c********************************************************************** c c Contains the following old 1-d model subroutines: c c -NLTEdlvr11_TCOOL_03 c -NLTEdlvr11_CZALU_03 c -NLTEdlvr11_FB626CTS_03 c c c c *** Old NLTEdlvr11_TCOOL_02 *** c c*********************************************************************** c*********************************************************************** subroutine nlte_tcool(ngridgcm,n_gcm, $ p_gcm, t_gcm, z_gcm, $ co2vmr_gcm, n2vmr_gcm, covmr_gcm, o3pvmr_gcm, $ q15umco2_gcm ) c*********************************************************************** implicit none include "dimensions.h" include "dimphys.h" include 'nlte_paramdef.h' include 'nlte_commons.h' include "chimiedata.h" include "conc.h" c Arguments integer n_gcm,ngridgcm real p_gcm(ngridgcm,n_gcm), t_gcm(ngridgcm,n_gcm) real z_gcm(ngridgcm,n_gcm) real co2vmr_gcm(ngridgcm,n_gcm), n2vmr_gcm(ngridgcm,n_gcm) real covmr_gcm(ngridgcm,n_gcm), o3pvmr_gcm(ngridgcm,n_gcm) real q15umco2_gcm(ngridgcm,n_gcm) ! real auxgcm(n_gcm) real*8 auxgcmd(n_gcm), aux2gcmd(n_gcm) real zmin_gcm integer ierr real*8 varerr c local variables and constants integer i,ig,l, indice, nl_cts_real, nzy_cts_real real*8 q15umco2_nltot(nltot), zld(nltot) real*8 hr110CTS(nl_cts) real xx,factor real p_ig(n_gcm),z_ig(n_gcm) real t_ig(n_gcm) real co2_ig(n_gcm),n2_ig(n_gcm),co_ig(n_gcm),o3p_ig(n_gcm) real mmean_ig(n_gcm),cpnew_ig(n_gcm) c*************** c*************** do ig=1,ngridgcm ierr = 0 nl_cts_real = 0 nzy_cts_real = 0 do l=1,n_gcm p_ig(l)=p_gcm(ig,l) t_ig(l)=t_gcm(ig,l) co2_ig(l)=co2vmr_gcm(ig,l) n2_ig(l)=n2vmr_gcm(ig,l) o3p_ig(l)=o3pvmr_gcm(ig,l) co_ig(l)=covmr_gcm(ig,l) z_ig(l)=z_gcm(ig,l)/1000. mmean_ig(l)=mmean(ig,l) cpnew_ig(l)=cpnew(ig,l) enddo ! From GCM's grid to NLTE's grid call NLTEdlvr11_ZGRID_02 (n_gcm, $ p_ig, t_ig, z_ig, $ co2_ig, n2_ig, co_ig, o3p_ig, $ mmean_ig,cpnew_ig, $ nl_cts_real, nzy_cts_real ) ! Isotopic Tstar & VC at the NLTE grid call interdp_ESCTVCISO ! Tstar para NLTE-CTS call MZESC110 ( nl_cts_real, nzy_cts_real ) ! 626FB C.M. call leetvt c110(1:nl,1:nl)=0.d0 ! call zerom (c110, nl) call zero2v (vc110,taustar11, nl) call MZTUD110 ( ierr, varerr ) if (ierr .gt. 0) goto 900 input_cza = 0 call NLTEdlvr11_CZALU input_cza = 1 call NLTEdlvr11_CZALU ! call NLTEdlvr11_FB626CTS ! Falta un merging del hr110CTS con el HR110 ! ! Interpolation of Tstar11(nl) to the GCM grid (será auxgcm) ! ! solo entre jlowerboundary y jtopboundary (la extension del NLTE ! ! model) ! call interhuntlimits( auxgcm, p_gcm,n_gcm, ! @ jlowerboundary,jtopboundary, ! @ taustar11, pl, nl, 3 ) ! ! Mejor inter+extra polacion de Tstar11(nl) to the GCM grid ! call TSTAR11_extension (n_gcm, p_gcm, auxgcm ) ! NLTE-CTS call NLTEdlvr11_FB626CTS ( hr110CTS , nl_cts_real ) ! total TCR do i = 1, nl q15umco2_nltot(i) =hr110(i) + hr210(i) + hr310(i) + hr410(i) @ + hr121(i) enddo ! Merging con / actualizacion del HR_total ! Eliminamos el ultimo pto de hrTotal, y en el penultimo ! (que coincide con i=1 en el grid nl_cts) ! hacemos la media entre hrTotal y hr110CTS : i=nl-1 q15umco2_nltot(i) = 0.5*( q15umco2_nltot(i) + hr110CTS(1) ) do i=2,nl_cts_real indice = (nl-2) + i q15umco2_nltot(indice) = hr110CTS(i) enddo do i=nl_cts_real+1,nl_cts indice = (nl-2) + i q15umco2_nltot(indice) = 0.0d0 enddo ! Interpol to original Pgrid ! ! Primero, la parte conocida ([1,nl_cts_real]) do i=1,nl zld(i) = - dble ( alog(pl(i)) ) !write (*,*) i, zld(i), q15umco2_nltot(i) enddo do i=3,nl_cts_real indice = (nl-2) + i zld(indice) = - dble ( alog(pl_cts(i)) ) !write (*,*) indice, zld(indice), q15umco2_nltot(indice) enddo ! En caso que nl_cts_real < nl_cts , extrapolo el grid alegremente factor = pl_cts(nl_cts_real)/pl_cts(nl_cts_real-1) xx = pl_cts(nl_cts_real) do i=nl_cts_real+1,nl_cts indice = (nl-2) + i xx = xx * factor zld(indice) = - dble ( alog(xx) ) enddo do i=1,n_gcm auxgcmd(i) = - dble( alog(p_gcm(ig,i)) ) enddo ! call zerov( aux2gcmd, n_gcm ) aux2gcmd(1:n_gcm)=0.d0 call interdp_limits $ ( aux2gcmd, auxgcmd, n_gcm, jlowerboundary,jtopCTS, $ q15umco2_nltot, zld, nltot, 1, nltot, $ 1 ) ! Smoothing call suaviza ( aux2gcmd, n_gcm, 1, auxgcmd ) do i=1,n_gcm q15umco2_gcm(ig,i) = sngl( aux2gcmd(i) ) enddo enddo c end subroutine return c Error messages 900 write (*,*) ' ERROR in MZTUD (banda 