1 |
SUBROUTINE sw2s(knu, paer, flag_aer, tauae, pizae, cgae, paki, palbd, palbp, & |
module sw2s_m |
2 |
pcg, pcld, pclear, pcldsw, pdsig, pomega, poz, prmu, psec, ptau, pud, & |
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pwv, pqs, pfdown, pfup) |
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USE dimens_m |
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USE dimphy |
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USE raddim |
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USE radepsi |
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3 |
IMPLICIT NONE |
IMPLICIT NONE |
4 |
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5 |
! ------------------------------------------------------------------ |
contains |
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! PURPOSE. |
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! -------- |
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! THIS ROUTINE COMPUTES THE SHORTWAVE RADIATION FLUXES IN THE |
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! SECOND SPECTRAL INTERVAL FOLLOWING FOUQUART AND BONNEL (1980). |
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! METHOD. |
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! ------- |
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! 1. COMPUTES REFLECTIVITY/TRANSMISSIVITY CORRESPONDING TO |
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! CONTINUUM SCATTERING |
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! 2. COMPUTES REFLECTIVITY/TRANSMISSIVITY CORRESPONDING FOR |
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! A GREY MOLECULAR ABSORPTION |
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! 3. LAPLACE TRANSFORM ON THE PREVIOUS TO GET EFFECTIVE AMOUNTS |
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! OF ABSORBERS |
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! 4. APPLY H2O AND U.M.G. TRANSMISSION FUNCTIONS |
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! 5. MULTIPLY BY OZONE TRANSMISSION FUNCTION |
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! REFERENCE. |
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! ---------- |
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! SEE RADIATION'S PART OF THE ECMWF RESEARCH DEPARTMENT |
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! DOCUMENTATION, AND FOUQUART AND BONNEL (1980) |
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! AUTHOR. |
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! ------- |
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! JEAN-JACQUES MORCRETTE *ECMWF* |
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! MODIFICATIONS. |
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! -------------- |
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! ORIGINAL : 89-07-14 |
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! 94-11-15 J.-J. MORCRETTE DIRECT/DIFFUSE ALBEDO |
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! ------------------------------------------------------------------ |
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! * ARGUMENTS: |
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INTEGER knu |
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! -OB |
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DOUBLE PRECISION flag_aer |
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DOUBLE PRECISION tauae(kdlon, kflev, 2) |
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DOUBLE PRECISION pizae(kdlon, kflev, 2) |
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DOUBLE PRECISION cgae(kdlon, kflev, 2) |
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DOUBLE PRECISION paer(kdlon, kflev, 5) |
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DOUBLE PRECISION paki(kdlon, 2) |
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DOUBLE PRECISION palbd(kdlon, 2) |
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DOUBLE PRECISION palbp(kdlon, 2) |
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DOUBLE PRECISION pcg(kdlon, 2, kflev) |
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DOUBLE PRECISION pcld(kdlon, kflev) |
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DOUBLE PRECISION pcldsw(kdlon, kflev) |
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DOUBLE PRECISION pclear(kdlon) |
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DOUBLE PRECISION pdsig(kdlon, kflev) |
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DOUBLE PRECISION pomega(kdlon, 2, kflev) |
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DOUBLE PRECISION poz(kdlon, kflev) |
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DOUBLE PRECISION pqs(kdlon, kflev) |
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DOUBLE PRECISION prmu(kdlon) |
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DOUBLE PRECISION psec(kdlon) |
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DOUBLE PRECISION ptau(kdlon, 2, kflev) |
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DOUBLE PRECISION pud(kdlon, 5, kflev+1) |
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DOUBLE PRECISION pwv(kdlon, kflev) |
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DOUBLE PRECISION pfdown(kdlon, kflev+1) |
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DOUBLE PRECISION pfup(kdlon, kflev+1) |
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! * LOCAL VARIABLES: |
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INTEGER iind2(2), iind3(3) |
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DOUBLE PRECISION zcgaz(kdlon, kflev) |
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DOUBLE PRECISION zfd(kdlon, kflev+1) |
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DOUBLE PRECISION zfu(kdlon, kflev+1) |
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DOUBLE PRECISION zg(kdlon) |
