0,0 → 1,970 |
PROGRAM modify_anomaly |
|
c ****************************************************************************** |
c * Read the modified and unmodified PV from the R file and * |
c * perform some non-standard modifications: (a) Change of amplitude, * |
c * (b) Stretching and shrinking along an axis, (c) rotation, or * |
c * (d) change in position. |
c * |
c # modify_anomaly.sh R_20060116_18 shifty=-10,rot=10,stretchy=1.5,rot=-10,shifty=10 |
c # modify_anomaly.sh R_20060116_18 fac=2 |
c # modify_anomaly.sh R_20060116_18 cex=-30,cey=-30,rot=20 |
c * * |
c * Michael Sprenger / Spring, Summer 2007 * |
c ****************************************************************************** |
|
implicit none |
|
c ----------------------------------------------------------------------------- |
c Declaration of parameters and variables |
c ----------------------------------------------------------------------------- |
|
c Input/output file and command string |
character*80 pvsrcfile |
character*80 commandstr |
|
c Grid parameters |
integer nx,ny,nz |
real xmin,ymin,zmin,xmax,ymax,zmax |
real dx,dy,dz |
real mdv |
|
c 3d fields for calculation of qgPV and Ertel's PV |
real,allocatable,dimension (:,:,:) :: pv1,pv2,ano |
|
c Numerical epsilon |
real eps |
parameter (eps=0.01) |
|
c Parameters for the transformations |
real cex,cey ! Centre point for rotation |
real angle ! Rotation angle |
|
c Auxiliary variables |
real zpos |
integer i,j,k |
integer stat |
character*80 varname |
integer n |
real par |
character*80 com |
|
c ----------------------------------------------------------------------------- |
c Preparations |
c ----------------------------------------------------------------------------- |
|
print*,'********************************************************' |
print*,'* MODIFY_ANOMALY *' |
print*,'********************************************************' |
|
c Read parameter file |
open(10,file='fort.10') |
read(10,*) pvsrcfile |
read(10,*) commandstr |
close(10) |
print* |
print*,'Input file : ',trim(pvsrcfile) |
print*,'Command : ',trim(commandstr) |
print* |
|
c Get lat/lon gid parameters from input file |
call read_dim (nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,mdv, |
> pvsrcfile) |
print*,'Read_Dim: nx,ny,nz = ',nx,ny,nz |
print*,' dx,dy,dz = ',dx,dy,dz |
print*,' xmin,ymin,zmin = ',xmin,ymin,zmin |
print*,' mdv = ',mdv |
print* |
|
c Count from 0, not from 1: consistent with <inv_cart.f>. |
nx=nx-1 |
ny=ny-1 |
nz=nz-1 |
|
c Allocate memory for modified and non-modified PV |
allocate(pv1 (0:nx,0:ny,0:nz),STAT=stat) |
if (stat.ne.0) print*,'error allocating pv1' |
allocate(pv2 (0:nx,0:ny,0:nz),STAT=stat) |
if (stat.ne.0) print*,'error allocating pv2' |
allocate(ano (0:nx,0:ny,0:nz),STAT=stat) |
if (stat.ne.0) print*,'error allocating ano' |
|
c Read data from file |
varname='PV' |
call read_inp (pv1,varname,pvsrcfile, |
> nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,mdv) |
varname='PV_FILT' |
call read_inp (pv2,varname,pvsrcfile, |
> nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,mdv) |
|
c Define the anomaly |
do i=0,nx |
do j=0,ny |
do k=0,nz |
if ( (abs(pv1(i,j,k)-mdv).gt.eps).and. |
> (abs(pv2(i,j,k)-mdv).gt.eps) ) then |
ano(i,j,k)=pv1(i,j,k)-pv2(i,j,k) |
else |
ano(i,j,k)=0. |
endif |
enddo |
enddo |
enddo |
|
|
c ------------------------------------------------------------------------------- |
c Modifications |
c ------------------------------------------------------------------------------- |
