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guez |
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SUBROUTINE LWTTM(PGA,PGB,PUU1,PUU2, PTT) |
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use dimens_m |
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use dimphy |
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use raddim |
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use raddimlw |
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IMPLICIT none |
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C |
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C ------------------------------------------------------------------ |
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C PURPOSE. |
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C -------- |
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C THIS ROUTINE COMPUTES THE TRANSMISSION FUNCTIONS FOR ALL THE |
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C ABSORBERS (H2O, UNIFORMLY MIXED GASES, AND O3) IN ALL SIX SPECTRAL |
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C INTERVALS. |
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C |
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C METHOD. |
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C ------- |
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C |
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C 1. TRANSMISSION FUNCTION BY H2O AND UNIFORMLY MIXED GASES ARE |
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C COMPUTED USING PADE APPROXIMANTS AND HORNER'S ALGORITHM. |
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C 2. TRANSMISSION BY O3 IS EVALUATED WITH MALKMUS'S BAND MODEL. |
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C 3. TRANSMISSION BY H2O CONTINUUM AND AEROSOLS FOLLOW AN |
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C A SIMPLE EXPONENTIAL DECREASE WITH ABSORBER AMOUNT. |
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C |
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C REFERENCE. |
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C ---------- |
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C |
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C SEE RADIATION'S PART OF THE MODEL'S DOCUMENTATION AND |
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C ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS |
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C |
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C AUTHOR. |
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C ------- |
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C JEAN-JACQUES MORCRETTE *ECMWF* |
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C |
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C MODIFICATIONS. |
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C -------------- |
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C ORIGINAL : 88-12-15 |
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C |
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C----------------------------------------------------------------------- |
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guez |
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DOUBLE PRECISION O1H, O2H |
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guez |
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PARAMETER (O1H=2230.) |
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PARAMETER (O2H=100.) |
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guez |
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DOUBLE PRECISION RPIALF0 |
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guez |
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PARAMETER (RPIALF0=2.0) |
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C |
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C* ARGUMENTS: |
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C |
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DOUBLE PRECISION PGA(KDLON,8,2) ! PADE APPROXIMANTS |
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DOUBLE PRECISION PGB(KDLON,8,2) ! PADE APPROXIMANTS |
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DOUBLE PRECISION PUU1(KDLON,NUA) ! ABSORBER AMOUNTS FROM TOP TO LEVEL 1 |
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DOUBLE PRECISION PUU2(KDLON,NUA) ! ABSORBER AMOUNTS FROM TOP TO LEVEL 2 |
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DOUBLE PRECISION PTT(KDLON,NTRA) ! TRANSMISSION FUNCTIONS |
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guez |
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C |
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C* LOCAL VARIABLES: |
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C |
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INTEGER ja, jl |
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DOUBLE PRECISION zz, zxd, zxn |
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DOUBLE PRECISION zpu, zpu10, zpu11, zpu12, zpu13 |
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DOUBLE PRECISION zeu, zeu10, zeu11, zeu12, zeu13 |
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DOUBLE PRECISION zx, zy, zuxy, zsq1, zsq2, zvxy, zaercn, zto1 |
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DOUBLE PRECISION zto2 |
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DOUBLE PRECISION zxch4, zych4, zsqh41, zodh41 |
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DOUBLE PRECISION zxn2o, zyn2o, zsqn21, zodn21, zsqh42, zodh42 |
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DOUBLE PRECISION zsqn22, zodn22, za11, zttf11, za12, zttf12 |
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DOUBLE PRECISION zuu11, zuu12 |
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C ------------------------------------------------------------------ |
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C |
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C* 1. HORNER'S ALGORITHM FOR H2O AND CO2 TRANSMISSION |
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C ----------------------------------------------- |
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C |
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100 CONTINUE |
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C |
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C |
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DO 130 JA = 1 , 8 |
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DO 120 JL = 1, KDLON |
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ZZ =SQRT(PUU1(JL,JA) - PUU2(JL,JA)) |
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ZXD =PGB( JL,JA,1) + ZZ *(PGB( JL,JA,2) + ZZ ) |
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ZXN =PGA( JL,JA,1) + ZZ *(PGA( JL,JA,2) ) |
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PTT(JL,JA)=ZXN /ZXD |
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120 CONTINUE |
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130 CONTINUE |
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C |
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C ------------------------------------------------------------------ |
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C |
