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PROGRAM trace
C ********************************************************************
C * *
C * Pseudo-lidar plots along trajectories *
C * *
C * Heini Wernli first version: April 1993 *
C * Michael Sprenger major upgrade: 2008-2009 *
C * *
C ********************************************************************
implicit none
c --------------------------------------------------------------------
c Declaration of parameters
c --------------------------------------------------------------------
c Maximum number of levels for input files
integer nlevmax
parameter (nlevmax=100)
c Maximum number of input files (dates, length of trajectories)
integer ndatmax
parameter (ndatmax=500)
c Numerical epsilon (for float comparison)
real eps
parameter (eps=0.001)
c Conversion factors
real pi180 ! deg -> rad
parameter (pi180=3.14159/180.)
real deg2km ! deg -> km (at equator)
parameter (deg2km=111.)
c Prefix for primary and secondary fields
character charp
character chars
parameter (charp='P')
parameter (chars='S')
c --------------------------------------------------------------------
c Declaration of variables
c --------------------------------------------------------------------
c Input and output format for trajectories (see iotra.f)
integer inpmode
c Input parameters
character*80 inpfile ! Input trajectory file
character*80 outfile ! Output netCDF file
character*80 outmode ! Output mode (sum,mean)
integer ntra ! Number of trajectories
integer ncol ! Number of columns (including time, lon, lat, p)
integer ntim ! Number of times per trajectory
integer ntrace0 ! Number of trace variables
character*80 tvar(200) ! Tracing variable name (only the variable)
character*1 tfil(200) ! Filename prefix
real fac(200) ! Scaling factor
integer compfl(200) ! Computation flag (1=compute)
integer numdat ! Number of input files
character*11 dat(ndatmax) ! Dates of input files
real timeinc ! Time increment between input files
real tst ! Time shift of start relative to first data file
real ten ! Time shift of end relatiev to first data file
character*20 startdate ! First time/date on trajectory
character*20 enddate ! Last time/date on trajectory
character*80 timecheck ! Either 'yes' or 'no'
character*80 intmode ! Interpolation mode ('normal', 'nearest')
real pmin,pmax ! Pressure range for output grid
integer npre ! Number of pressure levels in output grid
character*80 centering ! Centering around trajectory position ('yes','no')
character*80 direction ! Direction of lidar (vertical,lat,lon,normal)
character*80 dumpcoord ! Dumping coordinates ('yes','no')
c Trajectories
real,allocatable, dimension (:,:,:) :: trainp ! Input trajectories (ntra,ntim,ncol)
integer reftime(6) ! Reference date
character*80 varsinp(100) ! Field names for input trajectory
integer fid,fod ! File identifier for inp and out trajectories
real x0_tra,y0_tra,p0_tra ! Position of air parcel (physical space)
real reltpos0 ! Relative time of air parcel
real xind,yind,pind ! Position of air parcel (grid space)
integer fbflag ! Flag for forward (1) or backward (-1) trajectories
c Meteorological fields from input file
real,allocatable, dimension (:) :: spt0,spt1 ! Surface pressure
real,allocatable, dimension (:) :: p3t0,p3t1 ! 3d-pressure
real,allocatable, dimension (:) :: f3t0,f3t1 ! 3d field for tracing
character*80 svars(100) ! List of variables on S file
character*80 pvars(100) ! List of variables on P file
integer n_svars ! Number of variables on S file
integer n_pvars ! Number of variables on P file
c Input grid description
real pollon,pollat ! Longitude/latitude of pole
real ak(100) ! Vertical layers and levels
real bk(100)
real xmin,xmax ! Zonal grid extension
real ymin,ymax ! Meridional grid extension
integer nx,ny,nz ! Grid dimensions
real dx,dy ! Horizontal grid resolution
integer hem ! Flag for hemispheric domain
integer per ! Flag for periodic domain
real stagz ! Vertical staggering
real mdv ! Missing data value
c Output grid and fields
real levels(1000) ! Ouput levels
real times (1000) ! Output times
real,allocatable, dimension (:,:) :: out_pos ! Position of trajectories
real,allocatable, dimension (:,:) :: out_val ! Output lidar field
real,allocatable, dimension (:,:) :: out_cnt ! # output lidar sum ups
c Auxiliary variables
integer i,j,k,l,n
real rd
character*80 filename
real time0,time1,reltpos
integer itime0,itime1
integer stat
real tstart
integer iloaded0,iloaded1
real f0
real frac
real tload,tfrac
integer isok
character ch
integer ind
integer ind1,ind2,ind3,ind4,ind5
integer ind6,ind7,ind8,ind9,ind0
integer noutside
real delta
integer itrace0
character*80 string
character*80 cdfname
character*80 varname
real time
character*80 longname
character*80 unit
integer ind_time
integer ind_pre
real rlat,rlon
real x0,y0,p0
real vx0,vy0,vx1,vy1
real rotation,lon,lat
c Externals
real int_index4
external int_index4
c --------------------------------------------------------------------
c Start of program, Read parameters, get grid parameters
c --------------------------------------------------------------------
c Write start message
print*,'========================================================='
print*,' *** START OF PROGRAM LIDAR ***'
print*
c Read parameters
open(10,file='trace.param')
read(10,*) inpfile
read(10,*) outfile
read(10,*) outmode
read(10,*) startdate
read(10,*) enddate
read(10,*) fbflag
read(10,*) numdat
if ( fbflag.eq.1) then
do i=1,numdat
read(10,'(a11)') dat(i)
enddo
else
do i=numdat,1,-1
read(10,'(a11)') dat(i)
enddo
endif
read(10,*) timeinc
read(10,*) tst
read(10,*) ten
read(10,*) ntra
read(10,*) ntim
read(10,*) ncol
read(10,*) ntrace0
do i=1,ntrace0
read(10,*) tvar(i), fac(i), compfl(i), tfil(i)
enddo
read(10,*) n_pvars
do i=1,n_pvars
read(10,*) pvars(i)
enddo
read(10,*) n_svars
do i=1,n_svars
read(10,*) svars(i)
enddo
read(10,*) timecheck
read(10,*) intmode
read(10,*) pmin,pmax,npre
read(10,*) centering
read(10,*) direction
read(10,*) dumpcoord
close(10)
c Check that the direction is ok
if ( ( direction.ne.'vertical' ).and.
