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c |
SUBROUTINE swu(psct, pcldsw, ppmb, ppsol, prmu0, pfrac, ptave, pwv, paki, & |
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cIM ctes ds clesphys.h SUBROUTINE SWU (PSCT,RCO2,PCLDSW,PPMB,PPSOL,PRMU0,PFRAC, |
pcld, pclear, pdsig, pfact, prmu, psec, pud) |
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SUBROUTINE SWU (PSCT,PCLDSW,PPMB,PPSOL,PRMU0,PFRAC, |
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S PTAVE,PWV,PAKI,PCLD,PCLEAR,PDSIG,PFACT, |
USE dimens_m |
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S PRMU,PSEC,PUD) |
USE dimphy |
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use dimens_m |
USE clesphys |
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use dimphy |
USE suphec_m |
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use clesphys |
USE raddim |
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use SUPHEC_M |
USE radepsi |
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use raddim |
USE radopt |
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use radepsi |
IMPLICIT NONE |
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use radopt |
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IMPLICIT none |
! * ARGUMENTS: |
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C |
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C* ARGUMENTS: |
DOUBLE PRECISION psct |
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C |
! IM ctes ds clesphys.h DOUBLE PRECISION RCO2 |
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REAL*8 PSCT |
DOUBLE PRECISION pcldsw(kdlon, kflev) |
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cIM ctes ds clesphys.h REAL*8 RCO2 |
DOUBLE PRECISION ppmb(kdlon, kflev+1) |
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REAL*8 PCLDSW(KDLON,KFLEV) |
DOUBLE PRECISION ppsol(kdlon) |
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REAL*8 PPMB(KDLON,KFLEV+1) |
DOUBLE PRECISION prmu0(kdlon) |
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REAL*8 PPSOL(KDLON) |
DOUBLE PRECISION pfrac(kdlon) |
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REAL*8 PRMU0(KDLON) |
DOUBLE PRECISION ptave(kdlon, kflev) |
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REAL*8 PFRAC(KDLON) |
DOUBLE PRECISION pwv(kdlon, kflev) |
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REAL*8 PTAVE(KDLON,KFLEV) |
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REAL*8 PWV(KDLON,KFLEV) |
DOUBLE PRECISION paki(kdlon, 2) |
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C |
DOUBLE PRECISION pcld(kdlon, kflev) |
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REAL*8 PAKI(KDLON,2) |
DOUBLE PRECISION pclear(kdlon) |
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REAL*8 PCLD(KDLON,KFLEV) |
DOUBLE PRECISION pdsig(kdlon, kflev) |
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REAL*8 PCLEAR(KDLON) |
DOUBLE PRECISION pfact(kdlon) |
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REAL*8 PDSIG(KDLON,KFLEV) |
DOUBLE PRECISION prmu(kdlon) |
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REAL*8 PFACT(KDLON) |
DOUBLE PRECISION psec(kdlon) |
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REAL*8 PRMU(KDLON) |
DOUBLE PRECISION pud(kdlon, 5, kflev+1) |
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REAL*8 PSEC(KDLON) |
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REAL*8 PUD(KDLON,5,KFLEV+1) |
! * LOCAL VARIABLES: |
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C |
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C* LOCAL VARIABLES: |
INTEGER iind(2) |
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C |
DOUBLE PRECISION zc1j(kdlon, kflev+1) |
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INTEGER IIND(2) |
DOUBLE PRECISION zclear(kdlon) |
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REAL*8 ZC1J(KDLON,KFLEV+1) |
DOUBLE PRECISION zcloud(kdlon) |
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REAL*8 ZCLEAR(KDLON) |
DOUBLE PRECISION zn175(kdlon) |
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REAL*8 ZCLOUD(KDLON) |
DOUBLE PRECISION zn190(kdlon) |
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REAL*8 ZN175(KDLON) |
DOUBLE PRECISION zo175(kdlon) |
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REAL*8 ZN190(KDLON) |
DOUBLE PRECISION zo190(kdlon) |
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REAL*8 ZO175(KDLON) |
