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PROGRAM inv_cart
c ********************************************************************************
c * CALCULATES FOR A PV AND THETA DISTRIBUTION OTHER PROGNOSTIC FIELDS BY *
c * MEANS OF A PV INVERSION *
c * *
c * Rene Fehlmann 1994 / Code re-organization: Michael Sprenger, 2006 *
c ********************************************************************************
c --------------------------------------------------------------------------------
c Declaration of variables, parameters, externals and common blocks
c --------------------------------------------------------------------------------
implicit none
c Grid parameters
integer nx,ny,nz
real xmin,ymin,zmin,xmax,ymax,zmax
real dx,dy,dz
real deltax,deltay,deltaz
real mdv
real, allocatable,dimension (:,:) :: coriol
c Reference state
real, allocatable,dimension (:) :: nsqref
real, allocatable,dimension (:) :: thetaref
real, allocatable,dimension (:) :: rhoref
real, allocatable,dimension (:) :: pressref
real, allocatable,dimension (:) :: zref
C Boundary conditions
real, allocatable,dimension (:,:) :: thetatop
real, allocatable,dimension (:,:) :: thetabot
real, allocatable,dimension (:,:) :: ua
real, allocatable,dimension (:,:) :: ub
real, allocatable,dimension (:,:) :: va
real, allocatable,dimension (:,:) :: vb
c Potentiual vorticity and stream function
real, allocatable,dimension (:,:,:) :: psi
real, allocatable,dimension (:,:,:) :: pv
c Auxiliary arrays for numerics
real, allocatable,dimension (:,:,:) :: a
real, allocatable,dimension (:,:,:) :: b
real, allocatable,dimension (:,:,:) :: c
c Input parameters
character*80 pvsrcfile
character*80 referfile
c Auxiliary variables
integer i,j,k
integer stat
c --------------------------------------------------------------------------------
c Preparations
c --------------------------------------------------------------------------------
print*,'********************************************************'
print*,'* INV_CART *'
print*,'********************************************************'
c Read parameter file
open(10,file='fort.10')
read(10,*) pvsrcfile
read(10,*) referfile
close(10)
print*
print*,trim(pvsrcfile)
c Get lat/lon gid parameters from input file
call read_dim (nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,mdv,
> pvsrcfile)
print*
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
nx=nx-1
ny=ny-1
nz=nz-1
c Allocate memory for boundary conditions
allocate(thetatop(0:nx,0:ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array thetatop ***'
allocate(thetabot(0:nx,0:ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array thetabot ***'
allocate(ua(0:nx,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array ua ***'
allocate(ub(0:nx,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array ub ***'
allocate(va(0:ny,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array va ***'
allocate(vb(0:ny,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array vb ***'
c Allocate memory for 3d PV and stream function
allocate(psi(0:nx,0:ny,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array psi ***'
allocate(pv(0:nx,0:ny,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array pv ***'
c Alllocate memory for matrix elements for inversion operator
allocate(a(0:nx,0:ny,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array a ***'
allocate(b(0:nx,0:ny,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array b ***'
allocate(c(0:nx,0:ny,0:nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array c ***'
c Allocate memory for reference profile
allocate(nsqref(0:2*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array nsqref ***'
allocate(thetaref(0:2*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array thetaref ***'
allocate(rhoref(0:2*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array rhoref ***'
allocate(pressref(0:2*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array pressref ***'
allocate(zref(0:2*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array zref ***'
c Allocate memory for Coriolis parameter
allocate(coriol(0:nx,0:ny),STAT=stat)
if (stat.ne.0) print*,'error allocating coriol'
c --------------------------------------------------------------------------------
c Input
c --------------------------------------------------------------------------------
c Read reference profile and grid parameters
call read_ref (nsqref,rhoref,thetaref,pressref,zref,
> nx,ny,nz,deltax,deltay,deltaz,coriol,
> referfile)
deltax=1000.*deltax
deltay=1000.*deltay
c Read input fields from netcdf
call read_inp (pv,thetabot,thetatop,ua,ub,va,vb,
> nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,
> pvsrcfile)
c --------------------------------------------------------------------------------
c Perform the inversion
c --------------------------------------------------------------------------------
C Init matrix elements for inversion
call matrixel(a,b,c,coriol,nx,ny,nz,nsqref,rhoref,
> deltax,deltay,deltaz)
c Inversion
call sor(psi,nsqref,thetatop,thetabot,thetaref,rhoref,coriol,
> pv,ua,ub,va,vb,a,b,c,nx,ny,nz,deltax,deltay,deltaz)
c --------------------------------------------------------------------------------
c Output
c --------------------------------------------------------------------------------
c Write output to netcdf
print*
call write_out (psi,thetabot,thetatop,ua,ub,va,vb,
> nx,ny,nz,deltax,deltay,deltaz,
> coriol,thetaref,rhoref,pressref,pvsrcfile)
END
c ********************************************************************************
c * NETCDF AND ASCII INPUT AND OUTPUT *
c ********************************************************************************
c --------------------------------------------------------------------------------
c Output to netcdf file
c --------------------------------------------------------------------------------
SUBROUTINE write_out (psi,thetabot,thetatop,ua,ub,va,vb,nx,ny,nz,
> dx,dy,dz,coriol,thetaref,rhoref,pref,
> pvsrcfile)
c Write the result of the inversion to output netcdf
c
c psi : streamm function as calculated from inversion
c thetabot,thetatop : potential temperature at lower and upper boundary
c ua,ub : Zonal wind at western and eastern boundary
c va,vb : Meridional wind at southern and northern boundary
c nx,ny,nz : Grid dimension in x, y and z direction
c dx,dy,dz : Grid resolution
c coriol : Coriolis parameter
c thetaref : Reference profile of potential temperature
c rhoref : Reference profile of density
c pref : Reference profile of pressure
c pvsrcfile : Name of the output netcdf file
implicit none
c Declaration of subroutine parameters
integer nx,ny,nz
real psi(0:nx,0:ny,0:nz)
real thetatop(0:nx,0:ny)
real thetabot(0:nx,0:ny)
real ua(0:nx,0:nz)
real ub(0:nx,0:nz)
real va(0:ny,0:nz)
real vb(0:ny,0:nz)
character*(30) pvsrcfile
real dx,dy,dz
real thetaref(0:2*nz)
real rhoref(0:2*nz)
real pref(0:2*nz)
real coriol(0:nx,0:ny)
c Numerical and physical parameters
real eps
parameter (eps=0.01)
real g
parameter (g=9.81)
real preunit
parameter (preunit=0.01)
real kappa
parameter (kappa=0.286)
c Auxiliary variables
integer cdfid,stat
integer vardim(4)
real misdat
integer ndimin
real varmin(4),varmax(4),stag(4)
integer i,j,k,nf1,jj,kk
real tmp(0:nx,0:ny,0:nz)
real pr (0:nx,0:ny,0:nz)
real th (0:nx,0:ny,0:nz)
integer ntimes
real time(200)
character*80 vnam(100),varname
integer nvars
integer isok,ierr
real meanpsi,meancnt
c Get grid description
call cdfopn(pvsrcfile,cdfid,stat)
if (stat.ne.0) goto 997
call getvars(cdfid,nvars,vnam,stat)
if (stat.ne.0) goto 997
isok=0
varname='QGPV'
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdef(cdfid,varname,ndimin,misdat,vardim,
> varmin,varmax,stag,stat)
if (stat.ne.0) goto 997
time(1)=0.