110). ierr=',ierr write (*,*) ' VAR available : ', varerr return 901 write (*,*) ' ERROR in MZTVC for vc210. ierr=',ierr write (*,*) ' VAR available : ', varerr return 902 write (*,*) ' ERROR in MZTVC for vc310. ierr=',ierr write (*,*) ' VAR available : ', varerr return 903 write (*,*) ' ERROR in MZTVC for vc410. ierr=',ierr write (*,*) ' VAR available : ', varerr return 904 write (*,*) ' ERROR in mzescape_fb ierr=',ierr write (*,*) ' VAR available : ', varerr return 930 write (*,*) ' ERROR in mztvc3iso. Temp is NaN' write (*,*) ' ierr , VAR =', ierr, varerr if (ierr.eq.30) write (*,*) ' During computation of VC210.' if (ierr.eq.31) write (*,*) ' During computation of VC310.' if (ierr.eq.32) write (*,*) ' During computation of VC410.' return c end subroutine end c*********************************************************************** subroutine NLTEdlvr11_ZGRID_02 (n_gcm, $ p_gcm, t_gcm, z_gcm, co2vmr_gcm, n2vmr_gcm, $ covmr_gcm, o3pvmr_gcm, mmean_gcm,cpnew_gcm, $ nl_cts_real, nzy_cts_real ) c*********************************************************************** implicit none include 'nlte_paramdef.h' include 'nlte_commons.h' c Arguments integer n_gcm ! I real p_gcm(n_gcm), t_gcm(n_gcm) ! I real co2vmr_gcm(n_gcm), n2vmr_gcm(n_gcm) ! I real covmr_gcm(n_gcm), o3pvmr_gcm(n_gcm) ! I real z_gcm(n_gcm) ! I real mmean_gcm(n_gcm) ! I real cpnew_gcm(n_gcm) ! I integer nl_cts_real, nzy_cts_real ! O c local variables integer i, iz real distancia, meanm, gz, Hkm real zmin, zmax real mmean_nlte(n_gcm),cpnew_nlte(n_gcm) c functions external hrkday_convert real hrkday_convert c*********************************************************************** ! Define el working grid para MZ1D (NL, ZL, ZMIN) ! y otro mas fino para M.Curtis (NZ, ZX, ZXMIN = ZMIN) ! Tambien el working grid para MZESC110 (NL_cts, ZL_cts, ZMIN_cts=??) ! Para ello hace falta una z de ref del GCM, que voy a suponer la inferior ! Primero, construimos escala z_gcm ! z_gcm(1) = zmin_gcm ! [km] ! do iz = 2, n_gcm ! meanm = ( co2vmr_gcm(iz)*44. + o3pvmr_gcm(iz)*16. ! @ + n2vmr_gcm(iz)*28. + covmr_gcm(iz)*28. ) ! meanm = meanm / n_avog ! distancia = ( radio + z_gcm(iz-1) )*1.e5 ! gz = gg * masa / ( distancia * distancia ) ! Hkm = 0.5*( t_gcm(iz)+t_gcm(iz-1) ) / ( meanm * gz ) ! Hkm = kboltzman * Hkm *1e-5 ! [km] ! z_gcm(iz) = z_gcm(iz-1) - Hkm * log( p_gcm(iz)/p_gcm(iz-1) ) ! enddo ! Segundo, definimos los límites de los 2 modelos de NLTE. ! NLTE model completo: indices [jlowerboundary,jtopboundary] ! NLTE CTS : indices [jbotCTS,jtopCTS] donde jbotCTS = jtopboundary-2 !!!!!!!!!Primero el NLTE completo !!!!!!!! ! Bottom boundary for NLTE model : ! Pbot_atm = 2e-2 mb = 1.974e-5 atm , lnp(nb)=9.9 (see mz1d.par) jlowerboundary = 1 do while ( p_gcm(jlowerboundary) .gt. Pbottom_atm ) jlowerboundary = jlowerboundary + 1 if (jlowerboundary .gt. n_gcm) then write (*,*) 'Error in lower boundary pressure.' write (*,*) ' p_gcm too low or wrong. ' write (*,*) ' p_gcm, Pbottom_atm =', $ p_gcm(n_gcm), Pbottom_atm stop ' Check input value "p_gcm" or modify "Pbottom_atm" ' endif enddo ! Top boundary for NLTE model : ! Ptop_atm = 1e-9 atm (see mz1d.par) jtopboundary = jlowerboundary do while ( p_gcm(jtopboundary) .gt. Ptop_atm ) jtopboundary = jtopboundary + 1 if (jtopboundary .gt. n_gcm) then write (*,*) '!!!!!!!! Warning in top boundary pressure. ' write (*,*) ' Ptop_atm too high for p_gcm. ' write (*,*) ' p_gcm, Ptop_atm =', $ p_gcm(n_gcm), Ptop_atm write (*,*) '!!!!!!!! NLTE upper boundary modified '// $ ' to match p_gcm' jtopboundary=n_gcm goto 5000 endif enddo 5000 continue ! Grid steps zmin = z_gcm(jlowerboundary) zmax = z_gcm(jtopboundary) deltaz = (zmax-zmin) / (nl-1) do i=1,nl zl(i) = zmin + (i-1) * deltaz enddo ! Creamos el perfil del NLTE modelo completo interpolando call interhunt ( pl,zl,nl, p_gcm,z_gcm,n_gcm, 2) ! [atm] call interhunt5veces $ ( t, co2vmr, n2vmr, covmr, o3pvmr, $ zl, nl, $ t_gcm, co2vmr_gcm, n2vmr_gcm, covmr_gcm, o3pvmr_gcm, $ z_gcm, n_gcm, $ 1 ) call interhunt ( mmean_nlte,zl,nl,mmean_gcm,z_gcm,n_gcm,1) call interhunt ( cpnew_nlte,zl,nl,cpnew_gcm,z_gcm,n_gcm,1) do i = 1, nl nt(i) = 7.339e+21 * pl(i) / t(i) ! --> [cm-3] co2(i) = nt(i) * co2vmr(i) n2(i) = nt(i) * n2vmr(i) co(i) = nt(i) * covmr(i) o3p(i) = nt(i) * o3pvmr(i) ! hrkday_factor(i) = hrkday_convert( t(i), ! $ co2vmr(i), o3pvmr(i), n2vmr(i), covmr(i) ) hrkday_factor(i) = hrkday_convert(mmean_nlte(i) & ,cpnew_nlte(i)) enddo ! Comprobar que las temps no se salen del grid del histograma do i=1,nl if (t(i) .gt. 400.0) then write (*,*) '!!!! WARNING Temp higher than Histogram.' write (*,*) ' Histogram will be extrapolated. ' write (*,*) ' i, t(i), pl(i) =', i, t(i), pl(i) endif if (t(i) .lt. 50.0) then write (*,*) '!!!! WARNING Temp lower than Histogram.' write (*,*) ' Histogram will be extrapolated. ' write (*,*) ' i, t(i), pl(i) =', i, t(i), pl(i) endif enddo ! Fine grid for transmittance calculations zmin = z_gcm(jlowerboundary) zmax = z_gcm(jtopboundary) deltazy = (zmax-zmin) / (nzy-1) do i=1,nzy zy(i) = zmin + (i-1) * deltazy enddo call interhunt ( py,zy,nzy, p_gcm,z_gcm,n_gcm, 2) ! [atm] call interhunt2veces ( ty,co2y, zy,nzy, $ t_gcm,co2vmr_gcm, z_gcm,n_gcm, 1) do i=1,nzy nty(i) = 7.339e+21 * py(i) / ty(i) ! --> [cm-3] co2y(i) = co2y(i) * nty(i) enddo !!!!!!!!!Segundo, el NLTE - CTS !!!!!!!! ! Grid steps deltaz_cts = deltaz zl_cts(1) = zl(nl-1) nl_cts_real = 1 do i=2,nl_cts zl_cts(i) = zl_cts(1) + (i-1)*deltaz_cts if (zl_cts(i) .gt. z_gcm(n_gcm)) then ! write (*,*) '!!!!!!!! Warning in top CTS layers. ' ! write (*,*) ' zl_Cts too high for z_gcm. ' ! write (*,*) ' z_gcm, zl_cts(i), i =', ! $ z_gcm(n_gcm), zl_cts(i), i ! write (*,*) '!!!!!!!! NLTE-CTS upper boundary modified '// ! $ ' to match z_gcm' nl_cts_real=i-1 ! write (*,*) ' Original,Real NL_CTS=', nl_cts,nl_cts_real goto 6000 endif enddo nl_cts_real = nl_cts 6000 continue ! Creamos perfil por interpolacion call interhuntlimits ( pl_cts,zl_cts,nl_cts, 1,nl_cts_real, $ p_gcm,z_gcm,n_gcm, 2) call interhuntlimits5veces $ ( t_cts, co2vmr_cts, n2vmr_cts, covmr_cts, o3pvmr_cts, $ zl_cts, nl_cts, $ 1,nl_cts_real, $ t_gcm, co2vmr_gcm, n2vmr_gcm, covmr_gcm, o3pvmr_gcm, $ z_gcm, n_gcm, $ 1 ) call interhuntlimits( cpnew_cts,zl_cts,nl_cts,1,nl_cts_real, $ cpnew_gcm,z_gcm,n_gcm, 1) call interhuntlimits( mmean_cts,zl_cts,nl_cts,1,nl_cts_real, $ mmean_gcm,z_gcm,n_gcm, 1) do i = 1, nl_cts_real nt_cts(i) = 7.339e+21 * pl_cts(i) / t_cts(i) ! --> [cm-3] co2_cts(i) = nt_cts(i) * co2vmr_cts(i) n2_cts(i) = nt_cts(i) * n2vmr_cts(i) co_cts(i) = nt_cts(i) * covmr_cts(i) o3p_cts(i) = nt_cts(i) * o3pvmr_cts(i) hrkday_factor_cts(i) = hrkday_convert( mmean_cts(i) & ,cpnew_cts(i) ) enddo ! Comprobar que las temps no se salen del grid del histograma do i=1,nl_cts_real if (t_cts(i) .gt. 400.0) then write (*,*) '!!!! WARNING Temp higher than Histogram.' write (*,*) ' ZGRID: Histogram will be extrapolated. ' write (*,*) ' i, t(i), pl(i) =', i, t_cts(i), pl_cts(i) endif if (t_cts(i) .lt. 50.0) then write (*,*) '!!!! WARNING Temp lower than Histogram.' write (*,*) ' ZGRID: Histogram will be extrapolated. ' write (*,*) ' i, t(i), pl(i) =', i, t_cts(i), pl_cts(i) endif enddo ! Calculo del indice maximo del GCM hasta donde llega el NLTE-CTS jtopCTS = jtopboundary do while ( p_gcm(jtopCTS) .gt. pl_cts(nl_cts_real) ) jtopCTS = jtopCTS + 1 if (jtopCTS .gt. n_gcm) then write (*,*) '!!!!!!!! Warning in top boundary pressure. ' write (*,*) ' Ptop_NLTECTS too high for p_gcm. ' write (*,*) ' p_gcm, Ptop_NLTECTS =', $ p_gcm(n_gcm), pl_cts(nl_cts_real) write (*,*) '!!!!!!!! NLTE-CTS upper boundary modified '// $ ' to match p_gcm' jtopCTS=n_gcm goto 7000 endif enddo 7000 continue ! Fine grid for transmittance calculations deltazy_cts = 0.25*deltaz_cts ! Comprobar el factor 4 en mz1d.par do i=1,nzy_cts zy_cts(i) = zl_cts(1) + (i-1) * deltazy_cts enddo nzy_cts_real = (nl_cts_real - 1)*4 + 1 call interhuntlimits ( py_cts,zy_cts,nzy_cts, 1,nzy_cts_real, $ p_gcm, z_gcm, n_gcm, 2) ! [atm] call interhuntlimits2veces $ ( ty_cts,co2y_cts, zy_cts,nzy_cts, 1,nzy_cts_real, $ t_gcm,co2vmr_gcm, z_gcm,n_gcm, 1) do i=1,nzy_cts_real nty_cts(i) = 7.339e+21 * py_cts(i) / ty_cts(i) ! --> [cm-3] co2y_cts(i) = co2y_cts(i) * nty_cts(i) enddo ! write (*,*) ' NL = ', NL ! write (*,*) ' Original,Real NL_CTS=', nl_cts,nl_cts_real ! write (*,*) ' Original,Real NZY_CTS =', nzy_cts,nzy_cts_real c end return end c *** Old NLTEdlvr11_CZALU_03 *** c********************************************************************** subroutine NLTEdlvr11_CZALU c*********************************************************************** implicit none !