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PROGRAM create_startf
c **************************************************************
c * Create a <startfile> for <lagrangto>. It can be chosen *
c * whether to start from an isentropic or an isobaric *
c * surface. The starting points are equidistantly distributed *
c * Michael Sprenger / Autumn 2004 *
c **************************************************************
implicit none
c --------------------------------------------------------------
c Set parameters
c --------------------------------------------------------------
c Maximum number of starting positions
integer nmax
parameter (nmax=2000000)
c Maximum number of model levels
integer nlevmax
parameter (nlevmax=200)
c Grid constant (distance in km corresponding to 1 deg at the equator)
real deltat
parameter (deltat=111.)
c Mathematical constant (conversion degree -> radian)
real pi180
parameter (pi180=3.14159/180.)
c Numerical epsilon
real eps
parameter (eps=0.00001)
c --------------------------------------------------------------
c Set variables
c --------------------------------------------------------------
c Filenames and output format
character*80 pfile0,pfile1 ! P filenames
character*80 sfile0,sfile1 ! S filenames
character*80 topofile ! filename containing bathymetrie
character*80 ofile ! Output filename
integer oformat ! Output format
real timeshift ! Time shift relative to data files <*0>
real timeinc ! Time increment between input files
c Horizontal grid
character*80 hmode ! Horizontale mode
real lat1,lat2,lon1,lon2 ! Lat/lon boundaries
real ds,dlon,dlat ! Distance and lat/lon shifts
character*80 hfile ! Filename
integer hn ! Number of entries in lat/lon list
real latlist(nmax) ! List of latitudes
real lonlist(nmax) ! List of longitudes
integer pn ! Number of entries in lat/lon poly
real latpoly(500) ! List of polygon latitudes
real lonpoly(500) ! List of polygon longitudes
real loninpoly,latinpoly ! Lon/lat inside polygon
character*80 regionf ! Region file
integer iregion ! Region number
real xcorner(4),ycorner(4) ! Vertices of region
c Vertical grid
character*80 vmode ! Vertical mode
real lev1,lev2,levlist(nmax) ! Single levels, and list of levels
character*80 vfile ! Filename
integer vn ! Number of entries
c Unit of vertical axis
character*80 umode ! Unit of vertical axis
c Flag for 'no time check'
character*80 timecheck ! Either 'no' or 'yes'
c List of all starting positions
integer start_n ! Number of coordinates
real start_lat(nmax) ! Latitudes
real start_lon(nmax) ! Longitudes
real start_lev(nmax) ! Levels (depending on vertical unit)
real start_hgt(nmax) ! Level in hPa
integer reftime(6) ! Reference time
character*80 vars(10) ! Name of output fields (time,lon,lat,p)
real,allocatable, dimension (:,:,:) :: tra ! Trajectories (ntra,ntim,ncol)
real latmin,latmax
real lonmin,lonmax
real hgtmin,hgtmax
c Grid description
real pollon,pollat ! Longitude/latitude of pole
real xmin,xmax ! Zonal grid extension
real ymin,ymax ! Meridional grid extension
integer nx,ny,nz ! Grid dimensions
real dx,dy ! Horizontal grid resolution
real,allocatable, dimension (:,:,:) :: z ! 3d height
real,allocatable, dimension (:,:,:) :: topo ! bathymetrie
real,allocatable, dimension (:,:) :: zs ! surface height
real,allocatable, dimension (:,:) :: dummy2 ! 2d dummy array
real,allocatable, dimension (:,:,:) :: pr ! 3d pressure
real,allocatable, dimension (:,:) :: prs ! surface pressure
real,allocatable, dimension (:,:,:) :: th ! 3d potential temperature
real,allocatable, dimension (:,:) :: ths ! surface poential temperature
real,allocatable, dimension (:,:,:) :: pv ! 3d potential vorticity
real,allocatable, dimension (:,:) :: pvs ! surface potential vorticiy
real,allocatable, dimension (:,:,:) :: in ! 3d 'dummy' array with vertical indices
character*80 varname ! Name of input variable
integer fid,bid ! File identifier
real stagz ! Vertical staggering
real mdv ! Missing data values
real tstart,tend ! Time on P and S file
real rid,rjd,rkd ! Real grid position
c Auxiliary variable
integer i,j,k
real lon,lat
real rd
integer stat,flag
real tmp1,tmp2
real tfrac,frac
real radius,dist
character*80 string
character*80 selectstr
character*80 umode_save
real,allocatable, dimension (:,:,:) :: fld0
real,allocatable, dimension (:,:,:) :: fld1
real,allocatable, dimension (:,: ) :: sfc0
real,allocatable, dimension (:,:) :: sfc1
c Externals
real int_index3 ! 3d interpolation
external int_index3
real sdis ! Speherical distance
external sdis
integer inregion ! In/out of region
external inrehion
c ------------------------------------------------------------------
c Start of program, Read parameters
c ------------------------------------------------------------------
c Write start message
print*,'========================================================='
print*,' *** START OF PROGRAM CREATE_STARTF ***'
print*
c Read parameter file
open(10,file='create_startf.param')
c Input P and S file
read(10,*) pfile0,pfile1
read(10,*) sfile0,sfile1
read(10,*) ofile
c Read name of region file
read(10,*) regionf
c Reference time
do i=1,6
read(10,*) reftime(i)
enddo
c Time shift relative to data files <pfile0,sfile0> - format (hh.mm)
read(10,*) timeshift
c Read timeincrement between input files
read(10,*) timeinc
c Parameters for horizontal grid
read(10,*) hmode
if ( hmode.eq.'file' ) then ! from file
read(10,*) hfile
elseif ( hmode.eq.'line' ) then ! along a line
read(10,*) lon1,lon2,lat1,lat2,hn
elseif ( hmode.eq.'box.eqd' ) then ! box: 2d equidistant
read(10,*) lon1,lon2,lat1,lat2,ds
elseif ( hmode.eq.'box.grid' ) then ! box: 2d grid
read(10,*) lon1,lon2,lat1,lat2
elseif ( hmode.eq.'point' ) then ! single point
read(10,*) lon1,lat1
elseif ( hmode.eq.'shift' ) then ! centre + shifted
read(10,*) lon1,lat1,dlon,dlat
elseif ( hmode.eq.'polygon.eqd' ) then ! polygon: 2d equidistant
read(10,*) hfile,ds
elseif ( hmode.eq.'polygon.grid' ) then ! polygon: 2d grid
read(10,*) hfile
elseif ( hmode.eq.'circle.eqd' ) then ! circle: 2d equidistant
read(10,*) lon1,lat1,radius,ds
elseif ( hmode.eq.'circle.grid' ) then ! circle: 2d grid
read(10,*) lon1,lat1,radius
elseif ( hmode.eq.'region.eqd' ) then ! region: 2d equidistant
read(10,*) iregion,ds
elseif ( hmode.eq.'region.grid' ) then ! iregion: 2d grid
read(10,*) iregion
else
print*,' ERROR: horizontal mode not supported ',trim(hmode)
stop
endif
c Parameters for vertical grid
read(10,*) vmode
if ( vmode.eq.'file') then ! from file
read(10,*) vfile
elseif ( vmode.eq.'level' ) then ! single level (explicit command)
read(10,*) lev1
elseif ( vmode.eq.'list') then ! a list
read(10,*) vn
read(10,*) (levlist(i),i=1,vn)
elseif ( vmode.eq.'profile') then ! a profile
read(10,*) lev1,lev2,vn
elseif ( vmode.eq.'grid') then ! grid points
read(10,*) lev1,lev2
else
print*,' ERROR: vertical mode not supported ',trim(vmode)
stop
endif
c Read units of vertical axis
read(10,*) umode
if ( ( umode.ne.'m' ).and.