> ( direction.ne.'lat' ).and.
> ( direction.ne.'lon' ).and.
> ( direction.ne.'normal' ) )
>then
print*,' ERROR: invalid direction ',trim(direction)
stop
endif
c Remove commented tracing fields
itrace0 = 1
do while ( itrace0.le.ntrace0)
string = tvar(itrace0)
if ( string(1:1).eq.'#' ) then
do i=itrace0,ntrace0-1
tvar(i) = tvar(i+1)
fac(i) = fac(i+1)
compfl(i) = compfl(i+1)
tfil(i) = tfil(i+1)
enddo
ntrace0 = ntrace0 - 1
else
itrace0 = itrace0 + 1
endif
enddo
c Set the formats of the input files
call mode_tra(inpmode,inpfile)
if (inpmode.eq.-1) inpmode=1
C Convert time shifts <tst,ten> from <hh.mm> into fractional time
call hhmm2frac(tst,frac)
tst = frac
call hhmm2frac(ten,frac)
ten = frac
c Set the time for the first data file (depending on forward/backward mode)
if (fbflag.eq.1) then
tstart = -tst
else
tstart = tst
endif
c Read the constant grid parameters (nx,ny,nz,xmin,xmax,ymin,ymax,pollon,pollat)
c The negative <-fid> of the file identifier is used as a flag for parameter retrieval
filename = charp//dat(1)
varname = 'U'
call input_open (fid,filename)
call input_grid (-fid,varname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> tstart,pollon,pollat,rd,rd,nz,rd,rd,rd,timecheck)
call input_close(fid)
C Allocate memory for some meteorological arrays
allocate(spt0(nx*ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array spt0 ***' ! Surface pressure
allocate(spt1(nx*ny),stat=stat)
if (stat.ne.0) print*,'*** error allocating array spt1 ***'
allocate(p3t0(nx*ny*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array p3t0 ***' ! Pressure
allocate(p3t1(nx*ny*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array p3t1 ***'
allocate(f3t0(nx*ny*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array p3t0 ***' ! Lidar field
allocate(f3t1(nx*ny*nz),stat=stat)
if (stat.ne.0) print*,'*** error allocating array p3t1 ***'
c Allocate memory for output field
allocate(out_pos(ntim,npre),stat=stat)
if (stat.ne.0) print*,'*** error allocating array out_pos ***'
allocate(out_val(ntim,npre),stat=stat)
if (stat.ne.0) print*,'*** error allocating array out_val ***'
allocate(out_cnt(ntim,npre),stat=stat)
if (stat.ne.0) print*,'*** error allocating array out_cnt ***'
C Get memory for trajectory arrays
allocate(trainp(ntra,ntim,ncol),stat=stat)
if (stat.ne.0) print*,'*** error allocating array tra ***'
c Set the flags for periodic domains
if ( abs(xmax-xmin-360.).lt.eps ) then
per = 1
elseif ( abs(xmax-xmin-360.+dx).lt.eps ) then
per = 2
else
per = 0
endif
C Set logical flag for periodic data set (hemispheric or not)
hem = 0
if (per.eq.0.) then
delta=xmax-xmin-360.
if (abs(delta+dx).lt.eps) then ! Program aborts: arrays must be closed
print*,' ERROR: arrays must be closed... Stop'
else if (abs(delta).lt.eps) then ! Periodic and hemispheric
hem=1
per=360.
endif
else ! Periodic and hemispheric
hem=1
endif
c Write some status information
print*,'---- INPUT PARAMETERS -----------------------------------'
print*
print*,' Input trajectory file : ',trim(inpfile)
print*,' Format of input file : ',inpmode
print*,' Output netCDF file : ',trim(outfile)
print*,' Format of output file : ',trim(outmode)
print*,' Forward/backward : ',fbflag
print*,' #tra : ',ntra
print*,' #col : ',ncol
print*,' #tim : ',ntim
print*,' No time check : ',trim(timecheck)
print*,' Interpolation mode : ',trim(intmode)
do i=1,ntrace0
if (compfl(i).eq.0) then
print*,' Tracing field : ',
> trim(tvar(i)), fac(i), ' 0 ', tfil(i)
else
print*,' Tracing field : ',
> trim(tvar(i)),' : online calc not supported'
endif
enddo
print*,' Output (pmin,pmax,n) : ',pmin,pmax,npre
print*,' Centering : ',trim(centering)
print*,' Orientation : ',trim(direction)
print*,' Coordinate Dump : ',trim(dumpcoord)
print*
print*,'---- INPUT DATA FILES -----------------------------------'
print*
call frac2hhmm(tstart,tload)
print*,' Time of 1st data file : ',tload
print*,' #input files : ',numdat
print*,' time increment : ',timeinc
call frac2hhmm(tst,tload)
print*,' Shift of start : ',tload
call frac2hhmm(ten,tload)
print*,' Shift of end : ',tload
print*,' First/last input file : ',trim(dat(1)),
> ' ... ',
> trim(dat(numdat))
print*,' Primary variables : ',trim(pvars(1))
do i=2,n_pvars
print*,' : ',trim(pvars(i))
enddo
if ( n_svars.ge.1 ) then
print*,' Secondary variables : ',trim(svars(1))
do i=2,n_svars
print*,' : ',trim(svars(i))
enddo
endif
print*
print*,'---- CONSTANT GRID PARAMETERS ---------------------------'
print*
print*,' xmin,xmax : ',xmin,xmax
print*,' ymin,ymax : ',ymin,ymax
print*,' dx,dy : ',dx,dy
print*,' pollon,pollat : ',pollon,pollat
print*,' nx,ny,nz : ',nx,ny,nz
print*,' per, hem : ',per,hem
print*
c --------------------------------------------------------------------
c Load the input trajectories
c --------------------------------------------------------------------
c Read the input trajectory file
call ropen_tra(fid,inpfile,ntra,ntim,ncol,reftime,varsinp,inpmode)
call read_tra (fid,trainp,ntra,ntim,ncol,inpmode)
call close_tra(fid,inpmode)
c Check that first four columns correspond to time,lon,lat,p
if ( (varsinp(1).ne.'time' ).or.
