!WRF:MODEL_RA:RADIATION
!
!-----------------------------------------------------------------------
!-- Search for "!GFDL" for changes to improve coupling with microphysics
!-----------------------------------------------------------------------
MODULE MODULE_RA_HWRF 2
USE MODULE_CONFIGURE
,ONLY : GRID_CONFIG_REC_TYPE
USE MODULE_MODEL_CONSTANTS
!GFDL USE MODULE_MP_ETANEW, ONLY : RHGRD,FPVS
USE MODULE_MP_HWRF, ONLY : RHGRD_in,RHGRD_out,FPVS !GFDL
INTEGER,PARAMETER :: NL=81
INTEGER,PARAMETER :: NBLY=15
REAL,PARAMETER :: RTHRESH=1.E-15
INTEGER, SAVE, DIMENSION(3) :: LTOP
REAL , SAVE, DIMENSION(37,NL) :: XDUO3N,XDO3N2,XDO3N3,XDO3N4
REAL , SAVE, DIMENSION(NL) :: PRGFDL
REAL , SAVE :: AB15WD,SKO2D,SKC1R,SKO3R
REAL , SAVE :: EM1(28,180),EM1WDE(28,180),TABLE1(28,180), &
TABLE2(28,180),TABLE3(28,180),EM3(28,180), &
SOURCE(28,NBLY), DSRCE(28,NBLY)
REAL ,SAVE, DIMENSION(5040):: T1,T2,T4,EM1V,EM1VW,EM3V
REAL ,SAVE :: R1
! Created by CO2 initialization
REAL, SAVE, ALLOCATABLE, DIMENSION(:,:) :: CO251,CDT51,CDT58,C2D51,&
C2D58,CO258
REAL, SAVE, ALLOCATABLE, DIMENSION(:) :: STEMP,GTEMP,CO231,CO238, &
C2D31,C2D38,CDT31,CDT38, &
CO271,CO278,C2D71,C2D78, &
CDT71,CDT78
REAL, SAVE, ALLOCATABLE, DIMENSION(:) :: CO2M51,CO2M58,CDTM51,CDTM58, &
C2DM51,C2DM58
CHARACTER(256) :: ERRMESS
! Used by CO2 initialization
! COMMON/PRESS/PA(109)
! COMMON/TRAN/ TRANSA(109,109)
! COMMON/COEFS/XA(109),CA(109),ETA(109),SEXPV(109),CORE,UEXP,SEXP
REAL ,SAVE, DIMENSION(109) :: PA, XA, CA, ETA, SEXPV
REAL ,SAVE, DIMENSION(109,109) :: TRANSA
REAL ,SAVE :: CORE,UEXP,SEXP
EQUIVALENCE (EM1V(1),EM1(1,1)),(EM1VW(1),EM1WDE(1,1))
EQUIVALENCE (EM3V(1),EM3(1,1))
EQUIVALENCE (T1(1),TABLE1(1,1)),(T2(1),TABLE2(1,1)), &
(T4(1),TABLE3(1,1))
CONTAINS
!-----------------------------------------------------------------------
SUBROUTINE HWRFRAINIT(SFULL,SHALF,PPTOP,JULYR,MONTH,IDAY,GMT, & 2,6
& CONFIG_FLAGS, ALLOWED_TO_READ, &
& KDS,KDE,KMS,KME,KTS,KTE)
!-----------------------------------------------------------------------
IMPLICIT NONE
!-----------------------------------------------------------------------
TYPE (GRID_CONFIG_REC_TYPE) :: CONFIG_FLAGS
INTEGER,INTENT(IN) :: KDS,KDE,KMS,KME,KTS,KTE
REAL,DIMENSION(KMS:KME),INTENT(IN) :: SFULL, SHALF
INTEGER,INTENT(IN) :: JULYR,MONTH,IDAY
REAL,INTENT(IN) :: GMT,PPTOP
LOGICAL,INTENT(IN) :: ALLOWED_TO_READ
INTEGER :: IHRST,N
REAL :: PCLD
REAL :: SSLP=1013.25
REAL :: PTOP_HI=150.,PTOP_MID=350.,PTOP_LO=642.
!-----------------------------------------------------------------------
!***********************************************************************
!-----------------------------------------------------------------------
!
!*** INITIALIZE DIAGNOSTIC LOW,MIDDLE,HIGH CLOUD LAYER PRESSURE LIMITS.
!
LTOP(1)=0
LTOP(2)=0
LTOP(3)=0
!
!dule DO N=1,KTE
DO N=1,KTE-1
PCLD=(SSLP-PPTOP*10.)*SHALF(N)+PPTOP*10.
IF(PCLD>=PTOP_LO)LTOP(1)=N
IF(PCLD>=PTOP_MID)LTOP(2)=N
IF(PCLD>=PTOP_HI)LTOP(3)=N
! PRINT *,N,PCLD,SHALF(N),PSTAR,PPTOP
ENDDO
!
!*** USE CALL TO CONRAD FOR DIRECT READ OF CO2 FUNCTIONS
!*** OTHERWISE CALL CO2O3.
!
IF(ALLOWED_TO_READ)THEN
#if (EM_CORE==1)
CALL CO2O3(SFULL,SHALF,PPTOP,KME-KMS,KME-KMS+1,KME-KMS+2)
#endif
#if (NMM_CORE==1)
IF(CONFIG_FLAGS%CO2TF==1)THEN
CALL CO2O3(SFULL,SHALF,PPTOP,KME-KMS,KME-KMS+1,KME-KMS+2)
ELSE
CALL CONRAD(KDS,KDE,KMS,KME,KTS,KTE)
ENDIF
#endif
!
CALL O3CLIM
CALL TABLE
IHRST=NINT(GMT)
CALL SOLARD(IHRST,IDAY,MONTH,JULYR)
ENDIF
!
!-----------------------------------------------------------------------
END SUBROUTINE HWRFRAINIT
!-----------------------------------------------------------------------
!
!
!-----------------------------------------------------------------------
SUBROUTINE HWRFRA(explicit_convection, DT,THRATEN,THRATENLW,THRATENSW,PI3D & 2,2
& ,XLAND,P8W,DZ8W,RHO_PHY,P_PHY,T &
& ,QV,QW,QI &
& ,TSK2D,GLW,GSW &
& ,TOTSWDN,TOTLWDN,RSWTOA,RLWTOA,CZMEAN &
& ,GLAT,GLON,HTOP,HBOT,htopr,hbotr,ALBEDO,CUPPT &
& ,VEGFRA,SNOW,G,GMT &
& ,NSTEPRA,NPHS,ITIMESTEP &
& ,JULYR,JULDAY,GFDL_LW,GFDL_SW &
& ,CFRACL,CFRACM,CFRACH &
& ,ACFRST,NCFRST,ACFRCV,NCFRCV &
& ,IDS,IDE,JDS,JDE,KDS,KDE &
& ,IMS,IME,JMS,JME,KMS,KME &
& ,ITS,ITE,JTS,JTE,KTS,KTE)
!-----------------------------------------------------------------------
IMPLICIT NONE
!-----------------------------------------------------------------------
LOGICAL, INTENT(IN) :: explicit_convection
INTEGER,INTENT(IN) :: IDS,IDE,JDS,JDE,KDS,KDE &
& ,IMS,IME,JMS,JME,KMS,KME &
& ,ITS,ITE,JTS,JTE,KTS,KTE,ITIMESTEP &
& ,NPHS,NSTEPRA
INTEGER,INTENT(IN) :: julyr,julday
INTEGER,INTENT(INOUT),DIMENSION(ims:ime,jms:jme) :: NCFRST & !Added
,NCFRCV !Added
REAL,INTENT(IN) :: DT,GMT,G
REAL,INTENT(INOUT),DIMENSION(ims:ime, kms:kme, jms:jme):: &
THRATEN,THRATENLW,THRATENSW
REAL,INTENT(IN),DIMENSION(ims:ime, kms:kme, jms:jme)::p8w,dz8w, &
& rho_phy, &
& p_phy, &
& PI3D
REAL, INTENT(IN), DIMENSION(ims:ime, jms:jme):: ALBEDO,SNOW, &
& TSK2D,VEGFRA, &
& XLAND
REAL, INTENT(IN), DIMENSION(ims:ime, jms:jme):: GLAT,GLON
REAL, INTENT(INOUT), DIMENSION(ims:ime, jms:jme):: HTOP,HBOT,htopr,hbotr,cuppt
REAL, INTENT(INOUT), DIMENSION(ims:ime, jms:jme):: RSWTOA, & !Added
& RLWTOA, & !Added
& ACFRST, & !Added
& ACFRCV
REAL,INTENT(INOUT),DIMENSION(ims:ime, jms:jme):: GLW,GSW
REAL,INTENT(OUT),DIMENSION(ims:ime, jms:jme):: CZMEAN, &
& TOTLWDN,TOTSWDN
REAL,INTENT(OUT),DIMENSION(ims:ime, jms:jme):: CFRACL,CFRACM, & !Added
& CFRACH !Added
REAL, INTENT(IN), DIMENSION(ims:ime, kms:kme, jms:jme):: QI,QV, &
& QW,T
! REAL, INTENT(IN), DIMENSION(37*kte) :: RAD1,RAD2,RAD3,RAD4
LOGICAL, INTENT(IN) :: gfdl_lw,gfdl_sw
REAL, DIMENSION(its:ite, kms:kme, jts:jte):: PFLIP,QIFLIP,QFLIP, &
& QWFLIP,TFLIP
REAL, DIMENSION(its:ite, kms:kme, jts:jte)::P8WFLIP,PHYD
REAL, DIMENSION(its:ite, kts:kte, jts:jte)::TENDS,TENDL
INTEGER :: IDAT(3),Jmonth,Jday
INTEGER :: I,J,K,KFLIP,IHRST
!-----------------------------------------------------------------------
!***********************************************************************
!-----------------------------------------------------------------------
IF(GFDL_LW.AND.GFDL_SW )GO TO 100
!
! NEED HYDROSTATIC PRESSURE HERE (MONOTONIC CHANGE WITH HEIGHT)
DO J=JTS,JTE
DO I=ITS,ITE
PHYD(I,KTS,J)=P8W(I,KTS,J)
ENDDO
ENDDO
!
DO J=JTS,JTE
DO K=KTS,KTE
DO I=ITS,ITE
PHYD(I,K+1,J)=PHYD(I,K,J)-G*RHO_PHY(I,K,J)*DZ8W(I,K,J)
ENDDO
ENDDO
ENDDO
!
DO K=KMS,KME
KFLIP=KME+1-K
DO J=JTS,JTE
DO I=ITS,ITE
P8WFLIP(I,K,J)=PHYD(I,KFLIP,J)
ENDDO
ENDDO
ENDDO
!
!- Note that the effects of rain are ignored in this radiation package (BSF 2005-01-25)
!
DO K=KTS,KTE
KFLIP=KTE+1-K
DO J=JTS,JTE
DO I=ITS,ITE
TFLIP (I,K,J)=T(I,KFLIP,J)
QFLIP (I,K,J)=MAX(0.,QV(I,KFLIP,J)/(1.+QV(I,KFLIP,J)))
QWFLIP(I,K,J)=QW(I,KFLIP,J) !Modified
QIFLIP(I,K,J)=QI(I,KFLIP,J) !Added QI
! PFLIP (I,K,J)=P_PHY(I,KFLIP,J)
!
!*** USE MONOTONIC HYDROSTATIC PRESSURE INTERPOLATED TO MID-LEVEL
!
PFLIP(I,K,J)=0.5*(P8WFLIP(I,K,J)+P8WFLIP(I,K+1,J))
ENDDO
ENDDO
ENDDO
!
DO J=JTS,JTE
DO I=ITS,ITE
HBOTR(I,J)=HBOT(I,J)
HTOPR(I,J)=HTOP(I,J)
ENDDO
ENDDO
DO J=JTS,JTE
DO I=ITS,ITE
HBOT(I,J)=KTE+1-HBOT(I,J)
HTOP(I,J)=KTE+1-HTOP(I,J)
ENDDO
ENDDO
!
CALL CAL_MON_DAY(JULDAY,JULYR,JMONTH,JDAY)
!
IDAT(1)=JMONTH
IDAT(2)=JDAY
IDAT(3)=JULYR
IHRST =NINT(GMT)
! CALL SOLARD(R1,IHRST,IDAT)
! CALL SOLARD(R1,IHRST,JULDAY)
!-----------------------------------------------------------------------
CALL RADTN (DT,TFLIP,QFLIP,QWFLIP,QIFLIP, &
& PFLIP,P8WFLIP,XLAND,TSK2D, &
& GLAT,GLON,HTOP,HBOT,ALBEDO,cuppt, &
& .not.explicit_convection, &
& ACFRCV,NCFRCV,ACFRST,NCFRST, &
& VEGFRA,SNOW,GLW,GSW, &
& TOTSWDN,TOTLWDN, &
& IDAT,IHRST, &
& NSTEPRA,NSTEPRA,NPHS,ITIMESTEP, &
& TENDS,TENDL,RSWTOA,RLWTOA,CZMEAN, &
& CFRACL,CFRACM,CFRACH, &
& IDS,IDE,JDS,JDE,KDS,KDE, &
& IMS,IME,JMS,JME,KMS,KME, &
& ITS,ITE,JTS,JTE,KTS,KTE )
!-----------------------------------------------------------------------
!
IF(GFDL_LW)THEN
DO J=JTS,JTE
DO K = KTS,KTE
KFLIP=KTE+1-K
DO I=ITS,ITE
THRATENLW(I,K,J)=TENDL(I,KFLIP,J)/PI3D(I,K,J)
THRATENSW(I,K,J)=TENDS(I,KFLIP,J)/PI3D(I,K,J) !Put in SW section
THRATEN(I,K,J) =THRATEN(I,K,J) + THRATENLW(I,K,J)
ENDDO
ENDDO
ENDDO
ENDIF
!
!*** THIS ASSUMES THAT LONGWAVE IS CALLED FIRST IN THE RADIATION_DRIVER.
!
IF(GFDL_SW)THEN
DO J=JTS,JTE
DO K=KTS,KTE
KFLIP=KTE+1-K
DO I=ITS,ITE
THRATENSW(I,K,J)=TENDS(I,KFLIP,J)/PI3D(I,K,J)
!!! THRATEN(I,K,J)=THRATEN(I,K,J)+THRATENSW(I,K,J) !Added
ENDDO
ENDDO
ENDDO
ENDIF
!
!*** RESET ACCUMULATED CONVECTIVE CLOUD TOP/BOT AND CONVECTIVE PRECIP
!*** FOR NEXT INTERVAL BETWEEN RADIATION CALLS
!
DO J=JTS,JTE
DO I=ITS,ITE
!!!! HBOT(I,J)=KTE+1-HBOT(I,J)
!!!! HTOP(I,J)=KTE+1-HTOP(I,J)
HBOT(I,J)=REAL(KTE+1)
HTOP(I,J)=0.
CUPPT(I,J)=0.
ENDDO
ENDDO
!
100 IF(GFDL_SW)THEN
DO J=JTS,JTE
DO K=KTS,KTE
KFLIP=KTE+1-K
DO I=ITS,ITE
THRATEN(I,K,J)=THRATEN(I,K,J)+THRATENSW(I,K,J)
ENDDO
ENDDO
ENDDO
ENDIF
!
END SUBROUTINE HWRFRA
!
!-----------------------------------------------------------------------
SUBROUTINE RADTN(DT,T,Q,QCW,QICE, & 2,9
& PFLIP,P8WFLIP,XLAND,TSK2D, &
& GLAT,GLON,HTOP,HBOT,ALB,CUPPT,CNCLD, &
! & RAD1,RAD2,RAD3,RAD4, &
! & TABLE1,TABLE2,TABLE3,EM1,EM1WDE,EM3, &
& ACFRCV,NCFRCV,ACFRST,NCFRST, &
& VEGFRC,SNO,GLW,GSW, &
& RSWIN,RLWIN, & !Added
! & IDAT,LTOP,IHRST,PRGFDL, &
& IDAT,IHRST, &
& NRADS,NRADL,NPHS,NTSD, &
! & SKO3R,AB15WD,SKC1R,SKO2D, &
!#$ & TENDS,TENDL, &
& TENDS,TENDL,RSWTOA,RLWTOA,CZMEAN, &
& CFRACL,CFRACM,CFRACH, & !Added
& ids,ide, jds,jde, kds,kde, &
& ims,ime, jms,jme, kms,kme, &
& its,ite, jts,jte, kts,kte )
!-----------------------------------------------------------------------
IMPLICIT NONE
!-----------------------------------------------------------------------
! GLAT : geodetic latitude in radians of the mass points on the computational grid.
! CZEN : instantaneous cosine of the solar zenith angle.
! HTOP : (REAL) model layer number that is highest in the atmosphere
! in which convective cloud occurred since the previous call to the
! radiation driver.
! HBOT : (REAL) model layer number that is lowest in the atmosphere
! in which convective cloud occurred since the previous call to the
! radiation driver.
! ALB : is no longer used in the operational radiation. Prior to 24 July 2001
! ALB was the climatological albedo that was modified within RADTN to
! account for vegetation fraction and snow.
!
! ALB : reintroduced as the dynamic albedo from LSM
! CUPPT: accumulated convective precipitation (meters) since the
! last call to the radiation.
! THS : potential temperature of the ground surface.
! IHE and IHW are relative location indices needed to locate neighboring
! points on the Eta's Arakawa E grid since arrays are indexed locally on
! each MPI task rather than globally. IHE refers to the adjacent grid
! point (a V point) to the east of the mass point being considered. IHW
! is the adjacent grid point to the west of the given mass point.
! IRAD is a relic from older code that is no longer needed.
! ACFRCV : sum of the convective cloud fractions that were computed
! during each call to the radiation between calls to the subroutines that
! do the forecast output.
! NCFRCV : the total number of times in which the convective cloud
! fraction was computed to be greater than zero in the radiation between
! calls to the output routines. In the post-processor, ACFRCV is divided
! by NCFRCV to yield an average convective cloud fraction.
! ACFRST and NCFRST are the analogs for stratiform cloud cover.
! VEGFRC is the fraction of the gridbox with vegetation.
! LVL holds the number of model layers that lie below the ground surface
! at each point. Clearly for sigma coordinates LVL is zero everywhere.
! CTHK : an assumed maximum thickness of stratiform clouds currently set
! to 20000 Pascals. I think this is relevant for computing "low",
! "middle", and "high" cloud fractions which are post-processed but which
! do not feed back into the integration.
! IDAT : a 3-element integer array holding the month, day, and year,
! respectively, of the date for the start time of the free forecast.
! ABCFF : holds coefficients for various absorption bands. You can see
! where they are set in GFDLRD.F.
! LTOP : a 3-element integer array holding the model layer that is at or
! immediately below the specified pressure levels for the tops
! of "high" (15000 Pa), "middle" (35000 Pa), and "low" (64200 Pa)
! stratiform clouds. These are for the diagnostic cloud layers
! needed in the output but not in the integration.
! R1 : earth-sun distance in astronomical units.
! NRADS : integer number of fundamental timesteps (our smallest
! timestep, i.e., the one for inertial gravity wave adjustment)
! between updates of the shortwave tendencies. Currently we
! update the shortwave every hour.
! NRADL : integer number of fundamental timesteps between updates of
! the longwave tendencies. Currently we update the longwave
! every two hours.
! NTSD : integer counter of the fundamental timesteps that have
! elapsed since the start of the forecast.
!
!**********************************************************************
!****************************** NOTE **********************************
!**********************************************************************
!*** DUE TO THE RESETTING OF CONVECTIVE PRECIP AND CONVECTIVE CLOUD
!*** TOPS AND BOTTOMS, SHORTWAVE MUST NOT BE CALLED LESS FREQUENTLY
!*** THAN LONGWAVE.
!**********************************************************************
!****************************** NOTE **********************************
!**********************************************************************
!-----------------------------------------------------------------------
! INTEGER, PARAMETER :: NL=81
LOGICAL, INTENT(IN) :: cncld
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
& ims,ime, jms,jme, kms,kme , &
& its,ite, jts,jte, kts,kte
INTEGER, INTENT(IN) :: NRADS,NRADL,NTSD,NPHS
! LOGICAL, INTENT(IN) :: RESTRT
REAL , INTENT(IN) :: DT
! REAL , INTENT(IN), DIMENSION(37,NL) :: XDUO3N,XDO3N2,XDO3N3,XDO3N4
INTEGER, INTENT(IN), DIMENSION(3) :: IDAT
!-----------------------------------------------------------------------
REAL, PARAMETER :: CAPA=R_D/CP,DTR=3.1415926/180.
INTEGER :: LM1,LP1,LM
INTEGER, INTENT(IN) :: IHRST
! REAL, INTENT(IN), DIMENSION(NL) :: PRGFDL
!
REAL, PARAMETER :: ALPHA0=100.,CLFRMIN=0.1,CUPRATE=24.*1000., &
& EPS=R_D/R_V,EPSO3=1.E-10, &
& EPSQ=1.E-12,EPSQ1=1.E-5, &
& GAMMA=0.49,H0=0.,H1=1.,H69=-6.9,HPINC=1.E1, &
& PBOT=10000.0,PEXP=0.25, &
& QCLDMIN=EPSQ,RLAG=14.8125, &
& STBOL=STBOLT,T_ICE=-10.
!
INTEGER, PARAMETER :: NB=12,KSMUD=0
INTEGER,PARAMETER :: K15=SELECTED_REAL_KIND(15)
REAL (KIND=K15) :: DDX,EEX,PROD
! REAL, INTENT(IN) :: SKO3R,AB15WD,SKC1R,SKO2D
!-----------------------------------------------------------------------
LOGICAL :: SHORT,LONG
LOGICAL :: BITX,BITY,BITZ,BITW,BIT1,BIT2,BITC,BITS,BITCP1,BITSP1
LOGICAL :: NEW_CLOUD
!-----------------------------------------------------------------------
REAL, INTENT(IN), DIMENSION(ims:ime,jms:jme) :: XLAND,TSK2D
REAL, INTENT(IN), DIMENSION(its:ite, kms:kme, jts:jte):: Q,QCW, &
& QICE,T
REAL, INTENT(IN), DIMENSION(its:ite, kms:kme, jts:jte):: PFLIP, &
& P8WFLIP
! REAL, INTENT(IN), DIMENSION(28,180) :: TABLE1,TABLE2,TABLE3,EM3,EM1,EM1WDE
REAL, INTENT(OUT), DIMENSION(ims:ime, jms:jme):: GLW,GSW,CZMEAN &
& ,RSWIN,RLWIN & !Added
& ,CFRACL,CFRACM &
& ,CFRACH
! REAL, INTENT(IN), DIMENSION(kms:kme) :: ETAD
! REAL, INTENT(IN), DIMENSION(kms:kme) :: AETA
!-----------------------------------------------------------------------
REAL, INTENT(INOUT), DIMENSION(ims:ime,jms:jme) :: HTOP,HBOT
REAL, INTENT(IN ), DIMENSION(ims:ime,jms:jme) :: ALB,SNO
REAL, INTENT(IN ), DIMENSION(ims:ime,jms:jme) :: GLAT,GLON
!-----------------------------------------------------------------------
REAL, DIMENSION(ims:ime,jms:jme) :: CZEN
!#$ REAL, DIMENSION(its:ite,jts:jte) :: CZMEAN,SIGT4
REAL, DIMENSION(its:ite,jts:jte) :: SIGT4
INTEGER, DIMENSION(its:ite, jts:jte):: LMH
!-----------------------------------------------------------------------
REAL, INTENT(INOUT), DIMENSION(ims:ime,jms:jme) :: CUPPT
! REAL, DIMENSION(37*kte) :: RAD1,RAD2,RAD3,RAD4
!-----------------------------------------------------------------------
! INTEGER,INTENT(IN), DIMENSION(jms:jme) :: IHE,IHW
!-----------------------------------------------------------------------
REAL, INTENT(INOUT), DIMENSION(ims:ime,jms:jme) :: ACFRCV,ACFRST &
,RSWTOA,RLWTOA
INTEGER,INTENT(INOUT), DIMENSION(ims:ime,jms:jme) :: NCFRCV,NCFRST
!-----------------------------------------------------------------------
!#$ REAL, DIMENSION(its:ite,jts:jte) :: RLWIN,RLWOUT
REAL, DIMENSION(its:ite,jts:jte) :: RLWOUT
!-----------------------------------------------------------------------
REAL, INTENT(IN), DIMENSION(ims:ime,jms:jme) :: VEGFRC
REAL, INTENT(INOUT),DIMENSION(its:ite,kts:kte,jts:jte) :: TENDL,&
& TENDS
!#$ REAL, DIMENSION(its:ite,jts:jte) :: RSWIN,RSWOUT,RSWTOA
!#$ REAL, DIMENSION(its:ite,jts:jte) :: RSWIN,RSWOUT
REAL, DIMENSION(its:ite,jts:jte) :: RSWOUT
REAL, DIMENSION(its:ite,kts:kte,jts:jte):: RSWTT,RLWTT
!-----------------------------------------------------------------------
REAL :: CTHK(3)
DATA CTHK/20000.0,20000.0,20000.0/
REAL :: PTOPC(4)
REAL,DIMENSION(10),SAVE :: CC,PPT
!-----------------------------------------------------------------------
REAL,SAVE :: ABCFF(NB)
INTEGER,DIMENSION(its:ite,jts:jte) :: LVL
REAL, DIMENSION(its:ite, jts:jte):: PDSL,FNE,FSE,TL
REAL, DIMENSION( 0:kte) :: CLDAMT
REAL, DIMENSION(its:ite,3):: CLDCFR
INTEGER, DIMENSION(its:ite,3):: MBOT,MTOP
REAL, DIMENSION(its:ite) :: PSFC,TSKN,ALBEDO,XLAT,COSZ, &
& SLMSK,FLWUP, &
& FSWDN,FSWUP,FSWDNS,FSWUPS,FLWDNS, &
& FLWUPS
REAL, DIMENSION(its:ite,kts:kte) :: PMID,TMID
REAL, DIMENSION(its:ite,kts:kte) :: QMID,THMID,OZN,POZN
REAL, DIMENSION(its:ite,jts:jte) :: TOT
REAL, DIMENSION(its:ite,kts:kte+1) :: PINT,EMIS,CAMT
INTEGER,DIMENSION(its:ite,kts:kte+1) :: KBTM,KTOP
INTEGER,DIMENSION(its:ite) :: NCLDS,KCLD
REAL, DIMENSION(its:ite) :: TAUDAR
REAL, DIMENSION(its:ite,NB,kts:kte+1) ::RRCL,TTCL
REAL, DIMENSION(its:ite,kts:kte):: CSMID,CCMID,QWMID,QIMID
REAL,SAVE :: PLOMD,PMDHI,PHITP,P400,PLBTM
INTEGER,SAVE :: NFILE
!-----------------------------------------------------------------------
REAL :: CLSTP,TIME,DAYI,HOUR,ADDL,RANG,RSIN1,RCOS1,RCOS2
REAL :: TIMES,EXNER,APES,SNOFAC,CCLIMIT,CLIMIT,P1,P2,CC1,CC2
REAL :: PMOD,CLFR1,CTAU,WV,ARG,CLDMAX
REAL :: CL1,CL2,CR1,DPCL,QSUM,PRS1,PRS2,DELP,TCLD,DD,EE,AA,FF
REAL :: BB,GG,DENOM,FCTRA,FCTRB,PDSLIJ,CFRAVG,SNOMM
REAL :: TAUC,THICK,CONVPRATE,CLFR,ESAT,QSAT,RHUM,QCLD,RHGRID
INTEGER :: I,J,MYJS,MYJE,MYIS,MYIE,NTSPH,NRADPP,ITIMSW,ITIMLW, &
& JD,II
INTEGER :: L,N,LML,LVLIJ,IR,KNTLYR,LL,NC,L400,NMOD,LTROP,IWKL
INTEGER :: LCNVB,LCNVT
INTEGER :: NLVL,MALVL,LLTOP,LLBOT,KBT2,KTH1,KBT1,KTH2,KTOP1,KFLIP
INTEGER :: NBAND,NCLD,LBASE,NKTP,NBTM,KS,MYJS1,MYJS2,MYJE2,MYJE1
! REAL,DIMENSION(5040):: T1,T2,T4,EM1V,EM1VW,EM3V
! EQUIVALENCE (EM1V(1),EM1(1,1)),(EM1VW(1),EM1WDE(1,1))
! EQUIVALENCE (EM3V(1),EM3(1,1))
! EQUIVALENCE (T1(1),TABLE1(1,1)),(T2(1),TABLE2(1,1)), &
! (T4(1),TABLE3(1,1))
DATA PLOMD/64200./,PMDHI/35000./,PHITP/15000./,P400/40000./, &
PLBTM/105000./
DATA NFILE/14/
DATA CC/0.1,0.2,0.3,0.4,0.5,0.6,0.7,0.8,0.9,1.0/
DATA PPT/0.,.14,.31,.70,1.6,3.4,7.7,17.,38.,85./
DATA ABCFF/2*4.0E-5,.002,.035,.377,1.95,9.40,44.6,190.,989., &
& 2706.,39011./
!-----------------------------------------------------------------------
!***********************************************************************
!-----------------------------------------------------------------------
MYJS=jts
MYJE=jte
MYIS=its
MYIE=ite
MYJS1=jts !????
MYJE1=jte
MYJS2=jts
MYJE2=jte
LM=kte
LM1=LM-1
LP1=LM+1
! CNCLD=.TRUE.
!
DO J=JTS,JTE
DO I=ITS,ITE
LMH(I,J)=KME-1
LVL(I,J)=0
ENDDO
ENDDO
!***
!*** ASSIGN THE PRESSURES FOR CLOUD DOMAIN BOUNDARIES
!***
PTOPC(1)=PLBTM
PTOPC(2)=PLOMD
PTOPC(3)=PMDHI
PTOPC(4)=PHITP
!**********************************************************************
!*** THE FOLLOWING CODE IS EXECUTED EACH TIME THE RADIATION IS CALLED.
!**********************************************************************
!----------------------CONVECTION--------------------------------------
! NRADPP IS THE NUMBER OF TIME STEPS TO ACCUMULATE CONVECTIVE PRECIP
! FOR RADIATION
! NOTE: THIS WILL NOT WORK IF NRADS AND NRADL ARE DIFFERENT UNLESS
! THEY ARE INTEGER MULTIPLES OF EACH OTHER
! CLSTP IS THE NUMBER OF HOURS OF THE ACCUMULATION PERIOD
!
NTSPH=NINT(3600./DT)
NRADPP=MIN(NRADS,NRADL)
CLSTP=1.0*NRADPP/NTSPH
CONVPRATE=CUPRATE/CLSTP
!GFDL RHGRID=RHGRD
RHGRID=RHgrd_in !GFDL => simple right now w/o height-dependencies
!----------------------CONVECTION--------------------------------------
!***
!*** STATE WHETHER THE SHORT OR LONGWAVE COMPUTATIONS ARE TO BE DONE.
!***
SHORT=.TRUE.
LONG=.TRUE.
ITIMSW=0
ITIMLW=0
IF(SHORT)ITIMSW=1
IF(LONG) ITIMLW=1
!***
!*** FIND THE MEAN COSINE OF THE SOLAR ZENITH ANGLE
!*** BETWEEN THE CURRENT TIME AND THE NEXT TIME RADIATION IS
!*** CALLED. ONLY AVERAGE IF THE SUN IS ABOVE THE HORIZON.
!***
TIME=NTSD*DT
! CALL ZENITH(TIME,DAYI,HOUR)
!-----------------------------------------------------------------------
CALL ZENITH(TIME,DAYI,HOUR,IDAT,IHRST,GLON,GLAT,CZEN, &
& MYIS,MYIE,MYJS,MYJE, &
& ids,ide, jds,jde, kds,kde, &
& ims,ime, jms,jme, kms,kme, &
& its,ite, jts,jte, kts,kte )
!-----------------------------------------------------------------------
JD=INT(DAYI+0.50)
ADDL=0.
IF(MOD(IDAT(3),4).EQ.0)ADDL=1.
RANG=PI2*(DAYI-RLAG)/(365.25+ADDL)
RSIN1=SIN(RANG)
RCOS1=COS(RANG)
RCOS2=COS(2.*RANG)
!
!-----------------------------------------------------------------------
IF(SHORT)THEN
DO J=MYJS,MYJE
DO I=MYIS,MYIE
CZMEAN(I,J)=0.
TOT(I,J)=0.
ENDDO
ENDDO
!
DO II=0,NRADS,NPHS
TIMES=NTSD*DT+II*DT
CALL ZENITH(TIMES,DAYI,HOUR,IDAT,IHRST,GLON,GLAT,CZEN, &
& MYIS,MYIE,MYJS,MYJE, &
& ids,ide, jds,jde, kds,kde, &
& ims,ime, jms,jme, kms,kme, &
& its,ite, jts,jte, kts,kte )
DO J=MYJS,MYJE
DO I=MYIS,MYIE
IF(CZEN(I,J).GT.0.)THEN
CZMEAN(I,J)=CZMEAN(I,J)+CZEN(I,J)
TOT(I,J)=TOT(I,J)+1.
ENDIF
!
ENDDO
ENDDO
ENDDO
DO J=MYJS,MYJE
DO I=MYIS,MYIE
IF(TOT(I,J).GT.0.)CZMEAN(I,J)=CZMEAN(I,J)/TOT(I,J)
!
ENDDO
ENDDO
!
!*** MODIFY CZEN TO BE AT THE TOP OF THE HOUR.
!
! TIMES=NTSD*DT
! CALL ZENITH(TIMES,DAYI,HOUR,IDAT,IHRST,GLON,GLAT,CZEN, &
! & MYIS,MYIE,MYJS,MYJE, &
! & ids,ide, jds,jde, kds,kde, &
! & ims,ime, jms,jme, kms,kme, &
! & its,ite, jts,jte, kts,kte )
ENDIF
!-----------------------------------------------------------------------
!
!***********************************************************************
!*** THIS IS THE BEGINNING OF THE PRIMARY LOOP THROUGH THE DOMAIN
!***********************************************************************
! *********************
DO 700 J = MYJS, MYJE
! *********************
!
DO 125 L=1,LM
DO I=MYIS,MYIE
! IR=IRAD(I)
TMID(I,L)=T(I,1,J)
QMID(I,L)=EPSQ
QWMID(I,L)=0.
QIMID(I,L)=0.
CSMID(I,L)=0.
CCMID(I,L)=0.
OZN(I,L)=EPSO3
TENDS(I,L,J)=0.
TENDL(I,L,J)=0.
ENDDO
125 CONTINUE
!
DO 140 N=1,3
DO I=MYIS,MYIE
CLDCFR(I,N)=0.
MTOP(I,N)=0
MBOT(I,N)=0
ENDDO
140 CONTINUE
!***
!*** FILL IN WORKING ARRAYS WHERE VALUES AT L=LM ARE THOSE THAT
!*** ARE ACTUALLY AT ETA LEVEL L=LMH.
!***
DO 200 I=MYIS,MYIE
! IR=IRAD(I)
LML=LMH(I,J)
LVLIJ=LVL(I,J)
!
DO L=1,LML
PMID(I,L+LVLIJ)=PFLIP(I,L,J)
PINT(I,L+LVLIJ+1)=P8WFLIP(I,L+1,J)
EXNER=(1.E5/PMID(I,L+LVLIJ))**CAPA
TMID(I,L+LVLIJ)=T(I,L,J)
THMID(I,L+LVLIJ)=T(I,L,J)*EXNER
QMID(I,L+LVLIJ)=Q(I,L,J)
!--- Note that rain is ignored, only effects from cloud water and ice are considered
QWMID(I,L+LVLIJ)=QCW(I,L,J)
QIMID(I,L+LVLIJ)=QICE(I,L,J)
ENDDO
!***
!*** FILL IN ARTIFICIAL VALUES ABOVE THE TOP OF THE DOMAIN.
!*** PRESSURE DEPTHS OF THESE LAYERS IS 1 HPA.
!*** TEMPERATURES ABOVE ARE ALREADY ISOTHERMAL WITH (TRUE) LAYER 1.
!***
IF(LVLIJ.GT.0)THEN
KNTLYR=0
!
DO L=LVLIJ,1,-1
KNTLYR=KNTLYR+1
PMID(I,L)=P8WFLIP(I,1,J)-REAL(2*KNTLYR-1)*0.5*HPINC
PINT(I,L+1)=PMID(I,L)+0.5*HPINC
EXNER=(1.E5/PMID(I,L))**CAPA
THMID(I,L)=TMID(I,L)*EXNER
ENDDO
ENDIF
!
IF(LVLIJ.EQ.0) THEN
PINT(I,1)=P8WFLIP(I,1,J)
ELSE
PINT(I,1)=PMID(I,1)-0.5*HPINC
ENDIF
200 CONTINUE
!***
!*** FILL IN THE SURFACE PRESSURE, SKIN TEMPERATURE, GEODETIC LATITUDE,
!*** ZENITH ANGLE, SEA MASK, AND ALBEDO. THE SKIN TEMPERATURE IS
!*** NEGATIVE OVER WATER.
!***
DO 250 I=MYIS,MYIE
PSFC(I)=P8WFLIP(I,KME,J)
APES=(PSFC(I)*1.E-5)**CAPA
! TSKN(I)=THS(I,J)*APES*(1.-2.*SM(I,J))
IF((XLAND(I,J)-1.5).GT.0.)THEN
TSKN(I)=-TSK2D(I,J)
ELSE
TSKN(I)=TSK2D(I,J)
ENDIF
! TSKN(I)=THS(I,J)*APES*(1.-2.*(XLAND(I,J)-1.))
! SLMSK(I)=SM(I,J)
SLMSK(I)=XLAND(I,J)-1.
!
! SNO(I,J)=AMAX1(SNO(I,J),0.)
SNOMM=AMAX1(SNO(I,J),0.)
SNOFAC=AMIN1(SNOMM/0.02, 1.0)
!!!! ALBEDO(I)=ALB(I,J)+(1.0-0.01*VEGFRC(I,J))*SNOFAC*(SNOALB-ALB(I,J))
ALBEDO(I)=ALB(I,J)
!
XLAT(I)=GLAT(I,J)/DTR
COSZ(I)=CZMEAN(I,J)
250 CONTINUE
!-----------------------------------------------------------------------
!--- COMPUTE GRID-SCALE CLOUD COVER FOR RADIATION
! (modified by Ferrier, Feb '02)
!
!--- Cloud fraction parameterization follows Randall, 1994
! (see Hong et al., 1998)
!-----------------------------------------------------------------------
!
DO I=MYIS,MYIE
LML=LMH(I,J)
LVLIJ=LVL(I,J)
DO L=1,LML
LL=L+LVLIJ
!
!--- Water vapor mixing ratio
!
WV=QMID(I,LL)/(1.-QMID(I,LL))
!
!--- Saturation vapor pressure w/r/t water ( >=0C ) or ice ( <0C )
!
ESAT=1000.*FPVS(TMID(I,LL)) !--- Saturation vapor pressure (Pa)
QSAT=EPS*ESAT/(PMID(I,LL)-ESAT) !--- Saturation mixing ratio
RHUM=WV/QSAT !--- Relative humidity
!
!--- Total "cloud" mixing ratio, QCLD. Rain is not part of cloud,
! only cloud water + cloud ice + snow
!
QCLD=QWMID(I,LL)+QIMID(I,LL)
!
!--- Determine cloud fraction (modified from original algorithm)
!
IF (QCLD .LT. QCLDMIN) THEN
!
!--- Assume zero cloud fraction if there is no cloud mixing ratio
!
CLFR=H0
ELSEIF(RHUM.GE.RHGRID)THEN
!
!--- Assume cloud fraction of unity if near saturation and the cloud
! mixing ratio is at or above the minimum threshold
!
CLFR=H1
ELSE
!
!--- Adaptation of original algorithm (Randall, 1994; Zhao, 1995)
! modified based on assumed grid-scale saturation at RH=RHgrid.
!
DENOM=(RHGRID*QSAT-WV)**GAMMA
ARG=MAX(H69, -ALPHA0*QCLD/DENOM) ! <-- EXP(-6.9)=.001
CLFR=(RHUM/RHGRID)**PEXP*(1.-EXP(ARG))
!! ARG=-1000*QCLD/(RHUM-RHGRID)
!! ARG=MAX(ARG, ARGMIN)
!! CLFR=(RHUM/RHGRID)*(1.-EXP(ARG))
IF (CLFR .LT. .01) CLFR=0.
ENDIF !--- End IF (QCLD .LT. QCLDmin) ...
CSMID(I,LL)=MIN(H1,CLFR)
ENDDO !--- End DO L ...
ENDDO !--- End DO I ...
!***********************************************************************
!********************END OF STRATIFORM CLOUD SECTION********************
!***********************************************************************
!
!-----------------------------------------------------------------------
!--- COMPUTE CONVECTIVE CLOUD COVER FOR RADIATION
!
!--- The parameterization of Slingo (1987, QJRMS, Table 1, p. 904) is
! used for convective cloud fraction as a function of precipitation
! rate. Cloud fractions have been increased by 20% for each rainrate
! interval so that shallow, nonprecipitating convection is ascribed a
! constant cloud fraction of 0.1 (Ferrier, Feb '02).
!-----------------------------------------------------------------
!
IF (CNCLD) THEN
DO I=MYIS,MYIE
!
!*** CLOUD TOPS AND BOTTOMS COME FROM CUCNVC.
!*** CONVECTIVE CLOUDS NEED TO BE AT LEAST 2 MODEL LAYERS THICK.
!
IF (HBOT(I,J)-HTOP(I,J) .GT. 1.0) THEN
!--- Compute convective cloud fractions if appropriate (Ferrier, Feb '02)
CLFR=CC(1)
PMOD=CUPPT(I,J)*CONVPRATE
IF (PMOD .GT. PPT(1)) THEN
DO NC=1,10
IF(PMOD.GT.PPT(NC)) NMOD=NC
ENDDO
IF (NMOD .GE. 10) THEN
CLFR=CC(10)
ELSE
CC1=CC(NMOD)
CC2=CC(NMOD+1)
P1=PPT(NMOD)
P2=PPT(NMOD+1)
CLFR=CC1+(CC2-CC1)*(PMOD-P1)/(P2-P1)
ENDIF !--- End IF (NMOD .GE. 10) ...