> ( umode.ne.'m,agl' ).and.
> ( umode.ne.'INDEX' ) )
> then
print*,' ERROR: unit not supported ',trim(umode)
stop
endif
c Read selection criterion (dummy read)
read(10,*) selectstr
c Read flag for 'no time check'
read(10,*) timecheck
c Close parameter file
close(10)
c Decide which output format is used (1..4: trajectory format, -1: triple list)
call mode_tra(oformat,ofile)
c Decide whether all lat/lon/lev coordaintes are read from one file
if ( (hmode.eq.'file').and.(vmode.eq.'nil') ) then
hmode='file3'
elseif ( (hmode.eq.'file').and.(vmode.ne.'nil') ) then
hmode='file2'
endif
c Convert timeshift (hh.mm) into a fractional time shift
call hhmm2frac(timeshift,tfrac)
if (tfrac.gt.0.) then
tfrac=tfrac/timeinc
else
tfrac=0.
endif
c Read the region coordinates if needed
if ( (hmode.eq.'region.eqd' ).or.
> (hmode.eq.'region.grid') ) then
open(10,file=regionf)
50 read(10,*,end=51) string
if ( string(1:1).ne.'#' ) then
call regionsplit(string,i,xcorner,ycorner)
if ( i.eq.iregion ) goto 52
endif
goto 50
51 close(10)
print*,' ERROR: region ',iregion,' not found on ',trim(regionf)
stop
52 continue
endif
c Write some status information
print*,'---- INPUT PARAMETERS -----------------------------------'
print*
if ( timeshift.gt.0. ) then
print*,' P file : ',trim(pfile0),
> ' ',
> trim(pfile1)
print*,' S file : ',trim(sfile0),
> ' ',
> trim(sfile1)
else
print*,' P file : ',trim(pfile0)
print*,' S file : ',trim(sfile0)
endif
print*,' Output file : ',trim(ofile)
print*
if (oformat.eq.-1) then
print*,' Output format : (lon,lat,lev)-list'
else
print*,' Output format : ',oformat
endif
print*
print*,' Reference time (year) : ',reftime(1)
print*,' (month) : ',reftime(2)
print*,' (day) : ',reftime(3)
print*,' (hour) : ',reftime(4)
print*,' (min) : ',reftime(5)
print*,' Time range : ',reftime(6)
print*
print*,' Time shift : ',timeshift,' + ',
> trim(pfile0)
print*,' Region file : ',trim(regionf)
print*
print*,' hmode : ',trim(hmode)
if ( hmode.eq.'file2' ) then
print*,' filename [lat/lon] : ',trim(hfile)
elseif ( hmode.eq.'file3' ) then
print*,' filename [lat/lon/lev] : ',trim(hfile)
elseif ( hmode.eq.'line' ) then
write(*,'(a30,4f10.2,i4)')
> ' lon1,lon2,lat1,lat2,n : ',lon1,lon2,lat1,lat2,hn
elseif ( hmode.eq.'box.eqd' ) then
write(*,'(a30,5f10.2)')
> ' lon1,lon2,lat1,lat2,ds : ',lon1,lon2,lat1,lat2,ds
elseif ( hmode.eq.'box.grid' ) then
write(*,'(a30,4f10.2)')
> ' lon1,lon2,lat1,lat2 : ',lon1,lon2,lat1,lat2
elseif ( hmode.eq.'point' ) then
print*,' lon,lat : ',lon1,lat1
elseif ( hmode.eq.'shift' ) then
write(*,'(a30,4f10.2)')
> ' lon,lat,dlon,dlat : ',lon1,lat1,dlon,dlat
elseif ( hmode.eq.'polygon.eqd' ) then
write(*,'(a30,a10,f10.2)')
> ' hfile, ds : ',trim(hfile),ds
elseif ( hmode.eq.'polygon.grid' ) then
write(*,'(a30,a10)')
> ' hfile : ',trim(hfile)
elseif ( hmode.eq.'circle.eqd' ) then
write(*,'(a30,4f10.2)')
> ' lonc,latc,radius, ds : ',lon1,lat1,radius,ds
elseif ( hmode.eq.'circle.grid' ) then
write(*,'(a30,3f10.2)')
> ' lonc,latc,radius : ',lon1,lat1,radius
elseif ( hmode.eq.'region.eqd' ) then
write(*,'(a30,i4,1f10.2)')
> ' iregion, ds : ',iregion,ds
write(*,'(a30,4f10.2)')
> ' xcorner : ',(xcorner(i),i=1,4)
write(*,'(a30,4f10.2)')
> ' ycorner : ',(ycorner(i),i=1,4)
elseif ( hmode.eq.'region.grid' ) then
write(*,'(a30,i4)')
> ' iregion : ',iregion
write(*,'(a30,4f10.2)')
> ' xcorner : ',(xcorner(i),i=1,4)
write(*,'(a30,4f10.2)')
> ' ycorner : ',(ycorner(i),i=1,4)
endif
print*
print*,' vmode : ',trim(vmode)
if ( vmode.eq.'file') then
print*,' filename : ',trim(vfile)
elseif ( vmode.eq.'level' ) then
print*,' level : ',lev1
elseif ( vmode.eq.'list') then
print*,' n : ',vn
print*,' level(i) : ',(levlist(i),i=1,vn)
elseif ( vmode.eq.'profile') then
print*,' lev1,lev2,n : ',lev1,lev2,vn
elseif ( vmode.eq.'grid') then
print*,' lev1,lev2 : ',lev1,lev2
endif
print*
print*,' umode : ',trim(umode)
print*
print*,' time check : ',trim(timecheck)
print*
c ------------------------------------------------------------------
c Read grid parameters from inital files
c ------------------------------------------------------------------
c Get the time of the first and second data file
tstart = -timeshift ! Format hh.mm
call hhmm2frac(tstart,frac)
frac = frac + timeinc
call frac2hhmm(frac,tend) ! Format hh.mm
c Convert timeshift (hh.mm) into a fractional time shift
tfrac=real(int(timeshift))+
> 100.*(timeshift-real(int(timeshift)))/60.