> (varsinp(2).ne.'xpos' ).and.(varsinp(2).ne.'lon' ).or.
> (varsinp(3).ne.'ypos' ).and.(varsinp(3).ne.'lat' ).or.
> (varsinp(4).ne.'ppos' ).and.(varsinp(4).ne.'p' ) )
>then
print*,' ERROR: problem with input trajectories ...'
stop
endif
varsinp(1) = 'time'
varsinp(2) = 'lon'
varsinp(3) = 'lat'
varsinp(4) = 'p'
c Write some status information of the input trajectories
print*,'---- INPUT TRAJECTORIES ---------------------------------'
print*
print*,' Start date : ',trim(startdate)
print*,' End date : ',trim(enddate)
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 (min) : ',reftime(6)
do i=1,ncol
print*,' Var :',i,trim(varsinp(i))
enddo
print*
c Check that first time is 0 - otherwise the tracing will produce
c wrong results because later in the code only absolute times are
c considered: <itime0 = int(abs(tfrac-tstart)/timeinc) + 1>. This
c will be changed in a future version.
if ( abs( trainp(1,1,1) ).gt.eps ) then
print*,' ERROR: First time of trajectory must be 0, i.e. '
print*,' correspond to the reference date. Otherwise'
print*,' the tracing will give wrong results... STOP'
stop
endif
c If requested, open the coordinate dump file
if ( dumpcoord.eq.'yes' ) then
open(10,file=trim(outfile)//'.coord')
endif
c --------------------------------------------------------------------
c Trace the fields (fields available on input files)
c --------------------------------------------------------------------
print*
print*,'---- LIDAR FROM PRIMARY AND SECONDARY DATA FILES ------'
c Loop over all tracing fields
do i=1,ntrace0
c Skip all fields marked for online calculation
if ( compfl(i).eq.1 ) goto 110
c Init the output fields: position and lidar field
do k=1,ntim
do l=1,npre
out_pos(k,l) = 0.
out_val(k,l) = 0.
out_cnt(k,l) = 0.
enddo
enddo
c Write some status information
print*
print*,' Now lidaring : ',
> trim(tvar(i)),compfl(i),' ',trim(tfil(i))
c Reset flags for load manager
iloaded0 = -1
iloaded1 = -1
c Reset the counter for fields outside domain
noutside = 0
c Loop over all times
do j=1,ntim
c Convert trajectory time from hh.mm to fractional time
call hhmm2frac(trainp(1,j,1),tfrac)
c Get the times which are needed
itime0 = int(abs(tfrac-tstart)/timeinc) + 1
time0 = tstart + fbflag * real(itime0-1) * timeinc
itime1 = itime0 + 1
time1 = time0 + fbflag * timeinc
if ( itime1.gt.numdat ) then
itime1 = itime0
time1 = time0
endif
c Load manager: Check whether itime0 can be copied from itime1
if ( itime0.eq.iloaded1 ) then
f3t0 = f3t1
p3t0 = p3t1
spt0 = spt1
iloaded0 = itime0
endif
c Load manager: Check whether itime1 can be copied from itime0
if ( itime1.eq.iloaded0 ) then
f3t1 = f3t0
p3t1 = p3t0
spt1 = spt0
iloaded1 = itime1
endif
c Load manager: Load first time (tracing variable and grid)
if ( itime0.ne.iloaded0 ) then
filename = tfil(i)//dat(itime0)
call frac2hhmm(time0,tload)
varname = tvar(i)
write(*,'(a23,a20,a3,a5,f7.2)')
> ' -> loading : ',
> trim(filename),' ',trim(varname),tload
call input_open (fid,filename)
call input_wind
> (fid,varname,f3t0,tload,stagz,mdv,
> xmin,xmax,ymin,ymax,dx,dy,nx,ny,nz,timecheck)
call input_grid
> (fid,varname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> tload,pollon,pollat,p3t0,spt0,nz,ak,bk,stagz,
> timecheck)
call input_close(fid)
iloaded0 = itime0
endif
c Load manager: Load second time (tracing variable and grid)
if ( itime1.ne.iloaded1 ) then
filename = tfil(i)//dat(itime1)
call frac2hhmm(time1,tload)
varname = tvar(i)
write(*,'(a23,a20,a3,a5,f7.2)')
> ' -> loading : ',
> trim(filename),' ',trim(varname),tload
call input_open (fid,filename)
call input_wind
> (fid,varname,f3t1,tload,stagz,mdv,
> xmin,xmax,ymin,ymax,dx,dy,nx,ny,nz,timecheck)
call input_grid
> (fid,varname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> tload,pollon,pollat,p3t1,spt1,nz,ak,bk,stagz,
> timecheck)
call input_close(fid)
iloaded1 = itime1
endif
c Loop over all trajectories
do k=1,ntra
c Set the trajectory position
x0_tra = trainp(k,j,2) ! Longitude
y0_tra = trainp(k,j,3) ! Latitude
p0_tra = trainp(k,j,4) ! Pressure
c Get rotation angle - orient normal to trajectory
if ( direction.eq.'normal' ) then
vx0 = 1.
vy0 = 0.