DOUBLE PRECISION zsign(kdlon) |
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REAL*8 ZO190(KDLON) |
DOUBLE PRECISION zr(kdlon, 2) |
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REAL*8 ZSIGN(KDLON) |
DOUBLE PRECISION zsigo(kdlon) |
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REAL*8 ZR(KDLON,2) |
DOUBLE PRECISION zud(kdlon, 2) |
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REAL*8 ZSIGO(KDLON) |
DOUBLE PRECISION zrth, zrtu, zwh2o, zdsco2, zdsh2o, zfppw |
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REAL*8 ZUD(KDLON,2) |
INTEGER jl, jk, jkp1, jkl, jklp1, ja |
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REAL*8 ZRTH, ZRTU, ZWH2O, ZDSCO2, ZDSH2O, ZFPPW |
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INTEGER jl, jk, jkp1, jkl, jklp1, ja |
! * Prescribed Data: |
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C |
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C* Prescribed Data: |
DOUBLE PRECISION zpdh2o, zpdumg |
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c |
SAVE zpdh2o, zpdumg |
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REAL*8 ZPDH2O,ZPDUMG |
DOUBLE PRECISION zprh2o, zprumg |
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SAVE ZPDH2O,ZPDUMG |
SAVE zprh2o, zprumg |
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REAL*8 ZPRH2O,ZPRUMG |
DOUBLE PRECISION rtdh2o, rtdumg |
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SAVE ZPRH2O,ZPRUMG |
SAVE rtdh2o, rtdumg |
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REAL*8 RTDH2O,RTDUMG |
DOUBLE PRECISION rth2o, rtumg |
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SAVE RTDH2O,RTDUMG |
SAVE rth2o, rtumg |
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REAL*8 RTH2O ,RTUMG |
DATA zpdh2o, zpdumg/0.8, 0.75/ |
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SAVE RTH2O ,RTUMG |
DATA zprh2o, zprumg/30000., 30000./ |
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DATA ZPDH2O,ZPDUMG / 0.8 , 0.75 / |
DATA rtdh2o, rtdumg/0.40, 0.375/ |
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DATA ZPRH2O,ZPRUMG / 30000., 30000. / |
DATA rth2o, rtumg/240., 240./ |
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DATA RTDH2O,RTDUMG / 0.40 , 0.375 / |
! ------------------------------------------------------------------ |
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DATA RTH2O ,RTUMG / 240. , 240. / |
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C ------------------------------------------------------------------ |
! * 1. COMPUTES AMOUNTS OF ABSORBERS |
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C |
! ----------------------------- |
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C* 1. COMPUTES AMOUNTS OF ABSORBERS |
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C ----------------------------- |
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C |
iind(1) = 1 |
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100 CONTINUE |
iind(2) = 2 |
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C |
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IIND(1)=1 |
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IIND(2)=2 |
! * 1.1 INITIALIZES QUANTITIES |
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C |
! ---------------------- |
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C |
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C* 1.1 INITIALIZES QUANTITIES |
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C ---------------------- |
DO jl = 1, kdlon |
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C |
pud(jl, 1, kflev+1) = 0. |
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110 CONTINUE |
pud(jl, 2, kflev+1) = 0. |
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C |
pud(jl, 3, kflev+1) = 0. |
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DO 111 JL = 1, KDLON |
pud(jl, 4, kflev+1) = 0. |
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PUD(JL,1,KFLEV+1)=0. |
pud(jl, 5, kflev+1) = 0. |
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PUD(JL,2,KFLEV+1)=0. |
pfact(jl) = prmu0(jl)*pfrac(jl)*psct |
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PUD(JL,3,KFLEV+1)=0. |
prmu(jl) = sqrt(1224.*prmu0(jl)*prmu0(jl)+1.)/35. |
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PUD(JL,4,KFLEV+1)=0. |
psec(jl) = 1./prmu(jl) |