if (tfrac.gt.0.) then
tfrac=tfrac/timeinc
else
tfrac=0.
endif
c Read the constant grid parameters (nx,ny,nz,xmin,xmax,ymin,ymax,
c pollon,pollat) The negative <-fid> of the file identifier is used
c as a flag for parameter retrieval
varname = 'U'
nx = 1
ny = 1
nz = 1
call input_open (fid,pfile0)
call input_grid (-fid,varname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> tstart,pollon,pollat,rd,rd,nz,rd,timecheck)
call input_close(fid)
c Check whether region coordinates are within the domain
if ( (hmode.eq.'region.eqd' ).or.
> (hmode.eq.'region.grid') ) then
do i=1,4
if ( (xcorner(i).lt.xmin).or.
> (ycorner(i).lt.ymin).or.
> (xcorner(i).gt.xmax).or.
> (ycorner(i).gt.ymax) )
> then
print*,' ERROR: region not included in data domain...'
print*,' ',trim(string)
print*,' ',(xcorner(j),j=1,4)
print*,' ',(ycorner(j),j=1,4)
stop
endif
enddo
endif
C Check if the number of levels is too large
if (nz.gt.nlevmax) goto 993
c Allocate memory for 3d arrays: height, topo
allocate(z(nx,ny,nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array z ***'
allocate(zs(nx,ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array zs **'
allocate(in(nx,ny,nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array in ***'
allocate(topo(nx,ny,nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array topo ***'
c Allocate memory for temporary arrays for time interpolation
allocate(fld0(nx,ny,nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array tmp0 ***'
allocate(fld1(nx,ny,nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array tmp1 ***'
allocate(sfc0(nx,ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array sfc0 ***'
allocate(sfc1(nx,ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array sfc1 ***'
c Auxillary
allocate(dummy2(nx,ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array dummy2 ***'
c ------ Index -----------------------------------------------------
c Init the dummy array with vertical index; and the vertical height
if ( umode.eq.'INDEX' ) then
do i=1,nx
do j=1,ny
do k=1,nz
in(i,j,k) = real(k)
enddo
enddo
enddo
call input_open (fid,pfile0)
varname = 'lev'
call input_grid
> (fid,varname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> tend,pollon,pollat,z,zs,nz,stagz,timecheck)
endif
c ------ Height --------------------------------------------------
c Read height and topography from first data file
if ( (umode.eq.'m').or.(umode.eq.'m,agl') ) then
call input_open (fid,pfile0)
varname = 'lev'
call input_grid
> (fid,varname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> tend,pollon,pollat,z,zs,nz,stagz,timecheck)
call input_close(fid)
endif
c ------- Bathymetrie ---------------------------------------------
topofile='bath'
call input_open(bid,topofile)
varname='BATH'
call input_grid
> (bid,varname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> tend,pollon,pollat,topo,dummy2,nz,stagz,timecheck)
call input_close(bid)
c Write some status information
print*,'---- CONSTANT GRID PARAMETERS ---------------------------'
print*
print*,' xmin,xmax : ',xmin,xmax
print*,' ymin,ymax : ',ymin,ymax
print*,' zmin,zmax : ',zs(1,1),z(1,1,nz)
print*,' dx,dy : ',dx,dy
print*,' pollon,pollat : ',pollon,pollat
print*,' nx,ny,nz : ',nx,ny,nz
print*
print*,' Height loaded : ',trim(pfile0)
print*
c ------------------------------------------------------------------
c Determine the expanded list of starting coordinates
c ------------------------------------------------------------------
c Write some status information
print*,'---- EXPAND LIST OF STARTING POSITIONS -----------------'
print*
c ------ Read lat/lon/lev from <hfile> -----------------------------
if ( hmode.eq.'file3' ) then
start_n = 0
open(10,file=hfile)
100 continue
start_n = start_n + 1
read(10,*,end=101) start_lon(start_n),
> start_lat(start_n),
> start_lev(start_n)
goto 100
101 continue
start_n = start_n - 1
close(10)
goto 400
endif
c ------ Get lat/lon (horizontal) coordinates ---------------------
c Read lat/lon from <hfile>
if ( hmode.eq.'file2' ) then
hn = 0
open(10,file=hfile)
200 continue
hn = hn + 1
read(10,*,end=201) lonlist(hn),
> latlist(hn)
goto 200
201 continue
hn = hn - 1
close(10)
endif
c Get lat/lon along a line (linear in lat/lon space)
if ( hmode.eq.'line' ) then
do i=1,hn
lonlist(i) = lon1 + real(i-1)/real(hn-1)*(lon2-lon1)
latlist(i) = lat1 + real(i-1)/real(hn-1)*(lat2-lat1)
enddo
endif
c Lat/lon box: equidistant
if ( hmode.eq.'box.eqd' ) then
hn = 0
lat = lat1
do while ( lat.le.lat2 )
lon = lon1
do while ( lon.le.lon2 )
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
lon = lon+ds/(deltat*cos(pi180*lat))
enddo
lat = lat+ds/deltat
enddo
endif
c Lat/lon box: grid
if ( hmode.eq.'box.grid' ) then
hn = 0
do j=1,ny
do i=1,nx
lon = xmin + real(i-1) * dx
lat = ymin + real(j-1) * dy
if ( (lon.ge.lon1).and.(lon.le.lon2).and.
