Maintenance is scheduled between 16:00 and 23:59 CEST (14:00 and 21:59 UTC) on Thursday 2021-10-28. The system may be unavailable at any time during this timeframe. Please plan accordingly.

Commit a63c75a7 authored by Espen Sollum's avatar Espen Sollum
Browse files

Merge branch 'dev' into release-10

parents 941db732 6741557b
......@@ -18,7 +18,7 @@
CTL= -5.0000000, ! CTL>1, ABL time step = (Lagrangian timescale (TL))/CTL, uses LSYNCTIME if CTL<0
IFINE= 4, ! Reduction for time step in vertical transport, used only if CTL>1
IOUT= 1, ! Output type: [1]mass 2]pptv 3]1&2 4]plume 5]1&4, +8 for NetCDF output
IPOUT= 0, ! Particle position output: 0]no 1]every output 2]only at end
IPOUT= 0, ! Particle position output: 0]no 1]every output 2]only at end 3]time averaged
LSUBGRID= 0, ! Increase of ABL heights due to sub-grid scale orographic variations;[0]off 1]on
LCONVECTION= 1, ! Switch for convection parameterization;0]off [1]on
LAGESPECTRA= 0, ! Switch for calculation of age spectra (needs AGECLASSES);[0]off 1]on
......
......@@ -67,13 +67,7 @@ program flexpart
integer :: metdata_format = GRIBFILE_CENTRE_UNKNOWN
integer :: detectformat
! Initialize arrays in com_mod
!*****************************
call com_mod_allocate_part(maxpart)
! Generate a large number of random numbers
!******************************************
......@@ -142,7 +136,7 @@ program flexpart
print*,'nxshift=',nxshift
write(*,*) 'call readpaths'
endif
call readpaths(pathfile)
call readpaths
if (verbosity.gt.1) then !show clock info
!print*,'length(4)',length(4)
......@@ -171,6 +165,11 @@ program flexpart
endif
endif
! Initialize arrays in com_mod
!*****************************
call com_mod_allocate_part(maxpart)
! Read the age classes to be used
!********************************
if (verbosity.gt.0) then
......@@ -452,7 +451,9 @@ program flexpart
print*,'call timemanager'
endif
if (verbosity.gt.0) write (*,*) 'timemanager> call wetdepo'
call timemanager(metdata_format)
if (verbosity.gt.0) then
! NIK 16.02.2005
......@@ -467,7 +468,6 @@ program flexpart
write(*,*) '**********************************************'
endif
end do
write (*,*) 'timemanager> call wetdepo'
endif
write(*,*) 'CONGRATULATIONS: YOU HAVE SUCCESSFULLY COMPLETED A FLE&
......
......@@ -76,12 +76,7 @@ program flexpart
if (mp_measure_time) call mpif_mtime('flexpart',0)
! Initialize arrays in com_mod
!*****************************
if(.not.(lmpreader.and.lmp_use_reader)) call com_mod_allocate_part(maxpart_mpi)
! Generate a large number of random numbers
!******************************************
......@@ -150,7 +145,7 @@ program flexpart
if (verbosity.gt.0) then
write(*,*) 'call readpaths'
endif
call readpaths(pathfile)
call readpaths
if (verbosity.gt.1) then !show clock info
!print*,'length(4)',length(4)
......@@ -179,6 +174,11 @@ program flexpart
endif
endif
! Initialize arrays in com_mod
!*****************************
if(.not.(lmpreader.and.lmp_use_reader)) call com_mod_allocate_part(maxpart_mpi)
! Read the age classes to be used
!********************************
......@@ -412,7 +412,7 @@ program flexpart
if (nested_output.ne.1.and.surf_only.eq.1) call writeheader_surf
end if ! (mpif_pid == 0)
if (mp_measure_time) call mpif_mtime('iotime',0)
if (mp_measure_time) call mpif_mtime('iotime',1)
if (verbosity.gt.0 .and. lroot) then
print*,'call openreceptors'
......