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PUD(JL,5,KFLEV+1)=0. |
zc1j(jl, kflev+1) = 0. |
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PFACT(JL)= PRMU0(JL) * PFRAC(JL) * PSCT |
END DO |
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PRMU(JL)=SQRT(1224.* PRMU0(JL) * PRMU0(JL) + 1.) / 35. |
|
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PSEC(JL)=1./PRMU(JL) |
! * 1.3 AMOUNTS OF ABSORBERS |
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ZC1J(JL,KFLEV+1)=0. |
! -------------------- |
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111 CONTINUE |
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C |
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C* 1.3 AMOUNTS OF ABSORBERS |
DO jl = 1, kdlon |
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C -------------------- |
zud(jl, 1) = 0. |
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C |
zud(jl, 2) = 0. |
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130 CONTINUE |
zo175(jl) = ppsol(jl)**(zpdumg+1.) |
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C |
zo190(jl) = ppsol(jl)**(zpdh2o+1.) |
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DO 131 JL= 1, KDLON |
zsigo(jl) = ppsol(jl) |
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ZUD(JL,1) = 0. |
zclear(jl) = 1. |
102 |
ZUD(JL,2) = 0. |
zcloud(jl) = 0. |
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ZO175(JL) = PPSOL(JL)** (ZPDUMG+1.) |
END DO |
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ZO190(JL) = PPSOL(JL)** (ZPDH2O+1.) |
|
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ZSIGO(JL) = PPSOL(JL) |
DO jk = 1, kflev |
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ZCLEAR(JL)=1. |
jkp1 = jk + 1 |
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ZCLOUD(JL)=0. |
jkl = kflev + 1 - jk |
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131 CONTINUE |
jklp1 = jkl + 1 |
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C |
DO jl = 1, kdlon |
110 |
DO 133 JK = 1 , KFLEV |
zrth = (rth2o/ptave(jl,jk))**rtdh2o |
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JKP1 = JK + 1 |
zrtu = (rtumg/ptave(jl,jk))**rtdumg |
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JKL = KFLEV+1 - JK |
zwh2o = max(pwv(jl,jk), zepscq) |
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JKLP1 = JKL+1 |
zsign(jl) = 100.*ppmb(jl, jkp1) |
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DO 132 JL = 1, KDLON |
pdsig(jl, jk) = (zsigo(jl)-zsign(jl))/ppsol(jl) |
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ZRTH=(RTH2O/PTAVE(JL,JK))**RTDH2O |
zn175(jl) = zsign(jl)**(zpdumg+1.) |
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ZRTU=(RTUMG/PTAVE(JL,JK))**RTDUMG |
zn190(jl) = zsign(jl)**(zpdh2o+1.) |
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ZWH2O = MAX (PWV(JL,JK) , ZEPSCQ ) |
zdsco2 = zo175(jl) - zn175(jl) |
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ZSIGN(JL) = 100. * PPMB(JL,JKP1) |
zdsh2o = zo190(jl) - zn190(jl) |
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PDSIG(JL,JK) = (ZSIGO(JL) - ZSIGN(JL))/PPSOL(JL) |
pud(jl, 1, jk) = 1./(10.*rg*(zpdh2o+1.))/(zprh2o**zpdh2o)*zdsh2o*zwh2o* & |
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ZN175(JL) = ZSIGN(JL) ** (ZPDUMG+1.) |
zrth |
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ZN190(JL) = ZSIGN(JL) ** (ZPDH2O+1.) |
pud(jl, 2, jk) = 1./(10.*rg*(zpdumg+1.))/(zprumg**zpdumg)*zdsco2*rco2* & |
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ZDSCO2 = ZO175(JL) - ZN175(JL) |
zrtu |
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ZDSH2O = ZO190(JL) - ZN190(JL) |
zfppw = 1.6078*zwh2o/(1.+0.608*zwh2o) |
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PUD(JL,1,JK) = 1./( 10.* RG * (ZPDH2O+1.) )/(ZPRH2O**ZPDH2O) |
pud(jl, 4, jk) = pud(jl, 1, jk)*zfppw |
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. * ZDSH2O * ZWH2O * ZRTH |
pud(jl, 5, jk) = pud(jl, 1, jk)*(1.-zfppw) |
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PUD(JL,2,JK) = 1./( 10.* RG * (ZPDUMG+1.) )/(ZPRUMG**ZPDUMG) |
zud(jl, 1) = zud(jl, 1) + pud(jl, 1, jk) |
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. * ZDSCO2 * RCO2 * ZRTU |
zud(jl, 2) = zud(jl, 2) + pud(jl, 2, jk) |
128 |
ZFPPW=1.6078*ZWH2O/(1.+0.608*ZWH2O) |
zsigo(jl) = zsign(jl) |
129 |
PUD(JL,4,JK)=PUD(JL,1,JK)*ZFPPW |
zo175(jl) = zn175(jl) |
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PUD(JL,5,JK)=PUD(JL,1,JK)*(1.-ZFPPW) |