|
c Set the default values for parameters |
cex = 0. |
cey = 0. |
angle = 0. |
|
c Set the counter for the command string |
n=1 |
|
c Loop over all commands |
100 continue |
|
c Extract new command/parameter pair; exit if no new command |
call next_command(commandstr,n,com,par) |
if (com.eq.'nil') goto 200 |
print*,trim(com),par |
|
c Multiply the anomaly by a constant factor |
if (com.eq.'fac') then |
call mod_factor (ano,par,nx,ny,nz,mdv) |
endif |
|
c Set the centre point (needed for rotations) |
if (com.eq.'cex') then |
cex=par |
endif |
if (com.eq.'cey') then |
cey=par |
endif |
|
c Rotation around the centrre point |
if (com.eq.'rot') then |
call mod_rotation (ano,par,cex,cey, |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
endif |
|
c Shift in x or in y direction |
if (com.eq.'shiftx') then |
call mod_shift (ano,par,0., |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
endif |
if (com.eq.'shifty') then |
call mod_shift (ano,0.,par, |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
endif |
|
c Stretch/shrink in x or in y direction |
if (com.eq.'stretchx') then |
call mod_stretch (ano,par,1., |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
endif |
if (com.eq.'stretchy') then |
call mod_stretch (ano,1.,par, |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
endif |
|
|
c Goto next command/parameter pair |
goto 100 |
|
c All commands handled |
200 continue |
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c -------------------------------------------------------------------------------- |
c Write modified fields |
c -------------------------------------------------------------------------------- |
|
c Build the modified PV distribution from the anomaly |
do i=0,nx |
do j=0,ny |
do k=0,nz |
if ( (abs(pv1(i,j,k)-mdv).gt.eps).and. |
> (abs(ano(i,j,k)-mdv).gt.eps) ) then |
pv2(i,j,k)=pv1(i,j,k)-ano(i,j,k) |
else |
pv2(i,j,k)=mdv |
endif |
enddo |
enddo |
enddo |
|
c Write result to netcdf file |
varname='PV_FILT' |
call write_inp (pv2,varname,pvsrcfile,nx,ny,nz) |
|
c Write the modified anomaly also to the file |
varname='PV_ANOM' |
call write_inp (ano,varname,pvsrcfile,nx,ny,nz) |
|
end |
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c ******************************************************************************** |
c * Command handling and transformations * |
c ******************************************************************************** |
|
c -------------------------------------------------------------------------------- |
c Extract next command from command string |
c -------------------------------------------------------------------------------- |
|
subroutine next_command (commandstr,n,com,par) |
|
c Given the command string <commandstr>, extract the next command/parameter pair |
c <com,par> starting at position <n> of the command string. |
|
implicit none |
|
c Declaration of subroutine parameters |
character*80 commandstr |
character*80 com |
real par |
integer n |
|
c Auxiliary variables |
integer i,j,k |
|
c Check whether end of command line reached |
if (n.ge.80) then |
com='nil' |
par=0. |
goto 120 |
endif |
|
c Set indices to next next command/parameter pair |
i=n |
j=n |
100 if ( (commandstr(j:j).ne.'=').and.(j.lt.80) ) then |
j=j+1 |
goto 100 |
endif |
k=j+1 |
110 if ( (commandstr(k:k).ne.',' ).and. |
> (commandstr(k:k).ne.';' ).and. |
> (commandstr(k:k).ne.' ' ).and. |
> (k .lt.80 ) ) then |
k=k+1 |
goto 110 |
endif |
|
