pkg/gridalt/dyn2phys.F

      subroutine dyn2phys(qdyn,pedyn,im1,im2,jm1,jm2,lmdyn,Nsx,Nsy,
     . idim1,idim2,jdim1,jdim2,bi,bj,windphy,pephy,Lbot,lmphy,nlperdyn,
     . flg,qphy)
C***********************************************************************
C Purpose:
C   To interpolate an arbitrary quantity from the 'dynamics' eta (pstar)
C               grid to the higher resolution physics grid 
C Algorithm:
C   Routine works one layer (edge to edge pressure) at a time.
C   Dynamics -> Physics retains the dynamics layer mean value,
C   weights the field either with the profile of the physics grid 
C   wind speed (for U and V fields), or uniformly (T and Q)
C
C Input:
C   qdyn..... [im,jm,lmdyn] Arbitrary Quantity on Input Grid
C   pedyn.... [im,jm,lmdyn+1] Pressures at bottom edges of input levels
C   im1,2 ... Limits for Longitude Dimension of Input
C   jm1,2 ... Limits for Latitude  Dimension of Input
C   lmdyn.... Vertical  Dimension of Input
C   Nsx...... Number of processes in x-direction
C   Nsy...... Number of processes in y-direction
C   idim1,2.. Beginning and ending i-values to calculate
C   jdim1,2.. Beginning and ending j-values to calculate
C   bi....... Index of process number in x-direction
C   bj....... Index of process number in x-direction
C   windphy.. [im,jm,lmphy] Magnitude of the wind on the output levels
C   pephy.... [im,jm,lmphy+1] Pressures at bottom edges of output levels
C   lmphy.... Vertical  Dimension of Output
C   nlperdyn. [im,jm,lmdyn] Highest Physics level in each dynamics level
C   flg...... Flag to indicate field type (0 for T or Q, 1 for U or V)
C
C Output:
C   qphy..... [im,jm,lmphy] Quantity at output grid (physics grid)
C
C Notes:
C   1) This algorithm assumes that the output (physics) grid levels
C      fit exactly into the input (dynamics) grid levels
C***********************************************************************
      implicit none
#include "CPP_OPTIONS.h"

      integer  im1, im2, jm1, jm2, lmdyn, lmphy, Nsx, Nsy, flg
      integer idim1, idim2, jdim1, jdim2, bi, bj
      _RL qdyn(im1:im2,jm1:jm2,lmdyn,Nsx,Nsy)
      _RL pedyn(im1:im2,jm1:jm2,lmdyn+1,Nsx,Nsy)
      _RL pephy(im1:im2,jm1:jm2,lmphy+1,Nsx,Nsy)
      _RL windphy(im1:im2,jm1:jm2,lmphy,Nsx,Nsy)
      integer nlperdyn(im1:im2,jm1:jm2,lmdyn,Nsx,Nsy)
      _RL qphy(im1:im2,jm1:jm2,lmphy,Nsx,Nsy)
      integer Lbot(im1:im2,jm1:jm2,Nsx,Nsy)

      _RL weights(im1:im2,jm1:jm2,lmphy)
      _RL dpkedyn, dpkephy, windsum
      integer  i,j,L,Lout1,Lout2,Lphy
      _RL getcon, kappa

      kappa = getcon('KAPPA')

c do loop for all grid points
      do j = jdim1,jdim2
       do i = idim1,idim2
c do loop for all dynamics (input) levels
        do L = 1,lmdyn
c Check to make sure we are above ground - if not, do nothing
         if(L.ge.Lbot(i,j,bi,bj))then
          if(L.eq.Lbot(i,j,bi,bj)) then
           Lout1 = 0
          else
           Lout1 = nlperdyn(i,j,L-1,bi,bj)
          endif
          Lout2 = nlperdyn(i,j,L,bi,bj)
c for U and V fields, need to compute for the weights:
          if(flg.eq.1)then
cinterp1   dpkedyn = (pedyn(i,j,L,bi,bj)**kappa)-
cinterp1                                   (pedyn(i,j,L+1,bi,bj)**kappa)
           dpkedyn = pedyn(i,j,L,bi,bj)-pedyn(i,j,L+1,bi,bj)
           windsum = 0.
           do Lphy = Lout1+1,Lout2
cinterp1    dpkephy = (pephy(i,j,Lphy,bi,bj)**kappa)-
cinterp1                                (pephy(i,j,Lphy+1,bi,bj)**kappa)
            dpkephy = pephy(i,j,Lphy,bi,bj)-pephy(i,j,Lphy+1,bi,bj)
            windsum = windsum+(windphy(i,j,Lphy,bi,bj)*dpkephy)/dpkedyn
           enddo
          endif
c do loop for all physics levels contained in this dynamics level
          do Lphy = Lout1+1,Lout2
           weights(i,j,Lphy) = 1.
           if( (flg.eq.1).and.(windsum.ne.0.) )
     .                weights(i,j,Lphy)=windphy(i,j,Lphy,bi,bj)/windsum
           qphy(i,j,Lphy,bi,bj) = qdyn(i,j,L,bi,bj) * weights(i,j,Lphy)
          enddo
         endif
        enddo
       enddo
      enddo