zo190(jl) = zn190(jl) |
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ZUD(JL,1) = ZUD(JL,1) + PUD(JL,1,JK) |
|
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ZUD(JL,2) = ZUD(JL,2) + PUD(JL,2,JK) |
IF (novlp==1) THEN |
133 |
ZSIGO(JL) = ZSIGN(JL) |
zclear(jl) = zclear(jl)*(1.-max(pcldsw(jl,jkl),zcloud(jl)))/(1.-min( & |
134 |
ZO175(JL) = ZN175(JL) |
zcloud(jl),1.-zepsec)) |
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ZO190(JL) = ZN190(JL) |
zc1j(jl, jkl) = 1.0 - zclear(jl) |
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C |
zcloud(jl) = pcldsw(jl, jkl) |
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IF (NOVLP.EQ.1) THEN |
ELSE IF (novlp==2) THEN |
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ZCLEAR(JL)=ZCLEAR(JL) |
zcloud(jl) = max(pcldsw(jl,jkl), zcloud(jl)) |
139 |
S *(1.-MAX(PCLDSW(JL,JKL),ZCLOUD(JL))) |
zc1j(jl, jkl) = zcloud(jl) |
140 |
S /(1.-MIN(ZCLOUD(JL),1.-ZEPSEC)) |
ELSE IF (novlp==3) THEN |
141 |
ZC1J(JL,JKL)= 1.0 - ZCLEAR(JL) |
zclear(jl) = zclear(jl)*(1.-pcldsw(jl,jkl)) |
142 |
ZCLOUD(JL) = PCLDSW(JL,JKL) |
zcloud(jl) = 1.0 - zclear(jl) |
143 |
ELSE IF (NOVLP.EQ.2) THEN |
zc1j(jl, jkl) = zcloud(jl) |
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ZCLOUD(JL) = MAX(PCLDSW(JL,JKL),ZCLOUD(JL)) |
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ZC1J(JL,JKL) = ZCLOUD(JL) |
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ELSE IF (NOVLP.EQ.3) THEN |
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ZCLEAR(JL) = ZCLEAR(JL)*(1.-PCLDSW(JL,JKL)) |
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ZCLOUD(JL) = 1.0 - ZCLEAR(JL) |
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ZC1J(JL,JKL) = ZCLOUD(JL) |
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END IF |
END IF |
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132 CONTINUE |
END DO |
146 |
133 CONTINUE |
END DO |
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DO 134 JL=1, KDLON |
DO jl = 1, kdlon |
148 |
PCLEAR(JL)=1.-ZC1J(JL,1) |
pclear(jl) = 1. - zc1j(jl, 1) |
149 |
134 CONTINUE |
END DO |
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DO 136 JK=1,KFLEV |
DO jk = 1, kflev |
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DO 135 JL=1, KDLON |
DO jl = 1, kdlon |
152 |
IF (PCLEAR(JL).LT.1.) THEN |
IF (pclear(jl)<1.) THEN |
153 |
PCLD(JL,JK)=PCLDSW(JL,JK)/(1.-PCLEAR(JL)) |
pcld(jl, jk) = pcldsw(jl, jk)/(1.-pclear(jl)) |
154 |
ELSE |
ELSE |
155 |
PCLD(JL,JK)=0. |
pcld(jl, jk) = 0. |
156 |
END IF |
END IF |
157 |
135 CONTINUE |
END DO |
158 |
136 CONTINUE |
END DO |
159 |
C |
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160 |
C |
|
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C* 1.4 COMPUTES CLEAR-SKY GREY ABSORPTION COEFFICIENTS |
! * 1.4 COMPUTES CLEAR-SKY GREY ABSORPTION COEFFICIENTS |
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C ----------------------------------------------- |
! ----------------------------------------------- |
163 |
C |
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164 |
140 CONTINUE |
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C |
DO ja = 1, 2 |
166 |
DO 142 JA = 1,2 |
DO jl = 1, kdlon |
167 |
DO 141 JL = 1, KDLON |
zud(jl, ja) = zud(jl, ja)*psec(jl) |
168 |
ZUD(JL,JA) = ZUD(JL,JA) * PSEC(JL) |
END DO |
169 |
141 CONTINUE |
END DO |
170 |
142 CONTINUE |
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171 |
C |
CALL swtt1(2, 2, iind, zud, zr) |
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CALL SWTT1(2, 2, IIND, ZUD, ZR) |
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C |
DO ja = 1, 2 |
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DO 144 JA = 1,2 |
DO jl = 1, kdlon |
175 |
DO 143 JL = 1, KDLON |
paki(jl, ja) = -log(zr(jl,ja))/zud(jl, ja) |
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PAKI(JL,JA) = -LOG( ZR(JL,JA) ) / ZUD(JL,JA) |
END DO |
177 |
143 CONTINUE |
END DO |
178 |
144 CONTINUE |
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179 |
C |
END SUBROUTINE swu |
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C |
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C ------------------------------------------------------------------ |
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C |
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RETURN |
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END |
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