if ( j.lt.ntim ) then
lat = 0.5 * ( trainp(k,j,3) + trainp(k,j+1,3) )
vx1 = ( trainp(k,j+1,2) - trainp(k,j,2) ) *
> cos( lat * pi180 )
vy1 = ( trainp(k,j+1,3) - trainp(k,j,3) )
else
lat = 0.5 * ( trainp(k,j,3) + trainp(k,j-1,3) )
vx1 = ( trainp(k,j,2) - trainp(k,j-1,2) ) *
> cos( lat * pi180 )
vy1 = ( trainp(k,j,3) - trainp(k,j-1,3) )
endif
if ( vx1.gt.180 ) vx1 = vx1 - 360
if ( vx1.lt.-180 ) vx1 = vx1 + 360.
call getangle (vx0,vy0,vx1,vy1,rotation)
rotation = -rotation
else
rotation = 0.
endif
c Set the relative time
call hhmm2frac(trainp(k,j,1),tfrac)
reltpos0 = fbflag * (tfrac-time0)/timeinc
c Loop over pressure profile (or other positions for horizontal mode)
do l=1,npre
c Vertical
if ( direction.eq.'vertical' ) then
x0 = x0_tra
y0 = y0_tra
p0 = pmin + real(l-1)/real(npre-1) * (pmax-pmin)
if ( centering.eq.'yes' )then
p0 = p0 + trainp(k,j,4)
endif
c Longitude
elseif ( direction.eq.'lon' ) then
x0 = pmin + real(l-1)/real(npre-1) * (pmax-pmin)
y0 = y0_tra
p0 = p0_tra
if ( centering.eq.'yes' )then
x0 = x0 + x0_tra
endif
c Latitude
elseif ( direction.eq.'lat' ) then
x0 = x0_tra
y0 = pmin + real(l-1)/real(npre-1) * (pmax-pmin)
p0 = p0_tra
if ( centering.eq.'yes' )then
y0 = y0 + y0_tra
endif
c Normal to trajerctory
elseif ( direction.eq.'normal' ) then
c Set the coordinate in the rotated system
rlat = pmin +
> real(l-1)/real(npre-1) * (pmax-pmin)
rlon = 0.
c Transform it back to geographical lon/lat
call getenvir_b (x0_tra,y0_tra,rotation,
> x0,y0,rlon,rlat,1)
c Pressure unchanged
p0 = p0_tra
endif
c Handle periodic boundaries in zonal direction
if ( (x0.gt.xmax).and.(per.ne.0) ) x0 = x0 - 360.
if ( (x0.lt.xmin).and.(per.ne.0) ) x0 = x0 + 360.
c Handle pole problems for hemispheric data (taken from caltra.f)
if ((hem.eq.1).and.(y0.gt.90.)) then
y0=180.-y0
x0=x0+per/2.
endif
if ((hem.eq.1).and.(y0.lt.-90.)) then
y0=-180.-y0
x0=x0+per/2.
endif
if (y0.gt.89.99) then
y0=89.99
endif
c If requested, dump the lidar coordinates
if ( (dumpcoord.eq.'yes').and.(i.eq.1) ) then
write(10,'(3f10.2)') x0,y0,trainp(k,j,1)
write(10,'(3f10.2)') x0_tra,y0_tra,5.
endif
C Get the index where to interpolate (x0,y0,p0)
if ( (abs(x0-mdv).gt.eps).and.
> (abs(y0-mdv).gt.eps) )
> then
call get_index4 (xind,yind,pind,x0,y0,p0,reltpos0,
> p3t0,p3t1,spt0,spt1,3,
> nx,ny,nz,xmin,ymin,dx,dy,mdv)
else
xind = mdv
yind = mdv
pind = mdv
endif
c If requested, apply nearest-neighbor interpolation
if ( intmode.eq.'nearest') then
xind = real( nint(xind) )
yind = real( nint(yind) )
pind = real( nint(pind) )
if ( xind.lt.1. ) xind = 1.
if ( xind.gt.nx ) xind = real(nx)
if ( yind.lt.1. ) yind = 1.
if ( yind.gt.ny ) yind = real(ny)
if ( pind.lt.1. ) pind = 1.
if ( pind.gt.nz ) pind = real(nz)
endif
c Do the interpolation: everthing is ok
if ( (xind.ge.1.).and.(xind.le.real(nx)).and.
> (yind.ge.1.).and.(yind.le.real(ny)).and.
> (pind.ge.1.).and.(pind.le.real(nz)) )
> then
f0 = int_index4(f3t0,f3t1,nx,ny,nz,
> xind,yind,pind,reltpos0,mdv)
c Set to missing data
else
f0 = mdv
endif
c Save result to output array
if (abs(f0-mdv).gt.eps) then
out_val(j,l) = out_val(j,l) + f0 * fac(i)
out_cnt(j,l) = out_cnt(j,l) + 1.
endif
c End loop over all pressure levels
enddo
c Save output - time index
ind_time = j
c Save output - space index for 'no centering'
if ( centering.eq.'no' ) then
if ( direction.eq.'vertical') then
ind_pre = nint( real(npre) *
> ( (p0_tra - pmin)/(pmax-pmin) ) + 1.)
elseif ( direction.eq.'lon') then
ind_pre = nint( real(npre) *
> ( (x0_tra - pmin)/(pmax-pmin) ) + 1.)
elseif ( direction.eq.'lat') then
ind_pre = nint( real(npre) *
> ( (y0_tra - pmin)/(pmax-pmin) ) + 1.)
endif
c Save output - space index for 'centering'
else
ind_pre = nint( real(npre) *
> ( (0. - pmin)/(pmax-pmin) ) + 1.)
endif
c Update the output array
if ( (ind_time.ge.1).and.(ind_time.le.ntim).and.