      return
      end
1	molod	1.1	subroutine dyn2phys(qdyn,pedyn,im1,im2,jm1,jm2,lmdyn,Nsx,Nsy,
2			. idim1,idim2,jdim1,jdim2,bi,bj,windphy,pephy,Lbot,lmphy,nlperdyn,
3			. flg,qphy)
4			C***********************************************************************
5			C Purpose:
6			C To interpolate an arbitrary quantity from the 'dynamics' eta (pstar)
7			C grid to the higher resolution physics grid
8			C Algorithm:
9			C Routine works one layer (edge to edge pressure) at a time.
10			C Dynamics -> Physics retains the dynamics layer mean value,
11			C weights the field either with the profile of the physics grid
12			C wind speed (for U and V fields), or uniformly (T and Q)
13			C
14			C Input:
15			C qdyn..... [im,jm,lmdyn] Arbitrary Quantity on Input Grid
16			C pedyn.... [im,jm,lmdyn+1] Pressures at bottom edges of input levels
17			C im1,2 ... Limits for Longitude Dimension of Input
18			C jm1,2 ... Limits for Latitude Dimension of Input
19			C lmdyn.... Vertical Dimension of Input
20			C Nsx...... Number of processes in x-direction
21			C Nsy...... Number of processes in y-direction
22			C idim1,2.. Beginning and ending i-values to calculate
23			C jdim1,2.. Beginning and ending j-values to calculate
24			C bi....... Index of process number in x-direction
25			C bj....... Index of process number in x-direction
26			C windphy.. [im,jm,lmphy] Magnitude of the wind on the output levels
27			C pephy.... [im,jm,lmphy+1] Pressures at bottom edges of output levels
28			C lmphy.... Vertical Dimension of Output
29			C nlperdyn. [im,jm,lmdyn] Highest Physics level in each dynamics level
30			C flg...... Flag to indicate field type (0 for T or Q, 1 for U or V)
31			C
32			C Output:
33			C qphy..... [im,jm,lmphy] Quantity at output grid (physics grid)
34			C
35			C Notes:
36			C 1) This algorithm assumes that the output (physics) grid levels
37			C fit exactly into the input (dynamics) grid levels
38			C***********************************************************************
39			implicit none
40			#include "CPP_OPTIONS.h"
41
42			integer im1, im2, jm1, jm2, lmdyn, lmphy, Nsx, Nsy, flg
43			integer idim1, idim2, jdim1, jdim2, bi, bj
44			_RL qdyn(im1:im2,jm1:jm2,lmdyn,Nsx,Nsy)
45			_RL pedyn(im1:im2,jm1:jm2,lmdyn+1,Nsx,Nsy)
46			_RL pephy(im1:im2,jm1:jm2,lmphy+1,Nsx,Nsy)
47			_RL windphy(im1:im2,jm1:jm2,lmphy,Nsx,Nsy)
48			integer nlperdyn(im1:im2,jm1:jm2,lmdyn,Nsx,Nsy)
49			_RL qphy(im1:im2,jm1:jm2,lmphy,Nsx,Nsy)
50			integer Lbot(im1:im2,jm1:jm2,Nsx,Nsy)
51
52			_RL weights(im1:im2,jm1:jm2,lmphy)
53			_RL dpkedyn, dpkephy, windsum
54			integer i,j,L,Lout1,Lout2,Lphy
55			_RL getcon, kappa
56
57			kappa = getcon('KAPPA')
58
59			c do loop for all grid points
60			do j = jdim1,jdim2
61			do i = idim1,idim2
62			c do loop for all dynamics (input) levels
63			do L = 1,lmdyn
64			c Check to make sure we are above ground - if not, do nothing
65			if(L.ge.Lbot(i,j,bi,bj))then
66			if(L.eq.Lbot(i,j,bi,bj)) then
67			Lout1 = 0
68			else
69			Lout1 = nlperdyn(i,j,L-1,bi,bj)
70			endif
71			Lout2 = nlperdyn(i,j,L,bi,bj)
72			c for U and V fields, need to compute for the weights:
73			if(flg.eq.1)then
74	molod	1.2	cinterp1 dpkedyn = (pedyn(i,j,L,bi,bj)**kappa)-
75			cinterp1 (pedyn(i,j,L+1,bi,bj)**kappa)
76			dpkedyn = pedyn(i,j,L,bi,bj)-pedyn(i,j,L+1,bi,bj)
77	molod	1.1	windsum = 0.
78			do Lphy = Lout1+1,Lout2
79	molod	1.2	cinterp1 dpkephy = (pephy(i,j,Lphy,bi,bj)**kappa)-
80			cinterp1 (pephy(i,j,Lphy+1,bi,bj)**kappa)
81			dpkephy = pephy(i,j,Lphy,bi,bj)-pephy(i,j,Lphy+1,bi,bj)
82	molod	1.1	windsum = windsum+(windphy(i,j,Lphy,bi,bj)*dpkephy)/dpkedyn
83			enddo
84			endif
85			c do loop for all physics levels contained in this dynamics level
86			do Lphy = Lout1+1,Lout2
87			weights(i,j,Lphy) = 1.
88			if( (flg.eq.1).and.(windsum.ne.0.) )
89			. weights(i,j,Lphy)=windphy(i,j,Lphy,bi,bj)/windsum
90			qphy(i,j,Lphy,bi,bj) = qdyn(i,j,L,bi,bj) * weights(i,j,Lphy)
91			enddo
92			endif
93			enddo
94			enddo
95			enddo
96
97			return
98			end