call gettimes(cdfid,time,ntimes,stat)
if (stat.ne.0) goto 997
call clscdf(cdfid,stat)
if (stat.ne.0) goto 997
c Open output netcdf file
call cdfwopn(pvsrcfile,cdfid,stat)
if (stat.ne.0) goto 997
c Create the variable if necessary
call getvars(cdfid,nvars,vnam,stat)
if (stat.ne.0) goto 997
isok=0
varname='PSI'
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 997
endif
isok=0
varname='U'
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 997
endif
isok=0
varname='V'
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 997
endif
isok=0
varname='TH'
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 997
endif
isok=0
varname='T'
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 997
endif
isok=0
varname='P'
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 997
endif
c Write stream function
varname='PSI'
call putdat(cdfid,varname,time(1),0,psi,ierr)
if (stat.ne.0) goto 997
print*,'W PSI ',trim(pvsrcfile)
c Calculate and write velocity U: keep southern and northern boundary
do k=0,nz
do i=0,nx
do j=1,ny-1
tmp(i,j,k)=(psi(i,j-1,k)-psi(i,j+1,k))/
> (2.*dy*coriol(i,j))
enddo
tmp(i,0,k) =ua(i,k)
tmp(i,ny,k)=ub(i,k)
enddo
enddo
varname='U'
call putdat(cdfid,varname,time(1),0,tmp,ierr)
if (stat.ne.0) goto 997
print*,'W U ',trim(pvsrcfile)
C Calculate and write velocity V: keep western and eastern boundary
do k=0,nz
do j=0,ny
do i=1,nx-1
tmp(i,j,k)=(psi(i+1,j,k)-psi(i-1,j,k))/
> (2.*dx*coriol(i,j))
enddo
tmp(0,j,k)=va(j,k)
tmp(nx,j,k)=vb(j,k)
enddo
enddo
varname='V'
call putdat(cdfid,varname,time(1),0,tmp,ierr)
if (stat.ne.0) goto 997
print*,'W V ',trim(pvsrcfile)
c Calculate and write potential temperature: keep lower and upper boundary
c Potential temperature is needed for calculation of temperature: keep it
do i=0,nx
do j=0,ny
th(i,j,0)=thetabot(i,j)
do k=1,nz-1
th(i,j,k)=thetaref(2*k)*
> (psi(i,j,k+1)-psi(i,j,k-1))/(2.*dz*g)
enddo
th(i,j,nz)=thetatop(i,j)
enddo
enddo
varname='TH'
call putdat(cdfid,varname,time(1),0,th,ierr)
if (stat.ne.0) goto 997
print*,'W TH ',trim(pvsrcfile)
c Calculate and write pressure: The pressure is directly proportional to the
c streamfunction. But the streamfunction is determined only up to an additive
c constant. Shift the streamfunction in such a way that it vanish in the mean
c on the boundaries. Pressure is needed for calculation of temperature: keep it
meanpsi=0.
meancnt=0.
do i=0,nx
do j=0,ny
meanpsi=meanpsi+psi(i,j,0)+psi(i,j,nz)
meancnt=meancnt+2
enddo
enddo
do i=0,nx
do k=0,nz
meanpsi=meanpsi+psi(i,0,k)+psi(i,ny,k)
meancnt=meancnt+2
enddo
enddo
do j=0,ny
do k=0,nz
meanpsi=meanpsi+psi(0,j,k)+psi(nx,j,k)
meancnt=meancnt+2
enddo
enddo
meanpsi=meanpsi/meancnt
do i=0,nx
do j=0,ny
do k=0,nz
kk=2*k
pr(i,j,k)=preunit*rhoref(kk)*(psi(i,j,k)-meanpsi)
enddo
enddo
enddo
varname='P'
call putdat(cdfid,varname,time(1),0,pr,ierr)
if (stat.ne.0) goto 997
print*,'W P ',trim(pvsrcfile)
c Calculate and write temperature
do i=0,nx
do j=0,ny
do k=0,nz
kk=2*k
tmp(i,j,k)=((pref(kk)/1000.)**kappa) *
> (th(i,j,k)+kappa*thetaref(kk)*pr(i,j,k)/pref(kk))
enddo
enddo
enddo
varname='T'
call putdat(cdfid,varname,time(1),0,tmp,ierr)
if (stat.ne.0) goto 997
print*,'W T ',trim(pvsrcfile)
c Close output netcdf file
call clscdf(cdfid,stat)
if (stat.ne.0) goto 997
return
c Exception handling
997 print*,'Problem with output netcdf file... Stop'
stop
end
c --------------------------------------------------------------------------------
c Read the reference file
c --------------------------------------------------------------------------------
SUBROUTINE read_ref (nsqref,rhoref,thetaref,pressref,zref,
> nx,ny,nz,deltax,deltay,deltaz,coriol,
> pvsrcfile)
c Read the reference profile from file
c
c thetaref : Reference potential temperature (K)
c pressref : Reference pressure (Pa)
c rhoref : Reference density (kg/m^3)
c nsqref : Stratification (s^-1)
c zref : Reference height (m)
c nx,nny,nz : Grid dimension in x,y,z direction
c deltax,deltay,deltaz : Grid spacings used for calculations (m)
c coriol : Coriolis parameter (s^-1)
c pvsrcfile : Input file
implicit none
c Declaration of subroutine parameters
integer nx,ny,nz
real nsqref (0:2*nz)
real thetaref(0:2*nz)
real rhoref (0:2*nz)
real pressref(0:2*nz)
real zref (0:2*nz)
real deltax,deltay,deltaz
real coriol (0:nx,0:ny)
character*80 pvsrcfile
c Numerical and physical parameters
real eps
parameter (eps=0.01)
c Auxiliary variables
integer cdfid,stat
integer vardim(4)
real misdat
integer ndimin
real varmin(4),varmax(4),stag(4)
integer i,j,k,nf1
integer ntimes
real time(200)
character*80 vnam(100),varname
integer nvars
integer isok,ierr
real x(0:nx,0:ny),y(0:nx,0:ny)
real mean,count
c Get grid description from topography
call cdfopn(pvsrcfile,cdfid,stat)
if (stat.ne.0) goto 997
call getvars(cdfid,nvars,vnam,stat)
if (stat.ne.0) goto 997
isok=0
varname='ORO'
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdef(cdfid,varname,ndimin,misdat,vardim,
> varmin,varmax,stag,stat)
if (stat.ne.0) goto 997
time(1)=0.
