/[MITgcm]/MITgcm/pkg/gridalt/dyn2phys.F
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Revision 1.7 - (hide annotations) (download)
Sat Jul 7 00:08:08 2012 UTC (11 years, 10 months ago) by jmc
Branch: MAIN
CVS Tags: checkpoint64y, checkpoint64x, checkpoint64z, checkpoint64q, checkpoint64p, checkpoint64s, checkpoint64r, checkpoint64u, checkpoint64t, checkpoint64w, checkpoint64v, checkpoint64i, checkpoint64h, checkpoint64k, checkpoint64j, checkpoint64m, checkpoint64l, checkpoint64o, checkpoint64n, checkpoint64a, checkpoint64c, checkpoint64b, checkpoint64e, checkpoint64d, checkpoint64g, checkpoint64f, checkpoint63q, checkpoint63r, checkpoint63s, checkpoint64, checkpoint65, checkpoint66g, checkpoint66f, checkpoint66e, checkpoint66d, checkpoint66c, checkpoint66b, checkpoint66a, checkpoint66o, checkpoint66n, checkpoint66m, checkpoint66l, checkpoint66k, checkpoint66j, checkpoint66i, checkpoint66h, checkpoint65z, checkpoint65x, checkpoint65y, checkpoint65r, checkpoint65s, checkpoint65p, checkpoint65q, checkpoint65v, checkpoint65w, checkpoint65t, checkpoint65u, checkpoint65j, checkpoint65k, checkpoint65h, checkpoint65i, checkpoint65n, checkpoint65o, checkpoint65l, checkpoint65m, checkpoint65b, checkpoint65c, checkpoint65a, checkpoint65f, checkpoint65g, checkpoint65d, checkpoint65e, HEAD
Changes since 1.6: +8 -8 lines 
uses standard #indude ${PKG}_OPTIONS.h
1 jmc 1.7 C $Header: /u/gcmpack/MITgcm/pkg/gridalt/dyn2phys.F,v 1.6 2008/11/18 21:39:38 jmc Exp $
2 edhill 1.4 C $Name: $
3    
4 jmc 1.7 #include "GRIDALT_OPTIONS.h"
5    
6 molod 1.1 subroutine dyn2phys(qdyn,pedyn,im1,im2,jm1,jm2,lmdyn,Nsx,Nsy,
7     . idim1,idim2,jdim1,jdim2,bi,bj,windphy,pephy,Lbot,lmphy,nlperdyn,
8     . flg,qphy)
9     C***********************************************************************
10     C Purpose:
11     C To interpolate an arbitrary quantity from the 'dynamics' eta (pstar)
12 jmc 1.7 C grid to the higher resolution physics grid
13 molod 1.1 C Algorithm:
14     C Routine works one layer (edge to edge pressure) at a time.
15     C Dynamics -> Physics retains the dynamics layer mean value,
16 jmc 1.7 C weights the field either with the profile of the physics grid
17 molod 1.1 C wind speed (for U and V fields), or uniformly (T and Q)
18     C
19     C Input:
20     C qdyn..... [im,jm,lmdyn] Arbitrary Quantity on Input Grid
21     C pedyn.... [im,jm,lmdyn+1] Pressures at bottom edges of input levels
22     C im1,2 ... Limits for Longitude Dimension of Input
23     C jm1,2 ... Limits for Latitude Dimension of Input
24     C lmdyn.... Vertical Dimension of Input
25     C Nsx...... Number of processes in x-direction
26     C Nsy...... Number of processes in y-direction
27     C idim1,2.. Beginning and ending i-values to calculate
28     C jdim1,2.. Beginning and ending j-values to calculate
29     C bi....... Index of process number in x-direction
30     C bj....... Index of process number in x-direction
31     C windphy.. [im,jm,lmphy] Magnitude of the wind on the output levels
32     C pephy.... [im,jm,lmphy+1] Pressures at bottom edges of output levels
33     C lmphy.... Vertical Dimension of Output
34     C nlperdyn. [im,jm,lmdyn] Highest Physics level in each dynamics level
35     C flg...... Flag to indicate field type (0 for T or Q, 1 for U or V)
36     C
37     C Output:
38     C qphy..... [im,jm,lmphy] Quantity at output grid (physics grid)
