[e200b7a] | 1 | !********************************************************************** |
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| 2 | ! Copyright 1998,1999,2000,2001,2002,2005,2007,2008,2009,2010 * |
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| 3 | ! Andreas Stohl, Petra Seibert, A. Frank, Gerhard Wotawa, * |
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| 4 | ! Caroline Forster, Sabine Eckhardt, John Burkhart, Harald Sodemann * |
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| 5 | ! * |
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| 6 | ! This file is part of FLEXPART. * |
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| 7 | ! * |
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| 8 | ! FLEXPART is free software: you can redistribute it and/or modify * |
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| 9 | ! it under the terms of the GNU General Public License as published by* |
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| 10 | ! the Free Software Foundation, either version 3 of the License, or * |
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| 11 | ! (at your option) any later version. * |
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| 12 | ! * |
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| 13 | ! FLEXPART is distributed in the hope that it will be useful, * |
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| 14 | ! but WITHOUT ANY WARRANTY; without even the implied warranty of * |
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| 15 | ! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * |
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| 16 | ! GNU General Public License for more details. * |
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| 17 | ! * |
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| 18 | ! You should have received a copy of the GNU General Public License * |
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| 19 | ! along with FLEXPART. If not, see <http://www.gnu.org/licenses/>. * |
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| 20 | !********************************************************************** |
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| 21 | |
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| 22 | subroutine readwind(indj,n,uuh,vvh,wwh) |
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| 23 | |
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| 24 | !********************************************************************** |
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| 25 | ! * |
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| 26 | ! TRAJECTORY MODEL SUBROUTINE READWIND * |
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| 27 | ! * |
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| 28 | !********************************************************************** |
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| 29 | ! * |
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| 30 | ! AUTHOR: G. WOTAWA * |
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| 31 | ! DATE: 1997-08-05 * |
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| 32 | ! LAST UPDATE: 2000-10-17, Andreas Stohl * |
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| 33 | ! * |
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| 34 | !********************************************************************** |
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| 35 | ! Changes, Bernd C. Krueger, Feb. 2001: |
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| 36 | ! Variables tth and qvh (on eta coordinates) in common block |
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| 37 | !********************************************************************** |
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| 38 | ! * |
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| 39 | ! DESCRIPTION: * |
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| 40 | ! * |
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| 41 | ! READING OF ECMWF METEOROLOGICAL FIELDS FROM INPUT DATA FILES. THE * |
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| 42 | ! INPUT DATA FILES ARE EXPECTED TO BE AVAILABLE IN GRIB CODE * |
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| 43 | ! * |
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| 44 | ! INPUT: * |
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| 45 | ! indj indicates number of the wind field to be read in * |
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| 46 | ! n temporal index for meteorological fields (1 to 3)* |
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| 47 | ! * |
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| 48 | ! IMPORTANT VARIABLES FROM COMMON BLOCK: * |
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| 49 | ! * |
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| 50 | ! wfname File name of data to be read in * |
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| 51 | ! nx,ny,nuvz,nwz expected field dimensions * |
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| 52 | ! nlev_ec number of vertical levels ecmwf model * |
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| 53 | ! uu,vv,ww wind fields * |
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| 54 | ! tt,qv temperature and specific humidity * |
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| 55 | ! ps surface pressure * |
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| 56 | ! * |
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| 57 | !********************************************************************** |
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| 58 | |
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| 59 | use par_mod |
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| 60 | use com_mod |
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| 61 | |
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| 62 | implicit none |
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| 63 | |