......@@ -18,6 +18,8 @@ module com_mod
implicit none
!****************************************************************
! Variables defining where FLEXPART input/output files are stored
!****************************************************************
......@@ -68,7 +70,7 @@ module com_mod
! outstep = real(abs(loutstep))
real :: ctl,fine
integer :: ifine,iout,ipout,ipin,iflux,mdomainfill
integer :: ifine,iout,ipout,ipin,iflux,mdomainfill,ipoutfac
integer :: mquasilag,nested_output,ind_source,ind_receptor
integer :: ind_rel,ind_samp,ioutputforeachrelease,linit_cond,surf_only
logical :: turbswitch
......@@ -81,6 +83,7 @@ module com_mod
! iflux flux calculation options: 1 calculation of fluxes, 2 no fluxes
! iout output options: 1 conc. output (ng/m3), 2 mixing ratio (pptv), 3 both
! ipout particle dump options: 0 no, 1 every output interval, 2 only at end
! ipoutfac increase particle dump interval by factor (default 1)
! ipin read in particle positions from dumped file from a previous run
! fine real(ifine)
! mdomainfill 0: normal run
......@@ -120,6 +123,9 @@ module com_mod
integer :: lnetcdfout
! lnetcdfout 1 for netcdf grid output, 0 if not. Set in COMMAND (namelist input)
integer :: linversionout
! linversionout 1 for one grid_time output file for each release containing all timesteps
integer :: nageclass,lage(maxageclass)
! nageclass number of ageclasses for the age spectra calculation
......@@ -127,7 +133,6 @@ module com_mod
logical :: gdomainfill
! gdomainfill .T., if domain-filling is global, .F. if not
!ZHG SEP 2015 wheather or not to read clouds from GRIB
......@@ -173,7 +178,7 @@ module com_mod
real :: vset(maxspec,ni),schmi(maxspec,ni),fract(maxspec,ni)
real :: ri(5,numclass),rac(5,numclass),rcl(maxspec,5,numclass)
real :: rgs(maxspec,5,numclass),rlu(maxspec,5,numclass)
real :: rm(maxspec),dryvel(maxspec)
real :: rm(maxspec),dryvel(maxspec),kao(maxspec)
real :: ohcconst(maxspec),ohdconst(maxspec),ohnconst(maxspec)
real :: area_hour(maxspec,24),point_hour(maxspec,24)
......@@ -358,7 +363,9 @@ module com_mod
real :: clwc(0:nxmax-1,0:nymax-1,nzmax,numwfmem)=0.0 !liquid [kg/kg]
real :: ciwc(0:nxmax-1,0:nymax-1,nzmax,numwfmem)=0.0 !ice [kg/kg]
real :: clw(0:nxmax-1,0:nymax-1,nzmax,numwfmem)=0.0 !combined [m3/m3]
! RLT add pressure and dry air density
real :: prs(0:nxmax-1,0:nymax-1,nzmax,numwfmem)
real :: rho_dry(0:nxmax-1,0:nymax-1,nzmax,numwfmem)
real :: pv(0:nxmax-1,0:nymax-1,nzmax,numwfmem)
real :: rho(0:nxmax-1,0:nymax-1,nzmax,numwfmem)
real :: drhodz(0:nxmax-1,0:nymax-1,nzmax,numwfmem)
......@@ -380,6 +387,7 @@ module com_mod
! uu,vv,ww [m/2] wind components in x,y and z direction
! uupol,vvpol [m/s] wind components in polar stereographic projection
! tt [K] temperature data
! prs air pressure
! qv specific humidity data
! pv (pvu) potential vorticity
! rho [kg/m3] air density
......@@ -650,6 +658,7 @@ module com_mod
real :: xreceptor(maxreceptor),yreceptor(maxreceptor)
real :: receptorarea(maxreceptor)
real :: creceptor(maxreceptor,maxspec)
real, allocatable, dimension(:,:) :: creceptor0
character(len=16) :: receptorname(maxreceptor)
integer :: numreceptor
......@@ -673,6 +682,14 @@ module com_mod
real, allocatable, dimension(:,:) :: xmass1
real, allocatable, dimension(:,:) :: xscav_frac1
! Variables used for writing out interval averages for partoutput
!****************************************************************
integer, allocatable, dimension(:) :: npart_av
real, allocatable, dimension(:) :: part_av_cartx,part_av_carty,part_av_cartz,part_av_z,part_av_topo
