C $Header: /u/gcmpack/MITgcm/pkg/fizhi/fizhi_lwrad.F,v 1.26 2010/03/16 00:19:33 jmc Exp $ C $Name: $ #include "FIZHI_OPTIONS.h" subroutine lwrio (nymd,nhms,bi,bj,myid,istrip,npcs, . low_level,mid_level, . im,jm,lm, . pz,plz,plze,dpres,pkht,pkz,tz,qz,oz, . co2,cfc11,cfc12,cfc22,methane,n2o,emissivity, . tgz,radlwg,st4,dst4, . dtradlw,dlwdtg,dtradlwc,lwgclr, . nlwcld,cldlw,clwmo,nlwlz,lwlz, . lpnt,imstturb,qliqave,fccave,landtype) implicit none c Input Variables c --------------- integer nymd,nhms,istrip,npcs,bi,bj,myid integer mid_level,low_level integer im,jm,lm _RL pz(im,jm),plz(im,jm,lm),plze(im,jm,lm+1) _RL dpres(im,jm,lm),pkht(im,jm,lm+1),pkz(im,jm,lm) _RL tz(im,jm,lm),qz(im,jm,lm),oz(im,jm,lm) _RL co2,cfc11,cfc12,cfc22,methane(lm),n2o(lm) _RL emissivity(im,jm,10) _RL tgz(im,jm),radlwg(im,jm),st4(im,jm),dst4(im,jm) _RL dtradlw(im,jm,lm),dlwdtg (im,jm,lm) _RL dtradlwc(im,jm,lm),lwgclr(im,jm) integer nlwcld,nlwlz _RL cldlw(im,jm,lm),clwmo(im,jm,lm),lwlz(im,jm,lm) logical lpnt integer imstturb _RL qliqave(im,jm,lm),fccave(im,jm,lm) integer landtype(im,jm) c Local Variables c --------------- integer i,j,l,n,nn _RL cldtot (im,jm,lm) _RL cldmxo (im,jm,lm) _RL pl(istrip,lm) _RL pk(istrip,lm) _RL pke(istrip,lm) _RL ple(istrip,lm+1) _RL ADELPL(ISTRIP,lm) _RL dtrad(istrip,lm),dtradc(istrip,lm) _RL OZL(ISTRIP,lm),TZL(ISTRIP,lm) _RL SHZL(ISTRIP,lm),CLRO(ISTRIP,lm) _RL CLMO(ISTRIP,lm) _RL flx(ISTRIP,lm+1),flxclr(ISTRIP,lm+1) _RL cldlz(istrip,lm) _RL dfdts(istrip,lm+1),dtdtg(istrip,lm) _RL emiss(istrip,10) _RL taual(istrip,lm,10) _RL ssaal(istrip,lm,10) _RL asyal(istrip,lm,10) _RL cwc(istrip,lm,3) _RL reff(istrip,lm,3) _RL tauc(istrip,lm,3) _RL SGMT4(ISTRIP),TSURF(ISTRIP),dsgmt4(ISTRIP) integer lwi(istrip) _RL tmpstrip(istrip,lm) _RL tmpimjm(im,jm,lm) _RL tempor1(im,jm),tempor2(im,jm) _RL getcon,secday,convrt #ifdef ALLOW_DIAGNOSTICS logical diagnostics_is_on external diagnostics_is_on _RL tmpdiag(im,jm) #endif logical high, trace, cldwater c data high /.true./ c data trace /.true./ data high /.false./ data trace /.false./ data cldwater /.false./ C ********************************************************************** C **** INITIALIZATION **** C ********************************************************************** SECDAY = GETCON('SDAY') CONVRT = GETCON('GRAVITY') / ( 100.0 * GETCON('CP') ) c Adjust cloud fractions and cloud liquid water due to moist turbulence c --------------------------------------------------------------------- if(imstturb.ne.0) then do L =1,lm do j =1,jm do i =1,im cldtot(i,j,L)=min(1.0 _d 0,max(cldlw(i,j,L),fccave(i,j,L)/ $ imstturb)) cldmxo(i,j,L) = min( 1.0 _d 0, clwmo(i,j,L) ) lwlz(i,j,L) = lwlz(i,j,L) + qliqave(i,j,L)/imstturb enddo enddo enddo else do L =1,lm do j =1,jm do i =1,im cldtot(i,j,L) = min( 1.0 _d 0,cldlw(i,j,L) ) cldmxo(i,j,L) = min( 1.0 _d 0,clwmo(i,j,L) ) enddo enddo enddo endif C*********************************************************************** C **** LOOP OVER STRIPS **** C ********************************************************************** DO 1000 NN=1,NPCS C ********************************************************************** C **** VARIABLE INITIALIZATION **** C ********************************************************************** CALL STRIP (OZ,OZL ,im*jm,ISTRIP,lm ,NN) CALL STRIP (PLZE,ple ,im*jm,ISTRIP,lm+1 ,NN) CALL STRIP (PLZ ,pl ,im*jm,ISTRIP,lm ,NN) CALL STRIP (PKZ ,pk ,im*jm,ISTRIP,lm ,NN) CALL STRIP (PKHT,pke ,im*jm,ISTRIP,lm ,NN) CALL STRIP (TZ,TZL ,im*jm,ISTRIP,lm ,NN) CALL STRIP (qz,SHZL ,im*jm,ISTRIP,lm ,NN) CALL STRIP (cldtot,CLRO ,im*jm,ISTRIP,lm ,NN) CALL STRIP (cldmxo,CLMO ,im*jm,ISTRIP,lm ,NN) CALL STRIP (lwlz,cldlz ,im*jm,ISTRIP,lm ,NN) CALL STRIP (tgz,tsurf ,im*jm,ISTRIP,1 ,NN) CALL STRIP (emissivity,emiss,im*jm,ISTRIP,10,NN) call stripitint (landtype,lwi,im*jm,im*jm,istrip,1,nn) DO L = 1,lm DO I = 1,ISTRIP ADELPL(I,L) = convrt / ( ple(I,L+1)-ple(I,L) ) ENDDO ENDDO C Compute Clouds C -------------- IF(NLWCLD.NE.0)THEN DO L = 1,lm DO I = 1,ISTRIP CLRO(I,L) = min( 1.0 _d 0,clro(i,L) ) CLMO(I,L) = min( 1.0 _d 0,clmo(i,L) ) ENDDO ENDDO ENDIF C Convert to Temperature from Fizhi Theta C --------------------------------------- DO L = 1,lm DO I = 1,ISTRIP TZL(I,L) = TZL(I,L)*pk(I,L) ENDDO ENDDO DO I = 1,ISTRIP C To reduce longwave heating in lowest model layer TZL(I,lm) = ( 2*tzl(i,lm)+tsurf(i) )/3.0 ENDDO C Compute Optical Thicknesses C --------------------------- call opthk ( tzl,pl,ple,cldlz,clro,clmo,lwi,istrip,1,lm,tauc ) do n = 1,3 do L = 1,lm do i = 1,istrip tauc(i,L,n) = tauc(i,L,n)*0.75 enddo enddo enddo C Set the optical thickness, single scattering albedo and assymetry factor C for aerosols equal to zero to omit the contribution of aerosols c------------------------------------------------------------------------- do n = 1,10 do L = 1,lm do i = 1,istrip taual(i,L,n) = 0. ssaal(i,L,n) = 0. asyal(i,L,n) = 0. enddo enddo enddo C Set cwc and reff to zero - when cldwater is .false. c---------------------------------------------------- do n = 1,3 do L = 1,lm do i = 1,istrip cwc(i,L,n) = 0. reff(i,L,n) = 0. enddo enddo enddo C ********************************************************************** C **** CALL M-D Chou RADIATION **** C ********************************************************************** call irrad ( istrip,1,1,lm,ple,tzl,shzl,ozl,tsurf,co2, . n2o,methane,cfc11,cfc12,cfc22,emiss, . cldwater,cwc,tauc,reff,clro,mid_level,low_level, . taual,ssaal,asyal, . high,trace,flx,flxclr,dfdts,sgmt4 ) C ********************************************************************** C **** HEATING RATES **** C ********************************************************************** do L = 1,lm do i = 1,istrip dtrad(i,L) = ( flx(i,L)- flx(i,L+1))*adelpl(i,L) tmpstrip(i,L) = flx(i,L) dtdtg(i,L) = ( dfdts(i,L)- dfdts(i,L+1))*adelpl(i,L) dtradc(i,L) = (flxclr(i,L)-flxclr(i,L+1))*adelpl(i,L) enddo enddo C ********************************************************************** C **** NET UPWARD LONGWAVE FLUX (W/M**2) **** C ********************************************************************** DO I = 1,ISTRIP flx (i,1) = -flx (i,1) flxclr(i,1) = -flxclr(i,1) flx (i,lm+1) = -flx (i,lm+1) flxclr(i,lm+1) = -flxclr(i,lm+1) sgmt4(i) = - sgmt4(i) dsgmt4(i) = - dfdts(i,lm+1) ENDDO CALL PASTE ( flx (1,lm+1),RADLWG,ISTRIP,im*jm,1,NN ) CALL PASTE ( flxclr(1,lm+1),LWGCLR,ISTRIP,im*jm,1,NN ) CALL PASTE ( sgmt4, st4,ISTRIP,im*jm,1,NN ) CALL PASTE ( dsgmt4,dst4,ISTRIP,im*jm,1,NN ) C ********************************************************************** C **** PASTE AND BUMP SOME DIAGNOSTICS **** C ********************************************************************** CALL PASTE(flx(1,1),tempor1,ISTRIP,im*jm,1,NN) CALL PASTE(flxclr(1,1),tempor2,ISTRIP,im*jm,1,NN) C ********************************************************************** C **** TENDENCY UPDATES **** C ********************************************************************** DO L = 1,lm DO I = 1,ISTRIP DTRAD (I,L) = ple(i,lm+1) * DTRAD (I,L)/pk(I,L) DTRADC(I,L) = ple(i,lm+1) * DTRADC(I,L)/pk(I,L) dtdtg(I,L) = ple(i,lm+1) * dtdtg (I,L)/pk(I,L) ENDDO ENDDO CALL PASTE ( tmpstrip ,tmpimjm ,ISTRIP,im*jm,lm,NN ) CALL PASTE ( DTRAD ,DTRADLW ,ISTRIP,im*jm,lm,NN ) CALL PASTE ( DTRADC,DTRADLWC,ISTRIP,im*jm,lm,NN ) CALL PASTE ( dtdtg ,dlwdtg ,ISTRIP,im*jm,lm,NN ) 1000 CONTINUE C ********************************************************************** C **** BUMP DIAGNOSTICS **** C ********************************************************************** #ifdef ALLOW_DIAGNOSTICS if(diagnostics_is_on('TGRLW ',myid) ) then call diagnostics_fill(tgz,'TGRLW ',0,1,3,bi,bj,myid) endif do L = 1,lm if(diagnostics_is_on('TLW ',myid) ) then do j = 1,jm do i = 1,im tmpdiag(i,j) = tz(i,j,L)*pkz(i,j,L) enddo enddo call diagnostics_fill(tmpdiag,'TLW ',L,1,3,bi,bj,myid) endif if(diagnostics_is_on('SHRAD ',myid) ) then do j = 1,jm do i = 1,im tmpdiag(i,j) = qz(i,j,L)*1000. enddo enddo call diagnostics_fill(tmpdiag,'SHRAD ',L,1,3,bi,bj,myid) endif if(diagnostics_is_on('OZLW ',myid) ) then do j = 1,jm do i = 1,im tmpdiag(i,j) = oz(i,j,L) enddo enddo call diagnostics_fill(tmpdiag,'OZLW ',L,1,3,bi,bj,myid) endif enddo if(diagnostics_is_on('OLR ',myid) ) then call diagnostics_fill(tempor1,'OLR ',0,1,3,bi,bj,myid) endif if(diagnostics_is_on('OLRCLR ',myid) ) then call diagnostics_fill(tempor2,'OLRCLR ',0,1,3,bi,bj,myid) endif #endif C ********************************************************************** C **** Increment Diagnostics Counters and Zero-Out Cloud Info **** C ********************************************************************** nlwlz = 0 nlwcld = 0 imstturb = 0 do L = 1,lm do j = 1,jm do i = 1,im fccave(i,j,L) = 0. qliqave(i,j,L) = 0. enddo enddo enddo return end c********************** November 26, 1997 ************************** subroutine irrad (m,n,ndim,np,pl,ta,wa,oa,ts,co2, * n2o,ch4,cfc11,cfc12,cfc22,emiss, * cldwater,cwc,taucl,reff,fcld,ict,icb, * taual,ssaal,asyal, * high,trace,flx,flc,dfdts,st4) c*********************************************************************** c c Version IR-5 (September, 1998) c c New features of this version are: c (1) The effect of aerosol scattering on LW fluxes is included. c (2) Absorption and scattering of rain drops are included. c c*********************************************************************** c c Version IR-4 (October, 1997) c c New features of this version are: c (1) The surface is treated as non-black. The surface c emissivity, emiss, is an input parameter c (2) The effect of cloud scattering on LW fluxes is included c c********************************************************************* c c This routine computes ir fluxes due to water vapor, co2, o3, c trace gases (n2o, ch4, cfc11, cfc12, cfc22, co2-minor), c clouds, and aerosols. c c This is a vectorized code. It computes fluxes simultaneously for c (m x n) soundings, which is a subset of (m x ndim) soundings. c In a global climate model, m and ndim correspond to the numbers of c grid boxes in the zonal and meridional directions, respectively. c c Some detailed descriptions of the radiation routine are given in c Chou and Suarez (1994). c c Ice and liquid cloud particles are allowed to co-exist in any of the c np layers. c c If no information is available for the effective cloud particle size, c reff, default values of 10 micron for liquid water and 75 micron c for ice can be used. c c The maximum-random assumption is applied for cloud overlapping. c clouds are grouped into high, middle, and low clouds separated by the c level indices ict and icb. Within each of the three groups, clouds c are assumed maximally overlapped, and the cloud cover of a group is c the maximum cloud cover of all the layers in the group. clouds among c the three groups are assumed randomly overlapped. The indices ict and c icb correpond approximately to the 400 mb and 700 mb levels. c c Aerosols are allowed to be in any of the np layers. Aerosol optical c properties can be specified as functions of height and spectral band. c c There are options for computing fluxes: c c If cldwater=.true., taucl is computed from cwc and reff as a c function of height and spectral band. c If cldwater=.false., taucl must be given as input to the radiation c routine. It is independent of spectral band. c c If high = .true., transmission functions in the co2, o3, and the c three water vapor bands with strong absorption are computed using c table look-up. cooling rates are computed accurately from the c surface up to 0.01 mb. c If high = .false., transmission functions are computed using the c k-distribution method with linear pressure scaling for all spectral c bands and gases. cooling rates are not calculated accurately for c pressures less than 20 mb. the computation is faster with c high=.false. than with high=.true. c If trace = .true., absorption due to n2o, ch4, cfcs, and the c two minor co2 bands in the window region is included. c If trace = .false., absorption in minor bands is neglected. c c The IR spectrum is divided into nine bands: c c band wavenumber (/cm) absorber c c 1 0 - 340 h2o c 2 340 - 540 h2o c 3 540 - 800 h2o,cont,co2,n2o c 4 800 - 980 h2o,cont c co2,f11,f12,f22 c 5 980 - 1100 h2o,cont,o3 c co2,f11 c 6 1100 - 1215 h2o,cont c n2o,ch4,f12,f22 c 7 1215 - 1380 h2o c n2o,ch4 c 8 1380 - 1900 h2o c 9 1900 - 3000 h2o c c In addition, a narrow band in the 15 micrometer region is added to c compute flux reduction due to n2o c c 10 540 - 620 h2o,cont,co2,n2o c c Band 3 (540-800/cm) is further divided into 3 sub-bands : c c subband wavenumber (/cm) c c 1 540 - 620 c 2 620 - 720 c 3 720 - 800 c c---- Input parameters units size c c number of soundings in zonal direction (m) n/d 1 c number of soundings in meridional direction (n) n/d 1 c maximum number of soundings in c meridional direction (ndim>=n) n/d 1 c number of atmospheric layers (np) n/d 1 c level pressure (pl) mb m*ndim*(np+1) c layer temperature (ta) k m*ndim*np c layer specific humidity (wa) g/g m*ndim*np c layer ozone mixing ratio by mass (oa) g/g m*ndim*np c surface temperature (ts) k m*ndim c co2 mixing ratio by volumn (co2) pppv 1 c n2o mixing ratio by volumn (n2o) pppv np c ch4 mixing ratio by volumn (ch4) pppv np c cfc11 mixing ratio by volumn (cfc11) pppv 1 c cfc12 mixing ratio by volumn (cfc12) pppv 1 c cfc22 mixing ratio by volumn (cfc22) pppv 1 c surface emissivity (emiss) fraction m*ndim*10 c input option for cloud optical thickness n/d 1 c cldwater="true" if cwc is provided c cldwater="false" if taucl is provided c cloud water mixing ratio (cwc) gm/gm m*ndim*np*3 c index 1 for ice particles c index 2 for liquid drops c index 3 for rain drops c cloud optical thickness (taucl) n/d m*ndim*np*3 c index 1 for ice particles c index 2 for liquid drops c index 3 for rain drops c effective cloud-particle size (reff) micrometer m*ndim*np*3 c index 1 for ice particles c index 2 for liquid drops c index 3 for rain drops c cloud amount (fcld) fraction m*ndim*np c level index separating high and middle n/d 1 c clouds (ict) c level index separating middle and low n/d 1 c clouds (icb) c aerosol optical thickness (taual) n/d m*ndim*np*10 c aerosol single-scattering albedo (ssaal) n/d m*ndim*np*10 c aerosol asymmetry factor (asyal) n/d m*ndim*np*10 c high (see explanation above) 1 c trace (see explanation above) 1 c c Data used in table look-up for transmittance calculations: c c c1 , c2, c3: for co2 (band 3) c o1 , o2, o3: for o3 (band 5) c h11,h12,h13: for h2o (band 1) c h21,h22,h23: for h2o (band 2) c h81,h82,h83: for h2o (band 8) c c---- output parameters c c net downward flux, all-sky (flx) w/m**2 m*ndim*(np+1) c net downward flux, clear-sky (flc) w/m**2 m*ndim*(np+1) c sensitivity of net downward flux c to surface temperature (dfdts) w/m**2/k m*ndim*(np+1) c emission by the surface (st4) w/m**2 m*ndim c c Notes: c c (1) Water vapor continuum absorption is included in 540-1380 /cm. c (2) Scattering is parameterized for clouds and aerosols. c (3) Diffuse cloud and aerosol transmissions are computed c from exp(-1.66*tau). c (4) If there are no clouds, flx=flc. c (5) plevel(1) is the pressure at the top of the model atmosphere, c and plevel(np+1) is the surface pressure. c (6) Downward flux is positive and upward flux is negative. c (7) dfdts is negative because upward flux is defined as negative. c (8) For questions and coding errors, contact with Ming-Dah Chou, c Code 913, NASA/Goddard Space Flight Center, Greenbelt, MD 20771. c Phone: 301-286-4012, Fax: 301-286-1759, c e-mail: chou@climate.gsfc.nasa.gov c c-----parameters defining the size of the pre-computed tables for transmittance c calculations using table look-up. c c "nx" is the number of intervals in pressure c "no" is the number of intervals in o3 amount c "nc" is the number of intervals in co2 amount c "nh" is the number of intervals in h2o amount c "nt" is the number of copies to be made from the pre-computed c transmittance tables to reduce "memory-bank conflict" c in parallel machines and, hence, enhancing the speed of c computations using table look-up. c If such advantage does not exist, "nt" can be set to 1. c*************************************************************************** cfpp$ expand (h2oexps) cfpp$ expand (conexps) cfpp$ expand (co2exps) cfpp$ expand (n2oexps) cfpp$ expand (ch4exps) cfpp$ expand (comexps) cfpp$ expand (cfcexps) cfpp$ expand (b10exps) cfpp$ expand (tablup) cfpp$ expand (h2okdis) cfpp$ expand (co2kdis) cfpp$ expand (n2okdis) cfpp$ expand (ch4kdis) cfpp$ expand (comkdis) cfpp$ expand (cfckdis) cfpp$ expand (b10kdis) implicit none integer nx,no,nc,nh,nt integer i,j,k,ip,iw,it,ib,ik,iq,isb,k1,k2 parameter (nx=26,no=21,nc=24,nh=31,nt=7) c---- input parameters ------ integer m,n,ndim,np,ict,icb _RL pl(m,ndim,np+1),ta(m,ndim,np),wa(m,ndim,np),oa(m,ndim,np), * ts(m,ndim) _RL co2,n2o(np),ch4(np),cfc11,cfc12,cfc22,emiss(m,ndim,10) _RL cwc(m,ndim,np,3),taucl(m,ndim,np,3),reff(m,ndim,np,3), * fcld(m,ndim,np) _RL taual(m,ndim,np,10),ssaal(m,ndim,np,10),asyal(m,ndim,np,10) logical cldwater,high,trace c---- output parameters ------ _RL flx(m,ndim,np+1),flc(m,ndim,np+1),dfdts(m,ndim,np+1), * st4(m,ndim) c---- static data ----- _RL cb(5,10) _RL xkw(9),aw(9),bw(9),pm(9),fkw(6,9),gkw(6,3),xke(9) _RL aib(3,10),awb(4,10),aiw(4,10),aww(4,10),aig(4,10),awg(4,10) integer ne(9),mw(9) c---- temporary arrays ----- _RL pa(m,n,np),dt(m,n,np) _RL sh2o(m,n,np+1),swpre(m,n,np+1),swtem(m,n,np+1) _RL sco3(m,n,np+1),scopre(m,n,np+1),scotem(m,n,np+1) _RL dh2o(m,n,np),dcont(m,n,np),dco2(m,n,np),do3(m,n,np) _RL dn2o(m,n,np),dch4(m,n,np) _RL df11(m,n,np),df12(m,n,np),df22(m,n,np) _RL th2o(m,n,6),tcon(m,n,3),tco2(m,n,6,2) _RL tn2o(m,n,4),tch4(m,n,4),tcom(m,n,2) _RL tf11(m,n),tf12(m,n),tf22(m,n) _RL h2oexp(m,n,np,6),conexp(m,n,np,3),co2exp(m,n,np,6,2) _RL n2oexp(m,n,np,4),ch4exp(m,n,np,4),comexp(m,n,np,2) _RL f11exp(m,n,np), f12exp(m,n,np), f22exp(m,n,np) _RL clr(m,n,0:np+1),fclr(m,n) _RL blayer(m,n,0:np+1),dlayer(m,n,np+1),dbs(m,n) _RL clrlw(m,n),clrmd(m,n),clrhi(m,n) _RL cwp(m,n,np,3) _RL trant(m,n),tranal(m,n),transfc(m,n,np+1),trantcr(m,n,np+1) _RL flxu(m,n,np+1),flxd(m,n,np+1),flcu(m,n,np+1),flcd(m,n,np+1) _RL rflx(m,n,np+1),rflc(m,n,np+1) logical oznbnd,co2bnd,h2otbl,conbnd,n2obnd logical ch4bnd,combnd,f11bnd,f12bnd,f22bnd,b10bnd _RL c1 (nx,nc,nt),c2 (nx,nc,nt),c3 (nx,nc,nt) _RL o1 (nx,no,nt),o2 (nx,no,nt),o3 (nx,no,nt) _RL h11(nx,nh,nt),h12(nx,nh,nt),h13(nx,nh,nt) _RL h21(nx,nh,nt),h22(nx,nh,nt),h23(nx,nh,nt) _RL h81(nx,nh,nt),h82(nx,nh,nt),h83(nx,nh,nt) _RL dp,xx,p1,dwe,dpe,a1,b1,fk1,a2,b2,fk2 _RL w1,w2,w3,g1,g2,g3,ww,gg,ff,taux,reff1,reff2 c-----the following coefficients (equivalent to table 2 of c chou and suarez, 1995) are for computing spectrally c integrated planck fluxes using eq. (22) data cb/ 1 -2.6844e-1,-8.8994e-2, 1.5676e-3,-2.9349e-6, 2.2233e-9, 2 3.7315e+1,-7.4758e-1, 4.6151e-3,-6.3260e-6, 3.5647e-9, 3 3.7187e+1,-3.9085e-1,-6.1072e-4, 1.4534e-5,-1.6863e-8, 4 -4.1928e+1, 1.0027e+0,-8.5789e-3, 