CLFR=MIN(H1, CLFR)
ENDIF !--- End IF (PMOD .GT. PPT(1)) ...
!
!*** ADD LVL TO BE CONSISTENT WITH OTHER WORKING ARRAYS
!
LVLIJ=LVL(I,J)
LCNVT=NINT(HTOP(I,J))+LVLIJ
LCNVT=MIN(LM,LCNVT)
LCNVB=NINT(HBOT(I,J))+LVLIJ
LCNVB=MIN(LM,LCNVB)
!
DO LL=LCNVT,LCNVB
CCMID(I,LL)=CLFR
ENDDO
ENDIF !--- IF (HBOT(I,J)-HTOP(I,J) .GT. 1.0) ...
ENDDO !--- End DO I loop
ENDIF !--- End IF (CNCLD) ...
!*********************************************************************
!*****************END OF CONVECTIVE CLOUD SECTION*****************
!*********************************************************************
!***
!*** DETERMINE THE FRACTIONAL CLOUD COVERAGE FOR HIGH, MID
!*** AND LOW OF CLOUDS FROM THE CLOUD COVERAGE AT EACH LEVEL
!***
!*** NOTE: THIS IS FOR DIAGNOSTICS ONLY!!!
!***
!***
DO 500 I=MYIS,MYIE
!!
DO L=0,LM
CLDAMT(L)=0.
ENDDO
!!
!!*** NOW GOES LOW, MIDDLE, HIGH
!!
DO 480 NLVL=1,3
CLDMAX=0.
MALVL=LM
LLTOP=LM+1-LTOP(NLVL)+LVL(I,J)
!!***
!!*** GO TO THE NEXT CLOUD LAYER IF THE TOP OF THE CLOUD-TYPE IN
!!*** QUESTION IS BELOW GROUND OR IS IN THE LOWEST LAYER ABOVE GROUND.
!!***
IF(LLTOP.GE.LM)GO TO 480
!!
IF(NLVL.GT.1)THEN
LLBOT=LM+1-LTOP(NLVL-1)-1+LVL(I,J)
LLBOT=MIN(LLBOT,LM1)
ELSE
LLBOT=LM1
ENDIF
!!
DO 435 L=LLTOP,LLBOT
CLDAMT(L)=AMAX1(CSMID(I,L),CCMID(I,L))
IF(CLDAMT(L).GT.CLDMAX)THEN
MALVL=L
CLDMAX=CLDAMT(L)
ENDIF
435 CONTINUE
!!*********************************************************************
!! NOW, CALCULATE THE TOTAL CLOUD FRACTION IN THIS PRESSURE DOMAIN
!! USING THE METHOD DEVELOPED BY Y.H., K.A.C. AND A.K. (NOV., 1992).
!! IN THIS METHOD, IT IS ASSUMED THAT SEPERATED CLOUD LAYERS ARE
!! RADOMLY OVERLAPPED AND ADJACENT CLOUD LAYERS ARE MAXIMUM OVERLAPPED.
!! VERTICAL LOCATION OF EACH TYPE OF CLOUD IS DETERMINED BY THE THICKEST
!! CONTINUING CLOUD LAYERS IN THE DOMAIN.
!!*********************************************************************
CL1=0.0
CL2=0.0
KBT1=LLBOT
KBT2=LLBOT
KTH1=0
KTH2=0
!!
DO 450 LL=LLTOP,LLBOT
L=LLBOT-LL+LLTOP
BIT1=.FALSE.
CR1=CLDAMT(L)
BITX=(PINT(I,L).GE.PTOPC(NLVL+1)).AND. &
& (PINT(I,L).LT.PTOPC(NLVL)).AND. &
& (CLDAMT(L).GT.0.0)
BIT1=BIT1.OR.BITX
IF(.NOT.BIT1)GO TO 450
!!***
!!*** BITY=T: FIRST CLOUD LAYER; BITZ=T:CONSECUTIVE CLOUD LAYER
!!*** NOTE: WE ASSUME THAT THE THICKNESS OF EACH CLOUD LAYER IN THE
!!*** DOMAIN IS LESS THAN 200 MB TO AVOID TOO MUCH COOLING OR
!!*** HEATING. SO WE SET CTHK(NLVL)=200*E2. BUT THIS LIMIT MAY
!!*** WORK WELL FOR CONVECTIVE CLOUDS. MODIFICATION MAY BE
!!*** NEEDED IN THE FUTURE.
!!***
BITY=BITX.AND.(KTH2.LE.0)
BITZ=BITX.AND.(KTH2.GT.0)
!!
IF(BITY)THEN
KBT2=L
KTH2=1
ENDIF
!!
IF(BITZ)THEN
KTOP1=KBT2-KTH2+1
DPCL=PMID(I,KBT2)-PMID(I,KTOP1)
IF(DPCL.LT.CTHK(NLVL))THEN
KTH2=KTH2+1
ELSE
KBT2=KBT2-1
ENDIF
ENDIF
IF(BITX)CL2=AMAX1(CL2,CR1)
!!***
!!*** AT THE DOMAIN BOUNDARY OR SEPARATED CLD LAYERS, RANDOM OVERLAP.
!!*** CHOOSE THE THICKEST OR THE LARGEST FRACTION AMT AS THE CLD
!!*** LAYER IN THAT DOMAIN.
!!***
BIT2=.FALSE.
BITY=BITX.AND.(CLDAMT(L-1).LE.0.0.OR. &
PINT(I,L-1).LT.PTOPC(NLVL+1))
BITZ=BITY.AND.CL1.GT.0.0
BITW=BITY.AND.CL1.LE.0.0
BIT2=BIT2.OR.BITY
IF(.NOT.BIT2)GO TO 450
!!
IF(BITZ)THEN
KBT1=INT((CL1*KBT1+CL2*KBT2)/(CL1+CL2))
KTH1=INT((CL1*KTH1+CL2*KTH2)/(CL1+CL2))+1
CL1=CL1+CL2-CL1*CL2
ENDIF
!!
IF(BITW)THEN
KBT1=KBT2
KTH1=KTH2
CL1=CL2
ENDIF
!!
IF(BITY)THEN
KBT2=LLBOT
KTH2=0
CL2=0.0
ENDIF
450 CONTINUE
!
CLDCFR(I,NLVL)=AMIN1(1.0,CL1)
MTOP(I,NLVL)=MIN(KBT1,KBT1-KTH1+1)
MBOT(I,NLVL)=KBT1
480 CONTINUE
500 CONTINUE
!***
!*** SET THE UN-NEEDED TAUDAR TO ONE
!***
DO I=MYIS,MYIE
TAUDAR(I)=1.0
ENDDO
!----------------------------------------------------------------------
! NOW, CALCULATE THE CLOUD RADIATIVE PROPERTIES AFTER DAVIS (1982),
! HARSHVARDHAN ET AL (1987) AND Y.H., K.A.C. AND A.K. (1993).
!
! UPDATE: THE FOLLOWING PARTS ARE MODIFIED, AFTER Y.T.H. (1994), TO
! CALCULATE THE RADIATIVE PROPERTIES OF CLOUDS ON EACH MODEL
! LAYER. BOTH CONVECTIVE AND STRATIFORM CLOUDS ARE USED
! IN THIS CALCULATIONS.
!
! QINGYUN ZHAO 95-3-22
!
!----------------------------------------------------------------------
!
!***
!*** INITIALIZE ARRAYS FOR USES LATER
!***
DO 600 I=MYIS,MYIE
LML=LMH(I,J)
LVLIJ=LVL(I,J)
!
!***
!*** NOTE: LAYER=1 IS THE SURFACE, AND LAYER=2 IS THE FIRST CLOUD
!*** LAYER ABOVE THE SURFACE AND SO ON.
!***
EMIS(I,1)=1.0
KTOP(I,1)=LP1
KBTM(I,1)=LP1
CAMT(I,1)=1.0
KCLD(I)=2
!
DO NBAND=1,NB
RRCL(I,NBAND,1)=0.0
TTCL(I,NBAND,1)=1.0
ENDDO
!
DO 510 L=2,LP1
CAMT(I,L)=0.0
KTOP(I,L)=1
KBTM(I,L)=1
EMIS(I,L)=0.0
!
DO NBAND=1,NB
RRCL(I,NBAND,L)=0.0
TTCL(I,NBAND,L)=1.0
ENDDO
510 CONTINUE
!***
!*** NOW CALCULATE THE AMOUNT, TOP, BOTTOM AND TYPE OF EACH CLOUD LAYER
!*** CLOUD TYPE=1: STRATIFORM CLOUD
!*** TYPE=2: CONVECTIVE CLOUD
!*** WHEN BOTH CONVECTIVE AND STRATIFORM CLOUDS EXIST AT THE SAME POINT,
!*** SELECT CONVECTIVE CLOUD WITH THE HIGHER CLOUD FRACTION.
!*** CLOUD LAYERS ARE SEPARATED BY TOTAL ABSENCE OF CLOUDINESS.
!*** NOTE: THERE IS ONLY ONE CONVECTIVE CLOUD LAYER IN ONE COLUMN.
!*** KTOP AND KBTM ARE THE TOP AND BOTTOM OF EACH CLOUD LAYER IN TERMS
!*** OF MODEL LEVEL.
!***
NEW_CLOUD=.TRUE.
!
DO L=2,LML
LL=LML-L+1+LVLIJ !-- Model layer
CLFR=MAX(CCMID(I,LL),CSMID(I,LL)) !-- Cloud fraction in layer
CLFR1=MAX(CCMID(I,LL+1),CSMID(I,LL+1)) !-- Cloud fraction in lower layer
!-------------------
IF (CLFR .GE. CLFRMIN) THEN
!--- Cloud present at level
IF (NEW_CLOUD) THEN
!--- New cloud layer
IF(L==2.AND.CLFR1>=CLFRmin)THEN
KBTM(I,KCLD(I))=LL+1
CAMT(I,KCLD(I))=CLFR1
ELSE
KBTM(I,KCLD(I))=LL
CAMT(I,KCLD(I))=CLFR
ENDIF
NEW_CLOUD=.FALSE.
ELSE
!--- Existing cloud layer
CAMT(I,KCLD(I))=AMAX1(CAMT(I,KCLD(I)), CLFR)
ENDIF ! End IF (NEW_CLOUD .EQ. 0) ...
ELSE IF (CLFR1 .GE. CLFRMIN) THEN
!--- Cloud is not present at level but did exist at lower level, then ...
IF (L .EQ. 2) THEN
!--- For the case of ground fog
KBTM(I,KCLD(I))=LL+1
CAMT(I,KCLD(I))=CLFR1
ENDIF
KTOP(I,KCLD(I))=LL+1
NEW_CLOUD=.TRUE.
KCLD(I)=KCLD(I)+1
CAMT(I,KCLD(I))=0.0
ENDIF
!-------------------
ENDDO !--- End DO L loop
!***
!*** THE REAL NUMBER OF CLOUD LAYERS IS (THE FIRST IS THE GROUND;
!*** THE LAST IS THE SKY):
!***
NCLDS(I)=KCLD(I)-2
NCLD=NCLDS(I)
!***
!*** NOW CALCULATE CLOUD RADIATIVE PROPERTIES
!***
IF(NCLD.GE.1)THEN
!***
!*** NOTE: THE FOLLOWING CALCULATIONS, THE UNIT FOR PRESSURE IS MB!!!
!***
DO 580 NC=2,NCLD+1
!
TAUC=0.0 ! Total optical depth for each cloud layer
QSUM=0.0
NKTP=LP1
NBTM=0
BITX=CAMT(I,NC).GE.CLFRMIN
NKTP=MIN(NKTP,KTOP(I,NC))
NBTM=MAX(NBTM,KBTM(I,NC))
!
DO LL=NKTP,NBTM
IF(LL.GE.KTOP(I,NC).AND.LL.LE.KBTM(I,NC).AND.BITX)THEN
PRS1=PINT(I,LL)*0.01
PRS2=PINT(I,LL+1)*0.01
DELP=PRS2-PRS1
TCLD=TMID(I,LL)-273.16
QSUM=QSUM+QMID(I,LL)*DELP*(PRS1+PRS2) &
& /(120.1612*SQRT(TMID(I,LL)))
!
!--- The simple optical depth parameterization from eq. (1) of Harshvardhan
! et al. (1989, JAS, p. 1924; hereafter referred to as HRCD by authorship)
! is used for convective cloud properties with some simple changes.
!
!--- The optical depth Tau is Tau=CTau*DELP, where values of CTau are
! described below.
!
!--- For convection, assume simple optical depth coefficients of
! 1) CTau=0.16 for ice, assumed to be for T<=T_ICE (=-10C in GSMCOLUMN)
! This was referenced as "optically thick anvil associated with
! convection in
! 2) CTau=0.08 for water, assumed to be present for T>T_ICE
!
!--- For grid-scale processes in the absence of convection:
! 1) CTau=0.08*min(1., Qc/Q0) for cloud water, where
! Q0 is assumed to be the threshold mixing ratio for "thick anvils",
! as noted in the 2nd paragraph after eq. (1) in Harshvardhan et al.
! (1989). A value of Q0=0.1 g/kg is assumed based on experience w/
! cloud observations, and it is intended only to be a crude scaling
! factor for "order of magnitude" effects. The functional dependence
! on mixing ratio is based on Stephens (1978, JAS, p. 2124, eq. 7).
! 2) CTau=500*Qi for ice particles. This is based on the optical depth
! of snow. Prof. Q. Fu (U. Washington) provided the following eq.:
! Tau-1.5*SWP/(Res*RHOs)
! SWP is snow water path, Res is the snow effective radius, RHOs is
! the snow density. Based on derivations using Petch (1998, JAS, 1846-
! 1858) as a starting point, Res=1.5*Ds with Ds being the mean diameter
! of an exponential distribution of ice particles ("snow"). After some
! manipulation,
! Tau=CTau*DELP => CTau=CSTau*Qice, where
! CSTau=100./(G*Ds*RHOs) ~ 500 based on values of Ds and RHOs in the
! ice lookup tables (actually varies from 920 for Ds=.1 mm to ~520 for
! Ds>0.5 mm), and units of DELP in mb (must convert from Pascals).
! "Snow" (precipitating ice) is assumed because of it dominates over
! cloud ice in the scheme.
!
CTAU=0.
IF (CCMID(I,LL) .GE. CLFRMIN) THEN
!-- Crude convective cloud properties
IF (TCLD .GT. T_ICE) THEN
CTAU=0.08 !--- Cloud water
ELSE
CTAU=0.16 !--- Ice
ENDIF
ENDIF
!-- Crude grid-scale cloud properties
IF (CSMID(I,LL) .GE. CLFRMIN) &
& CTAU=CTAU+800.*QWMID(I,LL)+500.*QIMID(I,LL)
TAUC=TAUC+DELP*CTAU
ENDIF !--- End IF(LL.GE.KTOP(I,NC) ....
ENDDO !--- End DO LL
!
IF(BITX)EMIS(I,NC)=1.0-EXP(-0.75*TAUC)
!GFDL => should consider using this => IF(BITX)EMIS(I,NC)=1.0-EXP(-1.66*TAUC)
IF(QSUM.GE.EPSQ1)THEN
!
DO 570 NBAND=1,NB
IF(BITX)THEN
PROD=ABCFF(NBAND)*QSUM
DDX=TAUC/(TAUC+PROD)
EEX=1.0-DDX
IF(ABS(EEX).GE.1.E-8)THEN
DD=DDX
EE=EEX
FF=1.0-DD*0.85
AA=MIN(50.0,SQRT(3.0*EE*FF)*TAUC)
AA=EXP(-AA)
BB=FF/EE
GG=SQRT(BB)
DD=(GG+1.0)*(GG+1.0)-(GG-1.0)*(GG-1.0)*AA*AA
RRCL(I,NBAND,NC)=MAX(0.1E-5,(BB-1.0)*(1.0-AA*AA)/DD)
TTCL(I,NBAND,NC)=AMAX1(0.1E-5,4.0*GG*AA/DD)
ENDIF
ENDIF
570 CONTINUE
ENDIF
580 CONTINUE
!
ENDIF
!
600 CONTINUE
!*********************************************************************
!****************** COMPUTE OZONE AT MIDLAYERS *********************
!*********************************************************************
!
!*** MODIFY PRESSURES SO THAT THE ENTIRE COLUMN OF OZONE (TO 0 MB)
!*** IS INCLUDED IN THE MODEL COLUMN EVEN WHEN PT > 0 MB
!***
DO L=1,LM
DO I=MYIS,MYIE
DENOM=1./(PINT(I,LP1)-PINT(I,1))
FCTRA=PINT(I,LP1)*DENOM
FCTRB=-PINT(I,1)*PINT(I,LP1)*DENOM
POZN(I,L)=PMID(I,L)*FCTRA+FCTRB
ENDDO
ENDDO
!
CALL OZON2D(LM,POZN,XLAT,RSIN1,RCOS1,RCOS2,OZN, &
! XDUO3N,XDO3N4,XDO3N2,XDO3N3, &
! PRGFDL,MYIS,MYIE, &
MYIS,MYIE, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!
!***
!*** NOW THE VARIABLES REQUIRED BY RADFS HAVE BEEN CALCULATED.
!***
!----------------------------------------------------------------------
!***
!*** CALL THE GFDL RADIATION DRIVER
!***
!***
CALL RADFS &
& (PSFC,PMID,PINT,QMID,TMID,OZN,TSKN,SLMSK,ALBEDO,XLAT &
&, CAMT,KTOP,KBTM,NCLDS,EMIS,RRCL,TTCL &
&, COSZ,TAUDAR,1 &
&, 1,0 &
&, ITIMSW,ITIMLW,JD,HOUR &
&, TENDS(ITS,KTS,J),TENDL(ITS,KTS,J) &
&, FLWUP,FSWUP,FSWDN,FSWDNS,FSWUPS,FLWDNS,FLWUPS &
&, ids,ide, jds,jde, kds,kde &
&, ims,ime, jms,jme, kms,kme &
&, its,ite, jts,jte, kts,kte )
!----------------------------------------------------------------------
IF(LONG)THEN
DO I=MYIS,MYIE
GLW(I,J)=FLWDNS(I)
ENDDO
ENDIF
!
IF(SHORT)THEN
DO I=MYIS,MYIE
GSW(I,J)=FSWDNS(I)-FSWUPS(I)
ENDDO
ENDIF
!
DO 650 I=MYIS,MYIE
CFRACL(I,J)=CLDCFR(I,1)
CFRACM(I,J)=CLDCFR(I,2)
CFRACH(I,J)=CLDCFR(I,3)
!
!*** ARRAYS ACFRST AND ACFRCV ACCUMULATE AVERAGE STRATIFORM AND
!*** CONVECTIVE CLOUD FRACTIONS, RESPECTIVELY.
!*** ACCUMLATE THESE VARIABLES ONLY ONCE PER RADIATION CALL.
!
!*** ASSUME RANDOM OVERLAP BETWEEN LOW, MIDDLE, & HIGH LAYERS.
!
CFRAVG=1.-(1.-CFRACL(I,J))*(1.-CFRACM(I,J))*(1.-CFRACH(I,J))
!
IF(CNCLD)THEN
IF(HBOT(I,J)-HTOP(I,J).GT.1.)THEN
!--- Count locations with convective cloudiness
ACFRST(I,J)=ACFRST(I,J)+CFRAVG
NCFRST(I,J)=NCFRST(I,J)+1
ENDIF
BITS=.FALSE.
DO LL=1,LM
BITS=CSMID(I,LL).GE.CLFRMIN !--- Existence of grid-scale cloud in layer
IF(BITS)EXIT
ENDDO
IF(BITS)THEN
!--- Count locations with grid-scale cloudiness
ACFRST(I,J)=ACFRST(I,J)+CFRAVG
NCFRST(I,J)=NCFRST(I,J)+1
ENDIF
ELSE
!--- Count only locations with grid-scale cloudiness
ACFRCV(I,J)=ACFRCV(I,J)+CFRAVG
NCFRCV(I,J)=NCFRCV(I,J)+1
ENDIF
650 CONTINUE
!***
!*** COLLECT ATMOSPHERIC TEMPERATURE TENDENCIES DUE TO RADIATION.
!*** ALSO COLLECT THE TOTAL SW AND INCOMING LW RADIATION (W/M**2)
!*** AND CONVERT TO FORM NEEDED FOR PREDICTION OF THS IN SURFCE.
!***
DO 660 I=MYIS,MYIE
DO L=1,LM
LL=LVL(I,J)+L
IF(SHORT)RSWTT(I,L,J)=TENDS(I,LL,J)
IF(LONG) RLWTT(I,L,J)=TENDL(I,LL,J)
IF(LL.EQ.LM)GO TO 660
ENDDO
660 CONTINUE
!***
!*** SUM THE LW INCOMING AND SW RADIATION (W/M**2) FOR RADIN.
!***
DO 675 I=MYIS,MYIE
IF(LONG)THEN
SIGT4(I,J)=STBOL*TMID(I,LM)*TMID(I,LM)* &
TMID(I,LM)*TMID(I,LM)
ENDIF
!
!*** ACCUMULATE VARIOUS LW AND SW RADIATIVE FLUXES FOR POST
!*** PROCESSOR. PASSED VIA COMMON ACMRDL AND ACMRDS.
!
IF(LONG)THEN
RLWIN(I,J) =FLWDNS(I)
RLWOUT(I,J)=FLWUPS(I)
RLWTOA(I,J)=FLWUP(I)
ENDIF
IF(SHORT)THEN
RSWIN(I,J) =FSWDNS(I)
RSWOUT(I,J)=FSWUPS(I)
RSWTOA(I,J)=FSWUP(I)
ENDIF
675 CONTINUE
!***
!*** THIS ROW IS FINISHED. GO TO NEXT
!***
! *********************
700 CONTINUE
! *********************
!----------------------------------------------------------------------
!***
!*** CALLS TO RADIATION THIS TIME STEP ARE COMPLETE.
!***
!----------------------------------------------------------------------
!----------------------------------------------------------------------
!***
!*** HORIZONTAL SMOOTHING OF TEMPERATURE TENDENCIES
!***
!----------------------------------------------------------------------
IF(SHORT) THEN
DO 800 L=1,LM
! CALL ZERO2(TL, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
! CALL ZERO2(FNE, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
! CALL ZERO2(FSE, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
!
! IF(KSMUD.GE.1)THEN
! DO 750 KS=1,KSMUD
!!
! DO J=MYJS,MYJE
! DO I=MYIS,MYIE
! TL(I,J)=RSWTT(I,L,J)
!! TL(I,J)=RSWTT(I,L,J)*HTM(I,L,J)
! ENDDO
! ENDDO
!!
! DO J=MYJS,MYJE
! DO I=MYIS,MYIE
! FNE(I,J)=(TL(I+IHE(J),J+1)-TL(I,J))
!! *HTM(I,L,J)*HTM(I+IHE(J),J+1,L)
! ENDDO
! ENDDO
!!
! DO J=MYJS1,MYJE
! DO I=MYIS,MYIE
! FSE(I,J)=(TL(I+IHE(J),J-1)-TL(I,J))
!! *HTM(I+IHE(J),J-1,L)*HTM(I,L,J)
! ENDDO
! ENDDO
!!
! DO J=MYJS2,MYJE2
! DO I=MYIS,MYIE
! TL(I,J)=(FNE(I,J)-FNE(I+IHW(J),J-1) &
! +FSE(I,J)-FSE(I+IHW(J),J+1)) &
! *0.125+TL(I,J)
!! *HBM2(I,J)*0.125+TL(I,J)
! ENDDO
! ENDDO
!!
! DO J=MYJS,MYJE
! DO I=MYIS,MYIE
! RSWTT(I,L,J)=TL(I,J)
! ENDDO
! ENDDO
!!
! 750 CONTINUE
! ENDIF
!
800 CONTINUE
ENDIF
!----------------------------------------------------------------------
!
IF(LONG)THEN
!
DO 900 L=1,LM
! CALL ZERO2(TL, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
! CALL ZERO2(FNE, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
! CALL ZERO2(FSE, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
!
! IF(KSMUD.GE.1)THEN
! DO 850 KS=1,KSMUD
!!
! DO J=MYJS,MYJE
! DO I=MYIS,MYIE
! TL(I,J)=RLWTT(I,L,J)
!! TL(I,J)=RLWTT(I,L,J)*HTM(I,L,J)
! ENDDO
! ENDDO
!!
! DO J=MYJS,MYJE1
! DO I=MYIS,MYIE
! FNE(I,J)=(TL(I+IHE(J),J+1)-TL(I,J))
!! *HTM(I,L,J)*HTM(I+IHE(J),J+1,L)
! ENDDO
! ENDDO
!!
! DO J=MYJS1,MYJE
! DO I=MYIS,MYIE
! FSE(I,J)=(TL(I+IHE(J),J-1)-TL(I,J))
!! *HTM(I+IHE(J),J-1,L)*HTM(I,L,J)
! ENDDO
! ENDDO
!!
! DO J=MYJS2,MYJE2
! DO I=MYIS,MYIE
! TL(I,J)=(FNE(I,J)-FNE(I+IHW(J),J-1) &
! +FSE(I,J)-FSE(I+IHW(J),J+1)) &
! *0.125+TL(I,J)
!! *HBM2(I,J)*0.125+TL(I,J)
! ENDDO
! ENDDO
!!
! DO J=MYJS,MYJE
! DO I=MYIS,MYIE
! RLWTT(I,L,J)=TL(I,J)
! ENDDO
! ENDDO
!!
! 850 CONTINUE
! ENDIF
900 CONTINUE
ENDIF
!----------------------------------------------------------------------
END SUBROUTINE RADTN
!----------------------------------------------------------------------
SUBROUTINE ZENITH(TIMES,DAYI,HOUR,IDAT,IHRST,GLON,GLAT,CZEN, & 6
MYIS,MYIE,MYJS,MYJE, &
IDS,IDE, JDS,JDE, KDS,KDE, &
IMS,IME, JMS,JME, KMS,KME, &
ITS,ITE, JTS,JTE, KTS,KTE)
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: IDS,IDE, JDS,JDE, KDS,KDE , &
IMS,IME, JMS,JME, KMS,KME , &
ITS,ITE, JTS,JTE, KTS,KTE
INTEGER, INTENT(IN) :: MYJS,MYJE,MYIS,MYIE
REAL, INTENT(IN) :: TIMES
REAL, INTENT(OUT) :: HOUR,DAYI
INTEGER, INTENT(IN) :: IHRST
INTEGER, INTENT(IN), DIMENSION(3) :: IDAT
REAL, INTENT(IN), DIMENSION(IMS:IME,JMS:JME) :: GLAT,GLON
REAL, INTENT(OUT), DIMENSION(IMS:IME,JMS:JME) :: CZEN
REAL, PARAMETER :: GSTC1=24110.54841,GSTC2=8640184.812866, &
GSTC3=9.3104E-2,GSTC4=-6.2E-6, &
PI=3.1415926,PI2=2.*PI,PIH=0.5*PI, &
!#$ DEG2RD=1.745329E-2,OBLIQ=23.440*DEG2RD, &
DEG2RD=3.1415926/180.,OBLIQ=23.440*DEG2RD, &
ZEROJD=2451545.0
REAL :: DAY,YFCTR,ADDDAY,STARTYR,DATJUL,DIFJD,SLONM, &
ANOM,SLON,DEC,RA,DATJ0,TU,STIM0,SIDTIM,HRANG
REAL :: HRLCL,SINALT
INTEGER :: KMNTH,KNT,IDIFYR,J,I
LOGICAL :: LEAP
!-----------------------------------------------------------------------
!-----------------------------------------------------------------------
INTEGER :: MONTH (12)
!-----------------------------------------------------------------------
DATA MONTH/31,28,31,30,31,30,31,31,30,31,30,31/
!***********************************************************************
! SAVE MONTH
DAY=0.
LEAP=.FALSE.
IF(MOD(IDAT(3),4).EQ.0)THEN
MONTH(2)=29
LEAP=.TRUE.
ENDIF
IF(IDAT(1).GT.1)THEN
KMNTH=IDAT(1)-1
DO 10 KNT=1,KMNTH
DAY=DAY+REAL(MONTH(KNT))
10 CONTINUE
ENDIF
!***
!*** CALCULATE EXACT NUMBER OF DAYS FROM BEGINNING OF YEAR TO
!*** FORECAST TIME OF INTEREST
!***
DAY=DAY+REAL(IDAT(2)-1)+(REAL(IHRST)+TIMES/3600.)/24.
DAYI=REAL(INT(DAY)+1)
HOUR=(DAY-DAYI+1.)*24.
YFCTR=2000.-IDAT(3)
!-----------------------------------------------------------------------
!***
!*** FIND CELESTIAL LONGITUDE OF THE SUN THEN THE SOLAR DECLINATION AND
!*** RIGHT ASCENSION.
!***
!-----------------------------------------------------------------------
IDIFYR=IDAT(3)-2000
!***
!*** FIND JULIAN DATE OF START OF THE RELEVANT YEAR
!*** ADDING IN LEAP DAYS AS NEEDED
!***
IF(IDIFYR.LT.0)THEN
ADDDAY=REAL(IDIFYR/4)
ELSE
ADDDAY=REAL((IDIFYR+3)/4)
ENDIF
STARTYR=ZEROJD+IDIFYR*365.+ADDDAY-0.5
!***
!*** THE JULIAN DATE OF THE TIME IN QUESTION
!***
DATJUL=STARTYR+DAY
!
!*** DIFFERENCE OF ACTUAL JULIAN DATE FROM JULIAN DATE
!*** AT 00H 1 January 2000
!
DIFJD=DATJUL-ZEROJD
!
!*** MEAN GEOMETRIC LONGITUDE OF THE SUN
!
SLONM=(280.460+0.9856474*DIFJD)*DEG2RD+YFCTR*PI2
!
!*** THE MEAN ANOMOLY
!
ANOM=(357.528+0.9856003*DIFJD)*DEG2RD
!
!*** APPARENT GEOMETRIC LONGITUDE OF THE SUN
!
SLON=SLONM+(1.915*SIN(ANOM)+0.020*SIN(2.*ANOM))*DEG2RD
IF(SLON.GT.PI2)SLON=SLON-PI2
!
!*** DECLINATION AND RIGHT ASCENSION
!
DEC=ASIN(SIN(SLON)*SIN(OBLIQ))
RA=ACOS(COS(SLON)/COS(DEC))
IF(SLON.GT.PI)RA=PI2-RA
!***
!*** FIND THE GREENWICH SIDEREAL TIME THEN THE LOCAL SOLAR
!*** HOUR ANGLE.
!***
DATJ0=STARTYR+DAYI-1.
TU=(DATJ0-2451545.)/36525.
STIM0=GSTC1+GSTC2*TU+GSTC3*TU**2+GSTC4*TU**3
SIDTIM=STIM0/3600.+YFCTR*24.+1.00273791*HOUR
SIDTIM=SIDTIM*15.*DEG2RD
IF(SIDTIM.LT.0.)SIDTIM=SIDTIM+PI2
IF(SIDTIM.GT.PI2)SIDTIM=SIDTIM-PI2
HRANG=SIDTIM-RA
!
DO 100 J=MYJS,MYJE
DO 100 I=MYIS,MYIE
! HRLCL=HRANG-GLON(I,J)
HRLCL=HRANG+GLON(I,J)+PI2
!***
!*** THE ZENITH ANGLE IS THE COMPLEMENT OF THE ALTITUDE THUS THE
!*** COSINE OF THE ZENITH ANGLE EQUALS THE SINE OF THE ALTITUDE.
!***
SINALT=SIN(DEC)*SIN(GLAT(I,J))+COS(DEC)*COS(HRLCL)* &
COS(GLAT(I,J))
IF(SINALT.LT.0.)SINALT=0.
CZEN(I,J)=SINALT
100 CONTINUE
!***
!*** IF THE FORECAST IS IN A DIFFERENT YEAR THAN THE START TIME,
!*** RESET DAYI TO THE PROPER DAY OF THE NEW YEAR (IT MUST NOT BE
!*** RESET BEFORE THE SOLAR ZENITH ANGLE IS COMPUTED).
!***
IF(DAYI.GT.365.)THEN
IF(.NOT.LEAP)THEN
DAYI=DAYI-365.
ELSEIF(LEAP.AND.DAYI.GT.366.)THEN
DAYI=DAYI-366.
ENDIF
ENDIF
!
END SUBROUTINE ZENITH
!-----------------------------------------------------------------------
SUBROUTINE OZON2D (LK,POZN,XLAT,RSIN1,RCOS1,RCOS2,QO3, & 2
! XDUO3N,XDO3N4,XDO3N2,XDO3N3, &
! PRGFDL,MYIS,MYIE, &
MYIS,MYIE, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
INTEGER, INTENT(IN) :: LK,MYIS,MYIE
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte) :: POZN
REAL, INTENT(IN), DIMENSION(its:ite) :: XLAT
REAL, INTENT(INOUT), DIMENSION(its:ite,kts:kte) :: QO3
REAL, INTENT(IN) :: RSIN1,RCOS1,RCOS2
!----------------------------------------------------------------------
INTEGER, PARAMETER :: NL=81,NLP1=NL+1,LNGTH=37*NL
REAL, PARAMETER :: RTD=57.2957795
! REAL, INTENT(IN), DIMENSION(37,NL) :: XDUO3N,XDO3N4,XDO3N2,XDO3N3
! REAL, INTENT(IN), DIMENSION(NL) :: PRGFDL
!----------------------------------------------------------------------
!----------------------------------------------------------------------
INTEGER,DIMENSION(its:ite) :: JJROW
REAL, DIMENSION(its:ite) :: TTHAN
REAL, DIMENSION(its:ite,NL) :: QO3O3
INTEGER :: I,K,NUMITR,ILOG,IT,NHALF
REAL :: TH2,DO3V,DO3VP,APHI,APLO
!----------------------------------------------------------------------
DO I=MYIS,MYIE
TH2=0.2*XLAT(I)
JJROW(I)=19.001-TH2
TTHAN(I)=(19-JJROW(I))-TH2
ENDDO
!
!*** SEASONAL AND SPATIAL INTERPOLATION DONE BELOW.
!
DO K=1,NL
DO I=MYIS,MYIE
DO3V=XDUO3N(JJROW(I),K)+RSIN1*XDO3N2(JJROW(I),K) &
+RCOS1*XDO3N3(JJROW(I),K) &
+RCOS2*XDO3N4(JJROW(I),K)
DO3VP=XDUO3N(JJROW(I)+1,K)+RSIN1*XDO3N2(JJROW(I)+1,K) &
+RCOS1*XDO3N3(JJROW(I)+1,K) &
+RCOS2*XDO3N4(JJROW(I)+1,K)
!
!*** NOW LATITUDINAL INTERPOLATION
!*** AND CONVERT O3 INTO MASS MIXING RATIO (ORIG DATA MPY BY 1.E4)
!
QO3O3(I,K)=1.E-4*(DO3V+TTHAN(I)*(DO3VP-DO3V))
ENDDO
ENDDO
!***
!*** VERTICAL INTERPOLATION FOR EACH GRIDPOINT (LINEAR IN LN P)
!***
NUMITR=0
ILOG=NL
20 CONTINUE
ILOG=(ILOG+1)/2
IF(ILOG.EQ.1)GO TO 25
NUMITR=NUMITR+1
GO TO 20
25 CONTINUE
!
DO 60 K=1,LK
!
NHALF=(NL+1)/2
DO I=MYIS,MYIE
JJROW(I)=NHALF
ENDDO
!
DO 40 IT=1,NUMITR
NHALF=(NHALF+1)/2
DO I=MYIS,MYIE
IF(POZN(I,K).LT.PRGFDL(JJROW(I)-1))THEN
JJROW(I)=JJROW(I)-NHALF
ELSEIF(POZN(I,K).GE.PRGFDL(JJROW(I)))THEN
JJROW(I)=JJROW(I)+NHALF
ENDIF
JJROW(I)=MIN(JJROW(I),NL)
JJROW(I)=MAX(JJROW(I),2)
ENDDO
40 CONTINUE
!
DO 50 I=MYIS,MYIE
IF(POZN(I,K).LT.PRGFDL(1))THEN
QO3(I,K)=QO3O3(I,1)
ELSE IF(POZN(I,K).GT.PRGFDL(NL))THEN
QO3(I,K)=QO3O3(I,NL)
ELSE
APLO=ALOG(PRGFDL(JJROW(I)-1))
APHI=ALOG(PRGFDL(JJROW(I)))
QO3(I,K)=QO3O3(I,JJROW(I))+(ALOG(POZN(I,K))-APHI)/ &
(APLO-APHI)* &
(QO3O3(I,JJROW(I)-1)-QO3O3(I,JJROW(I)))
ENDIF
50 CONTINUE
!
60 CONTINUE
END SUBROUTINE OZON2D
!-----------------------------------------------------------------------
! SUBROUTINE ZERO2(ARRAY, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
!----------------------------------------------------------------------
!IMPLICIT NONE
!----------------------------------------------------------------------
! INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
! ims,ime, jms,jme, kms,kme , &
! its,ite, jts,jte, kts,kte
! REAL, INTENT(INOUT), DIMENSION(its:ite,jts:jte) :: ARRAY
! INTEGER :: I,J
!----------------------------------------------------------------------
! DO J=jts,jte
! DO I=its,ite
! ARRAY(I,J)=0.
! ENDDO
! ENDDO
! END SUBROUTINE ZERO2
!----------------------------------------------------------------
SUBROUTINE O3INT(PHALF,DDUO3N,DDO3N2,DDO3N3,DDO3N4, & 2
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
!$$$ SUBPROGRAM DOCUMENTATION BLOCK
! . . . .
! SUBPROGRAM: O3INT COMPUTE ZONAL MEAN OZONE FOR ETA LYRS
! PRGMMR: KENNETH CAMPANA ORG: W/NMC23 DATE: 89-07-07
! MICHAEL BALDWIN ORG: W/NMC22 DATE: 92-06-08
!
! ABSTRACT: THIS CODE WRITTEN AT GFDL...
! CALCULATES SEASONAL ZONAL MEAN OZONE,EVERY 5 DEG OF LATITUDE,
! FOR CURRENT MODEL VERTICAL COORDINATE. OUTPUT DATA IN G/G * 1.E4
! CODE IS CALLED ONLY ONCE.
!
! PROGRAM HISTORY LOG:
! 84-01-01 FELS AND SCHWARZKOPF,GFDL.
! 89-07-07 K. CAMPANA - ADAPTED STAND-ALONE CODE FOR IN-LINE USE.
! 92-06-08 M. BALDWIN - UPDATE TO RUN IN ETA MODEL
!
! USAGE: CALL O3INT(O3,SIGL) OLD
! INPUT ARGUMENT LIST:
! PHALF - MID LAYER PRESSURE (K=LM+1 IS MODEL SURFACE)
! OUTPUT ARGUMENT LIST:
! DDUO3N - ZONAL MEAN OZONE DATA IN ALL MODEL LAYERS (G/G*1.E4)
! DDO3N2 DIMENSIONED(L,N),WHERE L(=37) IS LATITUDE BETWEEN
! DDO3N3 N AND S POLES,N=NUM OF VERTICAL LYRS(K=1 IS TOP LYR)
! DDO3N4 AND SEASON-WIN,SPR,SUM,FALL.
! IN COMMON
!
! OUTPUT FILES:
! OUTPUT - PRINT FILE.
!
! ATTRIBUTES:
! LANGUAGE: FORTRAN 200.
!
!$$$
!.... PROGRAM O3INT FROM DAN SCHWARZKOPF-GETS ZONAL MEAN O3
!.. OUTPUT O3 IS WINTER,SPRING,SUMMER,FALL (NORTHERN HEMISPHERE)
!-----------------------------------------------------------------------
! INCLUDE "parmeta"
!-----------------------------------------------------------------------
! *********************************************************
INTEGER :: N,NP,NP2,NM1
! PARAMETER (N=LM,NP=N+1,NP2=N+2,NM1=N-1)
! *********************************************************
!-----------------------------------------------------------------------
!***
!*** SEASONAL CLIMATOLOGIES OF O3 (OBTAINED FROM A PREVIOUSLY RUN
!*** CODE WHICH INTERPOLATES O3 TO USER VERTICAL COORDINATE).
!*** DEFINED AS 5 DEG LAT MEANS N.P.->S.P.
!***
REAL, INTENT(OUT), DIMENSION(37,kte):: DDUO3N,DDO3N2,DDO3N3,DDO3N4
! C O M M O N /SAVMEM/
! ...WINTER.... ...SPRING.... ...SUMMER.... ....FALL.....