c Check whether this is a valid command/parameter pair |
if ( ((j-1).lt.i).or.((k-1).lt.(j+1)) ) then |
com='nil' |
par=0. |
goto 120 |
endif |
|
c Extract tzhe command and the parameter |
com=commandstr(i:j-1) |
read(commandstr(j+1:k-1),*) par |
|
c Set the counter to the next command/parameter pair |
n=k+1 |
|
c Exit point |
120 continue |
|
end |
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c -------------------------------------------------------------------------------- |
c Multiply the anomaly by a factor |
c -------------------------------------------------------------------------------- |
|
subroutine mod_factor (field,factor,nx,ny,nz,mdv) |
|
c Multiply the anomaly <field> by a constant factor <factor>. The grid and the |
c missing data value are given by <nx,ny,nz,mdv>. |
|
implicit none |
|
c Declaration of subroutine parameters |
integer nx,ny,nz |
real field(0:nx,0:ny,0:nz) |
real mdv |
real factor |
|
c Parameters |
real eps |
parameter (eps=0.01) |
|
c Auxiliary variables |
integer i,j,k |
|
c Do the transformation |
do i=0,nx |
do j=0,ny |
do k=0,nz |
if ( (abs(field(i,j,k)-mdv).gt.eps) ) then |
field(i,j,k)=factor*field(i,j,k) |
endif |
enddo |
enddo |
enddo |
|
end |
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c -------------------------------------------------------------------------------- |
c Rotate the anomaly |
c -------------------------------------------------------------------------------- |
|
subroutine mod_rotation (field,angle,cex,cey, |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
|
c Rotate the anomaly <field> in the horizontal by the angle <angle>. The centre |
c for the rotation is given by <cex,cey>, expressed in rotated longitude, latitude. |
c The grid and the missing data value are given by <nx,ny,nz,xmin,ymin,dx,dy,mdv>. |
|
|
implicit none |
|
c Declaration of subroutine parameters |
integer nx,ny,nz |
real field(0:nx,0:ny,0:nz) |
real xmin,ymin,dx,dy |
real mdv |
real angle |
real cex,cey |
|
c Parameters |
real eps |
parameter (eps=0.01) |
real pi180 |
parameter (pi180=3.14159/180.) |
|
c Auxiliary variables |
integer i,j,k |
real lon,lat,rlon,rlat |
real xmax,ymax |
real tmp1(0:nx,0:ny),tmp2(0:nx,0:ny) |
|
c Externals |
real int2d |
external int2d |
|
c Maximal grid extension |
xmax=xmin+real(nx-1)*dx |
ymax=ymin+real(ny-1)*dy |
|
c Do the Transformation |
do k=0,nz |
|
c Copy level to 2d array |
do i=0,nx |
do j=0,ny |
tmp1(i,j)=field(i,j,k) |
enddo |
enddo |
|
c Rotate each grid point |
do i=0,nx |
do j=0,ny |
|
c Lon/lat coordinates of grid point |
lon=xmin+real(i)*dx-cex |
lat=ymin+real(j)*dy-cey |
|
c Rotation |
rlon = cex + lon*cos(angle*pi180) + lat*sin(angle*pi180) |
rlat = cey - lon*sin(angle*pi180) + lat*cos(angle*pi180) |
|
c Do the interpolation |
if ( (rlon.gt.xmin).and.(rlon.lt.xmax).and. |
> (rlat.gt.ymin).and.(rlat.lt.ymax) ) |
> then |
tmp2(i,j)=int2d(tmp1,rlon,rlat, |
> dx,dy,xmin,ymin,nx,ny,mdv) |
else |
tmp2(i,j)=0. |
endif |
|
enddo |
enddo |
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c Copy 2d array to level |
do i=0,nx |
do j=0,ny |
field(i,j,k)=tmp2(i,j) |
enddo |
enddo |
|
enddo |
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end |
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c -------------------------------------------------------------------------------- |
c Shift the anomaly in x and y direction |
c -------------------------------------------------------------------------------- |
|