2.9199e-5,-2.5654e-8, 5 -4.9163e+1, 9.8457e-1,-7.0968e-3, 2.0478e-5,-1.5514e-8, 6 -4.7107e+1, 8.9130e-1,-5.9735e-3, 1.5596e-5,-9.5911e-9, 7 -5.4041e+1, 9.5332e-1,-5.7784e-3, 1.2555e-5,-2.9377e-9, 8 -6.9233e+0,-1.5878e-1, 3.9160e-3,-2.4496e-5, 4.9301e-8, 9 1.1483e+2,-2.2376e+0, 1.6394e-2,-5.3672e-5, 6.6456e-8, * 1.9668e+1,-3.1161e-1, 1.2886e-3, 3.6835e-7,-1.6212e-9/ c-----xkw are the absorption coefficients for the first c k-distribution function due to water vapor line absorption c (tables 4 and 7). units are cm**2/g data xkw / 29.55 , 4.167e-1, 1.328e-2, 5.250e-4, * 5.25e-4, 9.369e-3, 4.719e-2, 1.320e-0, 5.250e-4/ c-----xke are the absorption coefficients for the first c k-distribution function due to water vapor continuum absorption c (table 6). units are cm**2/g data xke / 0.00, 0.00, 27.40, 15.8, * 9.40, 7.75, 0.0, 0.0, 0.0/ c-----mw are the ratios between neighboring absorption coefficients c for water vapor line absorption (tables 4 and 7). data mw /6,6,8,6,6,8,9,6,16/ c-----aw and bw (table 3) are the coefficients for temperature scaling c in eq. (25). data aw/ 0.0021, 0.0140, 0.0167, 0.0302, * 0.0307, 0.0195, 0.0152, 0.0008, 0.0096/ data bw/ -1.01e-5, 5.57e-5, 8.54e-5, 2.96e-4, * 2.86e-4, 1.108e-4, 7.608e-5, -3.52e-6, 1.64e-5/ data pm/ 1.0, 1.0, 1.0, 1.0, 1.0, 0.77, 0.5, 1.0, 1.0/ c-----fkw is the planck-weighted k-distribution function due to h2o c line absorption given in table 4 of Chou and Suarez (1995). c the k-distribution function for the third band, fkw(*,3), is not used data fkw / 0.2747,0.2717,0.2752,0.1177,0.0352,0.0255, 2 0.1521,0.3974,0.1778,0.1826,0.0374,0.0527, 3 6*1.00, 4 0.4654,0.2991,0.1343,0.0646,0.0226,0.0140, 5 0.5543,0.2723,0.1131,0.0443,0.0160,0.0000, 6 0.5955,0.2693,0.0953,0.0335,0.0064,0.0000, 7 0.1958,0.3469,0.3147,0.1013,0.0365,0.0048, 8 0.0740,0.1636,0.4174,0.1783,0.1101,0.0566, 9 0.1437,0.2197,0.3185,0.2351,0.0647,0.0183/ c-----gkw is the planck-weighted k-distribution function due to h2o c line absorption in the 3 subbands (800-720,620-720,540-620 /cm) c of band 3 given in table 7. Note that the order of the sub-bands c is reversed. data gkw/ 0.1782,0.0593,0.0215,0.0068,0.0022,0.0000, 2 0.0923,0.1675,0.0923,0.0187,0.0178,0.0000, 3 0.0000,0.1083,0.1581,0.0455,0.0274,0.0041/ c-----ne is the number of terms used in each band to compute water vapor c continuum transmittance (table 6). data ne /0,0,3,1,1,1,0,0,0/ c c-----coefficients for computing the extinction coefficient c for cloud ice particles c polynomial fit: y=a1+a2/x**a3; x is in m**2/gm c data aib / -0.44171, 0.62951, 0.06465, 2 -0.13727, 0.61291, 0.28962, 3 -0.01878, 1.67680, 0.79080, 4 -0.01896, 1.06510, 0.69493, 5 -0.04788, 0.88178, 0.54492, 6 -0.02265, 1.57390, 0.76161, 7 -0.01038, 2.15640, 0.89045, 8 -0.00450, 2.51370, 0.95989, 9 -0.00044, 3.15050, 1.03750, * -0.02956, 1.44680, 0.71283/ c c-----coefficients for computing the extinction coefficient c for cloud liquid drops c polynomial fit: y=a1+a2*x+a3*x**2+a4*x**3; x is in m**2/gm c data awb / 0.08641, 0.01769, -1.5572e-3, 3.4896e-5, 2 0.22027, 0.00997, -1.8719e-3, 5.3112e-5, 3 0.39252, -0.02817, 7.2931e-4, -3.8151e-6, 4 0.39975, -0.03426, 1.2884e-3, -1.7930e-5, 5 0.34021, -0.02805, 1.0654e-3, -1.5443e-5, 6 0.15587, 0.00371, -7.7705e-4, 2.0547e-5, 7 0.05518, 0.04544, -4.2067e-3, 1.0184e-4, 8 0.12724, 0.04751, -5.2037e-3, 1.3711e-4, 9 0.30390, 0.01656, -3.5271e-3, 1.0828e-4, * 0.63617, -0.06287, 2.2350e-3, -2.3177e-5/ c c-----coefficients for computing the single-scattering albedo c for cloud ice particles c polynomial fit: y=a1+a2*x+a3*x**2+a4*x**3; x is in m**2/gm c data aiw/ 0.17201, 1.2229e-2, -1.4837e-4, 5.8020e-7, 2 0.81470, -2.7293e-3, 9.7816e-8, 5.7650e-8, 3 0.54859, -4.8273e-4, 5.4353e-6, -1.5679e-8, 4 0.39218, 4.1717e-3, - 4.8869e-5, 1.9144e-7, 5 0.71773, -3.3640e-3, 1.9713e-5, -3.3189e-8, 6 0.77345, -5.5228e-3, 4.8379e-5, -1.5151e-7, 7 0.74975, -5.6604e-3, 5.6475e-5, -1.9664e-7, 8 0.69011, -4.5348e-3, 4.9322e-5, -1.8255e-7, 9 0.83963, -6.7253e-3, 6.1900e-5, -2.0862e-7, * 0.64860, -2.8692e-3, 2.7656e-5, -8.9680e-8/ c c-----coefficients for computing the single-scattering albedo c for cloud liquid drops c polynomial fit: y=a1+a2*x+a3*x**2+a4*x**3; x is in m**2/gm c data aww/ -7.8566e-2, 8.0875e-2, -4.3403e-3, 8.1341e-5, 2 -1.3384e-2, 9.3134e-2, -6.0491e-3, 1.3059e-4, 3 3.7096e-2, 7.3211e-2, -4.4211e-3, 9.2448e-5, 4 -3.7600e-3, 9.3344e-2, -5.6561e-3, 1.1387e-4, 5 0.40212, 7.8083e-2, -5.9583e-3, 1.2883e-4, 6 0.57928, 5.9094e-2, -5.4425e-3, 1.2725e-4, 7 0.68974, 4.2334e-2, -4.9469e-3, 1.2863e-4, 8 0.80122, 9.4578e-3, -2.8508e-3, 9.0078e-5, 9 1.02340, -2.6204e-2, 4.2552e-4, 3.2160e-6, * 0.05092, 7.5409e-2, -4.7305e-3, 1.0121e-4/ c c-----coefficients for computing the asymmetry factor for cloud ice particles c polynomial fit: y=a1+a2*x+a3*x**2+a4*x**3; x is in m**2/gm c data aig / 0.57867, 1.0135e-2, -1.1142e-4, 4.1537e-7, 2 0.72259, 3.1149e-3, -1.9927e-5, 5.6024e-8, 3 0.76109, 4.5449e-3, -4.6199e-5, 1.6446e-7, 4 0.86934, 2.7474e-3, -3.1301e-5, 1.1959e-7, 5 0.89103, 1.8513e-3, -1.6551e-5, 5.5193e-8, 6 0.86325, 2.1408e-3, -1.6846e-5, 4.9473e-8, 7 0.85064, 2.5028e-3, -2.0812e-5, 6.3427e-8, 8 0.86945, 2.4615e-3, -2.3882e-5, 8.2431e-8, 9 0.80122, 3.1906e-3, -2.4856e-5, 7.2411e-8, * 0.73290, 4.8034e-3, -4.4425e-5, 1.4839e-7/ c c-----coefficients for computing the asymmetry factor for cloud liquid drops c polynomial fit: y=a1+a2*x+a3*x**2+a4*x**3; x is in m**2/gm c data awg / -0.51930, 0.20290, -1.1747e-2, 2.3868e-4, 2 -0.22151, 0.19708, -1.2462e-2, 2.6646e-4, 3 0.14157, 0.14705, -9.5802e-3, 2.0819e-4, 4 0.41590, 0.10482, -6.9118e-3, 1.5115e-4, 5 0.55338, 7.7016e-2, -5.2218e-3, 1.1587e-4, 6 0.61384, 6.4402e-2, -4.6241e-3, 1.0746e-4, 7 0.67891, 4.8698e-2, -3.7021e-3, 9.1966e-5, 8 0.78169, 2.0803e-2, -1.4749e-3, 3.9362e-5, 9 0.93218, -3.3425e-2, 2.9632e-3, -6.9362e-5, * 0.01649, 0.16561, -1.0723e-2, 2.3220e-4/ c c-----include tables used in the table look-up for co2 (band 3), c o3 (band 5), and h2o (bands 1, 2, and 7) transmission functions. logical first data first /.true./ #include "h2o-tran3.h" #include "co2-tran3.h" #include "o3-tran3.h" c save c1,c2,c3,o1,o2,o3 c save h11,h12,h13,h21,h22,h23,h81,h82,h83 if (first) then c-----tables co2 and h2o are only used with 'high' option if (high) then do iw=1,nh do ip=1,nx h11(ip,iw,1)=1.0-h11(ip,iw,1) h21(ip,iw,1)=1.0-h21(ip,iw,1) h81(ip,iw,1)=1.0-h81(ip,iw,1) enddo enddo do iw=1,nc do ip=1,nx c1(ip,iw,1)=1.0-c1(ip,iw,1) enddo enddo c-----copy tables to enhance the speed of co2 (band 3), o3 (band 5), c and h2o (bands 1, 2, and 8 only) transmission calculations c using table look-up. c-----tables are replicated to avoid memory bank conflicts do it=2,nt do iw=1,nc do ip=1,nx c1 (ip,iw,it)= c1(ip,iw,1) c2 (ip,iw,it)= c2(ip,iw,1) c3 (ip,iw,it)= c3(ip,iw,1) enddo enddo do iw=1,nh do ip=1,nx h11(ip,iw,it)=h11(ip,iw,1) h12(ip,iw,it)=h12(ip,iw,1) h13(ip,iw,it)=h13(ip,iw,1) h21(ip,iw,it)=h21(ip,iw,1) h22(ip,iw,it)=h22(ip,iw,1) h23(ip,iw,it)=h23(ip,iw,1) h81(ip,iw,it)=h81(ip,iw,1) h82(ip,iw,it)=h82(ip,iw,1) h83(ip,iw,it)=h83(ip,iw,1) enddo enddo enddo endif c-----always use table look-up for ozone transmittance do iw=1,no do ip=1,nx o1(ip,iw,1)=1.0-o1(ip,iw,1) enddo enddo do it=2,nt do iw=1,no do ip=1,nx o1 (ip,iw,it)= o1(ip,iw,1) o2 (ip,iw,it)= o2(ip,iw,1) o3 (ip,iw,it)= o3(ip,iw,1) enddo enddo enddo first=.false. endif c-----set the pressure at the top of the model atmosphere c to 1.0e-4 if it is zero do j=1,n do i=1,m if (pl(i,j,1) .eq. 0.0) then pl(i,j,1)=1.0e-4 endif enddo enddo c-----compute layer pressure (pa) and layer temperature minus 250K (dt) do k=1,np do j=1,n do i=1,m pa(i,j,k)=0.5*(pl(i,j,k)+pl(i,j,k+1)) dt(i,j,k)=ta(i,j,k)-250.0 enddo enddo enddo c-----compute layer absorber amount c dh2o : water vapor amount (g/cm**2) c dcont: scaled water vapor amount for continuum absorption c (g/cm**2) c dco2 : co2 amount (cm-atm)stp c do3 : o3 amount (cm-atm)stp c dn2o : n2o amount (cm-atm)stp c dch4 : ch4 amount (cm-atm)stp c df11 : cfc11 amount (cm-atm)stp c df12 : cfc12 amount (cm-atm)stp c df22 : cfc22 amount (cm-atm)stp c the factor 1.02 is equal to 1000/980 c factors 789 and 476 are for unit conversion c the factor 0.001618 is equal to 1.02/(.622*1013.25) c the factor 6.081 is equal to 1800/296 do k=1,np do j=1,n do i=1,m dp = pl(i,j,k+1)-pl(i,j,k) dh2o (i,j,k) = 1.02*wa(i,j,k)*dp+1.e-10 do3 (i,j,k) = 476.*oa(i,j,k)*dp+1.e-10 dco2 (i,j,k) = 789.*co2*dp+1.e-10 dch4 (i,j,k) = 789.*ch4(k)*dp+1.e-10 dn2o (i,j,k) = 789.*n2o(k)*dp+1.e-10 df11 (i,j,k) = 789.*cfc11*dp+1.e-10 df12 (i,j,k) = 789.*cfc12*dp+1.e-10 df22 (i,j,k) = 789.