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DOUBLE PRECISION zgg(kdlon) |
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DOUBLE PRECISION zpizaz(kdlon, kflev) |
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DOUBLE PRECISION zrayl(kdlon) |
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DOUBLE PRECISION zray1(kdlon, kflev+1) |
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DOUBLE PRECISION zray2(kdlon, kflev+1) |
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DOUBLE PRECISION zref(kdlon) |
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DOUBLE PRECISION zrefz(kdlon, 2, kflev+1) |
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DOUBLE PRECISION zre1(kdlon) |
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DOUBLE PRECISION zre2(kdlon) |
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DOUBLE PRECISION zrj(kdlon, 6, kflev+1) |
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DOUBLE PRECISION zrj0(kdlon, 6, kflev+1) |
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DOUBLE PRECISION zrk(kdlon, 6, kflev+1) |
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DOUBLE PRECISION zrk0(kdlon, 6, kflev+1) |
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DOUBLE PRECISION zrl(kdlon, 8) |
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DOUBLE PRECISION zrmue(kdlon, kflev+1) |
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DOUBLE PRECISION zrmu0(kdlon, kflev+1) |
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DOUBLE PRECISION zrmuz(kdlon) |
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DOUBLE PRECISION zrneb(kdlon) |
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DOUBLE PRECISION zruef(kdlon, 8) |
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DOUBLE PRECISION zr1(kdlon) |
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DOUBLE PRECISION zr2(kdlon, 2) |
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DOUBLE PRECISION zr3(kdlon, 3) |
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DOUBLE PRECISION zr4(kdlon) |
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DOUBLE PRECISION zr21(kdlon) |
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DOUBLE PRECISION zr22(kdlon) |
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DOUBLE PRECISION zs(kdlon) |
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DOUBLE PRECISION ztauaz(kdlon, kflev) |
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DOUBLE PRECISION zto1(kdlon) |
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DOUBLE PRECISION ztr(kdlon, 2, kflev+1) |
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DOUBLE PRECISION ztra1(kdlon, kflev+1) |
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DOUBLE PRECISION ztra2(kdlon, kflev+1) |
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DOUBLE PRECISION ztr1(kdlon) |
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DOUBLE PRECISION ztr2(kdlon) |
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DOUBLE PRECISION zw(kdlon) |
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DOUBLE PRECISION zw1(kdlon) |
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DOUBLE PRECISION zw2(kdlon, 2) |
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DOUBLE PRECISION zw3(kdlon, 3) |
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DOUBLE PRECISION zw4(kdlon) |
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DOUBLE PRECISION zw5(kdlon) |
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INTEGER jl, jk, k, jaj, ikm1, ikl, jn, jabs, jkm1 |
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INTEGER jref, jkl, jklp1, jajp, jkki, jkkp4, jn2j, iabs |
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DOUBLE PRECISION zrmum1, zwh2o, zcneb, zaa, zbb, zrki, zre11 |
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! * Prescribed Data: |
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DOUBLE PRECISION rsun(2) |
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SAVE rsun |
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DOUBLE PRECISION rray(2, 6) |
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SAVE rray |
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DATA rsun(1)/0.441676/ |
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DATA rsun(2)/0.558324/ |
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DATA (rray(1,k), k=1, 6)/.428937E-01, .890743E+00, -.288555E+01, & |
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.522744E+01, -.469173E+01, .161645E+01/ |
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DATA (rray(2,k), k=1, 6)/.697200E-02, .173297E-01, -.850903E-01, & |
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.248261E+00, -.302031E+00, .129662E+00/ |
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! ------------------------------------------------------------------ |
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! * 1. SECOND SPECTRAL INTERVAL (0.68-4.00 MICRON) |
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! ------------------------------------------- |
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! * 1.1 OPTICAL THICKNESS FOR RAYLEIGH SCATTERING |
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! ----------------------------------------- |
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DO jl = 1, kdlon |
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zrmum1 = 1. - prmu(jl) |
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zrayl(jl) = rray(knu, 1) + zrmum1*(rray(knu,2)+zrmum1*(rray(knu, & |
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3)+zrmum1*(rray(knu,4)+zrmum1*(rray(knu,5)+zrmum1*rray(knu,6))))) |
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END DO |
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! ------------------------------------------------------------------ |