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| 64 | real :: uuh(0:nxmax-1,0:nymax-1,nuvzmax) |
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| 65 | real :: vvh(0:nxmax-1,0:nymax-1,nuvzmax) |
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| 66 | real :: wwh(0:nxmax-1,0:nymax-1,nwzmax) |
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| 67 | integer :: indj,i,j,k,n,levdiff2,ifield,iumax,iwmax,lunit |
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| 68 | |
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| 69 | ! VARIABLES AND ARRAYS NEEDED FOR GRIB DECODING |
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| 70 | |
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| 71 | ! dimension of isec2 at least (22+n), where n is the number of parallels or |
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| 72 | ! meridians in a quasi-regular (reduced) Gaussian or lat/long grid |
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| 73 | |
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| 74 | ! dimension of zsec2 at least (10+nn), where nn is the number of vertical |
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| 75 | ! coordinate parameters |
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| 76 | |
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| 77 | integer :: isec0(2),isec1(56),isec2(22+nxmax+nymax),isec3(2) |
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| 78 | integer :: isec4(64),inbuff(jpack),ilen,ierr,iword |
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| 79 | !integer iswap |
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| 80 | real :: zsec2(60+2*nuvzmax),zsec3(2),zsec4(jpunp) |
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| 81 | real :: xaux,yaux,xaux0,yaux0 |
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| 82 | real,parameter :: eps=1.e-4 |
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| 83 | real :: ewss(0:nxmax-1,0:nymax-1),nsss(0:nxmax-1,0:nymax-1) |
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| 84 | real :: plev1,pmean,tv,fu,hlev1,ff10m,fflev1 |
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| 85 | |
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| 86 | character(len=1) :: yoper = 'D' |
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| 87 | logical :: hflswitch,strswitch |
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| 88 | |
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| 89 | hflswitch=.false. |
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| 90 | strswitch=.false. |
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| 91 | levdiff2=nlev_ec-nwz+1 |
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| 92 | iumax=0 |
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| 93 | iwmax=0 |
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| 94 | |
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| 95 | ! |
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| 96 | ! OPENING OF DATA FILE (GRIB CODE) |
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| 97 | ! |
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| 98 | 5 call pbopen(lunit,path(3)(1:length(3))//wfname(indj),'r',ierr) |
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| 99 | if(ierr.lt.0) goto 999 |
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| 100 | |
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| 101 | ifield=0 |
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| 102 | 10 ifield=ifield+1 |
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| 103 | ! |
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| 104 | ! GET NEXT FIELDS |
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| 105 | ! |
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| 106 | call pbgrib(lunit,inbuff,jpack,ilen,ierr) |
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| 107 | if(ierr.eq.-1) goto 50 ! EOF DETECTED |
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| 108 | if(ierr.lt.-1) goto 888 ! ERROR DETECTED |
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| 109 | |
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| 110 | ierr=1 |
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| 111 | |
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| 112 | ! Check whether we are on a little endian or on a big endian computer |
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| 113 | !******************************************************************** |
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| 114 | |
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| 115 | !if (inbuff(1).eq.1112101447) then ! little endian, swap bytes |
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| 116 | ! iswap=1+ilen/4 |
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| 117 | ! call swap32(inbuff,iswap) |
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| 118 | !else if (inbuff(1).ne.1196575042) then ! big endian |
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| 119 | ! stop 'subroutine gridcheck: corrupt GRIB data' |
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| 120 | !endif |
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| 121 | |
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| 122 | |
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| 123 | call gribex(isec0,isec1,isec2,zsec2,isec3,zsec3,isec4, & |
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| 124 | zsec4,jpunp,inbuff,jpack,iword,yoper,ierr) |
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| 125 | if (ierr.ne.0) goto 888 ! ERROR DETECTED |
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| 126 | |
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| 127 | if(ifield.eq.1) then |
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| 128 | |
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| 129 | ! CHECK GRID SPECIFICATIONS |
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| 130 | |
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| 131 | if(isec2(2).ne.nxfield) stop 'READWIND: NX NOT CONSISTENT' |