> (lat.ge.lat1).and.(lat.le.lat2) )
> then
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
endif
enddo
enddo
endif
c Get single starting point
if ( hmode.eq.'point' ) then
hn = 1
lonlist(hn) = lon1
latlist(hn) = lat1
endif
c Get shifted and central starting point
if ( hmode.eq.'shift' ) then
hn = 5
lonlist(1) = lon1
latlist(1) = lat1
lonlist(2) = lon1+dlon
latlist(2) = lat1
lonlist(3) = lon1-dlon
latlist(3) = lat1
lonlist(4) = lon1
latlist(4) = lat1+dlat
lonlist(5) = lon1
latlist(5) = lat1-dlat
endif
c Lat/lon polygon: grid
if ( hmode.eq.'polygon.grid' ) then
c Read list of polygon coordinates
pn = 0
open(10,file=hfile)
read(10,*) loninpoly,latinpoly
210 continue
pn = pn + 1
read(10,*,end=211) lonpoly(pn),
> latpoly(pn)
print*,pn,lonpoly(pn),latpoly(pn)
goto 210
211 continue
pn = pn - 1
close(10)
c Define the polygon boundaries
call DefSPolyBndry(latpoly,lonpoly,pn,latinpoly,loninpoly)
c Get the grid points inside the polygon
hn = 0
do j=1,ny
do i=1,nx
lon = xmin + real(i-1) * dx
lat = ymin + real(j-1) * dy
call LctPtRelBndry(lat,lon,flag)
if ( (flag.eq.1).or.(flag.eq.2) ) then
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
endif
enddo
enddo
endif
c Lat/lon polygon: equidistant
if ( hmode.eq.'polygon.eqd' ) then
c Read list of polygon coordinates
pn = 0
open(10,file=hfile)
read(10,*) loninpoly,latinpoly
220 continue
pn = pn + 1
read(10,*,end=221) lonpoly(pn),
> latpoly(pn)
goto 220
221 continue
pn = pn - 1
close(10)
c Define the polygon boundaries
call DefSPolyBndry(latpoly,lonpoly,pn,latinpoly,loninpoly)
c Get the grid points inside the polygon
hn = 0
lat = -90.
do while ( lat.le.90. )
lon = -180.
do while ( lon.lt.180. )
call LctPtRelBndry(lat,lon,flag)
if ( (flag.eq.1).or.(flag.eq.2) ) then
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
endif
lon = lon+ds/(deltat*cos(pi180*lat))
enddo
lat = lat+ds/deltat
enddo
endif
c Circle: equidistant
if ( hmode.eq.'circle.eqd' ) then
hn = 0
lat = ymin
do while ( lat.le.ymax )
lon = xmin
do while ( lon.le.xmax )
dist = sdis(lon1,lat1,lon,lat)
if ( dist.le.radius ) then
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
endif
lon = lon+ds/(deltat*cos(pi180*lat))
enddo
lat = lat+ds/deltat
enddo
endif
c Circle: grid
if ( hmode.eq.'circle.grid' ) then
hn = 0
do j=1,ny
do i=1,nx
lon = xmin + real(i-1) * dx
lat = ymin + real(j-1) * dy
dist = sdis(lon1,lat1,lon,lat)
if ( dist.le.radius ) then
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
endif
enddo
enddo
endif
c Region: equidistant
if ( hmode.eq.'region.eqd' ) then
hn = 0
lat = ymin
do while ( lat.le.ymax )
lon = xmin
do while ( lon.le.xmax )
flag = inregion(lon,lat,xcorner,ycorner)
if ( flag.eq.1 ) then
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
endif
lon = lon+ds/(deltat*cos(pi180*lat))
enddo
lat = lat+ds/deltat
enddo
endif
c Region: grid
if ( hmode.eq.'region.grid' ) then
hn = 0
do j=1,ny
do i=1,nx
lon = xmin + real(i-1) * dx
lat = ymin + real(j-1) * dy
flag = inregion(lon,lat,xcorner,ycorner)
if ( flag.eq.1 ) then
hn = hn+1
lonlist(hn) = lon
latlist(hn) = lat
endif
enddo
enddo
endif
c ------ Get lev (vertical) coordinates -------------------------
c Read level list from file
if ( vmode.eq.'file' ) then
vn = 0
open(10,file=vfile)
300 continue
vn = vn + 1
read(10,*,end=301) levlist(vn)
goto 300
301 continue
vn = vn - 1
close(10)
endif
c Get single starting level
if ( vmode.eq.'level' ) then
vn = 1
levlist(vn) = lev1
endif
c Get level profile
if ( vmode.eq.'profile' ) then
do i=1,vn
levlist(i) = lev1 + real(i-1)/real(vn-1)*(lev2-lev1)
enddo
endif
c Get all grid points in a layer: at the moment set the list of levels to
c all indices from 1 to nz; later the correct subset of indices will be chosen
if ( vmode.eq.'grid' ) then
vn = nz
do i=1,vn
levlist(i) = real(i)
enddo
umode_save = umode
umode = 'INDEX'
endif
c ------ Compile the complete list of starting positions ------
c Get all starting points in specified vertical coordinate system
start_n = 0
do i=1,vn
do j=1,hn
start_n = start_n + 1
start_lon(start_n) = lonlist(j)
start_lat(start_n) = latlist(j)
start_lev(start_n) = levlist(i)
enddo
enddo
c ------ Exit point of this section
400 continue
c Write status information
print*,' # expanded points : ', start_n
print*
c ------------------------------------------------------------------
c Transform starting levels into height
c ------------------------------------------------------------------