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!common variables and constants include 'nlte_paramdef.h' include 'nlte_commons.h' c local variables ! matrixes and vectors real*8 e110(nl), e210(nl), e310(nl), e410(nl) real*8 e121(nl) real*8 f1(nl,nl) real*8 cax1(nl,nl), cax2(nl,nl), cax3(nl,nl) real*8 v1(nl), v2(nl), v3(nl) real*8 alf11(nl,nl), alf12(nl,nl) real*8 alf21(nl,nl), alf31(nl,nl), alf41(nl,nl) real*8 a11(nl), a1112(nl,nl) real*8 a1121(nl,nl), a1131(nl,nl), a1141(nl,nl) real*8 a21(nl), a2131(nl,nl), a2141(nl,nl) real*8 a2111(nl,nl), a2112(nl,nl) real*8 a31(nl), a3121(nl,nl), a3141(nl,nl) real*8 a3111(nl,nl), a3112(nl,nl) real*8 a41(nl), a4121(nl,nl), a4131(nl,nl) real*8 a4111(nl,nl), a4112(nl,nl) real*8 a12(nl), a1211(nl,nl) real*8 a1221(nl,nl), a1231(nl,nl), a1241(nl,nl) real*8 aalf11(nl,nl),aalf21(nl,nl), @ aalf31(nl,nl),aalf41(nl,nl) real*8 aa11(nl), aa1121(nl,nl), aa1131(nl,nl), aa1141(nl,nl) real*8 aa21(nl), aa2111(nl,nl), aa2131(nl,nl), aa2141(nl,nl) real*8 aa31(nl), aa3111(nl,nl), aa3121(nl,nl), aa3141(nl,nl) real*8 aa41(nl), aa4111(nl,nl), aa4121(nl,nl), aa4131(nl,nl) real*8 aa1211(nl,nl),aa1221(nl,nl), @ aa1231(nl,nl),aa1241(nl,nl) real*8 aa1112(nl,nl),aa2112(nl,nl), @ aa3112(nl,nl),aa4112(nl,nl) real*8 aaalf11(nl,nl), aaalf31(nl,nl), aaalf41(nl,nl) real*8 aaa11(nl),aaa1131(nl,nl),aaa1141(nl,nl) real*8 aaa31(nl),aaa3111(nl,nl),aaa3141(nl,nl) real*8 aaa41(nl),aaa4111(nl,nl),aaa4131(nl,nl) real*8 aaaalf11(nl,nl),aaaalf41(nl,nl) real*8 aaaa11(nl),aaaa1141(nl,nl) real*8 aaaa41(nl),aaaa4111(nl,nl) ! populations real*8 n10(nl), n11(nl), n12(nl) real*8 n20(nl), n21(nl) real*8 n30(nl), n31(nl) real*8 n40(nl), n41(nl) ! productions and loses real*8 d19b1,d19c1 real*8 d19bp1,d19cp1 real*8 d19c2 real*8 d19cp2 real*8 d19c3 real*8 d19cp3 real*8 d19c4 real*8 d19cp4 real*8 l11, l12, l21, l31, l41 real*8 p11, p12, p21, p31, p41 real*8 p1112, p1211, p1221, p1231, p1241 real*8 p1121, p1131, p1141 real*8 p2111, p2112, p2131, p2141 real*8 p3111, p3112, p3121, p3141 real*8 p4111, p4112, p4121, p4131 real*8 pl11, pl12, pl21, pl31, pl41 c local constants and indexes real*8 co2t, o3pdbl, codble, n2dble real*8 a12_einst(nl) real*8 a21_einst(nl), a31_einst(nl), a41_einst(nl) real tsurf integer i, isot c external functions and subroutines external planckdp real*8 planckdp !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!start program call zero4v( aa11, aa21, aa31, aa41, nl) call zero4m( aa1121, aa1131, aa1141, aalf11, nl) call zero4m( aa2111, aa2131, aa2141, aalf21, nl) call zero4m( aa3111, aa3121, aa3141, aalf31, nl) call zero4m( aa4111, aa4121, aa4131, aalf41, nl) call zero4m( aa1112, aa2112, aa3112, aa4112, nl) call zero4m( aa1211, aa1221, aa1231, aa1241, nl) call zero3v( aaa41, aaa31, aaa11, nl ) call zero3m( aaa4111, aaa4131, aaalf41, nl) call zero3m( aaa3111, aaa3141, aaalf31, nl) call zero3m( aaa1131, aaa1141, aaalf11, nl) call zero2v( aaaa11, aaaa41, nl ) call zero2m( aaaa1141, aaaalf11, nl) call zero2m( aaaa4111, aaaalf41, nl) call zero2v (vt11,vt12,nl) call zero3v (vt21,vt31,vt41,nl) call zero2v (hr110,hr121,nl) call zero3v (hr210,hr310,hr410,nl) call zero2v (sl110,sl121,nl) call zero3v (sl210,sl310,sl410,nl) call zero4v (el11,el21,el31,el41,nl) call zero4v (e110,e210,e310,e410,nl) call zero2v (el12,e121,nl) call zero3m (cax1,cax2,cax3,nl) f1(1:nl,1:nl)=0.d0 ! call zerom (f1,nl) call zero3v (v1,v2,v3,nl) call zero4m (alf11,alf21,alf31,alf41,nl) alf12(1:nl,1:nl)=0.d0 ! call zerom (alf12,nl) call zero2v (a11,a12,nl) call zero3v (a21,a31,a41,nl) call zero3m (a1121,a1131,a1141,nl) a1112(1:nl,1:nl)=0.d0 ! call zerom (a1112,nl) call zero3m (a1221,a1231,a1241,nl) a1211(1:nl,1:nl)=0.d0 ! call zerom (a1211,nl) call zero2m (a2111,a2112,nl) call zero2m (a2131,a2141,nl) call zero2m (a3111,a3112,nl) call zero2m (a3121,a3141,nl) call zero2m (a4111,a4112,nl) call zero2m (a4121,a4131,nl) call zero2v (n11,n12,nl) call zero3v (n21,n31,n41,nl) nu11 = dble(nu(1,1)) nu12 = dble(nu(1,2)) nu121 = nu12-nu11 nu21 = dble(nu(2,1)) nu31 = dble(nu(3,1)) nu41 = dble(nu(4,1)) c c do i=1,nl n10(i) = dble( co2(i) * imr(1) ) n20(i) = dble( co2(i) * imr(2) ) n30(i) = dble( co2(i) * imr(3) ) n40(i) = dble( co2(i) * imr(4) ) if ( input_cza.ge.1 ) then n11(i) = n10(i) *2.d0 *exp( -ee*nu11/v626t1(i) ) n21(i) = n20(i) *2.d0 *exp( -ee*nu21/v628t1(i) ) n31(i) = n30(i) *2.d0* exp( -ee*nu31/v636t1(i) ) n41(i) = n40(i) *2.d0* exp( -ee*nu41/v627t1(i) ) end if enddo c c curtis matrix calculation c call zero3m (c210,c310,c410, nl) if ( input_cza.ge.1 ) then if (itt_cza.eq.15 ) then call MZMC121 elseif (itt_cza.eq.13) then ! call zerom ( c121, nl ) c121(1:nl,1:nl)=0.d0 call MZESC121 call MZTVC121 endif endif ! Lower Boundary tsurf = t(1) do i=1,nl sl110(i) = vc110(i) * planckdp( tsurf, nu11 ) sl210(i) = vc210(i) * planckdp( tsurf, nu21 ) sl310(i) = vc310(i) * planckdp( tsurf, nu31 ) sl410(i) = vc410(i) * planckdp( tsurf, nu41 ) end do if (input_cza.ge.1) then do i=1,nl sl121(i) = vc121(i) * planckdp( tsurf, nu121 ) end do endif do 4,i=nl,1,-1 !---------------------------------------------- co2t = dble( co2(i) *(imr(1)+imr(3)+imr(2)+imr(4)) ) o3pdbl = dble( o3p(i) ) n2dble = dble( n2(i) ) codble = dble ( co(i) ) call GETK_dlvr11 ( t(i) ) ! V-T productions and losses V-T isot = 1 d19b1 = k19ba(isot)*co2t + k19bb(isot)*n2dble @ + k19bc(isot)*codble d19c1 = k19ca(isot)*co2t + k19cb(isot)*n2dble @ + k19cc(isot)*codble d19bp1 = k19bap(isot)*co2t + k19bbp(isot)*n2dble @ + k19bcp(isot)*codble d19cp1 = k19cap(isot)*co2t + k19cbp(isot)*n2dble @ + k19ccp(isot)*codble isot = 2 d19c2 = k19ca(isot)*co2t + k19cb(isot)*n2dble @ + k19cc(isot)*codble d19cp2 = k19cap(isot)*co2t + k19cbp(isot)*n2dble @ + k19ccp(isot)*codble isot = 3 d19c3 = k19ca(isot)*co2t + k19cb(isot)*n2dble @ + k19cc(isot)*codble d19cp3 = k19cap(isot)*co2t + k19cbp(isot)*n2dble @ + k19ccp(isot)*codble isot = 4 d19c4 = k19ca(isot)*co2t + k19cb(isot)*n2dble @ + k19cc(isot)*codble d19cp4 = k19cap(isot)*co2t + k19cbp(isot)*n2dble @ + k19ccp(isot)*codble ! l11 = d19c1 + k20c(1)*o3pdbl p11 = ( d19cp1 + k20cp(1)*o3pdbl ) * n10(i) l21 = d19c2 + k20c(2)*o3pdbl p21 = ( d19cp2 + k20cp(2)*o3pdbl ) *n20(i) l31 = d19c3 + k20c(3)*o3pdbl p31 = ( d19cp3 + k20cp(3)*o3pdbl ) *n30(i) l41 = d19c4 + k20c(4)*o3pdbl p41 = ( d19cp4 + k20cp(4)*o3pdbl ) *n40(i) ! Addition of V-V l11 = l11 + k21cp(2)*n20(i) + k21cp(3)*n30(i) @ + k21cp(4)*n40(i) p1121 = k21c(2) * n10(i) p1131 = k21c(3) * n10(i) p1141 = k21c(4) * n10(i) ! l21 = l21 + k21c(2)*n10(i) + k23k21c*n30(i) + k24k21c*n40(i) p2111 = k21cp(2) * n20(i) p2131 = k23k21cp * n20(i) p2141 = k24k21cp * n20(i) ! l31 = l31 + k21c(3)*n10(i) + k23k21cp*n20(i) + k34k21c*n40(i) p3111 = k21cp(3)* n30(i) p3121 = k23k21c * n30(i) p3141 = k34k21cp* n30(i) ! l41 = l41 + k21c(4)*n10(i) + k24k21cp*n20(i) + k34k21cp*n30(i) p4111 = k21cp(4)* n40(i) p4121 = k24k21c * n40(i) p4131 = k34k21c * n40(i) if ( input_cza.ge.1 ) then l12 = d19b1 @ + k20b(1)*o3pdbl @ + k21b(1)*n10(i) @ + k33c*( n20(i) + n30(i) + n40(i) ) p12 = k21bp(1)*n11(i) * n11(i) p1211 = d19bp1 + k20bp(1)*o3pdbl p1221 = k33cp(2)*n11(i) p1231 = k33cp(3)*n11(i) p1241 = k33cp(4)*n11(i) l11 = l11 + d19bp1 @ + k20bp(1)*o3pdbl @ + 2.d0 * k21bp(1) * n11(i) @ + k33cp(2)*n21(i) + k33cp(3)*n31(i) + k33cp(4)*n41(i) p1112 = d19b1 @ + k20b(1)*o3pdbl @ + 2.d0*k21b(1)*n10(i) @ + k33c*( n20(i) + n30(i) + n40(i) ) l21 = l21 + k33cp(2)*n11(i) p2112 = k33c*n20(i) l31 = l31 + k33cp(3)*n11(i) p3112 = k33c*n30(i) l41 = l41 + k33cp(4)*n11(i) p4112 = k33c*n40(i) end if ! For ITT=13,15 a21_einst(i) = a2_010_000 * 1.8d0 / 4.d0 * taustar21(i) a31_einst(i) = a3_010_000 * 1.8d0 / 4.d0 * taustar31(i) a41_einst(i) = a4_010_000 * 1.8d0 / 4.d0 * taustar41(i) l21 = l21 + a21_einst(i) l31 = l31 + a31_einst(i) l41 = l41 + a41_einst(i) ! For ITT=13 if (input_cza.ge.1 .and. itt_cza.eq.13) then a12_einst(i) = a1_020_010/3.d0 * 1.8d0/4.d0 * taustar12(i) l12=l12+a12_einst(i) endif ! a11(i) = gamma*nu11**3.d0 * 1.d0/2.d0 * (p11) / @ (n10(i)*l11) a1121(i,i) = (nu11/nu21)**3.d0 * n20(i)/n10(i) * p1121/l11 a1131(i,i) = (nu11/nu31)**3.d0 * n30(i)/n10(i) * p1131/l11 a1141(i,i) = (nu11/nu41)**3.d0 * n40(i)/n10(i) * p1141/l11 e110(i) = 2.d0* vlight*nu11**2.d0 * 1.d0/2.d0 / @ ( n10(i) * l11 ) a21(i) = gamma*nu21**3.d0 * 1.d0/2.d0 * @ (p21)/(n20(i)*l21) a2111(i,i) = (nu21/nu11)**3.d0 * n10(i)/n20(i) * p2111/l21 a2131(i,i) = (nu21/nu31)**3.d0 * n30(i)/n20(i) * p2131/l21 a2141(i,i) = (nu21/nu41)**3.d0 * n40(i)/n20(i) * p2141/l21 e210(i) = 2.d0*vlight*nu21**2.d0 * 1.d0/2.d0 / @ ( n20(i) * l21 ) a31(i) = gamma*nu31**3.d0 * 1.d0/2.d0 * (p31) / @ (n30(i)*l31) a3111(i,i) = (nu31/nu11)**3.d0 * n10(i)/n30(i) * p3111/l31 a3121(i,i) = (nu31/nu21)**3.d0 * n20(i)/n30(i) * p3121/l31 a3141(i,i) = (nu31/nu41)**3.d0 * n40(i)/n30(i) * p3141/l31 e310(i) = 2.d0*vlight*nu31**2.d0 * 1.d0/2.d0 / @ ( n30(i) * l31 ) a41(i) = gamma*nu41**3.d0 * 1.d0/2.d0 * (p41) / @ (n40(i)*l41) a4111(i,i) = (nu41/nu11)**3.d0 * n10(i)/n40(i) * p4111/l41 a4121(i,i) = (nu41/nu21)**3.d0 * n20(i)/n40(i) * p4121/l41 a4131(i,i) = (nu41/nu31)**3.d0 * n30(i)/n40(i) * p4131/l41 e410(i) = 2.d0*vlight*nu41**2.d0 * 1.d0/2.d0 / @ ( n40(i) * l41 ) if (input_cza.ge.1) then a1112(i,i) = (nu11/nu121)**3.d0 * n11(i)/n10(i) * @ p1112/l11 a2112(i,i) = (nu21/nu121)**3.d0 * n11(i)/n20(i) * @ p2112/l21 a3112(i,i) = (nu31/nu121)**3.d0 * n11(i)/n30(i) * @ p3112/l31 a4112(i,i) = (nu41/nu121)**3.d0 * n11(i)/n40(i) * @ p4112/l41 a12(i) = gamma*nu121**3.d0 *2.d0/4.d0* (p12)/ @ (n11(i)*l12) a1211(i,i) = (nu121/nu11)**3.d0 * n10(i)/n11(i) * @ p1211/l12 a1221(i,i) = (nu121/nu21)**3.d0 * n20(i)/n11(i) * @ p1221/l12 a1231(i,i) = (nu121/nu31)**3.d0 * n30(i)/n11(i) * @ p1231/l12 a1241(i,i) = (nu121/nu41)**3.d0 * n40(i)/n11(i) * @ p1241/l12 e121(i) = 2.d0*vlight*nu121**2.d0 *2.d0/4.d0 / @ ( n11(i) * l12 ) end if 4 continue !------------------------------------------------------- !!!!!!!!!!!! Solucion del sistema !! Paso 0 : Calculo de los alphas alf11, alf21, alf31, alf41, alf12 call unit ( cax2, nl ) call diago ( cax1, e110, nl ) call mulmmf90 ( cax3, cax1,c110, nl ) call resmmf90 ( alf11, cax2,cax3, nl ) call diago ( cax1, e210, nl ) call mulmmf90 ( cax3, cax1,c210, nl ) call resmmf90 ( alf21, cax2,cax3, nl ) call diago ( cax1, e310, nl ) call mulmmf90 ( cax3, cax1,c310, nl ) call resmmf90 ( alf31, cax2,cax3, nl ) call diago ( cax1, e410, nl ) call mulmmf90 ( cax3, cax1,c410, nl ) call resmmf90 ( alf41, cax2,cax3, nl ) if (input_cza.ge.1) then call diago ( cax1, e121, nl ) call mulmmf90 ( cax3, cax1,c121, nl ) call resmmf90 ( alf12, cax2,cax3, nl ) endif !! Paso 1 : Calculo de vectores y matrices con 1 barra (aa***) if (input_cza.eq.0) then ! Skip paso 1, pues el12 no se calcula ! el11 call sypvvv( aa11, a11,e110,sl110, nl ) call samem( aa1121, a1121, nl ) call samem( aa1131, a1131, nl ) call samem( aa1141, a1141, nl ) call samem( aalf11, alf11, nl ) ! el21 call sypvvv( aa21, a21,e210,sl210, nl ) call samem( aa2111, a2111, nl ) call samem( aa2131, a2131, nl ) call samem( aa2141, a2141, nl ) call samem( aalf21, alf21, nl ) ! el31 call sypvvv( aa31, a31,e310,sl310, nl ) call samem( aa3111, a3111, nl ) call samem( aa3121, a3121, nl ) call samem( aa3141, a3141, nl ) call samem( aalf31, alf31, nl ) ! el41 call sypvvv( aa41, a41,e410,sl410, nl ) call samem( aa4111, a4111, nl ) call samem( aa4121, a4121, nl ) call samem( aa4131, a4131, nl ) call samem( aalf41, alf41, nl ) else ! (input_cza.ge.1) , FH ! call sypvvv( v1, a12,e121,sl121, nl ) ! a12 + e121 * sl121 ! aa11 call sypvvv( v2, a11,e110,sl110, nl ) call trucommvv( aa11 , alf12,a1112,v2, v1, nl ) ! aalf11 call invdiag( cax1, a1112, nl ) call mulmmf90( cax2, alf12, cax1, nl ) ! alf12 * (1/a1112) call mulmmf90( cax3, cax2, alf11, nl ) call resmmf90( aalf11, cax3, a1211, nl ) ! aa1121 call trucodiag(aa1121, alf12,a1112,a1121, a1221, nl) ! aa1131 call trucodiag(aa1131, alf12,a1112,a1131, a1231, nl) ! aa1141 call trucodiag(aa1141, alf12,a1112,a1141, a1241, nl) ! aa21 call sypvvv( v2, a21,e210,sl210, nl ) call trucommvv( aa21 , alf12,a2112,v2, v1, nl ) ! aalf21 call invdiag( cax1, a2112, nl ) call mulmmf90( cax2, alf12, cax1, nl ) ! alf12 * (1/a2112) call mulmmf90( cax3, cax2, alf21, nl ) call resmmf90( aalf21, cax3, a1221, nl ) ! aa2111 call trucodiag(aa2111, alf12,a2112,a2111, a1211, nl) ! aa2131 call trucodiag(aa2131, alf12,a2112,a2131, a1231, nl) ! aa2141 call trucodiag(aa2141, alf12,a2112,a2141, a1241, nl) ! aa31 call sypvvv ( v2, a31,e310,sl310, nl ) call trucommvv( aa31 , alf12,a3112,v2, v1, nl ) ! aalf31 call invdiag( cax1, a3112, nl ) call mulmmf90( cax2, alf12, cax1, nl ) ! alf12 * (1/a3112) call mulmmf90( cax3, cax2, alf31, nl ) call resmmf90( aalf31, cax3, a1231, nl ) ! aa3111 call trucodiag(aa3111, alf12,a3112,a3111, a1211, nl) ! aa3121 call trucodiag(aa3121, alf12,a3112,a3121, a1221, nl) ! aa3141 call trucodiag(aa3141, alf12,a3112,a3141, a1241, nl) ! aa41 