call gettimes(cdfid,time,ntimes,stat)
if (stat.ne.0) goto 997
call clscdf(cdfid,stat)
if (stat.ne.0) goto 997
c Open output netcdf file
call cdfopn(pvsrcfile,cdfid,stat)
if (stat.ne.0) goto 997
c Create the variable if necessary
call getvars(cdfid,nvars,vnam,stat)
if (stat.ne.0) goto 997
c Read data from netcdf file
isok=0
varname='NSQREF'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,nsqref,stat)
if (stat.ne.0) goto 997
isok=0
varname='RHOREF'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,rhoref,stat)
if (stat.ne.0) goto 997
isok=0
varname='THETAREF'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,thetaref,stat)
if (stat.ne.0) goto 997
isok=0
varname='PREREF'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,pressref,stat)
if (stat.ne.0) goto 997
isok=0
varname='ZREF'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,zref,stat)
if (stat.ne.0) goto 997
isok=0
varname='CORIOL'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,coriol,stat)
if (stat.ne.0) goto 997
isok=0
varname='X'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,x,stat)
if (stat.ne.0) goto 997
isok=0
varname='Y'
print*,'R ',trim(varname),' ',trim(pvsrcfile)
call check_varok(isok,varname,vnam,nvars)
if (isok.eq.0) goto 997
call getdat(cdfid,varname,time(1),0,y,stat)
if (stat.ne.0) goto 997
c Close netcdf file
call clscdf(cdfid,stat)
if (stat.ne.0) goto 997
c Determine the grid spacings <deltax, deltay, deltaz>
mean=0.
count=0.
do i=1,nx
do j=0,ny
mean=mean+abs(x(i,j)-x(i-1,j))
count=count+1.
enddo
enddo
deltax=mean/count
mean=0.
count=0.
do j=1,ny
do i=0,nx
mean=mean+abs(y(i,j)-y(i,j-1))
count=count+1.
enddo
enddo
deltay=mean/count
mean=0.
count=0.
do k=1,nz-1
mean=mean+abs(zref(k+1)-zref(k-1))
count=count+1.
enddo
deltaz=mean/count
return
c Exception handling
997 print*,'Read_Ref: Problem with input netcdf file... Stop'
stop
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='QGPV'
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
c -------------------------------------------------------------------------------
c Read the input netcdf file
c --------------------------------------------------------------------------------
SUBROUTINE read_inp (pv,thetabot,thetatop,ua,ub,va,vb,
> nx,ny,nz,dx,dy,dz,xmin,ymin,zmin,
> pvsrcfile)
c Read all needed field from netcdf file <pvsrcfile>. The input fields are:
c pv : quasigeostrophic potential vorticity
c thetabot,thetatop : potential temperature at lower and upper boundary
c ua,ub : Zonal wind at western and eastern boundary
c va,vb : Meridional wind at southern and northern boundary
c The grid is specified by <nx,ny,nz,dx,dy,dz,xmin,ymin,zmin>. A check is performed
c whether the input files are consitent with this grid. The input netcdf file must
c contain the variables <QGPV,THETA,U,V>. If the netcdf file also contains the fields
c <DQGPV,DTHETA,DU,DV>, these increments are added to <QGPV,THETA,U,V>.
implicit none
c Declaration of subroutine parameters
integer nx,ny,nz
real pv(0:nx,0:ny,0:nz)
real thetatop(0:nx,0:ny)
real thetabot(0:nx,0:ny)
real ua(0:nx,0:nz)
real ub(0:nx,0:nz)
real va(0:ny,0:nz)
real vb(0:ny,0:nz)
character*(30) pvsrcfile
real dx,dy,dz,xmin,ymin,zmin
c Numerical and physical parameters
real eps
parameter (eps=0.01)
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 max_th
real tmp(0:nx,0:ny,0: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='TH'
call check_varok(isok,varname,vnam,nvars)
varname='U'
call check_varok(isok,varname,vnam,nvars)
varname='V'
call check_varok(isok,varname,vnam,nvars)
varname='QGPV'
call check_varok(isok,varname,vnam,nvars)
if (isok.ne.4) goto 998
c Get the grid parameters
varname='QGPV'
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 consitent
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(nx)-dx).gt.eps).or.
> (abs((varmax(2)-varmin(2))/real(ny)-dy).gt.eps).or.