subroutine mod_shift (field,shiftx,shifty, |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
|
c Shift the anomaly <field> in the horizontal by the vector <shiftx,shifty>. |
c The grid and the missing data value are given by <nx,ny,nz,xmin,ymin,dx,dy,mdv>. |
|
|
implicit none |
|
c Declaration of subroutine parameters |
integer nx,ny,nz |
real field(0:nx,0:ny,0:nz) |
real xmin,ymin,dx,dy |
real mdv |
real shiftx,shifty |
|
c Parameters |
real eps |
parameter (eps=0.01) |
|
c Auxiliary variables |
integer i,j,k |
real lon,lat,rlon,rlat |
real xmax,ymax |
real tmp1(0:nx,0:ny),tmp2(0:nx,0:ny) |
|
c Externals |
real int2d |
external int2d |
|
c Maximal grid extension |
xmax=xmin+real(nx-1)*dx |
ymax=ymin+real(ny-1)*dy |
|
c Do the Transformation |
do k=0,nz |
|
c Copy level to 2d array |
do i=0,nx |
do j=0,ny |
tmp1(i,j)=field(i,j,k) |
enddo |
enddo |
|
c Rotate each grid point |
do i=0,nx |
do j=0,ny |
|
c Lon/lat coordinates of grid point |
lon=xmin+real(i)*dx |
lat=ymin+real(j)*dy |
|
c shifted coordinates |
rlon = lon - shiftx |
rlat = lat - shifty |
|
c Do the interpolation |
if ( (rlon.gt.xmin).and.(rlon.lt.xmax).and. |
> (rlat.gt.ymin).and.(rlat.lt.ymax) ) |
> then |
tmp2(i,j)=int2d(tmp1,rlon,rlat, |
> dx,dy,xmin,ymin,nx,ny,mdv) |
else |
tmp2(i,j)=0. |
endif |
|
enddo |
enddo |
|
c Copy 2d array to level |
do i=0,nx |
do j=0,ny |
field(i,j,k)=tmp2(i,j) |
enddo |
enddo |
|
enddo |
|
end |
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c -------------------------------------------------------------------------------- |
c Stretch/shrink the anomaly in x and y direction |
c -------------------------------------------------------------------------------- |
|
subroutine mod_stretch (field,stretchx,stretchy, |
> nx,ny,nz,xmin,ymin,dx,dy,mdv) |
|
c Stretch the anomaly <field> in the horizontal by the fatcors <stretchx,stretchy>. |
c The grid and the missing data value are given by <nx,ny,nz,xmin,ymin,dx,dy,mdv>. |
|
|
implicit none |
|
c Declaration of subroutine parameters |
integer nx,ny,nz |
real field(0:nx,0:ny,0:nz) |
real xmin,ymin,dx,dy |
real mdv |
real stretchx,stretchy |
|
c Parameters |
real eps |
parameter (eps=0.01) |
|
c Auxiliary variables |
integer i,j,k |
real lon,lat,rlon,rlat |
real xmax,ymax |
real tmp1(0:nx,0:ny),tmp2(0:nx,0:ny) |
|
c Externals |
real int2d |
external int2d |
|
c Maximal grid extension |
xmax=xmin+real(nx-1)*dx |
ymax=ymin+real(ny-1)*dy |
|
c Do the Transformation |
do k=0,nz |
|
c Copy level to 2d array |
do i=0,nx |
do j=0,ny |
tmp1(i,j)=field(i,j,k) |
enddo |
enddo |
|
c Rotate each grid point |
do i=0,nx |
do j=0,ny |
|
c Lon/lat coordinates of grid point |
lon=xmin+real(i)*dx |
lat=ymin+real(j)*dy |
|
c shifted coordinates |
rlon = 1./stretchx * lon |
rlat = 1./stretchy * lat |
|
c Do the interpolation |
if ( (rlon.gt.xmin).and.(rlon.lt.xmax).and. |
> (rlat.gt.ymin).and.(rlat.lt.ymax) ) |
> then |
tmp2(i,j)=int2d(tmp1,rlon,rlat, |
> dx,dy,xmin,ymin,nx,ny,mdv) |
else |
tmp2(i,j)=0. |
endif |
|
enddo |
enddo |
|
c Copy 2d array to level |
do i=0,nx |
do j=0,ny |
field(i,j,k)=tmp2(i,j) |
enddo |
enddo |
|
enddo |
|
end |
|
c ------------------------------------------------------------------------ |
c Two-dimensional interpolation |
c ------------------------------------------------------------------------ |
|
real function int2d(ar,lon,lat, |
> dx,dy,xmin,ymin,nx,ny,mdv) |
|
c Interpolate the field <ar(nx,ny)> to the position <lon,lat>. The |
c grid is specified by <dx,dy,xmin,ymin,nx,ny>. |
