to keep up with updates in LMDZ5 (up to
LMDZ5 trunk, rev 2350) concerning dynamics/physics separation:

  • Adapted makelmdz and makelmdz_fcm script to stop if trying to compile 1d model or newstart or start2archive in parallel.
  • got rid of references to "dimensions.h" in physics. Within physics packages, use nbp_lon (=iim), nbp_lat (=jjmp1) and nbp_lev (=llm) from module mod_grid_phy_lmdz (in phy_common) instead. Only partially done for Titan, because of many hard-coded commons; a necessary first step will be to clean these up (using modules).

EM

File size: 2.6 KB
Line 
1      subroutine blendrad(nlon, nlev, pplay, heat,
2     &                     cool, pdtnirco2,zdtnlte, dtsw,dtlw )
3c
4c  Combine radiative tendencies.  LTE contributions (heat and cool)
5c  have been calculated for the first NLAYLTE layers, zdtnirco2 and
6c  zdtnlte have been calculated for all nlev layers (but zdtnlte may
7c  be zero low down).  cool is phased out in favour of zdtnlte with
8c  height; heat is also phased out to remove possible spurious heating
9c  at low pressures.  The pressure at which the transition occurs and
10c  the scale over which this happens are set in the nlteparams.h file.
11c  Above layer NLAYLTE the tendency is purely the sum of NLTE contributions.
12c  (Note : nlaylte is calculated by "nlthermeq" and stored in common "yomlw.h")
13c  Stephen Lewis 6/2000 FF
14
15      use dimphy
16      implicit none
17c#include "dimradmars.h"
18#include "nlteparams.h"
19c#include "yomlw.h"
20#include "YOMCST.h"
21
22c     Input:
23      integer nlon, nlev
24      real pplay(nlon, nlev)
25      real cool(nlon, nlev)
26      real heat(nlon, nlev)
27      real pdtnirco2(nlon, nlev)
28      real zdtnlte(nlon, nlev)
29c
30c     Output:
31c      real dtrad(nlon, nlev)
32      real dtlw(nlon, nlev)
33      real dtsw(nlon, nlev)
34c
35c     Local:
36      integer l, ig
37      real alpha, alpha2
38      real, parameter :: p_lowup = 10.e2
39
40c
41c     This is split into two loops to minimize number of calculations,
42c     but for vector machines it may be faster to perform one big
43c     loop from 1 to nlev and remove the second loop.
44c
45
46c          print*, '--- NLAYTE value is: ---'
47c          print*, nlaylte
48
49c     Loop over layers for which heat/lw have been calculated.
50       do l = 1,nlaylte !defini dans nlthermeq
51         do ig = 1, nlon
52c           alpha is actually 0.5*(1+tanh((z-ztrans)/zw))
53c           written here in a simpler form, with z=-ln(p) and zwi=2/zw
54            alpha  = 1./(1.+(pplay(ig,l)/ptrans)**zwi)
55            alpha2 = 1./(1.+(pplay(ig,l)/p_lowup)**zwi)
56           
57c     This formula is used in the Martian routines
58c            dtrad(ig,l) = (1.-alpha)*(heat(ig,l)+cool(ig,l))
59c     &                  + pdtnirco2(ig,l) + alpha*zdtnlte(ig,l)
60
61            dtlw(ig,l) = (1.-alpha)*(-cool(ig,l))
62     &                  + alpha*zdtnlte(ig,l)
63            dtsw(ig,l) = (1-alpha2)*(heat(ig,l))
64     &                  +  alpha2*pdtnirco2(ig,l)
65
66         enddo
67      enddo
68
69c
70c     Faster loop over any remaining layers.
71      do l = nlaylte+1, nlev
72         do ig = 1, nlon
73
74c           dtrad(ig,l) = pdtnirco2(ig,l) + zdtnlte(ig,l)
75
76            dtlw(ig,l) = zdtnlte(ig,l)
77            dtsw(ig,l) = pdtnirco2(ig,l)
78         enddo
79      enddo
80
81      return
82      end
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