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| 132 | if(isec2(3).ne.ny) stop 'READWIND: NY NOT CONSISTENT' |
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| 133 | if(isec2(12)/2-1.ne.nlev_ec) & |
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| 134 | stop 'READWIND: VERTICAL DISCRETIZATION NOT CONSISTENT' |
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| 135 | xaux=real(isec2(5))/1000.+real(nxshift)*dx |
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| 136 | yaux=real(isec2(7))/1000. |
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| 137 | xaux0=xlon0 |
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| 138 | yaux0=ylat0 |
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| 139 | if(xaux.lt.0.) xaux=xaux+360. |
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| 140 | if(yaux.lt.0.) yaux=yaux+360. |
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| 141 | if(xaux0.lt.0.) xaux0=xaux0+360. |
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| 142 | if(yaux0.lt.0.) yaux0=yaux0+360. |
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| 143 | if(abs(xaux-xaux0).gt.eps) & |
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| 144 | stop 'READWIND: LOWER LEFT LONGITUDE NOT CONSISTENT' |
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| 145 | if(abs(yaux-yaux0).gt.eps) & |
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| 146 | stop 'READWIND: LOWER LEFT LATITUDE NOT CONSISTENT' |
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| 147 | endif |
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| 148 | |
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| 149 | do j=0,nymin1 |
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| 150 | do i=0,nxfield-1 |
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| 151 | k=isec1(8) |
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| 152 | if(isec1(6).eq.130) tth(i,j,nlev_ec-k+2,n)= &!! TEMPERATURE |
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| 153 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 154 | if(isec1(6).eq.131) uuh(i,j,nlev_ec-k+2)= &!! U VELOCITY |
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| 155 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 156 | if(isec1(6).eq.132) vvh(i,j,nlev_ec-k+2)= &!! V VELOCITY |
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| 157 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 158 | if(isec1(6).eq.133) then !! SPEC. HUMIDITY |
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| 159 | qvh(i,j,nlev_ec-k+2,n)=zsec4(nxfield*(ny-j-1)+i+1) |
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| 160 | if (qvh(i,j,nlev_ec-k+2,n) .lt. 0.) & |
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| 161 | qvh(i,j,nlev_ec-k+2,n) = 0. |
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| 162 | ! this is necessary because the gridded data may contain |
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| 163 | ! spurious negative values |
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| 164 | endif |
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| 165 | if(isec1(6).eq.134) ps(i,j,1,n)= &!! SURF. PRESS. |
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| 166 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 167 | |
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| 168 | if(isec1(6).eq.135) wwh(i,j,nlev_ec-k+1)= &!! W VELOCITY |
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| 169 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 170 | if(isec1(6).eq.141) sd(i,j,1,n)= &!! SNOW DEPTH |
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| 171 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 172 | if(isec1(6).eq.151) msl(i,j,1,n)= &!! SEA LEVEL PRESS. |
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| 173 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 174 | if(isec1(6).eq.164) tcc(i,j,1,n)= &!! CLOUD COVER |
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| 175 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 176 | if(isec1(6).eq.165) u10(i,j,1,n)= &!! 10 M U VELOCITY |
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| 177 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 178 | if(isec1(6).eq.166) v10(i,j,1,n)= &!! 10 M V VELOCITY |
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| 179 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 180 | if(isec1(6).eq.167) tt2(i,j,1,n)= &!! 2 M TEMPERATURE |
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| 181 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 182 | if(isec1(6).eq.168) td2(i,j,1,n)= &!! 2 M DEW POINT |
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| 183 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 184 | if(isec1(6).eq.142) then !! LARGE SCALE PREC. |
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| 185 | lsprec(i,j,1,n)=zsec4(nxfield*(ny-j-1)+i+1) |
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| 186 | if (lsprec(i,j,1,n).lt.0.) lsprec(i,j,1,n)=0. |
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| 187 | endif |
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| 188 | if(isec1(6).eq.143) then !! CONVECTIVE PREC. |
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| 189 | convprec(i,j,1,n)=zsec4(nxfield*(ny-j-1)+i+1) |
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| 190 | if (convprec(i,j,1,n).lt.0.) convprec(i,j,1,n)=0. |
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| 191 | endif |
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| 192 | if(isec1(6).eq.146) sshf(i,j,1,n)= &!! SENS. HEAT FLUX |
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| 193 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 194 | if((isec1(6).eq.146).and.(zsec4(nxfield*(ny-j-1)+i+1).ne.0.)) & |
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| 195 | hflswitch=.true. ! Heat flux available |
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| 196 | if(isec1(6).eq.176) then !! SOLAR RADIATION |
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| 197 | ssr(i,j,1,n)=zsec4(nxfield*(ny-j-1)+i+1) |