> (ind_pre .ge.1).and.(ind_pre .le.npre) )
> then
out_pos(ind_time,ind_pre) =
> out_pos(ind_time,ind_pre) + 1.
endif
c End loop over all trajectories
enddo
c End loop over all times
enddo
c Write the trajectory position to netCDF file - only once
if ( i.eq.1 ) then
cdfname = outfile
varname = 'POSITION'
longname = 'position of trajectory points'
unit = 'none'
time = 0.
do k=1,npre
levels(k) = pmin + real(k-1)/real(npre-1) * (pmax-pmin)
enddo
do k=1,ntim
times(k) = trainp(1,k,1)
enddo
call writecdf2D_cf
> (cdfname,varname,longname,unit,out_pos,time,levels,
> times,npre,ntim,1,1,direction)
endif
c If no valid lidar count: set the field to missing data
do k=1,ntim
do l=1,npre
if (abs(out_cnt(k,l)).lt.eps) then
out_val(k,l) = mdv
endif
enddo
enddo
c If requested, calculate the mean of the lidar field
if ( outmode.eq.'mean' ) then
do k=1,ntim
do l=1,npre
if ( (abs(out_val(k,l)-mdv).gt.eps).and.
> (abs(out_cnt(k,l) ).gt.0. ) )
> then
out_val(k,l) = out_val(k,l) / out_cnt(k,l)
endif
enddo
enddo
endif
c Write the lidar field and count
cdfname = outfile
if (outmode.eq.'sum' ) then
varname = trim(tvar(i))//'_SUM'
elseif (outmode.eq.'mean' ) then
varname = trim(tvar(i))//'_MEAN'
endif
longname = 'sum over all '//trim(tvar(i))//' profiles'
unit = 'not given'
time = 0.
call writecdf2D_cf
> (cdfname,varname,longname,unit,out_val,time,levels,
> times,npre,ntim,0,1,direction)
cdfname = outfile
varname = trim(tvar(i))//'_CNT'
longname = 'counts of all '//trim(tvar(i))//' profiles'
unit = 'not given'
time = 0.
call writecdf2D_cf
> (cdfname,varname,longname,unit,out_cnt,time,levels,
> times,npre,ntim,0,1,direction)
c Exit point for loop over all tracing variables
110 continue
c End loop over all lidar variables
enddo
c --------------------------------------------------------------------
c Write output to netCDF file
c --------------------------------------------------------------------
c Write status information
print*
print*,'---- WRITE OUTPUT LIDAR FIELDS --------------------------'
print*
c Close coord dump file
print*,' LIDAR written to : ',trim(outfile)
if ( dumpcoord.eq.'yes' ) then
print*,' Coordinates dumped to : ',trim(outfile)//'.coord'
endif
c Write some status information, and end of program message
print*
print*,'---- STATUS INFORMATION --------------------------------'
print*
print*,' ok'
print*
print*,' *** END OF PROGRAM LIDAR ***'
print*,'========================================================='
end
c ********************************************************************
c * INPUT / OUTPUT SUBROUTINES *
c ********************************************************************
c --------------------------------------------------------------------
c Subroutines to write 2D CF netcdf output file
c --------------------------------------------------------------------
subroutine writecdf2D_cf
> (cdfname,varname,longname,unit,arr,time,levels,times,
> npre,ntim,crefile,crevar,direction)
c Create and write to the CF netcdf file <cdfname>. The variable
c with name <varname> and with time <time> is written. The data
c are in the two-dimensional array <arr>. The flags <crefile> and
c <crevar> determine whether the file and/or the variable should
c be created.
USE netcdf
IMPLICIT NONE
c Declaration of input parameters
character*80 cdfname
character*80 varname,longname,unit
integer npre,ntim
real arr(ntim,npre)
real levels(npre)
real times (ntim)
real time
integer crefile,crevar
character*80 direction
c Numerical epsilon
real eps
parameter (eps=1.e-5)
c Local variables
integer ierr
integer ncID
integer LevDimId, varLevID
integer TimeDimID, varTimeID
real timeindex
integer i,j
integer nvars,varids(100)
integer ndims,dimids(100)
real timelist(1000)
integer ntimes
integer ind
integer varID
c Quick an dirty solution for fieldname conflict
if ( varname.eq.'time' ) varname = 'TIME'
c Initially set error to indicate no errors.
ierr = 0
c ---- Create the netCDF - skip if <crefile=0> ----------------------
if ( crefile.ne.1 ) goto 100
c Create the file
ierr = nf90_create(trim(cdfname), NF90_CLOBBER, ncID)
c Define dimensions
ierr=nf90_def_dim(ncID,'level',npre, LevDimID )
ierr=nf90_def_dim(ncID,'time' ,ntim, TimeDimID)
c Define space coordinate
ierr = nf90_def_var(ncID,'level',NF90_FLOAT,
> (/ LevDimID /),varLevID)
if ( direction.eq.'vertical' ) then
ierr = nf90_put_att(ncID, varLevID, "standard_name","level")
ierr = nf90_put_att(ncID, varLevID, "units" ,"hPa")
elseif ( direction.eq.'lat' ) then
ierr = nf90_put_att(ncID, varLevID, "standard_name","latitude")
ierr = nf90_put_att(ncID, varLevID, "units" ,"deg")
elseif ( direction.eq.'lon' ) then
ierr = nf90_put_att(ncID, varLevID, "standard_name","longitude")
ierr = nf90_put_att(ncID, varLevID, "units" ,"deg")
elseif ( direction.eq.'normal' ) then
ierr = nf90_put_att(ncID, varLevID, "standard_name","normal")
ierr = nf90_put_att(ncID, varLevID, "units" ,"deg")
endif
c Define time coordinate
ierr = nf90_def_var(ncID,'time',NF90_FLOAT,
> (/ TimeDimID /), varTimeID)
ierr = nf90_put_att(ncID, varTimeID, "long_name", "time")
ierr = nf90_put_att(ncID, varTimeID, "units", "hours")
c Write global attributes
ierr = nf90_put_att(ncID, NF90_GLOBAL, 'Conventions', 'CF-1.0')
ierr = nf90_put_att(ncID, NF90_GLOBAL, 'title',
> 'pseudo-lidar from trajectory file')
ierr = nf90_put_att(ncID, NF90_GLOBAL, 'source',
> 'Lagranto Trajectories')
ierr = nf90_put_att(ncID, NF90_GLOBAL, 'institution',
> 'ETH Zurich, IACETH')
c Check whether the definition was successful
ierr = nf90_enddef(ncID)
if (ierr.gt.0) then
print*, 'An error occurred while attempting to ',
> 'finish definition mode.'