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! * 2. CONTINUUM SCATTERING CALCULATIONS |
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! --------------------------------- |
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! * 2.1 CLEAR-SKY FRACTION OF THE COLUMN |
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! -------------------------------- |
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CALL swclr(knu, paer, flag_aer, tauae, pizae, cgae, palbp, pdsig, zrayl, & |
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psec, zcgaz, zpizaz, zray1, zray2, zrefz, zrj0, zrk0, zrmu0, ztauaz, & |
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ztra1, ztra2) |
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! * 2.2 CLOUDY FRACTION OF THE COLUMN |
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! ----------------------------- |
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CALL swr(knu, palbd, pcg, pcld, pdsig, pomega, zrayl, psec, ptau, zcgaz, & |
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zpizaz, zray1, zray2, zrefz, zrj, zrk, zrmue, ztauaz, ztra1, ztra2) |
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! ------------------------------------------------------------------ |
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! * 3. SCATTERING CALCULATIONS WITH GREY MOLECULAR ABSORPTION |
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! ------------------------------------------------------ |
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6 |
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7 |
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SUBROUTINE sw2s(knu, paki, palbd, palbp, pcg, pcld, pclear, pdsig, pomega, & |
8 |
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poz, prmu, psec, ptau, pud, pwv, pqs, pfdown, pfup) |
9 |
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10 |
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USE dimensions |
11 |
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USE dimphy |
12 |
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USE raddim |
13 |
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USE radepsi |
14 |
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use swclr_m, only: swclr |
15 |
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use swde_m, only: swde |
16 |
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use swr_m, only: swr |
17 |
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18 |
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! ------------------------------------------------------------------ |
19 |
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! PURPOSE. |
20 |
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! -------- |
21 |
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22 |
|
! THIS ROUTINE COMPUTES THE SHORTWAVE RADIATION FLUXES IN THE |
23 |
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! SECOND SPECTRAL INTERVAL FOLLOWING FOUQUART AND BONNEL (1980). |
24 |
|
|
25 |
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! METHOD. |
26 |
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! ------- |
27 |
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28 |
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! 1. COMPUTES REFLECTIVITY/TRANSMISSIVITY CORRESPONDING TO |
29 |
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! CONTINUUM SCATTERING |
30 |
|
! 2. COMPUTES REFLECTIVITY/TRANSMISSIVITY CORRESPONDING FOR |
31 |
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! A GREY MOLECULAR ABSORPTION |
32 |
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! 3. LAPLACE TRANSFORM ON THE PREVIOUS TO GET EFFECTIVE AMOUNTS |
33 |
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! OF ABSORBERS |
34 |
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! 4. APPLY H2O AND U.M.G. TRANSMISSION FUNCTIONS |
35 |
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! 5. MULTIPLY BY OZONE TRANSMISSION FUNCTION |
36 |
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|
37 |
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! REFERENCE. |
38 |
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! ---------- |
39 |
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40 |
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! SEE RADIATION'S PART OF THE ECMWF RESEARCH DEPARTMENT |
41 |
|
! DOCUMENTATION, AND FOUQUART AND BONNEL (1980) |
42 |
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|
43 |
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! AUTHOR. |
44 |
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! ------- |
45 |
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! JEAN-JACQUES MORCRETTE *ECMWF* |
46 |
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|
47 |
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! MODIFICATIONS. |
48 |
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! -------------- |
49 |
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! ORIGINAL : 89-07-14 |
50 |
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! 94-11-15 J.-J. MORCRETTE DIRECT/DIFFUSE ALBEDO |
51 |
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! ------------------------------------------------------------------ |
52 |
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! * ARGUMENTS: |
53 |
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54 |
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INTEGER knu |
55 |
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DOUBLE PRECISION paki(kdlon, 2) |
56 |
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DOUBLE PRECISION palbd(kdlon, 2) |
57 |
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DOUBLE PRECISION palbp(kdlon, 2) |
58 |