*cfc22*dp+1.e-10 c-----compute scaled water vapor amount for h2o continuum absorption c following eq. (43). xx=pa(i,j,k)*0.001618*wa(i,j,k)*wa(i,j,k)*dp dcont(i,j,k) = xx*exp(1800./ta(i,j,k)-6.081)+1.e-10 enddo enddo enddo c-----compute column-integrated h2o amoumt, h2o-weighted pressure c and temperature. it follows eqs. (37) and (38). if (high) then call column(m,n,np,pa,dt,dh2o,sh2o,swpre,swtem) endif c-----compute layer cloud water amount (gm/m**2) c index is 1 for ice, 2 for waterdrops and 3 for raindrops. c Rain optical thickness is 0.00307 /(gm/m**2). c It is for a specific drop size distribution provided by Q. Fu. if (cldwater) then do k=1,np do j=1,n do i=1,m dp =pl(i,j,k+1)-pl(i,j,k) cwp(i,j,k,1)=1.02*10000.0*cwc(i,j,k,1)*dp cwp(i,j,k,2)=1.02*10000.0*cwc(i,j,k,2)*dp cwp(i,j,k,3)=1.02*10000.0*cwc(i,j,k,3)*dp taucl(i,j,k,3)=0.00307*cwp(i,j,k,3) enddo enddo enddo endif c-----the surface (np+1) is treated as a layer filled with black clouds. c clr is the equivalent clear fraction of a layer c transfc is the transmttance between the surface and a pressure level. c trantcr is the clear-sky transmttance between the surface and a c pressure level. do j=1,n do i=1,m clr(i,j,0) = 1.0 clr(i,j,np+1) = 0.0 st4(i,j) = 0.0 transfc(i,j,np+1)=1.0 trantcr(i,j,np+1)=1.0 enddo enddo c-----initialize fluxes do k=1,np+1 do j=1,n do i=1,m flx(i,j,k) = 0.0 flc(i,j,k) = 0.0 dfdts(i,j,k)= 0.0 rflx(i,j,k) = 0.0 rflc(i,j,k) = 0.0 enddo enddo enddo c-----integration over spectral bands do 1000 ib=1,10 c-----if h2otbl, compute h2o (line) transmittance using table look-up. c if conbnd, compute h2o (continuum) transmittance in bands 3-6. c if co2bnd, compute co2 transmittance in band 3. c if oznbnd, compute o3 transmittance in band 5. c if n2obnd, compute n2o transmittance in bands 6 and 7. c if ch4bnd, compute ch4 transmittance in bands 6 and 7. c if combnd, compute co2-minor transmittance in bands 4 and 5. c if f11bnd, compute cfc11 transmittance in bands 4 and 5. c if f12bnd, compute cfc12 transmittance in bands 4 and 6. c if f22bnd, compute cfc22 transmittance in bands 4 and 6. c if b10bnd, compute flux reduction due to n2o in band 10. h2otbl=high.and.(ib.eq.1.or.ib.eq.2.or.ib.eq.8) conbnd=ib.ge.3.and.ib.le.6 co2bnd=ib.eq.3 oznbnd=ib.eq.5 n2obnd=ib.eq.6.or.ib.eq.7 ch4bnd=ib.eq.6.or.ib.eq.7 combnd=ib.eq.4.or.ib.eq.5 f11bnd=ib.eq.4.or.ib.eq.5 f12bnd=ib.eq.4.or.ib.eq.6 f22bnd=ib.eq.4.or.ib.eq.6 b10bnd=ib.eq.10 c-----blayer is the spectrally integrated planck flux of the mean layer c temperature derived from eq. (22) c the fitting for the planck flux is valid in the range 160-345 K. do k=1,np do j=1,n do i=1,m blayer(i,j,k)=ta(i,j,k)*(ta(i,j,k)*(ta(i,j,k) * *(ta(i,j,k)*cb(5,ib)+cb(4,ib))+cb(3,ib)) * +cb(2,ib))+cb(1,ib) enddo enddo enddo c-----the earth surface, with an index "np+1", is treated as a layer do j=1,n do i=1,m blayer(i,j,0) = 0.0 blayer(i,j,np+1)= ( ts(i,j)*(ts(i,j)*(ts(i,j) * *(ts(i,j)*cb(5,ib)+cb(4,ib))+cb(3,ib)) * +cb(2,ib))+cb(1,ib) )*emiss(i,j,ib) c-----dbs is the derivative of the surface emission with respect to c surface temperature (eq. 59). dbs(i,j)=(ts(i,j)*(ts(i,j)*(ts(i,j)*4.*cb(5,ib) * +3.*cb(4,ib))+2.*cb(3,ib))+cb(2,ib))*emiss(i,j,ib) enddo enddo do k=1,np+1 do j=1,n do i=1,m dlayer(i,j,k)=blayer(i,j,k-1)-blayer(i,j,k) enddo enddo enddo c-----compute column-integrated absorber amoumt, absorber-weighted c pressure and temperature for co2 (band 3) and o3 (band 5). c it follows eqs. (37) and (38). c-----this is in the band loop to save storage if (high .and. co2bnd) then call column(m,n,np,pa,dt,dco2,sco3,scopre,scotem) endif if (oznbnd) then call column(m,n,np,pa,dt,do3,sco3,scopre,scotem) endif c-----compute cloud optical thickness if (cldwater) then do k= 1, np do j= 1, n do i= 1, m taucl(i,j,k,1)=cwp(i,j,k,1)*(aib(1,ib)+aib(2,ib)/ * reff(i,j,k,1)**aib(3,ib)) taucl(i,j,k,2)=cwp(i,j,k,2)*(awb(1,ib)+(awb(2,ib)+(awb(3,ib) * +awb(4,ib)*reff(i,j,k,2))*reff(i,j,k,2))*reff(i,j,k,2)) enddo enddo enddo endif c-----compute cloud single-scattering albedo and asymmetry factor for c a mixture of ice particles, liquid drops, and rain drops c single-scattering albedo and asymmetry factor of rain are set c to 0.54 and 0.95, respectively. do k= 1, np do j= 1, n do i= 1, m clr(i,j,k) = 1.0 taux=taucl(i,j,k,1)+taucl(i,j,k,2)+taucl(i,j,k,3) if (taux.gt.0.02 .and. fcld(i,j,k).gt.0.01) then reff1=min(reff(i,j,k,1),130. _d 0) reff2=min(reff(i,j,k,2),20.0 _d 0) w1=taucl(i,j,k,1)*(aiw(1,ib)+(aiw(2,ib)+(aiw(3,ib) * +aiw(4,ib)*reff1)*reff1)*reff1) w2=taucl(i,j,k,2)*(aww(1,ib)+(aww(2,ib)+(aww(3,ib) * +aww(4,ib)*reff2)*reff2)*reff2) w3=taucl(i,j,k,3)*0.54 ww=(w1+w2+w3)/taux g1=w1*(aig(1,ib)+(aig(2,ib)+(aig(3,ib) * +aig(4,ib)*reff1)*reff1)*reff1) g2=w2*(awg(1,ib)+(awg(2,ib)+(awg(3,ib) * +awg(4,ib)*reff2)*reff2)*reff2) g3=w3*0.95 gg=(g1+g2+g3)/(w1+w2+w3) c-----parameterization of LW scattering c compute forward-scattered fraction and scale optical thickness ff=0.5+(0.3739+(0.0076+0.1185*gg)*gg)*gg taux=taux*(1.-ww*ff) c-----compute equivalent cloud-free fraction, clr, for each layer c the cloud diffuse transmittance is approximated by using c a diffusivity factor of 1.66. clr(i,j,k)=1.0-(fcld(i,j,k)*(1.0-exp(-1.66*taux))) endif enddo enddo enddo c-----compute the exponential terms (eq. 32) at each layer due to c water vapor line absorption when k-distribution is used if (.not.h2otbl .and. .not.b10bnd) then call h2oexps(ib,m,n,np,dh2o,pa,dt,xkw,aw,bw,pm,mw,h2oexp) endif c-----compute the exponential terms (eq. 46) at each layer due to c water vapor continuum absorption if (conbnd) then call conexps(ib,m,n,np,dcont,xke,conexp) endif c-----compute the exponential terms (eq. 32) at each layer due to c co2 absorption if (.not.high .and. co2bnd) then call co2exps(m,n,np,dco2,pa,dt,co2exp) endif c***** for trace gases ***** if (trace) then c-----compute the exponential terms at each layer due to n2o absorption if (n2obnd) then call n2oexps(ib,m,n,np,dn2o,pa,dt,n2oexp) endif c-----compute the exponential terms at each layer due to ch4 absorption if (ch4bnd) then call ch4exps(ib,m,n,np,dch4,pa,dt,ch4exp) endif c-----compute the exponential terms due to co2 minor absorption if (combnd) then call comexps(ib,m,n,np,dco2,dt,comexp) endif c-----compute the exponential terms due to cfc11 absorption if (f11bnd) then a1 = 1.26610e-3 b1 = 3.55940e-6 fk1 = 1.89736e+1 a2 = 8.19370e-4 b2 = 4.67810e-6 fk2 = 1.01487e+1 call cfcexps(ib,m,n,np,a1,b1,fk1,a2,b2,fk2,df11,dt,f11exp) endif c-----compute the exponential terms due to cfc12 absorption if (f12bnd) then a1 = 8.77370e-4 b1 =-5.88440e-6 fk1 = 1.58104e+1 a2 = 8.62000e-4 b2 =-4.22500e-6 fk2 = 3.70107e+1 call cfcexps(ib,m,n,np,a1,b1,fk1,a2,b2,fk2,df12,dt,f12exp) endif c-----compute the exponential terms due to cfc22 absorption if (f22bnd) then a1 = 9.65130e-4 b1 = 1.31280e-5 fk1 = 6.18536e+0 a2 =-3.00010e-5 b2 = 5.25010e-7 fk2 = 3.27912e+1 call cfcexps(ib,m,n,np,a1,b1,fk1,a2,b2,fk2,df22,dt,f22exp) endif c-----compute the exponential terms at each layer in band 10 due to c h2o line and continuum, co2, and n2o absorption if (b10bnd) then call b10exps(m,n,np,dh2o,dcont,dco2,dn2o,pa,dt * ,h2oexp,conexp,co2exp,n2oexp) endif endif c-----compute transmittances for regions between levels k1 and k2 c and update the fluxes at the two levels. c-----initialize fluxes do k=1,np+1 do j=1,n do i=1,m flxu(i,j,k) = 0.0 flxd(i,j,k) = 0.0 flcu(i,j,k) = 0.0 flcd(i,j,k) = 0.0 enddo enddo enddo do 2000 k1=1,np c-----initialize fclr, th2o, tcon, tco2, and tranal c fclr is the clear fraction of the line-of-sight c clrlw, clrmd, and clrhi are the clear-sky fractions of the c low, middle, and high troposphere, respectively c tranal is the aerosol transmission function do j=1,n do i=1,m fclr(i,j) = 1.0 clrlw(i,j) = 1.0 clrmd(i,j) = 1.0 clrhi(i,j) = 1.0 tranal(i,j)= 1.0 enddo enddo c-----for h2o line transmission if (.not. h2otbl) then do ik=1,6 do j=1,n do i=1,m th2o(i,j,ik)=1.0 enddo enddo enddo endif c-----for h2o continuum transmission if (conbnd) then do iq=1,3 do j=1,n do i=1,m tcon(i,j,iq)=1.0 enddo enddo enddo endif c-----for co2 transmission using k-distribution method. c band 3 is divided into 3 sub-bands, but sub-bands 3a and 3c c are combined in computing the co2 transmittance. if (.not.high .and. co2bnd) then do isb=1,2 do ik=1,6 do j=1,n do i=1,m tco2(i,j,ik,isb)=1.0 enddo enddo enddo enddo endif c***** for trace gases ***** if (trace) then c-----for n2o transmission using k-distribution method. if (n2obnd) then do ik=1,4 do j=1,n do i=1,m tn2o(i,j,ik)=1.0 enddo enddo enddo endif c-----for ch4 transmission using k-distribution method. if (ch4bnd) then do ik=1,4 do j=1,n do i=1,m tch4(i,j,ik)=1.0 enddo enddo enddo endif c-----for co2-minor transmission using k-distribution method. if (combnd) then do ik=1,2 do j=1,n do i=1,m tcom(i,j,ik)=1.0 enddo enddo enddo endif c-----for cfc-11 transmission using k-distribution method. if (f11bnd) then do j=1,n do i=1,m tf11(i,j)=1.0 enddo enddo endif c-----for cfc-12 transmission using k-distribution method. if (f12bnd) then do j=1,n do i=1,m tf12(i,j)=1.0 enddo enddo endif c-----for cfc-22 transmission when using k-distribution method. if (f22bnd) then do j=1,n do i=1,m tf22(i,j)=1.0 enddo enddo endif c-----for the transmission in band 10 using k-distribution method. if (b10bnd) then do ik=1,6 do j=1,n do i=1,m th2o(i,j,ik)=1.0 tco2(i,j,ik,1)=1.0 enddo enddo enddo do iq=1,3 do j=1,n do i=1,m tcon(i,j,iq)=1.0 enddo enddo enddo do ik=1,4 do j=1,n do i=1,m tn2o(i,j,ik)=1.0 enddo enddo enddo endif endif c-----loop over the bottom level of the region (k2) do 3000 k2=k1+1,np+1 c-----initialize total transmission function (trant) do j=1,n do i=1,m trant(i,j)=1.0 enddo enddo if (h2otbl) then w1=-8.0 p1=-2.0 dwe=0.3 dpe=0.2 c-----compute water vapor transmittance using table look-up if (ib.eq.1) then call tablup(k1,k2,m,n,np,nx,nh,nt,sh2o,swpre,swtem, * w1,p1,dwe,dpe,h11,h12,h13,trant) endif if (ib.eq.2) then call tablup(k1,k2,m,n,np,nx,nh,nt,sh2o,swpre,swtem, * w1,p1,dwe,dpe,h21,h22,h23,trant) endif if (ib.eq.8) then call tablup(k1,k2,m,n,np,nx,nh,nt,sh2o,swpre,swtem, * w1,p1,dwe,dpe,h81,h82,h83,trant) endif else c-----compute water vapor transmittance using k-distribution if (.not.b10bnd) then call h2okdis(ib,m,n,np,k2-1,fkw,gkw,ne,h2oexp,conexp, * th2o,tcon,trant) endif endif if (co2bnd) then if (high) then c-----compute co2 transmittance