> (abs((varmax(3)-varmin(3))/real(nz)-dz).gt.eps) ) then
print*,'Input grid inconsitency...'
print*,'xmin : ',xmin,varmin(1)
print*,'ymin : ',ymin,varmin(2)
print*,'zmin : ',zmin,varmin(3)
print*,'dx : ',dx,(varmax(1)-varmin(1))/real(nx)
print*,'dy : ',dy,(varmax(2)-varmin(2))/real(ny)
print*,'dz : ',dz,(varmax(3)-varmin(3))/real(nz)
print*,'nx : ',nx
print*,'ny : ',ny
print*,'nz : ',nz
goto 998
endif
c THETA: Load upper and lower boundary values
varname='TH'
call getdat(cdfid,varname,time(1),0,tmp,stat)
print*,'R TH ',trim(pvsrcfile)
if (stat.ne.0) goto 998
do i=0,nx
do j=0,ny
if ( abs(tmp(i,j,0)-misdat).lt.eps ) then
thetabot(i,j)=0.
else
thetabot(i,j)=tmp(i,j,0)
endif
if ( abs(tmp(i,j,nz)-misdat).lt.eps ) then
thetatop(i,j)=0.
else
thetatop(i,j)=tmp(i,j,nz)
endif
enddo
enddo
c U: Load zonal velocity at southern and northern boundary
varname='U'
call getdef(cdfid,varname,ndimin,misdat,vardim,
> varmin,varmax,stag,stat)
if (stat.ne.0) goto 998
call getdat(cdfid,varname,time(1),0,tmp,stat)
print*,'R U ',trim(pvsrcfile)
if (stat.ne.0) goto 998
do i=0,nx
do k=0,nz
if ( abs(tmp(i,0,k)-misdat).lt.eps ) then
ua(i,k)=0.
else
ua(i,k)=tmp(i,0,k)
endif
if ( abs(tmp(i,ny,k)-misdat).lt.eps ) then
ub(i,k)=0.
else
ub(i,k)=tmp(i,ny,k)
endif
enddo
enddo
c Load meridional velocity at western and eastern boundary
varname='V'
call getdef(cdfid,varname,ndimin,misdat,vardim,
> varmin,varmax,stag,stat)
if (stat.ne.0) goto 998
call getdat(cdfid,varname,time(1),0,tmp,stat)
print*,'R V ',trim(pvsrcfile)
if (stat.ne.0) goto 998
do j=0,ny
do k=0,nz
if ( abs(tmp(0,j,k)-misdat).lt.eps ) then
va(j,k)=0.
else
va(j,k)=tmp(0,j,k)
endif
if ( abs(tmp(nx,j,k)-misdat).lt.eps ) then
vb(j,k)=0.
else
vb(j,k)=tmp(nx,j,k)
endif
enddo
enddo
c Load qgPV
varname='QGPV'
call getdef(cdfid,varname,ndimin,misdat,vardim,
> varmin,varmax,stag,stat)
if (stat.ne.0) goto 998
call getdat(cdfid,varname,time(1),0,tmp,stat)
print*,'R QGPV ',trim(pvsrcfile)
if (stat.ne.0) goto 998
do i=0,nx
do j=0,ny
do k=0,nz
if ( abs(tmp(i,j,k)-misdat).lt.eps ) then
pv(i,j,k)=0.
else
pv(i,j,k)=tmp(i,j,k)
endif
enddo
enddo
enddo
c Close input netcdf file
call clscdf(cdfid,stat)
if (stat.ne.0) goto 998
return
c Exception handling
998 print*,'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 * INVERSION ROUTINES *
c ********************************************************************************
c --------------------------------------------------------------------------------
c SOR algorithm (successive over relaxation)
c --------------------------------------------------------------------------------
SUBROUTINE sor(psi,nsq,thetatop,thetabot,thetaref,rhoref,
> coriol,pv,ua,ub,va,vb,a,b,c,nx,ny,nz,dx,dy,dz)
c Solve the qgPV equation by succesive over relaxation (SOR). The subroutine
c parameters are:
c
c psi : Streamfunction, i.e. result of the PV inversion
c nsq,rhoref,thetaref : Reference profile
c thetatop,thetabot : Upper and lower boundary condition
c pv : quasigeostrophic potential vorticity (qgPV)
c ua,ub,va,vb : lateral boundary condition for wind
c a,b,c : Matrices for the inversion operator
c nx,ny,nz,dx,dy,dz : Grid specification
c coriol : Coriolis parameter
implicit none
c Declaration of subroutine parameters
integer nx,ny,nz
real dx,dy,dz
real psi (0:nx,0:ny,0:nz)
real nsq (0:2*nz)
real thetatop(0:nx,0:ny)
real thetabot(0:nx,0:ny)
real thetaref(0:2*nz)
real rhoref (0:2*nz)
real pv (0:nx,0:ny,0:nz)
real ua (0:nx,0:nz)
real ub (0:nx,0:nz)
real va (0:ny,0:nz)
real vb (0:ny,0:nz)
real a (0:nx,0:ny,0:nz)
real b (0:nx,0:ny,0:nz)
real c (0:nx,0:ny,0:nz)
real coriol (0:nx,0:ny)
c Numerical and physical parameters
real maxspec
parameter (maxspec=2.0)
integer nofiter
parameter (nofiter=500)
real omega
parameter (omega=1.81)
c Auxiliary variables
integer counter
integer i,j,k
real deltasq,psigauge
real specx,specy,specz
real helpx,helpy,helpz
c Init the output array
do i=0,nx
do j=0,ny
do k=0,nz
psi(i,j,k)=0.