|
implicit none |
|
c Declaration of subroutine paramters |
integer nx,ny |
real ar(0:nx,0:ny) |
real lon,lat |
real dx,dy,xmin,ymin |
real mdv |
|
c Parameters |
real eps |
parameter (eps=0.01) |
|
c Auxiliary variables |
real ri,rj |
integer i,j,ir,ju |
real frac0i,frac0j,frac1i,frac1j |
real tmp,nor |
|
c Get index |
ri=(lon-xmin)/dx |
rj=(lat-ymin)/dy |
i=int(ri) |
j=int(rj) |
if ((i.lt.0).or.(i.gt.nx).or. |
> (j.lt.0).or.(j.gt.ny)) then |
print*,'lat/lon interpolation not possible....' |
stop |
endif |
|
c Get inidices of left and upper neighbours |
ir=i+1 |
if (ir.gt.nx) ir=nx |
ju=j+1 |
if (ju.gt.ny) ju=ny |
|
c Get the weights for the bilinear interpolation |
frac0i=ri-float(i) |
frac0j=rj-float(j) |
frac1i=1.-frac0i |
frac1j=1.-frac0j |
|
c Bilinear interpolation with missing data check |
tmp=0. |
nor=0. |
if ( (abs(ar(i ,j )-mdv).gt.eps) ) then |
tmp = tmp + ar(i ,j ) * frac1i * frac1j |
nor = nor + frac1i * frac1j |
endif |
if ( (abs(ar(i ,ju)-mdv).gt.eps) ) then |
tmp = tmp + ar(i ,ju) * frac1i * frac0j |
nor = nor + frac1i * frac0j |
endif |
if ( (abs(ar(ir,j )-mdv).gt.eps) ) then |
tmp = tmp + ar(ir,j ) * frac0i * frac1j |
nor = nor + frac0i * frac1j |
endif |
if ( (abs(ar(ir,ju)-mdv).gt.eps) ) then |
tmp = tmp + ar(ir,ju) * frac0i * frac0j |
nor = nor + frac0i * frac0j |
endif |
|
c Return result |
int2d=tmp/nor |
|
end |
|
c ******************************************************************************** |
c * NETCDF INPUT AND OUTPUT * |
c ******************************************************************************** |
|
c -------------------------------------------------------------------------------- |
c Write input field to netcdf |
c -------------------------------------------------------------------------------- |
|
SUBROUTINE write_inp (field,fieldname,pvsrcfile,nx,ny,nz) |
|
c Read <fieldname> from netcdf file <pvsrcfile> into <field>. The grid is specified |
c by <nx,ny,nz,dx,dy,dz,xmin,ymin,zmin>. A check is performed whether the input |
c files are consitent with this grid. |
|
implicit none |
|
c Declaration of subroutine parameters |
integer nx,ny,nz |
real field (0:nx,0:ny,0:nz) |
character*80 fieldname |
character*80 pvsrcfile |
|
c Auxiliary variables |
integer cdfid,stat |
integer vardim(4) |
real misdat |
real varmin(4),varmax(4),stag(4) |
integer ndimin,outid,i,j,k |
real tmp(0:nx,0:ny,0:nz) |
integer ntimes |
real time(200) |
integer nvars |
character*80 vnam(100),varname |
integer isok |
|
c Get grid parameters from PV |
call cdfopn(pvsrcfile,cdfid,stat) |
if (stat.ne.0) goto 998 |
call getvars(cdfid,nvars,vnam,stat) |
if (stat.ne.0) goto 998 |
isok=0 |
varname='PV' |
call check_varok(isok,varname,vnam,nvars) |
if (isok.eq.0) goto 998 |
call getdef(cdfid,varname,ndimin,misdat,vardim, |
> varmin,varmax,stag,stat) |
if (stat.ne.0) goto 998 |
time(1)=0. |
call gettimes(cdfid,time,ntimes,stat) |
if (stat.ne.0) goto 998 |
call clscdf(cdfid,stat) |
if (stat.ne.0) goto 998 |
|
c Save variables (write definition, if necessary) |
call cdfwopn(pvsrcfile,cdfid,stat) |
if (stat.ne.0) goto 998 |
isok=0 |
varname=fieldname |
call check_varok(isok,varname,vnam,nvars) |
if (isok.eq.0) then |
call putdef(cdfid,varname,ndimin,misdat,vardim, |
> varmin,varmax,stag,stat) |
if (stat.ne.0) goto 998 |
endif |
call putdat(cdfid,varname,time(1),0,field,stat) |
print*,'W ',trim(varname),' ',trim(pvsrcfile) |
if (stat.ne.0) goto 998 |
|
c Close input netcdf file |