real, allocatable, dimension(:) :: part_av_pv,part_av_qv,part_av_tt,part_av_rho,part_av_tro,part_av_hmix
real, allocatable, dimension(:) :: part_av_uu,part_av_vv,part_av_energy
! eso: Moved from timemanager
real, allocatable, dimension(:) :: uap,ucp,uzp,us,vs,ws
integer(kind=2), allocatable, dimension(:) :: cbt
......@@ -779,13 +796,21 @@ contains
allocate(itra1(nmpart),npoint(nmpart),nclass(nmpart),&
& idt(nmpart),itramem(nmpart),itrasplit(nmpart),&
& xtra1(nmpart),ytra1(nmpart),ztra1(nmpart),&
& xmass1(nmpart, maxspec),&
& checklifetime(nmpart,maxspec), species_lifetime(maxspec,2))!CGZ-lifetime
& xmass1(nmpart, maxspec)) ! ,&
! & checklifetime(nmpart,maxspec), species_lifetime(maxspec,2))!CGZ-lifetime
if (ipout.eq.3) then
allocate(npart_av(nmpart),part_av_cartx(nmpart),part_av_carty(nmpart),&
& part_av_cartz(nmpart),part_av_z(nmpart),part_av_topo(nmpart))
allocate(part_av_pv(nmpart),part_av_qv(nmpart),part_av_tt(nmpart),&
& part_av_rho(nmpart),part_av_tro(nmpart),part_av_hmix(nmpart))
allocate(part_av_uu(nmpart),part_av_vv(nmpart),part_av_energy(nmpart))
end if
allocate(uap(nmpart),ucp(nmpart),uzp(nmpart),us(nmpart),&
& vs(nmpart),ws(nmpart),cbt(nmpart))
end subroutine com_mod_allocate_part
......
......@@ -71,6 +71,9 @@ subroutine concoutput(itime,outnum,gridtotalunc,wetgridtotalunc, &
integer :: sp_count_i,sp_count_r
real :: sp_fact
real :: outnum,densityoutrecept(maxreceptor),xl,yl
! RLT
real :: densitydryrecept(maxreceptor)
real :: factor_dryrecept(maxreceptor)
!real densityoutgrid(0:numxgrid-1,0:numygrid-1,numzgrid),
! +grid(0:numxgrid-1,0:numygrid-1,numzgrid,maxspec,maxpointspec_act,
......@@ -105,6 +108,7 @@ subroutine concoutput(itime,outnum,gridtotalunc,wetgridtotalunc, &
! mind eso:added to ensure identical results between 2&3-fields versions
character(LEN=8),save :: file_stat='REPLACE'
logical :: ldates_file
logical :: lexist
integer :: ierr
character(LEN=100) :: dates_char
......@@ -202,6 +206,9 @@ subroutine concoutput(itime,outnum,gridtotalunc,wetgridtotalunc, &
! rho(iix,jjy,kzz-1,2)*dz2)/dz
densityoutgrid(ix,jy,kz)=(rho(iix,jjy,kzz,mind)*dz1+ &
rho(iix,jjy,kzz-1,mind)*dz2)/dz
! RLT
densitydrygrid(ix,jy,kz)=(rho_dry(iix,jjy,kzz,mind)*dz1+ &
rho_dry(iix,jjy,kzz-1,mind)*dz2)/dz
end do
end do
end do
......@@ -213,8 +220,14 @@ subroutine concoutput(itime,outnum,gridtotalunc,wetgridtotalunc, &
jjy=max(min(nint(yl),nymin1),0)
!densityoutrecept(i)=rho(iix,jjy,1,2)
densityoutrecept(i)=rho(iix,jjy,1,mind)
! RLT
densitydryrecept(i)=rho_dry(iix,jjy,1,mind)
end do
! RLT
! conversion factor for output relative to dry air
factor_drygrid=densityoutgrid/densitydrygrid
factor_dryrecept=densityoutrecept/densitydryrecept
! Output is different for forward and backward simulations
do kz=1,numzgrid
......@@ -352,7 +365,7 @@ subroutine concoutput(itime,outnum,gridtotalunc,wetgridtotalunc, &
! Concentration output
!*********************
if ((iout.eq.1).or.(iout.eq.3).or.(iout.eq.5).or.(iout.eq.6)) then
if ((iout.eq.1).or.(iout.eq.3).or.(iout.eq.5)) then
! Wet deposition
sp_count_i=0
......@@ -613,6 +626,49 @@ subroutine concoutput(itime,outnum,gridtotalunc,wetgridtotalunc, &
end do
! RLT Aug 2017
! Write out conversion factor for dry air
inquire(file=path(2)(1:length(2))//'factor_drygrid',exist=lexist)
if (lexist) then
! open and append
open(unitoutfactor,file=path(2)(1:length(2))//'factor_drygrid',form='unformatted',&
status='old',action='write',access='append')
else
! create new
open(unitoutfactor,file=path(2)(1:length(2))//'factor_drygrid',form='unformatted',&
status='new',action='write')
endif
sp_count_i=0
sp_count_r=0
sp_fact=-1.