enddo
enddo
enddo
c Calculate the spectrum of the matrix
i=nx/2
specx=4.*a(i,0,0)/
> (2.*a(i,0,0)+b(i,0,0)+b(i,1,0)+c(i,0,0)+c(i,0,1))
specy=2.*(b(i,0,0)+b(i,1,0))/
> (2.*a(i,0,0)+b(i,0,0)+b(i,1,0)+c(i,0,0)+c(i,0,1))
specz=2.*(c(i,0,0)+c(i,0,1))/
> (2.*a(i,0,0)+b(i,0,0)+b(i,1,0)+c(i,0,0)+c(i,0,1))
do k=1,nz-2
do j=1,ny-2
helpx=4.*a(i,j,k)/
> (2.*a(i,j,k)+b(i,j,k)+b(i,j-1,k)+c(i,j,k)+c(i,j,k-1))
if (helpx.gt.specx) specx=helpx
helpy=2.*(b(i,j,k)+b(i,j+1,k))/
> (2.*a(i,j,k)+b(i,j,k)+b(i,j-1,k)+c(i,j,k)+c(i,j,k-1))
if (helpy.gt.specy) specy=helpy
helpz=2.*(c(i,j,k)+c(i,j,k+1))/
> (2.*a(i,j,k)+b(i,j,k)+b(i,j-1,k)+c(i,j,k)+c(i,j,k-1))
if (helpz.gt.specz) specz=helpz
enddo
enddo
c Check whether the dimensions of the grid are sufficient
print *
print *, 'Spectrum of the matrix in each direction '
print *, 'Spectrum = ', specx, specy, specz
print *
if ((maxspec*specx.lt.specy).or.(maxspec*specx.lt.specz)) then
print*,' Nx too small... Stop'
stop
endif
if ((maxspec*specy.lt.specx).or.(maxspec*specy.lt.specz)) then
print*,'Ny too small... Stop'
stop
endif
if ((maxspec*specz.lt.specx).or.(maxspec*specz.lt.specy)) then
print*,'Nz too small... Stop'
stop
endif
c Calculate error: control variable for the iteration
psigauge=0.
deltasq=0.
do k=1,nz-1
do i=1,nx-1
do j=1,ny-1
deltasq=deltasq+(-pv(i,j,k)+(
> a(i,j,k)*(psi(i+1,j,k)+psi(i-1,j,k)-
> 2.*psi(i,j,k)) +
> b(i,j,k)*(psi(i,j+1,k)-psi(i,j,k))-
> b(i,j-1,k)*(psi(i,j,k)-psi(i,j-1,k))+
> c(i,j,k)*(psi(i,j,k+1)-psi(i,j,k))-
> c(i,j,k-1)*(psi(i,j,k)-psi(i,j,k-1))
> )/(dx*dy*dz*rhoref(2*k)))**2.
enddo
enddo
enddo
print 102, 'psigauge', psigauge, 'deltasq',
> deltasq/(real(nx)*real(ny)*real(nz))
c Iterations
do counter=1,nofiter
C Perform one iteration step
call psiappsor(omega,pv,psi,nsq,rhoref,thetatop,
> thetabot,thetaref,coriol,ua,ub,va,vb,
> a,b,c,nx,ny,nz,dx,dy,dz)
c Adjustment
if (mod(counter,100).eq.0) then
psigauge=0.
do i=0,nx
do j=0,ny
if (psi(i,j,0).lt.psigauge) then
psigauge=psi(i,j,0)
endif
enddo
enddo
do k=0,nz
do i=0,nx
do j=0,ny
psi(i,j,k)=psi(i,j,k)-psigauge
enddo
enddo
enddo
endif
c Calculate error: control variable for the iteration
if (mod(counter,nofiter/10).eq.0) then
deltasq=0.
do k=1,nz-1
do i=1,nx-1
do j=1,ny-1
deltasq=deltasq+(-pv(i,j,k)+(
> a(i,j,k)*(psi(i+1,j,k)+psi(i-1,j,k)-
> 2.*psi(i,j,k)) +
> b(i,j,k)*(psi(i,j+1,k)-psi(i,j,k))-
> b(i,j-1,k)*(psi(i,j,k)-psi(i,j-1,k))+
> c(i,j,k)*(psi(i,j,k+1)-psi(i,j,k))-
> c(i,j,k-1)*(psi(i,j,k)-psi(i,j,k-1))
> )/(dx*dy*dz*rhoref(2*k)))**2.
enddo
enddo
enddo
print 102, 'psigauge', psigauge, 'deltasq',
> deltasq/(real(nx)*real(ny)*real(nz))
endif
enddo
return
c Format specifications
102 format (a11, ' = ',e10.3,a11, ' = ',e10.3)
end
c --------------------------------------------------------------------------------
c SOR algorithm (successive over relaxation)
c --------------------------------------------------------------------------------
subroutine psiappsor(omega,pv,psi,nsq,rhoref,thetatop,
> thetabot,thetaref,coriol,ua,ub,va,vb,
> a,b,c,nx,ny,nz,dx,dy,dz)
c Perform one relaxation step
c
c psi : Streamfunction, i.e. result of the PV inversion
c nsq,rhoref,thetaref : Reference profile
c thetatop,thetabot : Upper and lower boundary condition
c pv : quasigeostrophic potential vorticity (qgPV)
c ua,ub,va,vb : lateral boundary condition for wind
