!********************************************************************** ! 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 . * !********************************************************************** subroutine interpol_misslev_nests(n) ! i !***************************************************************************** ! * ! This subroutine interpolates u,v,w, density and density gradients. * ! * ! Author: A. Stohl * ! * ! 16 December 1997 * ! * !***************************************************************************** ! * ! Variables: * ! n level * ! * ! Constants: * ! * !***************************************************************************** use par_mod use com_mod use interpol_mod use hanna_mod implicit none ! Auxiliary variables needed for interpolation real :: y1(2),y2(2),y3(2),rho1(2),rhograd1(2) real :: usl,vsl,wsl,usq,vsq,wsq,xaux integer :: m,n,indexh real,parameter :: eps=1.0e-30 !******************************************** ! Multilinear interpolation in time and space !******************************************** !************************************** ! 1.) Bilinear horizontal interpolation ! 2.) Temporal interpolation (linear) !************************************** ! Loop over 2 time steps !*********************** usl=0. vsl=0. wsl=0. usq=0. vsq=0. wsq=0. do m=1,2 indexh=memind(m) y1(m)=p1*uun(ix ,jy ,n,indexh,ngrid) & +p2*uun(ixp,jy ,n,indexh,ngrid) & +p3*uun(ix ,jyp,n,indexh,ngrid) & +p4*uun(ixp,jyp,n,indexh,ngrid) y2(m)=p1*vvn(ix ,jy ,n,indexh,ngrid) & +p2*vvn(ixp,jy ,n,indexh,ngrid) & +p3*vvn(ix ,jyp,n,indexh,ngrid) & +p4*vvn(ixp,jyp,n,indexh,ngrid) y3(m)=p1*wwn(ix ,jy ,n,indexh,ngrid) & +p2*wwn(ixp,jy ,n,indexh,ngrid) & +p3*wwn(ix ,jyp,n,indexh,ngrid) & +p4*wwn(ixp,jyp,n,indexh,ngrid) rho1(m)=p1*rhon(ix ,jy ,n,indexh,ngrid) & +p2*rhon(ixp,jy ,n,indexh,ngrid) & +p3*rhon(ix ,jyp,n,indexh,ngrid) & +p4*rhon(ixp,jyp,n,indexh,ngrid) rhograd1(m)=p1*drhodzn(ix ,jy ,n,indexh,ngrid) & +p2*drhodzn(ixp,jy ,n,indexh,ngrid) & +p3*drhodzn(ix ,jyp,n,indexh,ngrid) & +p4*drhodzn(ixp,jyp,n,indexh,ngrid) usl=usl+uun(ix ,jy ,n,indexh,ngrid)+uun(ixp,jy ,n,indexh,ngrid) & +uun(ix ,jyp,n,indexh,ngrid)+uun(ixp,jyp,n,indexh,ngrid) vsl=vsl+vvn(ix ,jy ,n,indexh,ngrid)+vvn(ixp,jy ,n,indexh,ngrid) & +vvn(ix ,jyp,n,indexh,ngrid)+vvn(ixp,jyp,n,indexh,ngrid) wsl=wsl+wwn(ix ,jy ,n,indexh,ngrid)+wwn(ixp,jy ,n,indexh,ngrid) & +wwn(ix ,jyp,n,indexh,ngrid)+wwn(ixp,jyp,n,indexh,ngrid) usq=usq+uun(ix ,jy ,n,indexh,ngrid)*uun(ix ,jy ,n,indexh,ngrid)+ & uun(ixp,jy ,n,indexh,ngrid)*uun(ixp,jy ,n,indexh,ngrid)+ & uun(ix ,jyp,n,indexh,ngrid)*uun(ix ,jyp,n,indexh,ngrid)+ & uun(ixp,jyp,n,indexh,ngrid)*uun(ixp,jyp,n,indexh,ngrid) vsq=vsq+vvn(ix ,jy ,n,indexh,ngrid)*vvn(ix ,jy ,n,indexh,ngrid)+ & vvn(ixp,jy ,n,indexh,ngrid)*vvn(ixp,jy ,n,indexh,ngrid)+ & vvn(ix ,jyp,n,indexh,ngrid)*vvn(ix ,jyp,n,indexh,ngrid)+ & vvn(ixp,jyp,n,indexh,ngrid)*vvn(ixp,jyp,n,indexh,ngrid) wsq=wsq+wwn(ix ,jy ,n,indexh,ngrid)*wwn(ix ,jy ,n,indexh,ngrid)+ & wwn(ixp,jy ,n,indexh,ngrid)*wwn(ixp,jy ,n,indexh,ngrid)+ & wwn(ix ,jyp,n,indexh,ngrid)*wwn(ix ,jyp,n,indexh,ngrid)+ & wwn(ixp,jyp,n,indexh,ngrid)*wwn(ixp,jyp,n,indexh,ngrid) end do uprof(n)=(y1(1)*dt2+y1(2)*dt1)*dtt vprof(n)=(y2(1)*dt2+y2(2)*dt1)*dtt wprof(n)=(y3(1)*dt2+y3(2)*dt1)*dtt rhoprof(n)=(rho1(1)*dt2+rho1(2)*dt1)*dtt rhogradprof(n)=(rhograd1(1)*dt2+rhograd1(2)*dt1)*dtt indzindicator(n)=.false. ! Compute standard deviations !**************************** xaux=usq-usl*usl/8. if (xaux.lt.eps) then usigprof(n)=0. else usigprof(n)=sqrt(xaux/7.) endif xaux=vsq-vsl*vsl/8. if (xaux.lt.eps) then vsigprof(n)=0. else vsigprof(n)=sqrt(xaux/7.) endif xaux=wsq-wsl*wsl/8. if (xaux.lt.eps) then wsigprof(n)=0. else wsigprof(n)=sqrt(xaux/7.) endif end subroutine interpol_misslev_nests