Subversion Repositories pvinversion.ecmwf

      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

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

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

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

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

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     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

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