c a,b,c : Matrices for the inversion operator
c nx,ny,nz,dx,dy,dz : Grid specification
c nofiter : Number of iterations
c omega : Relaxation parameter
c coriol : Coriolis parameter
implicit none
c Declaration of subroutine parameters
integer nx,ny,nz
real pv(0:nx,0:ny,0:nz)
real psi(0:nx,0:ny,0:nz)
real nsq(0:2*nz)
real rhoref(0:2*nz)
real thetatop(0:nx,0:ny)
real thetabot(0:nx,0:ny)
real thetaref(0:2*nz)
real ua(0:nx,0:nz)
real ub(0:nx,0:nz)
real va(0:ny,0:nz)
real vb(0:ny,0:nz)
real a(0:nx,0:ny,0:nz)
real b(0:nx,0:ny,0:nz)
real c(0:nx,0:ny,0:nz)
real coriol(0:nx,0:ny)
real dx,dy,dz
real omega
c Numerical and physical parameters
real g
parameter (g=9.81)
c Auxiliary variables
integer i,j,k
real dxy,dxz,dyz,dxyz
c Set the area and volume infinitesimals for integration
dxy=dx*dy
dxz=dx*dz
dyz=dy*dz
dxyz=dx*dy*dz
c Inner
do k=1,nz-1
do i=1,nx-1
do j=1,ny-1
psi(i,j,k)=omega*(-dxyz*
> rhoref(2*k)*pv(i,j,k)+a(i,j,k)*
> (psi(i+1,j,k)+psi(i-1,j,k))+b(i,j,k)*
> psi(i,j+1,k)+b(i,j-1,k)*psi(i,j-1,k)+c(i,j,k)*
> psi(i,j,k+1)+c(i,j,k-1)*psi(i,j,k-1))/
> (2.*a(i,j,k)+b(i,j,k)+b(i,j-1,k)+c(i,j,k-1)+
> c(i,j,k))+(1.-omega)*psi(i,j,k)
enddo
enddo
enddo
c ZY plane
do k=1,nz-1
do j=1,ny-1
psi(0,j,k)=omega*(-dyz*
> rhoref(2*k)*(dx*pv(0,j,k)+va(j,k))+
> a(0,j,k)*psi(1,j,k)+
> b(0,j,k)*psi(0,j+1,k)+b(0,j-1,k)*psi(0,j-1,k)+
> c(0,j,k)*psi(0,j,k+1)+c(0,j,k-1)*psi(0,j,k-1))/
> (a(0,j,k)+b(0,j,k)+b(0,j-1,k)+c(0,j,k-1)+c(0,j,k))
> +(1.-omega)*psi(0,j,k)
c
psi(nx,j,k)=omega*(-dyz*
> rhoref(2*k)*(dx*pv(nx,j,k)-vb(j,k))+
> a(nx,j,k)*psi(nx-1,j,k)+
> b(nx,j,k)*psi(nx,j+1,k)+b(nx,j-1,k)*psi(nx,j-1,k)+
> c(nx,j,k)*psi(nx,j,k+1)+c(nx,j,k-1)*psi(nx,j,k-1))/
> (a(nx,j,k)+b(nx,j-1,k)+b(nx,j,k)+c(nx,j,k-1)+c(nx,j,k))
> +(1.-omega)*psi(nx,j,k)
enddo
enddo
c ZX plane
do k=1,nz-1
do i=1,nx-1
psi(i,0,k)=omega*(-dxz*
> rhoref(2*k)*(dy*pv(i,0,k)-ua(i,k))+
> a(i,0,k)*(psi(i+1,0,k)+psi(i-1,0,k))+
> b(i,0,k)*psi(i,1,k)+
> c(i,0,k)*psi(i,0,k+1)+c(i,0,k-1)*psi(i,0,k-1))/
> (2.*a(i,0,k)+b(i,0,k)+c(i,0,k-1)+c(i,0,k))
> +(1.-omega)*psi(i,0,k)
c
psi(i,ny,k)=omega*(-dxz*
> rhoref(2*k)*(dy*pv(i,ny,k)+ub(i,k))+
> a(i,ny-1,k)*(psi(i+1,ny,k)+psi(i-1,ny,k))+
> b(i,ny-1,k)*psi(i,ny-1,k)+
> c(i,ny-1,k)*psi(i,ny,k+1)+c(i,ny-1,k-1)*
> psi(i,ny,k-1))/(2.*a(i,ny-1,k)+b(i,ny-1,k)+
> c(i,ny-1,k-1)+c(i,ny-1,k))
> +(1.-omega)*psi(i,ny,k)
enddo
enddo
c XY plane
do i=1,nx-1
do j=1,ny-1
psi(i,j,0)=omega*(-dxy*rhoref(0)*(
> dz*pv(i,j,0)+g*coriol(i,j)*thetabot(i,j)/
> (nsq(0)*thetaref(0)))+
> a(i,j,0)*(psi(i+1,j,0)+psi(i-1,j,0))+
> b(i,j,0)*psi(i,j+1,0)+b(i,j-1,0)*psi(i,j-1,0)+
> c(i,j,0)*psi(i,j,1))/
> (2.*a(i,j,0)+b(i,j-1,0)+b(i,j,0)+c(i,j,0))
> +(1.-omega)*psi(i,j,0)
c
psi(i,j,nz)=omega*(-dxy*rhoref(2*nz)*(
> dz*pv(i,j,nz)-g*coriol(i,j)*thetatop(i,j)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(i,j,nz)*(psi(i+1,j,nz)+psi(i-1,j,nz))+
> b(i,j,nz)*psi(i,j+1,nz)+b(i,j-1,nz)*psi(i,j-1,nz)+
> c(i,j,nz-1)*psi(i,j,nz-1))/
> (2.*a(i,j,nz)+b(i,j-1,nz)+b(i,j,nz)+c(i,j,nz-1))
> +(1.-omega)*psi(i,j,nz)
enddo
enddo
c Y edges
do j=1,ny-1
psi(0,j,0)=omega*(-dy*rhoref(0)*(dxz*pv(0,j,0)+
> dz*va(j,0)+dx*g*coriol(0,j)*thetabot(0,j)/
> (nsq(0)*thetaref(0)))+
> a(0,j,0)*psi(1,j,0)+
> b(0,j,0)*psi(0,j+1,0)+b(0,j-1,0)*psi(0,j-1,0)+
> c(0,j,0)*psi(0,j,1))/
> (a(0,j,0)+b(0,j-1,0)+b(0,j,0)+c(0,j,0))
> +(1.-omega)*psi(0,j,0)
c