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DOUBLE PRECISION pcg(kdlon, 2, kflev) |
59 |
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DOUBLE PRECISION pcld(kdlon, kflev) |
60 |
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DOUBLE PRECISION pclear(kdlon) |
61 |
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DOUBLE PRECISION pdsig(kdlon, kflev) |
62 |
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DOUBLE PRECISION pomega(kdlon, 2, kflev) |
63 |
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DOUBLE PRECISION poz(kdlon, kflev) |
64 |
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DOUBLE PRECISION pqs(kdlon, kflev) |
65 |
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DOUBLE PRECISION prmu(kdlon) |
66 |
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DOUBLE PRECISION psec(kdlon) |
67 |
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DOUBLE PRECISION ptau(kdlon, 2, kflev) |
68 |
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DOUBLE PRECISION pud(kdlon, 5, kflev+1) |
69 |
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DOUBLE PRECISION pwv(kdlon, kflev) |
70 |
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71 |
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DOUBLE PRECISION pfdown(kdlon, kflev+1) |
72 |
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DOUBLE PRECISION pfup(kdlon, kflev+1) |
73 |
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74 |
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! * LOCAL VARIABLES: |
75 |
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76 |
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INTEGER iind2(2), iind3(3) |
77 |
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DOUBLE PRECISION zcgaz(kdlon, kflev) |
78 |
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DOUBLE PRECISION zfd(kdlon, kflev+1) |
79 |
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DOUBLE PRECISION zfu(kdlon, kflev+1) |
80 |
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DOUBLE PRECISION zg(kdlon) |
81 |
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DOUBLE PRECISION zgg(kdlon) |
82 |
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DOUBLE PRECISION zpizaz(kdlon, kflev) |
83 |
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DOUBLE PRECISION zrayl(kdlon) |
84 |
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DOUBLE PRECISION zray1(kdlon, kflev+1) |
85 |
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DOUBLE PRECISION zray2(kdlon, kflev+1) |
86 |
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DOUBLE PRECISION zref(kdlon) |
87 |
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DOUBLE PRECISION zrefz(kdlon, 2, kflev+1) |
88 |
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DOUBLE PRECISION zre1(kdlon) |
89 |
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DOUBLE PRECISION zre2(kdlon) |
90 |
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DOUBLE PRECISION zrj(kdlon, 6, kflev+1) |
91 |
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DOUBLE PRECISION zrj0(kdlon, 6, kflev+1) |
92 |
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DOUBLE PRECISION zrk(kdlon, 6, kflev+1) |
93 |
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DOUBLE PRECISION zrk0(kdlon, 6, kflev+1) |
94 |
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DOUBLE PRECISION zrl(kdlon, 8) |
95 |
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DOUBLE PRECISION zrmue(kdlon, kflev+1) |
96 |
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DOUBLE PRECISION zrmu0(kdlon, kflev+1) |
97 |
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DOUBLE PRECISION zrmuz(kdlon) |
98 |
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DOUBLE PRECISION zrneb(kdlon) |
99 |
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DOUBLE PRECISION zr1(kdlon) |
100 |
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DOUBLE PRECISION zr2(kdlon, 2) |
101 |
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DOUBLE PRECISION zr3(kdlon, 3) |
102 |
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DOUBLE PRECISION zr4(kdlon) |
103 |
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DOUBLE PRECISION zr21(kdlon) |
104 |
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DOUBLE PRECISION zr22(kdlon) |
105 |
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DOUBLE PRECISION zs(kdlon) |
106 |
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DOUBLE PRECISION ztauaz(kdlon, kflev) |
107 |
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DOUBLE PRECISION zto1(kdlon) |
108 |
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DOUBLE PRECISION ztr(kdlon, 2, kflev+1) |
109 |
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DOUBLE PRECISION ztra1(kdlon, kflev+1) |
110 |
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DOUBLE PRECISION ztra2(kdlon, kflev+1) |
111 |
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DOUBLE PRECISION ztr1(kdlon) |
112 |
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DOUBLE PRECISION ztr2(kdlon) |
113 |
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DOUBLE PRECISION zw(kdlon) |
114 |
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DOUBLE PRECISION zw1(kdlon) |
115 |
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DOUBLE PRECISION zw2(kdlon, 2) |
116 |
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DOUBLE PRECISION zw3(kdlon, 3) |
117 |
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DOUBLE PRECISION zw4(kdlon) |
118 |
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DOUBLE PRECISION zw5(kdlon) |
119 |
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120 |
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INTEGER jl, jk, k, jaj, ikm1, ikl, jn, jabs, jkm1 |
121 |
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INTEGER jref, jkl, jklp1, jajp, jkki, jkkp4, jn2j, iabs |