c Write some status information
print*,'---- STARTING POSITIONS ---------------------------------'
print*
c Vertical mode <m>
if ( umode.eq.'m' ) then
do i=1,start_n
start_hgt(i) = start_lev(i)
enddo
c Vertical mode <m,agl>
elseif ( umode.eq.'m,agl' ) then
do i=1,start_n
call get_index3(rid,rjd,rkd,start_lon(i),start_lat(i),
> 0.,3,z,zs,nx,ny,nz,xmin,ymin,dx,dy)
tmp1 = int_index3 (zs,nx,ny,1,rid,rjd,1.,mdv)
start_hgt(i) = tmp1 + start_lev(i)
enddo
c Vertical mode <INDEX>
elseif ( umode.eq.'INDEX' ) then
do i=1,start_n
call get_index3(rid,rjd,rkd,start_lon(i),start_lat(i),
> 0.,2,z,zs,nx,ny,nz,xmin,ymin,dx,dy)
rkd = start_lev(i)
tmp1 = int_index3 (z,nx,ny,nz,rid,rjd,rkd,mdv)
start_hgt(i) = tmp1
enddo
endif
c ------------------------------------------------------------------
c Remove invalid points from the list
c ------------------------------------------------------------------
c Select the correct subset if <vmode=grid>: starting points outside the layer
c will receive a <mdv> vertical height and will be removed
if ( vmode.eq.'grid' ) then
do i=1,start_n
c Get the height at the grid point
if ( ( umode_save.eq.'m' ).or.
> (umode_save.eq.'m,asl') )
> then
call get_index3(rid,rjd,rkd,start_lon(i),start_lat(i),
> start_hgt(i),3,z,zs,nx,ny,nz,xmin,
> ymin,dx,dy)
tmp1 = int_index3 (z,nx,ny,nz,rid,rjd,rkd,mdv)
c Get height AGL at grid point
elseif ( umode_save.eq.'m,agl' ) then
call get_index3(rid,rjd,rkd,start_lon(i),
> start_lat(i),start_hgt(i),3,z,zs,
> nx,ny,nz,xmin,ymin,dx,dy)
tmp1 = int_index3 (z,nx,ny,nz,rid,rjd,rkd,mdv)
call get_index3(rid,rjd,rkd,start_lon(i),
> start_hgt(i),0.,3,z,zs,nx,ny,
> nz,xmin,ymin,dx,dy)
tmp2 = int_index3 (zs,nx,ny,1,rid,rjd,1,mdv)
tmp1 = tmp2 - tmp1
c Get vertical index at the grid point
elseif ( umode_save.eq.'INDEX' ) then
call get_index3(rid,rjd,rkd,start_lon(i),start_lat(i),
> start_hgt(i),3,z,zs,nx,ny,nz,
> xmin,ymin,dx,dy)
tmp1 = int_index3 (in,nx,ny,nz,rid,rjd,rkd,mdv)
endif
c Remove points outside layer
if ( ( tmp1.lt.lev1).or.(tmp1.gt.lev2) ) then
start_hgt(i) = mdv
endif
enddo
endif
c Check whether the starting points are outside topography
do i=1,start_n
call get_index3(rid,rjd,rkd,start_lon(i),start_lat(i),
> start_hgt(i),3,z,zs,nx,ny,nz,xmin,ymin,dx,dy)
tmp1 = int_index3 (topo,nx,ny,nz,rid,rjd,rkd,mdv)
if ( abs(tmp1-1.).lt.eps ) then
start_hgt(i) = mdv
end if
enddo
c Check whether the starting levels are valid (in data domain)
do i=1,start_n
call get_index3(rid,rjd,rkd,start_lon(i),start_lat(i),
> 0.,3,z,zs,nx,ny,nz,xmin,ymin,dx,dy)
tmp1 = int_index3 (zs,nx,ny, 1,rid,rjd,real( 1),mdv) ! Surface
tmp2 = int_index3 (z ,nx,ny,nz,rid,rjd,real(nz),mdv) ! Top of domain
if ( (start_hgt(i).lt.tmp1).or.
> (start_hgt(i).gt.tmp2).or.
> (start_lon(i).lt.xmin).or.
> (start_lon(i).gt.xmax).or.
> (start_lat(i).lt.ymin).or.
> (start_lat(i).gt.ymax) )
> then
start_hgt(i) = mdv
endif
enddo
c Remove all starting points outside the domain
i = 1
do while ( i.le.start_n )
if ( abs(start_hgt(i)-mdv).lt.eps ) then
if ( vmode.ne.'grid') then
print*,' Outside ', start_lon(i),start_lat(i),start_lev(i)
endif
do j=i,start_n
start_lon(j) = start_lon(j+1)
start_lat(j) = start_lat(j+1)
start_hgt(j) = start_hgt(j+1)
start_lev(j) = start_lev(j+1)
enddo
start_n = start_n - 1
else
i = i + 1
endif
enddo
c Write some status information
latmin = start_lat(1)
latmax = start_lat(1)
lonmin = start_lon(1)
lonmax = start_lon(1)
hgtmin = start_hgt(1)
hgtmax = start_hgt(1)
do i=1,start_n
if (start_lat(i).lt.latmin) latmin = start_lat(i)
if (start_lat(i).gt.latmax) latmax = start_lat(i)
if (start_lon(i).lt.lonmin) lonmin = start_lon(i)
if (start_lon(i).gt.lonmax) lonmax = start_lon(i)
if (start_hgt(i).lt.hgtmin) hgtmin = start_hgt(i)
if (start_hgt(i).gt.hgtmax) hgtmax = start_hgt(i)
enddo
print*,' min(lat),max(lat) : ', latmin,latmax
print*,' min(lon),max(lon) : ', lonmin,lonmax
print*,' min(hgt),max(hgt) : ', hgtmin,hgtmax
print*
print*,' # starting points : ', start_n
print*
c ------------------------------------------------------------------
c Write starting positions to output file
c ------------------------------------------------------------------
c Output as a trajectory file (with only one time == 0)
if (oformat.ne.-1) then
allocate(tra(start_n,1,5),stat=stat)
vars(1) ='time'
vars(2) ='lon'
vars(3) ='lat'
vars(4) ='depth'
vars(5) ='level'
call wopen_tra(fid,ofile,start_n,1,5,reftime,vars,oformat)
do i=1,start_n
tra(i,1,1) = 0.