psi(nx,j,0)=omega*(-dy*rhoref(0)*(dxz*pv(nx,j,0)-
> dz*vb(j,0)+dx*g*coriol(nx,j)*thetabot(nx,j)/
> (nsq(0)*thetaref(0)))+
> a(nx,j,0)*psi(nx-1,j,0)+
> b(nx,j,0)*psi(nx,j+1,0)+b(nx,j-1,0)*psi(nx,j-1,0)+
> c(nx,j,0)*psi(nx,j,1))/
> (a(nx,j,0)+b(nx,j-1,0)+b(nx,j,0)+c(nx,j,0))
> +(1.-omega)*psi(nx,j,0)
c
psi(0,j,nz)=omega*(-dy*rhoref(2*nz)*(dxz*pv(0,j,nz)+
> dz*va(j,nz)-dx*g*coriol(0,j)*thetatop(0,j)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(0,j,nz)*psi(1,j,nz)+
> b(0,j,nz)*psi(0,j+1,nz)+b(0,j-1,nz)*psi(0,j-1,nz)+
> c(0,j,nz-1)*psi(0,j,nz-1))/
> (a(0,j,nz)+b(0,j-1,nz)+b(0,j,nz)+c(0,j,nz-1))
> +(1.-omega)*psi(0,j,nz)
c
psi(nx,j,nz)=omega*(-dy*rhoref(2*nz)*(dxz*pv(nx,j,nz)-
> dz*vb(j,nz)-dx*g*coriol(nx,j)*thetatop(nx,j)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(nx,j,nz)*psi(nx-1,j,nz)+
> b(nx,j,nz)*psi(nx,j+1,nz)+b(nx,j-1,nz)*psi(nx,j-1,nz)+
> c(nx,j,nz-1)*psi(nx,j,nz-1))/
> (a(nx,j,nz)+b(nx,j-1,nz)+b(nx,j,nz)+c(nx,j,nz-1))
> +(1.-omega)*psi(nx,j,nz)
enddo
c X edges
do i=1,nx-1
psi(i,0,0)=omega*(-dx*rhoref(0)*(dyz*pv(i,0,0)-
> dz*ua(i,0)+dy*g*coriol(i,0)*thetabot(i,0)/
> (nsq(0)*thetaref(0)))+
> a(i,0,0)*(psi(i+1,0,0)+psi(i-1,0,0))+
> b(i,0,0)*psi(i,1,0)+
> c(i,0,0)*psi(i,0,1))/
> (2.*a(i,0,0)+b(i,0,0)+c(i,0,0))
> +(1.-omega)*psi(i,0,0)
c
psi(i,ny,0)=omega*(-dx*rhoref(0)*(dyz*pv(i,ny,0)+
> dz*ub(i,0)+dy*g*coriol(i,ny)*thetabot(i,ny)/
> (nsq(0)*thetaref(0)))+
> a(i,ny,0)*(psi(i+1,ny,0)+psi(i-1,ny,0))+
> b(i,ny-1,0)*psi(i,ny-1,0)+
> c(i,ny,0)*psi(i,ny,1))/
> (2.*a(i,ny,0)+b(i,ny-1,0)+c(i,ny,0))
> +(1.-omega)*psi(i,ny,0)
c
psi(i,0,nz)=omega*(-dx*rhoref(2*nz)*(dyz*pv(i,0,nz)-
> dz*ua(i,nz)-dy*g*coriol(i,0)*thetatop(i,0)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(i,0,nz)*(psi(i+1,0,nz)+psi(i-1,0,nz))+
> b(i,0,nz)*psi(i,1,nz)+
> c(i,0,nz-1)*psi(i,0,nz-1))/
> (2.*a(i,0,nz)+b(i,0,nz)+c(i,0,nz-1))
> +(1.-omega)*psi(i,0,nz)
c
psi(i,ny,nz)=omega*(-dx*rhoref(2*nz)*(dyz*pv(i,ny,nz)+
> dz*ub(i,nz)-dy*g*coriol(i,ny)*thetatop(i,ny)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(i,ny,nz)*(psi(i+1,ny,nz)+psi(i-1,ny,nz))+
> b(i,ny-1,nz)*psi(i,ny-1,nz)+
> c(i,ny,nz-1)*psi(i,ny,nz-1))/
> (2.*a(i,ny,nz)+b(i,ny-1,nz)+c(i,ny,nz-1))
> +(1.-omega)*psi(i,ny,nz)
enddo
c Z edges
do k=1,nz-1
psi(0,0,k)=omega*(-dz*rhoref(2*k)*(dxy*pv(0,0,k)+
> dy*va(0,k)-dx*ua(0,k))+
> a(0,0,k)*psi(1,0,k)+
> b(0,0,k)*psi(0,1,k)+
> c(0,0,k)*psi(0,0,k+1)+c(0,0,k-1)*psi(0,0,k-1))/
> (a(0,0,k)+b(0,0,k)+c(0,0,k-1)+c(0,0,k))
> +(1.-omega)*psi(0,0,k)
c
psi(nx,0,k)=omega*(-dz*rhoref(2*k)*(dxy*pv(nx,0,k)-
> dy*vb(0,k)-dx*ua(nx,k))+
> a(nx,0,k)*psi(nx-1,0,k)+
> b(nx,0,k)*psi(nx,1,k)+
> c(nx,0,k)*psi(nx,0,k+1)+c(nx,0,k-1)*psi(nx,0,k-1))/
> (a(nx,0,k)+b(nx,0,k)+c(nx,0,k-1)+c(nx,0,k))
> +(1.-omega)*psi(nx,0,k)
c
psi(0,ny,k)=omega*(-dz*rhoref(2*k)*(dxy*pv(0,ny,k)+
> dy*va(ny,k)+dx*ub(0,k))+
> a(0,ny,k)*psi(1,ny,k)+
> b(0,ny-1,k)*psi(0,ny-1,k)+
> c(0,ny,k)*psi(0,ny,k+1)+c(0,ny,k-1)*psi(0,ny,k-1))/
> (a(0,ny,k)+b(0,ny-1,k)+c(0,ny,k-1)+c(0,ny,k))
> +(1.-omega)*psi(0,ny,k)
c
psi(nx,ny,k)=omega*(-dz*rhoref(2*k)*(dxy*pv(nx,ny,k)-
> dy*vb(ny,k)+dx*ub(nx,k))+
> a(nx,ny,k)*psi(nx-1,ny,k)+
> b(nx,ny-1,k)*psi(nx,ny-1,k)+
> c(nx,ny,k)*psi(nx,ny,k+1)+c(nx,ny,k-1)*psi(nx,ny,k-1))/
> (a(nx,ny,k)+b(nx,ny-1,k)+c(nx,ny,k-1)+c(nx,ny,k))
> +(1.-omega)*psi(nx,ny,k)
enddo
c Points
psi(0,0,0)=omega*(-rhoref(0)*(dxyz*pv(0,0,0)+dyz*va(0,0)-