! 1 DDUO3N(37,LM), DDO3N2(37,LM), DDO3N3(37,LM), DDO3N4(37,LM)
! ..... K.CAMPANA OCTOBER 1988
!CCC DIMENSION T41(NP2,2),O3O3(37,N,4)
! DIMENSION SIGL(N)
! *********************************************************
REAL :: QI(82)
REAL :: DDUO3(19,kts:kte),RO31(10,41),RO32(10,41),DUO3N(19,41)
REAL :: TEMPN(19)
REAL :: O3HI(10,25),O3LO1(10,16),O3LO2(10,16),O3LO3(10,16), &
O3LO4(10,16)
REAL :: O3HI1(10,16),O3HI2(10,9),PH1(45),PH2(37),P1(48),P2(33)
REAL :: O35DEG(37,kts:kte)
REAL :: RSTD(81),RO3(10,41),RO3M(10,40),RBAR(kts:kte),RDATA(81), &
PHALF(kts:kte+1),P(81),PH(82)
INTEGER :: NKK,NK,NKP,K,L,NCASE,ITAPE,IPLACE,NKMM,NKM,KI,KK,KQ,JJ,KEN
REAL :: O3RD,O3TOT,O3DU
EQUIVALENCE (O3HI1(1,1),O3HI(1,1)),(O3HI2(1,1),O3HI(1,17))
EQUIVALENCE (PH1(1),PH(1)),(PH2(1),PH(46))
EQUIVALENCE (P1(1),P(1)),(P2(1),P(49))
DATA PH1/ 0., &
0.1027246E-04, 0.1239831E-04, 0.1491845E-04, 0.1788053E-04, &
0.2135032E-04, 0.2540162E-04, 0.3011718E-04, 0.3558949E-04, &
0.4192172E-04, 0.4922875E-04, 0.5763817E-04, 0.6729146E-04, &
0.7834518E-04, 0.9097232E-04, 0.1053635E-03, 0.1217288E-03, &
0.1402989E-03, 0.1613270E-03, 0.1850904E-03, 0.2119495E-03, &
0.2423836E-03, 0.2768980E-03, 0.3160017E-03, 0.3602623E-03, &
0.4103126E-03, 0.4668569E-03, 0.5306792E-03, 0.6026516E-03, &
0.6839018E-03, 0.7759249E-03, 0.8803303E-03, 0.9987843E-03, &
0.1133178E-02, 0.1285955E-02, 0.1460360E-02, 0.1660001E-02, &
0.1888764E-02, 0.2151165E-02, 0.2452466E-02, 0.2798806E-02, &
0.3197345E-02, 0.3656456E-02, 0.4185934E-02, 0.4797257E-02/
DATA PH2/ &
0.5503893E-02, 0.6321654E-02, 0.7269144E-02, 0.8368272E-02, &
0.9644873E-02, 0.1112946E-01, 0.1285810E-01, 0.1487354E-01, &
0.1722643E-01, 0.1997696E-01, 0.2319670E-01, 0.2697093E-01, &
0.3140135E-01, 0.3660952E-01, 0.4274090E-01, 0.4996992E-01, &
0.5848471E-01, 0.6847525E-01, 0.8017242E-01, 0.9386772E-01, &
0.1099026E+00, 0.1286765E+00, 0.1506574E+00, 0.1763932E+00, &
0.2065253E+00, 0.2415209E+00, 0.2814823E+00, 0.3266369E+00, &
0.3774861E+00, 0.4345638E+00, 0.4984375E+00, 0.5697097E+00, &
0.6490189E+00, 0.7370409E+00, 0.8344896E+00, 0.9421190E+00, &
0.1000000E+01/
DATA P1/ &
0.9300000E-05, 0.1129521E-04, 0.1360915E-04, 0.1635370E-04, &
0.1954990E-04, 0.2331653E-04, 0.2767314E-04, 0.3277707E-04, &
0.3864321E-04, 0.4547839E-04, 0.5328839E-04, 0.6234301E-04, &
0.7263268E-04, 0.8450696E-04, 0.9793231E-04, 0.1133587E-03, &
0.1307170E-03, 0.1505832E-03, 0.1728373E-03, 0.1982122E-03, &
0.2266389E-03, 0.2592220E-03, 0.2957792E-03, 0.3376068E-03, &
0.3844381E-03, 0.4379281E-03, 0.4976965E-03, 0.5658476E-03, &
0.6418494E-03, 0.7287094E-03, 0.8261995E-03, 0.9380076E-03, &
0.1063498E-02, 0.1207423E-02, 0.1369594E-02, 0.1557141E-02, &
0.1769657E-02, 0.2015887E-02, 0.2295520E-02, 0.2620143E-02, &
0.2989651E-02, 0.3419469E-02, 0.3909867E-02, 0.4481491E-02, &
0.5135272E-02, 0.5898971E-02, 0.6774619E-02, 0.7799763E-02/
DATA P2/ &
0.8978218E-02, 0.1036103E-01, 0.1195488E-01, 0.1382957E-01, &
0.1599631E-01, 0.1855114E-01, 0.2151235E-01, 0.2501293E-01, &
0.2908220E-01, 0.3390544E-01, 0.3952926E-01, 0.4621349E-01, &
0.5403168E-01, 0.6330472E-01, 0.7406807E-01, 0.8677983E-01, &
0.1015345E+00, 0.1189603E+00, 0.1391863E+00, 0.1630739E+00, &
0.1908004E+00, 0.2235461E+00, 0.2609410E+00, 0.3036404E+00, &
0.3513750E+00, 0.4055375E+00, 0.4656677E+00, 0.5335132E+00, &
0.6083618E+00, 0.6923932E+00, 0.7845676E+00, 0.8875882E+00, &
0.1000000E+01/
DATA O3HI1/ &
.55,.50,.45,.45,.40,.35,.35,.30,.30,.30, &
.55,.51,.46,.47,.42,.38,.37,.36,.35,.35, &
.55,.53,.48,.49,.44,.42,.41,.40,.38,.38, &
.60,.55,.52,.52,.50,.47,.46,.44,.42,.41, &
.65,.60,.55,.56,.53,.52,.50,.48,.45,.45, &
.75,.65,.60,.60,.55,.55,.55,.50,.48,.47, &
.80,.75,.75,.75,.70,.70,.65,.63,.60,.60, &
.90,.85,.85,.80,.80,.75,.75,.74,.72,.71, &
1.10,1.05,1.00,.90,.90,.90,.85,.83,.80,.80, &
1.40,1.30,1.25,1.25,1.25,1.20,1.15,1.10,1.05,1.00, &
1.7,1.7,1.6,1.6,1.6,1.6,1.6,1.6,1.5,1.5, &
2.1,2.0,1.9,1.9,1.9,1.8,1.8,1.8,1.7,1.7, &
2.4,2.3,2.2,2.2,2.2,2.1,2.1,2.1,2.0,2.0, &
2.7,2.5,2.5,2.5,2.5,2.5,2.4,2.4,2.3,2.3, &
2.9,2.8,2.7,2.7,2.7,2.7,2.7,2.7,2.6,2.6, &
3.1,3.1,3.0,3.0,3.0,3.0,3.0,3.0,2.9,2.8/
DATA O3HI2/ &
3.3,3.4,3.4,3.6,3.7,3.9,4.0,4.1,4.0,3.8, &
3.6,3.8,3.9,4.2,4.7,5.3,5.6,5.7,5.5,5.2, &
4.1,4.3,4.7,5.2,6.0,6.7,7.0,6.8,6.4,6.2, &
5.4,5.7,6.0,6.6,7.3,8.0,8.4,7.7,7.1,6.7, &
6.7,6.8,7.0,7.6,8.3,10.0,9.6,8.2,7.5,7.2, &
9.2,9.3,9.4,9.6,10.3,10.6,10.0,8.5,7.7,7.3, &
12.6,12.1,12.0,12.1,11.7,11.0,10.0,8.6,7.8,7.4, &
14.2,13.5,13.1,12.8,11.9,10.9,9.8,8.5,7.8,7.5, &
14.3,14.0,13.4,12.7,11.6,10.6,9.3,8.4,7.6,7.3/
DATA O3LO1/ &
14.9,14.2,13.3,12.5,11.2,10.3,9.5,8.6,7.5,7.4, &
14.5,14.1,13.0,11.8,10.5,9.8,9.2,7.9,7.4,7.4, &
11.8,11.5,10.9,10.5,9.9,9.6,8.9,7.5,7.2,7.2, &
7.3,7.7,7.8,8.4,8.4,8.5,7.9,7.4,7.1,7.1, &
4.1,4.4,5.3,6.6,6.9,7.5,7.4,7.2,7.0,6.9, &
1.8,1.9,2.5,3.3,4.5,5.8,6.3,6.3,6.4,6.1, &
0.4,0.5,0.8,1.2,2.7,3.6,4.6,4.7,5.0,5.2, &
.10,.15,.20,.50,1.4,2.1,3.0,3.2,3.5,3.9, &
.07,.10,.12,.30,1.0,1.4,1.8,1.9,2.3,2.5, &
.06,.08,.10,.15,.60,.80,1.4,1.5,1.5,1.6, &
.05,.05,.06,.09,.20,.40,.70,.80,.90,.90, &
.05,.05,.06,.08,.10,.13,.20,.25,.30,.40, &
.05,.05,.05,.06,.07,.07,.08,.09,.10,.13, &
.05,.05,.05,.05,.06,.06,.06,.06,.07,.07, &
.05,.05,.05,.05,.05,.05,.05,.06,.06,.06, &
.04,.04,.04,.04,.04,.04,.04,.05,.05,.05/
DATA O3LO2/ &
14.8,14.2,13.8,12.2,11.0,9.8,8.5,7.8,7.4,6.9, &
13.2,13.0,12.5,11.3,10.4,9.0,7.8,7.5,7.0,6.6, &
10.6,10.6,10.7,10.1,9.4,8.6,7.5,7.0,6.5,6.1, &
7.0,7.3,7.5,7.5,7.5,7.3,6.7,6.4,6.0,5.8, &
3.8,4.0,4.7,5.0,5.2,5.9,5.8,5.6,5.5,5.5, &
1.4,1.6,2.4,3.0,3.7,4.1,4.6,4.8,5.1,5.0, &
.40,.50,.90,1.2,2.0,2.7,3.2,3.6,4.3,4.1, &
.07,.10,.20,.30,.80,1.4,2.1,2.4,2.7,3.0, &
.06,.07,.09,.15,.30,.70,1.2,1.4,1.6,2.0, &
.05,.05,.06,.12,.15,.30,.60,.70,.80,.80, &
.04,.05,.06,.08,.09,.15,.30,.40,.40,.40, &
.04,.04,.05,.055,.06,.09,.12,.13,.15,.15, &
.03,.03,.045,.052,.055,.06,.07,.07,.06,.07, &
.03,.03,.04,.051,.052,.052,.06,.06,.05,.05, &
.02,.02,.03,.05,.05,.05,.04,.04,.04,.04, &
.02,.02,.02,.04,.04,.04,.03,.03,.03,.03/
DATA O3LO3/ &
14.5,14.0,13.5,11.3,11.0,10.0,9.0,8.3,7.5,7.3, &
13.5,13.2,12.5,11.1,10.4,9.7,8.2,7.8,7.4,6.8, &
10.8,10.9,11.0,10.4,10.0,9.6,7.9,7.5,7.0,6.7, &
7.3,7.5,7.8,8.5,9.0,8.5,7.7,7.4,6.9,6.5, &
4.1,4.5,5.3,6.2,7.3,7.7,7.3,7.0,6.6,6.4, &
1.8,2.0,2.2,3.8,4.3,5.6,6.2,6.2,6.4,6.2, &
.30,.50,.60,1.5,2.8,3.7,4.5,4.7,5.5,5.6, &
.09,.10,.15,.60,1.2,2.1,3.0,3.5,4.0,4.3, &
.06,.08,.10,.30,.60,1.1,1.9,2.2,2.9,3.0, &
.04,.05,.06,.15,.45,.60,1.1,1.3,1.6,1.8, &
.04,.04,.04,.08,.20,.30,.55,.60,.75,.90, &
.04,.04,.04,.05,.06,.10,.12,.15,.20,.25, &
.04,.04,.03,.04,.05,.06,.07,.07,.07,.08, &
.03,.03,.04,.05,.05,.05,.05,.05,.05,.05, &
.03,.03,.03,.04,.04,.04,.05,.05,.04,.04, &
.02,.02,.02,.04,.04,.04,.04,.04,.03,.03/
DATA O3LO4/ &
14.2,13.8,13.2,12.5,11.7,10.5,8.6,7.8,7.5,6.6, &
12.5,12.4,12.2,11.7,10.8,9.8,7.8,7.2,6.5,6.1, &
10.6,10.5,10.4,10.1,9.6,9.0,7.1,6.8,6.1,5.9, &
7.0,7.4,7.9,7.8,7.6,7.3,6.2,6.1,5.8,5.6, &
4.2,4.6,5.1,5.6,5.9,5.9,5.9,5.8,5.6,5.3, &
2.1,2.3,2.6,2.9,3.5,4.3,4.8,4.9,5.1,5.1, &
0.7,0.8,1.0,1.5,2.0,2.8,3.5,3.6,3.7,4.0, &
.15,.20,.40,.50,.60,1.4,2.1,2.2,2.3,2.5, &
.08,.10,.15,.25,.30,.90,1.2,1.3,1.4,1.6, &
.07,.08,.10,.14,.20,.50,.70,.90,.90,.80, &
.05,.06,.08,.12,.14,.20,.35,.40,.60,.50, &
.05,.05,.08,.09,.09,.09,.11,.12,.15,.18, &
.04,.05,.06,.07,.07,.08,.08,.08,.08,.08, &
.04,.04,.05,.07,.07,.07,.07,.07,.06,.05, &
.02,.02,.04,.05,.05,.05,.05,.05,.04,.04, &
.02,.02,.03,.04,.04,.04,.04,.04,.03,.03/
!!!!!
! PSS=101325.
! PDIF=PSS-PT
!
! DO L=1,LM1
! PHALF(L+1)=AETA(L)*PDIF+PT
! ENDDO
!
! PHALF(1)=0.
! PHALF(LP1)=PSS
!!!!
N=kte;NP=N+1;NP2=N+2;NM1=N-1
NKK=41
NK=81
NKP=NK+1
DO 24 K=1,NP
! 24 PHALF(K)=PHALF(K)*1.0E 03
24 PHALF(K)=PHALF(K)*0.01*1.0E+03
! 24 PSTD(K)=PSTD(K+1)*1.0E 03
DO 25 K=1,NK
PH(K)=PH(K)*1013250.
25 P(K)=P(K)*1013250.
PH(NKP)=PH(NKP)*1013250.
!KAC WRITE (6,3) PH
!KAC WRITE (6,3) P
! WRITE (6,3) (PHALF(K),K=1,NP)
! WRITE (6,3) (PSTD(K),K=1,NP)
!***LOAD ARRAYS RO31,RO32,AS IN DICKS PGM.
DO 1010 K=1,25
DO 1010 L=1,10
RO31(L,K)=O3HI(L,K)
RO32(L,K)=O3HI(L,K)
1010 CONTINUE
!
DO 3000 NCASE=1,4
ITAPE=NCASE+50
IPLACE=2
IF (NCASE.EQ.2) IPLACE=4
IF (NCASE.EQ.3) IPLACE=1
IF (NCASE.EQ.4) IPLACE=3
!***NCASE=1: SPRING (IN N.H.)
!***NCASE=2: FALL (IN N.H.)
!***NCASE=3: WINTER (IN N.H.)
!***NCASE=4: SUMMER (IN N.H.)
IF (NCASE.EQ.1.OR.NCASE.EQ.2) THEN
DO 1011 K=26,41
DO 1011 L=1,10
RO31(L,K)=O3LO1(L,K-25)
RO32(L,K)=O3LO2(L,K-25)
1011 CONTINUE
ENDIF
IF (NCASE.EQ.3.OR.NCASE.EQ.4) THEN
DO 1031 K=26,41
DO 1031 L=1,10
RO31(L,K)=O3LO3(L,K-25)
RO32(L,K)=O3LO4(L,K-25)
1031 CONTINUE
ENDIF
DO 30 KK=1,NKK
DO 31 L=1,10
DUO3N(L,KK)=RO31(11-L,KK)
31 DUO3N(L+9,KK)=RO32(L,KK)
DUO3N(10,KK)=.5*(RO31(1,KK)+RO32(1,KK))
30 CONTINUE
!***FOR NCASE=2 OR NCASE=4,REVERSE LATITUDE ARRANGEMENT OF CORR. SEASON
IF (NCASE.EQ.2.OR.NCASE.EQ.4) THEN
DO 1024 KK=1,NKK
DO 1025 L=1,19
TEMPN(L)=DUO3N(20-L,KK)
1025 CONTINUE
DO 1026 L=1,19
DUO3N(L,KK)=TEMPN(L)
1026 CONTINUE
1024 CONTINUE
ENDIF
!***DUO3N NOW IS O3 PROFILE FOR APPROPRIATE SEASON,AT STD. PRESSURE
! LEVELS
!KAC WRITE (6,800) DUO3N
!***BEGIN LATITUDE (10 DEG) LOOP
DO 33 L=1,19
DO 22 KK=1,NKK
22 RSTD(KK)=DUO3N(L,KK)
NKM=NK-1
NKMM=NK-3
! BESSELS HALF-POINT INTERPOLATION FORMULA
DO 60 K=4,NKMM,2
KI=K/2
60 RDATA(K)=.5*(RSTD(KI)+RSTD(KI+1))-(RSTD(KI+2)-RSTD(KI+1)-RSTD(KI)+ &
RSTD(KI-1))/16.
RDATA(2)=.5*(RSTD(2)+RSTD(1))
RDATA(NKM)=.5*(RSTD(NKK)+RSTD(NKK-1))
! PUT UNCHANGED DATA INTO NEW ARRAY
DO 61 K=1,NK,2
KQ=(K+1)/2
61 RDATA(K)=RSTD(KQ)
!---NOTE TO NMC: THIS WRITE IS COMMENTED OUT TO REDUCE PRINTOUT
! WRITE (6,798) RDATA
! CALCULATE LAYER-MEAN OZONE MIXING RATIO FOR EACH MODEL LEVEL
DO 99 KK=1,N
RBAR(KK)=0.
! LOOP TO CALCULATE SUMS TO GET LAYER OZONE MEAN
DO 98 K=1,NK
IF(PH(K+1).LT.PHALF(KK)) GO TO 98
IF(PH(K).GT.PHALF(KK+1)) GO TO 98
IF(PH(K+1).LT.PHALF(KK+1).AND.PH(K).LT.PHALF(KK)) RBAR(KK)=RBAR(KK &
)+RDATA(K)*(PH(K+1)-PHALF(KK))
IF(PH(K+1).LT.PHALF(KK+1).AND.PH(K).GE.PHALF(KK)) RBAR(KK)=RBAR(KK &
)+RDATA(K)*(PH(K+1)-PH(K))
IF(PH(K+1).GT.PHALF(KK+1).AND.PH(K).GT.PHALF(KK)) RBAR(KK)=RBAR(KK &
)+RDATA(K)*(PHALF(KK+1)-PH(K))
98 CONTINUE
RBAR(KK)=RBAR(KK)/(PHALF(KK+1)-PHALF(KK))
IF(RBAR(KK).GT..0000) GO TO 99
! CODE TO COVER CASE WHEN MODEL RESOLUTION IS SO FINE THAT NO VALUE
! OF P(K) IN THE OZONE DATA ARRAY FALLS BETWEEN PHALF(KK+1) AND
! PHALF(KK). PROCEDURE IS TO SIMPLY GRAB THE NEAREST VALUE FROM
! RDATA
DO 29 K=1,NK
IF(PH(K).LT.PHALF(KK).AND.PH(K+1).GE.PHALF(KK+1)) RBAR(KK)=RDATA(K)
29 CONTINUE
99 CONTINUE
! CALCULATE TOTAL OZONE
O3RD=0.
DO 89 KK=1,80
89 O3RD=O3RD+RDATA(KK)*(PH(KK+1)-PH(KK))
O3RD=O3RD+RDATA(81)*(P(81)-PH(81))
O3RD=O3RD/980.
O3TOT=0.
DO 88 KK=1,N
88 O3TOT=O3TOT+RBAR(KK)*(PHALF(KK+1)-PHALF(KK))
O3TOT=O3TOT/980.
! UNITS ARE MICROGRAMS/CM**2
O3DU=O3TOT/2.144
! O3DU UNITS ARE DOBSON UNITS (10**-3 ATM-CM)
!--NOTE TO NMC: THIS IS COMMENTED OUT TO SAVE PRINTOUT
! WRITE (6,796) O3RD,O3TOT,O3DU
DO 23 KK=1,N
23 DDUO3(L,KK)=RBAR(KK)*.01
33 CONTINUE
!***END OF LATITUDE LOOP
!
!***CREATE 5 DEG OZONE QUANTITIES BY LINEAR INTERPOLATION OF
! 10 DEG VALUES
DO 1060 KK=1,N
DO 1061 L=1,19
O35DEG(2*L-1,KK)=DDUO3(L,KK)
1061 CONTINUE
DO 1062 L=1,18
O35DEG(2*L,KK)=0.5*(DDUO3(L,KK)+DDUO3(L+1,KK))
1062 CONTINUE
1060 CONTINUE
!***OUTPUT TO UNIT (ITAPE) THE OZONE VALUES FOR LATER USE
!O222 ***************************************************
!C WRITE (66) O35DEG
IF (IPLACE.EQ.1) THEN
DO 302 JJ=1,37
DO 302 KEN=1,N
DDUO3N(JJ,KEN) = O35DEG(JJ,KEN)
302 CONTINUE
ELSE IF (IPLACE.EQ.2) THEN
DO 312 JJ=1,37
DO 312 KEN=1,N
DDO3N2(JJ,KEN) = O35DEG(JJ,KEN)
312 CONTINUE
ELSE IF (IPLACE.EQ.3) THEN
DO 322 JJ=1,37
DO 322 KEN=1,N
DDO3N3(JJ,KEN) = O35DEG(JJ,KEN)
322 CONTINUE
ELSE IF (IPLACE.EQ.4) THEN
DO 332 JJ=1,37
DO 332 KEN=1,N
DDO3N4(JJ,KEN) = O35DEG(JJ,KEN)
332 CONTINUE
END IF
!O222 ***************************************************
3000 CONTINUE
!***END OF LOOP OVER CASES
RETURN
1 FORMAT(10F4.2)
2 FORMAT(10X,E14.7,1X,E14.7,1X,E14.7,1X,E14.7,1X)
3 FORMAT(10E12.5)
797 FORMAT(10F7.2)
799 FORMAT(19F6.4)
800 FORMAT(19F6.2)
102 FORMAT(' O3 IPLACE=',I4)
1033 FORMAT(19F6.5)
101 FORMAT(5X,1H*,F6.5,1H,,F6.5,1H,,F6.5,1H,,F6.5,1H,,F6.5,1H,,F6.5, &
1H,,F6.5,1H,,F6.5,1H,,F6.5,1H,)
END SUBROUTINE O3INT
!----------------------------------------------------------------
SUBROUTINE CLO89(CLDFAC,CAMT,NCLDS,KBTM,KTOP & 2
, ids,ide, jds,jde, kds,kde &
, ims,ime, jms,jme, kms,kme &
, its,ite, jts,jte, kts,kte )
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
!----------------------------------------------------------------------
! ************************************************************
! * *
! * THIS SUBROUTINE WAS MODIFIED TO BE USED IN THE ETA MODEL *
! * *
! * Q. ZHAO 95-3-22 *
! * *
! ************************************************************
REAL, INTENT(OUT),DIMENSION(its:ite,kts:kte+1,kts:kte+1) :: CLDFAC
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: CAMT
INTEGER, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: KBTM,KTOP
INTEGER, INTENT(IN), DIMENSION(its:ite) :: NCLDS
REAL, DIMENSION(kts:kte+1,kts:kte+1,64) :: CLDIPT
REAL, DIMENSION(kts:kte+1) :: CLDROW
INTEGER:: IQ,ITOP,I,J,JTOP,IR,IP,K1,K2,KB,K,KP,KT,NC
REAL :: XCLD
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE
! DIMENSION CLDIPT(LP1,LP1, 64 )
! DIMENSION NCLDS(IDIM1:IDIM2),KTOP(IDIM1:IDIM2,LP1), &
! KBTM(IDIM1:IDIM2,LP1)
! DIMENSION CLDROW(LP1)
! DIMENSION CAMT(IDIM1:IDIM2,LP1),CLDFAC(IDIM1:IDIM2,LP1,LP1)
L=kte
LP1=L+1; LP2=L+2; LP3=L+3
LM1=L-1; LM2=L-2; LM3=L-3
MYIS=its; MYIE=ite
!
DO 1 IQ=MYIS,MYIE,64
ITOP=IQ+63
IF(ITOP.GT.MYIE) ITOP=MYIE
JTOP=ITOP-IQ+1
DO 11 IP=1,JTOP
IR=IQ+IP-1
IF (NCLDS(IR).EQ.0) THEN
DO 25 J=1,LP1
DO 25 I=1,LP1
CLDIPT(I,J,IP)=1.
25 CONTINUE
ENDIF
IF (NCLDS(IR).GE.1) THEN
XCLD=1.-CAMT(IR,2)
K1=KTOP(IR,2)+1
K2=KBTM(IR,2)
DO 27 J=1,LP1
CLDROW(J)=1.
27 CONTINUE
DO 29 J=1,K2
CLDROW(J)=XCLD
29 CONTINUE
KB=MAX(K1,K2+1)
DO 33 K=KB,LP1
DO 33 KP=1,LP1
CLDIPT(KP,K,IP)=CLDROW(KP)
33 CONTINUE
DO 37 J=1,LP1
CLDROW(J)=1.
37 CONTINUE
DO 39 J=K1,LP1
CLDROW(J)=XCLD
39 CONTINUE
KT=MIN(K1-1,K2)
DO 43 K=1,KT
DO 43 KP=1,LP1
CLDIPT(KP,K,IP)=CLDROW(KP)
43 CONTINUE
IF(K2+1.LE.K1-1) THEN
DO 31 J=K2+1,K1-1
DO 31 I=1,LP1
CLDIPT(I,J,IP)=1.
31 CONTINUE
ELSE IF(K1.LE.K2) THEN
DO 32 J=K1,K2
DO 32 I=1,LP1
CLDIPT(I,J,IP)=XCLD
32 CONTINUE
ENDIF
ENDIF
IF (NCLDS(IR).GE.2) THEN
DO 21 NC=2,NCLDS(IR)
XCLD=1.-CAMT(IR,NC+1)
K1=KTOP(IR,NC+1)+1
K2=KBTM(IR,NC+1)
DO 47 J=1,LP1
CLDROW(J)=1.
47 CONTINUE
DO 49 J=1,K2
CLDROW(J)=XCLD
49 CONTINUE
KB=MAX(K1,K2+1)
DO 53 K=KB,LP1
DO 53 KP=1,LP1
CLDIPT(KP,K,IP)=CLDIPT(KP,K,IP)*CLDROW(KP)
53 CONTINUE
DO 57 J=1,LP1
CLDROW(J)=1.
57 CONTINUE
DO 59 J=K1,LP1
CLDROW(J)=XCLD
59 CONTINUE
KT=MIN(K1-1,K2)
DO 63 K=1,KT
DO 63 KP=1,LP1
CLDIPT(KP,K,IP)=CLDIPT(KP,K,IP)*CLDROW(KP)
63 CONTINUE
IF(K1.LE.K2) THEN
DO 52 J=K1,K2
DO 52 I=1,LP1
CLDIPT(I,J,IP)=CLDIPT(I,J,IP)*XCLD
52 CONTINUE
ENDIF
21 CONTINUE
ENDIF
11 CONTINUE
DO 71 J=1,LP1
DO 71 I=1,LP1
DO 71 IP=1,JTOP
IR=IQ+IP-1
CLDFAC(IR,I,J)=CLDIPT(I,J,IP)
71 CONTINUE
1 CONTINUE
END SUBROUTINE CLO89
!----------------------------------------------------------------
! SUBROUTINE LWR88(HEATRA,GRNFLX,TOPFLX, &
! PRESS,TEMP,RH2O,QO3,CLDFAC, &
! CAMT,NCLDS,KTOP,KBTM, &
!! BO3RND,AO3RND,T1,T2,T4,EM1V,EM1VW,EM3V, &
! BO3RND,AO3RND, &
! APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
! ZERO,ONE,H18E3,P0INV,H6P08108,DIFFCTR, &
! GINV,H3M4,BETINW,RATH2OMW,GP0INV,P0,P0XZP8, &
! P0XZP2,H3M3,H1M3,H1M2,H25E2,B0,B2,B1,B3,HAF, &
! TEN,HP1,FOUR,HM1EZ,SKO3R, &
! AB15WD,SKC1R,RADCON,QUARTR,TWO, &
! HM6666M2,HMP66667,HMP5, HP166666,H41666M2, &
! RADCON1,H16E1, H28E1,H44194M2,H1P41819,SKO2D, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
SUBROUTINE LWR88(HEATRA,GRNFLX,TOPFLX, & 2,2
PRESS,TEMP,RH2O,QO3,CLDFAC, &
CAMT,NCLDS,KTOP,KBTM, &
! BO3RND,AO3RND,T1,T2,T4,EM1V,EM1VW,EM3V, &
BO3RND,AO3RND, &
APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
ZERO,ONE,H18E3,P0INV,H6P08108,DIFFCTR, &
GINV,H3M4,BETINW,RATH2OMW,GP0INV,P0,P0XZP8, &
P0XZP2,H3M3,H1M3,H1M2,H25E2,B0,B2,B1,B3,HAF, &
TEN,HP1,FOUR,HM1EZ, &
RADCON,QUARTR,TWO, &
HM6666M2,HMP66667,HMP5, HP166666,H41666M2, &
RADCON1,H16E1, H28E1,H44194M2,H1P41819, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
! INTEGER, PARAMETER :: NBLY=15
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
REAL, INTENT(IN) :: ZERO,ONE,H18E3,P0INV,H6P08108,DIFFCTR
REAL, INTENT(IN) :: GINV,H3M4,BETINW,RATH2OMW,GP0INV
REAL, INTENT(IN) :: P0XZP8,P0XZP2,H3M3,P0,H1M3
REAL, INTENT(IN) :: H1M2,H25E2,B0,B1,B2,B3,HAF
! REAL, INTENT(IN) :: TEN,HP1,FOUR,HM1EZ,SKO3R
REAL, INTENT(IN) :: TEN,HP1,FOUR,HM1EZ
! REAL, INTENT(IN) :: AB15WD,SKC1R,RADCON,QUARTR,TWO
REAL, INTENT(IN) :: RADCON,QUARTR,TWO
REAL, INTENT(IN) :: HM6666M2,HMP66667,HMP5, HP166666,H41666M2
! REAL, INTENT(IN) :: RADCON1,H16E1, H28E1,H44194M2,H1P41819,SKO2D
REAL, INTENT(IN) :: RADCON1,H16E1, H28E1,H44194M2,H1P41819
!----------------------------------------------------------------------
REAL, INTENT(IN), DIMENSION(3) :: BO3RND,AO3RND
! REAL,INTENT(IN),DIMENSION(5040):: T1,T2,T4,EM1V,EM1VW
! REAL, INTENT(IN), DIMENSION(5040) :: EM3V
REAL,INTENT(IN),DIMENSION(NBLY) :: APCM,BPCM,ATPCM,BTPCM,ACOMB, &
BCOMB,BETACM
REAL, INTENT(IN),DIMENSION(its:ite,kts:kte+1,kts:kte+1) :: CLDFAC
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: CAMT
INTEGER, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: KBTM,KTOP
INTEGER, INTENT(IN), DIMENSION(its:ite) :: NCLDS
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: PRESS,TEMP
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte) :: RH2O,QO3
REAL, INTENT(OUT), DIMENSION(its:ite,kts:kte) :: HEATRA
REAL, INTENT(OUT), DIMENSION(its:ite) :: GRNFLX,TOPFLX
! REAL, DIMENSION(kts:kte+1,kts:kte+1,64) :: CLDIPT
! Include co2 data from a file, which needs to have exactly vertical
! dimension of the model.
!!! ??? co2 table
! REAL, DIMENSION(kts:kte+1,kts:kte+1) :: CO251,CDT51,CDT58,C2D51,&
! C2D58,CO258
! REAL, DIMENSION(kts:kte+1) :: STEMP,GTEMP,CO231,CO238, &
! C2D31,C2D38,CDT31,CDT38, &
! CO271,CO278,C2D71,C2D78, &
! CDT71,CDT78
! REAL, DIMENSION(kts:kte) :: CO2M51,CO2M58,CDTM51,CDTM58, &
! C2DM51,C2DM58
!!! end co2 table
! REAL, DIMENSION(kts:kte+1) :: CLDROW
REAL, DIMENSION(its:ite,kts:kte+1) :: TEXPSL,TOTPHI,TOTO3,CNTVAL,&
TPHIO3,TOTVO2,TSTDAV,TDAV, &
VSUM3,CO2R1,D2CD21,DCO2D1, &
CO2R2,D2CD22,DCO2D2,CO2SP1,&
CO2SP2,CO2R,DCO2DT,D2CDT2, &
TLSQU,DIFT
REAL, DIMENSION(its:ite,kts:kte) :: DELP2,DELP,CO2NBL,&
QH2O,VV,VAR1,VAR2,VAR3,VAR4
REAL, DIMENSION(its:ite,kts:kte+1) :: P,T
REAL, DIMENSION(its:ite,kts:kte) :: CO2MR,CO2MD,CO2M2D
REAL, DIMENSION(its:ite,kts:kte*2+1):: EMPL
REAL, DIMENSION(its:ite) :: EMX1,EMX2,VSUM1,VSUM2,A1,A2
REAL, DIMENSION(its:ite,kts:kte+1,kts:kte+1) :: CO21
! COMMON/CO2BD3/CO251(LP1,LP1),CO258(LP1,LP1),CDT51(LP1,LP1),
! DIMENSION CO21(IDIM1:IDIM2,LP1,LP1),CO2NBL(IDIM1:IDIM2,L)
! DIMENSION CO2R(IDIM1:IDIM2,LP1),DIFT(IDIM1:IDIM2,LP1)
! 1 CO2M2D(IDIM1:IDIM2,L)
! DIMENSION CO2MR(IDIM1:IDIM2,L),CO2MD(IDIM1:IDIM2,L),
! 2 CO2M58(L),CDTM51(L),CDTM58(L),C2DM51(L),C2DM58(L),
! 1 CDT58(LP1,LP1),C2D51(LP1,LP1),C2D58(LP1,LP1),CO2M51(L),
! COMMON / CO2BD2 / CO231(LP1),CO238(LP1),CDT31(LP1),
! 1 CDT38(LP1),C2D31(LP1),C2D38(LP1)
! DIMENSION CO2R1(IDIM1:IDIM2,LP1),DCO2D1(IDIM1:IDIM2,LP1)
! DIMENSION D2CD21(IDIM1:IDIM2,LP1),D2CD22(IDIM1:IDIM2,LP1)
! 3 STEMP(LP1),GTEMP(LP1),B0,B1,B2,B3
! 1 VV(IDIM1:IDIM2,L),VSUM3(IDIM1:IDIM2,LP1),VSUM1(IDIM1:IDIM2),
! 2 VSUM2(IDIM1:IDIM2)
! DIMENSION TDAV(IDIM1:IDIM2,LP1),TSTDAV(IDIM1:IDIM2,LP1),
! LLP1=LL+1, LL = 2L
! EMX2(IDIM1:IDIM2),EMPL(IDIM1:IDIM2,LLP1)
! DIMENSION TPHIO3(IDIM1:IDIM2,LP1),
! DIMENSION TEXPSL(IDIM1:IDIM2,LP1)
! DIMENSION QH2O(IDIM1:IDIM2,L)
! DIMENSION DELP2(IDIM1:IDIM2,L)
! DIMENSION VAR1(IDIM1:IDIM2,L),VAR2(IDIM1:IDIM2,L),
! 1 VAR3(IDIM1:IDIM2,L),VAR4(IDIM1:IDIM2,L)
! 1 VV(IDIM1:IDIM2,L)
! DIMENSION CNTVAL(IDIM1:IDIM2,LP1)
! DIMENSION TOTO3(IDIM1:IDIM2,LP1)
! DIMENSION EMX1(IDIM1:IDIM2),
! DIMENSION PRESS(IDIM1:IDIM2,LP1),TEMP(IDIM1:IDIM2,LP1), &
! RH2O(IDIM1:IDIM2,L),QO3(IDIM1:IDIM2,L)
! DIMENSION HEATRA(IDIM1:IDIM2,L),GRNFLX(IDIM1:IDIM2), &
! TOPFLX(IDIM1:IDIM2)
!
!
!****COMPUTE FLUX PRESSURES (P) AND DIFFERENCES (DELP2,DELP)
!****COMPUTE FLUX LEVEL TEMPERATURES (T) AND CONTINUUM TEMPERATURE
! CORRECTIONS (TEXPSL)
INTEGER :: K, I,KP
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE,LLP1,LL
L=kte
LP1=L+1; LP2=L+2; LP3=L+3; LLP1 = 2*L + 1
LM1=L-1; LM2=L-2; LM3=L-3; LL = 2*L
MYIS=its; MYIE=ite
DO 103 K=2,L
DO 103 I=MYIS,MYIE
P(I,K)=HAF*(PRESS(I,K-1)+PRESS(I,K))
T(I,K)=HAF*(TEMP(I,K-1)+TEMP(I,K))
103 CONTINUE
DO 105 I=MYIS,MYIE
P(I,1)=ZERO
P(I,LP1)=PRESS(I,LP1)
T(I,1)=TEMP(I,1)
T(I,LP1)=TEMP(I,LP1)
105 CONTINUE
DO 107 K=1,L
DO 107 I=MYIS,MYIE
DELP2(I,K)=P(I,K+1)-P(I,K)
DELP(I,K)=ONE/DELP2(I,K)
107 CONTINUE
!****COMPUTE ARGUMENT FOR CONT.TEMP.COEFF.
! (THIS IS 1800.(1./TEMP-1./296.))
DO 125 K=1,LP1
DO 125 I=MYIS,MYIE
TEXPSL(I,K)=H18E3/TEMP(I,K)-H6P08108
!...THEN TAKE EXPONENTIAL
TEXPSL(I,K)=EXP(TEXPSL(I,K))
125 CONTINUE
!***COMPUTE OPTICAL PATHS FOR H2O AND O3, USING THE DIFFUSIVITY
! APPROXIMATION FOR THE ANGULAR INTEGRATION (1.66). OBTAIN THE
! UNWEIGHTED VALUES(VAR1,VAR3) AND THE WEIGHTED VALUES(VAR2,VAR4).
! THE QUANTITIES H3M4(.0003) AND H3M3(.003) APPEARING IN THE VAR2 AND
! VAR4 EXPRESSIONS ARE THE APPROXIMATE VOIGT CORRECTIONS FOR H2O AND
! O3,RESPECTIVELY.
!
DO 131 K=1,L
DO 131 I=MYIS,MYIE
QH2O(I,K)=RH2O(I,K)*DIFFCTR
!---VV IS THE LAYER-MEAN PRESSURE (IN ATM),WHICH IS NOT THE SAME AS
! THE LEVEL PRESSURE (PRESS)
VV(I,K)=HAF*(P(I,K+1)+P(I,K))*P0INV
VAR1(I,K)=DELP2(I,K)*QH2O(I,K)*GINV
VAR3(I,K)=DELP2(I,K)*QO3(I,K)*DIFFCTR*GINV
VAR2(I,K)=VAR1(I,K)*(VV(I,K)+H3M4)
VAR4(I,K)=VAR3(I,K)*(VV(I,K)+H3M3)
! COMPUTE OPTICAL PATH FOR THE H2O CONTINUUM, USING ROBERTS COEFFS.
! (BETINW),AND TEMP. CORRECTION (TEXPSL). THE DIFFUSIVITY FACTOR
! (WHICH CANCELS OUT IN THIS EXPRESSION) IS ASSUMED TO BE 1.66. THE
! USE OF THE DIFFUSIVITY FACTOR HAS BEEN SHOWN TO BE A SIGNIFICANT
! SOURCE OF ERROR IN THE CONTINUUM CALCS.,BUT THE TIME PENALTY OF
! AN ANGULAR INTEGRATION IS SEVERE.
!
CNTVAL(I,K)=TEXPSL(I,K)*RH2O(I,K)*VAR2(I,K)*BETINW/ &
(RH2O(I,K)+RATH2OMW)
131 CONTINUE
! COMPUTE SUMMED OPTICAL PATHS FOR H2O,O3 AND CONTINUUM
DO 201 I=MYIS,MYIE
TOTPHI(I,1)=ZERO
TOTO3(I,1)=ZERO
TPHIO3(I,1)=ZERO
TOTVO2(I,1)=ZERO
201 CONTINUE
DO 203 K=2,LP1
DO 203 I=MYIS,MYIE
TOTPHI(I,K)=TOTPHI(I,K-1)+VAR2(I,K-1)
TOTO3(I,K)=TOTO3(I,K-1)+VAR3(I,K-1)
TPHIO3(I,K)=TPHIO3(I,K-1)+VAR4(I,K-1)
TOTVO2(I,K)=TOTVO2(I,K-1)+CNTVAL(I,K-1)
203 CONTINUE
!---EMX1 IS THE ADDITIONAL PRESSURE-SCALED MASS FROM PRESS(L) TO
! P(L). IT IS USED IN NEARBY LAYER AND EMISS CALCULATIONS.
!---EMX2 IS THE ADDITIONAL PRESSURE-SCALED MASS FROM PRESS(L) TO
! P(LP1). IT IS USED IN CALCULATIONS BETWEEN FLUX LEVELS L AND LP1.
!
DO 801 I=MYIS,MYIE
EMX1(I)=QH2O(I,L)*PRESS(I,L)*(PRESS(I,L)-P(I,L))*GP0INV
EMX2(I)=QH2O(I,L)*PRESS(I,L)*(P(I,LP1)-PRESS(I,L))*GP0INV
801 CONTINUE
!---EMPL IS THE PRESSURE SCALED MASS FROM P(K) TO PRESS(K) (INDEX 2-LP1)
! OR TO PRESS(K+1) (INDEX LP2-LL)
DO 811 K=1,L
DO 811 I=MYIS,MYIE
EMPL(I,K+1)=QH2O(I,K)*P(I,K+1)*(P(I,K+1)-PRESS(I,K))*GP0INV
811 CONTINUE
DO 812 K=1,LM1
DO 812 I=MYIS,MYIE
EMPL(I,LP2+K-1)=QH2O(I,K+1)*P(I,K+1)*(PRESS(I,K+1)-P(I,K+1)) &
*GP0INV
812 CONTINUE
DO 821 I=MYIS,MYIE
EMPL(I,1)=VAR2(I,L)
EMPL(I,LLP1)=EMPL(I,LL)
821 CONTINUE
!***COMPUTE WEIGHTED TEMPERATURE (TDAV) AND PRESSURE (TSTDAV) INTEGRALS
! FOR USE IN OBTAINING TEMP. DIFFERENCE BET. SOUNDING AND STD.