39     C
40     C Notes:
41     C 1) This algorithm assumes that the output (physics) grid levels
42     C fit exactly into the input (dynamics) grid levels
43     C***********************************************************************
44     implicit none
45    
46     integer im1, im2, jm1, jm2, lmdyn, lmphy, Nsx, Nsy, flg
47     integer idim1, idim2, jdim1, jdim2, bi, bj
48     _RL qdyn(im1:im2,jm1:jm2,lmdyn,Nsx,Nsy)
49     _RL pedyn(im1:im2,jm1:jm2,lmdyn+1,Nsx,Nsy)
50     _RL pephy(im1:im2,jm1:jm2,lmphy+1,Nsx,Nsy)
51     _RL windphy(im1:im2,jm1:jm2,lmphy,Nsx,Nsy)
52     integer nlperdyn(im1:im2,jm1:jm2,lmdyn,Nsx,Nsy)
53     _RL qphy(im1:im2,jm1:jm2,lmphy,Nsx,Nsy)
54     integer Lbot(im1:im2,jm1:jm2,Nsx,Nsy)
55    
56     _RL weights(im1:im2,jm1:jm2,lmphy)
57 molod 1.5 _RL pphy(im1:im2,jm1:jm2,lmphy)
58 molod 1.3 _RL dpkedyn, dpkephy, windsum, qd
59 molod 1.1 integer i,j,L,Lout1,Lout2,Lphy
60 jmc 1.6 cinterp1 _RL kappa
61     #ifdef ALLOW_FIZHI
62     cinterp1 _RL getcon
63     #else
64     cinterp1 #include 'SIZE.h'
65     cinterp1 #include 'EEPARAMS.h'
66     cinterp1 #include 'PARAMS.h'
67     #endif
68    
69     #ifdef ALLOW_FIZHI
70     cinterp1 kappa = getcon('KAPPA')
71     #else
72     cinterp1 kappa = atm_kappa
73     #endif
74 molod 1.1
75 molod 1.5 C define physics grid mid level pressures
76     do Lphy = 1,lmphy
77     do j = jdim1,jdim2
78     do i = idim1,idim2
79 jmc 1.7 pphy(i,j,Lphy) =
80 molod 1.5 . (pephy(i,j,Lphy,bi,bj)+pephy(i,j,Lphy+1,bi,bj))/2.
81     enddo
82     enddo
83     enddo
84    
85 molod 1.3 c do loop for all dynamics (input) levels
86     do L = 1,lmdyn
87 molod 1.1 c do loop for all grid points
88 molod 1.3 do j = jdim1,jdim2
89     do i = idim1,idim2
90     qd = qdyn(i,j,L,bi,bj)
91 molod 1.1 c Check to make sure we are above ground - if not, do nothing
92     if(L.ge.Lbot(i,j,bi,bj))then
93     if(L.eq.Lbot(i,j,bi,bj)) then
94     Lout1 = 0
95     else
96     Lout1 = nlperdyn(i,j,L-1,bi,bj)
97     endif
98     Lout2 = nlperdyn(i,j,L,bi,bj)
99     c for U and V fields, need to compute for the weights:
100 molod 1.5 cinterp1 dpkedyn = (pedyn(i,j,L,bi,bj)**kappa)-
101     cinterp1 (pedyn(i,j,L+1,bi,bj)**kappa)
102     dpkedyn = pedyn(i,j,L,bi,bj)-pedyn(i,j,L+1,bi,bj)
103 molod 1.1 if(flg.eq.1)then
104     windsum = 0.
105     do Lphy = Lout1+1,Lout2
106 molod 1.2 cinterp1 dpkephy = (pephy(i,j,Lphy,bi,bj)**kappa)-
107     cinterp1 (pephy(i,j,Lphy+1,bi,bj)**kappa)
108     dpkephy = pephy(i,j,Lphy,bi,bj)-pephy(i,j,Lphy+1,bi,bj)
109 molod 1.1 windsum = windsum+(windphy(i,j,Lphy,bi,bj)*dpkephy)/dpkedyn
110     enddo
111     endif
112     c do loop for all physics levels contained in this dynamics level
113     do Lphy = Lout1+1,Lout2
114     weights(i,j,Lphy) = 1.
115     if( (flg.eq.1).and.(windsum.ne.0.) )
116     . weights(i,j,Lphy)=windphy(i,j,Lphy,bi,bj)/windsum
117 molod 1.5 if( (flg.eq.2) .and. (pedyn(i,j,L,bi,bj).lt.10000.)) then
118 jmc 1.7 weights(i,j,Lphy) =
119 molod 1.5 . (qd-5. + (10.*(pedyn(i,j,L,bi,bj)-pphy(i,j,Lphy))/dpkedyn))/qd
120     elseif( (flg.eq.2) .and. (pedyn(i,j,L,bi,bj).ge.10000.)) then
121     weights(i,j,Lphy) = 1.
122 jmc 1.7 endif
123 molod 1.3 qphy(i,j,Lphy,bi,bj) = qd * weights(i,j,Lphy)
124 molod 1.1 enddo
125     endif
126     enddo
127     enddo
128     enddo
129    
130     return
131     end
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