stop
endif
c Write coordinate data
ierr = nf90_put_var(ncID,varLevID ,levels)
ierr = nf90_put_var(ncID,varTimeID ,times )
c Close netCDF file
ierr = nf90_close(ncID)
100 continue
c ---- Define a new variable - skip if <crevar=0> -----------------------
if ( crevar.ne.1 ) goto 110
print*,'Now defining ',trim(varname)
c Open the file for read/write access
ierr = nf90_open (trim(cdfname), NF90_WRITE , ncID)
c Get the IDs for dimensions
ierr = nf90_inq_dimid(ncID,'level', LevDimID )
ierr = nf90_inq_dimid(ncID,'time' , TimeDimID)
c Enter define mode
ierr = nf90_redef(ncID)
c Write definition and add attributes
ierr = nf90_def_var(ncID,varname,NF90_FLOAT,
> (/ TimeDimID, LevDimID /),varID)
ierr = nf90_put_att(ncID, varID, "long_name" , longname )
ierr = nf90_put_att(ncID, varID, "units" , unit )
ierr = nf90_put_att(ncID, varID, '_FillValue', -999.99 )
c Check whether definition was successful
ierr = nf90_enddef(ncID)
if (ierr.gt.0) then
print*, 'An error occurred while attempting to ',
> 'finish definition mode.'
stop
endif
c Close netCDF file
ierr = nf90_close(ncID)
110 continue
c ---- Write data --------------------------------------------------
c Open the file for read/write access
ierr = nf90_open (trim(cdfname), NF90_WRITE , ncID)
c Get the varID
ierr = nf90_inq_varid(ncID,varname, varID )
if (ierr.ne.0) then
print*,'Variable ',trim(varname),' is not defined on ',
> trim(cdfname)
stop
endif
c Write data block
ierr = nf90_put_var(ncID,varID,arr,
> start = (/ 1, 1 /),
> count = (/ ntim, npre/) )
c Check whether writing was successful
ierr = nf90_close(ncID)
if (ierr.ne.0) then
write(*,*) trim(nf90_strerror(ierr))
write(*,*) 'An error occurred while attempting to ',
> 'close the netcdf file.'
write(*,*) 'in clscdf_CF'
endif
end
c ********************************************************************************
c * Coordinate rotation - lidar normal to trajectory *
c ********************************************************************************
c --------------------------------------------------------------------------------
c Backward coordinate transformation (Rotated lon/lat -> True lon/lat)
c --------------------------------------------------------------------------------
SUBROUTINE getenvir_b (clon,clat,rotation,
> lon,lat,rlon,rlat,n)
implicit none
c Declaration of input and output parameters
integer n
real clon,clat,rotation
real lon(n), lat(n)
real rlon(n),rlat(n)
c Auxiliary variables
real pollon,pollat
integer i
real rlon1(n),rlat1(n)
c Externals
real lmstolm,phstoph
external lmstolm,phstoph
c First coordinate transformation (make the local coordinate system parallel to equator)
pollon=-180.
pollat=90.+rotation
do i=1,n
rlon1(i)=90.+lmstolm(rlat(i),rlon(i)-90.,pollat,pollon)
rlat1(i)=phstoph(rlat(i),rlon(i)-90.,pollat,pollon)
enddo
c Second coordinate transformation (make the local coordinate system parallel to equator)
pollon=clon-180.
if (pollon.lt.-180.) pollon=pollon+360.
pollat=90.-clat
do i=1,n
lon(i)=lmstolm(rlat1(i),rlon1(i),pollat,pollon)
lat(i)=phstoph(rlat1(i),rlon1(i),pollat,pollon)
enddo
END
c ---------------------------------------------------------------------
c Determine the angle between two vectors
c ---------------------------------------------------------------------
SUBROUTINE getangle (vx1,vy1,vx2,vy2,angle)
c Given two vectors <vx1,vy1> and <vx2,vy2>, determine the angle (in deg)
c between the two vectors.
implicit none
c Declaration of subroutine parameters
real vx1,vy1
real vx2,vy2
real angle
c Auxiliary variables and parameters
real len1,len2,len3
real val1,val2,val3
real pi
parameter (pi=3.14159265359)
len1=sqrt(vx1*vx1+vy1*vy1)
len2=sqrt(vx2*vx2+vy2*vy2)
if ((len1.gt.0.).and.(len2.gt.0.)) then
vx1=vx1/len1
vy1=vy1/len1
vx2=vx2/len2
vy2=vy2/len2
val1=vx1*vx2+vy1*vy2
val2=-vy1*vx2+vx1*vy2
len3=sqrt(val1*val1+val2*val2)
if ( (val1.ge.0.).and.(val2.ge.0.) ) then
val3=acos(val1/len3)
else if ( (val1.lt.0.).and.(val2.ge.0.) ) then
val3=pi-acos(abs(val1)/len3)
else if ( (val1.ge.0.).and.(val2.le.0.) ) then
val3=-acos(val1/len3)
else if ( (val1.lt.0.).and.(val2.le.0.) ) then
val3=-pi+acos(abs(val1)/len3)
endif
else
val3=0.