sp_zer=.true.
do kz=1,numzgrid
do jy=0,numygrid-1
do ix=0,numxgrid-1
if (factor_drygrid(ix,jy,kz).gt.(1.+smallnum).or.factor_drygrid(ix,jy,kz).lt.(1.-smallnum)) then
if (sp_zer.eqv..true.) then ! first value not equal to one
sp_count_i=sp_count_i+1
sparse_dump_i(sp_count_i)= &
ix+jy*numxgrid+kz*numxgrid*numygrid
sp_zer=.false.
sp_fact=sp_fact*(-1.)
endif
sp_count_r=sp_count_r+1
sparse_dump_r(sp_count_r)= &
sp_fact*factor_drygrid(ix,jy,kz)
else ! factor is one
sp_zer=.true.
endif
end do
end do
end do
write(unitoutfactor) sp_count_i
write(unitoutfactor) (sparse_dump_i(i),i=1,sp_count_i)
write(unitoutfactor) sp_count_r
write(unitoutfactor) (sparse_dump_r(i),i=1,sp_count_r)
close(unitoutfactor)
if (gridtotal.gt.0.) gridtotalunc=gridsigmatotal/gridtotal
if (wetgridtotal.gt.0.) wetgridtotalunc=wetgridsigmatotal/ &
wetgridtotal
......@@ -639,7 +695,23 @@ subroutine concoutput(itime,outnum,gridtotalunc,wetgridtotalunc, &
end do
endif
! RLT Aug 2017
! Write out conversion factor for dry air
if (numreceptor.gt.0) then
inquire(file=path(2)(1:length(2))//'factor_dryreceptor',exist=lexist)
if (lexist) then
! open and append
open(unitoutfactor,file=path(2)(1:length(2))//'factor_dryreceptor',form='unformatted',&
status='old',action='write',access='append')
else
! create new
open(unitoutfactor,file=path(2)(1:length(2))//'factor_dryreceptor',form='unformatted',&
status='new',action='write')
endif
write(unitoutfactor) itime
write(unitoutfactor) (factor_dryrecept(i),i=1,numreceptor)
close(unitoutfactor)
endif
! Reinitialization of grid
!*************************
......
!**********************************************************************
! Copyright 1998,1999,2000,2001,2002,2005,2007,2008,2009,2010 *
! Andreas Stohl, Petra Seibert, A. Frank, Gerhard Wotawa, *
! Caroline Forster, Sabine Eckhardt, John Burkhart, Harald Sodemann *
! *
! This file is part of FLEXPART. *
! *
! FLEXPART is free software: you can redistribute it and/or modify *
! it under the terms of the GNU General Public License as published by*
! the Free Software Foundation, either version 3 of the License, or *
! (at your option) any later version. *
! *
! FLEXPART is distributed in the hope that it will be useful, *
! but WITHOUT ANY WARRANTY; without even the implied warranty of *
! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
! GNU General Public License for more details. *
! *
! You should have received a copy of the GNU General Public License *
! along with FLEXPART. If not, see <http://www.gnu.org/licenses/>. *
!**********************************************************************
subroutine concoutput_inversion(itime,outnum,gridtotalunc,wetgridtotalunc, &
drygridtotalunc)
! i i o o
! o
!*****************************************************************************
! *
! Output of the concentration grid and the receptor concentrations. *
! *
! Author: A. Stohl *
! *
! 24 May 1995 *
! *
! 13 April 1999, Major update: if output size is smaller, dump output *
! in sparse matrix format; additional output of *
! uncertainty *
! *
! 05 April 2000, Major update: output of age classes; output for backward*
! runs is time spent in grid cell times total mass of *
! species. *
! *
! 17 February 2002, Appropriate dimensions for backward and forward runs *
! are now specified in file par_mod *
! *
! June 2006, write grid in sparse matrix with a single write command *
! in order to save disk space *
! *
! 2008 new sparse matrix format *
!