! TEMP. SOUNDING (DIFT)
DO 161 I=MYIS,MYIE
TSTDAV(I,1)=ZERO
TDAV(I,1)=ZERO
161 CONTINUE
DO 162 K=1,LP1
DO 162 I=MYIS,MYIE
VSUM3(I,K)=TEMP(I,K)-STEMP(K)
162 CONTINUE
DO 163 K=1,L
DO 165 I=MYIS,MYIE
VSUM2(I)=GTEMP(K)*DELP2(I,K)
VSUM1(I)=VSUM2(I)*VSUM3(I,K)
TSTDAV(I,K+1)=TSTDAV(I,K)+VSUM2(I)
TDAV(I,K+1)=TDAV(I,K)+VSUM1(I)
165 CONTINUE
163 CONTINUE
!
!****EVALUATE COEFFICIENTS FOR CO2 PRESSURE INTERPOLATION (A1,A2)
DO 171 I=MYIS,MYIE
A1(I)=(PRESS(I,LP1)-P0XZP8)/P0XZP2
A2(I)=(P0-PRESS(I,LP1))/P0XZP2
171 CONTINUE
!***PERFORM CO2 PRESSURE INTERPOLATION ON ALL INPUTTED TRANSMISSION
! FUNCTIONS AND TEMP. DERIVATIVES
!---SUCCESSIVELY COMPUTING CO2R,DCO2DT AND D2CDT2 IS DONE TO SAVE
! STORAGE (AT A SLIGHT LOSS IN COMPUTATION TIME)
DO 184 K=1,LP1
DO 184 I=MYIS,MYIE
CO2R1(I,K)=A1(I)*CO231(K)+A2(I)*CO238(K)
D2CD21(I,K)=H1M3*(A1(I)*C2D31(K)+A2(I)*C2D38(K))
DCO2D1(I,K)=H1M2*(A1(I)*CDT31(K)+A2(I)*CDT38(K))
CO2R2(I,K)=A1(I)*CO271(K)+A2(I)*CO278(K)
D2CD22(I,K)=H1M3*(A1(I)*C2D71(K)+A2(I)*C2D78(K))
DCO2D2(I,K)=H1M2*(A1(I)*CDT71(K)+A2(I)*CDT78(K))
184 CONTINUE
DO 190 K=1,L
DO 190 I=MYIS,MYIE
CO2MR(I,K)=A1(I)*CO2M51(K)+A2(I)*CO2M58(K)
CO2MD(I,K)=H1M2*(A1(I)*CDTM51(K)+A2(I)*CDTM58(K))
CO2M2D(I,K)=H1M3*(A1(I)*C2DM51(K)+A2(I)*C2DM58(K))
190 CONTINUE
!***COMPUTE CO2 TEMPERATURE INTERPOLATIONS FOR ALL BANDS,USING DIFT
!
! THE CASE WHERE K=1 IS HANDLED FIRST. WE ARE NOW REPLACING
! 3-DIMENSIONAL ARRAYS BY 2-D ARRAYS, TO SAVE SPACE. THUS THIS
! CALCULATION IS FOR (I,KP,1)
DO 211 KP=2,LP1
DO 211 I=MYIS,MYIE
DIFT(I,KP)=TDAV(I,KP)/TSTDAV(I,KP)
211 CONTINUE
DO 212 I=MYIS,MYIE
CO21(I,1,1)=1.0
CO2SP1(I,1)=1.0
CO2SP2(I,1)=1.0
212 CONTINUE
DO 215 KP=2,LP1
DO 215 I=MYIS,MYIE
!---CALCULATIONS FOR KP>1 FOR K=1
CO2R(I,KP)=A1(I)*CO251(KP,1)+A2(I)*CO258(KP,1)
DCO2DT(I,KP)=H1M2*(A1(I)*CDT51(KP,1)+A2(I)*CDT58(KP,1))
D2CDT2(I,KP)=H1M3*(A1(I)*C2D51(KP,1)+A2(I)*C2D58(KP,1))
CO21(I,KP,1)=CO2R(I,KP)+DIFT(I,KP)*(DCO2DT(I,KP)+ &
HAF*DIFT(I,KP)*D2CDT2(I,KP))
!---CALCULATIONS FOR (EFFECTIVELY) KP=1,K>KP. THESE USE THE
! SAME VALUE OF DIFT DUE TO SYMMETRY
CO2R(I,KP)=A1(I)*CO251(1,KP)+A2(I)*CO258(1,KP)
DCO2DT(I,KP)=H1M2*(A1(I)*CDT51(1,KP)+A2(I)*CDT58(1,KP))
D2CDT2(I,KP)=H1M3*(A1(I)*C2D51(1,KP)+A2(I)*C2D58(1,KP))
CO21(I,1,KP)=CO2R(I,KP)+DIFT(I,KP)*(DCO2DT(I,KP)+ &
HAF*DIFT(I,KP)*D2CDT2(I,KP))
215 CONTINUE
! THE TRANSMISSION FUNCTIONS USED IN SPA88 MAY BE COMPUTED NOW.
!---(IN THE 250 LOOP,DIFT REALLY SHOULD BE (I,1,K), BUT DIFT IS
! INVARIANT WITH RESPECT TO K,KP,AND SO (I,1,K)=(I,K,1))
DO 250 K=2,LP1
DO 250 I=MYIS,MYIE
CO2SP1(I,K)=CO2R1(I,K)+DIFT(I,K)*(DCO2D1(I,K)+HAF*DIFT(I,K)* &
D2CD21(I,K))
CO2SP2(I,K)=CO2R2(I,K)+DIFT(I,K)*(DCO2D2(I,K)+HAF*DIFT(I,K)* &
D2CD22(I,K))
250 CONTINUE
!
! NEXT THE CASE WHEN K=2...L
DO 220 K=2,L
DO 222 KP=K+1,LP1
DO 222 I=MYIS,MYIE
DIFT(I,KP)=(TDAV(I,KP)-TDAV(I,K))/ &
(TSTDAV(I,KP)-TSTDAV(I,K))
CO2R(I,KP)=A1(I)*CO251(KP,K)+A2(I)*CO258(KP,K)
DCO2DT(I,KP)=H1M2*(A1(I)*CDT51(KP,K)+A2(I)*CDT58(KP,K))
D2CDT2(I,KP)=H1M3*(A1(I)*C2D51(KP,K)+A2(I)*C2D58(KP,K))
CO21(I,KP,K)=CO2R(I,KP)+DIFT(I,KP)*(DCO2DT(I,KP)+ &
HAF*DIFT(I,KP)*D2CDT2(I,KP))
CO2R(I,KP)=A1(I)*CO251(K,KP)+A2(I)*CO258(K,KP)
DCO2DT(I,KP)=H1M2*(A1(I)*CDT51(K,KP)+A2(I)*CDT58(K,KP))
D2CDT2(I,KP)=H1M3*(A1(I)*C2D51(K,KP)+A2(I)*C2D58(K,KP))
CO21(I,K,KP)=CO2R(I,KP)+DIFT(I,KP)*(DCO2DT(I,KP)+ &
HAF*DIFT(I,KP)*D2CDT2(I,KP))
222 CONTINUE
220 CONTINUE
! FINALLY THE CASE WHEN K=KP,K=2..LP1
DO 206 K=2,LP1
DO 206 I=MYIS,MYIE
DIFT(I,K)=HAF*(VSUM3(I,K)+VSUM3(I,K-1))
CO2R(I,K)=A1(I)*CO251(K,K)+A2(I)*CO258(K,K)
DCO2DT(I,K)=H1M2*(A1(I)*CDT51(K,K)+A2(I)*CDT58(K,K))
D2CDT2(I,K)=H1M3*(A1(I)*C2D51(K,K)+A2(I)*C2D58(K,K))
CO21(I,K,K)=CO2R(I,K)+DIFT(I,K)*(DCO2DT(I,K)+ &
HAF*DIFT(I,K)*D2CDT2(I,K))
206 CONTINUE
!--- WE AREN'T DOING NBL TFS ON THE 100 CM-1 BANDS .
DO 260 K=1,L
DO 260 I=MYIS,MYIE
CO2NBL(I,K)=CO2MR(I,K)+VSUM3(I,K)*(CO2MD(I,K)+HAF* &
VSUM3(I,K)*CO2M2D(I,K))
260 CONTINUE
!***COMPUTE TEMP. COEFFICIENT BASED ON T(K) (SEE REF.2)
DO 264 K=1,LP1
DO 264 I=MYIS,MYIE
IF (T(I,K).LE.H25E2) THEN
TLSQU(I,K)=B0+(T(I,K)-H25E2)* &
(B1+(T(I,K)-H25E2)* &
(B2+B3*(T(I,K)-H25E2)))
ELSE
TLSQU(I,K)=B0
ENDIF
264 CONTINUE
!***APPLY TO ALL CO2 TFS
DO 280 K=1,LP1
DO 282 KP=1,LP1
DO 282 I=MYIS,MYIE
CO21(I,KP,K)=CO21(I,KP,K)*(ONE-TLSQU(I,KP))+TLSQU(I,KP)
282 CONTINUE
280 CONTINUE
DO 284 K=1,LP1
DO 286 I=MYIS,MYIE
CO2SP1(I,K)=CO2SP1(I,K)*(ONE-TLSQU(I,1))+TLSQU(I,1)
CO2SP2(I,K)=CO2SP2(I,K)*(ONE-TLSQU(I,1))+TLSQU(I,1)
286 CONTINUE
284 CONTINUE
DO 288 K=1,L
DO 290 I=MYIS,MYIE
CO2NBL(I,K)=CO2NBL(I,K)*(ONE-TLSQU(I,K))+TLSQU(I,K)
290 CONTINUE
288 CONTINUE
! CALL FST88(HEATRA,GRNFLX,TOPFLX, &
! QH2O,PRESS,P,DELP,DELP2,TEMP,T, &
! CLDFAC,NCLDS,KTOP,KBTM,CAMT, &
! CO21,CO2NBL,CO2SP1,CO2SP2, &
! VAR1,VAR2,VAR3,VAR4,CNTVAL, &
! TOTO3,TPHIO3,TOTPHI,TOTVO2, &
! EMX1,EMX2,EMPL, &
!
! BO3RND,AO3RND, &
!! T1,T2,T4 , EM1V,EM1VW, EM3V, &
! APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
! TEN,HP1,HAF,ONE,FOUR,HM1EZ,SKO3R, &
! AB15WD,SKC1R,RADCON,QUARTR,TWO, &
! HM6666M2,HMP66667,HMP5, &
! HP166666,H41666M2,RADCON1, &
! H16E1, H28E1, H25E2, H44194M2,H1P41819, &
! SKO2D, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
CALL FST88(HEATRA,GRNFLX,TOPFLX, &
QH2O,PRESS,P,DELP,DELP2,TEMP,T, &
CLDFAC,NCLDS,KTOP,KBTM,CAMT, &
CO21,CO2NBL,CO2SP1,CO2SP2, &
VAR1,VAR2,VAR3,VAR4,CNTVAL, &
TOTO3,TPHIO3,TOTPHI,TOTVO2, &
EMX1,EMX2,EMPL, &
!
BO3RND,AO3RND, &
! T1,T2,T4 , EM1V,EM1VW, EM3V, &
APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
TEN,HP1,HAF,ONE,FOUR,HM1EZ, &
RADCON,QUARTR,TWO, &
HM6666M2,HMP66667,HMP5, &
HP166666,H41666M2,RADCON1, &
H16E1, H28E1, H25E2, H44194M2,H1P41819, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
END SUBROUTINE LWR88
!---------------------------------------------------------------------
! SUBROUTINE FST88(HEATRA,GRNFLX,TOPFLX, &
! QH2O,PRESS,P,DELP,DELP2,TEMP,T, &
! CLDFAC,NCLDS,KTOP,KBTM,CAMT, &
! CO21,CO2NBL,CO2SP1,CO2SP2, &
! VAR1,VAR2,VAR3,VAR4,CNTVAL, &
! TOTO3,TPHIO3,TOTPHI,TOTVO2, &
! EMX1,EMX2,EMPL, &
! BO3RND,AO3RND, &
!! T1,T2,T4 , EM1V,EM1VW, EM3V, &
! APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
! TEN,HP1,HAF,ONE,FOUR,HM1EZ,SKO3R, &
! AB15WD,SKC1R,RADCON,QUARTR,TWO, &
! HM6666M2,HMP66667,HMP5, &
! HP166666,H41666M2,RADCON1, &
! H16E1, H28E1, H25E2, H44194M2,H1P41819, &
! SKO2D, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
SUBROUTINE FST88(HEATRA,GRNFLX,TOPFLX, & 2,10
QH2O,PRESS,P,DELP,DELP2,TEMP,T, &
CLDFAC,NCLDS,KTOP,KBTM,CAMT, &
CO21,CO2NBL,CO2SP1,CO2SP2, &
VAR1,VAR2,VAR3,VAR4,CNTVAL, &
TOTO3,TPHIO3,TOTPHI,TOTVO2, &
EMX1,EMX2,EMPL, &
BO3RND,AO3RND, &
! T1,T2,T4 , EM1V,EM1VW, EM3V, &
APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
TEN,HP1,HAF,ONE,FOUR,HM1EZ, &
RADCON,QUARTR,TWO, &
HM6666M2,HMP66667,HMP5, &
HP166666,H41666M2,RADCON1, &
H16E1, H28E1, H25E2, H44194M2,H1P41819, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
! INTEGER, PARAMETER :: NBLY=15
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
! REAL, INTENT(IN) :: TEN,HP1,HAF,ONE,FOUR,HM1EZ,SKO3R
REAL, INTENT(IN) :: TEN,HP1,HAF,ONE,FOUR,HM1EZ
! REAL, INTENT(IN) :: AB15WD,SKC1R,RADCON,QUARTR,TWO
REAL, INTENT(IN) :: RADCON,QUARTR,TWO
REAL, INTENT(IN) :: HM6666M2,HMP66667,HMP5
REAL, INTENT(IN) :: HP166666,H41666M2,RADCON1,H16E1, H28E1
! REAL, INTENT(IN) :: H25E2,H44194M2,H1P41819,SKO2D
REAL, INTENT(IN) :: H25E2,H44194M2,H1P41819
REAL,INTENT(IN),DIMENSION(NBLY) :: APCM,BPCM,ATPCM,BTPCM,ACOMB, &
BCOMB,BETACM
! REAL, INTENT(IN), DIMENSION(5040) :: T1,T2,T4,EM1V,EM1VW
! REAL, INTENT(IN), DIMENSION(5040) :: EM3V
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte*2+1) :: EMPL
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: TOTO3,TPHIO3,TOTPHI,CNTVAL,&
CO2SP1,CO2SP2
REAL, INTENT(IN),DIMENSION(its:ite,kts:kte+1,kts:kte+1) :: CLDFAC
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: CAMT,TOTVO2
INTEGER, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: KBTM,KTOP
INTEGER, INTENT(IN), DIMENSION(its:ite) :: NCLDS
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte) :: QH2O
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: PRESS,TEMP
REAL, INTENT(OUT), DIMENSION(its:ite,kts:kte) :: HEATRA
REAL, INTENT(OUT), DIMENSION(its:ite) :: GRNFLX,TOPFLX
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: P,T
REAL, INTENT(INOUT), DIMENSION(its:ite,kts:kte+1,kts:kte+1) :: CO21
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte) :: CO2NBL,DELP2, &
DELP,&
VAR1,VAR2,VAR3,VAR4
REAL, INTENT(IN), DIMENSION(3) :: BO3RND,AO3RND
REAL, INTENT(IN), DIMENSION(its:ite) :: EMX1,EMX2
REAL, DIMENSION(its:ite,kts:kte*2+1) :: TPL,EMD,ALP,C,CSUB,CSUB2
REAL, DIMENSION(its:ite,kts:kte*2+1) :: C2
INTEGER, DIMENSION(its:ite,kts:kte+1) :: IXO
REAL, DIMENSION(its:ite,kts:kte+1) :: VTMP3,FXO,DT,FXOE2,DTE2, &
SS1,CSOUR,TC,OSS,CSS,DTC,SS2,&
AVEPHI,E1CTS1,E1FLX, &
E1CTW1,DSORC,EMISS,FAC1,&
TO3SP,OVER1D,CNTTAU,TOTEVV,&
CO2SP,FLX,AVMO3, &
AVPHO3,AVVO2,CONT1D,TO31D,EMISDG,&
DELPR1
REAL, DIMENSION(its:ite,kts:kte+1) :: EMISSB,DELPR2,CONTDG,TO3DG,HEATEM,&
VSUM1,FLXNET,Z1
REAL, DIMENSION(its:ite,kts:kte+1,NBLY) :: SORC
REAL, DIMENSION(its:ite,kts:kte) :: E1CTS2,E1CTW2,TO3SPC,RLOG,EXCTS,&
CTSO3,CTS
REAL, DIMENSION(its:ite) :: GXCTS,FLX1E1
REAL, DIMENSION(its:ite) :: PTOP,PBOT,FTOP,FBOT,DELPTC
REAL, DIMENSION(its:ite,2) :: FXOSP,DTSP,EMSPEC
! REAL, DIMENSION(28,NBLY) :: SOURCE,DSRCE
INTEGER :: K, I,KP,LLM2,J1,J3,KMAX,KMIN,KCLDS,ICNT,LLM1
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE,LLP1,LL,KK,KLEN
L=kte
LP1=L+1; LP2=L+2; LP3=L+3; LLP1 = 2*L + 1
LM1=L-1; LM2=L-2; LM3=L-3; LL = 2*L
LLM2 = LL-2; LLM1=LL-1
MYIS=its; MYIE=ite
!
DO 101 K=1,LP1
DO 101 I=MYIS,MYIE
!---TEMP. INDICES FOR E1,SOURCE
VTMP3(I,K)=AINT(TEMP(I,K)*HP1)
FXO(I,K)=VTMP3(I,K)-9.
DT(I,K)=TEMP(I,K)-TEN*VTMP3(I,K)
!---INTEGER INDEX FOR SOURCE (USED IMMEDIATELY)
IXO(I,K)=FXO(I,K)
101 CONTINUE
DO 103 k=1,L
DO 103 I=MYIS,MYIE
!---TEMP. INDICES FOR E2 (KP=1 LAYER NOT USED IN FLUX CALCULATIONS)
VTMP3(I,K)=AINT(T(I,K+1)*HP1)
FXOE2(I,K)=VTMP3(I,K)-9.
DTE2(I,K)=T(I,K+1)-TEN*VTMP3(I,K)
103 CONTINUE
!---SPECIAL CASE TO HANDLE KP=LP1 LAYER AND SPECIAL E2 CALCS.
DO 105 I=MYIS,MYIE
FXOE2(I,LP1)=FXO(I,L)
DTE2(I,LP1)=DT(I,L)
FXOSP(I,1)=FXOE2(I,LM1)
FXOSP(I,2)=FXO(I,LM1)
DTSP(I,1)=DTE2(I,LM1)
DTSP(I,2)=DT(I,LM1)
105 CONTINUE
!
!---SOURCE FUNCTION FOR COMBINED BAND 1
DO 4114 I=MYIS,MYIE
DO 4114 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),1)
DSORC(I,K)=DSRCE(IXO(I,K),1)
4114 CONTINUE
DO 4112 K=1,LP1
DO 4112 I=MYIS,MYIE
SORC(I,K,1)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4112 CONTINUE
!---SOURCE FUNCTION FOR COMBINED BAND 2
DO 4214 I=MYIS,MYIE
DO 4214 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),2)
DSORC(I,K)=DSRCE(IXO(I,K),2)
4214 CONTINUE
DO 4212 K=1,LP1
DO 4212 I=MYIS,MYIE
SORC(I,K,2)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4212 CONTINUE
!---SOURCE FUNCTION FOR COMBINED BAND 3
DO 4314 I=MYIS,MYIE
DO 4314 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),3)
DSORC(I,K)=DSRCE(IXO(I,K),3)
4314 CONTINUE
DO 4312 K=1,LP1
DO 4312 I=MYIS,MYIE
SORC(I,K,3)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4312 CONTINUE
!---SOURCE FUNCTION FOR COMBINED BAND 4
DO 4414 I=MYIS,MYIE
DO 4414 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),4)
DSORC(I,K)=DSRCE(IXO(I,K),4)
4414 CONTINUE
DO 4412 K=1,LP1
DO 4412 I=MYIS,MYIE
SORC(I,K,4)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4412 CONTINUE
!---SOURCE FUNCTION FOR COMBINED BAND 5
DO 4514 I=MYIS,MYIE
DO 4514 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),5)
DSORC(I,K)=DSRCE(IXO(I,K),5)
4514 CONTINUE
DO 4512 K=1,LP1
DO 4512 I=MYIS,MYIE
SORC(I,K,5)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4512 CONTINUE
!---SOURCE FUNCTION FOR COMBINED BAND 6
DO 4614 I=MYIS,MYIE
DO 4614 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),6)
DSORC(I,K)=DSRCE(IXO(I,K),6)
4614 CONTINUE
DO 4612 K=1,LP1
DO 4612 I=MYIS,MYIE
SORC(I,K,6)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4612 CONTINUE
!---SOURCE FUNCTION FOR COMBINED BAND 7
DO 4714 I=MYIS,MYIE
DO 4714 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),7)
DSORC(I,K)=DSRCE(IXO(I,K),7)
4714 CONTINUE
DO 4712 K=1,LP1
DO 4712 I=MYIS,MYIE
SORC(I,K,7)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4712 CONTINUE
!---SOURCE FUNCTION FOR COMBINED BAND 8
DO 4814 I=MYIS,MYIE
DO 4814 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),8)
DSORC(I,K)=DSRCE(IXO(I,K),8)
4814 CONTINUE
DO 4812 K=1,LP1
DO 4812 I=MYIS,MYIE
SORC(I,K,8)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4812 CONTINUE
!---SOURCE FUNCTION FOR BAND 9 (560-670 CM-1)
DO 4914 I=MYIS,MYIE
DO 4914 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),9)
DSORC(I,K)=DSRCE(IXO(I,K),9)
4914 CONTINUE
DO 4912 K=1,LP1
DO 4912 I=MYIS,MYIE
SORC(I,K,9)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
4912 CONTINUE
!---SOURCE FUNCTION FOR BAND 10 (670-800 CM-1)
DO 5014 I=MYIS,MYIE
DO 5014 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),10)
DSORC(I,K)=DSRCE(IXO(I,K),10)
5014 CONTINUE
DO 5012 K=1,LP1
DO 5012 I=MYIS,MYIE
SORC(I,K,10)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
5012 CONTINUE
!---SOURCE FUNCTION FOR BAND 11 (800-900 CM-1)
DO 5114 I=MYIS,MYIE
DO 5114 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),11)
DSORC(I,K)=DSRCE(IXO(I,K),11)
5114 CONTINUE
DO 5112 K=1,LP1
DO 5112 I=MYIS,MYIE
SORC(I,K,11)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
5112 CONTINUE
!---SOURCE FUNCTION FOR BAND 12 (900-990 CM-1)
DO 5214 I=MYIS,MYIE
DO 5214 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),12)
DSORC(I,K)=DSRCE(IXO(I,K),12)
5214 CONTINUE
DO 5212 K=1,LP1
DO 5212 I=MYIS,MYIE
SORC(I,K,12)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
5212 CONTINUE
!---SOURCE FUNCTION FOR BAND 13 (990-1070 CM-1)
DO 5314 I=MYIS,MYIE
DO 5314 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),13)
DSORC(I,K)=DSRCE(IXO(I,K),13)
5314 CONTINUE
DO 5312 K=1,LP1
DO 5312 I=MYIS,MYIE
SORC(I,K,13)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
5312 CONTINUE
!---SOURCE FUNCTION FOR BAND 14 (1070-1200 CM-1)
DO 5414 I=MYIS,MYIE
DO 5414 K=1,LP1
VTMP3(I,K)=SOURCE(IXO(I,K),14)
DSORC(I,K)=DSRCE(IXO(I,K),14)
5414 CONTINUE
DO 5412 K=1,LP1
DO 5412 I=MYIS,MYIE
SORC(I,K,14)=VTMP3(I,K)+DT(I,K)*DSORC(I,K)
5412 CONTINUE
!
! THE FOLLOWING SUBROUTINE OBTAINS NLTE SOURCE FUNCTION FOR CO2
!
!
! CALL NLTE
!
!
!---OBTAIN SPECIAL SOURCE FUNCTIONS FOR THE 15 UM BAND (CSOUR)
! AND THE WINDOW REGION (SS1)
DO 131 K=1,LP1
DO 131 I=MYIS,MYIE
SS1(I,K)=SORC(I,K,11)+SORC(I,K,12)+SORC(I,K,14)
131 CONTINUE
DO 143 K=1,LP1
DO 143 I=MYIS,MYIE
CSOUR(I,K)=SORC(I,K,9)+SORC(I,K,10)
143 CONTINUE
!
!---COMPUTE TEMP**4 (TC) AND VERTICAL TEMPERATURE DIFFERENCES
! (OSS,CSS,SS2,DTC). ALL THESE WILL BE USED LATER IN FLUX COMPUTA-
! TIONS.
!
DO 901 K=1,LP1
DO 901 I=MYIS,MYIE
TC(I,K)=(TEMP(I,K)*TEMP(I,K))**2
901 CONTINUE
DO 903 K=1,L
DO 903 I=MYIS,MYIE
OSS(I,K+1)=SORC(I,K+1,13)-SORC(I,K,13)
CSS(I,K+1)=CSOUR(I,K+1)-CSOUR(I,K)
DTC(I,K+1)=TC(I,K+1)-TC(I,K)
SS2(I,K+1)=SS1(I,K+1)-SS1(I,K)
903 CONTINUE
!
!
!---THE FOLLOWIMG IS A DRASTIC REWRITE OF THE RADIATION CODE TO
! (LARGELY) ELIMINATE THREE-DIMENSIONAL ARRAYS. THE CODE WORKS
! ON THE FOLLOWING PRINCIPLES:
!
! LET K = FIXED FLUX LEVEL, KP = VARYING FLUX LEVEL
! THEN FLUX(K)=SUM OVER KP : (DELTAB(KP)*TAU(KP,K))
! OVER ALL KP'S, FROM 1 TO LP1.
!
! WE CAN BREAK DOWN THE CALCULATIONS FOR ALL K'S AS FOLLOWS:
!
! FOR ALL K'S K=1 TO LP1:
! FLUX(K)=SUM OVER KP : (DELTAB(KP)*TAU(KP,K)) (1)
! OVER ALL KP'S, FROM K+1 TO LP1
! AND
! FOR KP FROM K+1 TO LP1:
! FLUX(KP) = DELTAB(K)*TAU(K,KP) (2)
!
! NOW IF TAU(K,KP)=TAU(KP,K) (SYMMETRICAL ARRAYS)
! WE CAN COMPUTE A 1-DIMENSIONAL ARRAY TAU1D(KP) FROM
! K+1 TO LP1, EACH TIME K IS INCREMENTED.
! EQUATIONS (1) AND (2) THEN BECOME:
!
! TAU1D(KP) = (VALUES FOR TAU(KP,K) AT THE PARTICULAR K)
! FLUX(K) = SUM OVER KP : (DELTAB(KP)*TAU1D(KP)) (3)
! FLUX(KP) = DELTAB(K)*TAU1D(KP) (4)
!
! THE TERMS FOR TAU (K,K) AND OTHER SPECIAL TERMS (FOR
! NEARBY LAYERS) MUST, OF COURSE, BE HANDLED SEPARATELY, AND
! WITH CARE.
!
! COMPUTE "UPPER TRIANGLE" TRANSMISSION FUNCTIONS FOR
! THE 9.6 UM BAND (TO3SP) AND THE 15 UM BAND (OVER1D). ALSO,
! THE
! STAGE 1...COMPUTE O3 ,OVER TRANSMISSION FCTNS AND AVEPHI
!---DO K=1 CALCULATION (FROM FLUX LAYER KK TO THE TOP) SEPARATELY
! AS VECTORIZATION IS IMPROVED,AND OZONE CTS TRANSMISSIVITY
! MAY BE EXTRACTED HERE.
DO 3021 K=1,L
DO 3021 I=MYIS,MYIE
AVEPHI(I,K)=TOTPHI(I,K+1)
3021 CONTINUE
!---IN ORDER TO PROPERLY EVALUATE EMISS INTEGRATED OVER THE (LP1)
! LAYER, A SPECIAL EVALUATION OF EMISS IS DONE. THIS REQUIRES
! A SPECIAL COMPUTATION OF AVEPHI, AND IT IS STORED IN THE
! (OTHERWISE VACANT) LP1'TH POSITION
!
DO 803 I=MYIS,MYIE
AVEPHI(I,LP1)=AVEPHI(I,LM1)+EMX1(I)
803 CONTINUE
! COMPUTE FLUXES FOR K=1
CALL E1E290(E1CTS1,E1CTS2,E1FLX,E1CTW1,E1CTW2,EMISS, &
FXO,DT,FXOE2,DTE2,AVEPHI,TEMP,T, &
! T1,T2,T4 ,EM1V,EM1VW, &
H16E1,TEN,HP1,H28E1,HAF, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
DO 302 K=1,L
DO 302 I=MYIS,MYIE
FAC1(I,K)=BO3RND(2)*TPHIO3(I,K+1)/TOTO3(I,K+1)
TO3SPC(I,K)=HAF*(FAC1(I,K)* &
(SQRT(ONE+(FOUR*AO3RND(2)*TOTO3(I,K+1))/FAC1(I,K))-ONE))
! FOR K=1, TO3SP IS USED INSTEAD OF TO31D (THEY ARE EQUAL IN THIS
! CASE); TO3SP IS PASSED TO SPA90, WHILE TO31D IS A WORK-ARRAY.
TO3SP(I,K)=EXP(HM1EZ*(TO3SPC(I,K)+SKO3R*TOTVO2(I,K+1)))
OVER1D(I,K)=EXP(HM1EZ*(SQRT(AB15WD*TOTPHI(I,K+1))+ &
SKC1R*TOTVO2(I,K+1)))
!---BECAUSE ALL CONTINUUM TRANSMISSIVITIES ARE OBTAINED FROM THE
! 2-D QUANTITY CNTTAU (AND ITS RECIPROCAL TOTEVV) WE STORE BOTH
! OF THESE HERE. FOR K=1, CONT1D EQUALS CNTTAU
CNTTAU(I,K)=EXP(HM1EZ*TOTVO2(I,K+1))
TOTEVV(I,K)=1./CNTTAU(I,K)
302 CONTINUE
DO 3022 K=1,L
DO 3022 I=MYIS,MYIE
CO2SP(I,K+1)=OVER1D(I,K)*CO21(I,1,K+1)
3022 CONTINUE
DO 3023 K=1,L
DO 3023 I=MYIS,MYIE
CO21(I,K+1,1)=CO21(I,K+1,1)*OVER1D(I,K)
3023 CONTINUE
!---RLOG IS THE NBL AMOUNT FOR THE 15 UM BAND CALCULATION
DO 1808 I=MYIS,MYIE
RLOG(I,1)=OVER1D(I,1)*CO2NBL(I,1)
1808 CONTINUE
!---THE TERMS WHEN KP=1 FOR ALL K ARE THE PHOTON EXCHANGE WITH
! THE TOP OF THE ATMOSPHERE, AND ARE OBTAINED DIFFERENTLY THAN
! THE OTHER CALCULATIONS
DO 305 K=2,LP1
DO 305 I=MYIS,MYIE
FLX(I,K)= (TC(I,1)*E1FLX(I,K) &
+SS1(I,1)*CNTTAU(I,K-1) &
+SORC(I,1,13)*TO3SP(I,K-1) &
+CSOUR(I,1)*CO2SP(I,K)) &
*CLDFAC(I,1,K)
305 CONTINUE
DO 307 I=MYIS,MYIE
FLX(I,1)= TC(I,1)*E1FLX(I,1)+SS1(I,1)+SORC(I,1,13) &
+CSOUR(I,1)
307 CONTINUE
!---THE KP TERMS FOR K=1...
DO 303 KP=2,LP1
DO 303 I=MYIS,MYIE
FLX(I,1)=FLX(I,1)+(OSS(I,KP)*TO3SP(I,KP-1) &
+SS2(I,KP)*CNTTAU(I,KP-1) &
+CSS(I,KP)*CO21(I,KP,1) &
+DTC(I,KP)*EMISS(I,KP-1))*CLDFAC(I,KP,1)
303 CONTINUE
! SUBROUTINE SPA88 IS CALLED TO OBTAIN EXACT CTS FOR WATER
! CO2 AND O3, AND APPROXIMATE CTS CO2 AND O3 CALCULATIONS.
!
CALL SPA88(EXCTS,CTSO3,GXCTS,SORC,CSOUR, &
CLDFAC,TEMP,PRESS,VAR1,VAR2, &
P,DELP,DELP2,TOTVO2,TO3SP,TO3SPC, &
CO2SP1,CO2SP2,CO2SP, &
APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
H25E2,ONE,H44194M2,H1P41819,HAF,HM1EZ,TWO, &
! SKO2D,RADCON, &
RADCON, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!
! THIS SECTION COMPUTES THE EMISSIVITY CTS HEATING RATES FOR 2
! EMISSIVITY BANDS: THE 0-160,1200-2200 CM-1 BAND AND THE 800-
! 990,1070-1200 CM-1 BAND. THE REMAINING CTS COMTRIBUTIONS ARE
! CONTAINED IN CTSO3, COMPUTED IN SPA88.
!
DO 998 I=MYIS,MYIE
VTMP3(I,1)=1.
998 CONTINUE
DO 999 K=1,L
DO 999 I=MYIS,MYIE
VTMP3(I,K+1)=CNTTAU(I,K)*CLDFAC(I,K+1,1)
999 CONTINUE
DO 1001 K=1,L
DO 1001 I=MYIS,MYIE
CTS(I,K)=RADCON*DELP(I,K)*(TC(I,K)* &
(E1CTW2(I,K)*CLDFAC(I,K+1,1)-E1CTW1(I,K)*CLDFAC(I,K,1)) + &
SS1(I,K)*(VTMP3(I,K+1)-VTMP3(I,K)))
1001 CONTINUE
!
DO 1011 K=1,L
DO 1011 I=MYIS,MYIE
VTMP3(I,K)=TC(I,K)*(CLDFAC(I,K,1)*(E1CTS1(I,K)-E1CTW1(I,K)) - &
CLDFAC(I,K+1,1)*(E1CTS2(I,K)-E1CTW2(I,K)))
1011 CONTINUE
DO 1012 I=MYIS,MYIE
FLX1E1(I)=TC(I,LP1)*CLDFAC(I,LP1,1)* &
(E1CTS1(I,LP1)-E1CTW1(I,LP1))
1012 CONTINUE
DO 1014 K=1,L
DO 1013 I=MYIS,MYIE
FLX1E1(I)=FLX1E1(I)+VTMP3(I,K)
1013 CONTINUE
1014 CONTINUE
!
!---NOW REPEAT FLUX CALCULATIONS FOR THE K=2..LM1 CASES.
! CALCULATIONS FOR FLUX LEVEL L AND LP1 ARE DONE SEPARATELY, AS ALL
! EMISSIVITY AND CO2 CALCULATIONS ARE SPECIAL CASES OR NEARBY LAYERS.
!
DO 321 K=2,LM1
KLEN=K
!
DO 3218 KK=1,LP1-K
DO 3218 I=MYIS,MYIE
AVEPHI(I,KK+K-1)=TOTPHI(I,KK+K)-TOTPHI(I,K)
3218 CONTINUE
DO 1803 I=MYIS,MYIE
AVEPHI(I,LP1)=AVEPHI(I,LM1)+EMX1(I)
1803 CONTINUE
!---COMPUTE EMISSIVITY FLUXES (E2) FOR THIS CASE. NOTE THAT
! WE HAVE OMITTED THE NEARBY LATER CASE (EMISS(I,K,K)) AS WELL
! AS ALL CASES WITH K=L OR LP1. BUT THESE CASES HAVE ALWAYS
! BEEN HANDLED AS SPECIAL CASES, SO WE MAY AS WELL COMPUTE
! THEIR FLUXES SEPARASTELY.
!
CALL E290(EMISSB,EMISS,AVEPHI,KLEN,FXOE2,DTE2, &
! T1,T2,T4, &
H16E1,HP1,H28E1,HAF,TEN, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
DO 322 KK=1,LP1-K
DO 322 I=MYIS,MYIE
AVMO3(I,KK+K-1)=TOTO3(I,KK+K)-TOTO3(I,K)
AVPHO3(I,KK+K-1)=TPHIO3(I,KK+K)-TPHIO3(I,K)
AVVO2(I,KK+K-1)=TOTVO2(I,KK+K)-TOTVO2(I,K)
CONT1D(I,KK+K-1)=CNTTAU(I,KK+K-1)*TOTEVV(I,K-1)
322 CONTINUE
!
DO 3221 KK=1,LP1-K
DO 3221 I=MYIS,MYIE
FAC1(I,K+KK-1)=BO3RND(2)*AVPHO3(I,K+KK-1)/AVMO3(I,K+KK-1)
VTMP3(I,K+KK-1)=HAF*(FAC1(I,K+KK-1)* &
(SQRT(ONE+(FOUR*AO3RND(2)*AVMO3(I,K+KK-1))/ &
FAC1(I,K+KK-1))-ONE))
TO31D(I,K+KK-1)=EXP(HM1EZ*(VTMP3(I,K+KK-1) &
+SKO3R*AVVO2(I,K+KK-1)))
OVER1D(I,K+KK-1)=EXP(HM1EZ*(SQRT(AB15WD*AVEPHI(I,K+KK-1))+ &
SKC1R*AVVO2(I,K+KK-1)))
CO21(I,K+KK,K)=OVER1D(I,K+KK-1)*CO21(I,K+KK,K)
3221 CONTINUE
DO 3223 KP=K+1,LP1
DO 3223 I=MYIS,MYIE
CO21(I,K,KP)=OVER1D(I,KP-1)*CO21(I,K,KP)
3223 CONTINUE
!---RLOG IS THE NBL AMOUNT FOR THE 15 UM BAND CALCULATION
DO 1804 I=MYIS,MYIE
RLOG(I,K)=OVER1D(I,K)*CO2NBL(I,K)
1804 CONTINUE
!---THE KP TERMS FOR ARBIRRARY K..
DO 3423 KP=K+1,LP1
DO 3423 I=MYIS,MYIE
FLX(I,K)=FLX(I,K)+(OSS(I,KP)*TO31D(I,KP-1) &
+SS2(I,KP)*CONT1D(I,KP-1) &
+CSS(I,KP)*CO21(I,KP,K) &
+DTC(I,KP)*EMISS(I,KP-1))*CLDFAC(I,KP,K)
3423 CONTINUE
DO 3425 KP=K+1,LP1
DO 3425 I=MYIS,MYIE
FLX(I,KP)=FLX(I,KP)+(OSS(I,K)*TO31D(I,KP-1) &
+SS2(I,K)*CONT1D(I,KP-1) &
+CSS(I,K)*CO21(I,K,KP) &
+DTC(I,K)*EMISSB(I,KP-1))*CLDFAC(I,K,KP)
3425 CONTINUE
321 CONTINUE
!
DO 821 I=MYIS,MYIE
TPL(I,1)=TEMP(I,L)
TPL(I,LP1)=HAF*(T(I,LP1)+TEMP(I,L))
TPL(I,LLP1)=HAF*(T(I,L)+TEMP(I,L))
821 CONTINUE
DO 823 K=2,L
DO 823 I=MYIS,MYIE
TPL(I,K)=T(I,K)
TPL(I,K+L)=T(I,K)
823 CONTINUE
!
!---E2 FUNCTIONS ARE REQUIRED IN THE NBL CALCULATIONS FOR 2 CASES,
! DENOTED (IN OLD CODE) AS (L,LP1) AND (LP1,LP1)
DO 833 I=MYIS,MYIE
AVEPHI(I,1)=VAR2(I,L)
AVEPHI(I,2)=VAR2(I,L)+EMPL(I,L)
833 CONTINUE
CALL E2SPEC(EMISS,AVEPHI,FXOSP,DTSP, &
! T1,T2,T4, &
H16E1,TEN,H28E1,HP1, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!
! CALL E3V88 FOR NBL H2O TRANSMISSIVITIES
! CALL E3V88(EMD,TPL,EMPL,EM3V, &
CALL E3V88(EMD,TPL,EMPL, &
TEN,HP1,H28E1,H16E1, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!
! COMPUTE NEARBY LAYER AND SPECIAL-CASE TRANSMISSIVITIES FOR EMISS
! USING METHODS FOR H2O GIVEN IN REF. (4)
DO 851 K=2,L
DO 851 I=MYIS,MYIE
EMISDG(I,K)=EMD(I,K+L)+EMD(I,K)
851 CONTINUE
!
! NOTE THAT EMX1/2 (PRESSURE SCALED PATHS) ARE NOW COMPUTED IN
! LWR88
DO 861 I=MYIS,MYIE
EMSPEC(I,1)=(EMD(I,1)*EMPL(I,1)-EMD(I,LP1)*EMPL(I,LP1))/ &
EMX1(I) + QUARTR*(EMISS(I,1)+EMISS(I,2))
EMISDG(I,LP1)=TWO*EMD(I,LP1)
EMSPEC(I,2)=TWO*(EMD(I,1)*EMPL(I,1)-EMD(I,LLP1)*EMPL(I,LLP1))/ &
EMX2(I)
861 CONTINUE
DO 331 I=MYIS,MYIE
FAC1(I,L)=BO3RND(2)*VAR4(I,L)/VAR3(I,L)
VTMP3(I,L)=HAF*(FAC1(I,L)* &
(SQRT(ONE+(FOUR*AO3RND(2)*VAR3(I,L))/FAC1(I,L))-ONE))
TO31D(I,L)=EXP(HM1EZ*(VTMP3(I,L)+SKO3R*CNTVAL(I,L)))
OVER1D(I,L)=EXP(HM1EZ*(SQRT(AB15WD*VAR2(I,L))+ &
SKC1R*CNTVAL(I,L)))
CONT1D(I,L)=CNTTAU(I,L)*TOTEVV(I,LM1)
RLOG(I,L)=OVER1D(I,L)*CO2NBL(I,L)
331 CONTINUE
DO 618 K=1,L
DO 618 I=MYIS,MYIE
RLOG(I,K)=LOG(RLOG(I,K))
618 CONTINUE
DO 601 K=1,LM1
DO 601 I=MYIS,MYIE
DELPR1(I,K+1)=DELP(I,K+1)*(PRESS(I,K+1)-P(I,K+1))
ALP(I,LP1+K-1)=-SQRT(DELPR1(I,K+1))*RLOG(I,K+1)
601 CONTINUE
DO 603 K=1,L
DO 603 I=MYIS,MYIE
DELPR2(I,K+1)=DELP(I,K)*(P(I,K+1)-PRESS(I,K))
ALP(I,K)=-SQRT(DELPR2(I,K+1))*RLOG(I,K)
603 CONTINUE
DO 625 I=MYIS,MYIE
ALP(I,LL)=-RLOG(I,L)
ALP(I,LLP1)=-RLOG(I,L)*SQRT(DELP(I,L)*(P(I,LP1)-PRESS(I,LM1)))
625 CONTINUE
! THE FIRST COMPUTATION IS FOR THE 15 UM BAND,WITH THE
! FOR THE COMBINED H2O AND CO2 TRANSMISSION FUNCTION.