122 |
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DOUBLE PRECISION zrmum1, zwh2o, zcneb, zaa, zbb, zrki, zre11 |
123 |
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124 |
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! * Prescribed Data: |
125 |
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126 |
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DOUBLE PRECISION rsun(2) |
127 |
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SAVE rsun |
128 |
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DOUBLE PRECISION rray(2, 6) |
129 |
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SAVE rray |
130 |
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DATA rsun(1)/0.441676d0/ |
131 |
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DATA rsun(2)/0.558324d0/ |
132 |
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DATA (rray(1,k), k=1, 6)/.428937d-01, .890743d+00, -.288555d+01, & |
133 |
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.522744d+01, -.469173d+01, .161645d+01/ |
134 |
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DATA (rray(2,k), k=1, 6)/.697200d-02, .173297d-01, -.850903d-01, & |
135 |
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.248261d+00, -.302031d+00, .129662d+00/ |
136 |
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137 |
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! ------------------------------------------------------------------ |
138 |
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139 |
jn = 2 |
! * 1. SECOND SPECTRAL INTERVAL (0.68-4.00 MICRON) |
140 |
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! ------------------------------------------- |
141 |
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DO jabs = 1, 2 |
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142 |
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143 |
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144 |
! * 3.1 SURFACE CONDITIONS |
! * 1.1 OPTICAL THICKNESS FOR RAYLEIGH SCATTERING |
145 |
! ------------------ |
! ----------------------------------------- |
146 |
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147 |
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148 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
149 |
zrefz(jl, 2, 1) = palbd(jl, knu) |
zrmum1 = 1. - prmu(jl) |
150 |
zrefz(jl, 1, 1) = palbd(jl, knu) |
zrayl(jl) = rray(knu, 1) + zrmum1*(rray(knu,2)+zrmum1*(rray(knu, & |
151 |
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3)+zrmum1*(rray(knu,4)+zrmum1*(rray(knu,5)+zrmum1*rray(knu,6))))) |
152 |
END DO |
END DO |
153 |
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154 |
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155 |
! * 3.2 INTRODUCING CLOUD EFFECTS |
! ------------------------------------------------------------------ |
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! ------------------------- |
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156 |
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157 |
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! * 2. CONTINUUM SCATTERING CALCULATIONS |
158 |
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! --------------------------------- |
159 |
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DO jk = 2, kflev + 1 |
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jkm1 = jk - 1 |
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ikl = kflev + 1 - jkm1 |
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DO jl = 1, kdlon |
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zrneb(jl) = pcld(jl, jkm1) |
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IF (jabs==1 .AND. zrneb(jl)>2.*zeelog) THEN |
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zwh2o = max(pwv(jl,jkm1), zeelog) |
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zcneb = max(zeelog, min(zrneb(jl),1.-zeelog)) |
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zbb = pud(jl, jabs, jkm1)*pqs(jl, jkm1)/zwh2o |
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zaa = max((pud(jl,jabs,jkm1)-zcneb*zbb)/(1.-zcneb), zeelog) |
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ELSE |
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zaa = pud(jl, jabs, jkm1) |
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zbb = zaa |
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END IF |
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zrki = paki(jl, jabs) |
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zs(jl) = exp(-zrki*zaa*1.66) |
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zg(jl) = exp(-zrki*zaa/zrmue(jl,jk)) |
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ztr1(jl) = 0. |
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zre1(jl) = 0. |
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ztr2(jl) = 0. |
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zre2(jl) = 0. |
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160 |
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161 |
zw(jl) = pomega(jl, knu, jkm1) |
! * 2.1 CLEAR-SKY FRACTION OF THE COLUMN |
162 |
zto1(jl) = ptau(jl, knu, jkm1)/zw(jl) + ztauaz(jl, jkm1)/zpizaz(jl, & |
! -------------------------------- |
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jkm1) + zbb*zrki |
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163 |
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zr21(jl) = ptau(jl, knu, jkm1) + ztauaz(jl, jkm1) |
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zr22(jl) = ptau(jl, knu, jkm1)/zr21(jl) |
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zgg(jl) = zr22(jl)*pcg(jl, knu, jkm1) + (1.-zr22(jl))*zcgaz(jl, jkm1) |
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zw(jl) = zr21(jl)/zto1(jl) |