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C* 2. CONTINUUM, OZONE AND AEROSOL TRANSMISSION FUNCTIONS |
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C --------------------------------------------------- |
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C |
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200 CONTINUE |
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C |
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DO 201 JL = 1, KDLON |
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PTT(JL, 9) = PTT(JL, 8) |
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C |
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C- CONTINUUM ABSORPTION: E- AND P-TYPE |
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C |
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ZPU = 0.002 * (PUU1(JL,10) - PUU2(JL,10)) |
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ZPU10 = 112. * ZPU |
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ZPU11 = 6.25 * ZPU |
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ZPU12 = 5.00 * ZPU |
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ZPU13 = 80.0 * ZPU |
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ZEU = (PUU1(JL,11) - PUU2(JL,11)) |
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ZEU10 = 12. * ZEU |
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ZEU11 = 6.25 * ZEU |
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ZEU12 = 5.00 * ZEU |
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ZEU13 = 80.0 * ZEU |
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C |
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C- OZONE ABSORPTION |
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C |
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ZX = (PUU1(JL,12) - PUU2(JL,12)) |
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ZY = (PUU1(JL,13) - PUU2(JL,13)) |
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ZUXY = 4. * ZX * ZX / (RPIALF0 * ZY) |
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ZSQ1 = SQRT(1. + O1H * ZUXY ) - 1. |
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ZSQ2 = SQRT(1. + O2H * ZUXY ) - 1. |
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ZVXY = RPIALF0 * ZY / (2. * ZX) |
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ZAERCN = (PUU1(JL,17) -PUU2(JL,17)) + ZEU12 + ZPU12 |
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ZTO1 = EXP( - ZVXY * ZSQ1 - ZAERCN ) |
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ZTO2 = EXP( - ZVXY * ZSQ2 - ZAERCN ) |
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C |
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C-- TRACE GASES (CH4, N2O, CFC-11, CFC-12) |
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C |
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C* CH4 IN INTERVAL 800-970 + 1110-1250 CM-1 |
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C |
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ZXCH4 = (PUU1(JL,19) - PUU2(JL,19)) |
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ZYCH4 = (PUU1(JL,20) - PUU2(JL,20)) |
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ZUXY = 4. * ZXCH4*ZXCH4/(0.103*ZYCH4) |
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ZSQH41 = SQRT(1. + 33.7 * ZUXY) - 1. |
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ZVXY = 0.103 * ZYCH4 / (2. * ZXCH4) |
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ZODH41 = ZVXY * ZSQH41 |
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C |
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C* N2O IN INTERVAL 800-970 + 1110-1250 CM-1 |
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C |
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ZXN2O = (PUU1(JL,21) - PUU2(JL,21)) |
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ZYN2O = (PUU1(JL,22) - PUU2(JL,22)) |
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ZUXY = 4. * ZXN2O*ZXN2O/(0.416*ZYN2O) |
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ZSQN21 = SQRT(1. + 21.3 * ZUXY) - 1. |
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ZVXY = 0.416 * ZYN2O / (2. * ZXN2O) |
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ZODN21 = ZVXY * ZSQN21 |
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C |
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C* CH4 IN INTERVAL 1250-1450 + 1880-2820 CM-1 |
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C |
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ZUXY = 4. * ZXCH4*ZXCH4/(0.113*ZYCH4) |
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ZSQH42 = SQRT(1. + 400. * ZUXY) - 1. |
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ZVXY = 0.113 * ZYCH4 / (2. * ZXCH4) |
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ZODH42 = ZVXY * ZSQH42 |
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C |
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C* N2O IN INTERVAL 1250-1450 + 1880-2820 CM-1 |
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C |
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ZUXY = 4. * ZXN2O*ZXN2O/(0.197*ZYN2O) |
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ZSQN22 = SQRT(1. + 2000. * ZUXY) - 1. |
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ZVXY = 0.197 * ZYN2O / (2. * ZXN2O) |
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ZODN22 = ZVXY * ZSQN22 |
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C |
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C* CFC-11 IN INTERVAL 800-970 + 1110-1250 CM-1 |
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C |
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ZA11 = (PUU1(JL,23) - PUU2(JL,23)) * 4.404E+05 |
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ZTTF11 = 1. - ZA11 * 0.003225 |
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C |
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C* CFC-12 IN INTERVAL 800-970 + 1110-1250 CM-1 |
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C |
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ZA12 = (PUU1(JL,24) - PUU2(JL,24)) * 6.7435E+05 |
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ZTTF12 = 1. - ZA12 * 0.003225 |
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C |
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ZUU11 = - (PUU1(JL,15) - PUU2(JL,15)) - ZEU10 - ZPU10 |
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ZUU12 = - (PUU1(JL,16) - PUU2(JL,16)) - ZEU11 - ZPU11 - |
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S ZODH41 - ZODN21 |
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PTT(JL,10) = EXP( - (PUU1(JL,14)- PUU2(JL,14)) ) |
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PTT(JL,11) = EXP( ZUU11 ) |
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PTT(JL,12) = EXP( ZUU12 ) * ZTTF11 * ZTTF12 |
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PTT(JL,13) = 0.7554 * ZTO1 + 0.2446 * ZTO2 |
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PTT(JL,14) = PTT(JL,10) * EXP( - ZEU13 - ZPU13 ) |
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PTT(JL,15) = EXP ( - (PUU1(JL,14) - PUU2(JL,14)) - ZODH42-ZODN22 ) |
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201 CONTINUE |
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C |
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RETURN |
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END |