call clscdf(cdfid,stat) |
if (stat.ne.0) goto 998 |
|
return |
|
c Exception handling |
998 print*,'Write_Inp: Problem with input netcdf file... Stop' |
stop |
|
end |
|
|
c -------------------------------------------------------------------------------- |
c Read input fields for reference profile |
c -------------------------------------------------------------------------------- |
|
SUBROUTINE read_inp (field,fieldname,pvsrcfile, |
> nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,mdv) |
|
c Read <fieldname> from netcdf file <pvsrcfile> into <field>. The grid is specified |
c by <nx,ny,nz,dx,dy,dz,xmin,ymin,zmin>. A check is performed whether the input |
c files are consitent with this grid. The missing data value is set to <mdv>. |
|
implicit none |
|
c Declaration of subroutine parameters |
integer nx,ny,nz |
real field(0:nx,0:ny,0:nz) |
character*80 fieldname |
character*80 pvsrcfile |
real dx,dy,dz,xmin,ymin,zmin |
real mdv |
|
c Numerical and physical parameters |
real eps |
parameter (eps=0.01) |
|
c Auxiliary variables |
integer cdfid,stat,cdfid99 |
integer vardim(4) |
real misdat |
real varmin(4),varmax(4),stag(4) |
integer ndimin,outid,i,j,k |
real tmp(nx,ny,nz) |
integer ntimes |
real time(200) |
integer nvars |
character*80 vnam(100),varname |
integer isok |
|
c Open the input netcdf file |
call cdfopn(pvsrcfile,cdfid,stat) |
if (stat.ne.0) goto 998 |
|
c Check whether needed variables are on file |
call getvars(cdfid,nvars,vnam,stat) |
if (stat.ne.0) goto 998 |
isok=0 |
varname=trim(fieldname) |
call check_varok(isok,varname,vnam,nvars) |
if (isok.eq.0) goto 998 |
|
c Get the grid parameters from theta |
call getdef(cdfid,varname,ndimin,misdat,vardim, |
> varmin,varmax,stag,stat) |
if (stat.ne.0) goto 998 |
time(1)=0. |
call gettimes(cdfid,time,ntimes,stat) |
if (stat.ne.0) goto 998 |
|
c Check whether grid parameters are consistent |
if ( (vardim(1).ne.(nx+1)).or. |
> (vardim(2).ne.(ny+1)).or. |
> (vardim(3).ne.(nz+1)).or. |
> (abs(varmin(1)-xmin).gt.eps).or. |
> (abs(varmin(2)-ymin).gt.eps).or. |
> (abs(varmin(3)-zmin).gt.eps).or. |
> (abs((varmax(1)-varmin(1))/real(vardim(1)-1)-dx).gt.eps).or. |
> (abs((varmax(2)-varmin(2))/real(vardim(2)-1)-dy).gt.eps).or. |
> (abs((varmax(3)-varmin(3))/real(vardim(3)-1)-dz).gt.eps) ) |
>then |
print*,'Input grid inconsitency...' |
print*,' Nx = ',vardim(1),nx+1 |
print*,' Ny = ',vardim(2),ny+1 |
print*,' Nz = ',vardim(3),nz+1 |
print*,' Varminx = ',varmin(1),xmin |
print*,' Varminy = ',varmin(2),ymin |
print*,' Varminz = ',varmin(3),zmin |
print*,' Dx = ',(varmax(1)-varmin(1))/real(nx-1),dx |
print*,' Dy = ',(varmax(2)-varmin(2))/real(ny-1),dy |
print*,' Dz = ',(varmax(3)-varmin(3))/real(nz-1),dz |
goto 998 |
endif |
|
c Load variables |
call getdef(cdfid,varname,ndimin,misdat,vardim, |
> varmin,varmax,stag,stat) |
if (stat.ne.0) goto 998 |
call getdat(cdfid,varname,time(1),0,field,stat) |
print*, 'R ',trim(varname),' ',trim(pvsrcfile) |
if (stat.ne.0) goto 998 |
|
c Close input netcdf file |
call clscdf(cdfid,stat) |
if (stat.ne.0) goto 998 |
|
c Set missing data value to <mdv> |
do i=1,nx |
do j=1,ny |
do k=1,nz |
if (abs(field(i,j,k)-misdat).lt.eps) then |
field(i,j,k)=mdv |
endif |
enddo |
enddo |
enddo |
|
return |
|
c Exception handling |
998 print*,'Read_Inp: Problem with input netcdf file... Stop' |
stop |
|
end |
|
c -------------------------------------------------------------------------------- |
c Check whether variable is found on netcdf file |