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zref(jl) = zrefz(jl, 1, jkm1) |
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zrmuz(jl) = zrmue(jl, jk) |
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END DO |
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164 |
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165 |
CALL swde(zgg, zref, zrmuz, zto1, zw, zre1, zre2, ztr1, ztr2) |
CALL swclr(knu, palbp, pdsig, zrayl, psec, zpizaz, zray1, zray2, zrefz, & |
166 |
|
zrj0, zrk0, zrmu0, ztauaz, ztra1, ztra2) |
167 |
|
|
|
DO jl = 1, kdlon |
|
168 |
|
|
169 |
zrefz(jl, 2, jk) = (1.-zrneb(jl))*(zray1(jl,jkm1)+zrefz(jl,2,jkm1)* & |
! * 2.2 CLOUDY FRACTION OF THE COLUMN |
170 |
ztra1(jl,jkm1)*ztra2(jl,jkm1))*zg(jl)*zs(jl) + zrneb(jl)*zre1(jl) |
! ----------------------------- |
171 |
|
|
|
ztr(jl, 2, jkm1) = zrneb(jl)*ztr1(jl) + (ztra1(jl,jkm1))*zg(jl)*(1.- & |
|
|
zrneb(jl)) |
|
172 |
|
|
173 |
zrefz(jl, 1, jk) = (1.-zrneb(jl))*(zray1(jl,jkm1)+zrefz(jl,1,jkm1)* & |
zcgaz = 0d0 |
174 |
ztra1(jl,jkm1)*ztra2(jl,jkm1)/(1.-zray2(jl,jkm1)*zrefz(jl,1, & |
CALL swr(knu, palbd, pcg, pcld, pomega, psec, ptau, zcgaz, & |
175 |
jkm1)))*zg(jl)*zs(jl) + zrneb(jl)*zre2(jl) |
zpizaz, zray1, zray2, zrefz, zrj, zrk, zrmue, ztauaz, ztra1, ztra2) |
176 |
|
|
|
ztr(jl, 1, jkm1) = zrneb(jl)*ztr2(jl) + (ztra1(jl,jkm1)/(1.-zray2(jl, & |
|
|
jkm1)*zrefz(jl,1,jkm1)))*zg(jl)*(1.-zrneb(jl)) |
|
177 |
|
|
178 |
END DO |
! ------------------------------------------------------------------ |
|
END DO |
|
179 |
|
|
180 |
! * 3.3 REFLECT./TRANSMISSIVITY BETWEEN SURFACE AND LEVEL |
! * 3. SCATTERING CALCULATIONS WITH GREY MOLECULAR ABSORPTION |
181 |
! ------------------------------------------------- |
! ------------------------------------------------------ |
182 |
|
|
183 |
|
|
184 |
DO jref = 1, 2 |
jn = 2 |
185 |
|
|
186 |
jn = jn + 1 |
DO jabs = 1, 2 |
187 |
|
|
|
DO jl = 1, kdlon |
|
|
zrj(jl, jn, kflev+1) = 1. |
|
|
zrk(jl, jn, kflev+1) = zrefz(jl, jref, kflev+1) |
|
|
END DO |
|
188 |
|
|
189 |
DO jk = 1, kflev |
! * 3.1 SURFACE CONDITIONS |
190 |
jkl = kflev + 1 - jk |
! ------------------ |
|
jklp1 = jkl + 1 |
|
|
DO jl = 1, kdlon |
|
|
zre11 = zrj(jl, jn, jklp1)*ztr(jl, jref, jkl) |
|
|
zrj(jl, jn, jkl) = zre11 |
|
|
zrk(jl, jn, jkl) = zre11*zrefz(jl, jref, jkl) |
|
|
END DO |
|
|
END DO |
|
|
END DO |
|
|
END DO |
|
191 |
|
|
192 |
|
|
193 |
! ------------------------------------------------------------------ |
DO jl = 1, kdlon |
194 |
|
zrefz(jl, 2, 1) = palbd(jl, knu) |
195 |
|
zrefz(jl, 1, 1) = palbd(jl, knu) |
196 |
|
END DO |
197 |
|
|
|
! * 4. INVERT GREY AND CONTINUUM FLUXES |
|
|
! -------------------------------- |
|
198 |
|
|
199 |
|
! * 3.2 INTRODUCING CLOUD EFFECTS |
200 |
|
! ------------------------- |
201 |
|
|
202 |
|
|
203 |
! * 4.1 UPWARD (ZRK) AND DOWNWARD (ZRJ) PSEUDO-FLUXES |
DO jk = 2, kflev + 1 |
204 |
! --------------------------------------------- |
jkm1 = jk - 1 |
205 |
|
ikl = kflev + 1 - jkm1 |
206 |
|
DO jl = 1, kdlon |
207 |
|
zrneb(jl) = pcld(jl, jkm1) |
208 |
|
IF (jabs==1 .AND. zrneb(jl)>2.*zeelog) THEN |
209 |
|
zwh2o = max(pwv(jl,jkm1), zeelog) |
210 |
|
zcneb = max(zeelog, min(zrneb(jl),1.-zeelog)) |
211 |
|
zbb = pud(jl, jabs, jkm1)*pqs(jl, jkm1)/zwh2o |
212 |
|
zaa = max((pud(jl,jabs,jkm1)-zcneb*zbb)/(1.-zcneb), zeelog) |
213 |
|
ELSE |
214 |
|
zaa = pud(jl, jabs, jkm1) |
215 |
|
zbb = zaa |
216 |
|
END IF |
217 |
|
zrki = paki(jl, jabs) |
218 |
|
zs(jl) = exp(-zrki*zaa*1.66) |
219 |
|
zg(jl) = exp(-zrki*zaa/zrmue(jl,jk)) |
220 |
|
ztr1(jl) = 0. |
221 |
|
zre1(jl) = 0. |
222 |
|
ztr2(jl) = 0. |
223 |
|
zre2(jl) = 0. |
224 |
|
|
225 |
|
zw(jl) = pomega(jl, knu, jkm1) |
226 |
|
zto1(jl) = ptau(jl, knu, jkm1)/zw(jl) + ztauaz(jl, jkm1)/zpizaz(jl, & |
227 |
|
jkm1) + zbb*zrki |
228 |
|
|
229 |
DO jk = 1, kflev + 1 |
zr21(jl) = ptau(jl, knu, jkm1) + ztauaz(jl, jkm1) |
230 |
DO jaj = 1, 5, 2 |
zr22(jl) = ptau(jl, knu, jkm1)/zr21(jl) |
231 |
jajp = jaj + 1 |
zgg(jl) = zr22(jl)*pcg(jl, knu, jkm1) + (1.-zr22(jl))*zcgaz(jl, jkm1) |
232 |
DO jl = 1, kdlon |
zw(jl) = zr21(jl)/zto1(jl) |
233 |
zrj(jl, jaj, jk) = zrj(jl, jaj, jk) - zrj(jl, jajp, jk) |
zref(jl) = zrefz(jl, 1, jkm1) |
234 |
zrk(jl, jaj, jk) = zrk(jl, jaj, jk) - zrk(jl, jajp, jk) |
zrmuz(jl) = zrmue(jl, jk) |
235 |
zrj(jl, jaj, jk) = max(zrj(jl,jaj,jk), zeelog) |
END DO |
|
zrk(jl, jaj, jk) = max(zrk(jl,jaj,jk), zeelog) |
|
|
END DO |
|
|
END DO |
|
|
END DO |
|
236 |
|
|
237 |
DO jk = 1, kflev + 1 |
CALL swde(zgg, zref, zrmuz, zto1, zw, zre1, zre2, ztr1, ztr2) |
238 |
DO jaj = 2, 6, 2 |
|
239 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
|
zrj(jl, jaj, jk) = max(zrj(jl,jaj,jk), zeelog) |
|
|
zrk(jl, jaj, jk) = max(zrk(jl,jaj,jk), zeelog) |
|
|
END DO |
|
|
END DO |
|
|
END DO |
|
240 |
|
|
241 |
! * 4.2 EFFECTIVE ABSORBER AMOUNTS BY INVERSE LAPLACE |
zrefz(jl, 2, jk) = (1.-zrneb(jl))*(zray1(jl,jkm1)+zrefz(jl,2,jkm1)* & |
242 |
! --------------------------------------------- |
ztra1(jl,jkm1)*ztra2(jl,jkm1))*zg(jl)*zs(jl) + zrneb(jl)*zre1(jl) |
243 |
|
|
244 |
|
ztr(jl, 2, jkm1) = zrneb(jl)*ztr1(jl) + (ztra1(jl,jkm1))*zg(jl)*(1.- & |
245 |
|
zrneb(jl)) |
246 |
|
|
247 |
DO jk = 1, kflev + 1 |
zrefz(jl, 1, jk) = (1.-zrneb(jl))*(zray1(jl,jkm1)+zrefz(jl,1,jkm1)* & |
248 |
jkki = 1 |
ztra1(jl,jkm1)*ztra2(jl,jkm1)/(1.-zray2(jl,jkm1)*zrefz(jl,1, & |
249 |
DO jaj = 1, 2 |
jkm1)))*zg(jl)*zs(jl) + zrneb(jl)*zre2(jl) |
|
iind2(1) = jaj |
|
|
iind2(2) = jaj |
|
|
DO jn = 1, 2 |
|
|
jn2j = jn + 2*jaj |
|
|
jkkp4 = jkki + 4 |
|
250 |
|
|
251 |
! * 4.2.1 EFFECTIVE ABSORBER AMOUNTS |
ztr(jl, 1, jkm1) = zrneb(jl)*ztr2(jl) + (ztra1(jl,jkm1)/(1.-zray2(jl, & |
252 |
! -------------------------- |
jkm1)*zrefz(jl,1,jkm1)))*zg(jl)*(1.-zrneb(jl)) |
253 |
|
|
254 |
|
END DO |
255 |
|
END DO |
256 |
|
|
257 |
DO jl = 1, kdlon |
! * 3.3 REFLECT./TRANSMISSIVITY BETWEEN SURFACE AND LEVEL |
258 |
