!*********************************************************************** !* Copyright 2012,2013 * !* Jerome Brioude, Delia Arnold, Andreas Stohl, Wayne Angevine, * !* John Burkhart, Massimo Cassiani, Adam Dingwell, Richard C Easter, Sabine Eckhardt,* !* Stephanie Evan, Jerome D Fast, Don Morton, Ignacio Pisso, * !* Petra Seibert, Gerard Wotawa, Caroline Forster, Harald Sodemann, * !* * !* This file is part of FLEXPART WRF * !* * !* 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 . * !*********************************************************************** subroutine interpol_rain_nests(yy1,yy2,yy3,iy1,iy2,nxmaxn,nymaxn,nzmax, & maxnests,ngrid,nxn,nyn,memind,xt,yt,level,itime1,itime2,itime, & yint1,yint2,yint3,intiy1,intiy2,icmv) ! i i i i i i ! i i i i i i i i i i i ! o o o !**************************************************************************** ! * ! Interpolation of meteorological fields on 2-d model layers for nested * ! grids. This routine is related to levlin3interpol.f for the mother domain* ! * ! In horizontal direction bilinear interpolation interpolation is used. * ! Temporally a linear interpolation is used. * ! Three fields are interpolated at the same time. * ! * ! This is a special version of levlininterpol to save CPU time. * ! * ! 1 first time * ! 2 second time * ! * ! * ! Author: A. Stohl * ! * ! 15 March 2000 * ! * !**************************************************************************** ! * ! Variables: * ! * ! dt1,dt2 time differences between fields and current position * ! dz1,dz2 z distance between levels and current position * ! height(nzmax) heights of the model levels * ! indexh help variable * ! indz the level closest to the current trajectory position * ! indzh help variable * ! itime current time * ! itime1 time of the first wind field * ! itime2 time of the second wind field * ! ix,jy x,y coordinates of lower left subgrid point * ! level level at which interpolation shall be done * ! memind(3) points to the places of the wind fields * ! nx,ny actual field dimensions in x,y and z direction * ! nxmax,nymax,nzmax maximum field dimensions in x,y and z direction * ! xt current x coordinate * ! yint the final interpolated value * ! yt current y coordinate * ! yy(0:nxmax,0:nymax,nzmax,3) meteorological field used for interpolation * ! zt current z coordinate * ! * ! Changed 10/22/2007 yy1,yy2 are accumulated rain (mm) ! convert them into hourly rain (mm/hr) !**************************************************************************** implicit none integer :: maxnests,ngrid integer :: nxn(maxnests),nyn(maxnests),nxmaxn,nymaxn,nzmax,memind(2) integer :: m,ix,jy,ixp,jyp,itime,itime1,itime2,level,indexh,i1,i2 integer :: ip1,ip2,ip3,ip4 integer :: intiy1,intiy2,ipsum,icmv real :: yy1(0:nxmaxn-1,0:nymaxn-1,nzmax,2,maxnests) real :: yy2(0:nxmaxn-1,0:nymaxn-1,nzmax,2,maxnests) real :: yy3(0:nxmaxn-1,0:nymaxn-1,nzmax,2,maxnests) integer :: iy1(0:nxmaxn-1,0:nymaxn-1,2,maxnests) integer :: iy2(0:nxmaxn-1,0:nymaxn-1,2,maxnests) real :: ddx,ddy,rddx,rddy,dt1,dt2,dt,y1(2),y2(2),y3(2),yi1(2),yi2(2) real :: xt,yt,yint1,yint2,yint3,yint4,p1,p2,p3,p4 ! If point at border of grid -> small displacement into grid !*********************************************************** if (xt.ge.real(nxn(ngrid)-1)) xt=real(nxn(ngrid)-1)-0.00001 if (yt.ge.real(nyn(ngrid)-1)) yt=real(nyn(ngrid)-1)-0.00001 !********************************************************************** ! 1.) Bilinear horizontal interpolation ! This has to be done separately for 2 fields (Temporal) !