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| 198 | if (ssr(i,j,1,n).lt.0.) ssr(i,j,1,n)=0. |
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| 199 | endif |
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| 200 | if(isec1(6).eq.180) ewss(i,j)= &!! EW SURFACE STRESS |
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| 201 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 202 | if(isec1(6).eq.181) nsss(i,j)= &!! NS SURFACE STRESS |
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| 203 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 204 | if(((isec1(6).eq.180).or.(isec1(6).eq.181)).and. & |
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| 205 | (zsec4(nxfield*(ny-j-1)+i+1).ne.0.)) strswitch=.true. ! stress available |
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| 206 | if(isec1(6).eq.129) oro(i,j)= &!! ECMWF OROGRAPHY |
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| 207 | zsec4(nxfield*(ny-j-1)+i+1)/ga |
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| 208 | if(isec1(6).eq.160) excessoro(i,j)= &!! STANDARD DEVIATION OF OROGRAPHY |
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| 209 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 210 | if(isec1(6).eq.172) lsm(i,j)= &!! ECMWF LAND SEA MASK |
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| 211 | zsec4(nxfield*(ny-j-1)+i+1) |
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| 212 | if(isec1(6).eq.131) iumax=max(iumax,nlev_ec-k+1) |
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| 213 | if(isec1(6).eq.135) iwmax=max(iwmax,nlev_ec-k+1) |
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| 214 | end do |
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| 215 | end do |
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| 216 | |
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| 217 | goto 10 !! READ NEXT LEVEL OR PARAMETER |
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| 218 | ! |
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| 219 | ! CLOSING OF INPUT DATA FILE |
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| 220 | ! |
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| 221 | 50 call pbclose(lunit,ierr) !! FINNISHED READING / CLOSING GRIB FILE |
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| 222 | |
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| 223 | if(levdiff2.eq.0) then |
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| 224 | iwmax=nlev_ec+1 |
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| 225 | do i=0,nxmin1 |
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| 226 | do j=0,nymin1 |
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| 227 | wwh(i,j,nlev_ec+1)=0. |
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| 228 | end do |
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| 229 | end do |
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| 230 | endif |
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| 231 | |
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| 232 | |
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| 233 | ! For global fields, assign the leftmost data column also to the rightmost |
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| 234 | ! data column; if required, shift whole grid by nxshift grid points |
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| 235 | !************************************************************************* |
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| 236 | |
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| 237 | if (xglobal) then |
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| 238 | call shift_field_0(ewss,nxfield,ny) |
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| 239 | call shift_field_0(nsss,nxfield,ny) |
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| 240 | call shift_field_0(oro,nxfield,ny) |
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| 241 | call shift_field_0(excessoro,nxfield,ny) |
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| 242 | call shift_field_0(lsm,nxfield,ny) |
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| 243 | call shift_field(ps,nxfield,ny,1,1,2,n) |
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| 244 | call shift_field(sd,nxfield,ny,1,1,2,n) |
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| 245 | call shift_field(msl,nxfield,ny,1,1,2,n) |
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| 246 | call shift_field(tcc,nxfield,ny,1,1,2,n) |
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| 247 | call shift_field(u10,nxfield,ny,1,1,2,n) |
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| 248 | call shift_field(v10,nxfield,ny,1,1,2,n) |
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| 249 | call shift_field(tt2,nxfield,ny,1,1,2,n) |
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| 250 | call shift_field(td2,nxfield,ny,1,1,2,n) |
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| 251 | call shift_field(lsprec,nxfield,ny,1,1,2,n) |
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| 252 | call shift_field(convprec,nxfield,ny,1,1,2,n) |
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| 253 | call shift_field(sshf,nxfield,ny,1,1,2,n) |
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| 254 | call shift_field(ssr,nxfield,ny,1,1,2,n) |
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| 255 | call shift_field(tth,nxfield,ny,nuvzmax,nuvz,2,n) |
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| 256 | call shift_field(qvh,nxfield,ny,nuvzmax,nuvz,2,n) |
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| 257 | call shift_field(uuh,nxfield,ny,nuvzmax,nuvz,1,1) |
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| 258 | call shift_field(vvh,nxfield,ny,nuvzmax,nuvz,1,1) |
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| 259 | call shift_field(wwh,nxfield,ny,nwzmax,nwz,1,1) |
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| 260 | endif |
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| 261 | |