zw2(jl, 1) = log(zrj(jl,jn,jk)/zrj(jl,jn2j,jk))/paki(jl, jaj) |
! ------------------------------------------------- |
|
zw2(jl, 2) = log(zrk(jl,jn,jk)/zrk(jl,jn2j,jk))/paki(jl, jaj) |
|
|
END DO |
|
259 |
|
|
|
! * 4.2.2 TRANSMISSION FUNCTION |
|
|
! --------------------- |
|
260 |
|
|
261 |
|
DO jref = 1, 2 |
262 |
|
|
263 |
CALL swtt1(knu, 2, iind2, zw2, zr2) |
jn = jn + 1 |
264 |
|
|
265 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
266 |
zrl(jl, jkki) = zr2(jl, 1) |
zrj(jl, jn, kflev+1) = 1. |
267 |
zruef(jl, jkki) = zw2(jl, 1) |
zrk(jl, jn, kflev+1) = zrefz(jl, jref, kflev+1) |
268 |
zrl(jl, jkkp4) = zr2(jl, 2) |
END DO |
|
zruef(jl, jkkp4) = zw2(jl, 2) |
|
|
END DO |
|
269 |
|
|
270 |
jkki = jkki + 1 |
DO jk = 1, kflev |
271 |
END DO |
jkl = kflev + 1 - jk |
272 |
|
jklp1 = jkl + 1 |
273 |
|
DO jl = 1, kdlon |
274 |
|
zre11 = zrj(jl, jn, jklp1)*ztr(jl, jref, jkl) |
275 |
|
zrj(jl, jn, jkl) = zre11 |
276 |
|
zrk(jl, jn, jkl) = zre11*zrefz(jl, jref, jkl) |
277 |
|
END DO |
278 |
|
END DO |
279 |
|
END DO |
280 |
END DO |
END DO |
281 |
|
|
|
! * 4.3 UPWARD AND DOWNWARD FLUXES WITH H2O AND UMG ABSORPTION |
|
|
! ------------------------------------------------------ |
|
282 |
|
|
283 |
|
! ------------------------------------------------------------------ |
284 |
|
|
285 |
DO jl = 1, kdlon |
! * 4. INVERT GREY AND CONTINUUM FLUXES |
286 |
pfdown(jl, jk) = zrj(jl, 1, jk)*zrl(jl, 1)*zrl(jl, 3) + & |
! -------------------------------- |
287 |
zrj(jl, 2, jk)*zrl(jl, 2)*zrl(jl, 4) |
|
288 |
pfup(jl, jk) = zrk(jl, 1, jk)*zrl(jl, 5)*zrl(jl, 7) + & |
|
289 |
zrk(jl, 2, jk)*zrl(jl, 6)*zrl(jl, 8) |
|
290 |
|
! * 4.1 UPWARD (ZRK) AND DOWNWARD (ZRJ) PSEUDO-FLUXES |
291 |
|
! --------------------------------------------- |
292 |
|
|
293 |
|
|
294 |
|
DO jk = 1, kflev + 1 |
295 |
|
DO jaj = 1, 5, 2 |
296 |
|
jajp = jaj + 1 |
297 |
|
DO jl = 1, kdlon |
298 |
|
zrj(jl, jaj, jk) = zrj(jl, jaj, jk) - zrj(jl, jajp, jk) |
299 |
|
zrk(jl, jaj, jk) = zrk(jl, jaj, jk) - zrk(jl, jajp, jk) |
300 |
|
zrj(jl, jaj, jk) = max(zrj(jl,jaj,jk), zeelog) |
301 |
|
zrk(jl, jaj, jk) = max(zrk(jl,jaj,jk), zeelog) |
302 |
|
END DO |
303 |
|
END DO |
304 |
END DO |
END DO |
|
END DO |
|
305 |
|
|
306 |
|
DO jk = 1, kflev + 1 |
307 |
|
DO jaj = 2, 6, 2 |
308 |
|
DO jl = 1, kdlon |
309 |
|
zrj(jl, jaj, jk) = max(zrj(jl,jaj,jk), zeelog) |
310 |
|
zrk(jl, jaj, jk) = max(zrk(jl,jaj,jk), zeelog) |
311 |
|
END DO |
312 |
|
END DO |
313 |
|
END DO |
314 |
|
|
315 |
! ------------------------------------------------------------------ |
! * 4.2 EFFECTIVE ABSORBER AMOUNTS BY INVERSE LAPLACE |
316 |
|
! --------------------------------------------- |
317 |
|
|
|
! * 5. MOLECULAR ABSORPTION ON CLEAR-SKY FLUXES |
|
|
! ---------------------------------------- |
|
318 |
|
|
319 |
|
DO jk = 1, kflev + 1 |
320 |
|
jkki = 1 |
321 |
|
DO jaj = 1, 2 |
322 |
|
iind2(1) = jaj |
323 |
|
iind2(2) = jaj |
324 |
|
DO jn = 1, 2 |
325 |
|
jn2j = jn + 2*jaj |
326 |
|
jkkp4 = jkki + 4 |
327 |
|
|
328 |
|
! * 4.2.1 EFFECTIVE ABSORBER AMOUNTS |
329 |
|
! -------------------------- |
330 |
|
|
|
! * 5.1 DOWNWARD FLUXES |
|
|
! --------------- |
|
331 |
|
|
332 |
|
DO jl = 1, kdlon |
333 |
|
zw2(jl, 1) = log(zrj(jl,jn,jk)/zrj(jl,jn2j,jk))/paki(jl, jaj) |
334 |
|
zw2(jl, 2) = log(zrk(jl,jn,jk)/zrk(jl,jn2j,jk))/paki(jl, jaj) |
335 |
|
END DO |
336 |
|
|
337 |
jaj = 2 |
! * 4.2.2 TRANSMISSION FUNCTION |
338 |
iind3(1) = 1 |
! --------------------- |
|
iind3(2) = 2 |
|
|
iind3(3) = 3 |
|
339 |
|
|
|
DO jl = 1, kdlon |
|
|
zw3(jl, 1) = 0. |
|
|
zw3(jl, 2) = 0. |
|
|
zw3(jl, 3) = 0. |
|
|
zw4(jl) = 0. |
|
|
zw5(jl) = 0. |
|
|
zr4(jl) = 1. |
|
|
zfd(jl, kflev+1) = zrj0(jl, jaj, kflev+1) |
|
|
END DO |
|
|
DO jk = 1, kflev |
|
|
ikl = kflev + 1 - jk |
|
|
DO jl = 1, kdlon |
|
|
zw3(jl, 1) = zw3(jl, 1) + pud(jl, 1, ikl)/zrmu0(jl, ikl) |
|
|
zw3(jl, 2) = zw3(jl, 2) + pud(jl, 2, ikl)/zrmu0(jl, ikl) |
|
|
zw3(jl, 3) = zw3(jl, 3) + poz(jl, ikl)/zrmu0(jl, ikl) |
|
|
zw4(jl) = zw4(jl) + pud(jl, 4, ikl)/zrmu0(jl, ikl) |
|
|
zw5(jl) = zw5(jl) + pud(jl, 5, ikl)/zrmu0(jl, ikl) |
|
|
END DO |
|
340 |
|
|
341 |
CALL swtt1(knu, 3, iind3, zw3, zr3) |
CALL swtt1(knu, 2, iind2, zw2, zr2) |
342 |
|
|
343 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
344 |
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
zrl(jl, jkki) = zr2(jl, 1) |
345 |
zfd(jl, ikl) = zr3(jl, 1)*zr3(jl, 2)*zr3(jl, 3)*zr4(jl)* & |
zrl(jl, jkkp4) = zr2(jl, 2) |
346 |
zrj0(jl, jaj, ikl) |
END DO |
347 |
|
|
348 |
|
jkki = jkki + 1 |
349 |
|
END DO |
350 |
|
END DO |
351 |
|
|
352 |
|
! * 4.3 UPWARD AND DOWNWARD FLUXES WITH H2O AND UMG ABSORPTION |
353 |
|
! ------------------------------------------------------ |
354 |
|
|
355 |
|
|
356 |
|
DO jl = 1, kdlon |
357 |
|
pfdown(jl, jk) = zrj(jl, 1, jk)*zrl(jl, 1)*zrl(jl, 3) + & |
358 |
|
zrj(jl, 2, jk)*zrl(jl, 2)*zrl(jl, 4) |
359 |
|
pfup(jl, jk) = zrk(jl, 1, jk)*zrl(jl, 5)*zrl(jl, 7) + & |
360 |
|
zrk(jl, 2, jk)*zrl(jl, 6)*zrl(jl, 8) |
361 |
|
END DO |
362 |
END DO |
END DO |
|
END DO |
|
363 |
|
|
364 |
|
|
365 |
! * 5.2 UPWARD FLUXES |
! ------------------------------------------------------------------ |
366 |
! ------------- |
|
367 |
|
! * 5. MOLECULAR ABSORPTION ON CLEAR-SKY FLUXES |
368 |
|
! ---------------------------------------- |
369 |
|
|
370 |
|
|
|
DO jl = 1, kdlon |
|
|
zfu(jl, 1) = zfd(jl, 1)*palbp(jl, knu) |
|
|
END DO |
|
371 |
|
|
372 |
DO jk = 2, kflev + 1 |
! * 5.1 DOWNWARD FLUXES |
373 |
ikm1 = jk - 1 |
! --------------- |
374 |
|
|
375 |
|
|
376 |
|
jaj = 2 |
377 |
|
iind3(1) = 1 |
378 |
|
iind3(2) = 2 |
379 |
|
iind3(3) = 3 |
380 |
|
|
381 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
382 |
zw3(jl, 1) = zw3(jl, 1) + pud(jl, 1, ikm1)*1.66 |
zw3(jl, 1) = 0. |
383 |
zw3(jl, 2) = zw3(jl, 2) + pud(jl, 2, ikm1)*1.66 |
zw3(jl, 2) = 0. |
384 |