c -------------------------------------------------------------------------------- |
|
subroutine check_varok (isok,varname,varlist,nvars) |
|
c Check whether the variable <varname> is in the list <varlist(nvars)>. If this is |
C the case, <isok> is incremented by 1. Otherwise <isok> keeps its value. |
|
implicit none |
|
c Declaraion of subroutine parameters |
integer isok |
integer nvars |
character*80 varname |
character*80 varlist(nvars) |
|
c Auxiliary variables |
integer i |
|
c Main |
do i=1,nvars |
if (trim(varname).eq.trim(varlist(i))) isok=isok+1 |
enddo |
|
end |
|
c -------------------------------------------------------------------------------- |
c Get grid parameters |
c -------------------------------------------------------------------------------- |
|
subroutine read_dim (nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,mdv, |
> pvsrcfile) |
|
c Get the grid parameters from the variable <THETA> on the input file <pvsrcfile>. |
c The grid parameters are |
c nx,ny,nz : Number of grid points in x, y and z direction |
c xmin,ymin,zmin : Minimum domain coordinates in x, y and z direction |
c xmax,ymax,zmax : Maximal domain coordinates in x, y and z direction |
c dx,dy,dz : Horizontal and vertical resolution |
c Additionally, it is checked whether the vertical grid is equally spaced. If ok, |
c the grid paramters are transformed from lon/lat to distance (in meters) |
|
implicit none |
|
c Declaration of subroutine parameters |
character*80 pvsrcfile |
integer nx,ny,nz |
real dx,dy,dz |
real xmin,ymin,zmin,xmax,ymax,zmax |
real mdv |
|
c Numerical epsilon and other physical/geoemtrical parameters |
real eps |
parameter (eps=0.01) |
|
c Auxiliary variables |
integer cdfid,cstid |
integer ierr |
character*80 vnam(100),varname |
integer nvars |
integer isok |
integer vardim(4) |
real misdat |
real varmin(4),varmax(4),stag(4) |
real aklev(1000),bklev(1000),aklay(1000),bklay(1000) |
real dh |
character*80 csn |
integer ndim |
integer i |
|
c Get all grid parameters |
call cdfopn(pvsrcfile,cdfid,ierr) |
if (ierr.ne.0) goto 998 |
call getvars(cdfid,nvars,vnam,ierr) |
if (ierr.ne.0) goto 998 |
isok=0 |
varname='PV' |
call check_varok(isok,varname,vnam,nvars) |
if (isok.eq.0) goto 998 |
call getcfn(cdfid,csn,ierr) |
if (ierr.ne.0) goto 998 |
call cdfopn(csn,cstid,ierr) |
if (ierr.ne.0) goto 998 |
call getdef(cdfid,varname,ndim,misdat,vardim,varmin,varmax, |
> stag,ierr) |
if (ierr.ne.0) goto 998 |
nx=vardim(1) |
ny=vardim(2) |
nz=vardim(3) |
xmin=varmin(1) |
ymin=varmin(2) |
zmin=varmin(3) |
call getlevs(cstid,nz,aklev,bklev,aklay,bklay,ierr) |
if (ierr.ne.0) goto 998 |
call getgrid(cstid,dx,dy,ierr) |
if (ierr.ne.0) goto 998 |
xmax=varmax(1) |
ymax=varmax(2) |
zmax=varmax(3) |
dz=(zmax-zmin)/real(nz-1) |
call clscdf(cstid,ierr) |
if (ierr.ne.0) goto 998 |
call clscdf(cdfid,ierr) |
if (ierr.ne.0) goto 998 |
|
c Check whether the grid is equallay spaced in the vertical |
do i=1,nz-1 |
dh=aklev(i+1)-aklev(i) |
if (abs(dh-dz).gt.eps) then |
print*,'Aklev: Vertical grid must be equally spaced... Stop' |
print*,(aklev(i),i=1,nz) |
stop |
endif |
dh=aklay(i+1)-aklay(i) |
if (abs(dh-dz).gt.eps) then |
print*,'Aklay: Vertical grid must be equally spaced... Stop' |
print*,(aklay(i),i=1,nz) |
stop |
endif |
enddo |
|
c Set missing data value |
mdv=misdat |
|
return |
|
c Exception handling |
998 print*,'Read_Dim: Problem with input netcdf file... Stop' |
stop |
|
end |
Property changes: |
Added: svn:executable |