! January 2017, Separate files by release but include all timesteps
! *
!*****************************************************************************
! *
! Variables: *
! outnum number of samples *
! ncells number of cells with non-zero concentrations *
! sparse .true. if in sparse matrix format, else .false. *
! tot_mu 1 for forward, initial mass mixing ration for backw. runs *
! *
!*****************************************************************************
use unc_mod
use point_mod
use outg_mod
use par_mod
use com_mod
use mean_mod
implicit none
real(kind=dp) :: jul
integer :: itime,i,ix,jy,kz,ks,kp,l,iix,jjy,kzz,nage,jjjjmmdd,ihmmss
integer :: sp_count_i,sp_count_r
real :: sp_fact
real :: outnum,densityoutrecept(maxreceptor),xl,yl
! RLT
real :: densitydryrecept(maxreceptor)
real :: factor_dryrecept(maxreceptor)
!real densityoutgrid(0:numxgrid-1,0:numygrid-1,numzgrid),
! +grid(0:numxgrid-1,0:numygrid-1,numzgrid,maxspec,maxpointspec_act,
! + maxageclass)
!real wetgrid(0:numxgrid-1,0:numygrid-1,maxspec,maxpointspec_act,
! + maxageclass)
!real drygrid(0:numxgrid-1,0:numygrid-1,maxspec,
! + maxpointspec_act,maxageclass)
!real gridsigma(0:numxgrid-1,0:numygrid-1,numzgrid,maxspec,
! + maxpointspec_act,maxageclass),
! + drygridsigma(0:numxgrid-1,0:numygrid-1,maxspec,
! + maxpointspec_act,maxageclass),
! + wetgridsigma(0:numxgrid-1,0:numygrid-1,maxspec,
! + maxpointspec_act,maxageclass)
!real factor(0:numxgrid-1,0:numygrid-1,numzgrid)
!real sparse_dump_r(numxgrid*numygrid*numzgrid)
!integer sparse_dump_i(numxgrid*numygrid*numzgrid)
!real sparse_dump_u(numxgrid*numygrid*numzgrid)
real(dep_prec) :: auxgrid(nclassunc)
real(sp) :: gridtotal,gridsigmatotal,gridtotalunc
real(dep_prec) :: wetgridtotal,wetgridsigmatotal,wetgridtotalunc
real(dep_prec) :: drygridtotal,drygridsigmatotal,drygridtotalunc
real :: halfheight,dz,dz1,dz2,tot_mu(maxspec,maxpointspec_act)
real,parameter :: smallnum = tiny(0.0) ! smallest number that can be handled
real,parameter :: weightair=28.97
logical :: sp_zer
character :: adate*8,atime*6
character(len=3) :: anspec
logical :: lexist
character :: areldate*8,areltime*6
logical,save :: lstart=.true.
logical,save,allocatable,dimension(:) :: lstartrel
integer :: ierr
character(LEN=100) :: dates_char
integer, parameter :: unitrelnames=654
if(lstart) then
allocate(lstartrel(maxpointspec_act))
lstartrel(:)=.true.
endif
print*, 'lstartrel = ',lstartrel
if (verbosity.eq.1) then
print*,'inside concoutput_inversion '
CALL SYSTEM_CLOCK(count_clock)
WRITE(*,*) 'SYSTEM_CLOCK',count_clock - count_clock0
endif
! Determine current calendar date
!**********************************************************
jul=bdate+real(itime,kind=dp)/86400._dp
call caldate(jul,jjjjmmdd,ihmmss)
write(adate,'(i8.8)') jjjjmmdd
write(atime,'(i6.6)') ihmmss
! write(unitdates,'(a)') adate//atime
! Prepare output files for dates
!**********************************************************
! Overwrite existing dates file on first call, later append to it
! If 'dates' file exists in output directory, copy to new file dates.old
inquire(file=path(2)(1:length(2))//'dates', exist=lexist)
if (lexist.and.lstart) then
! copy contents of existing dates file to dates.old
print*, 'warning: replacing old dates file'
open(unit=unitdates, file=path(2)(1:length(2))//'dates',form='formatted', &
&access='sequential', status='old', action='read', iostat=ierr)
open(unit=unittmp, file=path(2)(1:length(2))//'dates.old', access='sequential', &
&status='replace', action='write', form='formatted', iostat=ierr)
do while (.true.)