zw3(jl, 3) = zw3(jl, 3) + poz(jl, ikm1)*1.66 |
zw3(jl, 3) = 0. |
385 |
zw4(jl) = zw4(jl) + pud(jl, 4, ikm1)*1.66 |
zw4(jl) = 0. |
386 |
zw5(jl) = zw5(jl) + pud(jl, 5, ikm1)*1.66 |
zw5(jl) = 0. |
387 |
|
zr4(jl) = 1. |
388 |
|
zfd(jl, kflev+1) = zrj0(jl, jaj, kflev+1) |
389 |
|
END DO |
390 |
|
DO jk = 1, kflev |
391 |
|
ikl = kflev + 1 - jk |
392 |
|
DO jl = 1, kdlon |
393 |
|
zw3(jl, 1) = zw3(jl, 1) + pud(jl, 1, ikl)/zrmu0(jl, ikl) |
394 |
|
zw3(jl, 2) = zw3(jl, 2) + pud(jl, 2, ikl)/zrmu0(jl, ikl) |
395 |
|
zw3(jl, 3) = zw3(jl, 3) + poz(jl, ikl)/zrmu0(jl, ikl) |
396 |
|
zw4(jl) = zw4(jl) + pud(jl, 4, ikl)/zrmu0(jl, ikl) |
397 |
|
zw5(jl) = zw5(jl) + pud(jl, 5, ikl)/zrmu0(jl, ikl) |
398 |
|
END DO |
399 |
|
|
400 |
|
CALL swtt1(knu, 3, iind3, zw3, zr3) |
401 |
|
|
402 |
|
DO jl = 1, kdlon |
403 |
|
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
404 |
|
zfd(jl, ikl) = zr3(jl, 1)*zr3(jl, 2)*zr3(jl, 3)*zr4(jl)* & |
405 |
|
zrj0(jl, jaj, ikl) |
406 |
|
END DO |
407 |
END DO |
END DO |
408 |
|
|
409 |
CALL swtt1(knu, 3, iind3, zw3, zr3) |
|
410 |
|
! * 5.2 UPWARD FLUXES |
411 |
|
! ------------- |
412 |
|
|
413 |
|
|
414 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
415 |
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
zfu(jl, 1) = zfd(jl, 1)*palbp(jl, knu) |
|
zfu(jl, jk) = zr3(jl, 1)*zr3(jl, 2)*zr3(jl, 3)*zr4(jl)* & |
|
|
zrk0(jl, jaj, jk) |
|
416 |
END DO |
END DO |
|
END DO |
|
417 |
|
|
418 |
|
DO jk = 2, kflev + 1 |
419 |
|
ikm1 = jk - 1 |
420 |
|
DO jl = 1, kdlon |
421 |
|
zw3(jl, 1) = zw3(jl, 1) + pud(jl, 1, ikm1)*1.66 |
422 |
|
zw3(jl, 2) = zw3(jl, 2) + pud(jl, 2, ikm1)*1.66 |
423 |
|
zw3(jl, 3) = zw3(jl, 3) + poz(jl, ikm1)*1.66 |
424 |
|
zw4(jl) = zw4(jl) + pud(jl, 4, ikm1)*1.66 |
425 |
|
zw5(jl) = zw5(jl) + pud(jl, 5, ikm1)*1.66 |
426 |
|
END DO |
427 |
|
|
428 |
! ------------------------------------------------------------------ |
CALL swtt1(knu, 3, iind3, zw3, zr3) |
429 |
|
|
430 |
! * 6. INTRODUCTION OF OZONE AND H2O CONTINUUM ABSORPTION |
DO jl = 1, kdlon |
431 |
! -------------------------------------------------- |
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
432 |
|
zfu(jl, jk) = zr3(jl, 1)*zr3(jl, 2)*zr3(jl, 3)*zr4(jl)* & |
433 |
|
zrk0(jl, jaj, jk) |
434 |
|
END DO |
435 |
|
END DO |
436 |
|
|
|
iabs = 3 |
|
437 |
|
|
438 |
! * 6.1 DOWNWARD FLUXES |
! ------------------------------------------------------------------ |
|
! --------------- |
|
439 |
|
|
440 |
DO jl = 1, kdlon |
! * 6. INTRODUCTION OF OZONE AND H2O CONTINUUM ABSORPTION |
441 |
zw1(jl) = 0. |
! -------------------------------------------------- |
|
zw4(jl) = 0. |
|
|
zw5(jl) = 0. |
|
|
zr1(jl) = 0. |
|
|
pfdown(jl, kflev+1) = ((1.-pclear(jl))*pfdown(jl,kflev+1)+pclear(jl)*zfd( & |
|
|
jl,kflev+1))*rsun(knu) |
|
|
END DO |
|
442 |
|
|
443 |
DO jk = 1, kflev |
iabs = 3 |
|
ikl = kflev + 1 - jk |
|
|
DO jl = 1, kdlon |
|
|
zw1(jl) = zw1(jl) + poz(jl, ikl)/zrmue(jl, ikl) |
|
|
zw4(jl) = zw4(jl) + pud(jl, 4, ikl)/zrmue(jl, ikl) |
|
|
zw5(jl) = zw5(jl) + pud(jl, 5, ikl)/zrmue(jl, ikl) |
|
|
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
|
|
END DO |
|
444 |
|
|
445 |
CALL swtt(knu, iabs, zw1, zr1) |
! * 6.1 DOWNWARD FLUXES |
446 |
|
! --------------- |
447 |
|
|
448 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
449 |
pfdown(jl, ikl) = ((1.-pclear(jl))*zr1(jl)*zr4(jl)*pfdown(jl,ikl)+ & |
zw1(jl) = 0. |
450 |
pclear(jl)*zfd(jl,ikl))*rsun(knu) |
zw4(jl) = 0. |
451 |
|
zw5(jl) = 0. |
452 |
|
zr1(jl) = 0. |
453 |
|
pfdown(jl, kflev+1) = ((1.-pclear(jl))*pfdown(jl,kflev+1)+pclear(jl)*zfd( & |
454 |
|
jl,kflev+1))*rsun(knu) |
455 |
|
END DO |
456 |
|
|
457 |
|
DO jk = 1, kflev |
458 |
|
ikl = kflev + 1 - jk |
459 |
|
DO jl = 1, kdlon |
460 |
|
zw1(jl) = zw1(jl) + poz(jl, ikl)/zrmue(jl, ikl) |
461 |
|
zw4(jl) = zw4(jl) + pud(jl, 4, ikl)/zrmue(jl, ikl) |
462 |
|
zw5(jl) = zw5(jl) + pud(jl, 5, ikl)/zrmue(jl, ikl) |
463 |
|
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
464 |
|
END DO |
465 |
|
|
466 |
|
CALL swtt(knu, iabs, zw1, zr1) |
467 |
|
|
468 |
|
DO jl = 1, kdlon |
469 |
|
pfdown(jl, ikl) = ((1.-pclear(jl))*zr1(jl)*zr4(jl)*pfdown(jl,ikl)+ & |
470 |
|
pclear(jl)*zfd(jl,ikl))*rsun(knu) |
471 |
|
END DO |
472 |
END DO |
END DO |
|
END DO |
|
473 |
|
|
474 |
|
|
475 |
! * 6.2 UPWARD FLUXES |
! * 6.2 UPWARD FLUXES |
476 |
! ------------- |
! ------------- |
477 |
|
|
|
DO jl = 1, kdlon |
|
|
pfup(jl, 1) = ((1.-pclear(jl))*zr1(jl)*zr4(jl)*pfup(jl,1)+pclear(jl)*zfu( & |
|
|
jl,1))*rsun(knu) |
|
|
END DO |
|
|
|
|
|
DO jk = 2, kflev + 1 |
|
|
ikm1 = jk - 1 |
|
478 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
479 |
zw1(jl) = zw1(jl) + poz(jl, ikm1)*1.66 |
pfup(jl, 1) = ((1.-pclear(jl))*zr1(jl)*zr4(jl)*pfup(jl,1)+pclear(jl)*zfu( & |
480 |
zw4(jl) = zw4(jl) + pud(jl, 4, ikm1)*1.66 |
jl,1))*rsun(knu) |
|
zw5(jl) = zw5(jl) + pud(jl, 5, ikm1)*1.66 |
|
|
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
|
481 |
END DO |
END DO |
482 |
|
|
483 |
CALL swtt(knu, iabs, zw1, zr1) |
DO jk = 2, kflev + 1 |
484 |
|
ikm1 = jk - 1 |
485 |
|
DO jl = 1, kdlon |
486 |
|
zw1(jl) = zw1(jl) + poz(jl, ikm1)*1.66 |
487 |
|
zw4(jl) = zw4(jl) + pud(jl, 4, ikm1)*1.66 |
488 |
|
zw5(jl) = zw5(jl) + pud(jl, 5, ikm1)*1.66 |
489 |
|
! ZR4(JL) = EXP(-RSWCE*ZW4(JL)-RSWCP*ZW5(JL)) |
490 |
|
END DO |
491 |
|
|
492 |
|
CALL swtt(knu, iabs, zw1, zr1) |
493 |
|
|
494 |
DO jl = 1, kdlon |
DO jl = 1, kdlon |
495 |
pfup(jl, jk) = ((1.-pclear(jl))*zr1(jl)*zr4(jl)*pfup(jl,jk)+pclear(jl)* & |
pfup(jl, jk) = ((1.-pclear(jl))*zr1(jl)*zr4(jl)*pfup(jl,jk)+pclear(jl)* & |
496 |
zfu(jl,jk))*rsun(knu) |
zfu(jl,jk))*rsun(knu) |
497 |
|
END DO |
498 |
END DO |
END DO |
|
END DO |
|
499 |
|
|
500 |
! ------------------------------------------------------------------ |
END SUBROUTINE sw2s |
501 |
|
|
502 |
RETURN |
end module sw2s_m |
|
END SUBROUTINE sw2s |
|