!
! PERFORM NBL COMPUTATIONS FOR THE 15 UM BAND
!***THE STATEMENT FUNCTION SF IN PREV. VERSIONS IS NOW EXPLICITLY
! EVALUATED.
DO 631 K=1,LLP1
DO 631 I=MYIS,MYIE
C(I,K)=ALP(I,K)*(HMP66667+ALP(I,K)*(QUARTR+ALP(I,K)*HM6666M2))
631 CONTINUE
DO 641 I=MYIS,MYIE
CO21(I,LP1,LP1)=ONE+C(I,L)
CO21(I,LP1,L)=ONE+(DELP2(I,L)*C(I,LL)-(PRESS(I,L)-P(I,L))* &
C(I,LLM1))/(P(I,LP1)-PRESS(I,L))
CO21(I,L,LP1)=ONE+((P(I,LP1)-PRESS(I,LM1))*C(I,LLP1)- &
(P(I,LP1)-PRESS(I,L))*C(I,L))/(PRESS(I,L)-PRESS(I,LM1))
641 CONTINUE
DO 643 K=2,L
DO 643 I=MYIS,MYIE
CO21(I,K,K)=ONE+HAF*(C(I,LM1+K)+C(I,K-1))
643 CONTINUE
!
! COMPUTE NEARBY-LAYER TRANSMISSIVITIES FOR THE O3 BAND AND FOR THE
! ONE-BAND CONTINUUM BAND (TO3 AND EMISS2). THE SF2 FUNCTION IS
! USED. THE METHOD IS THE SAME AS DESCRIBED FOR CO2 IN REF (4).
DO 651 K=1,LM1
DO 651 I=MYIS,MYIE
CSUB(I,K+1)=CNTVAL(I,K+1)*DELPR1(I,K+1)
CSUB(I,LP1+K-1)=CNTVAL(I,K)*DELPR2(I,K+1)
651 CONTINUE
!---THE SF2 FUNCTION IN PREV. VERSIONS IS NOW EXPLICITLY EVALUATED
DO 655 K=1,LLM2
DO 655 I=MYIS,MYIE
CSUB2(I,K+1)=SKO3R*CSUB(I,K+1)
C(I,K+1)=CSUB(I,K+1)*(HMP5+CSUB(I,K+1)* &
(HP166666-CSUB(I,K+1)*H41666M2))
C2(I,K+1)=CSUB2(I,K+1)*(HMP5+CSUB2(I,K+1)* &
(HP166666-CSUB2(I,K+1)*H41666M2))
655 CONTINUE
DO 661 I=MYIS,MYIE
CONTDG(I,LP1)=1.+C(I,LLM1)
TO3DG(I,LP1)=1.+C2(I,LLM1)
661 CONTINUE
DO 663 K=2,L
DO 663 I=MYIS,MYIE
CONTDG(I,K)=ONE+HAF*(C(I,K)+C(I,LM1+K))
TO3DG(I,K)=ONE+HAF*(C2(I,K)+C2(I,LM1+K))
663 CONTINUE
!---NOW OBTAIN FLUXES
!
! FOR THE DIAGONAL TERMS...
DO 871 K=2,LP1
DO 871 I=MYIS,MYIE
FLX(I,K)=FLX(I,K)+(DTC(I,K)*EMISDG(I,K) &
+SS2(I,K)*CONTDG(I,K) &
+OSS(I,K)*TO3DG(I,K) &
+CSS(I,K)*CO21(I,K,K))*CLDFAC(I,K,K)
871 CONTINUE
! FOR THE TWO OFF-DIAGONAL TERMS...
DO 873 I=MYIS,MYIE
FLX(I,L)=FLX(I,L)+(CSS(I,LP1)*CO21(I,LP1,L) &
+DTC(I,LP1)*EMSPEC(I,2) &
+OSS(I,LP1)*TO31D(I,L) &
+SS2(I,LP1)*CONT1D(I,L))*CLDFAC(I,LP1,L)
FLX(I,LP1)=FLX(I,LP1)+(CSS(I,L)*CO21(I,L,LP1) &
+OSS(I,L)*TO31D(I,L) &
+SS2(I,L)*CONT1D(I,L) &
+DTC(I,L)*EMSPEC(I,1))*CLDFAC(I,L,LP1)
873 CONTINUE
!
! FINAL SECTION OBTAINS EMISSIVITY HEATING RATES,
! TOTAL HEATING RATES AND THE FLUX AT THE GROUND
!
! .....CALCULATE THE EMISSIVITY HEATING RATES
DO 1101 K=1,L
DO 1101 I=MYIS,MYIE
HEATEM(I,K)=RADCON*(FLX(I,K+1)-FLX(I,K))*DELP(I,K)
1101 CONTINUE
! .....CALCULATE THE TOTAL HEATING RATES
DO 1103 K=1,L
DO 1103 I=MYIS,MYIE
HEATRA(I,K)=HEATEM(I,K)-CTS(I,K)-CTSO3(I,K)+EXCTS(I,K)
1103 CONTINUE
! .....CALCULATE THE FLUX AT EACH FLUX LEVEL USING THE FLUX AT THE
! TOP (FLX1E1+GXCTS) AND THE INTEGRAL OF THE HEATING RATES (VSUM1)
DO 1111 K=1,L
DO 1111 I=MYIS,MYIE
VSUM1(I,K)=HEATRA(I,K)*DELP2(I,K)*RADCON1
1111 CONTINUE
DO 1115 I=MYIS,MYIE
TOPFLX(I)=FLX1E1(I)+GXCTS(I)
FLXNET(I,1)=TOPFLX(I)
1115 CONTINUE
!---ONLY THE SURFACE VALUE OF FLUX (GRNFLX) IS NEEDED UNLESS
! THE THICK CLOUD SECTION IS INVOKED.
DO 1123 K=2,LP1
DO 1123 I=MYIS,MYIE
FLXNET(I,K)=FLXNET(I,K-1)+VSUM1(I,K-1)
1123 CONTINUE
DO 1125 I=MYIS,MYIE
GRNFLX(I)=FLXNET(I,LP1)
1125 CONTINUE
!
! THIS IS THE THICK CLOUD SECTION.OPTIONALLY,IF THICK CLOUD
! FLUXES ARE TO BE "CONVECTIVELY ADJUSTED",IE,DF/DP IS CONSTANT,
! FOR CLOUDY PART OF GRID POINT, THE FOLLOWING CODE IS EXECUTED.
!***FIRST,COUNT THE NUMBER OF CLOUDS ALONG THE LAT. ROW. SKIP THE
! ENTIRE THICK CLOUD COMPUTATION OF THERE ARE NO CLOUDS.
ICNT=0
DO 1301 I=MYIS,MYIE
ICNT=ICNT+NCLDS(I)
1301 CONTINUE
IF (ICNT.EQ.0) GO TO 6999
!---FIND THE MAXIMUM NUMBER OF CLOUDS IN THE LATITUDE ROW
KCLDS=NCLDS(MYIS)
DO 2106 I=MYIS,MYIE
KCLDS=MAX(NCLDS(I),KCLDS)
2106 CONTINUE
!
!
!***OBTAIN THE PRESSURES AND FLUXES OF THE TOP AND BOTTOM OF
! THE NC'TH CLOUD (IT IS ASSUMED THAT ALL KTOP AND KBTM'S HAVE
! BEEN DEFINED!).
DO 1361 KK=1,KCLDS
KMIN=LP1
KMAX=0
DO 1362 I=MYIS,MYIE
J1=KTOP(I,KK+1)
! IF (J1.EQ.1) GO TO 1362
J3=KBTM(I,KK+1)
IF (J3.GT.J1) THEN
PTOP(I)=P(I,J1)
PBOT(I)=P(I,J3+1)
FTOP(I)=FLXNET(I,J1)
FBOT(I)=FLXNET(I,J3+1)
!***OBTAIN THE "FLUX DERIVATIVE" DF/DP (DELPTC)
DELPTC(I)=(FTOP(I)-FBOT(I))/(PTOP(I)-PBOT(I))
KMIN=MIN(KMIN,J1)
KMAX=MAX(KMAX,J3)
ENDIF
1362 CONTINUE
KMIN=KMIN+1
!***CALCULATE THE TOT. FLUX CHG. FROM THE TOP OF THE CLOUD, FOR
! ALL LEVELS.
DO 1365 K=KMIN,KMAX
DO 1363 I=MYIS,MYIE
! IF (KTOP(I,KK+1).EQ.1) GO TO 1363
IF(KTOP(I,KK+1).LT.K .AND. K.LE.KBTM(I,KK+1)) THEN
Z1(I,K)=(P(I,K)-PTOP(I))*DELPTC(I)+FTOP(I)
!ORIGINAL FLXNET(I,K)=FLXNET(I,K)*(ONE-CAMT(I,KK+1)) +
!ORIGINAL1 Z1(I,K)*CAMT(I,KK+1)
FLXNET(I,K)=Z1(I,K)
ENDIF
1363 CONTINUE
1365 CONTINUE
1361 CONTINUE
!***USING THIS FLUX CHG. IN THE CLOUDY PART OF THE GRID BOX, OBTAIN
! THE NEW FLUXES, WEIGHTING THE CLEAR AND CLOUDY FLUXES:AGAIN, ONLY
! THE FLUXES IN THICK-CLOUD LEVELS WILL EVENTUALLY BE USED.
! DO 6051 K=1,LP1
! DO 6051 I=MYIS,MYIE
! FLXNET(I,K)=FLXNET(I,K)*(ONE-CAMT(I,NC)) +
! 1 Z1(I,K)*CAMT(I,NC)
!051 CONTINUE
!***MERGE FLXTHK INTO FLXNET FOR APPROPRIATE LEVELS.
! DO 1401 K=1,LP1
! DO 1401 I=MYIS,MYIE
! IF (K.GT.ITOP(I) .AND. K.LE.IBOT(I)
! 1 .AND. (NC-1).LE.NCLDS(I)) THEN
! FLXNET(I,K)=FLXTHK(I,K)
! ENDIF
!401 CONTINUE
!
!******END OF CLOUD LOOP*****
6001 CONTINUE
6999 CONTINUE
!***THE FINAL STEP IS TO RECOMPUTE THE HEATING RATES BASED ON THE
! REVISED FLUXES:
DO 6101 K=1,L
DO 6101 I=MYIS,MYIE
HEATRA(I,K)=RADCON*(FLXNET(I,K+1)-FLXNET(I,K))*DELP(I,K)
6101 CONTINUE
! THE THICK CLOUD SECTION ENDS HERE.
END SUBROUTINE FST88
!----------------------------------------------------------------------
SUBROUTINE E1E290(G1,G2,G3,G4,G5,EMISS,FXOE1,DTE1,FXOE2,DTE2, & 2
AVEPHI,TEMP,T, &
! T1,T2,T4,EM1V,EM1VW, &
H16E1,TEN,HP1,H28E1,HAF, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
REAL,INTENT(IN) :: H16E1,TEN,HP1,H28E1,HAF
REAL,INTENT(OUT),DIMENSION(its:ite,kts:kte+1) :: G1,G4,G3,EMISS
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte+1) :: FXOE1,DTE1,FXOE2,DTE2
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte+1) :: AVEPHI,TEMP,T
REAL,INTENT(OUT),DIMENSION(its:ite,kts:kte) :: G2,G5
! REAL,INTENT(IN),DIMENSION(5040):: T1,T2,T4 ,EM1V,EM1VW
REAL,DIMENSION(its:ite,kts:kte+1) :: TMP3,DU,FYO,WW1,WW2
INTEGER,DIMENSION(its:ite,kts:kte*3+2) :: IT1
INTEGER,DIMENSION(its:ite,kts:kte+1) :: IVAL
! REAL,DIMENSION(28,180):: EM1,EM1WDE,TABLE1,TABLE2, &
! TABLE3
! EQUIVALENCE (EM1V(1),EM1(1,1)),(EM1VW(1),EM1WDE(1,1))
! EQUIVALENCE (T1(1),TABLE1(1,1)),(T2(1),TABLE2(1,1)), &
! (T4(1),TABLE3(1,1))
INTEGER :: K, I,KP,LLM2,J1,J3,KMAX,KMIN,KCLDS,ICNT,LLM1
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE,LLP1,LL,KK,KLEN
L=kte
LP1=L+1; LP2=L+2; LP3=L+3; LLP1 = 2*L + 1
LM1=L-1; LM2=L-2; LM3=L-3; LL = 2*L
LLM2 = LL-2; LLM1=LL-1
MYIS=its; MYIE=ite
!---FIRST WE OBTAIN THE EMISSIVITIES AS A FUNCTION OF TEMPERATURE
! (INDEX FXO) AND WATER AMOUNT (INDEX FYO). THIS PART OF THE CODE
! THUS GENERATES THE E2 FUNCTION. THE FXO INDICES HAVE BEEN
! OBTAINED IN FST88, FOR CONVENIENCE.
!
!---THIS SUBROUTINE EVALUATES THE K=1 CASE ONLY--
!
!---THIS LOOP REPLACES LOOPS GOING FROMI=1,IMAX AND KP=2,LP1 PLUS
! THE SPECIAL CASE FOR THE LP1TH LAYER.
DO 1322 K=1,LP1
DO 1322 I=MYIS,MYIE
TMP3(I,K)=LOG10(AVEPHI(I,K))+H16E1
FYO(I,K)=AINT(TMP3(I,K)*TEN)
DU(I,K)=TMP3(I,K)-HP1*FYO(I,K)
FYO(I,K)=H28E1*FYO(I,K)
IVAL(I,K)=FYO(I,K)+FXOE2(I,K)
EMISS(I,K)=T1(IVAL(I,K))+DU(I,K)*T2(IVAL(I,K)) &
+DTE2(I,K)*T4(IVAL(I,K))
1322 CONTINUE
!
!---THE SPECIAL CASE EMISS(I,L) (LAYER KP) IS OBTAINED NOW
! BY AVERAGING THE VALUES FOR L AND LP1:
DO 1344 I=MYIS,MYIE
EMISS(I,L)=HAF*(EMISS(I,L)+EMISS(I,LP1))
1344 CONTINUE
!
! CALCULATIONS FOR THE KP=1 LAYER ARE NOT PERFORMED, AS
! THE RADIATION CODE ASSUMES THAT THE TOP FLUX LAYER (ABOVE THE
! TOP DATA LEVEL) IS ISOTHERMAL, AND HENCE CONTRIBUTES NOTHING
! TO THE FLUXES AT OTHER LEVELS.
!
!***THE FOLLOWING IS THE CALCULATION FOR THE E1 FUNCTION, FORMERLY
! DONE IN SUBROUTINE E1V88. THE MOVE TO E1E288 IS DUE TO THE
! SAVINGS IN OBTAINING INDEX VALUES (THE TEMP. INDICES HAVE
! BEEN OBTAINED IN FST88, WHILE THE U-INDICES ARE OBTAINED
! IN THE E2 CALCS.,WITH K=1).
!
!
! FOR TERMS INVOLVING TOP LAYER, DU IS NOT KNOWN; IN FACT, WE
! USE INDEX 2 TO REPERSENT INDEX 1 IN PREV. CODE. THIS MEANS THAT
! THE IT1 INDEX 1 AND LLP1 HAS TO BE CALCULATED SEPARATELY. THE
! INDEX LLP2 GIVES THE SAME VALUE AS 1; IT CAN BE OMITTED.
DO 208 I=MYIS,MYIE
IT1(I,1)=FXOE1(I,1)
WW1(I,1)=TEN-DTE1(I,1)
WW2(I,1)=HP1
208 CONTINUE
DO 209 K=1,L
DO 209 I=MYIS,MYIE
IT1(I,K+1)=FYO(I,K)+FXOE1(I,K+1)
IT1(I,LP2+K-1)=FYO(I,K)+FXOE1(I,K)
WW1(I,K+1)=TEN-DTE1(I,K+1)
WW2(I,K+1)=HP1-DU(I,K)
209 CONTINUE
DO 211 KP=1,L
DO 211 I=MYIS,MYIE
IT1(I,KP+LLP1)=FYO(I,KP)+FXOE1(I,1)
211 CONTINUE
!
!
! G3(I,1) HAS THE SAME VALUES AS G1 (AND DID ALL ALONG)
DO 230 I=MYIS,MYIE
G1(I,1)=WW1(I,1)*WW2(I,1)*EM1V(IT1(I,1))+ &
WW2(I,1)*DTE1(I,1)*EM1V(IT1(I,1)+1)
G3(I,1)=G1(I,1)
230 CONTINUE
DO 240 K=1,L
DO 240 I=MYIS,MYIE
G1(I,K+1)=WW1(I,K+1)*WW2(I,K+1)*EM1V(IT1(I,K+1))+ &
WW2(I,K+1)*DTE1(I,K+1)*EM1V(IT1(I,K+1)+1)+ &
WW1(I,K+1)*DU(I,K)*EM1V(IT1(I,K+1)+28)+ &
DTE1(I,K+1)*DU(I,K)*EM1V(IT1(I,K+1)+29)
G2(I,K)=WW1(I,K)*WW2(I,K+1)*EM1V(IT1(I,K+LP2-1))+ &
WW2(I,K+1)*DTE1(I,K)*EM1V(IT1(I,K+LP2-1)+1)+ &
WW1(I,K)*DU(I,K)*EM1V(IT1(I,K+LP2-1)+28)+ &
DTE1(I,K)*DU(I,K)*EM1V(IT1(I,K+LP2-1)+29)
240 CONTINUE
DO 241 KP=2,LP1
DO 241 I=MYIS,MYIE
G3(I,KP)=WW1(I,1)*WW2(I,KP)*EM1V(IT1(I,LL+KP))+ &
WW2(I,KP)*DTE1(I,1)*EM1V(IT1(I,LL+KP)+1)+ &
WW1(I,1)*DU(I,KP-1)*EM1V(IT1(I,LL+KP)+28)+ &
DTE1(I,1)*DU(I,KP-1)*EM1V(IT1(I,LL+KP)+29)
241 CONTINUE
!
DO 244 I=MYIS,MYIE
G4(I,1)=WW1(I,1)*WW2(I,1)*EM1VW(IT1(I,1))+ &
WW2(I,1)*DTE1(I,1)*EM1VW(IT1(I,1)+1)
244 CONTINUE
DO 242 K=1,L
DO 242 I=MYIS,MYIE
G4(I,K+1)=WW1(I,K+1)*WW2(I,K+1)*EM1VW(IT1(I,K+1))+ &
WW2(I,K+1)*DTE1(I,K+1)*EM1VW(IT1(I,K+1)+1)+ &
WW1(I,K+1)*DU(I,K)*EM1VW(IT1(I,K+1)+28)+ &
DTE1(I,K+1)*DU(I,K)*EM1VW(IT1(I,K+1)+29)
G5(I,K)=WW1(I,K)*WW2(I,K+1)*EM1VW(IT1(I,K+LP2-1))+ &
WW2(I,K+1)*DTE1(I,K)*EM1VW(IT1(I,K+LP2-1)+1)+ &
WW1(I,K)*DU(I,K)*EM1VW(IT1(I,K+LP2-1)+28)+ &
DTE1(I,K)*DU(I,K)*EM1VW(IT1(I,K+LP2-1)+29)
242 CONTINUE
!
END SUBROUTINE E1E290
!----------------------------------------------------------------------
SUBROUTINE SPA88(EXCTS,CTSO3,GXCTS,SORC,CSOUR, & 2
CLDFAC,TEMP,PRESS,VAR1,VAR2, &
P,DELP,DELP2,TOTVO2,TO3SP,TO3SPC, &
CO2SP1,CO2SP2,CO2SP, &
APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
H25E2,ONE,H44194M2,H1P41819,HAF,HM1EZ,TWO, &
! SKO2D,RADCON, &
RADCON, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
! INTEGER, PARAMETER :: NBLY=15
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
REAL,INTENT(IN) :: H25E2,ONE,H44194M2,H1P41819,HAF,HM1EZ,TWO, &
RADCON
! SKO2D,RADCON
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte+1) :: CSOUR
REAL,INTENT(OUT),DIMENSION(its:ite,kts:kte) :: CTSO3
REAL,INTENT(OUT),DIMENSION(its:ite,kts:kte) :: EXCTS
REAL,INTENT(OUT),DIMENSION(its:ite) :: GXCTS
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte+1,NBLY) :: SORC
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte+1,kts:kte+1) :: CLDFAC
REAL,INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: PRESS,TEMP
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte) :: VAR1,VAR2
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte+1) :: P
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte) :: DELP,DELP2,TO3SPC
REAL,INTENT(IN),DIMENSION(its:ite,kts:kte+1) ::TOTVO2,TO3SP,CO2SP1,&
CO2SP2,CO2SP
REAL,INTENT(IN),DIMENSION(NBLY) :: APCM,BPCM,ATPCM,BTPCM,ACOMB, &
BCOMB,BETACM
REAL,DIMENSION(its:ite,kts:kte+1) ::CTMP,CTMP2,CTMP3
REAL,DIMENSION(its:ite,kts:kte) ::X,Y,FAC1,FAC2,F,FF,AG,AGG, &
PHITMP,PSITMP,TOPM,TOPPHI,TT
INTEGER :: K, I,KP,LLM2,J1,J3,KMAX,KMIN,KCLDS,ICNT,LLM1
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE,LLP1,LL,KK,KLEN
L=kte
LP1=L+1; LP2=L+2; LP3=L+3; LLP1 = 2*L + 1
LM1=L-1; LM2=L-2; LM3=L-3; LL = 2*L
LLM2 = LL-2; LLM1=LL-1
MYIS=its; MYIE=ite
!--!COMPUTE TEMPERATURE QUANTITIES FOR USE IN PROGRAM
DO 101 K=1,L
DO 101 I=MYIS,MYIE
X(I,K)=TEMP(I,K)-H25E2
Y(I,K)=X(I,K)*X(I,K)
101 CONTINUE
!---INITIALIZE CTMP(I,1),CTMP2(I,1),CTMP3(I,1) TO UNITY; THESE ARE
! TRANSMISSION FCTNS AT THE TOP.
DO 345 I=MYIS,MYIE
CTMP(I,1)=ONE
CTMP2(I,1)=1.
CTMP3(I,1)=1.
345 CONTINUE
!***BEGIN LOOP ON FREQUENCY BANDS (1)***
!
!---CALCULATION FOR BAND 1 (COMBINED BAND 1)
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 301 K=1,L
DO 301 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(1)*X(I,K)+BPCM(1)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(1)*X(I,K)+BTPCM(1)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
301 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 315 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
315 CONTINUE
DO 319 K=2,L
DO 317 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
317 CONTINUE
319 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 321 K=1,L
DO 321 I=MYIS,MYIE
FAC1(I,K)=ACOMB(1)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(1)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*FAC1(I,K)/SQRT(1.+FAC2(I,K)))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
321 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 353 K=1,L
DO 353 I=MYIS,MYIE
EXCTS(I,K)=SORC(I,K,1)*(CTMP(I,K+1)-CTMP(I,K))
353 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 361 I=MYIS,MYIE
GXCTS(I)=CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,1)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,1)-SORC(I,L,1)))
361 CONTINUE
!
!
!-----CALCULATION FOR BAND 2 (COMBINED BAND 2)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 401 K=1,L
DO 401 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(2)*X(I,K)+BPCM(2)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(2)*X(I,K)+BTPCM(2)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
401 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 415 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
415 CONTINUE
DO 419 K=2,L
DO 417 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
417 CONTINUE
419 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 421 K=1,L
DO 421 I=MYIS,MYIE
FAC1(I,K)=ACOMB(2)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(2)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*FAC1(I,K)/SQRT(1.+FAC2(I,K)))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
421 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 453 K=1,L
DO 453 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,2)* &
(CTMP(I,K+1)-CTMP(I,K))
453 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 461 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,2)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,2)-SORC(I,L,2)))
461 CONTINUE
!
!-----CALCULATION FOR BAND 3 (COMBINED BAND 3)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 501 K=1,L
DO 501 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(3)*X(I,K)+BPCM(3)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(3)*X(I,K)+BTPCM(3)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
501 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 515 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
515 CONTINUE
DO 519 K=2,L
DO 517 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
517 CONTINUE
519 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 521 K=1,L
DO 521 I=MYIS,MYIE
FAC1(I,K)=ACOMB(3)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(3)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*FAC1(I,K)/SQRT(1.+FAC2(I,K)))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
521 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 553 K=1,L
DO 553 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,3)* &
(CTMP(I,K+1)-CTMP(I,K))
553 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 561 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,3)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,3)-SORC(I,L,3)))
561 CONTINUE
!
!-----CALCULATION FOR BAND 4 (COMBINED BAND 4)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 601 K=1,L
DO 601 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(4)*X(I,K)+BPCM(4)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(4)*X(I,K)+BTPCM(4)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
601 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 615 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
615 CONTINUE
DO 619 K=2,L
DO 617 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
617 CONTINUE
619 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 621 K=1,L
DO 621 I=MYIS,MYIE
FAC1(I,K)=ACOMB(4)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(4)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*FAC1(I,K)/SQRT(1.+FAC2(I,K)))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
621 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 653 K=1,L
DO 653 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,4)* &
(CTMP(I,K+1)-CTMP(I,K))
653 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 661 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,4)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,4)-SORC(I,L,4)))
661 CONTINUE
!
!-----CALCULATION FOR BAND 5 (COMBINED BAND 5)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 701 K=1,L
DO 701 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(5)*X(I,K)+BPCM(5)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(5)*X(I,K)+BTPCM(5)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
701 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 715 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
715 CONTINUE
DO 719 K=2,L
DO 717 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
717 CONTINUE
719 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 721 K=1,L
DO 721 I=MYIS,MYIE
FAC1(I,K)=ACOMB(5)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(5)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(5)*TOTVO2(I,K+1)*SKO2D))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
721 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 753 K=1,L
DO 753 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,5)* &
(CTMP(I,K+1)-CTMP(I,K))
753 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 761 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,5)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,5)-SORC(I,L,5)))
761 CONTINUE
!
!-----CALCULATION FOR BAND 6 (COMBINED BAND 6)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 801 K=1,L
DO 801 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(6)*X(I,K)+BPCM(6)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(6)*X(I,K)+BTPCM(6)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
801 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 815 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
815 CONTINUE
DO 819 K=2,L
DO 817 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
817 CONTINUE
819 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 821 K=1,L
DO 821 I=MYIS,MYIE
FAC1(I,K)=ACOMB(6)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(6)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(6)*TOTVO2(I,K+1)*SKO2D))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
821 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 853 K=1,L
DO 853 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,6)* &
(CTMP(I,K+1)-CTMP(I,K))
853 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 861 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,6)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,6)-SORC(I,L,6)))
861 CONTINUE
!
!-----CALCULATION FOR BAND 7 (COMBINED BAND 7)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 901 K=1,L
DO 901 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(7)*X(I,K)+BPCM(7)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(7)*X(I,K)+BTPCM(7)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
901 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 915 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
915 CONTINUE
DO 919 K=2,L
DO 917 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
917 CONTINUE
919 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 921 K=1,L
DO 921 I=MYIS,MYIE
FAC1(I,K)=ACOMB(7)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(7)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(7)*TOTVO2(I,K+1)*SKO2D))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
921 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 953 K=1,L
DO 953 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,k,7)* &
(CTMP(I,K+1)-CTMP(I,K))
953 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 961 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,7)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,7)-SORC(I,L,7)))
961 CONTINUE
!
!-----CALCULATION FOR BAND 8 (COMBINED BAND 8)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 1001 K=1,L
DO 1001 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(8)*X(I,K)+BPCM(8)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(8)*X(I,K)+BTPCM(8)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
1001 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 1015 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
1015 CONTINUE
DO 1019 K=2,L
DO 1017 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
1017 CONTINUE
1019 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 1021 K=1,L
DO 1021 I=MYIS,MYIE
FAC1(I,K)=ACOMB(8)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(8)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(8)*TOTVO2(I,K+1)*SKO2D))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
1021 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 1053 K=1,L
DO 1053 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,8)* &
(CTMP(I,K+1)-CTMP(I,K))
1053 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 1061 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,8)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,8)-SORC(I,L,8)))
1061 CONTINUE
!
!-----CALCULATION FOR BAND 9 ( 560-670 CM-1; INCLUDES CO2)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 1101 K=1,L
DO 1101 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(9)*X(I,K)+BPCM(9)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(9)*X(I,K)+BTPCM(9)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
1101 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 1115 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
1115 CONTINUE
DO 1119 K=2,L
DO 1117 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
1117 CONTINUE
1119 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 1121 K=1,L
DO 1121 I=MYIS,MYIE
FAC1(I,K)=ACOMB(9)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(9)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(9)*TOTVO2(I,K+1)*SKO2D))*CO2SP1(I,K+1)
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
1121 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 1153 K=1,L
DO 1153 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,9)* &
(CTMP(I,K+1)-CTMP(I,K))
1153 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 1161 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,9)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,9)-SORC(I,L,9)))
1161 CONTINUE
!
!-----CALCULATION FOR BAND 10 (670-800 CM-1; INCLUDES CO2)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 1201 K=1,L
DO 1201 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(10)*X(I,K)+BPCM(10)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(10)*X(I,K)+BTPCM(10)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
1201 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 1215 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
1215 CONTINUE
DO 1219 K=2,L
DO 1217 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
1217 CONTINUE
1219 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 1221 K=1,L
DO 1221 I=MYIS,MYIE
FAC1(I,K)=ACOMB(10)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(10)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(10)*TOTVO2(I,K+1)*SKO2D))*CO2SP2(I,K+1)
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
1221 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 1253 K=1,L
DO 1253 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,10)* &
(CTMP(I,K+1)-CTMP(I,K))
1253 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 1261 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,10)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,10)-SORC(I,L,10)))
1261 CONTINUE
!
!-----CALCULATION FOR BAND 11 (800-900 CM-1)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 1301 K=1,L
DO 1301 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(11)*X(I,K)+BPCM(11)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(11)*X(I,K)+BTPCM(11)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
1301 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 1315 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
1315 CONTINUE
DO 1319 K=2,L
DO 1317 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
1317 CONTINUE
1319 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 1321 K=1,L
DO 1321 I=MYIS,MYIE
FAC1(I,K)=ACOMB(11)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(11)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(11)*TOTVO2(I,K+1)*SKO2D))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
1321 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 1353 K=1,L
DO 1353 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,11)* &
(CTMP(I,K+1)-CTMP(I,K))
1353 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 1361 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,11)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,11)-SORC(I,L,11)))
1361 CONTINUE
!
!-----CALCULATION FOR BAND 12 (900-990 CM-1)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 1401 K=1,L
DO 1401 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(12)*X(I,K)+BPCM(12)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(12)*X(I,K)+BTPCM(12)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
1401 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 1415 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
1415 CONTINUE
DO 1419 K=2,L
DO 1417 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
1417 CONTINUE
1419 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 1421 K=1,L
DO 1421 I=MYIS,MYIE
FAC1(I,K)=ACOMB(12)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(12)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(12)*TOTVO2(I,K+1)*SKO2D))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
1421 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 1453 K=1,L
DO 1453 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,12)* &
(CTMP(I,K+1)-CTMP(I,K))
1453 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 1461 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,12)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,12)-SORC(I,L,12)))
1461 CONTINUE
!
!-----CALCULATION FOR BAND 13 (990-1070 CM-1; INCLUDES O3))
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 1501 K=1,L
DO 1501 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(13)*X(I,K)+BPCM(13)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(13)*X(I,K)+BTPCM(13)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
1501 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 1515 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
1515 CONTINUE
DO 1519 K=2,L
DO 1517 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
1517 CONTINUE
1519 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 1521 K=1,L
DO 1521 I=MYIS,MYIE
FAC1(I,K)=ACOMB(13)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(13)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(13)*TOTVO2(I,K+1)*SKO2D+TO3SPC(I,K)))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
1521 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 1553 K=1,L
DO 1553 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,13)* &
(CTMP(I,K+1)-CTMP(I,K))
1553 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 1561 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,13)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,13)-SORC(I,L,13)))
1561 CONTINUE
!
!-----CALCULATION FOR BAND 14 (1070-1200 CM-1)
!
!
!---OBTAIN TEMPERATURE CORRECTION (CAPPHI,CAPPSI),THEN MULTIPLY
! BY OPTICAL PATH (VAR1,VAR2) TO COMPUTE TEMPERATURE-CORRECTED
! OPTICAL PATH AND MEAN PRESSURE FOR A LAYER (PHITMP,PSITMP)
DO 1601 K=1,L
DO 1601 I=MYIS,MYIE
F(I,K)=H44194M2*(APCM(14)*X(I,K)+BPCM(14)*Y(I,K))
FF(I,K)=H44194M2*(ATPCM(14)*X(I,K)+BTPCM(14)*Y(I,K))
AG(I,K)=(H1P41819+F(I,K))*F(I,K)+ONE
AGG(I,K)=(H1P41819+FF(I,K))*FF(I,K)+ONE
PHITMP(I,K)=VAR1(I,K)*(((( AG(I,K)*AG(I,K))**2)**2)**2)
PSITMP(I,K)=VAR2(I,K)*(((( AGG(I,K)*AGG(I,K))**2)**2)**2)
1601 CONTINUE
!---OBTAIN OPTICAL PATH,MEAN PRESSURE FROM THE TOP TO THE PRESSURE
! P(K) (TOPM,TOPPHI)
DO 1615 I=MYIS,MYIE
TOPM(I,1)=PHITMP(I,1)
TOPPHI(I,1)=PSITMP(I,1)
1615 CONTINUE
DO 1619 K=2,L
DO 1617 I=MYIS,MYIE
TOPM(I,K)=TOPM(I,K-1)+PHITMP(I,K)
TOPPHI(I,K)=TOPPHI(I,K-1)+PSITMP(I,K)
1617 CONTINUE
1619 CONTINUE
!---TT IS THE CLOUD-FREE CTS TRANSMISSION FUNCTION
DO 1621 K=1,L
DO 1621 I=MYIS,MYIE
FAC1(I,K)=ACOMB(14)*TOPM(I,K)
FAC2(I,K)=FAC1(I,K)*TOPM(I,K)/(BCOMB(14)*TOPPHI(I,K))
TT(I,K)=EXP(HM1EZ*(FAC1(I,K)/SQRT(ONE+FAC2(I,K))+ &
BETACM(14)*TOTVO2(I,K+1)*SKO2D))
CTMP(I,K+1)=TT(I,K)*CLDFAC(I,K+1,1)
1621 CONTINUE
!---EXCTS IS THE CTS COOLING RATE ACCUMULATED OVER FREQUENCY BANDS
DO 1653 K=1,L
DO 1653 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)+SORC(I,K,14)* &
(CTMP(I,K+1)-CTMP(I,K))
1653 CONTINUE
!---GXCTS IS THE EXACT CTS TOP FLUX ACCUMULATED OVER FREQUENCY BANDS
DO 1661 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)+CLDFAC(I,LP1,1)*(TT(I,L)*SORC(I,L,14)+ &
(HAF*DELP(I,L)*(TT(I,LM1)*(P(I,LP1)-PRESS(I,L)) + &
TT(I,L)*(P(I,LP1)+PRESS(I,L)-TWO*P(I,L)))) * &
(SORC(I,LP1,14)-SORC(I,L,14)))
1661 CONTINUE
!
!
! OBTAIN CTS FLUX AT THE TOP BY INTEGRATION OF HEATING RATES AND
! USING CTS FLUX AT THE BOTTOM (CURRENT VALUE OF GXCTS). NOTE
! THAT THE PRESSURE QUANTITIES AND CONVERSION FACTORS HAVE NOT
! BEEN INCLUDED EITHER IN EXCTS OR IN GXCTS. THESE CANCEL OUT, THUS
! REDUCING COMPUTATIONS!
DO 1731 K=1,L
DO 1731 I=MYIS,MYIE
GXCTS(I)=GXCTS(I)-EXCTS(I,K)
1731 CONTINUE
!
! NOW SCALE THE COOLING RATE (EXCTS) BY INCLUDING THE PRESSURE
! FACTOR (DELP) AND THE CONVERSION FACTOR (RADCON)
DO 1741 K=1,L
DO 1741 I=MYIS,MYIE
EXCTS(I,K)=EXCTS(I,K)*RADCON*DELP(I,K)
1741 CONTINUE
!---THIS IS THE END OF THE EXACT CTS COMPUTATIONS; AT THIS POINT
! EXCTS HAS ITS APPROPRIATE VALUE.
!
!*** COMPUTE APPROXIMATE CTS HEATING RATES FOR 15UM AND 9.6 UM BANDS
! (CTSO3)
DO 1711 K=1,L
DO 1711 I=MYIS,MYIE
CTMP2(I,K+1)=CO2SP(I,K+1)*CLDFAC(I,K+1,1)
CTMP3(I,K+1)=TO3SP(I,K)*CLDFAC(I,K+1,1)
1711 CONTINUE
DO 1701 K=1,L
DO 1701 I=MYIS,MYIE
CTSO3(I,K)=RADCON*DELP(I,K)* &
(CSOUR(I,K)*(CTMP2(I,K+1)-CTMP2(I,K)) + &
SORC(I,K,13)*(CTMP3(I,K+1)-CTMP3(I,K)))
1701 CONTINUE
END SUBROUTINE SPA88
!----------------------------------------------------------------------
SUBROUTINE E290(EMISSB,EMISS,AVEPHI,KLEN,FXOE2,DTE2, & 2
! T1,T2,T4, &
H16E1,HP1,H28E1,HAF,TEN, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
INTEGER, INTENT(IN) :: KLEN
REAL, INTENT(IN) :: H16E1,HP1,H28E1,HAF ,TEN
REAL, INTENT(OUT),DIMENSION(its:ite,kts:kte+1) :: EMISSB
REAL, INTENT(IN ),DIMENSION(its:ite,kts:kte+1) :: AVEPHI,FXOE2,DTE2
! REAL, INTENT(IN ), DIMENSION(5040) :: T1,T2,T4
REAL, INTENT(INOUT), DIMENSION(its:ite,kts:kte+1) :: EMISS
REAL, DIMENSION(its:ite,kts:kte+1) :: TMP3,DT,FYO,DU
INTEGER, DIMENSION(its:ite,kts:kte+1) :: IVAL
! REAL, DIMENSION(28,180) :: TABLE1,TABLE2,TABLE3
! EQUIVALENCE (T1(1),TABLE1(1,1)),(T2(1),TABLE2(1,1)), &
! (T4(1),TABLE3(1,1))
! EQUIVALENCE (TMP3,DT)
INTEGER :: K, I,KP,LLM2,J1,J3,KMAX,KMIN,KCLDS,ICNT,LLM1
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE,LLP1,LL,KK
L=kte
LP1=L+1; LP2=L+2; LP3=L+3; LLP1 = 2*L + 1
LM1=L-1; LM2=L-2; LM3=L-3; LL = 2*L
LLM2 = LL-2; LLM1=LL-1
MYIS=its; MYIE=ite
!---FIRST WE OBTAIN THE EMISSIVITIES AS A FUNCTION OF TEMPERATURE
! (INDEX FXO) AND WATER AMOUNT (INDEX FYO). THIS PART OF THE CODE
! THUS GENERATES THE E2 FUNCTION.
!
!---CALCULATIONS FOR VARYING KP (FROM KP=K+1 TO LP1, INCLUDING SPECIAL
! CASE: RESULTS ARE IN EMISS
DO 132 K=1,LP2-KLEN
DO 132 I=MYIS,MYIE
TMP3(I,K)=LOG10(AVEPHI(I,KLEN+K-1))+H16E1
FYO(I,K)=AINT(TMP3(I,K)*TEN)
DU(I,K)=TMP3(I,K)-HP1*FYO(I,K)
FYO(I,K)=H28E1*FYO(I,K)
IVAL(I,K)=FYO(I,K)+FXOE2(I,KLEN+K-1)
EMISS(I,KLEN+K-1)=T1(IVAL(I,K))+DU(I,K)*T2(IVAL(I,K)) &
+DTE2(I,KLEN+K-1)*T4(IVAL(I,K))
132 CONTINUE
!---THE SPECIAL CASE EMISS(I,L) (LAYER KP) IS OBTAINED NOW
! BY AVERAGING THE VALUES FOR L AND LP1:
DO 1344 I=MYIS,MYIE
EMISS(I,L)=HAF*(EMISS(I,L)+EMISS(I,LP1))
1344 CONTINUE
!---NOTE THAT EMISS(I,LP1) IS NOT USEFUL AFTER THIS POINT.
!
!---CALCULATIONS FOR KP=KLEN AND VARYING K; RESULTS ARE IN EMISSB.
! IN THIS CASE, THE TEMPERATURE INDEX IS UNCHANGED, ALWAYS BEING
! FXO(I,KLEN-1); THE WATER INDEX CHANGES, BUT IS SYMMETRICAL WITH
! THAT FOR THE VARYING KP CASE.NOTE THAT THE SPECIAL CASE IS NOT
! INVOLVED HERE.
! (FIXED LEVEL) K VARIES FROM (KLEN+1) TO LP1; RESULTS ARE IN
! EMISSB(I,(KLEN) TO L)
DO 142 K=1,LP1-KLEN
DO 142 I=MYIS,MYIE
DT(I,K)=DTE2(I,KLEN-1)
IVAL(I,K)=FYO(I,K)+FXOE2(I,KLEN-1)
142 CONTINUE
!