endif
angle=180./pi*val3
END
c --------------------------------------------------------------------------------
c Transformation routine: LMSTOLM and PHSTOPH from library gm2em
c --------------------------------------------------------------------------------
REAL FUNCTION LMSTOLM (PHIS, LAMS, POLPHI, POLLAM)
C
C**** LMSTOLM - FC:BERECHNUNG DER WAHREN GEOGRAPHISCHEN LAENGE FUER
C**** EINEN PUNKT MIT DEN KOORDINATEN (PHIS, LAMS)
C**** IM ROTIERTEN SYSTEM. DER NORDPOL DES SYSTEMS HAT
C**** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** AUFRUF : LAM = LMSTOLM (PHIS, LAMS, POLPHI, POLLAM)
C** ENTRIES : KEINE
C** ZWECK : BERECHNUNG DER WAHREN GEOGRAPHISCHEN LAENGE FUER
C** EINEN PUNKT MIT DEN KOORDINATEN (PHIS, LAMS)
C** IM ROTIERTEN SYSTEM. DER NORDPOL DIESES SYSTEMS HAT
C** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** VERSIONS-
C** DATUM : 03.05.90
C**
C** EXTERNALS: KEINE
C** EINGABE-
C** PARAMETER: PHIS REAL GEOGR. BREITE DES PUNKTES IM ROT.SYS.
C** LAMS REAL GEOGR. LAENGE DES PUNKTES IM ROT.SYS.
C** POLPHI REAL WAHRE GEOGR. BREITE DES NORDPOLS
C** POLLAM REAL WAHRE GEOGR. LAENGE DES NORDPOLS
C** AUSGABE-
C** PARAMETER: WAHRE GEOGRAPHISCHE LAENGE ALS WERT DER FUNKTION
C** ALLE WINKEL IN GRAD (NORDEN>0, OSTEN>0)
C**
C** COMMON-
C** BLOECKE : KEINE
C**
C** FEHLERBE-
C** HANDLUNG : KEINE
C** VERFASSER: D.MAJEWSKI
REAL LAMS,PHIS,POLPHI,POLLAM
DATA ZRPI18 , ZPIR18 / 57.2957795 , 0.0174532925 /
ZSINPOL = SIN(ZPIR18*POLPHI)
ZCOSPOL = COS(ZPIR18*POLPHI)
ZLAMPOL = ZPIR18*POLLAM
ZPHIS = ZPIR18*PHIS
ZLAMS = LAMS
IF(ZLAMS.GT.180.0) ZLAMS = ZLAMS - 360.0
ZLAMS = ZPIR18*ZLAMS
ZARG1 = SIN(ZLAMPOL)*(- ZSINPOL*COS(ZLAMS)*COS(ZPHIS) +
1 ZCOSPOL* SIN(ZPHIS)) -
2 COS(ZLAMPOL)* SIN(ZLAMS)*COS(ZPHIS)
ZARG2 = COS(ZLAMPOL)*(- ZSINPOL*COS(ZLAMS)*COS(ZPHIS) +
1 ZCOSPOL* SIN(ZPHIS)) +
2 SIN(ZLAMPOL)* SIN(ZLAMS)*COS(ZPHIS)
IF (ABS(ZARG2).LT.1.E-30) THEN
IF (ABS(ZARG1).LT.1.E-30) THEN
LMSTOLM = 0.0
ELSEIF (ZARG1.GT.0.) THEN
LMSTOLAM = 90.0
ELSE
LMSTOLAM = -90.0
ENDIF
ELSE
LMSTOLM = ZRPI18*ATAN2(ZARG1,ZARG2)
ENDIF
RETURN
END
REAL FUNCTION PHSTOPH (PHIS, LAMS, POLPHI, POLLAM)
C
C**** PHSTOPH - FC:BERECHNUNG DER WAHREN GEOGRAPHISCHEN BREITE FUER
C**** EINEN PUNKT MIT DEN KOORDINATEN (PHIS, LAMS) IM
C**** ROTIERTEN SYSTEM. DER NORDPOL DIESES SYSTEMS HAT
C**** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** AUFRUF : PHI = PHSTOPH (PHIS, LAMS, POLPHI, POLLAM)
C** ENTRIES : KEINE
C** ZWECK : BERECHNUNG DER WAHREN GEOGRAPHISCHEN BREITE FUER
C** EINEN PUNKT MIT DEN KOORDINATEN (PHIS, LAMS) IM
C** ROTIERTEN SYSTEM. DER NORDPOL DIESES SYSTEMS HAT
C** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** VERSIONS-
C** DATUM : 03.05.90
C**
C** EXTERNALS: KEINE
C** EINGABE-
C** PARAMETER: PHIS REAL GEOGR. BREITE DES PUNKTES IM ROT.SYS.
C** LAMS REAL GEOGR. LAENGE DES PUNKTES IM ROT.SYS.