using table look-up method w1=-4.0 p1=-2.0 dwe=0.3 dpe=0.2 call tablup(k1,k2,m,n,np,nx,nc,nt,sco3,scopre,scotem, * w1,p1,dwe,dpe,c1,c2,c3,trant) else c-----compute co2 transmittance using k-distribution method call co2kdis(m,n,np,k2-1,co2exp,tco2,trant) endif endif c-----All use table look-up to compute o3 transmittance. if (oznbnd) then w1=-6.0 p1=-2.0 dwe=0.3 dpe=0.2 call tablup(k1,k2,m,n,np,nx,no,nt,sco3,scopre,scotem, * w1,p1,dwe,dpe,o1,o2,o3,trant) endif c***** for trace gases ***** if (trace) then c-----compute n2o transmittance using k-distribution method if (n2obnd) then call n2okdis(ib,m,n,np,k2-1,n2oexp,tn2o,trant) endif c-----compute ch4 transmittance using k-distribution method if (ch4bnd) then call ch4kdis(ib,m,n,np,k2-1,ch4exp,tch4,trant) endif c-----compute co2-minor transmittance using k-distribution method if (combnd) then call comkdis(ib,m,n,np,k2-1,comexp,tcom,trant) endif c-----compute cfc11 transmittance using k-distribution method if (f11bnd) then call cfckdis(m,n,np,k2-1,f11exp,tf11,trant) endif c-----compute cfc12 transmittance using k-distribution method if (f12bnd) then call cfckdis(m,n,np,k2-1,f12exp,tf12,trant) endif c-----compute cfc22 transmittance using k-distribution method if (f22bnd) then call cfckdis(m,n,np,k2-1,f22exp,tf22,trant) endif c-----compute transmittance in band 10 using k-distribution method c here, trant is the change in transmittance due to n2o absorption if (b10bnd) then call b10kdis(m,n,np,k2-1,h2oexp,conexp,co2exp,n2oexp * ,th2o,tcon,tco2,tn2o,trant) endif endif c c-----include aerosol effect c do j=1,n do i=1,m ff=0.5+(0.3739+(0.0076+0.1185*asyal(i,j,k2-1,ib)) * *asyal(i,j,k2-1,ib))*asyal(i,j,k2-1,ib) taux=taual(i,j,k2-1,ib)*(1.-ssaal(i,j,k2-1,ib)*ff) tranal(i,j)=tranal(i,j)*exp(-1.66*taux) trant (i,j)=trant(i,j) *tranal(i,j) enddo enddo c-----Identify the clear-sky fractions clrhi, clrmd and clrlw, in the c high, middle and low cloud groups. c fclr is the clear-sky fraction between levels k1 and k2 assuming c the three cloud groups are randomly overlapped. do j=1,n do i=1,m if( k2 .le. ict ) then clrhi(i,j)=min(clr(i,j,k2-1),clrhi(i,j)) elseif( k2 .gt. ict .and. k2 .le. icb ) then clrmd(i,j)=min(clr(i,j,k2-1),clrmd(i,j)) elseif( k2 .gt. icb ) then clrlw(i,j)=min(clr(i,j,k2-1),clrlw(i,j)) endif fclr(i,j)=clrlw(i,j)*clrmd(i,j)*clrhi(i,j) enddo enddo c-----compute upward and downward fluxes (band 1-9). c add "boundary" terms to the net downward flux. c these are the first terms on the right-hand-side of c eqs. (56a) and (56b). downward fluxes are positive. if (.not. b10bnd) then if (k2 .eq. k1+1) then do j=1,n do i=1,m c-----compute upward and downward fluxes for clear-sky situation flcu(i,j,k1)=flcu(i,j,k1)-blayer(i,j,k1) flcd(i,j,k2)=flcd(i,j,k2)+blayer(i,j,k1) c-----compute upward and downward fluxes for all-sky situation flxu(i,j,k1)=flxu(i,j,k1)-blayer(i,j,k1) flxd(i,j,k2)=flxd(i,j,k2)+blayer(i,j,k1) enddo enddo endif c-----add flux components involving the four layers above and below c the levels k1 and k2. it follows eqs. (56a) and (56b). do j=1,n do i=1,m xx=trant(i,j)*dlayer(i,j,k2) flcu(i,j,k1) =flcu(i,j,k1)+xx flxu(i,j,k1) =flxu(i,j,k1)+xx*fclr(i,j) xx=trant(i,j)*dlayer(i,j,k1) flcd(i,j,k2) =flcd(i,j,k2)+xx flxd(i,j,k2) =flxd(i,j,k2)+xx*fclr(i,j) enddo enddo else c-----flux reduction due to n2o in band 10 if (trace) then do j=1,n do i=1,m rflx(i,j,k1) = rflx(i,j,k1)+trant(i,j)*fclr(i,j) * *dlayer(i,j,k2) rflx(i,j,k2) = rflx(i,j,k2)+trant(i,j)*fclr(i,j) * *dlayer(i,j,k1) rflc(i,j,k1) = rflc(i,j,k1)+trant(i,j) * *dlayer(i,j,k2) rflc(i,j,k2) = rflc(i,j,k2)+trant(i,j) * *dlayer(i,j,k1) enddo enddo endif endif 3000 continue c-----transmission between level k1 and the surface do j=1,n do i=1,m trantcr(i,j,k1) =trant(i,j) transfc(i,j,k1) =trant(i,j)*fclr(i,j) enddo enddo c-----compute the partial derivative of fluxes with respect to c surface temperature (eq. 59) if (trace .or. (.not. b10bnd) ) then do j=1,n do i=1,m dfdts(i,j,k1) =dfdts(i,j,k1)-dbs(i,j)*transfc(i,j,k1) enddo enddo endif 2000 continue if (.not. b10bnd) then c-----add contribution from the surface to the flux terms at the surface do j=1,n do i=1,m flcu(i,j,np+1)=flcu(i,j,np+1)-blayer(i,j,np+1) flxu(i,j,np+1)=flxu(i,j,np+1)-blayer(i,j,np+1) st4(i,j)=st4(i,j)-blayer(i,j,np+1) dfdts(i,j,np+1)=dfdts(i,j,np+1)-dbs(i,j) enddo enddo c-----add the flux component reflected by the surface c note: upward flux is negative do k=1, np+1 do j=1,n do i=1,m flcu(i,j,k)=flcu(i,j,k)- * flcd(i,j,np+1)*trantcr(i,j,k)*(1.-emiss(i,j,ib)) flxu(i,j,k)=flxu(i,j,k)- * flxd(i,j,np+1)*transfc(i,j,k)*(1.-emiss(i,j,ib)) enddo enddo enddo endif c-----summation of fluxes over spectral bands do k=1,np+1 do j=1,n do i=1,m flc(i,j,k)=flc(i,j,k)+flcd(i,j,k)+flcu(i,j,k) flx(i,j,k)=flx(i,j,k)+flxd(i,j,k)+flxu(i,j,k) enddo enddo enddo 1000 continue c-----adjust fluxes due to n2o absorption in band 10 do k=1,np+1 do j=1,n do i=1,m flc(i,j,k)=flc(i,j,k)+rflc(i,j,k) flx(i,j,k)=flx(i,j,k)+rflx(i,j,k) enddo enddo enddo return end c*********************************************************************** subroutine column (m,n,np,pa,dt,sabs0,sabs,spre,stem) c*********************************************************************** c-----compute column-integrated (from top of the model atmosphere) c absorber amount (sabs), absorber-weighted pressure (spre) and c temperature (stem). c computations of spre and stem follows eqs. (37) and (38). c c--- input parameters c number of soundings in zonal direction (m) c number of soundings in meridional direction (n) c number of atmospheric layers (np) c layer pressure (pa) c layer temperature minus 250K (dt) c layer absorber amount (sabs0) c c--- output parameters c column-integrated absorber amount (sabs) c column absorber-weighted pressure (spre) c column absorber-weighted temperature (stem) c c--- units of pa and dt are mb and k, respectively. c units of sabs are g/cm**2 for water vapor and (cm-atm)stp c for co2 and o3 c*********************************************************************** implicit none integer m,n,np,i,j,k c---- input parameters ----- _RL pa(m,n,np),dt(m,n,np),sabs0(m,n,np) c---- output parameters ----- _RL sabs(m,n,np+1),spre(m,n,np+1),stem(m,n,np+1) c********************************************************************* do j=1,n do i=1,m sabs(i,j,1)=0.0 spre(i,j,1)=0.0 stem(i,j,1)=0.0 enddo enddo do k=1,np do j=1,n do i=1,m sabs(i,j,k+1)=sabs(i,j,k)+sabs0(i,j,k) spre(i,j,k+1)=spre(i,j,k)+pa(i,j,k)*sabs0(i,j,k) stem(i,j,k+1)=stem(i,j,k)+dt(i,j,k)*sabs0(i,j,k) enddo enddo enddo return end c********************************************************************** subroutine h2oexps(ib,m,n,np,dh2o,pa,dt,xkw,aw,bw,pm,mw,h2oexp) c********************************************************************** c compute exponentials for water vapor line absorption c in individual layers. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c layer water vapor amount for line absorption (dh2o) c layer pressure (pa) c layer temperature minus 250K (dt) c absorption coefficients for the first k-distribution c function due to h2o line absorption (xkw) c coefficients for the temperature and pressure scaling (aw,bw,pm) c ratios between neighboring absorption coefficients for c h2o line absorption (mw) c c---- output parameters c 6 exponentials for each layer (h2oexp) c********************************************************************** implicit none integer ib,m,n,np,i,j,k,ik c---- input parameters ------ _RL dh2o(m,n,np),pa(m,n,np),dt(m,n,np) c---- output parameters ----- _RL h2oexp(m,n,np,6) c---- static data ----- integer mw(9) _RL xkw(9),aw(9),bw(9),pm(9) c---- temporary arrays ----- _RL xh,xh1 c********************************************************************** c note that the 3 sub-bands in band 3 use the same set of xkw, aw, c and bw, therefore, h2oexp for these sub-bands are identical. c********************************************************************** do k=1,np do j=1,n do i=1,m c-----xh is the scaled water vapor amount for line absorption c computed from (27) xh = dh2o(i,j,k)*(pa(i,j,k)/500.)**pm(ib) 1 * ( 1.+(aw(ib)+bw(ib)* dt(i,j,k))*dt(i,j,k) ) c-----h2oexp is the water vapor transmittance of the layer k c due to line absorption h2oexp(i,j,k,1) = exp(-xh*xkw(ib)) enddo enddo enddo do ik=2,6 if (mw(ib).eq.6) then do k=1,np do j=1,n do i=1,m xh = h2oexp(i,j,k,ik-1)*h2oexp(i,j,k,ik-1) h2oexp(i,j,k,ik) = xh*xh*xh enddo enddo enddo elseif (mw(ib).eq.8) then do k=1,np do j=1,n do i=1,m xh = h2oexp(i,j,k,ik-1)*h2oexp(i,j,k,ik-1) xh = xh*xh h2oexp(i,j,k,ik) = xh*xh enddo enddo enddo elseif (mw(ib).eq.9) then do k=1,np do j=1,n do i=1,m xh=h2oexp(i,j,k,ik-1)*h2oexp(i,j,k,ik-1)*h2oexp(i,j,k,ik-1) xh1 = xh*xh h2oexp(i,j,k,ik) = xh*xh1 enddo enddo enddo else do k=1,np do j=1,n do i=1,m xh = h2oexp(i,j,k,ik-1)*h2oexp(i,j,k,ik-1) xh = xh*xh xh = xh*xh h2oexp(i,j,k,ik) = xh*xh enddo enddo enddo endif enddo return end c********************************************************************** subroutine conexps(ib,m,n,np,dcont,xke,conexp) c********************************************************************** c compute exponentials for continuum absorption in individual layers. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c layer scaled water vapor amount for continuum absorption (dcont) c absorption coefficients for the first k-distribution function c due to water vapor continuum absorption (xke) c c---- output parameters c 1 or 3 exponentials for each layer (conexp) c********************************************************************** implicit none integer ib,m,n,np,i,j,k,iq c---- input parameters ------ _RL dcont(m,n,np) c---- updated parameters ----- _RL conexp(m,n,np,3) c---- static data ----- _RL xke(9) c********************************************************************** do k=1,np do j=1,n do i=1,m conexp(i,j,k,1) = exp(-dcont(i,j,k)*xke(ib)) enddo enddo enddo if (ib .eq. 3) then c-----the absorption coefficients for sub-bands 3b (iq=2) and 3a (iq=3) c are, respectively, two and three times the absorption coefficient c for sub-band 3c (iq=1) (table 6). do iq=2,3 do k=1,np do j=1,n do i=1,m conexp(i,j,k,iq) = conexp(i,j,k,iq-1) *conexp(i,j,k,iq-1) enddo enddo enddo enddo endif return end c********************************************************************** subroutine co2exps(m,n,np,dco2,pa,dt,co2exp) c********************************************************************** c compute co2 exponentials for individual layers. c c---- input parameters c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c layer co2 amount (dco2) c layer pressure (pa) c layer temperature minus 250K (dt) c c---- output parameters c 6 exponentials for each layer (co2exp) c********************************************************************** implicit none integer m,n,np,i,j,k c---- input parameters ----- _RL dco2(m,n,np),pa(m,n,np),dt(m,n,np) c---- output parameters ----- _RL co2exp(m,n,np,6,2) c---- temporary arrays ----- _RL xc c********************************************************************** do k=1,np do j=1,n do i=1,m c-----compute the scaled co2 amount from eq. (27) for band-wings c (sub-bands 3a and 3c). xc = dco2(i,j,k)*(pa(i,j,k)/300.0)**0.5 1 *(1.+(0.0182+1.07e-4*dt(i,j,k))*dt(i,j,k)) c-----six exponentials by powers of 8 (table 7). co2exp(i,j,k,1,1)=exp(-xc*2.656e-5) xc=co2exp(i,j,k,1,1)*co2exp(i,j,k,1,1) xc=xc*xc co2exp(i,j,k,2,1)=xc*xc xc=co2exp(i,j,k,2,1)*co2exp(i,j,k,2,1) xc=xc*xc co2exp(i,j,k,3,1)=xc*xc xc=co2exp(i,j,k,3,1)*co2exp(i,j,k,3,1) xc=xc*xc co2exp(i,j,k,4,1)=xc*xc xc=co2exp(i,j,k,4,1)*co2exp(i,j,k,4,1) xc=xc*xc co2exp(i,j,k,5,1)=xc*xc xc=co2exp(i,j,k,5,1)*co2exp(i,j,k,5,1) xc=xc*xc co2exp(i,j,k,6,1)=xc*xc c-----compute the scaled co2 amount from eq. (27) for band-center c region (sub-band 3b). xc = dco2(i,j,k)*(pa(i,j,k)/30.0)**0.85 1 *(1.+(0.0042+2.00e-5*dt(i,j,k))*dt(i,j,k)) co2exp(i,j,k,1,2)=exp(-xc*2.656e-3) xc=co2exp(i,j,k,1,2)*co2exp(i,j,k,1,2) xc=xc*xc co2exp(i,j,k,2,2)=xc*xc xc=co2exp(i,j,k,2,2)*co2exp(i,j,k,2,2) xc=xc*xc co2exp(i,j,k,3,2)=xc*xc xc=co2exp(i,j,k,3,2)*co2exp(i,j,k,3,2) xc=xc*xc co2exp(i,j,k,4,2)=xc*xc xc=co2exp(i,j,k,4,2)*co2exp(i,j,k,4,2) xc=xc*xc co2exp(i,j,k,5,2)=xc*xc xc=co2exp(i,j,k,5,2)*co2exp(i,j,k,5,2) xc=xc*xc co2exp(i,j,k,6,2)=xc*xc enddo enddo enddo return end c********************************************************************** subroutine n2oexps(ib,m,n,np,dn2o,pa,dt,n2oexp) c********************************************************************** c compute n2o exponentials for individual layers. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c layer n2o amount (dn2o) c layer pressure (pa) c layer temperature minus 250K (dt) c c---- output parameters c 2 or 4 exponentials for each layer (n2oexp) c********************************************************************** implicit none integer ib,m,n,np,i,j,k c---- input parameters ----- _RL dn2o(m,n,np),pa(m,n,np),dt(m,n,np) c---- output parameters ----- _RL n2oexp(m,n,np,4) c---- temporary arrays ----- _RL xc,xc1,xc2 c********************************************************************** do k=1,np do j=1,n do i=1,m c-----four exponential by powers of 21 for band 6 if (ib.eq.6) then xc=dn2o(i,j,k)*(1.+(1.9297e-3+4.3750e-6*dt(i,j,k))*dt(i,j,k)) n2oexp(i,j,k,1)=exp(-xc*6.31582e-2) xc=n2oexp(i,j,k,1)*n2oexp(i,j,k,1)*n2oexp(i,j,k,1) xc1=xc*xc xc2=xc1*xc1 n2oexp(i,j,k,2)=xc*xc1*xc2 c-----four exponential by powers of 8 for band 7 else xc=dn2o(i,j,k)*(pa(i,j,k)/500.0)**0.48 * *(1.+(1.3804e-3+7.4838e-6*dt(i,j,k))*dt(i,j,k)) n2oexp(i,j,k,1)=exp(-xc*5.35779e-2) xc=n2oexp(i,j,k,1)*n2oexp(i,j,k,1) xc=xc*xc n2oexp(i,j,k,2)=xc*xc xc=n2oexp(i,j,k,2)*n2oexp(i,j,k,2) xc=xc*xc n2oexp(i,j,k,3)=xc*xc xc=n2oexp(i,j,k,3)*n2oexp(i,j,k,3) xc=xc*xc n2oexp(i,j,k,4)=xc*xc endif enddo enddo enddo return end c********************************************************************** subroutine ch4exps(ib,m,n,np,dch4,pa,dt,ch4exp) c********************************************************************** c compute ch4 exponentials for individual layers. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c layer ch4 amount (dch4) c layer pressure (pa) c layer temperature minus 250K (dt) c c---- output parameters c 1 or 4 exponentials for each layer (ch4exp) c********************************************************************** implicit none integer ib,m,n,np,i,j,k c---- input parameters ----- _RL dch4(m,n,np),pa(m,n,np),dt(m,n,np) c---- output parameters ----- _RL ch4exp(m,n,np,4) c---- temporary arrays ----- _RL xc c********************************************************************** do k=1,np do j=1,n do i=1,m c-----four exponentials for band 6 if (ib.eq.6) then xc=dch4(i,j,k)*(1.+(1.7007e-2+1.5826e-4*dt(i,j,k))*dt(i,j,k)) ch4exp(i,j,k,1)=exp(-xc*5.80708e-3) c-----four exponentials by powers of 12 for band 7 else xc=dch4(i,j,k)*(pa(i,j,k)/500.0)**0.65 * *(1.+(5.9590e-4-2.2931e-6*dt(i,j,k))*dt(i,j,k)) ch4exp(i,j,k,1)=exp(-xc*6.29247e-2) xc=ch4exp(i,j,k,1)*ch4exp(i,j,k,1)*ch4exp(i,j,k,1) xc=xc*xc ch4exp(i,j,k,2)=xc*xc xc=ch4exp(i,j,k,2)*ch4exp(i,j,k,2)*ch4exp(i,j,k,2) xc=xc*xc ch4exp(i,j,k,3)=xc*xc xc=ch4exp(i,j,k,3)*ch4exp(i,j,k,3)*ch4exp(i,j,k,3) xc=xc*xc ch4exp(i,j,k,4)=xc*xc endif enddo enddo enddo return end c********************************************************************** subroutine comexps(ib,m,n,np,dcom,dt,comexp) c********************************************************************** c compute co2-minor exponentials for individual layers. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c layer co2 amount (dcom) c layer temperature minus 250K (dt) c c---- output parameters c 2 exponentials for each layer (comexp) c********************************************************************** implicit none integer ib,m,n,np,i,j,k c---- input parameters ----- _RL dcom(m,n,np),dt(m,n,np) c---- output parameters ----- _RL comexp(m,n,np,2) c---- temporary arrays ----- _RL xc,xc1,xc2 c********************************************************************** do k=1,np do j=1,n do i=1,m c-----two exponentials by powers of 60 for band 4 if (ib.eq.4) then xc=dcom(i,j,k)*(1.+(3.5775e-2+4.0447e-4*dt(i,j,k))*dt(i,j,k)) comexp(i,j,k,1)=exp(-xc*2.18947e-5) xc=comexp(i,j,k,1)*comexp(i,j,k,1)*comexp(i,j,k,1) xc=xc*xc xc1=xc*xc xc=xc1*xc1 xc=xc*xc comexp(i,j,k,2)=xc*xc1 c-----two exponentials by powers of 44 for band 5 else xc=dcom(i,j,k)*(1.+(3.4268e-2+3.7401e-4*dt(i,j,k))*dt(i,j,k)) comexp(i,j,k,1)=exp(-xc*4.74570e-5) xc=comexp(i,j,k,1)*comexp(i,j,k,1) xc1=xc*xc xc2=xc1*xc1 xc=xc2*xc2 xc=xc*xc comexp(i,j,k,2)=xc1*xc2*xc endif enddo enddo enddo return end c********************************************************************** subroutine cfcexps(ib,m,n,np,a1,b1,fk1,a2,b2,fk2,dcfc,dt,cfcexp) c********************************************************************** c compute cfc(-11, -12, -22) exponentials for individual layers. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c parameters for computing the scaled cfc amounts c for temperature scaling (a1,b1,a2,b2) c the absorption coefficients for the c first k-distribution function due to cfcs (fk1,fk2) c layer cfc amounts (dcfc) c layer temperature minus 250K (dt) c c---- output parameters c 1 exponential for each layer (cfcexp) c********************************************************************** implicit none integer ib,m,n,np,i,j,k c---- input parameters ----- _RL dcfc(m,n,np),dt(m,n,np) c---- output parameters ----- _RL cfcexp(m,n,np) c---- static data ----- _RL a1,b1,fk1,a2,b2,fk2 c---- temporary arrays ----- _RL xf c********************************************************************** do k=1,np do j=1,n do i=1,m c-----compute the scaled cfc amount (xf) and exponential (cfcexp) if (ib.eq.4) then xf=dcfc(i,j,k)*(1.+(a1+b1*dt(i,j,k))*dt(i,j,k)) cfcexp(i,j,k)=exp(-xf*fk1) else xf=dcfc(i,j,k)*(1.+(a2+b2*dt(i,j,k))*dt(i,j,k)) cfcexp(i,j,k)=exp(-xf*fk2) endif enddo enddo enddo return end c********************************************************************** subroutine b10exps(m,n,np,dh2o,dcont,dco2,dn2o,pa,dt * ,h2oexp,conexp,co2exp,n2oexp) c********************************************************************** c compute band3a exponentials for individual layers. c c---- input parameters c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of layers (np) c layer h2o amount for line absorption (dh2o) c layer h2o amount for continuum absorption (dcont) c layer co2 amount (dco2) c layer n2o amount (dn2o) c layer pressure (pa) c layer temperature minus 250K (dt) c c---- output parameters c c exponentials for each layer (h2oexp,conexp,co2exp,n2oexp) c********************************************************************** implicit none integer m,n,np,i,j,k c---- input parameters ----- _RL dh2o(m,n,np),dcont(m,n,np),dn2o(m,n,np) _RL dco2(m,n,np),pa(m,n,np),dt(m,n,np) c---- output parameters ----- _RL h2oexp(m,n,np,6),conexp(m,n,np,3),co2exp(m,n,np,6,2) * ,n2oexp(m,n,np,4) c---- temporary arrays ----- _RL xx,xx1,xx2,xx3 c********************************************************************** do k=1,np do j=1,n do i=1,m c-----compute the scaled h2o-line amount for the sub-band 3a c table 3, Chou et al. (JAS, 1993) xx=dh2o(i,j,k)*(pa(i,j,k)/500.0) 1 *(1.