read(unitdates, '(a)', iostat=ierr) dates_char
if (ierr.ne.0) exit
write(unit=unittmp, fmt='(a)', iostat=ierr, advance='yes') trim(dates_char)
end do
close(unit=unitdates)
close(unit=unittmp)
! create new dates file
open(unit=unitdates, file=path(2)(1:length(2))//'dates',form='formatted', &
&access='sequential', status='replace', iostat=ierr)
close(unit=unitdates)
endif
open(unitdates,file=path(2)(1:length(2))//'dates', ACCESS='APPEND')
write(unitdates,'(a)') adate//atime
close(unitdates)
!CGZ: Make a filename with names of releases
if (lstart) then
open(unit=unitrelnames, file=path(2)(1:length(2))//'releases_out',form='formatted', &
&access='sequential', status='replace', iostat=ierr)
close(unitrelnames)
endif
print*, 'after creating dates files: lstart = ',lstart
! print*, 'outnum:',outnum
! print*, 'datetime:',adate//atime
! For forward simulations, output fields have dimension MAXSPEC,
! for backward simulations, output fields have dimension MAXPOINT.
! Thus, make loops either about nspec, or about numpoint
!*****************************************************************
if (ldirect.eq.1) then
do ks=1,nspec
do kp=1,maxpointspec_act
tot_mu(ks,kp)=1
end do
end do
else
do ks=1,nspec
do kp=1,maxpointspec_act
tot_mu(ks,kp)=xmass(kp,ks)
end do
end do
endif
if (verbosity.eq.1) then
print*,'concoutput_inversion 2'
CALL SYSTEM_CLOCK(count_clock)
WRITE(*,*) 'SYSTEM_CLOCK',count_clock - count_clock0
endif
!*******************************************************************
! Compute air density: sufficiently accurate to take it
! from coarse grid at some time
! Determine center altitude of output layer, and interpolate density
! data to that altitude
!*******************************************************************
do kz=1,numzgrid
if (kz.eq.1) then
halfheight=outheight(1)/2.
else
halfheight=(outheight(kz)+outheight(kz-1))/2.
endif
do kzz=2,nz
if ((height(kzz-1).lt.halfheight).and. &
(height(kzz).gt.halfheight)) goto 46
end do
46 kzz=max(min(kzz,nz),2)
dz1=halfheight-height(kzz-1)
dz2=height(kzz)-halfheight
dz=dz1+dz2
do jy=0,numygrid-1
do ix=0,numxgrid-1
xl=outlon0+real(ix)*dxout
yl=outlat0+real(jy)*dyout
xl=(xl-xlon0)/dx
yl=(yl-ylat0)/dy
iix=max(min(nint(xl),nxmin1),0)
jjy=max(min(nint(yl),nymin1),0)
densityoutgrid(ix,jy,kz)=(rho(iix,jjy,kzz,2)*dz1+ &
rho(iix,jjy,kzz-1,2)*dz2)/dz
! RLT
densitydrygrid(ix,jy,kz)=(rho_dry(iix,jjy,kzz,2)*dz1+ &
rho_dry(iix,jjy,kzz-1,2)*dz2)/dz
end do
end do
end do
do i=1,numreceptor
xl=xreceptor(i)
yl=yreceptor(i)
iix=max(min(nint(xl),nxmin1),0)
jjy=max(min(nint(yl),nymin1),0)
densityoutrecept(i)=rho(iix,jjy,1,2)
! RLT
densitydryrecept(i)=rho_dry(iix,jjy,1,2)
end do
! RLT
! conversion factor for output relative to dry air
factor_drygrid=densityoutgrid/densitydrygrid
factor_dryrecept=densityoutrecept/densitydryrecept