> dxz*ua(0,0)+dxy*g*coriol(0,0)*thetabot(0,0)/
> (nsq(0)*thetaref(0)))+
> a(0,0,0)*psi(1,0,0)+
> b(0,0,0)*psi(0,1,0)+
> c(0,0,0)*psi(0,0,1))/
> (a(0,0,0)+b(0,0,0)+c(0,0,0))+
> (1.-omega)*psi(0,0,0)
c
psi(nx,0,0)=omega*(-rhoref(0)*(dxyz*pv(nx,0,0)-dyz*vb(0,0)-
> dxz*ua(nx,0)+dxy*g*coriol(nx,0)*thetabot(nx,0)/
> (nsq(0)*thetaref(0)))+
> a(nx,0,0)*psi(nx-1,0,0)+
> b(nx,0,0)*psi(nx,1,0)+
> c(nx,0,0)*psi(nx,0,1))/
> (a(nx,0,0)+b(nx,0,0)+c(nx,0,0))+
> (1.-omega)*psi(nx,0,0)
c
psi(0,ny,0)=omega*(-rhoref(0)*(dxyz*pv(0,ny,0)+dyz*va(ny,0)+
> dxz*ub(0,0)+dxy*g*coriol(0,ny)*thetabot(0,ny)/
> (nsq(0)*thetaref(0)))+
> a(0,ny,0)*psi(1,ny,0)+
> b(0,ny-1,0)*psi(0,ny-1,0)+
> c(0,ny,0)*psi(0,ny,1))/
> (a(0,ny,0)+b(0,ny-1,0)+c(0,ny,0))+
> (1.-omega)*psi(0,ny,0)
c
psi(nx,ny,0)=omega*(-rhoref(0)*(dxyz*pv(nx,ny,0)-dyz*vb(ny,0)+
> dxz*ub(nx,0)+dxy*g*coriol(nx,ny)*thetabot(nx,ny)/
> (nsq(0)*thetaref(0)))+
> a(nx,ny,0)*psi(nx-1,ny,0)+
> b(nx,ny-1,0)*psi(nx,ny-1,0)+
> c(nx,ny,0)*psi(nx,ny,1))/
> (a(nx,ny,0)+b(nx,ny-1,0)+c(nx,ny,0))+
> (1.-omega)*psi(nx,ny,0)
c
psi(0,0,nz)=omega*(-rhoref(2*nz)*(dxyz*pv(0,0,nz)+dyz*va(0,nz)-
> dxz*ua(0,nz)-dxy*g*coriol(0,0)*thetatop(0,0)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(0,0,nz)*psi(1,0,nz)+
> b(0,0,nz)*psi(0,1,nz)+
> c(0,0,nz-1)*psi(0,0,nz-1))/
> (a(0,0,nz)+b(0,0,nz)+c(0,0,nz-1))+
> (1.-omega)*psi(0,0,nz)
c
psi(nx,0,nz)=omega*(-rhoref(2*nz)*(dxyz*pv(nx,0,nz)-dyz*vb(0,nz)
> -dxz*ua(nx,nz)-dxy*g*coriol(nx,0)*thetatop(nx,0)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(nx,0,nz)*psi(nx-1,0,nz)+
> b(nx,0,nz)*psi(nx,1,nz)+
> c(nx,0,nz-1)*psi(nx,0,nz-1))/
> (a(nx,0,nz)+b(nx,0,nz)+c(nx,0,nz-1))+
> (1.-omega)*psi(nx,0,nz)
c
psi(0,ny,nz)=omega*(-rhoref(2*nz)*(dxyz*pv(0,ny,nz)+
> dyz*va(ny,nz)+dxz*ub(0,nz)-
> dxy*g*coriol(0,ny)*thetatop(0,ny)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(0,ny,nz)*psi(1,ny,nz)+
> b(0,ny-1,nz)*psi(0,ny-1,nz)+
> c(0,ny,nz-1)*psi(0,ny,nz-1))/
> (a(0,ny,nz)+b(0,ny-1,nz)+c(0,ny,nz-1))+
> (1.-omega)*psi(0,ny,nz)
c
psi(nx,ny,nz)=omega*(-rhoref(2*nz)*(dxyz*pv(nx,ny,nz)-
> dyz*vb(ny,nz)+dxz*ub(nx,nz)-
> dxy*g*coriol(nx,ny)*thetatop(nx,ny)/
> (nsq(2*nz)*thetaref(2*nz)))+
> a(nx,ny,nz)*psi(nx-1,ny,nz)+
> b(nx,ny-1,nz)*psi(nx,ny-1,nz)+
> c(nx,ny,nz-1)*psi(nx,ny,nz-1))/
> (a(nx,ny,nz)+b(nx,ny-1,nz)+c(nx,ny,nz-1))+
> (1.-omega)*psi(nx,ny,nz)
c
end
c --------------------------------------------------------------------------------
c Init matrix elements for the inversion
c --------------------------------------------------------------------------------
subroutine matrixel(a,b,c,coriol,nx,ny,nz,nsq,rhoref,dx,dy,dz)
c Define the coefficients for the inversion problem (see page 119ff in Rene's
c dissertation).
implicit none
c Declaration of subroutine parameters
integer nx,nz,ny
real a (0:nx,0:ny,0:nz)
real b (0:nx,0:ny,0:nz)
real c (0:nx,0:ny,0:nz)
real coriol(0:nx,0:ny)
real nsq (0:2*nz)
real rhoref(0:2*nz)
real dx,dy,dz
c Auxiliary variables
integer i,j,k
c Calculate coefficients
do i=0,nx
do j=0,ny
do k=0,nz
a(i,j,k)=dy*dz*rhoref(2*k)/(dx*coriol(i,j))
if (j.lt.ny) then
b(i,j,k)=dx*dz*rhoref(2*k)/
> (dy*0.5*(coriol(i,j)+coriol(i,j+1)))
else
b(i,j,k)=0.
endif
if (k.lt.nz) then
c(i,j,k)=dx*dy*rhoref(2*k+1)*coriol(i,j)/
> (dz*nsq(2*k+1))
else
c(i,j,k)=0.
endif
enddo
enddo
enddo
end