tra(i,1,2) = start_lon(i)
tra(i,1,3) = start_lat(i)
tra(i,1,4) = start_hgt(i)
tra(i,1,5) = start_lev(i)
enddo
call write_tra(fid,tra,start_n,1,5,oformat)
call close_tra(fid,oformat)
c Output as a triple list (corresponding to <startf> file)
else
fid = 10
open(fid,file=ofile)
do i=1,start_n
write(fid,'(3f10.3)') start_lon(i),start_lat(i),
> start_hgt(i)
enddo
close(fid)
endif
c Write some status information, and end of program message
print*
print*,'---- STATUS INFORMATION --------------------------------'
print*
print*,'ok'
print*
print*,' *** END OF PROGRAM CREATE_STARTF ***'
print*,'========================================================='
c ------------------------------------------------------------------
c Exception handling
c ------------------------------------------------------------------
stop
993 write(*,*) '*** ERROR: problems with array size'
call exit(1)
end
c --------------------------------------------------------------------------
c Split a region string and get corners of the domain
c --------------------------------------------------------------------------
subroutine regionsplit(string,iregion,xcorner,ycorner)
c The region string comes either as <lonw,lone,lats,latn> or as <lon1,lat1,
c lon2,lat2,lon3,lat3,lon4,lat4>: split it into ints components and get the
c four coordinates for the region
implicit none
c Declaration of subroutine parameters
character*80 string
real xcorner(4),ycorner(4)
integer iregion
c Local variables
integer i,n
integer il,ir
real subfloat (80)
integer stat
integer len
c ------- Split the string
i = 1
n = 0
stat = 0
il = 1
len = len_trim(string)
100 continue
c Find start of a substring
do while ( stat.eq.0 )
if ( string(i:i).ne.' ' ) then
stat = 1
il = i
else
i = i + 1
endif
enddo
c Find end of substring
do while ( stat.eq.1 )
if ( ( string(i:i).eq.' ' ) .or. ( i.eq.len ) ) then
stat = 2
ir = i
else
i = i + 1
endif
enddo
c Convert the substring into a number
if ( stat.eq.2 ) then
n = n + 1
read(string(il:ir),*) subfloat(n)
stat = 0
endif
if ( i.lt.len ) goto 100
c -------- Get the region number
iregion = nint(subfloat(1))
c -------- Get the corners of the region
if ( n.eq.5 ) then ! lonw(2),lone(3),lats(4),latn(5)
xcorner(1) = subfloat(2)
ycorner(1) = subfloat(4)
xcorner(2) = subfloat(3)
ycorner(2) = subfloat(4)
xcorner(3) = subfloat(3)
ycorner(3) = subfloat(5)
xcorner(4) = subfloat(2)
ycorner(4) = subfloat(5)
elseif ( n.eq.9 ) then ! lon1,lat1,lon2,lat2,lon3,lon4,lat4
xcorner(1) = subfloat(2)
ycorner(1) = subfloat(3)
xcorner(2) = subfloat(4)
ycorner(2) = subfloat(5)
xcorner(3) = subfloat(6)
ycorner(3) = subfloat(7)
xcorner(4) = subfloat(8)
ycorner(4) = subfloat(9)
else
print*,' ERROR: invalid region specification '
print*,' ',trim(string)
stop
endif
end
c --------------------------------------------------------------------------
c Decide whether lat/lon point is in or out of region
c --------------------------------------------------------------------------
integer function inregion (lon,lat,xcorner,ycorner)
c Decide whether point (lon/lat) is in the region specified by <xcorner(1..4),
c ycorner(1..4).
implicit none
c Declaration of subroutine parameters
real lon,lat
real xcorner(4),ycorner(4)
c Local variables
integer flag
real xmin,xmax,ymin,ymax
integer i
c Reset the flag
flag = 0
c Set some boundaries
xmax = xcorner(1)
xmin = xcorner(1)
ymax = ycorner(1)
ymin = ycorner(1)
do i=2,4
if (xcorner(i).lt.xmin) xmin = xcorner(i)
if (xcorner(i).gt.xmax) xmax = xcorner(i)
if (ycorner(i).lt.ymin) ymin = ycorner(i)
if (ycorner(i).gt.ymax) ymax = ycorner(i)
enddo
c Do the tests - set flag=1 if all tests pased
if (lon.lt.xmin) goto 970
if (lon.gt.xmax) goto 970
if (lat.lt.ymin) goto 970
if (lat.gt.ymax) goto 970
if ((lon-xcorner(1))*(ycorner(2)-ycorner(1))-
> (lat-ycorner(1))*(xcorner(2)-xcorner(1)).gt.0.) goto 970
if ((lon-xcorner(2))*(ycorner(3)-ycorner(2))-
> (lat-ycorner(2))*(xcorner(3)-xcorner(2)).gt.0.) goto 970
if ((lon-xcorner(3))*(ycorner(4)-ycorner(3))-
> (lat-ycorner(3))*(xcorner(4)-xcorner(3)).gt.0.) goto 970
if ((lon-xcorner(4))*(ycorner(1)-ycorner(4))-
> (lat-ycorner(4))*(xcorner(1)-xcorner(4)).gt.0.) goto 970
flag = 1
c Return the value
970 continue
inregion = flag
return
end
c --------------------------------------------------------------------------
c Spherical distance between lat/lon points
c --------------------------------------------------------------------------
real function sdis(xp,yp,xq,yq)
c
c calculates spherical distance (in km) between two points given
c by their spherical coordinates (xp,yp) and (xq,yq), respectively.