C** POLPHI REAL WAHRE GEOGR. BREITE DES NORDPOLS
C** POLLAM REAL WAHRE GEOGR. LAENGE DES NORDPOLS
C** AUSGABE-
C** PARAMETER: WAHRE GEOGRAPHISCHE BREITE ALS WERT DER FUNKTION
C** ALLE WINKEL IN GRAD (NORDEN>0, OSTEN>0)
C**
C** COMMON-
C** BLOECKE : KEINE
C**
C** FEHLERBE-
C** HANDLUNG : KEINE
C** VERFASSER: D.MAJEWSKI
REAL LAMS,PHIS,POLPHI,POLLAM
DATA ZRPI18 , ZPIR18 / 57.2957795 , 0.0174532925 /
SINPOL = SIN(ZPIR18*POLPHI)
COSPOL = COS(ZPIR18*POLPHI)
ZPHIS = ZPIR18*PHIS
ZLAMS = LAMS
IF(ZLAMS.GT.180.0) ZLAMS = ZLAMS - 360.0
ZLAMS = ZPIR18*ZLAMS
ARG = COSPOL*COS(ZPHIS)*COS(ZLAMS) + SINPOL*SIN(ZPHIS)
PHSTOPH = ZRPI18*ASIN(ARG)
RETURN
END
REAL FUNCTION LMTOLMS (PHI, LAM, POLPHI, POLLAM)
C
C%Z% Modul %M%, V%I% vom %G%, extrahiert am %H%
C
C**** LMTOLMS - FC:UMRECHNUNG DER WAHREN GEOGRAPHISCHEN LAENGE LAM
C**** AUF EINEM PUNKT MIT DEN KOORDINATEN (PHIS, LAMS)
C**** IM ROTIERTEN SYSTEM. DER NORDPOL DES SYSTEMS HAT
C**** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** AUFRUF : LAM = LMTOLMS (PHI, LAM, POLPHI, POLLAM)
C** ENTRIES : KEINE
C** ZWECK : UMRECHNUNG DER WAHREN GEOGRAPHISCHEN LAENGE LAM AUF
C** EINEM PUNKT MIT DEN KOORDINATEN (PHIS, LAMS) IM
C** ROTIERTEN SYSTEM. DER NORDPOL DIESES SYSTEMS HAT
C** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** VERSIONS-
C** DATUM : 03.05.90
C**
C** EXTERNALS: KEINE
C** EINGABE-
C** PARAMETER: PHI REAL BREITE DES PUNKTES IM GEOGR. SYSTEM
C** LAM REAL LAENGE DES PUNKTES IM GEOGR. SYSTEM
C** POLPHI REAL GEOGR.BREITE DES N-POLS DES ROT. SYSTEMS
C** POLLAM REAL GEOGR.LAENGE DES N-POLS DES ROT. SYSTEMS
C** AUSGABE-
C** PARAMETER: WAHRE GEOGRAPHISCHE LAENGE ALS WERT DER FUNKTION
C** ALLE WINKEL IN GRAD (NORDEN>0, OSTEN>0)
C**
C** COMMON-
C** BLOECKE : KEINE
C**
C** FEHLERBE-
C** HANDLUNG : KEINE
C** VERFASSER: G. DE MORSIER
REAL LAM,PHI,POLPHI,POLLAM
DATA ZRPI18 , ZPIR18 / 57.2957795 , 0.0174532925 /
ZSINPOL = SIN(ZPIR18*POLPHI)
ZCOSPOL = COS(ZPIR18*POLPHI)
ZLAMPOL = ZPIR18*POLLAM
ZPHI = ZPIR18*PHI
ZLAM = LAM
IF(ZLAM.GT.180.0) ZLAM = ZLAM - 360.0
ZLAM = ZPIR18*ZLAM
ZARG1 = - SIN(ZLAM-ZLAMPOL)*COS(ZPHI)
ZARG2 = - ZSINPOL*COS(ZPHI)*COS(ZLAM-ZLAMPOL)+ZCOSPOL*SIN(ZPHI)
IF (ABS(ZARG2).LT.1.E-30) THEN
IF (ABS(ZARG1).LT.1.E-30) THEN
LMTOLMS = 0.0
ELSEIF (ZARG1.GT.0.) THEN
LMTOLMS = 90.0
ELSE
LMTOLMS = -90.0
ENDIF
ELSE
LMTOLMS = ZRPI18*ATAN2(ZARG1,ZARG2)
ENDIF
RETURN
END
REAL FUNCTION PHTOPHS (PHI, LAM, POLPHI, POLLAM)
C
C%Z% Modul %M%, V%I% vom %G%, extrahiert am %H%
C
C**** PHTOPHS - FC:UMRECHNUNG DER WAHREN GEOGRAPHISCHEN BREITE PHI
C**** AUF EINEM PUNKT MIT DEN KOORDINATEN (PHIS, LAMS)
C**** IM ROTIERTEN SYSTEM. DER NORDPOL DES SYSTEMS HAT
C**** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** AUFRUF : PHI = PHTOPHS (PHI, LAM, POLPHI, POLLAM)
C** ENTRIES : KEINE
C** ZWECK : UMRECHNUNG DER WAHREN GEOGRAPHISCHEN BREITE PHI AUF
C** EINEM PUNKT MIT DEN KOORDINATEN (PHIS, LAMS) IM
C** ROTIERTEN SYSTEM. DER NORDPOL DIESES SYSTEMS HAT
C** DIE WAHREN KOORDINATEN (POLPHI, POLLAM)
C** VERSIONS-
C** DATUM : 03.05.90
C**
C** EXTERNALS: KEINE
C** EINGABE-
C** PARAMETER: PHI REAL BREITE DES PUNKTES IM GEOGR. SYSTEM
C** LAM REAL LAENGE DES PUNKTES IM GEOGR. SYSTEM
C** POLPHI REAL GEOGR.BREITE DES N-POLS DES ROT. SYSTEMS
C** POLLAM REAL GEOGR.LAENGE DES N-POLS DES ROT. SYSTEMS
C** AUSGABE-
C** PARAMETER: ROTIERTE BREITE PHIS ALS WERT DER FUNKTION
C** ALLE WINKEL IN GRAD (NORDEN>0, OSTEN>0)
C**
C** COMMON-
C** BLOECKE : KEINE
C**
C** FEHLERBE-
C** HANDLUNG : KEINE
C** VERFASSER: G. DE MORSIER
REAL LAM,PHI,POLPHI,POLLAM
DATA ZRPI18 , ZPIR18 / 57.2957795 , 0.0174532925 /
ZSINPOL = SIN(ZPIR18*POLPHI)
ZCOSPOL = COS(ZPIR18*POLPHI)
ZLAMPOL = ZPIR18*POLLAM
ZPHI = ZPIR18*PHI
ZLAM = LAM
IF(ZLAM.GT.180.0) ZLAM = ZLAM - 360.0
ZLAM = ZPIR18*ZLAM
ZARG = ZCOSPOL*COS(ZPHI)*COS(ZLAM-ZLAMPOL) + ZSINPOL*SIN(ZPHI)
PHTOPHS = ZRPI18*ASIN(ZARG)
RETURN
END