call sypvvv( v2, a41,e410,sl410, nl ) call trucommvv( aa41 , alf12,a4112,v2, v1, nl ) ! aalf41 call invdiag( cax1, a4112, nl ) call mulmmf90( cax2, alf12, cax1, nl ) ! alf12 * (1/a4112) call mulmmf90( cax3, cax2, alf41, nl ) call resmmf90( aalf41, cax3, a1241, nl ) ! aa4111 call trucodiag(aa4111, alf12,a4112,a4111, a1211, nl) ! aa4121 call trucodiag(aa4121, alf12,a4112,a4121, a1221, nl) ! aa4131 call trucodiag(aa4131, alf12,a4112,a4131, a1231, nl) endif ! Final caso input_cza.ge.1 !! Paso 2 : Calculo de vectores y matrices con 2 barras (aaa***) ! aaalf41 call invdiag( cax1, aa4121, nl ) call mulmmf90( cax2, aalf21, cax1, nl ) ! alf21 * (1/a4121) call mulmmf90( cax3, cax2, aalf41, nl ) call resmmf90( aaalf41, cax3, aa2141, nl ) ! aaa41 call trucommvv(aaa41, aalf21,aa4121,aa41, aa21, nl) ! aaa4111 call trucodiag(aaa4111, aalf21,aa4121,aa4111, aa2111, nl) ! aaa4131 call trucodiag(aaa4131, aalf21,aa4121,aa4131, aa2131, nl) ! aaalf31 call invdiag( cax1, aa3121, nl ) call mulmmf90( cax2, aalf21, cax1, nl ) ! alf21 * (1/a3121) call mulmmf90( cax3, cax2, aalf31, nl ) call resmmf90( aaalf31, cax3, aa2131, nl ) ! aaa31 call trucommvv(aaa31, aalf21,aa3121,aa31, aa21, nl) ! aaa3111 call trucodiag(aaa3111, aalf21,aa3121,aa3111, aa2111, nl) ! aaa3141 call trucodiag(aaa3141, aalf21,aa3121,aa3141, aa2141, nl) ! aaalf11 call invdiag( cax1, aa1121, nl ) call mulmmf90( cax2, aalf21, cax1, nl ) ! alf21 * (1/a1121) call mulmmf90( cax3, cax2, aalf11, nl ) call resmmf90( aaalf11, cax3, aa2111, nl ) ! aaa11 call trucommvv(aaa11, aalf21,aa1121,aa11, aa21, nl) ! aaa1131 call trucodiag(aaa1131, aalf21,aa1121,aa1131, aa2131, nl) ! aaa1141 call trucodiag(aaa1141, aalf21,aa1121,aa1141, aa2141, nl) !! Paso 3 : Calculo de vectores y matrices con 3 barras (aaaa***) ! aaaalf41 call invdiag( cax1, aaa4131, nl ) call mulmmf90( cax2, aaalf31, cax1, nl ) ! aaalf31 * (1/aaa4131) call mulmmf90( cax3, cax2, aaalf41, nl ) call resmmf90( aaaalf41, cax3, aaa3141, nl ) ! aaaa41 call trucommvv(aaaa41, aaalf31,aaa4131,aaa41, aaa31, nl) ! aaaa4111 call trucodiag(aaaa4111, aaalf31,aaa4131,aaa4111,aaa3111, nl) ! aaaalf11 call invdiag( cax1, aaa1131, nl ) call mulmmf90( cax2, aaalf31, cax1, nl ) ! aaalf31 * (1/aaa4131) call mulmmf90( cax3, cax2, aaalf11, nl ) call resmmf90( aaaalf11, cax3, aaa3111, nl ) ! aaaa11 call trucommvv(aaaa11, aaalf31,aaa1131,aaa11, aaa31, nl) ! aaaa1141 call trucodiag(aaaa1141, aaalf31,aaa1131,aaa1141,aaa3141, nl) !! Paso 4 : Calculo de vectores y matrices finales y calculo de J1 call trucommvv(v1, aaaalf41,aaaa1141,aaaa11, aaaa41, nl) ! call invdiag( cax1, aaaa1141, nl ) call mulmmf90( cax2, aaaalf41, cax1, nl ) ! aaaalf41 * (1/aaaa1141) call mulmmf90( cax3, cax2, aaaalf11, nl ) call resmmf90( cax1, cax3, aaaa4111, nl ) ! call LUdec ( el11, cax1, v1, nl, nl2 ) ! Solucion para el41 call sypvmv( v1, aaaa41, aaaa4111,el11, nl ) call LUdec ( el41, aaaalf41, v1, nl, nl2 ) ! Solucion para el31 call sypvmv( v2, aaa31, aaa3111,el11, nl ) call sypvmv( v1, v2, aaa3141,el41, nl ) call LUdec ( el31, aaalf31, v1, nl, nl2 ) ! Solucion para el21 call sypvmv( v3, aa21, aa2111,el11, nl ) call sypvmv( v2, v3, aa2131,el31, nl ) call sypvmv( v1, v2, aa2141,el41, nl ) call LUdec ( el21, aalf21, v1, nl, nl2 ) !!! el11(1) = planckdp( t(1), nu11 ) el21(1) = planckdp( t(1), nu21 ) el31(1) = planckdp( t(1), nu31 ) el41(1) = planckdp( t(1), nu41 ) el11(nl) = 2.d0 * el11(nl-1) - el11(nl2) el21(nl) = 2.d0 * el21(nl-1) - el21(nl2) el31(nl) = 2.d0 * el31(nl-1) - el31(nl2) el41(nl) = 2.d0 * el41(nl-1) - el41(nl2) call mulmv ( v1, c110,el11, nl ) call sumvv ( hr110, v1,sl110, nl ) ! Solucion para el12 if (input_cza.ge.1) then call sypvmv( v1, a12, a1211,el11, nl ) call sypvmv( v3, v1, a1221,el21, nl ) call sypvmv( v2, v3, a1231,el31, nl ) call sypvmv( v1, v2, a1241,el41, nl ) call LUdec ( el12, alf12, v1, nl, nl2 ) el12(1) = planckdp( t(1), nu121 ) el12(nl) = 2.d0 * el12(nl-1) - el12(nl2) if (itt_cza.eq.15) then call mulmv ( v1, c121,el12, nl ) call sumvv ( hr121, v1,sl121, nl ) endif end if if (input_cza.lt.1) then do i=1,nl pl11 = el11(i)/( gamma * nu11**3.0d0 * 1.d0/2.d0 /n10(i) ) pl21 = el21(i)/( gamma * nu21**3.0d0 * 1.d0/2.d0 /n20(i) ) pl31 = el31(i)/( gamma * nu31**3.0d0 * 1.d0/2.d0 /n30(i) ) pl41 = el41(i)/( gamma * nu41**3.0d0 * 