c
real re
parameter (re=6370.)
real pi180
parameter (pi180=3.14159/180.)
real xp,yp,xq,yq,arg
arg=sin(pi180*yp)*sin(pi180*yq)+
> cos(pi180*yp)*cos(pi180*yq)*cos(pi180*(xp-xq))
if (arg.lt.-1.) arg=-1.
if (arg.gt.1.) arg=1.
sdis=re*acos(arg)
end
c ****************************************************************
c * Given some spherical polygon S and some point X known to be *
c * located inside S, these routines will determine if an arbit- *
c * -rary point P lies inside S, outside S, or on its boundary. *
c * The calling program must first call DefSPolyBndry to define *
c * the boundary of S and the point X. Any subsequent call to *
c * subroutine LctPtRelBndry will determine if some point P lies *
c * inside or outside S, or on its boundary. (Usually *
c * DefSPolyBndry is called once, then LctPrRelBndry is called *
c * many times). *
c * *
c * REFERENCE: Bevis, M. and Chatelain, J.-L. (1989) *
c * Maflaematical Geology, vol 21. *
c * VERSION 1.0 *
c ****************************************************************
Subroutine DefSPolyBndry(vlat,vlon,nv,xlat, xlon)
c ****************************************************************
c * This mmn entry point is used m define ~e spheric~ polygon S *
c * and the point X. *
c * ARGUMENTS: *
c * vlat,vlon (sent) ... vectors containing the latitude and *
c * longitude of each vertex of the *
c * spherical polygon S. The ith.vertex is *
c * located at [vlat(i),vlon(i)]. *
c * nv (sent) ... the number of vertices and sides in the *
c * spherical polygon S *
c * xlat,xlon (sent) ... latitude and longitude of some point X *
c * located inside S. X must not be located *
c * on any great circle that includes two *
c * vertices of S. *
c * *
c * UNITS AND SIGN CONVENTION: *
c * Latitudes and longitudes are specified in degrees. *
c * Latitudes are positive to the north and negative to the *
c * south. *
c * Longitudes are positive to the east and negative to the *
c * west. *
c * *
c * VERTEX ENUMERATION: *
c * The vertices of S should be numbered sequentially around the *
c * border of the spherical polygon. Vertex 1 lies between vertex*
c * nv and vertex 2. Neighbouring vertices must be seperated by *
c * less than 180 degrees. (In order to generate a polygon side *
c * whose arc length equals or exceeds 180 degrees simply *
c * introduce an additional (pseudo)vertex). Having chosen *
c * vertex 1, the user may number the remaining vertices in *
c * either direction. However if the user wishes to use the *
c * subroutine SPA to determine the area of the polygon S (Bevis *
c * & Cambareri, 1987, Math. Geol., v.19, p. 335-346) then he or *
c * she must follow the convention whereby in moving around the *
c * polygon border in the direction of increasing vertex number *
c * clockwise bends occur at salient vertices. A vertex is *
c * salient if the interior angle is less than 180 degrees. *
c * (In the case of a convex polygon this convention implies *
c * that vertices are numbered in clockwise sequence). *
c ****************************************************************
implicit none
integer mxnv,nv
c ----------------------------------------------------------------
c Edit next statement to increase maximum number of vertices that
c may be used to define the spherical polygon S
c The value of parameter mxnv in subroutine LctPtRelBndry must match
c that of parameter mxnv in this subroutine, as assigned above.
c ----------------------------------------------------------------
parameter (mxnv=500)
real vlat(nv),vlon(nv),xlat,xlon,dellon
real tlonv(mxnv),vlat_c(mxnv),vlon_c(mxnv),xlat_c,xlon_c
integer i,ibndry,nv_c,ip
data ibndry/0/
common/spolybndry/vlat_c,vlon_c,nv_c,xlat_c,xlon_c,tlonv,ibndry
if (nv.gt.mxnv) then
print *,'nv exceeds maximum allowed value'
print *,'adjust parameter mxnv in subroutine DefSPolyBndry'
stop
endif
ibndry=1 ! boundary defined at least once (flag)
nv_c=nv ! copy for named common
xlat_c=xlat ! . . . .
xlon_c=xlon !
do i=1,nv
vlat_c(i)=vlat(i) ! "
vlon_c(i)=vlon(i) !
call TrnsfmLon(xlat,xlon,vlat(i),vlon(i),tlonv(i))
if (i.gt.1) then
ip=i-1
else
ip=nv
endif
if ((vlat(i).eq.vlat(ip)).and.(vlon(i).eq.vlon(ip))) then
print *,'DefSPolyBndry detects user error:'
print *,'vertices ',i,' and ',ip,' are not distinct'
print*,'lat ',i,ip,vlat(i),vlat(ip)
print*,'lon ',i,ip,vlon(i),vlon(ip)
stop
endif
if (tlonv(i).eq.tlonv(ip)) then
print *,'DefSPolyBndry detects user error:'
print *,'vertices ',i,' & ',ip,' on same gt. circle as X'
stop
endif
if (vlat(i).eq.(-vlat(ip))) then
dellon=vlon(i)-vlon(ip)
if (dellon.gt.+180.) dellon=dellon-360.
if (dellon.lt.-180.) dellon=dellon-360.