******************************************************* ! Determine the lower left corner and its distance to the current position !************************************************************************* ix=int(xt) jy=int(yt) ixp=ix+1 jyp=jy+1 ddx=xt-real(ix) ddy=yt-real(jy) rddx=1.-ddx rddy=1.-ddy p1=rddx*rddy p2=ddx*rddy p3=rddx*ddy p4=ddx*ddy ! Loop over 2 time steps !*********************** ! y1 and y2 are accumulated rain, need change to hourly rain i1=memind(1) i2=memind(2) ! time interval between two fields, second to hour dt=real(itime2-itime1)/3600.0 yint1=p1*(yy1(ix ,jy ,level,i2,ngrid)- & yy1(ix ,jy ,level,i1,ngrid)) & + p2*(yy1(ixp,jy ,level,i2,ngrid)- & yy1(ixp,jy ,level,i1,ngrid)) & + p3*(yy1(ix ,jyp,level,i2,ngrid)- & yy1(ix ,jyp,level,i1,ngrid)) & + p4*(yy1(ixp,jyp,level,i2,ngrid)- & yy1(ixp,jyp,level,i1,ngrid)) yint1=yint1/dt yint2=p1*(yy2(ix ,jy ,level,i2,ngrid)- & yy2(ix ,jy ,level,i1,ngrid)) & + p2*(yy2(ixp,jy ,level,i2,ngrid)- & yy2(ixp,jy ,level,i1,ngrid)) & + p3*(yy2(ix ,jyp,level,i2,ngrid)- & yy2(ix ,jyp,level,i1,ngrid)) & + p4*(yy2(ixp,jyp,level,i2,ngrid)- & yy2(ixp,jyp,level,i1,ngrid)) yint2=yint2/dt ! Y3 is cloud fraction in an hour do m=1,2 indexh=memind(m) y3(m)=p1*yy3(ix ,jy ,level,indexh,ngrid) & + p2*yy3(ixp,jy ,level,indexh,ngrid) & + p3*yy3(ix ,jyp,level,indexh,ngrid) & + p4*yy3(ixp,jyp,level,indexh,ngrid) enddo ! CDA new clouds do m=1,2 indexh=memind(m) ip1=1 ip2=1 ip3=1 ip4=1 if (iy1(ix ,jy ,indexh,ngrid) .eq. icmv) ip1=0 if (iy1(ixp,jy ,indexh,ngrid) .eq. icmv) ip2=0 if (iy1(ix ,jyp,indexh,ngrid) .eq. icmv) ip3=0 if (iy1(ixp,jyp,indexh,ngrid) .eq. icmv) ip4=0 ipsum= ip1+ip2+ip3+ip4 if (ipsum .eq. 0) then yi1(m)=icmv else yi1(m)=(ip1*p1*iy1(ix ,jy ,indexh,ngrid) & + ip2*p2*iy1(ixp,jy ,indexh,ngrid) & + ip3*p3*iy1(ix ,jyp,indexh,ngrid) & + ip4*p4*iy1(ixp,jyp,indexh,ngrid))/ipsum endif ip1=1 ip2=1 ip3=1 ip4=1 if (iy2(ix ,jy ,indexh,ngrid) .eq. icmv) ip1=0 if (iy2(ixp,jy ,indexh,ngrid) .eq. icmv) ip2=0 if (iy2(ix ,jyp,indexh,ngrid) .eq. icmv) ip3=0 if (iy2(ixp,jyp,indexh,ngrid) .eq. icmv) ip4=0 ipsum= ip1+ip2+ip3+ip4 if (ipsum .eq. 0) then yi2(m)=icmv else yi2(m)=(ip1*p1*iy2(ix ,jy ,indexh,ngrid) & + ip2*p2*iy2(ixp,jy ,indexh,ngrid) & + ip3*p3*iy2(ix ,jyp,indexh,ngrid) & + ip4*p4*iy2(ixp,jyp,indexh,ngrid))/ipsum endif ip1=1 ip2=1 ip3=1 ip4=1 if (iy2(ix ,jy ,indexh,ngrid) .eq. icmv) ip1=0 if (iy2(ixp,jy ,indexh,ngrid) .eq. icmv) ip2=0 if (iy2(ix ,jyp,indexh,ngrid) .eq. icmv) ip3=0 if (iy2(ixp,jyp,indexh,ngrid) .eq. icmv) ip4=0 ipsum= ip1+ip2+ip3+ip4 if (ipsum .eq. 0) then yi2(m)=icmv else yi2(m)=(ip1*p1*iy2(ix ,jy ,indexh,ngrid) & + ip2*p2*iy2(ixp,jy ,indexh,ngrid) & + ip3*p3*iy2(ix ,jyp,indexh,ngrid) & + ip4*p4*iy2(ixp,jyp,indexh,ngrid))/ipsum endif enddo !CPS end clouds 10 continue !************************************ ! 2.) Temporal interpolation (linear) !************************************ dt1=real(itime-itime1) dt2=real(itime2-itime) dt=dt1+dt2 ! yint1=(y1(1)*dt2+y1(2)*dt1)/dt ! yint2=(y2(1)*dt2+y2(2)*dt1)/dt yint3=(y3(1)*dt2+y3(2)*dt1)/dt !CPS clouds: intiy1=(yi1(1)*dt2 + yi1(2)*dt1)/dt if (yi1(1) .eq. float(icmv)) intiy1=yi1(2) if (yi1(2) .eq. float(icmv)) intiy1=yi1(1) intiy2=(yi2(1)*dt2 + yi2(2)*dt1)/dt if (yi2(1) .eq. float(icmv)) intiy2=yi2(2) if (yi2(2) .eq. float(icmv)) intiy2=yi2(1) if (intiy1 .ne. icmv .and. intiy2 .ne. icmv) then intiy2 = intiy1 + intiy2 ! convert cloud thickness to cloud top else intiy1=icmv intiy2=icmv endif !CPS end clouds end subroutine interpol_rain_nests