DO 234 K=1,LP1-KLEN
DO 234 I=MYIS,MYIE
EMISSB(I,KLEN+K-1)=T1(IVAL(I,K))+DU(I,K)*T2(IVAL(I,K)) &
+DT(I,K)*T4(IVAL(I,K))
234 CONTINUE
END SUBROUTINE E290
!---------------------------------------------------------------------
SUBROUTINE E2SPEC(EMISS,AVEPHI,FXOSP,DTSP, & 2
! T1,T2,T4, &
H16E1,TEN,H28E1,HP1, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
REAL,INTENT(IN ) :: H16E1,TEN,H28E1,HP1
REAL,INTENT(INOUT),DIMENSION(its:ite,kts:kte+1) :: EMISS
REAL,INTENT(IN ),DIMENSION(its:ite,kts:kte+1) :: AVEPHI
REAL,INTENT(IN ),DIMENSION(its:ite,2) :: FXOSP,DTSP
! REAL, INTENT(IN ),DIMENSION(5040) :: T1,T2,T4
! REAL, DIMENSION(28,180) :: TABLE1,TABLE2,TABLE3
! EQUIVALENCE (T1(1),TABLE1(1,1)),(T2(1),TABLE2(1,1)), &
! (T4(1),TABLE3(1,1))
INTEGER :: K,I,MYIS,MYIE
REAL, DIMENSION(its:ite,kts:kte+1) :: TMP3,FYO,DU
INTEGER, DIMENSION(its:ite,kts:kte+1) :: IVAL
MYIS=its
MYIE=ite
DO 132 K=1,2
DO 132 I=MYIS,MYIE
TMP3(I,K)=LOG10(AVEPHI(I,K))+H16E1
FYO(I,K)=AINT(TMP3(I,K)*TEN)
DU(I,K)=TMP3(I,K)-HP1*FYO(I,K)
IVAL(I,K)=H28E1*FYO(I,K)+FXOSP(I,K)
EMISS(I,K)=T1(IVAL(I,K))+DU(I,K)*T2(IVAL(I,K))+ &
DTSP(I,K)*T4(IVAL(I,K))
132 CONTINUE
END SUBROUTINE E2SPEC
!---------------------------------------------------------------------
! SUBROUTINE E3V88(EMV,TV,AV,EM3V, &
SUBROUTINE E3V88(EMV,TV,AV, & 2
TEN,HP1,H28E1,H16E1, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
REAL, INTENT(IN) :: TEN,HP1,H28E1,H16E1
!-----------------------------------------------------------------------
REAL, INTENT(OUT), DIMENSION(its:ite,kts:kte*2+1) :: EMV
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte*2+1) :: TV,AV
! REAL, INTENT(IN), DIMENSION(5040) :: EM3V
REAL,DIMENSION(its:ite,kts:kte*2+1) ::FXO,TMP3,DT,WW1,WW2,DU,&
FYO
! REAL, DIMENSION(5040) :: EM3V
! EQUIVALENCE (EM3V(1),EM3(1,1))
INTEGER,DIMENSION(its:ite,kts:kte*2+1) ::IT
INTEGER :: LLP1,I,K,MYIS,MYIE ,L
L = kte
LLP1 = 2*L + 1
MYIS=its; MYIE=ite
!---THE FOLLOWING LOOP REPLACES A DOUBLE LOOP OVER I (1-IMAX) AND
! K (1-LLP1)
DO 203 K=1,LLP1
DO 203 I=MYIS,MYIE
FXO(I,K)=AINT(TV(I,K)*HP1)
TMP3(I,K)=LOG10(AV(I,K))+H16E1
DT(I,K)=TV(I,K)-TEN*FXO(I,K)
FYO(I,K)=AINT(TMP3(I,K)*TEN)
DU(I,K)=TMP3(I,K)-HP1*FYO(I,K)
!---OBTAIN INDEX FOR TABLE LOOKUP; THIS VALUE WILL HAVE TO BE
! DECREMENTED BY 9 TO ACCOUNT FOR TABLE TEMPS STARTING AT 100K.
IT(I,K)=FXO(I,K)+FYO(I,K)*H28E1
WW1(I,K)=TEN-DT(I,K)
WW2(I,K)=HP1-DU(I,K)
EMV(I,K)=WW1(I,K)*WW2(I,K)*EM3V(IT(I,K)-9)+ &
WW2(I,K)*DT(I,K)*EM3V(IT(I,K)-8)+ &
WW1(I,K)*DU(I,K)*EM3V(IT(I,K)+19)+ &
DT(I,K)*DU(I,K)*EM3V(IT(I,K)+20)
203 CONTINUE
END SUBROUTINE E3V88
!-----------------------------------------------------------------------
SUBROUTINE SWR93(FSWC,HSWC,UFSWC,DFSWC,FSWL,HSWL,UFSWL, & 2
DFSWL, &
PRESS,COSZRO,TAUDAR,RH2O,RRCO2,SSOLAR,QO3, &
NCLDS,KTOPSW,KBTMSW,CAMT,CRR,CTT, &
ALVB,ALNB,ALVD,ALND,GDFVB,GDFNB,GDFVD,GDFND, &
! UCO2,UO3,TUCO2,TUO3,TDO3,TDCO2, &
ABCFF,PWTS, &
H35E1,H1224E3,ONE,ZERO,HAF,H69766E5,HP219, &
HP816,RRAYAV,GINV,CFCO2,CFO3, &
TWO,H235M3,HP26,H129M2,H75826M4,H1036E2, &
H1P082,HMP805,H1386E2,H658M2,H2118M2,H42M2, &
H323M4,HM1EZ,DIFFCTR,O3DIFCTR,FIFTY,RADCON, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
REAL,INTENT(IN) :: RRCO2,SSOLAR
REAL,INTENT(IN) :: H35E1,H1224E3,ONE,ZERO,HAF,H69766E5,HP219,HP816,RRAYAV,&
GINV,CFCO2,CFO3
REAL,INTENT(IN) :: TWO,H235M3,HP26,H129M2,H75826M4,H1036E2
REAL,INTENT(IN) :: H1P082,HMP805,H1386E2,H658M2,H2118M2,H42M2,H323M4,HM1EZ
REAL,INTENT(IN) :: DIFFCTR,O3DIFCTR,FIFTY,RADCON
!----------------------------------------------------------------------
INTEGER, PARAMETER :: NB=12
REAL, INTENT(IN ),DIMENSION(its:ite,kts:kte+1) :: PRESS,CAMT
REAL, INTENT(IN ),DIMENSION(its:ite,kts:kte) :: RH2O,QO3
REAL, INTENT(IN ),DIMENSION(its:ite) :: COSZRO,TAUDAR,ALVB,ALVD,ALNB,ALND
INTEGER, INTENT(IN ),DIMENSION(its:ite) :: NCLDS
INTEGER, INTENT(IN ),DIMENSION(its:ite,kts:kte+1) ::KTOPSW,KBTMSW
REAL, INTENT(IN ),DIMENSION(its:ite,NB,kts:kte+1) ::CRR,CTT
REAL, INTENT(OUT),DIMENSION(its:ite,kts:kte+1) :: &
FSWC,HSWC,UFSWC,DFSWC,FSWL,HSWL,UFSWL,DFSWL
REAL, INTENT(OUT),DIMENSION(its:ite) :: GDFVB,GDFVD,GDFNB,GDFND
REAL, INTENT(IN), DIMENSION(NB) :: ABCFF,PWTS
! REAL, INTENT(IN), DIMENSION(its:ite,kts:kte*2+2) :: UCO2,UO3
! REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1) :: TUCO2,TUO3,TDO3,TDCO2
REAL, DIMENSION(its:ite,kts:kte*2+2) :: UCO2,UO3
REAL, DIMENSION(its:ite,kts:kte+1) :: TUCO2,TUO3,TDO3,TDCO2
REAL, DIMENSION(its:ite,kts:kte*2+2) :: TCO2,TO3
REAL, DIMENSION(its:ite,kts:kte+1) :: PP,DP,PR2,DU,DUCO2,DUO3,UD,TTD
REAL, DIMENSION(its:ite,kts:kte+1) :: UDCO2,UDO3,UR,URCO2,URO3,TTU
REAL, DIMENSION(its:ite,kts:kte+1) :: DFN,UFN
REAL, DIMENSION(its:ite,kts:kte+1) :: XAMT,FF,FFCO2,FFO3,CR,CT
REAL, DIMENSION(its:ite,kts:kte+1) :: PPTOP,DPCLD,TTDB1,TTUB1
REAL, DIMENSION(its:ite,kts:kte+1) :: TDCL1,TUCL1,TDCL2,DFNTRN, &
UFNTRN,TCLU,TCLD,ALFA,ALFAU, &
UFNCLU,DFNCLU
REAL, DIMENSION(its:ite,NB) :: DFNTOP
REAL, DIMENSION(its:ite) :: SECZ,TMP1,RRAY,REFL,REFL2,CCMAX
! EQUIVALENCE &
! (UDO3,UO3(its,1),DFNCLU), (URO3,UO3(its,kte+2), UFNCLU) &
! , (UDCO2,UCO2(its,1),TCLD), (URCO2,UCO2(its,kte+2), TCLU) &
! , (TDO3 ,TO3(its,1),DFNTRN),(TUO3,TO3(its,kte+2), UFNTRN) &
! , (TDCO2,TCO2(its,1) ),(TUCO2,TCO2(its,kte+2) ) &
! , (FF , ALFA ), (FFCO2 , ALFAU ), (FFO3 , TTDB1 ) &
! , (DU , TTUB1), (DUCO2 , TUCL1 ), (DUO3 , TDCL1 ) &
! , (PR2 , TDCL2)
! EQUIVALENCE &
! (UDO3,DFNCLU), (URO3,UFNCLU) &
! , (UDCO2,TCLD ), (URCO2,TCLU) &
! , (TDO3 ,DFNTRN),(TUO3,UFNTRN) &
!! , (TDCO2,TCO2(its,1) ),(TUCO2,TCO2(its,kte+2) ) &
! , (FF , ALFA ), (FFCO2 , ALFAU ), (FFO3 , TTDB1 ) &
! , (DU , TTUB1), (DUCO2 , TUCL1 ), (DUO3 , TDCL1 ) &
! , (PR2 , TDCL2)
INTEGER :: K,I,KP,N,IP,MYIS1,KCLDS,NNCLDS,JTOP,KK,J2,J3,J1
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE,LLP1,LL
REAL :: DENOM,HTEMP,TEMPF,TEMPG
L=kte
LP1=L+1; LP2=L+2; LP3=L+3; LLP1 = 2*L + 1
LM1=L-1; LM2=L-2; LM3=L-3; LL = 2*L
MYIS=its; MYIE=ite
MYIS1=MYIS+1 ! ??
DO 100 I=MYIS,MYIE
SECZ(I) = H35E1/SQRT(H1224E3*COSZRO(I)*COSZRO(I)+ONE)
PP(I,1) = ZERO
PP(I,LP1) = PRESS(I,LP1)
TMP1(I) = ONE/PRESS(I,LP1)
100 CONTINUE
DO 110 K=1,LM1
DO 110 I=MYIS,MYIE
PP(I,K+1) = HAF*(PRESS(I,K+1)+PRESS(I,K))
110 CONTINUE
DO 120 K=1,L
DO 120 I=MYIS,MYIE
DP (I,K) = PP(I,K+1)-PP(I,K)
PR2(I,K) = HAF*(PP(I,K)+PP(I,K+1))
120 CONTINUE
DO 130 K=1,L
DO 130 I=MYIS,MYIE
PR2(I,K) = PR2(I,K)*TMP1(I)
130 CONTINUE
! CALCULATE ENTERING FLUX AT THE TOP FOR EACH BAND(IN CGS UNITS)
DO 140 N=1,NB
DO 140 IP=MYIS,MYIE
DFNTOP(IP,N) = SSOLAR*H69766E5*COSZRO(IP)*TAUDAR(IP)*PWTS(N)
140 CONTINUE
! EXECUTE THE LACIS-HANSEN REFLECTIVITY PARAMETERIZATION
! FOR THE VISIBLE BAND
DO 150 I=MYIS,MYIE
RRAY(I) = HP219/(ONE+HP816*COSZRO(I))
REFL(I) = RRAY(I) + (ONE-RRAY(I))*(ONE-RRAYAV)*ALVB(I)/ &
(ONE-ALVD(I)*RRAYAV)
150 CONTINUE
DO 155 I=MYIS,MYIE
RRAY(I) = 0.104/(ONE+4.8*COSZRO(I))
REFL2(I)= RRAY(I) + (ONE-RRAY(I))*(ONE-0.093)*ALVB(I)/ &
(ONE-ALVD(I)*0.093)
155 CONTINUE
! CALCULATE PRESSURE-WEIGHTED OPTICAL PATHS FOR EACH LAYER
! IN UNITS OF CM-ATM. PRESSURE WEIGHTING IS USING PR2.
! DU= VALUE FOR H2O;DUCO2 FOR CO2;DUO3 FOR O3.
DO 160 K=1,L
DO 160 I=MYIS,MYIE
DU (I,K) = GINV*RH2O(I,K)*DP(I,K)*PR2(I,K)
DUCO2(I,K) = (RRCO2*GINV*CFCO2)*DP(I,K)*PR2(I,K)
DUO3 (I,K) = (GINV*CFO3)*QO3(I,K)*DP(I,K)
160 CONTINUE
!
! CALCULATE CLEAR SKY SW FLUX
!
! OBTAIN THE OPTICAL PATH FROM THE TOP OF THE ATMOSPHERE TO THE
! FLUX PRESSURE. ANGULAR FACTORS ARE NOW INCLUDED. UD=DOWNWARD
! PATH FOR H2O,WIGTH UR THE UPWARD PATH FOR H2O. CORRESPONDING
! QUANTITIES FOR CO2,O3 ARE UDCO2/URCO2 AND UDO3/URO3.
DO 200 IP=MYIS,MYIE
UD (IP,1) = ZERO
UDCO2(IP,1) = ZERO
UDO3 (IP,1) = ZERO
! SH
UO3 (IP,1) = UDO3 (IP,1)
UCO2 (IP,1) = UDCO2(IP,1)
200 CONTINUE
DO 210 K=2,LP1
DO 210 I=MYIS,MYIE
UD (I,K) = UD (I,K-1)+DU (I,K-1)*SECZ(I)
UDCO2(I,K) = UDCO2(I,K-1)+DUCO2(I,K-1)*SECZ(I)
UDO3 (I,K) = UDO3 (I,K-1)+DUO3 (I,K-1)*SECZ(I)
! SH
UO3 (I,K) = UDO3 (I,K)
UCO2 (I,K) = UDCO2(I,K)
210 CONTINUE
DO 220 IP=MYIS,MYIE
UR (IP,LP1) = UD (IP,LP1)
URCO2(IP,LP1) = UDCO2(IP,LP1)
URO3 (IP,LP1) = UDO3 (IP,LP1)
! SH
UO3 (IP,LP1+LP1) = URO3 (IP,LP1)
UCO2 (IP,LP1+LP1) = URCO2(IP,LP1)
220 CONTINUE
DO 230 K=L,1,-1
DO 230 IP=MYIS,MYIE
UR (IP,K) = UR (IP,K+1)+DU (IP,K)*DIFFCTR
URCO2(IP,K) = URCO2(IP,K+1)+DUCO2(IP,K)*DIFFCTR
URO3 (IP,K) = URO3 (IP,K+1)+DUO3 (IP,K)*O3DIFCTR
! SH
UO3 (IP,LP1+K) = URO3 (IP,K)
UCO2(IP,LP1+K) = URCO2(IP,K)
230 CONTINUE
! CALCULATE CO2 ABSORPTIONS . THEY WILL BE USED IN NEAR INFRARED
! BANDS.SINCE THE ABSORPTION AMOUNT IS GIVEN (IN THE FORMULA USED
! BELOW, DERIVED FROM SASAMORI) IN TERMS OF THE TOTAL SOLAR FLUX,
! AND THE ABSORPTION IS ONLY INCLUDED IN THE NEAR IR (50 PERCENT
! OF THE SOLAR SPECTRUM), THE ABSORPTIONS ARE MULTIPLIED BY 2.
! SINCE CODE ACTUALLY REQUIRES TRANSMISSIONS, THESE ARE THE
! VALUES ACTUALLY STORED IN TCO2.
DO 240 K=1,LL
DO 240 I=MYIS,MYIE
TCO2(I,K+1)=ONE-TWO*(H235M3*EXP(HP26*LOG(UCO2(I,K+1)+H129M2)) &
-H75826M4)
240 CONTINUE
! SH
DO 241 K=1,L
DO 241 I=MYIS,MYIE
TDCO2(I,K+1)=TCO2(I,K+1)
241 CONTINUE
DO 242 K=1,L
DO 242 I=MYIS,MYIE
TUCO2(I,K)=TCO2(I,LP1+K)
242 CONTINUE
! NOW CALCULATE OZONE ABSORPTIONS. THESE WILL BE USED IN
! THE VISIBLE BAND.JUST AS IN THE CO2 CASE, SINCE THIS BAND IS
! 50 PERCENT OF THE SOLAR SPECTRUM,THE ABSORPTIONS ARE MULTIPLIED
! BY 2. THE TRANSMISSIONS ARE STORED IN TO3.
HTEMP = H1036E2*H1036E2*H1036E2
DO 250 K=1,LL
DO 250 I=MYIS,MYIE
TO3(I,K+1)=ONE-TWO*UO3(I,K+1)* &
(H1P082*EXP(HMP805*LOG(ONE+H1386E2*UO3(I,K+1)))+ &
H658M2/(ONE+HTEMP*UO3(I,K+1)*UO3(I,K+1)*UO3(I,K+1))+ &
H2118M2/(ONE+UO3(I,K+1)*(H42M2+H323M4*UO3(I,K+1))))
250 CONTINUE
! SH
DO 251 K=1,L
DO 251 I=MYIS,MYIE
TDO3(I,K+1)=TO3(I,K+1)
251 CONTINUE
DO 252 K=1,L
DO 252 I=MYIS,MYIE
TUO3(I,K)=TO3(I,LP1+K)
252 CONTINUE
! START FREQUENCY LOOP (ON N) HERE
!
!--- BAND 1 (VISIBLE) INCLUDES O3 AND H2O ABSORPTION
DO 260 K=1,L
DO 260 I=MYIS,MYIE
TTD(I,K+1) = EXP(HM1EZ*MIN(FIFTY,ABCFF(1)*UD(I,K+1)))
TTU(I,K) = EXP(HM1EZ*MIN(FIFTY,ABCFF(1)*UR(I,K)))
DFN(I,K+1) = TTD(I,K+1)*TDO3(I,K+1)
UFN(I,K) = TTU(I,K)*TUO3(I,K)
260 CONTINUE
DO 270 I=MYIS,MYIE
DFN(I,1) = ONE
UFN(I,LP1) = DFN(I,LP1)
270 CONTINUE
! SCALE VISIBLE BAND FLUXES BY SOLAR FLUX AT THE TOP OF THE
! ATMOSPHERE (DFNTOP(I,1))
! DFSW/UFSW WILL BE THE FLUXES, SUMMED OVER ALL BANDS
DO 280 K=1,LP1
DO 280 I=MYIS,MYIE
DFSWL(I,K) = DFN(I,K)*DFNTOP(I,1)
UFSWL(I,K) = REFL(I)*UFN(I,K)*DFNTOP(I,1)
280 CONTINUE
DO 285 I=MYIS,MYIE
GDFVB(I) = DFSWL(I,LP1)*EXP(-0.15746*SECZ(I))
GDFVD(I) = ((ONE-REFL2(I))*DFSWL(I,LP1) - &
(ONE-ALVB(I)) *GDFVB(I)) / (ONE-ALVD(I))
GDFNB(I) = ZERO
GDFND(I) = ZERO
285 CONTINUE
!---NOW OBTAIN FLUXES FOR THE NEAR IR BANDS. THE METHODS ARE THE SAME
! AS FOR THE VISIBLE BAND, EXCEPT THAT THE REFLECTION AND
! TRANSMISSION COEFFICIENTS (OBTAINED BELOW) ARE DIFFERENT, AS
! RAYLEIGH SCATTERING NEED NOT BE CONSIDERED.
DO 350 N=2,NB
IF (N.EQ.2) THEN
! THE WATER VAPOR TRANSMISSION FUNCTION FOR BAND 2 IS EQUAL TO
! THAT OF BAND 1 (SAVED AS TTD,TTU)
!--- BAND 2-9 (NEAR-IR) INCLUDES O3, CO2 AND H2O ABSORPTION
DO 290 K=1,L
DO 290 I=MYIS,MYIE
DFN(I,K+1) = TTD(I,K+1)*TDCO2(I,K+1)
UFN(I,K) = TTU(I,K)*TUCO2(I,K)
290 CONTINUE
ELSE
! CALCULATE WATER VAPOR TRANSMISSION FUNCTIONS FOR NEAR INFRARED
! BANDS. INCLUDE CO2 TRANSMISSION (TDCO2/TUCO2), WHICH
! IS THE SAME FOR ALL INFRARED BANDS.
DO 300 K=1,L
DO 300 I=MYIS,MYIE
DFN(I,K+1)=EXP(HM1EZ*MIN(FIFTY,ABCFF(N)*UD(I,K+1))) &
*TDCO2(I,K+1)
UFN(I,K)=EXP(HM1EZ*MIN(FIFTY,ABCFF(N)*UR(I,K))) &
*TUCO2(I,K)
300 CONTINUE
ENDIF
!---AT THIS POINT,INCLUDE DFN(1),UFN(LP1), NOTING THAT DFN(1)=1 FOR
! ALL BANDS, AND THAT UFN(LP1)=DFN(LP1) FOR ALL BANDS.
DO 310 I=MYIS,MYIE
DFN(I,1) = ONE
UFN(I,LP1) = DFN(I,LP1)
310 CONTINUE
! SCALE THE PREVIOUSLY COMPUTED FLUXES BY THE FLUX AT THE TOP
! AND SUM OVER BANDS
DO 320 K=1,LP1
DO 320 I=MYIS,MYIE
DFSWL(I,K) = DFSWL(I,K) + DFN(I,K)*DFNTOP(I,N)
UFSWL(I,K) = UFSWL(I,K) + ALNB(I)*UFN(I,K)*DFNTOP(I,N)
320 CONTINUE
DO 330 I=MYIS,MYIE
GDFNB(I) = GDFNB(I) + DFN(I,LP1)*DFNTOP(I,N)
330 CONTINUE
350 CONTINUE
DO 360 K=1,LP1
DO 360 I=MYIS,MYIE
FSWL(I,K) = UFSWL(I,K)-DFSWL(I,K)
360 CONTINUE
DO 370 K=1,L
DO 370 I=MYIS,MYIE
HSWL(I,K)=RADCON*(FSWL(I,K+1)-FSWL(I,K))/DP(I,K)
370 CONTINUE
!
!---END OF FREQUENCY LOOP (OVER N)
!
! CALCULATE CLOUDY SKY SW FLUX
!
KCLDS=NCLDS(MYIS)
DO 400 I=MYIS1,MYIE
KCLDS=MAX(NCLDS(I),KCLDS)
400 CONTINUE
DO 410 K=1,LP1
DO 410 I=MYIS,MYIE
DFSWC(I,K) = DFSWL(I,K)
UFSWC(I,K) = UFSWL(I,K)
FSWC (I,K) = FSWL (I,K)
410 CONTINUE
DO 420 K=1,L
DO 420 I=MYIS,MYIE
HSWC(I,K) = HSWL(I,K)
420 CONTINUE
!*******************************************************************
IF (KCLDS .EQ. 0) RETURN
!*******************************************************************
DO 430 K=1,LP1
DO 430 I=MYIS,MYIE
XAMT(I,K) = CAMT(I,K)
430 CONTINUE
DO 470 I=MYIS,MYIE
NNCLDS = NCLDS(I)
CCMAX(I) = ZERO
IF (NNCLDS .LE. 0) GO TO 470
CCMAX(I) = ONE
DO 450 K=1,NNCLDS
CCMAX(I) = CCMAX(I) * (ONE - CAMT(I,K+1))
450 CONTINUE
CCMAX(I) = ONE - CCMAX(I)
IF (CCMAX(I) .GT. ZERO) THEN
DO 460 K=1,NNCLDS
XAMT(I,K+1) = CAMT(I,K+1)/CCMAX(I)
460 CONTINUE
END IF
470 CONTINUE
DO 480 K=1,LP1
DO 480 I=MYIS,MYIE
FF (I,K) = DIFFCTR
FFCO2(I,K) = DIFFCTR
FFO3 (I,K) = O3DIFCTR
480 CONTINUE
DO 490 IP=MYIS,MYIE
JTOP = KTOPSW(IP,NCLDS(IP)+1)
DO 490 K=1,JTOP
FF (IP,K) = SECZ(IP)
FFCO2(IP,K) = SECZ(IP)
FFO3 (IP,K) = SECZ(IP)
490 CONTINUE
DO 500 I=MYIS,MYIE
RRAY(I) = HP219/(ONE+HP816*COSZRO(I))
REFL(I) = RRAY(I) + (ONE-RRAY(I))*(ONE-RRAYAV)*ALVD(I)/ &
(ONE-ALVD(I)*RRAYAV)
500 CONTINUE
DO 510 IP=MYIS,MYIE
UD (IP,1) = ZERO
UDCO2(IP,1) = ZERO
UDO3 (IP,1) = ZERO
! SH
UO3 (IP,1) = UDO3 (IP,1)
UCO2 (IP,1) = UDCO2(IP,1)
510 CONTINUE
DO 520 K=2,LP1
DO 520 I=MYIS,MYIE
UD (I,K) = UD (I,K-1)+DU (I,K-1)*FF (I,K)
UDCO2(I,K) = UDCO2(I,K-1)+DUCO2(I,K-1)*FFCO2(I,K)
UDO3 (I,K) = UDO3 (I,K-1)+DUO3 (I,K-1)*FFO3 (I,K)
! SH
UO3 (I,K) = UDO3 (I,K)
UCO2(I,K) = UDCO2(I,K)
520 CONTINUE
DO 530 IP=MYIS,MYIE
UR (IP,LP1) = UD (IP,LP1)
URCO2(IP,LP1) = UDCO2(IP,LP1)
URO3 (IP,LP1) = UDO3 (IP,LP1)
! SH
UO3 (IP,LP1+LP1) = URO3 (IP,LP1)
UCO2 (IP,LP1+LP1) = URCO2(IP,LP1)
530 CONTINUE
DO 540 K=L,1,-1
DO 540 IP=MYIS,MYIE
UR (IP,K) = UR (IP,K+1)+DU (IP,K)*DIFFCTR
URCO2(IP,K) = URCO2(IP,K+1)+DUCO2(IP,K)*DIFFCTR
URO3 (IP,K) = URO3 (IP,K+1)+DUO3 (IP,K)*O3DIFCTR
! SH
UO3 (IP,LP1+K) = URO3 (IP,K)
UCO2(IP,LP1+K) = URCO2(IP,K)
540 CONTINUE
DO 550 K=1,LL
DO 550 I=MYIS,MYIE
TCO2(I,K+1)=ONE-TWO*(H235M3*EXP(HP26*LOG(UCO2(I,K+1)+H129M2)) &
-H75826M4)
550 CONTINUE
! SH
DO 551 K=1,L
DO 551 I=MYIS,MYIE
TDCO2(I,K+1)=TCO2(I,K+1)
551 CONTINUE
DO 552 K=1,L
DO 552 I=MYIS,MYIE
TUCO2(I,K)=TCO2(I,LP1+K)
552 CONTINUE
DO 560 K=1,LL
DO 560 I=MYIS,MYIE
TO3(I,K+1)=ONE-TWO*UO3(I,K+1)* &
(H1P082*EXP(HMP805*LOG(ONE+H1386E2*UO3(I,K+1)))+ &
H658M2/(ONE+HTEMP*UO3(I,K+1)*UO3(I,K+1)*UO3(I,K+1))+ &
H2118M2/(ONE+UO3(I,K+1)*(H42M2+H323M4*UO3(I,K+1))))
560 CONTINUE
! SH
DO 561 K=1,L
DO 561 I=MYIS,MYIE
TDO3(I,K+1)=TO3(I,K+1)
561 CONTINUE
DO 562 K=1,L
DO 562 I=MYIS,MYIE
TUO3(I,K)=TO3(I,LP1+K)
562 CONTINUE
!********************************************************************
!---THE FIRST CLOUD IS THE GROUND; ITS PROPERTIES ARE GIVEN
! BY REFL (THE TRANSMISSION (0) IS IRRELEVANT FOR NOW!).
!********************************************************************
DO 570 I=MYIS,MYIE
CR(I,1) = REFL(I)
570 CONTINUE
!***OBTAIN CLOUD REFLECTION AND TRANSMISSION COEFFICIENTS FOR
! REMAINING CLOUDS (IF ANY) IN THE VISIBLE BAND
!---THE MAXIMUM NO OF CLOUDS IN THE ROW (KCLDS) IS USED. THIS CREATES
! EXTRA WORK (MAY BE REMOVED IN A SUBSEQUENT UPDATE).
DO 581 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 581
DO 580 KK=2,KCLDS+1
CR(I,KK) = CRR(I,1,KK)*XAMT(I,KK)
CT(I,KK) = ONE - (ONE-CTT(I,1,KK))*XAMT(I,KK)
580 CONTINUE
581 CONTINUE
!---OBTAIN THE PRESSURE AT THE TOP,BOTTOM AND THE THICKNESS OF
! "THICK" CLOUDS (THOSE AT LEAST 2 LAYERS THICK). THIS IS USED
! LATER IS OBTAINING FLUXES INSIDE THE THICK CLOUDS, FOR ALL
! FREQUENCY BANDS.
DO 591 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 591
DO 590 KK=1,KCLDS
IF ((KBTMSW(I,KK+1)-1).GT.KTOPSW(I,KK+1)) THEN
PPTOP(I,KK)=PP(I,KTOPSW(I,KK+1))
DPCLD(I,KK)=ONE/(PPTOP(I,KK)-PP(I,KBTMSW(I,KK+1)))
ENDIF
590 CONTINUE
591 CONTINUE
DO 600 K=1,L
DO 600 I=MYIS,MYIE
TTDB1(I,K+1) = EXP(HM1EZ*MIN(FIFTY,ABCFF(1)*UD(I,K+1)))
TTUB1(I,K) = EXP(HM1EZ*MIN(FIFTY,ABCFF(1)*UR(I,K)))
TTD (I,K+1) = TTDB1(I,K+1)*TDO3(I,K+1)
TTU (I,K) = TTUB1(I,K)*TUO3(I,K)
600 CONTINUE
DO 610 I=MYIS,MYIE
TTD(I,1) = ONE
TTU(I,LP1) = TTD(I,LP1)
610 CONTINUE
!***FOR EXECUTION OF THE CLOUD LOOP, IT IS NECESSARY TO SEPARATE OUT
! TRANSMISSION FCTNS AT THE TOP AND BOTTOM OF THE CLOUDS, FOR
! EACH BAND N. THE REQUIRED QUANTITIES ARE:
! TTD(I,KTOPSW(I,K),N) K RUNS FROM 1 TO NCLDS(I)+1:
! TTU(I,KTOPSW(I,K),N) K RUNS FROM 1 TO NCLDS(I)+1:
! TTD(I,KBTMSW(I,K),N) K RUNS FROM 1 TO NCLDS(I)+1:
! AND INVERSES OF THE FIRST TWO. THE ABOVE QUANTITIES ARE
! STORED IN TDCL1,TUCL1,TDCL2, AND DFNTRN,UFNTRN, RESPECTIVELY,
! AS THEY HAVE MULTIPLE USE IN THE PGM.
!---FOR FIRST CLOUD LAYER (GROUND) TDCL1,TUCL1 ARE KNOWN:
DO 620 I=MYIS,MYIE
TDCL1 (I,1) = TTD(I,LP1)
TUCL1 (I,1) = TTU(I,LP1)
TDCL2 (I,1) = TDCL1(I,1)
DFNTRN(I,1) = ONE/TDCL1(I,1)
UFNTRN(I,1) = DFNTRN(I,1)
620 CONTINUE
DO 631 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 631
DO 630 KK=2,KCLDS+1
TDCL1(I,KK) = TTD(I,KTOPSW(I,KK))
TUCL1(I,KK) = TTU(I,KTOPSW(I,KK))
TDCL2(I,KK) = TTD(I,KBTMSW(I,KK))
630 CONTINUE
631 CONTINUE
!---COMPUTE INVERSES
DO 641 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 641
! SH
DO 640 KK=2,KCLDS+1
DFNTRN(I,KK) = ONE/TDCL1(I,KK)
UFNTRN(I,KK) = ONE/TUCL1(I,KK)
640 CONTINUE
641 CONTINUE
!---COMPUTE THE TRANSMISSIVITY FROM THE TOP OF CLOUD (K+1) TO THE
! TOP OF CLOUD (K). THE CLOUD TRANSMISSION (CT) IS INCLUDED. THIS
! QUANTITY IS CALLED TCLU (INDEX K). ALSO, OBTAIN THE TRANSMISSIVITY
! FROM THE BOTTOM OF CLOUD (K+1) TO THE TOP OF CLOUD (K)(A PATH
! ENTIRELY OUTSIDE CLOUDS). THIS QUANTITY IS CALLED TCLD (INDEX K).
DO 651 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 651
DO 650 KK=1,KCLDS
TCLU(I,KK) = TDCL1(I,KK)*DFNTRN(I,KK+1)*CT(I,KK+1)
TCLD(I,KK) = TDCL1(I,KK)/TDCL2(I,KK+1)
650 CONTINUE
651 CONTINUE
!***THE FOLLOWING IS THE RECURSION RELATION FOR ALFA: THE REFLECTION
! COEFFICIENT FOR A SYSTEM INCLUDING THE CLOUD IN QUESTION AND THE
! FLUX COMING OUT OF THE CLOUD SYSTEM INCLUDING ALL CLOUDS BELOW
! THE CLOUD IN QUESTION.
!---ALFAU IS ALFA WITHOUT THE REFLECTION OF THE CLOUD IN QUESTION
DO 660 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 660
ALFA (I,1)=CR(I,1)
ALFAU(I,1)=ZERO
660 CONTINUE
!---AGAIN,EXCESSIVE CALCULATIONS-MAY BE CHANGED LATER!
DO 671 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 671
DO 670 KK=2,KCLDS+1
ALFAU(I,KK)= TCLU(I,KK-1)*TCLU(I,KK-1)*ALFA(I,KK-1)/ &
(ONE - TCLD(I,KK-1)*TCLD(I,KK-1)*ALFA(I,KK-1)*CR(I,KK))
ALFA (I,KK)= ALFAU(I,KK)+CR(I,KK)
670 CONTINUE
671 CONTINUE
! CALCULATE UFN AT CLOUD TOPS AND DFN AT CLOUD BOTTOMS
!---NOTE THAT UFNCLU(I,KCLDS+1) GIVES THE UPWARD FLUX AT THE TOP
! OF THE HIGHEST REAL CLOUD (IF NCLDS(I)=KCLDS). IT GIVES THE FLUX
! AT THE TOP OF THE ATMOSPHERE IF NCLDS(I) < KCLDS. IN THE FIRST
! CASE, TDCL1 EQUALS THE TRANSMISSION FCTN TO THE TOP OF THE
! HIGHEST CLOUD, AS WE WANT. IN THE SECOND CASE, TDCL1=1, SO UFNCLU
! EQUALS ALFA. THIS IS ALSO CORRECT.
DO 680 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 680
UFNCLU(I,KCLDS+1) = ALFA(I,KCLDS+1)*TDCL1(I,KCLDS+1)
DFNCLU(I,KCLDS+1) = TDCL1(I,KCLDS+1)
680 CONTINUE
!---THIS CALCULATION IS THE REVERSE OF THE RECURSION RELATION USED
! ABOVE
DO 691 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 691
DO 690 KK=KCLDS,1,-1
UFNCLU(I,KK) = UFNCLU(I,KK+1)*ALFAU(I,KK+1)/(ALFA(I,KK+1)* &
TCLU(I,KK))
DFNCLU(I,KK) = UFNCLU(I,KK)/ALFA(I,KK)
690 CONTINUE
691 CONTINUE
DO 701 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 701
DO 700 KK=1,KCLDS+1
UFNTRN(I,KK) = UFNCLU(I,KK)*UFNTRN(I,KK)
DFNTRN(I,KK) = DFNCLU(I,KK)*DFNTRN(I,KK)
700 CONTINUE
701 CONTINUE
!---CASE OF KK=1( FROM THE GROUND TO THE BOTTOM OF THE LOWEST CLOUD)
DO 720 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 720
J2=KBTMSW(I,2)
DO 710 K=J2,LP1
UFN(I,K) = UFNTRN(I,1)*TTU(I,K)
DFN(I,K) = DFNTRN(I,1)*TTD(I,K)
710 CONTINUE
720 CONTINUE
!---REMAINING LEVELS (IF ANY!)
DO 760 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 760
DO 755 KK=2,KCLDS+1
J1=KTOPSW(I,KK)
J2=KBTMSW(I,KK+1)
IF (J1.EQ.1) GO TO 755
DO 730 K=J2,J1
UFN(I,K) = UFNTRN(I,KK)*TTU(I,K)
DFN(I,K) = DFNTRN(I,KK)*TTD(I,K)
730 CONTINUE
!---FOR THE THICK CLOUDS, THE FLUX DIVERGENCE THROUGH THE CLOUD
! LAYER IS ASSUMED TO BE CONSTANT. THE FLUX DERIVATIVE IS GIVEN BY
! TEMPF (FOR THE UPWARD FLUX) AND TEMPG (FOR THE DOWNWARD FLUX).
J3=KBTMSW(I,KK)
IF ((J3-J1).GT.1) THEN
TEMPF = (UFNCLU(I,KK)-UFN(I,J3))*DPCLD(I,KK-1)
TEMPG = (DFNCLU(I,KK)-DFN(I,J3))*DPCLD(I,KK-1)
DO 740 K=J1+1,J3-1
UFN(I,K) = UFNCLU(I,KK)+TEMPF*(PP(I,K)-PPTOP(I,KK-1))
DFN(I,K) = DFNCLU(I,KK)+TEMPG*(PP(I,K)-PPTOP(I,KK-1))
740 CONTINUE
ENDIF
755 CONTINUE
760 CONTINUE
DO 770 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 770
DO 771 K=1,LP1
DFSWC(I,K) = DFN(I,K)*DFNTOP(I,1)
UFSWC(I,K) = UFN(I,K)*DFNTOP(I,1)
771 CONTINUE
770 CONTINUE
DO 780 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 780
TMP1(I) = ONE - CCMAX(I)
GDFVB(I) = TMP1(I)*GDFVB(I)
GDFNB(I) = TMP1(I)*GDFNB(I)
GDFVD(I) = TMP1(I)*GDFVD(I) + CCMAX(I)*DFSWC(I,LP1)
780 CONTINUE
!---NOW OBTAIN FLUXES FOR THE NEAR IR BANDS. THE METHODS ARE THE SAME
! AS FOR THE VISIBLE BAND, EXCEPT THAT THE REFLECTION AND
! TRANSMISSION COEFFICIENTS ARE DIFFERENT, AS
! RAYLEIGH SCATTERING NEED NOT BE CONSIDERED.
!
DO 1000 N=2,NB
!YH93
DO 791 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 791
DO 790 K=1,KCLDS+1
CR(I,K) = CRR(I,N,K)*XAMT(I,K)
CT(I,K) = ONE - (ONE-CTT(I,N,K))*XAMT(I,K)
790 CONTINUE
791 CONTINUE
!YH93
IF (N.EQ.2) THEN
! THE WATER VAPOR TRANSMISSION FUNCTION FOR BAND 2 IS EQUAL TO
! THAT OF BAND 1 (SAVED AS TTDB1,TTUB1)
DO 800 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 800
DO 801 KK=2,LP1
TTD(I,KK) = TTDB1(I,KK)*TDCO2(I,KK)
801 CONTINUE
DO 802 KK=1,L
TTU(I,KK) = TTUB1(I,KK)*TUCO2(I,KK)
802 CONTINUE
800 CONTINUE
ELSE
DO 810 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 810
DO 811 KK=2,LP1
TTD(I,KK) = EXP(HM1EZ*MIN(FIFTY,ABCFF(N)*UD(I,KK))) &
* TDCO2(I,KK)
811 CONTINUE
DO 812 KK=1,L
TTU(I,KK) = EXP(HM1EZ*MIN(FIFTY,ABCFF(N)*UR(I,KK))) &
* TUCO2(I,KK)
812 CONTINUE
810 CONTINUE
ENDIF
!---AT THIS POINT,INCLUDE TTD(1),TTU(LP1), NOTING THAT TTD(1)=1 FOR
! ALL BANDS, AND THAT TTU(LP1)=TTD(LP1) FOR ALL BANDS.
DO 820 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 820
TTU(I,LP1) = TTD(I,LP1)
TTD(I,1) = ONE
820 CONTINUE
!***FOR EXECUTION OF THE CLOUD LOOP, IT IS NECESSARY TO SEPARATE OUT
! TRANSMISSION FCTNS AT THE TOP AND BOTTOM OF THE CLOUDS, FOR
! EACH BAND N. THE REQUIRED QUANTITIES ARE:
! TTD(I,KTOPSW(I,K),N) K RUNS FROM 1 TO NCLDS(I)+1:
! TTD(I,KBTMSW(I,K),N) K RUNS FROM 2 TO NCLDS(I)+1:
! TTU(I,KTOPSW(I,K),N) K RUNS FROM 1 TO NCLDS(I)+1:
! AND INVERSES OF THE ABOVE. THE ABOVE QUANTITIES ARE STORED
! IN TDCL1,TDCL2,TUCL1,AND DFNTRN,UFNTRN,RESPECTIVELY, AS
! THEY HAVE MULTIPLE USE IN THE PGM.