if ((dellon.eq.+180.0).or.(dellon.eq.-180.0)) then
print *,'DefSPolyBndry detects user error:'
print *,'vertices ',i,' and ',ip,' are antipodal'
stop
endif
endif
enddo
return
end
c ****************************************************************
Subroutine LctPtRelBndry(plat,plon,location)
c ****************************************************************
c ****************************************************************
c * This routine is used to see if some point P is located *
c * inside, outside or on the boundary of the spherical polygon *
c * S previously defined by a call to subroutine DefSPolyBndry. *
c * There is a single restriction on point P: it must not be *
c * antipodal to the point X defined in the call to DefSPolyBndry*
c * (ie.P and X cannot be seperated by exactly 180 degrees). *
c * ARGUMENTS: *
c * plat,plon (sent)... the latitude and longitude of point P *
c * location (returned)... specifies the location of P: *
c * location=0 implies P is outside of S *
c * location=1 implies P is inside of S *
c * location=2 implies P on boundary of S *
c * location=3 implies user error (P is *
c * antipodal to X) *
c * UNFfS AND SIGN CONVENTION: *
c * Latitudes and longitudes are specified in degrees. *
c * Latitudes are positive to the north and negative to the *
c * south. *
c * Longitudes are positive to the east and negative to the *
c * west. *
c ****************************************************************
implicit none
integer mxnv
c ----------------------------------------------------------------
c The statement below must match that in subroutine DefSPolyBndry
c ----------------------------------------------------------------
parameter (mxnv=500)
real tlonv(mxnv),vlat_c(mxnv),vlon_c(mxnv),xlat_c,xlon_c
real plat,plon,vAlat,vAlon,vBlat,vBlon,tlonA,tlonB,tlonP
real tlon_X,tlon_P,tlon_B,dellon
integer i,ibndry,nv_c,location,icross,ibrngAB,ibrngAP,ibrngPB
integer ibrng_BX,ibrng_BP,istrike
common/spolybndry/vlat_c,vlon_c,nv_c,xlat_c,xlon_c,tlonv,ibndry
if (ibndry.eq.0) then ! user has never defined the bndry
print*,'Subroutine LctPtRelBndry detects user error:'
print*,'Subroutine DefSPolyBndry must be called before'
print*,'subroutine LctPtRelBndry can be called'
stop
endif
if (plat.eq.(-xlat_c)) then
dellon=plon-xlon_c
if (dellon.lt.(-180.)) dellon=dellon+360.
if (dellon.gt.+180.) dellon=dellon-360.
if ((dellon.eq.+180.0).or.(dellon.eq.-180.)) then
print*,'Warning: LctPtRelBndry detects case P antipodal
> to X'
print*,'location of P relative to S is undetermined'
location=3
return
endif
endif
location=0 ! default ( P is outside S)
icross=0 ! initialize counter
if ((plat.eq.xlat_c).and.(plon.eq.xlon_c)) then
location=1
return
endif
call TrnsfmLon (xlat_c,xlon_c,plat,plon,tlonP)
do i=1,nv_c ! start of loop over sides of S
vAlat=vlat_c(i)
vAlon=vlon_c(i)
tlonA=tlonv(i)
if (i.lt.nv_c) then
vBlat=vlat_c(i+1)
vBlon=vlon_c(i+1)
tlonB=tlonv(i+1)
else
vBlat=vlat_c(1)
vBlon=vlon_c(1)
tlonB=tlonv(1)
endif
istrike=0
if (tlonP.eq.tlonA) then
istrike=1
else
call EastOrWest(tlonA,tlonB,ibrngAB)
call EastOrWest(tlonA,tlonP,ibrngAP)
call EastOrWest(tlonP,tlonB,ibrngPB)
if((ibrngAP.eq.ibrngAB).and.(ibrngPB.eq.ibrngAB)) istrike=1
endif
if (istrike.eq.1) then
if ((plat.eq.vAlat).and.(plon.eq.vAlon)) then
location=2 ! P lies on a vertex of S
return
endif
call TrnsfmLon(vAlat,vAlon,xlat_c,xlon_c,tlon_X)
call TrnsfmLon(vAlat,vAlon,vBlat,vBlon,tlon_B)
call TrnsfmLon(vAlat,vAlon,plat,plon,tlon_P)
if (tlon_P.eq.tlon_B) then
location=2 ! P lies on side of S
return
else
call EastOrWest(tlon_B,tlon_X,ibrng_BX)
call EastOrWest(tlon_B,tlon_P,ibrng_BP)
if(ibrng_BX.eq.(-ibrng_BP)) icross=icross+1
endif
endif
enddo ! end of loop over the sides of S
c if the arc XP crosses the boundary S an even number of times then P
c is in S
if (mod(icross,2).eq.0) location=1
return
end
c ****************************************************************
subroutine TrnsfmLon(plat,plon,qlat,qlon,tranlon)
c ****************************************************************
c * This subroutine is required by subroutines DefSPolyBndry & *
c * LctPtRelBndry. It finds the 'longitude' of point Q in a *
c * geographic coordinate system for which point P acts as a *
c * 'north pole'. SENT: plat,plon,qlat,qlon, in degrees. *
c * RETURNED: tranlon, in degrees. *
c ****************************************************************
implicit none
real pi,dtr,plat,plon,qlat,qlon,tranlon,t,b
parameter (pi=3.141592654,dtr=pi/180.0)
if (plat.eq.90.) then
tranlon=qlon
else
t=sin((qlon-plon)*dtr)*cos(qlat*dtr)
b=sin(dtr*qlat)*cos(plat*dtr)-cos(qlat*dtr)*sin(plat*dtr)
> *cos((qlon-plon)*dtr)
tranlon=atan2(t,b)/dtr
endif
return
end
c ****************************************************************
subroutine EastOrWest(clon,dlon,ibrng)
c ****************************************************************
c * This subroutine is required by subroutine LctPtRelBndry. *
c * This routine determines if in travelling the shortest path *
c * from point C (at longitude clon) to point D (at longitude *
c * dlon) one is heading east, west or neither. *
c * SENT: clon,dlon; in degrees. RETURNED: ibrng *
c * (1=east,-1=west, 0=neither). *
c ****************************************************************
implicit none
real clon,dlon,del
integer ibrng
del=dlon-clon
if (del.gt.180.) del=del-360.
if (del.lt.-180.) del=del+360.
if ((del.gt.0.0).and.(del.ne.180.)) then
ibrng=-1 ! (D is west of C)
elseif ((del.lt.0.0).and.(del.ne.-180.)) then
ibrng=+1 ! (D is east of C)
else
ibrng=0 ! (D north or south of C)
endif
return
end