+(0.0149+6.20e-5*dt(i,j,k))*dt(i,j,k)) c-----six exponentials by powers of 8 c the constant 0.10624 is equal to 1.66*0.064 h2oexp(i,j,k,1)=exp(-xx*0.10624) xx=h2oexp(i,j,k,1)*h2oexp(i,j,k,1) xx=xx*xx h2oexp(i,j,k,2)=xx*xx xx=h2oexp(i,j,k,2)*h2oexp(i,j,k,2) xx=xx*xx h2oexp(i,j,k,3)=xx*xx xx=h2oexp(i,j,k,3)*h2oexp(i,j,k,3) xx=xx*xx h2oexp(i,j,k,4)=xx*xx xx=h2oexp(i,j,k,4)*h2oexp(i,j,k,4) xx=xx*xx h2oexp(i,j,k,5)=xx*xx xx=h2oexp(i,j,k,5)*h2oexp(i,j,k,5) xx=xx*xx h2oexp(i,j,k,6)=xx*xx c-----compute the scaled co2 amount for the sub-band 3a c table 1, Chou et al. (JAS, 1993) xx=dco2(i,j,k)*(pa(i,j,k)/300.0)**0.5 1 *(1.+(0.0179+1.02e-4*dt(i,j,k))*dt(i,j,k)) c-----six exponentials by powers of 8 c the constant 2.656e-5 is equal to 1.66*1.60e-5 co2exp(i,j,k,1,1)=exp(-xx*2.656e-5) xx=co2exp(i,j,k,1,1)*co2exp(i,j,k,1,1) xx=xx*xx co2exp(i,j,k,2,1)=xx*xx xx=co2exp(i,j,k,2,1)*co2exp(i,j,k,2,1) xx=xx*xx co2exp(i,j,k,3,1)=xx*xx xx=co2exp(i,j,k,3,1)*co2exp(i,j,k,3,1) xx=xx*xx co2exp(i,j,k,4,1)=xx*xx xx=co2exp(i,j,k,4,1)*co2exp(i,j,k,4,1) xx=xx*xx co2exp(i,j,k,5,1)=xx*xx xx=co2exp(i,j,k,5,1)*co2exp(i,j,k,5,1) xx=xx*xx co2exp(i,j,k,6,1)=xx*xx c-----one exponential of h2o continuum for sub-band 3a c tabl 5 of Chou et. al. (JAS, 1993) c the constant 1.04995e+2 is equal to 1.66*63.25 conexp(i,j,k,1)=exp(-dcont(i,j,k)*1.04995e+2) c-----compute the scaled n2o amount for sub-band 3a xx=dn2o(i,j,k)*(1.+(1.4476e-3+3.6656e-6*dt(i,j,k))*dt(i,j,k)) c-----two exponential2 by powers of 58 n2oexp(i,j,k,1)=exp(-xx*0.25238) xx=n2oexp(i,j,k,1)*n2oexp(i,j,k,1) xx1=xx*xx xx1=xx1*xx1 xx2=xx1*xx1 xx3=xx2*xx2 n2oexp(i,j,k,2)=xx*xx1*xx2*xx3 enddo enddo enddo return end c********************************************************************** subroutine tablup(k1,k2,m,n,np,nx,nh,nt,sabs,spre,stem,w1,p1, * dwe,dpe,coef1,coef2,coef3,tran) c********************************************************************** c compute water vapor, co2 and o3 transmittances between levels c k1 and k2 for m x n soundings, using table look-up. c c calculations follow Eq. (40) of Chou and Suarez (1994) c c---- input --------------------- c indices for pressure levels (k1 and k2) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of atmospheric layers (np) c number of pressure intervals in the table (nx) c number of absorber amount intervals in the table (nh) c number of tables copied (nt) c column-integrated absorber amount (sabs) c column absorber amount-weighted pressure (spre) c column absorber amount-weighted temperature (stem) c first value of absorber amount (log10) in the table (w1) c first value of pressure (log10) in the table (p1) c size of the interval of absorber amount (log10) in the table (dwe) c size of the interval of pressure (log10) in the table (dpe) c pre-computed coefficients (coef1, coef2, and coef3) c c---- updated --------------------- c transmittance (tran) c c Note: c (1) units of sabs are g/cm**2 for water vapor and c (cm-atm)stp for co2 and o3. c (2) units of spre and stem are, respectively, mb and K. c (3) there are nt identical copies of the tables (coef1, coef2, and c coef3). the prupose of using the multiple copies of tables is c to increase the speed in parallel (vectorized) computations. C if such advantage does not exist, nt can be set to 1. c c********************************************************************** implicit none integer k1,k2,m,n,np,nx,nh,nt,i,j c---- input parameters ----- _RL w1,p1,dwe,dpe _RL sabs(m,n,np+1),spre(m,n,np+1),stem(m,n,np+1) _RL coef1(nx,nh,nt),coef2(nx,nh,nt),coef3(nx,nh,nt) c---- update parameter ----- _RL tran(m,n) c---- temporary variables ----- _RL x1,x2,x3,we,pe,fw,fp,pa,pb,pc,ax,ba,bb,t1,ca,cb,t2 integer iw,ip,nn c********************************************************************** do j=1,n do i=1,m nn=mod(i,nt)+1 x1=sabs(i,j,k2)-sabs(i,j,k1) x2=(spre(i,j,k2)-spre(i,j,k1))/x1 x3=(stem(i,j,k2)-stem(i,j,k1))/x1 we=(log10(x1)-w1)/dwe pe=(log10(x2)-p1)/dpe we=max(we,w1-2.*dwe) pe=max(pe,p1) iw=int(we+1.5) ip=int(pe+1.5) iw=min(iw,nh-1) iw=max(iw, 2) ip=min(ip,nx-1) ip=max(ip, 1) fw=we-float(iw-1) fp=pe-float(ip-1) c-----linear interpolation in pressure pa = coef1(ip,iw-1,nn)*(1.-fp)+coef1(ip+1,iw-1,nn)*fp pb = coef1(ip,iw, nn)*(1.-fp)+coef1(ip+1,iw, nn)*fp pc = coef1(ip,iw+1,nn)*(1.-fp)+coef1(ip+1,iw+1,nn)*fp c-----quadratic interpolation in absorber amount for coef1 ax = (-pa*(1.-fw)+pc*(1.+fw)) *fw*0.5 + pb*(1.-fw*fw) c-----linear interpolation in absorber amount for coef2 and coef3 ba = coef2(ip,iw, nn)*(1.-fp)+coef2(ip+1,iw, nn)*fp bb = coef2(ip,iw+1,nn)*(1.-fp)+coef2(ip+1,iw+1,nn)*fp t1 = ba*(1.-fw) + bb*fw ca = coef3(ip,iw, nn)*(1.-fp)+coef3(ip+1,iw, nn)*fp cb = coef3(ip,iw+1,nn)*(1.-fp)+coef3(ip+1,iw+1,nn)*fp t2 = ca*(1.-fw) + cb*fw c-----update the total transmittance between levels k1 and k2 tran(i,j)= (ax + (t1+t2*x3) * x3)*tran(i,j) enddo enddo return end c********************************************************************** subroutine h2okdis(ib,m,n,np,k,fkw,gkw,ne,h2oexp,conexp, * th2o,tcon,tran) c********************************************************************** c compute water vapor transmittance between levels k1 and k2 for c m x n soundings, using the k-distribution method. c c computations follow eqs. (34), (46), (50) and (52). c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of levels (np) c current level (k) c planck-weighted k-distribution function due to c h2o line absorption (fkw) c planck-weighted k-distribution function due to c h2o continuum absorption (gkw) c number of terms used in each band to compute water vapor c continuum transmittance (ne) c exponentials for line absorption (h2oexp) c exponentials for continuum absorption (conexp) c c---- updated parameters c transmittance between levels k1 and k2 due to c water vapor line absorption (th2o) c transmittance between levels k1 and k2 due to c water vapor continuum absorption (tcon) c total transmittance (tran) c c********************************************************************** implicit none integer ib,m,n,np,k,i,j c---- input parameters ------ _RL conexp(m,n,np,3),h2oexp(m,n,np,6) integer ne(9) _RL fkw(6,9),gkw(6,3) c---- updated parameters ----- _RL th2o(m,n,6),tcon(m,n,3),tran(m,n) c---- temporary arrays ----- _RL trnth2o c-----tco2 are the six exp factors between levels k1 and k2 c tran is the updated total transmittance between levels k1 and k2 c-----th2o is the 6 exp factors between levels k1 and k2 due to c h2o line absorption. c-----tcon is the 3 exp factors between levels k1 and k2 due to c h2o continuum absorption. c-----trnth2o is the total transmittance between levels k1 and k2 due c to both line and continuum absorption computed from eq. (52). do j=1,n do i=1,m th2o(i,j,1) = th2o(i,j,1)*h2oexp(i,j,k,1) th2o(i,j,2) = th2o(i,j,2)*h2oexp(i,j,k,2) th2o(i,j,3) = th2o(i,j,3)*h2oexp(i,j,k,3) th2o(i,j,4) = th2o(i,j,4)*h2oexp(i,j,k,4) th2o(i,j,5) = th2o(i,j,5)*h2oexp(i,j,k,5) th2o(i,j,6) = th2o(i,j,6)*h2oexp(i,j,k,6) enddo enddo if (ne(ib).eq.0) then do j=1,n do i=1,m trnth2o =(fkw(1,ib)*th2o(i,j,1) * + fkw(2,ib)*th2o(i,j,2) * + fkw(3,ib)*th2o(i,j,3) * + fkw(4,ib)*th2o(i,j,4) * + fkw(5,ib)*th2o(i,j,5) * + fkw(6,ib)*th2o(i,j,6)) tran(i,j)=tran(i,j)*trnth2o enddo enddo elseif (ne(ib).eq.1) then do j=1,n do i=1,m tcon(i,j,1)= tcon(i,j,1)*conexp(i,j,k,1) trnth2o =(fkw(1,ib)*th2o(i,j,1) * + fkw(2,ib)*th2o(i,j,2) * + fkw(3,ib)*th2o(i,j,3) * + fkw(4,ib)*th2o(i,j,4) * + fkw(5,ib)*th2o(i,j,5) * + fkw(6,ib)*th2o(i,j,6))*tcon(i,j,1) tran(i,j)=tran(i,j)*trnth2o enddo enddo else do j=1,n do i=1,m tcon(i,j,1)= tcon(i,j,1)*conexp(i,j,k,1) tcon(i,j,2)= tcon(i,j,2)*conexp(i,j,k,2) tcon(i,j,3)= tcon(i,j,3)*conexp(i,j,k,3) trnth2o = ( gkw(1,1)*th2o(i,j,1) * + gkw(2,1)*th2o(i,j,2) * + gkw(3,1)*th2o(i,j,3) * + gkw(4,1)*th2o(i,j,4) * + gkw(5,1)*th2o(i,j,5) * + gkw(6,1)*th2o(i,j,6) ) * tcon(i,j,1) * + ( gkw(1,2)*th2o(i,j,1) * + gkw(2,2)*th2o(i,j,2) * + gkw(3,2)*th2o(i,j,3) * + gkw(4,2)*th2o(i,j,4) * + gkw(5,2)*th2o(i,j,5) * + gkw(6,2)*th2o(i,j,6) ) * tcon(i,j,2) * + ( gkw(1,3)*th2o(i,j,1) * + gkw(2,3)*th2o(i,j,2) * + gkw(3,3)*th2o(i,j,3) * + gkw(4,3)*th2o(i,j,4) * + gkw(5,3)*th2o(i,j,5) * + gkw(6,3)*th2o(i,j,6) ) * tcon(i,j,3) tran(i,j)=tran(i,j)*trnth2o enddo enddo endif return end c********************************************************************** subroutine co2kdis(m,n,np,k,co2exp,tco2,tran) c********************************************************************** c compute co2 transmittances between levels k1 and k2 for c m x n soundings, using the k-distribution method with linear c pressure scaling. computations follow eq. (34). c c---- input parameters c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of levels (np) c current level (k) c exponentials for co2 absorption (co2exp) c c---- updated parameters c transmittance between levels k1 and k2 due to co2 absorption c for the various values of the absorption coefficient (tco2) c total transmittance (tran) c c********************************************************************** implicit none integer m,n,np,k,i,j c---- input parameters ----- _RL co2exp(m,n,np,6,2) c---- updated parameters ----- _RL tco2(m,n,6,2),tran(m,n) c---- temporary arrays ----- _RL xc c-----tco2 is the 6 exp factors between levels k1 and k2. c xc is the total co2 transmittance given by eq. (53). do j=1,n do i=1,m c-----band-wings tco2(i,j,1,1)=tco2(i,j,1,1)*co2exp(i,j,k,1,1) xc= 0.1395 *tco2(i,j,1,1) tco2(i,j,2,1)=tco2(i,j,2,1)*co2exp(i,j,k,2,1) xc=xc+0.1407 *tco2(i,j,2,1) tco2(i,j,3,1)=tco2(i,j,3,1)*co2exp(i,j,k,3,1) xc=xc+0.1549 *tco2(i,j,3,1) tco2(i,j,4,1)=tco2(i,j,4,1)*co2exp(i,j,k,4,1) xc=xc+0.1357 *tco2(i,j,4,1) tco2(i,j,5,1)=tco2(i,j,5,1)*co2exp(i,j,k,5,1) xc=xc+0.0182 *tco2(i,j,5,1) tco2(i,j,6,1)=tco2(i,j,6,1)*co2exp(i,j,k,6,1) xc=xc+0.0220 *tco2(i,j,6,1) c-----band-center region tco2(i,j,1,2)=tco2(i,j,1,2)*co2exp(i,j,k,1,2) xc=xc+0.0766 *tco2(i,j,1,2) tco2(i,j,2,2)=tco2(i,j,2,2)*co2exp(i,j,k,2,2) xc=xc+0.1372 *tco2(i,j,2,2) tco2(i,j,3,2)=tco2(i,j,3,2)*co2exp(i,j,k,3,2) xc=xc+0.1189 *tco2(i,j,3,2) tco2(i,j,4,2)=tco2(i,j,4,2)*co2exp(i,j,k,4,2) xc=xc+0.0335 *tco2(i,j,4,2) tco2(i,j,5,2)=tco2(i,j,5,2)*co2exp(i,j,k,5,2) xc=xc+0.0169 *tco2(i,j,5,2) tco2(i,j,6,2)=tco2(i,j,6,2)*co2exp(i,j,k,6,2) xc=xc+0.0059 *tco2(i,j,6,2) tran(i,j)=tran(i,j)*xc enddo enddo return end c********************************************************************** subroutine n2okdis(ib,m,n,np,k,n2oexp,tn2o,tran) c********************************************************************** c compute n2o transmittances between levels k1 and k2 for c m x n soundings, using the k-distribution method with linear c pressure scaling. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of levels (np) c current level (k) c exponentials for n2o absorption (n2oexp) c c---- updated parameters c transmittance between levels k1 and k2 due to n2o absorption c for the various values of the absorption coefficient (tn2o) c total transmittance (tran) c c********************************************************************** implicit none integer ib,m,n,np,k,i,j c---- input parameters ----- _RL n2oexp(m,n,np,4) c---- updated parameters ----- _RL tn2o(m,n,4),tran(m,n) c---- temporary arrays ----- _RL xc c-----tn2o is the 2 exp factors between levels k1 and k2. c xc is the total n2o transmittance do j=1,n do i=1,m c-----band 6 if (ib.eq.6) then tn2o(i,j,1)=tn2o(i,j,1)*n2oexp(i,j,k,1) xc= 0.940414*tn2o(i,j,1) tn2o(i,j,2)=tn2o(i,j,2)*n2oexp(i,j,k,2) xc=xc+0.059586*tn2o(i,j,2) c-----band 7 else tn2o(i,j,1)=tn2o(i,j,1)*n2oexp(i,j,k,1) xc= 0.561961*tn2o(i,j,1) tn2o(i,j,2)=tn2o(i,j,2)*n2oexp(i,j,k,2) xc=xc+0.138707*tn2o(i,j,2) tn2o(i,j,3)=tn2o(i,j,3)*n2oexp(i,j,k,3) xc=xc+0.240670*tn2o(i,j,3) tn2o(i,j,4)=tn2o(i,j,4)*n2oexp(i,j,k,4) xc=xc+0.058662*tn2o(i,j,4) endif tran(i,j)=tran(i,j)*xc enddo enddo return end c********************************************************************** subroutine ch4kdis(ib,m,n,np,k,ch4exp,tch4,tran) c********************************************************************** c compute ch4 transmittances between levels k1 and k2 for c m x n soundings, using the k-distribution method with c linear pressure scaling. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of levels (np) c current level (k) c exponentials for ch4 absorption (ch4exp) c c---- updated parameters c transmittance between levels k1 and k2 due to ch4 absorption c for the various values of the absorption coefficient (tch4) c total transmittance (tran) c c********************************************************************** implicit none integer ib,m,n,np,k,i,j c---- input parameters ----- _RL ch4exp(m,n,np,4) c---- updated parameters ----- _RL tch4(m,n,4),tran(m,n) c---- temporary arrays ----- _RL xc c-----tch4 is the 2 exp factors between levels k1 and k2. c xc is the total ch4 transmittance do j=1,n do i=1,m c-----band 6 if (ib.eq.6) then tch4(i,j,1)=tch4(i,j,1)*ch4exp(i,j,k,1) xc= tch4(i,j,1) c-----band 7 else tch4(i,j,1)=tch4(i,j,1)*ch4exp(i,j,k,1) xc= 0.610650*tch4(i,j,1) tch4(i,j,2)=tch4(i,j,2)*ch4exp(i,j,k,2) xc=xc+0.280212*tch4(i,j,2) tch4(i,j,3)=tch4(i,j,3)*ch4exp(i,j,k,3) xc=xc+0.107349*tch4(i,j,3) tch4(i,j,4)=tch4(i,j,4)*ch4exp(i,j,k,4) xc=xc+0.001789*tch4(i,j,4) endif tran(i,j)=tran(i,j)*xc enddo enddo return end c********************************************************************** subroutine comkdis(ib,m,n,np,k,comexp,tcom,tran) c********************************************************************** c compute co2-minor transmittances between levels k1 and k2 c for m x n soundings, using the k-distribution method c with linear pressure scaling. c c---- input parameters c spectral band (ib) c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of levels (np) c current level (k) c exponentials for co2-minor absorption (comexp) c c---- updated parameters c transmittance between levels k1 and k2 due to co2-minor absorption c for the various values of the absorption coefficient (tcom) c total transmittance (tran) c c********************************************************************** implicit none integer ib,m,n,np,k,i,j c---- input parameters ----- _RL comexp(m,n,np,2) c---- updated parameters ----- _RL tcom(m,n,2),tran(m,n) c---- temporary arrays ----- _RL xc c-----tcom is the 2 exp factors between levels k1 and k2. c xc is the total co2-minor transmittance do j=1,n do i=1,m c-----band 4 if (ib.eq.4) then tcom(i,j,1)=tcom(i,j,1)*comexp(i,j,k,1) xc= 0.972025*tcom(i,j,1) tcom(i,j,2)=tcom(i,j,2)*comexp(i,j,k,2) xc=xc+0.027975*tcom(i,j,2) c-----band 5 else tcom(i,j,1)=tcom(i,j,1)*comexp(i,j,k,1) xc= 0.961324*tcom(i,j,1) tcom(i,j,2)=tcom(i,j,2)*comexp(i,j,k,2) xc=xc+0.038676*tcom(i,j,2) endif tran(i,j)=tran(i,j)*xc enddo enddo return end c********************************************************************** subroutine cfckdis(m,n,np,k,cfcexp,tcfc,tran) c********************************************************************** c compute cfc-(11,12,22) transmittances between levels k1 and k2 c for m x n soundings, using the k-distribution method with c linear pressure scaling. c c---- input parameters c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of levels (np) c current level (k) c exponentials for cfc absorption (cfcexp) c c---- updated parameters c transmittance between levels k1 and k2 due to cfc absorption c for the various values of the absorption coefficient (tcfc) c total transmittance (tran) c c********************************************************************** implicit none integer m,n,np,k,i,j c---- input parameters ----- _RL cfcexp(m,n,np) c---- updated parameters ----- _RL tcfc(m,n),tran(m,n) c-----tcfc is the exp factors between levels k1 and k2. do j=1,n do i=1,m tcfc(i,j)=tcfc(i,j)*cfcexp(i,j,k) tran(i,j)=tran(i,j)*tcfc(i,j) enddo enddo return end c********************************************************************** subroutine b10kdis(m,n,np,k,h2oexp,conexp,co2exp,n2oexp * ,th2o,tcon,tco2,tn2o,tran) c********************************************************************** c c compute h2o (line and continuum),co2,n2o transmittances between c levels k1 and k2 for m x n soundings, using the k-distribution c method with linear pressure scaling. c c---- input parameters c number of grid intervals in zonal direction (m) c number of grid intervals in meridional direction (n) c number of levels (np) c current level (k) c exponentials for h2o line absorption (h2oexp) c exponentials for h2o continuum absorption (conexp) c exponentials for co2 absorption (co2exp) c exponentials for n2o absorption (n2oexp) c c---- updated parameters c transmittance between levels k1 and k2 due to h2o line absorption c for the various values of the absorption coefficient (th2o) c transmittance between levels k1 and k2 due to h2o continuum c absorption for the various values of the absorption c coefficient (tcon) c transmittance between levels k1 and k2 due to co2 absorption c for the various values of the absorption coefficient (tco2) c transmittance between levels k1 and k2 due to n2o absorption c for the various values of the absorption coefficient (tn2o) c total transmittance (tran) c c********************************************************************** implicit none integer m,n,np,k,i,j c---- input parameters ----- _RL h2oexp(m,n,np,6),conexp(m,n,np,3),co2exp(m,n,np,6,2) * ,n2oexp(m,n,np,4) c---- updated parameters ----- _RL th2o(m,n,6),tcon(m,n,3),tco2(m,n,6,2),tn2o(m,n,4) * ,tran(m,n) c---- temporary arrays ----- _RL xx c-----initialize tran do j=1,n do i=1,m tran(i,j)=1.0 enddo enddo c-----for h2o line do j=1,n do i=1,m th2o(i,j,1)=th2o(i,j,1)*h2oexp(i,j,k,1) xx= 0.3153*th2o(i,j,1) th2o(i,j,2)=th2o(i,j,2)*h2oexp(i,j,k,2) xx=xx+0.4604*th2o(i,j,2) th2o(i,j,3)=th2o(i,j,3)*h2oexp(i,j,k,3) xx=xx+0.1326*th2o(i,j,3) th2o(i,j,4)=th2o(i,j,4)*h2oexp(i,j,k,4) xx=xx+0.0798*th2o(i,j,4) th2o(i,j,5)=th2o(i,j,5)*h2oexp(i,j,k,5) xx=xx+0.0119*th2o(i,j,5) tran(i,j)=tran(i,j)*xx enddo enddo c-----for h2o continuum do j=1,n do i=1,m tcon(i,j,1)=tcon(i,j,1)*conexp(i,j,k,1) tran(i,j)=tran(i,j)*tcon(i,j,1) enddo enddo c-----for co2 do j=1,n do i=1,m tco2(i,j,1,1)=tco2(i,j,1,1)*co2exp(i,j,k,1,1) xx= 0.2673*tco2(i,j,1,1) tco2(i,j,2,1)=tco2(i,j,2,1)*co2exp(i,j,k,2,1) xx=xx+ 0.2201*tco2(i,j,2,1) tco2(i,j,3,1)=tco2(i,j,3,1)*co2exp(i,j,k,3,1) xx=xx+ 0.2106*tco2(i,j,3,1) tco2(i,j,4,1)=tco2(i,j,4,1)*co2exp(i,j,k,4,1) xx=xx+ 0.2409*tco2(i,j,4,1) tco2(i,j,5,1)=tco2(i,j,5,1)*co2exp(i,j,k,5,1) xx=xx+ 0.0196*tco2(i,j,5,1) tco2(i,j,6,1)=tco2(i,j,6,1)*co2exp(i,j,k,6,1) xx=xx+ 0.0415*tco2(i,j,6,1) tran(i,j)=tran(i,j)*xx enddo enddo c-----for n2o do j=1,n do i=1,m tn2o(i,j,1)=tn2o(i,j,1)*n2oexp(i,j,k,1) xx= 0.970831*tn2o(i,j,1) tn2o(i,j,2)=tn2o(i,j,2)*n2oexp(i,j,k,2) xx=xx+0.029169*tn2o(i,j,2) tran(i,j)=tran(i,j)*(xx-1.0) enddo enddo return end