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| 262 | do i=0,nxmin1 |
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| 263 | do j=0,nymin1 |
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| 264 | surfstr(i,j,1,n)=sqrt(ewss(i,j)**2+nsss(i,j)**2) |
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| 265 | end do |
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| 266 | end do |
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| 267 | |
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| 268 | if ((.not.hflswitch).or.(.not.strswitch)) then |
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| 269 | write(*,*) 'WARNING: No flux data contained in GRIB file ', & |
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| 270 | wfname(indj) |
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| 271 | |
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| 272 | ! CALCULATE USTAR AND SSHF USING THE PROFILE METHOD |
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| 273 | ! As ECMWF has increased the model resolution, such that now the first model |
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| 274 | ! level is at about 10 m (where 10-m wind is given), use the 2nd ECMWF level |
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| 275 | ! (3rd model level in FLEXPART) for the profile method |
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| 276 | !*************************************************************************** |
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| 277 | |
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| 278 | do i=0,nxmin1 |
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| 279 | do j=0,nymin1 |
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| 280 | plev1=akz(3)+bkz(3)*ps(i,j,1,n) |
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| 281 | pmean=0.5*(ps(i,j,1,n)+plev1) |
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| 282 | tv=tth(i,j,3,n)*(1.+0.61*qvh(i,j,3,n)) |
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| 283 | fu=-r_air*tv/ga/pmean |
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| 284 | hlev1=fu*(plev1-ps(i,j,1,n)) ! HEIGTH OF FIRST MODEL LAYER |
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| 285 | ff10m= sqrt(u10(i,j,1,n)**2+v10(i,j,1,n)**2) |
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| 286 | fflev1=sqrt(uuh(i,j,3)**2+vvh(i,j,3)**2) |
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| 287 | call pbl_profile(ps(i,j,1,n),td2(i,j,1,n),hlev1, & |
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| 288 | tt2(i,j,1,n),tth(i,j,3,n),ff10m,fflev1, & |
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| 289 | surfstr(i,j,1,n),sshf(i,j,1,n)) |
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| 290 | if(sshf(i,j,1,n).gt.200.) sshf(i,j,1,n)=200. |
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| 291 | if(sshf(i,j,1,n).lt.-400.) sshf(i,j,1,n)=-400. |
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| 292 | end do |
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| 293 | end do |
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| 294 | endif |
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| 295 | |
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| 296 | |
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| 297 | ! Assign 10 m wind to model level at eta=1.0 to have one additional model |
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| 298 | ! level at the ground |
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| 299 | ! Specific humidity is taken the same as at one level above |
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| 300 | ! Temperature is taken as 2 m temperature |
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| 301 | !************************************************************************** |
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| 302 | |
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| 303 | do i=0,nxmin1 |
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| 304 | do j=0,nymin1 |
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| 305 | uuh(i,j,1)=u10(i,j,1,n) |
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| 306 | vvh(i,j,1)=v10(i,j,1,n) |
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| 307 | qvh(i,j,1,n)=qvh(i,j,2,n) |
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| 308 | tth(i,j,1,n)=tt2(i,j,1,n) |
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| 309 | end do |
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| 310 | end do |
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| 311 | |
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| 312 | if(iumax.ne.nuvz-1) stop 'READWIND: NUVZ NOT CONSISTENT' |
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| 313 | if(iwmax.ne.nwz) stop 'READWIND: NWZ NOT CONSISTENT' |
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| 314 | |
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| 315 | return |
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| 316 | 888 write(*,*) ' #### FLEXPART MODEL ERROR! WINDFIELD #### ' |
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| 317 | write(*,*) ' #### ',wfname(indj),' #### ' |
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| 318 | write(*,*) ' #### IS NOT GRIB FORMAT !!! #### ' |
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| 319 | stop 'Execution terminated' |
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| 320 | 999 write(*,*) ' #### FLEXPART MODEL ERROR! WINDFIELD #### ' |
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| 321 | write(*,*) ' #### ',wfname(indj),' #### ' |
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| 322 | write(*,*) ' #### CANNOT BE OPENED !!! #### ' |
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| 323 | stop 'Execution terminated' |
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| 324 | |
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| 325 | end subroutine readwind |
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