!---FOR FIRST CLOUD LAYER (GROUND) TDCL1,TUCL1 ARE KNOWN:
DO 830 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 830
TDCL1 (I,1) = TTD(I,LP1)
TUCL1 (I,1) = TTU(I,LP1)
TDCL2 (I,1) = TDCL1(I,1)
DFNTRN(I,1) = ONE/TDCL1(I,1)
UFNTRN(I,1) = DFNTRN(I,1)
830 CONTINUE
DO 841 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 841
DO 840 KK=2,KCLDS+1
TDCL1(I,KK) = TTD(I,KTOPSW(I,KK))
TUCL1(I,KK) = TTU(I,KTOPSW(I,KK))
TDCL2(I,KK) = TTD(I,KBTMSW(I,KK))
840 CONTINUE
841 CONTINUE
DO 851 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 851
DO 850 KK=2,KCLDS+1
DFNTRN(I,KK) = ONE/TDCL1(I,KK)
UFNTRN(I,KK) = ONE/TUCL1(I,KK)
850 CONTINUE
851 CONTINUE
DO 861 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 861
DO 860 KK=1,KCLDS
TCLU(I,KK) = TDCL1(I,KK)*DFNTRN(I,KK+1)*CT(I,KK+1)
TCLD(I,KK) = TDCL1(I,KK)/TDCL2(I,KK+1)
860 CONTINUE
861 CONTINUE
!***THE FOLLOWING IS THE RECURSION RELATION FOR ALFA: THE REFLECTION
! COEFFICIENT FOR A SYSTEM INCLUDING THE CLOUD IN QUESTION AND THE
! FLUX COMING OUT OF THE CLOUD SYSTEM INCLUDING ALL CLOUDS BELOW
! THE CLOUD IN QUESTION.
DO 870 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 870
ALFA (I,1) = CR(I,1)
ALFAU(I,1) = ZERO
870 CONTINUE
!---AGAIN,EXCESSIVE CALCULATIONS-MAY BE CHANGED LATER!
DO 881 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 881
DO 880 KK=2,KCLDS+1
ALFAU(I,KK) = TCLU(I,KK-1)*TCLU(I,KK-1)*ALFA(I,KK-1)/(ONE - &
TCLD(I,KK-1)*TCLD(I,KK-1)*ALFA(I,KK-1)*CR(I,KK))
ALFA (I,KK) = ALFAU(I,KK)+CR(I,KK)
880 CONTINUE
881 CONTINUE
! CALCULATE UFN AT CLOUD TOPS AND DFN AT CLOUD BOTTOMS
!---NOTE THAT UFNCLU(I,KCLDS+1) GIVES THE UPWARD FLUX AT THE TOP
! OF THE HIGHEST REAL CLOUD (IF NCLDS(I)=KCLDS). IT GIVES THE FLUX
! AT THE TOP OF THE ATMOSPHERE IF NCLDS(I) < KCLDS. IT THE FIRST
! CASE, TDCL1 EQUALS THE TRANSMISSION FCTN TO THE TOP OF THE
! HIGHEST CLOUD, AS WE WANT. IN THE SECOND CASE, TDCL1=1, SO UFNCLU
! EQUALS ALFA. THIS IS ALSO CORRECT.
DO 890 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 890
UFNCLU(I,KCLDS+1) = ALFA(I,KCLDS+1)*TDCL1(I,KCLDS+1)
DFNCLU(I,KCLDS+1) = TDCL1(I,KCLDS+1)
890 CONTINUE
DO 901 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 901
DO 900 KK=KCLDS,1,-1
!
!*** ACCOUNT FOR UNREALISTICALLY SMALL CLOUD AMOUNT
!
DENOM=ALFA(I,KK+1)*TCLU(I,KK)
IF(DENOM.GT.RTHRESH)THEN
UFNCLU(I,KK)=UFNCLU(I,KK+1)*ALFAU(I,KK+1)/DENOM
ELSE
UFNCLU(I,KK)=0.
ENDIF
IF(ALFA(I,KK).GT.RTHRESH)THEN
DFNCLU(I,KK)=UFNCLU(I,KK)/ALFA(I,KK)
ELSE
DFNCLU(I,KK)=0.
ENDIF
900 CONTINUE
901 CONTINUE
! NOW OBTAIN DFN AND UFN FOR LEVELS BETWEEN THE CLOUDS
DO 911 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 911
DO 910 KK=1,KCLDS+1
UFNTRN(I,KK) = UFNCLU(I,KK)*UFNTRN(I,KK)
DFNTRN(I,KK) = DFNCLU(I,KK)*DFNTRN(I,KK)
910 CONTINUE
911 CONTINUE
DO 930 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 930
J2=KBTMSW(I,2)
DO 920 K=J2,LP1
UFN(I,K) = UFNTRN(I,1)*TTU(I,K)
DFN(I,K) = DFNTRN(I,1)*TTD(I,K)
920 CONTINUE
930 CONTINUE
DO 970 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 970
DO 965 KK=2,KCLDS+1
J1 = KTOPSW(I,KK)
J2 = KBTMSW(I,KK+1)
IF (J1.EQ.1) GO TO 965
DO 940 K=J2,J1
UFN(I,K) = UFNTRN(I,KK)*TTU(I,K)
DFN(I,K) = DFNTRN(I,KK)*TTD(I,K)
940 CONTINUE
J3 = KBTMSW(I,KK)
IF ((J3-J1).GT.1) THEN
TEMPF = (UFNCLU(I,KK)-UFN(I,J3))*DPCLD(I,KK-1)
TEMPG = (DFNCLU(I,KK)-DFN(I,J3))*DPCLD(I,KK-1)
DO 950 K=J1+1,J3-1
UFN(I,K) = UFNCLU(I,KK)+TEMPF*(PP(I,K)-PPTOP(I,KK-1))
DFN(I,K) = DFNCLU(I,KK)+TEMPG*(PP(I,K)-PPTOP(I,KK-1))
950 CONTINUE
ENDIF
965 CONTINUE
970 CONTINUE
DO 980 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 980
DO 981 K=1,LP1
DFSWC(I,K) = DFSWC(I,K) + DFN(I,K)*DFNTOP(I,N)
UFSWC(I,K) = UFSWC(I,K) + UFN(I,K)*DFNTOP(I,N)
981 CONTINUE
980 CONTINUE
DO 990 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 990
GDFND(I) = GDFND(I) + CCMAX(I)*DFN(I,LP1)*DFNTOP(I,N)
990 CONTINUE
1000 CONTINUE
DO 1100 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 1100
DO 1101 K=1,LP1
DFSWC(I,K) = TMP1(I)*DFSWL(I,K) + CCMAX(I)*DFSWC(I,K)
UFSWC(I,K) = TMP1(I)*UFSWL(I,K) + CCMAX(I)*UFSWC(I,K)
1101 CONTINUE
1100 CONTINUE
DO 1200 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 1200
DO 1201 KK=1,LP1
FSWC(I,KK) = UFSWC(I,KK)-DFSWC(I,KK)
1201 CONTINUE
1200 CONTINUE
DO 1250 I=MYIS,MYIE
KCLDS=NCLDS(I)
IF(KCLDS.EQ.0) GO TO 1250
DO 1251 KK=1, L
HSWC(I,KK) = RADCON*(FSWC(I,KK+1)-FSWC(I,KK))/DP(I,KK)
1251 CONTINUE
1250 CONTINUE
END SUBROUTINE SWR93
!-----------------------------------------------------------------------
SUBROUTINE RADFS & 2,8
! *****************************************************************
! * *
! * THE INTERNAL DRIVE FOR GFDL RADIATION *
! * THIS SUBROUTINE WAS FROM Y.H AND K.A.C (1993) *
! * AND MODIFIED BY Q. ZHAO FOR USE IN THE ETA MODEL *
! * NOV. 18, 1993 *
! * *
! * UPDATE: THIS SUBROUTINE WAS MODIFIED TO USE CLOUD FRACTION *
! * ON EACH MODEL LAYER. *
! * QINGYUN ZHAO 95-3-22 *
! * *
! * UPDATE: R1 HAS BEEN ADDED TO THE INPUTS FROM RADTN TO *
! * COMPUTE THE VARIATION OF SOLAR CONSTANT AT THE TOP *
! * OF ATMOSPHERE WITH JULIAN DAY IN A YEAR. *
! * QINGYUN ZHAO 96-7-23 *
! *****************************************************************
!***
!*** REQUIRED INPUT:
!***
(QS,PP,PPI,QQH2O,TT,O3QO3,TSFC,SLMSK,ALBEDO,XLAT &
, CAMT,KTOP,KBTM,NCLDS,EMCLD,RRCL,TTCL &
, COSZRO,TAUDAR,IBEG &
, KO3,KALB &
, ITIMSW,ITIMLW &
!***************************************************************************
!* IX IS THE LENGTH OF A ROW IN THE DOMAIN
!
!* QS(IX): THE SURFACE PRESSURE (PA)
!* PP(IX,L): THE MIDLAYER PRESSURES (PA) (L IS THE VERT. DIMEN.)
!* PPI(IX,LP1) THE INTERFACE PRESSURES (PA)
!* QQH2O(IX,L): THE MIDLAYER WATER VAPOR MIXING RATIO (KG/KG)
!* TT(IX,L): THE MIDLAYER TEMPERATURE (K)
!* O3QO3(IX,L): THE MIDLAYER OZONE MIXING RATIO
!* TSFC(IX): THE SKIN TEMP. (K); NEGATIVE OVER WATER
!* SLMSK(IX): THE SEA MASK (LAND=0,SEA=1)
!* ALBEDO(IX): THE SURFACE ALBEDO (EXPRESSED AS A FRACTION)
!* XLAT(IX): THE GEODETIC LATITUDES OF EACH COLUMN IN DEGREES
!* (N.H.> 0)
!* THE FOLLOWING ARE CLOUD INFORMATION FOR EACH CLOUD LAYER
!* LAYER=1:SURFACE
!* LAYER=2:FIRST LAYER ABOVE GROUND, AND SO ON
!* CAMT(IX,LP1): CLOUD FRACTION OF EACH CLOUD LAYER
!* ITYP(IX,LP1): CLOUD TYPE(=1: STRATIFORM, =2:CONVECTIVE)
!* KTOP(IX,LP1): HEIGHT OF CLOUD TOP OF EACH CLOUD LAYER (IN ETA LEVEL)
!* KBTM(IX,LP1): BOTTOM OF EACH CLOUD LAYER
!* NCLDS(IX): NUMBER OF CLOUD LAYERS
!* EMCLD(IX,LP1): CLOUD EMISSIVITY
!* RRCL(IX,NB,LP1) CLOUD REFLECTTANCES FOR SW SPECTRAL BANDS
!* TTCL(IX,NB,LP1) CLOUD TRANSMITANCES FOR SW SPECTRAL BANDS
!* THE ABOVE ARE CLOUD INFORMATION FOR EACH CLOUD LAYER
!*
!* COSZRO(IX): THE COSINE OF THE SOLAR ZENITH ANGLE
!* TAUDAR: =1.0
!* IBEG: =1
!* KO3: =1 ( READ IN THE QZONE DATA)
!* KALB: =0
!* SLMRF(LP1): THE INTERFACE'S ETA (LP1=L+1)
!* SLYMRF(L): THE MIDLAYER ETA
!* ITIMSW: =1/0 (SHORTWAVE CALC. ARE DESIRED/NOT DESIRED)
!* ITIMLW: =1/0 (LONGWAVE CALC. ARE DESIRED/NOT DESIRED)
!************************************************************************
!***
!*** THE FOLLOWING ARE ADDITIONAL FOR ETA MODEL
!***
, JD,GMT &
!**************************************************************************
!* JD: JULIAN DAY IN A YEAR
!* R1: THE NON-DIMENSIONAL SUN-EARTH DISTANCE
!* GMT:HOUR
!**************************************************************************
!***
!*** GENERATED OUTPUT REQUIRED BY THE ETA MODEL
!***
, SWH,HLW &
! , T1,T2,T4,EM1V,EM1VW,EM3V &
, FLWUP,FSWUP,FSWDN,FSWDNS,FSWUPS,FLWDNS,FLWUPS &
! , DDUO3N,DDO3N2,DDO3N3,DDO3N4 &
! , SKO3R,AB15WD,SKC1R,SKO2D &
, ids,ide, jds,jde, kds,kde &
, ims,ime, jms,jme, kms,kme &
, its,ite, jts,jte, kts,kte )
!************************************************************************
!* SWH: ATMOSPHERIC SHORTWAVE HEATING RATES IN K/S.
!* SWH IS A REAL ARRAY DIMENSIONED (NCOL X LM).
!* HLW: ATMOSPHERIC LONGWAVE HEATING RATES IN K/S.
!* HLW IS A REAL ARRAY DIMENSIONED (NCOL X LM).
!* FLWUP: UPWARD LONGWAVE FLUX AT TOP OF THE ATMOSPHERE IN W/M**2.
!* FLWUP IS A REAL ARRAY DIMENSIONED (NCOL).
!* FSWUP: UPWARD SHORTWAVE FLUX AT TOP OF THE ATMOSPHERE IN W/M**2.
!* FSWUP IS A REAL ARRAY DIMENSIONED (NCOL).
!* FSWDN: DOWNWARD SHORTWAVE FLUX AT TOP OF THE ATMOSPHERE IN W/M**2.
!* FSWDN IS A REAL ARRAY DIMENSIONED (NCOL).
!* FSWDNS: DOWNWARD SHORTWAVE FLUX AT THE SURFACE IN W/M**2.
!* FSWDNS IS A REAL ARRAY DIMENSIONED (NCOL).
!* FSWUPS: UPWARD SHORTWAVE FLUX AT THE SURFACE IN W/M**2.
!* FSWUPS IS A REAL ARRAY DIMENSIONED (NCOL).
!* FLWDNS: DOWNWARD LONGWAVE FLUX AT THE SURFACE IN W/M**2.
!* FLWDNS IS A REAL ARRAY DIMENSIONED (NCOL).
!* FLWUPS: UPWARD LONGWAVE FLUX AT THE SURFACE IN W/M**2.
!* FLWUPS IS A REAL ARRAY DIMENSIONED (NCOL).
!************************************************************************
!***
!*** THE FOLLOWING OUTPUTS ARE NOT REQUIRED BY THE ETA MODEL
!***
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
!INTEGER, PARAMETER :: NBLY=15
INTEGER, PARAMETER :: NB=12
INTEGER, PARAMETER :: NBLX=47
INTEGER , PARAMETER:: NBLW = 163
REAL,PARAMETER :: AMOLWT=28.9644
REAL,PARAMETER :: CSUBP=1.00484E7
REAL,PARAMETER :: DIFFCTR=1.66
REAL,PARAMETER :: G=980.665
REAL,PARAMETER :: GINV=1./G
REAL,PARAMETER :: GRAVDR=980.0
REAL,PARAMETER :: O3DIFCTR=1.90
REAL,PARAMETER :: P0=1013250.
REAL,PARAMETER :: P0INV=1./P0
REAL,PARAMETER :: GP0INV=GINV*P0INV
REAL,PARAMETER :: P0XZP2=202649.902
REAL,PARAMETER :: P0XZP8=810600.098
REAL,PARAMETER :: P0X2=2.*1013250.
REAL,PARAMETER :: RADCON=8.427
REAL,PARAMETER :: RADCON1=1./8.427
REAL,PARAMETER :: RATCO2MW=1.519449738
REAL,PARAMETER :: RATH2OMW=.622
REAL,PARAMETER :: RGAS=8.3142E7
REAL,PARAMETER :: RGASSP=8.31432E7
REAL,PARAMETER :: SECPDA=8.64E4
!
!******THE FOLLOWING ARE MATHEMATICAL CONSTANTS*******
! ARRANGED IN DECREASING ORDER
REAL,PARAMETER :: HUNDRED=100.
REAL,PARAMETER :: HNINETY=90.
REAL,PARAMETER :: HNINE=9.0
REAL,PARAMETER :: SIXTY=60.
REAL,PARAMETER :: FIFTY=50.
REAL,PARAMETER :: TEN=10.
REAL,PARAMETER :: EIGHT=8.
REAL,PARAMETER :: FIVE=5.
REAL,PARAMETER :: FOUR=4.
REAL,PARAMETER :: THREE=3.
REAL,PARAMETER :: TWO=2.
REAL,PARAMETER :: ONE=1.
REAL,PARAMETER :: HAF=0.5
REAL,PARAMETER :: QUARTR=0.25
REAL,PARAMETER :: ZERO=0.
!
!******FOLLOWING ARE POSITIVE FLOATING POINT CONSTANTS(H'S)
! ARRANGED IN DECREASING ORDER
REAL,PARAMETER :: H83E26=8.3E26
REAL,PARAMETER :: H71E26=7.1E26
REAL,PARAMETER :: H1E15=1.E15
REAL,PARAMETER :: H1E13=1.E13
REAL,PARAMETER :: H1E11=1.E11
REAL,PARAMETER :: H1E8=1.E8
REAL,PARAMETER :: H2E6=2.0E6
REAL,PARAMETER :: H1E6=1.0E6
REAL,PARAMETER :: H69766E5=6.97667E5
REAL,PARAMETER :: H4E5=4.E5
REAL,PARAMETER :: H165E5=1.65E5
REAL,PARAMETER :: H5725E4=57250.
REAL,PARAMETER :: H488E4=48800.
REAL,PARAMETER :: H1E4=1.E4
REAL,PARAMETER :: H24E3=2400.
REAL,PARAMETER :: H20788E3=2078.8
REAL,PARAMETER :: H2075E3=2075.
REAL,PARAMETER :: H18E3=1800.
REAL,PARAMETER :: H1224E3=1224.
REAL,PARAMETER :: H67390E2=673.9057
REAL,PARAMETER :: H5E2=500.
REAL,PARAMETER :: H3082E2=308.2
REAL,PARAMETER :: H3E2=300.
REAL,PARAMETER :: H2945E2=294.5
REAL,PARAMETER :: H29316E2=293.16
REAL,PARAMETER :: H26E2=260.0
REAL,PARAMETER :: H25E2=250.
REAL,PARAMETER :: H23E2=230.
REAL,PARAMETER :: H2E2=200.0
REAL,PARAMETER :: H15E2=150.
REAL,PARAMETER :: H1386E2=138.6
REAL,PARAMETER :: H1036E2=103.6
REAL,PARAMETER :: H8121E1=81.21
REAL,PARAMETER :: H35E1=35.
REAL,PARAMETER :: H3116E1=31.16
REAL,PARAMETER :: H28E1=28.
REAL,PARAMETER :: H181E1=18.1
REAL,PARAMETER :: H18E1=18.
REAL,PARAMETER :: H161E1=16.1
REAL,PARAMETER :: H16E1=16.
REAL,PARAMETER :: H1226E1=12.26
REAL,PARAMETER :: H9P94=9.94
REAL,PARAMETER :: H6P08108=6.081081081
REAL,PARAMETER :: H3P6=3.6
REAL,PARAMETER :: H3P5=3.5
REAL,PARAMETER :: H2P9=2.9
REAL,PARAMETER :: H2P8=2.8
REAL,PARAMETER :: H2P5=2.5
REAL,PARAMETER :: H1P8=1.8
REAL,PARAMETER :: H1P4387=1.4387
REAL,PARAMETER :: H1P41819=1.418191
REAL,PARAMETER :: H1P4=1.4
REAL,PARAMETER :: H1P25892=1.258925411
REAL,PARAMETER :: H1P082=1.082
REAL,PARAMETER :: HP816=0.816
REAL,PARAMETER :: HP805=0.805
REAL,PARAMETER :: HP8=0.8
REAL,PARAMETER :: HP60241=0.60241
REAL,PARAMETER :: HP602409=0.60240964
REAL,PARAMETER :: HP6=0.6
REAL,PARAMETER :: HP526315=0.52631579
REAL,PARAMETER :: HP518=0.518
REAL,PARAMETER :: HP5048=0.5048
REAL,PARAMETER :: HP3795=0.3795
REAL,PARAMETER :: HP369=0.369
REAL,PARAMETER :: HP26=0.26
REAL,PARAMETER :: HP228=0.228
REAL,PARAMETER :: HP219=0.219
REAL,PARAMETER :: HP166666=.166666
REAL,PARAMETER :: HP144=0.144
REAL,PARAMETER :: HP118666=0.118666192
REAL,PARAMETER :: HP1=0.1
! (NEGATIVE EXPONENTIALS BEGIN HERE)
REAL,PARAMETER :: H658M2=0.0658
REAL,PARAMETER :: H625M2=0.0625
REAL,PARAMETER :: H44871M2=4.4871E-2
REAL,PARAMETER :: H44194M2=.044194
REAL,PARAMETER :: H42M2=0.042
REAL,PARAMETER :: H41666M2=0.0416666
REAL,PARAMETER :: H28571M2=.02857142857
REAL,PARAMETER :: H2118M2=0.02118
REAL,PARAMETER :: H129M2=0.0129
REAL,PARAMETER :: H1M2=.01
REAL,PARAMETER :: H559M3=5.59E-3
REAL,PARAMETER :: H3M3=0.003
REAL,PARAMETER :: H235M3=2.35E-3
REAL,PARAMETER :: H1M3=1.0E-3
REAL,PARAMETER :: H987M4=9.87E-4
REAL,PARAMETER :: H323M4=0.000323
REAL,PARAMETER :: H3M4=0.0003
REAL,PARAMETER :: H285M4=2.85E-4
REAL,PARAMETER :: H1M4=0.0001
REAL,PARAMETER :: H75826M4=7.58265E-4
REAL,PARAMETER :: H6938M5=6.938E-5
REAL,PARAMETER :: H394M5=3.94E-5
REAL,PARAMETER :: H37412M5=3.7412E-5
REAL,PARAMETER :: H15M5=1.5E-5
REAL,PARAMETER :: H1439M5=1.439E-5
REAL,PARAMETER :: H128M5=1.28E-5
REAL,PARAMETER :: H102M5=1.02E-5
REAL,PARAMETER :: H1M5=1.0E-5
REAL,PARAMETER :: H7M6=7.E-6
REAL,PARAMETER :: H4999M6=4.999E-6
REAL,PARAMETER :: H451M6=4.51E-6
REAL,PARAMETER :: H25452M6=2.5452E-6
REAL,PARAMETER :: H1M6=1.E-6
REAL,PARAMETER :: H391M7=3.91E-7
REAL,PARAMETER :: H1174M7=1.174E-7
REAL,PARAMETER :: H8725M8=8.725E-8
REAL,PARAMETER :: H327M8=3.27E-8
REAL,PARAMETER :: H257M8=2.57E-8
REAL,PARAMETER :: H1M8=1.0E-8
REAL,PARAMETER :: H23M10=2.3E-10
REAL,PARAMETER :: H14M10=1.4E-10
REAL,PARAMETER :: H11M10=1.1E-10
REAL,PARAMETER :: H1M10=1.E-10
REAL,PARAMETER :: H83M11=8.3E-11
REAL,PARAMETER :: H82M11=8.2E-11
REAL,PARAMETER :: H8M11=8.E-11
REAL,PARAMETER :: H77M11=7.7E-11
REAL,PARAMETER :: H72M11=7.2E-11
REAL,PARAMETER :: H53M11=5.3E-11
REAL,PARAMETER :: H48M11=4.8E-11
REAL,PARAMETER :: H44M11=4.4E-11
REAL,PARAMETER :: H42M11=4.2E-11
REAL,PARAMETER :: H37M11=3.7E-11
REAL,PARAMETER :: H35M11=3.5E-11
REAL,PARAMETER :: H32M11=3.2E-11
REAL,PARAMETER :: H3M11=3.0E-11
REAL,PARAMETER :: H28M11=2.8E-11
REAL,PARAMETER :: H24M11=2.4E-11
REAL,PARAMETER :: H23M11=2.3E-11
REAL,PARAMETER :: H2M11=2.E-11
REAL,PARAMETER :: H18M11=1.8E-11
REAL,PARAMETER :: H15M11=1.5E-11
REAL,PARAMETER :: H14M11=1.4E-11
REAL,PARAMETER :: H114M11=1.14E-11
REAL,PARAMETER :: H11M11=1.1E-11
REAL,PARAMETER :: H1M11=1.E-11
REAL,PARAMETER :: H96M12=9.6E-12
REAL,PARAMETER :: H93M12=9.3E-12
REAL,PARAMETER :: H77M12=7.7E-12
REAL,PARAMETER :: H74M12=7.4E-12
REAL,PARAMETER :: H65M12=6.5E-12
REAL,PARAMETER :: H62M12=6.2E-12
REAL,PARAMETER :: H6M12=6.E-12
REAL,PARAMETER :: H45M12=4.5E-12
REAL,PARAMETER :: H44M12=4.4E-12
REAL,PARAMETER :: H4M12=4.E-12
REAL,PARAMETER :: H38M12=3.8E-12
REAL,PARAMETER :: H37M12=3.7E-12
REAL,PARAMETER :: H3M12=3.E-12
REAL,PARAMETER :: H29M12=2.9E-12
REAL,PARAMETER :: H28M12=2.8E-12
REAL,PARAMETER :: H24M12=2.4E-12
REAL,PARAMETER :: H21M12=2.1E-12
REAL,PARAMETER :: H16M12=1.6E-12
REAL,PARAMETER :: H14M12=1.4E-12
REAL,PARAMETER :: H12M12=1.2E-12
REAL,PARAMETER :: H8M13=8.E-13
REAL,PARAMETER :: H46M13=4.6E-13
REAL,PARAMETER :: H36M13=3.6E-13
REAL,PARAMETER :: H135M13=1.35E-13
REAL,PARAMETER :: H12M13=1.2E-13
REAL,PARAMETER :: H1M13=1.E-13
REAL,PARAMETER :: H3M14=3.E-14
REAL,PARAMETER :: H15M14=1.5E-14
REAL,PARAMETER :: H14M14=1.4E-14
!
!******FOLLOWING ARE NEGATIVE FLOATING POINT CONSTANTS (HM'S)
! ARRANGED IN DESCENDING ORDER
REAL,PARAMETER :: HM2M2=-.02
REAL,PARAMETER :: HM6666M2=-.066667
REAL,PARAMETER :: HMP5=-0.5
REAL,PARAMETER :: HMP575=-0.575
REAL,PARAMETER :: HMP66667=-.66667
REAL,PARAMETER :: HMP805=-0.805
REAL,PARAMETER :: HM1EZ=-1.
REAL,PARAMETER :: HM13EZ=-1.3
REAL,PARAMETER :: HM19EZ=-1.9
REAL,PARAMETER :: HM1E1=-10.
REAL,PARAMETER :: HM1597E1=-15.97469413
REAL,PARAMETER :: HM161E1=-16.1
REAL,PARAMETER :: HM1797E1=-17.97469413
REAL,PARAMETER :: HM181E1=-18.1
REAL,PARAMETER :: HM8E1=-80.
REAL,PARAMETER :: HM1E2=-100.
!
REAL,PARAMETER :: H1M16=1.0E-16
REAL,PARAMETER :: H1M20=1.E-20
REAL,PARAMETER :: HP98=0.98
REAL,PARAMETER :: Q19001=19.001
REAL,PARAMETER :: DAYSEC=1.1574E-5
REAL,PARAMETER :: HSIGMA=5.673E-5
REAL,PARAMETER :: TWENTY=20.0
REAL,PARAMETER :: HP537=0.537
REAL,PARAMETER :: HP2=0.2
REAL,PARAMETER :: RCO2=3.3E-4
REAL,PARAMETER :: Q14330=1.43306E-6
REAL,PARAMETER :: H3M6=3.0E-6
REAL,PARAMETER :: PI=3.1415927
REAL,PARAMETER :: DEGRAD=180.0/PI
REAL,PARAMETER :: H74E1=74.0
REAL,PARAMETER :: H15E1=15.0
REAL, PARAMETER:: B0 = -.51926410E-4
REAL, PARAMETER:: B1 = -.18113332E-3
REAL, PARAMETER:: B2 = -.10680132E-5
REAL, PARAMETER:: B3 = -.67303519E-7
REAL, PARAMETER:: AWIDE = 0.309801E+01
REAL, PARAMETER:: BWIDE = 0.495357E-01
REAL, PARAMETER:: BETAWD = 0.347839E+02
REAL, PARAMETER:: BETINW = 0.766811E+01
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
ims,ime, jms,jme, kms,kme , &
its,ite, jts,jte, kts,kte
INTEGER, INTENT(IN) :: IBEG,KO3,KALB,ITIMSW,ITIMLW,JD
REAL, INTENT(IN) :: GMT
!----------------------------------------------------------------------
! ****************************************************************
! * GENERALIZED FOR PLUG-COMPATIBILITY - *
! * ORIGINAL CODE WAS CLEANED-UP GFDL CODE...K.CAMPANA MAR89..*
!......* EXAMPLE FOR MRF: *
! * KO3 =0 AND O3QO3=DUMMY ARRAY. (GFDL CLIMO O3 USED) *
! * KEMIS=0 AND HI CLD EMIS COMPUTED HERE (CEMIS=DUMMY INPUT)*
! * KALB =0 AND SFC ALBEDO OVER OPEN WATER COMPUTED BELOW... *
! * KCCO2=0,CO2 OBTAINED FROM BLOCK DATA *
! * =1,CO2 COMPUTED IN HERE --- NOT AVAILABLE YET... *
! * SLMRF = INTERFACE (LEVELS) SIGMA *
! * SLYMRF= LAYER SIGMA *
! * UPDATED FOR YUTAI HOU SIB SW RADIATION....KAC 6 MAR 92 *
! * OCEAN ALBEDO FOR BEAM SET TO BULK SFCALB, SINCE *
! * COSINE ZENITH ANGLE EFFECTS ALREADY THERE(REF:PAYNE) *
! * SLMSK = 0. *
! * SNOW ICE ALBEDO FOR BEAM NOT ENHANCED VIA COSINE ZENITH *
! * ANGLE EITHER CAUSE VALU ALREADY HIGH (WE SEE POLAR *
! * COOLING IF WE DO BEAM CALCULATION)....KAC 17MAR92 *
! * ALBEDO GE .5 *
! * UPDATED TO OBTAIN CLEAR SKY FLUXES "ON THE FLY" FOR *
! * CLOUD FORCING DIAGNOSTICS ELSEWHERE...KAC 7AUG92 *
! * SEE ##CLR LINES...RADFS,LWR88,FST88,SPA88 ....... *
! * UPDATED FOR USE NEW CLD SCHEME ......YH DEC 92 *
! * INPUT CLD MAY BE AS ORIGINAL IN 3 DOMAIN (CLD,MTOP,MBOT) *
! * OR IN A VERTICAL ARRAY OF 18 MDL LAYERS (CLDARY) *
! * IEMIS=0 USE THE ORG. CLD EMIS SCHEME *
! * =1 USE TEMP DEP. CLD EMIS SCHEME *
! * UPDATED TO COMPUTE CLD LAYER REFLECTTANCE AND TRANSMITTANCE *
! * INPUT CLD EMISSIVITY AND OPTICAL THICKNESS 'EMIS0,TAUC0' *
! * ......YH FEB 93 *
! ****************************************************************
!--------------------------------
! INTEGER, PARAMETER:: LNGTH=37*kte
!--------------------------------
! REAL, INTENT(IN) :: SKO3R,AB15WD,SKC1R,SKO2D
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte):: PP,TT
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte):: QQH2O
REAL, INTENT(IN), DIMENSION(its:ite,kts:kte+1):: PPI,CAMT,EMCLD
REAL, INTENT(IN), DIMENSION(its:ite):: QS,TSFC,SLMSK,ALBEDO,XLAT
REAL, INTENT(IN), DIMENSION(its:ite):: COSZRO,TAUDAR
REAL, INTENT(OUT), DIMENSION(its:ite):: FLWUPS
INTEGER, INTENT(IN), DIMENSION(its:ite):: NCLDS
INTEGER, INTENT(IN), DIMENSION(its:ite,kts:kte+1):: KTOP,KBTM
REAL, INTENT(INOUT), DIMENSION(its:ite,NB,kts:kte+1):: TTCL,RRCL
REAL, intent(IN), DIMENSION(its:ite,kts:kte):: O3QO3
! REAL, INTENT(IN), DIMENSION(5040):: T1,T2,T4,EM1V,EM1VW
! REAL, INTENT(IN), DIMENSION(5040) :: EM3V
! REAL, DIMENSION(its:ite)::ALVBR,ALNBR, ALVDR,ALNDR
! TABLE ???
REAL, DIMENSION(3) :: BO3RND,AO3RND
REAL, DIMENSION(NBLY) :: APCM,BPCM,ATPCM,BTPCM,ACOMB, &
BCOMB,BETACM
DATA AO3RND / 0.543368E+02, 0.234676E+04, 0.384881E+02/
DATA BO3RND / 0.526064E+01, 0.922424E+01, 0.496515E+01/
DATA ACOMB / &
0.152070E+05, 0.332194E+04, 0.527177E+03, 0.163124E+03, &
0.268808E+03, 0.534591E+02, 0.268071E+02, 0.123133E+02, &
0.600199E+01, 0.640803E+00, 0.501549E-01, 0.167961E-01, &
0.178110E-01, 0.170166E+00, 0.537083E-02/
DATA BCOMB / &
0.152538E+00, 0.118677E+00, 0.103660E+00, 0.100119E+00, &
0.127518E+00, 0.118409E+00, 0.904061E-01, 0.642011E-01, &
0.629660E-01, 0.643346E-01, 0.717082E-01, 0.629730E-01, &
0.875182E-01, 0.857907E-01, 0.214005E+00/
DATA APCM / &
-0.671879E-03, 0.654345E-02, 0.143657E-01, 0.923593E-02, &
0.117022E-01, 0.159596E-01, 0.181600E-01, 0.145013E-01, &
0.170062E-01, 0.233303E-01, 0.256735E-01, 0.274745E-01, &
0.279259E-01, 0.197002E-01, 0.349782E-01/
DATA BPCM / &
-0.113520E-04, -0.323965E-04, -0.448417E-04, -0.230779E-04, &
-0.361981E-04, -0.145117E-04, 0.198349E-04, -0.486529E-04, &
-0.550050E-04, -0.684057E-04, -0.447093E-04, -0.778390E-04, &
-0.982953E-04, -0.772497E-04, -0.748263E-04/
DATA ATPCM / &
-0.106346E-02, 0.641531E-02, 0.137362E-01, 0.922513E-02, &
0.136162E-01, 0.169791E-01, 0.206959E-01, 0.166223E-01, &
0.171776E-01, 0.229724E-01, 0.275530E-01, 0.302731E-01, &
0.281662E-01, 0.199525E-01, 0.370962E-01/
DATA BTPCM / &
-0.735731E-05, -0.294149E-04, -0.505592E-04, -0.280894E-04, &
-0.492972E-04, -0.341508E-04, -0.362947E-04, -0.250487E-04, &
-0.521369E-04, -0.746260E-04, -0.744124E-04, -0.881905E-04, &
-0.933645E-04, -0.664045E-04, -0.115290E-03/
DATA BETACM / &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.188625E+03, 0.144293E+03, 0.174098E+03, 0.909366E+02, &
0.497489E+02, 0.221212E+02, 0.113124E+02, 0.754174E+01, &
0.589554E+01, 0.495227E+01, 0.000000E+00/
! *********************************************
!====> * OUTPUT TO CALLING PROGRAM *
! *********************************************
REAL, INTENT(INOUT),DIMENSION(its:ite,kts:kte)::SWH,HLW
REAL, INTENT(OUT), DIMENSION(its:ite):: FSWUP,FSWUPS,FSWDN, &
FSWDNS,FLWUP,FLWDNS
! *********************************************
!====> * POSSIBLE OUTPUT TO CALLING PROGRAM *
! *********************************************
REAL, DIMENSION(its:ite):: GDFVBR,GDFNBR,GDFVDR,GDFNDR
! ************************************************************
!====> * ARRAYS NEEDED BY SWR91SIB..FOR CLEAR SKY DATA(EG.FSWL) *
! ************************************************************
REAL, DIMENSION(its:ite,kts:kte+1)::FSWL,HSWL,UFL,DFL
! ******************************************************
!====> * ARRAYS NEEDED BY CLO88, LWR88, SWR89 OR SWR91SIB *
! ******************************************************
REAL, DIMENSION(its:ite,kts:kte+1,kts:kte+1)::CLDFAC
REAL, DIMENSION(its:ite,kts:kte+1)::EQCMT,PRESS,TEMP,FSW,HSW,UF,DF
REAL, DIMENSION(its:ite,kts:kte)::RH2O,QO3,HEATRA
REAL, DIMENSION(its:ite):: COSZEN,TAUDA,GRNFLX,TOPFLX,GRDFLX
REAL, DIMENSION(kts:kte+1)::PHALF
!..... ADD PRESSURE INTERFACE
REAL, DIMENSION(NB) :: ABCFF,PWTS
DATA ABCFF/2*4.0E-5,.002,.035,.377,1.95,9.40,44.6,190., &
989.,2706.,39011./
DATA PWTS/.5000,.121416,.0698,.1558,.0631,.0362,.0243,.0158,.0087, &
.001467,.002342,.001075/
REAL :: CFCO2,CFO3,REFLO3,RRAYAV
DATA CFCO2,CFO3/508.96,466.64/
DATA REFLO3/1.9/
DATA RRAYAV/0.144/
! *********************************************
!====> * VECTOR TEMPORARIES FOR CLOUD CALC. *
! *********************************************
REAL, DIMENSION(its:ite):: TTHAN
REAL, DIMENSION(its:ite,kts:kte):: DO3V,DO3VP
INTEGER, DIMENSION(its:ite):: JJROW
!====> **************************************************************
!-- SEASONAL CLIMATOLOGIES OF O3 (OBTAINED FROM A PREVIOUSLY RUN
! CODE WHICH INTERPOLATES O3 TO USER VERTICAL COORDINATE).
! DEFINED AS 5 DEG LAT MEANS N.P.->S.P.
! COMMON /SAVMEM/ &
!- ...WINTER.... ...SPRING.... ...SUMMER.... ....FALL.....
! DDUO3N(37,L), DDO3N2(37,L), DDO3N3(37,L), DDO3N4(37,L)
REAL, DIMENSION(37,kte) :: DDUO3N,DDO3N2,DDO3N3,DDO3N4
! DIMENSION RAD1(37*kte), RAD2(37*kte), RAD3(37*kte), RAD4(37*kte)
! EQUIVALENCE (RAD1(1),DDUO3N(1,1)),(RAD2(1),DDO3N2(1,1))
! EQUIVALENCE (RAD3(1),DDO3N3(1,1)),(RAD4(1),DDO3N4(1,1))
!====> **************************************************************
!
REAL, DIMENSION(21,20) :: ALBD
REAL, DIMENSION(20) :: ZA
REAL, DIMENSION(21) :: TRN
REAL, DIMENSION(19) :: DZA
REAL :: YEAR,RLAG,TPI,SC,SSOLAR,DATE,RANG,TH2,ZEN,DZEN,ALB1,ALB2
INTEGER :: IR,IQ,JX
DATA TRN/.00,.05,.10,.15,.20,.25,.30,.35,.40,.45,.50,.55,.60,.65, &
.70,.75,.80,.85,.90,.95,1.00/
REAL :: ALB11(21,7),ALB22(21,7),ALB33(21,6)
EQUIVALENCE (ALB11(1,1),ALBD(1,1)),(ALB22(1,1),ALBD(1,8)), &
(ALB33(1,1),ALBD(1,15))
DATA ALB11/ .061,.062,.072,.087,.115,.163,.235,.318,.395,.472,.542, &
.604,.655,.693,.719,.732,.730,.681,.581,.453,.425,.061,.062,.070, &
.083,.108,.145,.198,.263,.336,.415,.487,.547,.595,.631,.656,.670, &
.652,.602,.494,.398,.370,.061,.061,.068,.079,.098,.130,.174,.228, &
.290,.357,.424,.498,.556,.588,.603,.592,.556,.488,.393,.342,.325, &
.061,.061,.065,.073,.086,.110,.150,.192,.248,.306,.360,.407,.444, &
.469,.480,.474,.444,.386,.333,.301,.290,.061,.061,.065,.070,.082, &
.101,.131,.168,.208,.252,.295,.331,.358,.375,.385,.377,.356,.320, &
.288,.266,.255,.061,.061,.063,.068,.077,.092,.114,.143,.176,.210, &
.242,.272,.288,.296,.300,.291,.273,.252,.237,.266,.220,.061,.061, &
.062,.066,.072,.084,.103,.127,.151,.176,.198,.219,.236,.245,.250, &
.246,.235,.222,.211,.205,.200/
DATA ALB22/ .061,.061,.061,.065,.071,.079,.094,.113,.134,.154,.173, &
.185,.190,.193,.193,.190,.188,.185,.182,.180,.178,.061,.061,.061, &
.064,.067,.072,.083,.099,.117,.135,.150,.160,.164,.165,.164,.162, &
.160,.159,.158,.157,.157,.061,.061,.061,.062,.065,.068,.074,.084, &
.097,.111,.121,.127,.130,.131,.131,.130,.129,.127,.126,.125,.122, &
.061,.061,.061,.061,.062,.064,.070,.076,.085,.094,.101,.105,.107, &
.106,.103,.100,.097,.096,.095,.095,.095,.061,.061,.061,.060,.061, &
.062,.065,.070,.075,.081,.086,.089,.090,.088,.084,.080,.077,.075, &
.074,.074,.074,.061,.061,.060,.060,.060,.061,.063,.065,.068,.072, &
.076,.077,.076,.074,.071,.067,.064,.062,.061,.061,.061,.061,.061, &
.060,.060,.060,.060,.061,.062,.065,.068,.069,.069,.068,.065,.061, &
.058,.055,.054,.053,.052,.052/
DATA ALB33/ .061,.061,.060,.060,.060,.060,.060,.060,.062,.065,.065, &
.063,.060,.057,.054,.050,.047,.046,.045,.044,.044,.061,.061,.060, &
.060,.060,.059,.059,.059,.059,.059,.058,.055,.051,.047,.043,.039, &
.035,.033,.032,.031,.031,.061,.061,.060,.060,.060,.059,.059,.058, &
.057,.056,.054,.051,.047,.043,.039,.036,.033,.030,.028,.027,.026, &
.061,.061,.060,.060,.060,.059,.059,.058,.057,.055,.052,.049,.045, &
.040,.036,.032,.029,.027,.026,.025,.025,.061,.061,.060,.060,.060, &
.059,.059,.058,.056,.053,.050,.046,.042,.038,.034,.031,.028,.026, &
.025,.025,.025,.061,.061,.060,.060,.059,.058,.058,.057,.055,.053, &
.050,.046,.042,.038,.034,.030,.028,.029,.025,.025,.025/
DATA ZA/90.,88.,86.,84.,82.,80.,78.,76.,74.,70.,66.,62.,58.,54., &
50.,40.,30.,20.,10.,0.0/
DATA DZA/8*2.0,6*4.0,5*10.0/
! ***********************************************************
!