1.d0/2.d0 /n40(i) ) vt11(i) = -ee*nu11 / log( abs(pl11) / (2.0d0*n10(i)) ) vt21(i) = -ee*nu21 / log( abs(pl21) / (2.0d0*n20(i)) ) vt31(i) = -ee*nu31 / log( abs(pl31) / (2.0d0*n30(i)) ) vt41(i) = -ee*nu41 / log( abs(pl41) / (2.0d0*n40(i)) ) hr210(i) = sl210(i) -hplanck*vlight*nu21 *a21_einst(i)*pl21 hr310(i) = sl310(i) -hplanck*vlight*nu31 *a31_einst(i)*pl31 hr410(i) = sl410(i) -hplanck*vlight*nu41 *a41_einst(i)*pl41 enddo v626t1(1:nl)=vt11(1:nl) v628t1(1:nl)=vt21(1:nl) v636t1(1:nl)=vt31(1:nl) v627t1(1:nl)=vt41(1:nl) ! call dinterconnection( v626t1, vt11 ) ! call dinterconnection ( v628t1, vt21 ) ! call dinterconnection ( v636t1, vt31 ) ! call dinterconnection ( v627t1, vt41 ) else do i=1,nl pl21 = el21(i)/( gamma * nu21**3.0d0 * 1.d0/2.d0 / n20(i) ) pl31 = el31(i)/( gamma * nu31**3.0d0 * 1.d0/2.d0 / n30(i) ) pl41 = el41(i)/( gamma * nu41**3.0d0 * 1.d0/2.d0 / n40(i) ) hr210(i) = sl210(i) -hplanck*vlight*nu21 *a21_einst(i)*pl21 hr310(i) = sl310(i) -hplanck*vlight*nu31 *a31_einst(i)*pl31 hr410(i) = sl410(i) -hplanck*vlight*nu41 *a41_einst(i)*pl41 if (itt_cza.eq.13) then pl12 = el12(i)/( gamma*nu121**3.0d0 * 2.d0/4.d0 /n11(i) ) hr121(i) = - hplanck*vlight * nu121 * a12_einst(i)*pl12 hr121(i) = hr121(i) + sl121(i) endif enddo endif ! K/Dday do i=1,nl hr110(i)=hr110(i)*dble( hrkday_factor(i) / nt(i) ) hr210(i)=hr210(i)*dble( hrkday_factor(i) / nt(i) ) hr310(i)=hr310(i)*dble( hrkday_factor(i) / nt(i) ) hr410(i)=hr410(i)*dble( hrkday_factor(i) / nt(i) ) hr121(i)=hr121(i)*dble( hrkday_factor(i) / nt(i) ) end do c final return c end c *** Old NLTEdlvr11_FB626CTS_02 *** c*********************************************************************** subroutine NLTEdlvr11_FB626CTS ( hr110CTS, nl_cts_real ) c*********************************************************************** implicit none !!!!!!!!!!!!!!!!!! common variables and constants include 'nlte_paramdef.h' include 'nlte_commons.h' c Arguments real*8 hr110CTS(nl_cts) ! output integer nl_cts_real ! i c local variables real*8 n11CTS(nl_cts), slopeTstar110(nl_cts) real*8 n10(nl_cts), co2t, codbl, n2dbl, o3pdbl real*8 d19c1, d19cp1, l11, p11 real*8 a11_einst(nl_cts), hcv, maxslope integer i, isot !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! start program nu11 = dble(nu(1,1)) hcv = hplanck*vlight*nu11 call zero2v (hr110CTS,n11CTS,nl_cts) do i=1,nl_cts_real co2t = dble ( co2_cts(i) *(imr(1)+imr(3)+imr(2)+imr(4)) ) n10(i) = dble( co2_cts(i) * imr(1) ) codbl = dble(co_cts(i)) o3pdbl = dble(o3p_cts(i)) n2dbl = dble(n2_cts(i)) call GETK_dlvr11 ( t_cts(i) ) isot = 1 d19c1 = k19ca(isot)*co2t + k19cb(isot)*n2dbl $ + k19cc(isot)*codbl d19cp1 = k19cap(isot)*co2t + k19cbp(isot)*n2dbl $ + k19ccp(isot)*codbl l11 = d19c1 + k20c(1)*o3pdbl p11 = ( d19cp1 + k20cp(1)*o3pdbl ) * n10(i) a11_einst(i) = a1_010_000 * 1.8d0/4.d0 * taustar11_cts(i) n11CTS(i) = p11 / (l11 + a11_einst(i)) hr110CTS(i) = - n11CTS(i) * a11_einst(i) * hcv hr110CTS(i) = hr110CTS(i)* $ dble( hrkday_factor_cts(i) / nt_cts(i) ) !K/Day enddo c calculo de la altura de transicion, a partir de Tstar c y merging con el hr110(i), ya calculado con CZALU slopeTstar110(1) = taustar11_cts(2)-taustar11_cts(1) slopeTstar110(nl_cts_real) = taustar11_cts(nl_cts_real) - $ taustar11_cts(nl_cts_real-1) maxslope = max( slopeTstar110(1),slopeTstar110(nl_cts_real)) if (nl_cts_real .gt. 2) then do i=2,nl_cts_real-1 slopeTstar110(i) = ( taustar11_cts(i+1) - $ taustar11_cts(i-1) ) * 0.5d0 if ( slopeTstar110(i) .gt. maxslope ) then !write (*,*) i, pl_cts(i), maxslope, slopeTstar110(i) maxslope=slopeTstar110(i) endif enddo endif c return end c*********************************************************************** c hrkday_convert.f c c fortran function that returns the factor for conversion from c hr' [erg s-1 cm-3] to hr [ k day-1 ] c c mar 2010 fgg adapted to GCM c jan 99 malv add o2 as major component. c ago 98 malv also returns cp_avg,pm_avg c jul 98 malv first version. c*********************************************************************** function hrkday_convert @ ( mmean_nlte,cpmean_nlte ) implicit none include 'comcstfi.h' include 'param.h' c argumentos real mmean_nlte,cpmean_nlte real hrkday_convert ccccccccccccccccccccccccccccccccccccc hrkday_convert = daysec * n_avog / & ( cpmean_nlte * 1.e4 * mmean_nlte ) c end return end