REAL, DIMENSION(its:ite) :: ALVB,ALNB,ALVD,ALND, &
GDFVB, &
GDFNB,GDFVD,GDFND, &
SFCALB
REAL :: SOLC,RSIN1,RCOS1,RCOS2
REAL :: ALBD0,ALVD1,ALND1,RRVCO2,RRCO2
INTEGER :: N
!====> BEGIN HERE .......................
!
! SOLC,THE SOLAR CONSTANT IS SCALED TO A MORE CURRENT VALUE.
! I.E. IF SOLC=2.0 LY/MIN THEN SSOLAR=1.96 LY/MIN.
!.. RE-COMPUTED CAUSE SSOLAR OVERWRITTEN AS PART OF SCRATCH COMMON
!
INTEGER :: K, I,KP,LLM2,J1,J3,KMAX,KMIN,KCLDS,ICNT,LLM1
INTEGER :: L,LP1,LP2,LP3,LM1,LM2,LM3,MYIS,MYIE,LLP1,LL,KK,KLEN
L=kte
LP1=L+1; LP2=L+2; LP3=L+3; LLP1 = 2*L + 1
LM1=L-1; LM2=L-2; LM3=L-3; LL = 2*L
LLM2 = LL-2; LLM1=LL-1
MYIS=its; MYIE=ite
!******ZHAO
! NOTE: XLAT IS IN DEGREE HERE
!*****ZHAO
YEAR=365.25
RLAG=14.8125
TPI=6.283185308
SC=2.
SOLC=SC/(R1*R1)
!*****************************
! Special note: The solar constant is reduced extra 3 percent to account
! for the lack of aerosols in the shortwave radiation
! parameterization. Q. Zhao 96-7-23
!****************************
SSOLAR=SOLC*HP98
SSOLAR=SSOLAR*0.97
DATE=JD+GMT/24.0
RANG=TPI*(DATE-RLAG)/YEAR
RSIN1=SIN(RANG)
RCOS1=COS(RANG)
RCOS2=COS(2.0*RANG)
DO 40 I=MYIS,MYIE
IR = I + IBEG - 1
TH2=HP2*XLAT(IR)
JJROW(I)=Q19001-TH2
TTHAN(I)=(19-JJROW(I))-TH2
!..... NOTE THAT THE NMC VARIABLES ARE IN MKS (THUS PRESSURE IS IN
! CENTIBARS)WHILE ALL GFDL VARIABLES ARE IN CGS UNITS
SFCALB(I) = ALBEDO(IR)
!..... NOW PUT SFC TEMP,PRESSURES, ZENITH ANGLE INTO SW COMMON BLOCK...
!***ZHAO
! NOTE: ALL PRESSURES INPUT FROM THE ETA MODEL ARE IN PA
! THE UNIT FOR PRESS IS MICRO BAR
! SURFACE TEMPERATURE ARE NEGATIVE OVER OCEANS IN THE ETA MODEL
!***ZHAO
PRESS(I,LP1)=QS(IR)*10.0
TEMP(I,LP1)=ABS(TSFC(IR))
COSZEN(I) = COSZRO(IR)
TAUDA(I) = TAUDAR(IR)
40 CONTINUE
!***ZHAO
!..... ALL GFDL VARIABLES HAVE K=1 AT THE TOP OF THE ATMOSPHERE.NMC
! ETA MODEL HAS THE SAME STRUCTURE
!***ZHAO
DO 50 K=1,L
DO 50 I=MYIS,MYIE
IR = I + IBEG - 1
!..... NOW PUT TEMP,PRESSURES, INTO SW COMMON BLOCK..........
TEMP(I,K) = TT(IR,K)
PRESS(I,K) = 10.0 * PP(IR,K)
!.... STORE LYR MOISTURE AND ADD TO SW COMMON BLOCK
RH2O(I,K)=QQH2O(IR,K)
IF(RH2O(I,K).LT.H3M6) RH2O(I,K)=H3M6
50 CONTINUE
!... *************************
IF (KO3.EQ.0) GO TO 65
!... *************************
DO 60 K=1,L
DO 60 I=MYIS,MYIE
QO3(I,K) = O3QO3(I+IBEG-1,K)
60 CONTINUE
65 CONTINUE
!... ************************************
IF (KALB.GT.0) GO TO 110
!... ************************************
!..... THE FOLLOWING CODE GETS ALBEDO FROM PAYNE,1972 TABLES IF
! 1) OPEN SEA POINT (SLMSK=1);2) KALB=0
IQ=INT(TWENTY*HP537+ONE)
DO 105 I=MYIS,MYIE
IF(COSZEN(I).GT.0.0 .AND. SLMSK(I+IBEG-1).GT.0.5) THEN
ZEN=DEGRAD*ACOS(MAX(COSZEN(I),0.0))
IF(ZEN.GE.H74E1) JX=INT(HAF*(HNINETY-ZEN)+ONE)
IF(ZEN.LT.H74E1.AND.ZEN.GE.FIFTY) &
JX=INT(QUARTR*(H74E1-ZEN)+HNINE)
IF(ZEN.LT.FIFTY) JX=INT(HP1*(FIFTY-ZEN)+H15E1)
DZEN=-(ZEN-ZA(JX))/DZA(JX)
ALB1=ALBD(IQ,JX)+DZEN*(ALBD(IQ,JX+1)-ALBD(IQ,JX))
ALB2=ALBD(IQ+1,JX)+DZEN*(ALBD(IQ+1,JX+1)-ALBD(IQ+1,JX))
SFCALB(I)=ALB1+TWENTY*(ALB2-ALB1)*(HP537-TRN(IQ))
ENDIF
105 CONTINUE
110 CONTINUE
! **********************************
IF (KO3.GT.0) GO TO 135
! **********************************
!.... COMPUTE CLIMATOLOGICAL ZONAL MEAN OZONE,
!.... SEASONAL AND SPATIAL INTERPOLATION DONE BELOW.
DO 125 I=MYIS,MYIE
PHALF(1)=0.
PHALF(LP1)=PPI(I,kme)
DO L=1,LM1
PHALF(L+1)=PP(I,L) ! AETA(L)*PDIF+PT
ENDDO
CALL O3INT(PHALF,DDUO3N,DDO3N2,DDO3N3,DDO3N4, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
DO 130 K=1,L
DO3V(I,K) = DDUO3N(JJROW(I),K) + RSIN1*DDO3N2(JJROW(I),K) &
+RCOS1*DDO3N3(JJROW(I),K) &
+RCOS2*DDO3N4(JJROW(I),K)
DO3VP(I,K) = DDUO3N(JJROW(I)+1,K) + RSIN1*DDO3N2(JJROW(I)+1,K) &
+RCOS1*DDO3N3(JJROW(I)+1,K) &
+RCOS2*DDO3N4(JJROW(I)+1,K)
!... NOW LATITUDINAL INTERPOLATION, AND
! CONVERT O3 INTO MASS MIXING RATIO(ORIGINAL DATA MPY BY 1.E4)
QO3(I,K) = H1M4 * (DO3V(I,K)+TTHAN(I)*(DO3VP(I,K)-DO3V(I,K)))
130 CONTINUE
125 CONTINUE
135 CONTINUE
!.............
DO 195 I=MYIS,MYIE
!..... VISIBLE AND NEAR IR DIFFUSE ALBEDO
ALVD(I) = SFCALB(I)
ALND(I) = SFCALB(I)
!..... VISIBLE AND NEAR IR DIRECT BEAM ALBEDO
ALVB(I) = SFCALB(I)
ALNB(I) = SFCALB(I)
!..... VISIBLE AND NEAR IR DIRECT BEAM ALBEDO,IF NOT OCEAN NOR SNOW
! ..FUNCTION OF COSINE SOLAR ZENITH ANGLE..
IF (SLMSK(I+IBEG-1).LT.0.5) THEN
IF (SFCALB(I).LE.0.5) THEN
ALBD0 = -18.0 * (0.5 - ACOS(COSZEN(I))/PI)
ALBD0 = EXP (ALBD0)
ALVD1 = (ALVD(I) - 0.054313) / 0.945687
ALND1 = (ALND(I) - 0.054313) / 0.945687
ALVB(I) = ALVD1 + (1.0 - ALVD1) * ALBD0
ALNB(I) = ALND1 + (1.0 - ALND1) * ALBD0
END IF
END IF
195 CONTINUE
!.....SURFACE VALUES OF RRCL AND TTCL
DO 200 N=1,2
DO 200 I=MYIS,MYIE
RRCL(I,N,1)=ALVD(I)
TTCL(I,N,1)=ZERO
200 CONTINUE
DO 220 N=3,NB
DO 220 I=MYIS,MYIE
RRCL(I,N,1)=ALND(I)
TTCL(I,N,1)=ZERO
220 CONTINUE
!... **************************
!... * END OF CLOUD SECTION *
!... **************************
!... THE FOLLOWING CODE CONVERTS RRVCO2,THE VOLUME MIXING RATIO OF CO2
! INTO RRCO2,THE MASS MIXING RATIO.
RRVCO2=RCO2
RRCO2=RRVCO2*RATCO2MW
250 IF(ITIMLW .EQ. 0) GO TO 300
!
! ***********************
!====> * LONG WAVE RADIATION *
! ***********************
!
!.... ACCOUNT FOR REDUCED EMISSIVITY OF ANY CLDS
DO 240 K=1,LP1
DO 240 I=MYIS,MYIE
EQCMT(I,K)=CAMT(I,K)*EMCLD(I,K)
240 CONTINUE
!.... GET CLD FACTOR FOR LW CALCULATIONS
!....
! shuhua
CALL CLO89(CLDFAC,EQCMT,NCLDS,KBTM,KTOP, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
! shuhua
!===> LONG WAVE RADIATION
! CALL LWR88(HEATRA,GRNFLX,TOPFLX, &
! PRESS,TEMP,RH2O,QO3,CLDFAC, &
! EQCMT,NCLDS,KTOP,KBTM, &
!
!! BO3RND,AO3RND,T1,T2,T4,EM1V,EM1VW,EM3V, &
! BO3RND,AO3RND, &
! APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
! ZERO,ONE,H18E3,P0INV,H6P08108,DIFFCTR, &
! GINV,H3M4,BETINW,RATH2OMW,GP0INV,P0,P0XZP8, &
! P0XZP2,H3M3,H1M3,H1M2,H25E2,B0,B2,B1,B3,HAF, &
! TEN,HP1,FOUR,HM1EZ,SKO3R, &
! AB15WD,SKC1R,RADCON,QUARTR,TWO, &
! HM6666M2,HMP66667,HMP5, HP166666,H41666M2, &
! RADCON1,H16E1, H28E1,H44194M2,H1P41819,SKO2D, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
CALL LWR88(HEATRA,GRNFLX,TOPFLX, &
PRESS,TEMP,RH2O,QO3,CLDFAC, &
EQCMT,NCLDS,KTOP,KBTM, &
!
! BO3RND,AO3RND,T1,T2,T4,EM1V,EM1VW,EM3V, &
BO3RND,AO3RND, &
APCM,BPCM,ATPCM,BTPCM,ACOMB,BCOMB,BETACM, &
ZERO,ONE,H18E3,P0INV,H6P08108,DIFFCTR, &
GINV,H3M4,BETINW,RATH2OMW,GP0INV,P0,P0XZP8, &
P0XZP2,H3M3,H1M3,H1M2,H25E2,B0,B2,B1,B3,HAF, &
TEN,HP1,FOUR,HM1EZ, &
RADCON,QUARTR,TWO, &
HM6666M2,HMP66667,HMP5, HP166666,H41666M2, &
RADCON1,H16E1, H28E1,H44194M2,H1P41819, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!....
DO 280 I=MYIS,MYIE
IR = I + IBEG - 1
FLWUP(IR) = TOPFLX(I) * .001E0
GRNFLX(I)=Q14330*(HSIGMA*TEMP(I,LP1)**4-GRNFLX(I))
!.... GET LW FLUX DOWN AND UP AT GROUND(WATTS/M**2) - GRNFLX=LW DOWN.
FLWDNS(IR)=GRNFLX(I)/(1.43306E-06*1000.E0)
FLWUPS(IR)=HSIGMA*.001E0 * TEMP(I,LP1)**4
280 CONTINUE
!.... CONVERT HEATING RATES TO DEG/SEC
DO 290 K=1,L
DO 290 I=MYIS,MYIE
HLW(I+IBEG-1,K)=HEATRA(I,K)*DAYSEC
290 CONTINUE
300 CONTINUE
IF(ITIMSW .EQ. 0) GO TO 350
!SW
CALL SWR93(FSW,HSW,UF,DF,FSWL,HSWL,UFL,DFL, &
PRESS,COSZEN,TAUDA,RH2O,RRCO2,SSOLAR,QO3, &
NCLDS,KTOP,KBTM,CAMT,RRCL,TTCL, &
ALVB,ALNB,ALVD,ALND,GDFVB,GDFNB,GDFVD,GDFND, &
!
! UCO2,UO3,TUCO2,TUO3,TDO3,TDCO2, &
ABCFF,PWTS, &
H35E1,H1224E3,ONE,ZERO,HAF,H69766E5,HP219, &
HP816,RRAYAV,GINV,CFCO2,CFO3, &
TWO,H235M3,HP26,H129M2,H75826M4,H1036E2, &
H1P082,HMP805,H1386E2,H658M2,H2118M2,H42M2, &
H323M4,HM1EZ,DIFFCTR,O3DIFCTR,FIFTY,RADCON, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte )
!SW
!
!..... GET SW FLUXES IN WATTS/M**2
DO 320 I=MYIS,MYIE
IR = I + IBEG - 1
FSWUP(IR) = UF(I,1) * 1.E-3
FSWDN(IR) = DF(I,1) * 1.E-3
FSWUPS(IR) = UF(I,LP1) * 1.E-3
!C..COUPLE W/M2 DIFF, IF FSWDNS(IR)=DF(I,LP1)*1.#E-3
FSWDNS(IR) = (GDFVB(I)+GDFNB(I)+GDFVD(I)+GDFND(I)) * 1.E-3
!... DOWNWARD SFC FLUX FOR THE SIB PARAMETERATION
!..... VISIBLE AND NEAR IR DIFFUSE
GDFVDR(IR) = GDFVD(I) * 1.E-3
GDFNDR(IR) = GDFND(I) * 1.E-3
!..... VISIBLE AND NEAR IR DIRECT BEAM
GDFVBR(IR) = GDFVB(I) * 1.E-3
GDFNBR(IR) = GDFNB(I) * 1.E-3
320 CONTINUE
!.... CONVERT HEATING RATES TO DEG/SEC
DO 330 K=1,L
DO 330 I=MYIS,MYIE
SWH(I+IBEG-1,K)=HSW(I,K)*DAYSEC
330 CONTINUE
350 CONTINUE
RETURN
1000 FORMAT(1H ,' YOU ARE CALLING GFDL RADIATION CODE FOR',I5,' PTS', &
'AND',I4,' LYRS,WITH KDAPRX,KO3,KCZ,KEMIS,KALB = ',5I2)
END SUBROUTINE RADFS
!-----------------------------------------------------------------------
SUBROUTINE O3CLIM 2
! (XDUO3N,XDO3N2,XDO3N3,XDO3N4,PRGFDL, &
! ids,ide, jds,jde, kds,kde, &
! ims,ime, jms,jme, kms,kme, &
! its,ite, jts,jte, kts,kte )
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
! INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde , &
! ims,ime, jms,jme, kms,kme , &
! its,ite, jts,jte, kts,kte
! ******************************************************************
!$$$ SUBPROGRAM DOCUMENTATION BLOCK
! . . .
! SUBPROGRAM: O3CLIM GENERATE SEASONAL OZONE DISTRIBUTION
! PRGRMMR: GFDL/CAMPANA ORG: W/NP22 DATE: ??-??-??
!
! ABSTRACT:
! O3CLIM COMPUTES THE SEASONAL CLIMATOLOGY OF OZONE USING
! 81-LAYER DATA FROM GFDL.
!
! PROGRAM HISTORY LOG:
! ??-??-?? GFDL/KC - ORIGINATOR
! 96-07-26 BLACK - MODIFIED FOR ETA MODEL
!
! USAGE: CALL O3CLIM FROM SUBROUTINE RADTN
! INPUT ARGUMENT LIST:
! NONE
!
! OUTPUT ARGUMENT LIST:
! NONE
!
! OUTPUT FILES:
! NONE
!
! SUBPROGRAMS CALLED:
!
! UNIQUE:
! NONE
!
! LIBRARY:
! NONE
!
! COMMON BLOCKS: SEASO3
! O3DATA
!
! ATTRIBUTES:
! LANGUAGE: FORTRAN 90
! MACHINE : IBM SP
!$$$
!----------------------------------------------------------------------
! INTEGER :: NL,NLP1,NLGTH,NKK,NK,NKP
INTEGER, PARAMETER :: NL=81,NLP1=NL+1,NLGTH=37*NL,NKK=41,NK=81,NKP=NK+1
!----------------------------------------------------------------------
! INCLUDE "SEASO3.comm"
!---------------------------------------------------------------------
! REAL, INTENT(OUT), DIMENSION(37,NL) :: XDUO3N,XDO3N2,XDO3N3,XDO3N4
! REAL, INTENT(OUT), DIMENSION(NL) :: PRGFDL
! COMMON /SEASO3/
! ...WINTER.... ...SPRING.... ...SUMMER.... ....FALL.....
! & XDUO3N(37,NL), XDO3N2(37,NL), XDO3N3(37,NL), XDO3N4(37,NL)
!
! &,PRGFDL(NL)
!---------------------------------------------------------------------
REAL :: PH1(45),PH2(37),P1(48),P2(33),O3HI1(10,16),O3HI2(10,9) &
,O3LO1(10,16),O3LO2(10,16),O3LO3(10,16),O3LO4(10,16)
!----------------------------------------------------------------------
REAL :: AVG,A1,B1,B2
INTEGER :: K,N,NCASE,IPLACE,KK,NKM,NKMM,KI,KQ,JJ,KEN,I,iindex,jindex
!----------------------------------------------------------------------
REAL :: PSTD(NL),TEMPN(19),O3O3(37,NL,4),O35DEG(37,NL) &
,XRAD1(NLGTH),XRAD2(NLGTH),XRAD3(NLGTH),XRAD4(NLGTH) &
,DDUO3N(19,NL),DUO3N(19,41) &
,RO3(10,41),RO3M(10,40),RO31(10,41),RO32(10,41) &
,O3HI(10,25) &
,RSTD(81),RBAR(NL),RDATA(81) &
,PHALF(NL),P(81),PH(82)
REAL :: PXX(81),PYY(82) ! fix for nesting: gopal's doing
!----------------------------------------------------------------------
! EQUIVALENCE &
! (O3HI1(1,1),O3HI(1,1)),(O3HI2(1,1),O3HI(1,17)) &
! ,(PH1(1),PH(1)),(PH2(1),PH(46)) &
! ,(P1(1),P(1)),(P2(1),P(49))
EQUIVALENCE &
(O3HI1(1,1),O3HI(1,1)),(O3HI2(1,1),O3HI(1,17)) &
,(PH1(1),PYY(1)),(PH2(1),PYY(46)) & ! fix for nesting: gopal's doing
,(P1(1),PXX(1)),(P2(1),PXX(49)) ! fix for nesting: gopal's doing
!----------------------------------------------------------------------
! EQUIVALENCE &
! (XRAD1(1),XDUO3N(1,1),O3O3(1,1,1)) &
! ,(XRAD2(1),XDO3N2(1,1)) &
! ,(XRAD3(1),XDO3N3(1,1)),(XRAD4(1),XDO3N4(1,1),)
EQUIVALENCE &
(XRAD1(1),O3O3(1,1,1)) &
,(XRAD2(1),O3O3(1,1,2)) &
,(XRAD3(1),O3O3(1,1,3)),(XRAD4(1),O3O3(1,1,4))
!----------------------------------------------------------------------
!---------------------------------------------------------------------
DATA PH1/ 0., &
0.1027246E-04, 0.1239831E-04, 0.1491845E-04, 0.1788053E-04, &
0.2135032E-04, 0.2540162E-04, 0.3011718E-04, 0.3558949E-04, &
0.4192172E-04, 0.4922875E-04, 0.5763817E-04, 0.6729146E-04, &
0.7834518E-04, 0.9097232E-04, 0.1053635E-03, 0.1217288E-03, &
0.1402989E-03, 0.1613270E-03, 0.1850904E-03, 0.2119495E-03, &
0.2423836E-03, 0.2768980E-03, 0.3160017E-03, 0.3602623E-03, &
0.4103126E-03, 0.4668569E-03, 0.5306792E-03, 0.6026516E-03, &
0.6839018E-03, 0.7759249E-03, 0.8803303E-03, 0.9987843E-03, &
0.1133178E-02, 0.1285955E-02, 0.1460360E-02, 0.1660001E-02, &
0.1888764E-02, 0.2151165E-02, 0.2452466E-02, 0.2798806E-02, &
0.3197345E-02, 0.3656456E-02, 0.4185934E-02, 0.4797257E-02/
DATA PH2/ &
0.5503893E-02, 0.6321654E-02, 0.7269144E-02, 0.8368272E-02, &
0.9644873E-02, 0.1112946E-01, 0.1285810E-01, 0.1487354E-01, &
0.1722643E-01, 0.1997696E-01, 0.2319670E-01, 0.2697093E-01, &
0.3140135E-01, 0.3660952E-01, 0.4274090E-01, 0.4996992E-01, &
0.5848471E-01, 0.6847525E-01, 0.8017242E-01, 0.9386772E-01, &
0.1099026E+00, 0.1286765E+00, 0.1506574E+00, 0.1763932E+00, &
0.2065253E+00, 0.2415209E+00, 0.2814823E+00, 0.3266369E+00, &
0.3774861E+00, 0.4345638E+00, 0.4984375E+00, 0.5697097E+00, &
0.6490189E+00, 0.7370409E+00, 0.8344896E+00, 0.9421190E+00, &
0.1000000E+01/
DATA P1/ &
0.9300000E-05, 0.1129521E-04, 0.1360915E-04, 0.1635370E-04, &
0.1954990E-04, 0.2331653E-04, 0.2767314E-04, 0.3277707E-04, &
0.3864321E-04, 0.4547839E-04, 0.5328839E-04, 0.6234301E-04, &
0.7263268E-04, 0.8450696E-04, 0.9793231E-04, 0.1133587E-03, &
0.1307170E-03, 0.1505832E-03, 0.1728373E-03, 0.1982122E-03, &
0.2266389E-03, 0.2592220E-03, 0.2957792E-03, 0.3376068E-03, &
0.3844381E-03, 0.4379281E-03, 0.4976965E-03, 0.5658476E-03, &
0.6418494E-03, 0.7287094E-03, 0.8261995E-03, 0.9380076E-03, &
0.1063498E-02, 0.1207423E-02, 0.1369594E-02, 0.1557141E-02, &
0.1769657E-02, 0.2015887E-02, 0.2295520E-02, 0.2620143E-02, &
0.2989651E-02, 0.3419469E-02, 0.3909867E-02, 0.4481491E-02, &
0.5135272E-02, 0.5898971E-02, 0.6774619E-02, 0.7799763E-02/
DATA P2/ &
0.8978218E-02, 0.1036103E-01, 0.1195488E-01, 0.1382957E-01, &
0.1599631E-01, 0.1855114E-01, 0.2151235E-01, 0.2501293E-01, &
0.2908220E-01, 0.3390544E-01, 0.3952926E-01, 0.4621349E-01, &
0.5403168E-01, 0.6330472E-01, 0.7406807E-01, 0.8677983E-01, &
0.1015345E+00, 0.1189603E+00, 0.1391863E+00, 0.1630739E+00, &
0.1908004E+00, 0.2235461E+00, 0.2609410E+00, 0.3036404E+00, &
0.3513750E+00, 0.4055375E+00, 0.4656677E+00, 0.5335132E+00, &
0.6083618E+00, 0.6923932E+00, 0.7845676E+00, 0.8875882E+00, &
0.1000000E+01/
DATA O3HI1/ &
.55,.50,.45,.45,.40,.35,.35,.30,.30,.30, &
.55,.51,.46,.47,.42,.38,.37,.36,.35,.35, &
.55,.53,.48,.49,.44,.42,.41,.40,.38,.38, &
.60,.55,.52,.52,.50,.47,.46,.44,.42,.41, &
.65,.60,.55,.56,.53,.52,.50,.48,.45,.45, &
.75,.65,.60,.60,.55,.55,.55,.50,.48,.47, &
.80,.75,.75,.75,.70,.70,.65,.63,.60,.60, &
.90,.85,.85,.80,.80,.75,.75,.74,.72,.71, &
1.10,1.05,1.00,.90,.90,.90,.85,.83,.80,.80, &
1.40,1.30,1.25,1.25,1.25,1.20,1.15,1.10,1.05,1.00, &
1.7,1.7,1.6,1.6,1.6,1.6,1.6,1.6,1.5,1.5, &
2.1,2.0,1.9,1.9,1.9,1.8,1.8,1.8,1.7,1.7, &
2.4,2.3,2.2,2.2,2.2,2.1,2.1,2.1,2.0,2.0, &
2.7,2.5,2.5,2.5,2.5,2.5,2.4,2.4,2.3,2.3, &
2.9,2.8,2.7,2.7,2.7,2.7,2.7,2.7,2.6,2.6, &
3.1,3.1,3.0,3.0,3.0,3.0,3.0,3.0,2.9,2.8/
DATA O3HI2/ &
3.3,3.4,3.4,3.6,3.7,3.9,4.0,4.1,4.0,3.8, &
3.6,3.8,3.9,4.2,4.7,5.3,5.6,5.7,5.5,5.2, &
4.1,4.3,4.7,5.2,6.0,6.7,7.0,6.8,6.4,6.2, &
5.4,5.7,6.0,6.6,7.3,8.0,8.4,7.7,7.1,6.7, &
6.7,6.8,7.0,7.6,8.3,10.0,9.6,8.2,7.5,7.2, &
9.2,9.3,9.4,9.6,10.3,10.6,10.0,8.5,7.7,7.3, &
12.6,12.1,12.0,12.1,11.7,11.0,10.0,8.6,7.8,7.4, &
14.2,13.5,13.1,12.8,11.9,10.9,9.8,8.5,7.8,7.5, &
14.3,14.0,13.4,12.7,11.6,10.6,9.3,8.4,7.6,7.3/
DATA O3LO1/ &
14.9,14.2,13.3,12.5,11.2,10.3,9.5,8.6,7.5,7.4, &
14.5,14.1,13.0,11.8,10.5,9.8,9.2,7.9,7.4,7.4, &
11.8,11.5,10.9,10.5,9.9,9.6,8.9,7.5,7.2,7.2, &
7.3,7.7,7.8,8.4,8.4,8.5,7.9,7.4,7.1,7.1, &
4.1,4.4,5.3,6.6,6.9,7.5,7.4,7.2,7.0,6.9, &
1.8,1.9,2.5,3.3,4.5,5.8,6.3,6.3,6.4,6.1, &
0.4,0.5,0.8,1.2,2.7,3.6,4.6,4.7,5.0,5.2, &
.10,.15,.20,.50,1.4,2.1,3.0,3.2,3.5,3.9, &
.07,.10,.12,.30,1.0,1.4,1.8,1.9,2.3,2.5, &
.06,.08,.10,.15,.60,.80,1.4,1.5,1.5,1.6, &
.05,.05,.06,.09,.20,.40,.70,.80,.90,.90, &
.05,.05,.06,.08,.10,.13,.20,.25,.30,.40, &
.05,.05,.05,.06,.07,.07,.08,.09,.10,.13, &
.05,.05,.05,.05,.06,.06,.06,.06,.07,.07, &
.05,.05,.05,.05,.05,.05,.05,.06,.06,.06, &
.04,.04,.04,.04,.04,.04,.04,.05,.05,.05/
DATA O3LO2/ &
14.8,14.2,13.8,12.2,11.0,9.8,8.5,7.8,7.4,6.9, &
13.2,13.0,12.5,11.3,10.4,9.0,7.8,7.5,7.0,6.6, &
10.6,10.6,10.7,10.1,9.4,8.6,7.5,7.0,6.5,6.1, &
7.0,7.3,7.5,7.5,7.5,7.3,6.7,6.4,6.0,5.8, &
3.8,4.0,4.7,5.0,5.2,5.9,5.8,5.6,5.5,5.5, &
1.4,1.6,2.4,3.0,3.7,4.1,4.6,4.8,5.1,5.0, &
.40,.50,.90,1.2,2.0,2.7,3.2,3.6,4.3,4.1, &
.07,.10,.20,.30,.80,1.4,2.1,2.4,2.7,3.0, &
.06,.07,.09,.15,.30,.70,1.2,1.4,1.6,2.0, &
.05,.05,.06,.12,.15,.30,.60,.70,.80,.80, &
.04,.05,.06,.08,.09,.15,.30,.40,.40,.40, &
.04,.04,.05,.055,.06,.09,.12,.13,.15,.15, &
.03,.03,.045,.052,.055,.06,.07,.07,.06,.07, &
.03,.03,.04,.051,.052,.052,.06,.06,.05,.05, &
.02,.02,.03,.05,.05,.05,.04,.04,.04,.04, &
.02,.02,.02,.04,.04,.04,.03,.03,.03,.03/
DATA O3LO3/ &
14.5,14.0,13.5,11.3,11.0,10.0,9.0,8.3,7.5,7.3, &
13.5,13.2,12.5,11.1,10.4,9.7,8.2,7.8,7.4,6.8, &
10.8,10.9,11.0,10.4,10.0,9.6,7.9,7.5,7.0,6.7, &
7.3,7.5,7.8,8.5,9.0,8.5,7.7,7.4,6.9,6.5, &
4.1,4.5,5.3,6.2,7.3,7.7,7.3,7.0,6.6,6.4, &
1.8,2.0,2.2,3.8,4.3,5.6,6.2,6.2,6.4,6.2, &
.30,.50,.60,1.5,2.8,3.7,4.5,4.7,5.5,5.6, &
.09,.10,.15,.60,1.2,2.1,3.0,3.5,4.0,4.3, &
.06,.08,.10,.30,.60,1.1,1.9,2.2,2.9,3.0, &
.04,.05,.06,.15,.45,.60,1.1,1.3,1.6,1.8, &
.04,.04,.04,.08,.20,.30,.55,.60,.75,.90, &
.04,.04,.04,.05,.06,.10,.12,.15,.20,.25, &
.04,.04,.03,.04,.05,.06,.07,.07,.07,.08, &
.03,.03,.04,.05,.05,.05,.05,.05,.05,.05, &
.03,.03,.03,.04,.04,.04,.05,.05,.04,.04, &
.02,.02,.02,.04,.04,.04,.04,.04,.03,.03/
DATA O3LO4/ &
14.2,13.8,13.2,12.5,11.7,10.5,8.6,7.8,7.5,6.6, &
12.5,12.4,12.2,11.7,10.8,9.8,7.8,7.2,6.5,6.1, &
10.6,10.5,10.4,10.1,9.6,9.0,7.1,6.8,6.1,5.9, &
7.0,7.4,7.9,7.8,7.6,7.3,6.2,6.1,5.8,5.6, &
4.2,4.6,5.1,5.6,5.9,5.9,5.9,5.8,5.6,5.3, &
2.1,2.3,2.6,2.9,3.5,4.3,4.8,4.9,5.1,5.1, &
0.7,0.8,1.0,1.5,2.0,2.8,3.5,3.6,3.7,4.0, &
.15,.20,.40,.50,.60,1.4,2.1,2.2,2.3,2.5, &
.08,.10,.15,.25,.30,.90,1.2,1.3,1.4,1.6, &
.07,.08,.10,.14,.20,.50,.70,.90,.90,.80, &
.05,.06,.08,.12,.14,.20,.35,.40,.60,.50, &
.05,.05,.08,.09,.09,.09,.11,.12,.15,.18, &
.04,.05,.06,.07,.07,.08,.08,.08,.08,.08, &
.04,.04,.05,.07,.07,.07,.07,.07,.06,.05, &
.02,.02,.04,.05,.05,.05,.05,.05,.04,.04, &
.02,.02,.03,.04,.04,.04,.04,.04,.03,.03/
!----------------------------------------------------------------------
!***
!*** COMPUTE DETAILED O3 PROFILE FROM THE ORIGINAL GFDL PRESSURES
!*** WHERE OUTPUT FROM O3INT (PSTD) IS TOP DOWN IN MB*1.E3
!*** AND PSFC=1013.25 MB ......K.A.C. DEC94
!***
DO K=1,NK
PH(K)=PYY(K)*1013250. ! fix for nesting: gopal's doing
P(K)=PXX(K)*1013250.
ENDDO
!
PH(NKP)=PYY(NKP)*1013250. ! fixed; dusan
!
DO K=1,NL
PSTD(K)=P(K)
ENDDO
!
DO K=1,25
DO N=1,10
RO31(N,K)=O3HI(N,K)
RO32(N,K)=O3HI(N,K)
ENDDO
ENDDO
!----------------------------------------------------------------------
DO 100 NCASE=1,4
!
!*** NCASE=1: SPRING (IN N.H.)
!*** NCASE=2: FALL (IN N.H.)
!*** NCASE=3: WINTER (IN N.H.)
!*** NCASE=4: SUMMER (IN N.H.)
!
IPLACE=2
IF(NCASE.EQ.2)IPLACE=4
IF(NCASE.EQ.3)IPLACE=1
IF(NCASE.EQ.4)IPLACE=3
!
IF(NCASE.EQ.1.OR.NCASE.EQ.2)THEN
DO K=26,41
DO N=1,10
RO31(N,K)=O3LO1(N,K-25)
RO32(N,K)=O3LO2(N,K-25)
ENDDO
ENDDO
ENDIF
!
IF(NCASE.EQ.3.OR.NCASE.EQ.4)THEN
DO K=26,41
DO N=1,10
RO31(N,K)=O3LO3(N,K-25)
RO32(N,K)=O3LO4(N,K-25)
ENDDO
ENDDO
ENDIF
!
DO 25 KK=1,NKK
DO N=1,10
DUO3N(N,KK)=RO31(11-N,KK)
DUO3N(N+9,KK)=RO32(N,KK)
ENDDO
DUO3N(10,KK)=0.5*(RO31(1,KK)+RO32(1,KK))
25 CONTINUE
!
!***FOR NCASE=2 OR NCASE=4,REVERSE LATITUDE ARRANGEMENT OF CORR. SEASON
!
IF(NCASE.EQ.2.OR.NCASE.EQ.4)THEN
DO 50 KK=1,NKK
DO N=1,19
TEMPN(N)=DUO3N(20-N,KK)
ENDDO
DO N=1,19
DUO3N(N,KK)=TEMPN(N)
ENDDO
50 CONTINUE
ENDIF
!
!*** DUO3N NOW IS O3 PROFILE FOR APPROPRIATE SEASON AT STD PRESSURE
!*** LEVELS
!
!*** BEGIN LATITUDE (10 DEG) LOOP
!
DO 75 N=1,19
!
DO KK=1,NKK
RSTD(KK)=DUO3N(N,KK)
ENDDO
!
NKM=NK-1
NKMM=NK-3
!***
!*** BESSELS HALF-POINT INTERPOLATION FORMULA
!***
DO K=4,NKMM,2
KI=K/2
RDATA(K)=0.5*(RSTD(KI)+RSTD(KI+1))-(RSTD(KI+2)-RSTD(KI+1) &
-RSTD(KI)+RSTD(KI-1))/16.
ENDDO
!
RDATA(2)=0.5*(RSTD(2)+RSTD(1))
RDATA(NKM)=0.5*(RSTD(NKK)+RSTD(NKK-1))
!
!*** PUT UNCHANGED DATA INTO NEW ARRAY
!
DO K=1,NK,2
KQ=(K+1)/2
RDATA(K)=RSTD(KQ)
ENDDO
!
DO KK=1,NL
DDUO3N(N,KK)=RDATA(KK)*.01
ENDDO
!
75 CONTINUE
!
!*** END OF LATITUDE LOOP
!
!----------------------------------------------------------------------
!***
!*** CREATE 5 DEG OZONE QUANTITIES BY LINEAR INTERPOLATION OF
!*** 10 DEG VALUES
!***
DO 90 KK=1,NL
!
DO N=1,19
O35DEG(2*N-1,KK)=DDUO3N(N,KK)
ENDDO
!
DO N=1,18
O35DEG(2*N,KK)=0.5*(DDUO3N(N,KK)+DDUO3N(N+1,KK))
ENDDO
!
90 CONTINUE
!
DO JJ=1,37
DO KEN=1,NL
O3O3(JJ,KEN,IPLACE)=O35DEG(JJ,KEN)
ENDDO
ENDDO
!
100 CONTINUE
!----------------------------------------------------------------------
!*** END OF LOOP OVER CASES
!----------------------------------------------------------------------
!***
!*** AVERAGE CLIMATOLOGICAL VALUS OF O3 FROM 5 DEG LAT MEANS, SO THAT
!*** TIME AND SPACE INTERPOLATION WILL WORK (SEE SUBR OZON2D)
!***
DO I=1,NLGTH
AVG=0.25*(XRAD1(I)+XRAD2(I)+XRAD3(I)+XRAD4(I))
A1=0.5*(XRAD2(I)-XRAD4(I))
B1=0.5*(XRAD1(I)-XRAD3(I))
B2=0.25*((XRAD1(I)+XRAD3(I))-(XRAD2(I)+XRAD4(I)))
! XRAD1(I)=AVG
! XRAD2(I)=A1
! XRAD3(I)=B1
! XRAD4(I)=B2
iindex = 1+mod((I-1),37)
jindex = 1+(I-1)/37
XDUO3N(iindex,jindex)=AVG
XDO3N2(iindex,jindex)=A1
XDO3N3(iindex,jindex)=B1
XDO3N4(iindex,jindex)=B2
ENDDO
!***
!*** CONVERT GFDL PRESSURE (MICROBARS) TO PA
!***
DO N=1,NL
PRGFDL(N)=PSTD(N)*1.E-1
ENDDO
!
END SUBROUTINE O3CLIM
!---------------------------------------------------------------------
SUBROUTINE TABLE 2
! (TABLE1,TABLE2,TABLE3,EM1,EM1WDE,EM3, &
! SOURCE,DSRCE )
!---------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
!INTEGER, PARAMETER :: NBLY=15
INTEGER, PARAMETER :: NB=12
INTEGER, PARAMETER :: NBLX=47
INTEGER , PARAMETER:: NBLW = 163
REAL,PARAMETER :: AMOLWT=28.9644
REAL,PARAMETER :: CSUBP=1.00484E7
REAL,PARAMETER :: DIFFCTR=1.66
REAL,PARAMETER :: G=980.665
REAL,PARAMETER :: GINV=1./G
REAL,PARAMETER :: GRAVDR=980.0
REAL,PARAMETER :: O3DIFCTR=1.90
REAL,PARAMETER :: P0=1013250.
REAL,PARAMETER :: P0INV=1./P0
REAL,PARAMETER :: GP0INV=GINV*P0INV
REAL,PARAMETER :: P0XZP2=202649.902
REAL,PARAMETER :: P0XZP8=810600.098
REAL,PARAMETER :: P0X2=2.*1013250.
REAL,PARAMETER :: RADCON=8.427
REAL,PARAMETER :: RADCON1=1./8.427
REAL,PARAMETER :: RATCO2MW=1.519449738
REAL,PARAMETER :: RATH2OMW=.622
REAL,PARAMETER :: RGAS=8.3142E7
REAL,PARAMETER :: RGASSP=8.31432E7
REAL,PARAMETER :: SECPDA=8.64E4
!
!******THE FOLLOWING ARE MATHEMATICAL CONSTANTS*******
! ARRANGED IN DECREASING ORDER
REAL,PARAMETER :: HUNDRED=100.
REAL,PARAMETER :: HNINETY=90.
REAL,PARAMETER :: HNINE=9.0
REAL,PARAMETER :: SIXTY=60.
REAL,PARAMETER :: FIFTY=50.
REAL,PARAMETER :: TEN=10.
REAL,PARAMETER :: EIGHT=8.
REAL,PARAMETER :: FIVE=5.
REAL,PARAMETER :: FOUR=4.
REAL,PARAMETER :: THREE=3.
REAL,PARAMETER :: TWO=2.
REAL,PARAMETER :: ONE=1.
REAL,PARAMETER :: HAF=0.5
REAL,PARAMETER :: QUARTR=0.25
REAL,PARAMETER :: ZERO=0.
!
!******FOLLOWING ARE POSITIVE FLOATING POINT CONSTANTS(H'S)
! ARRANGED IN DECREASING ORDER
REAL,PARAMETER :: H83E26=8.3E26
REAL,PARAMETER :: H71E26=7.1E26
REAL,PARAMETER :: H1E15=1.E15
REAL,PARAMETER :: H1E13=1.E13
REAL,PARAMETER :: H1E11=1.E11
REAL,PARAMETER :: H1E8=1.E8
REAL,PARAMETER :: H2E6=2.0E6
REAL,PARAMETER :: H1E6=1.0E6
REAL,PARAMETER :: H69766E5=6.97667E5
REAL,PARAMETER :: H4E5=4.E5
REAL,PARAMETER :: H165E5=1.65E5
REAL,PARAMETER :: H5725E4=57250.
REAL,PARAMETER :: H488E4=48800.
REAL,PARAMETER :: H1E4=1.E4
REAL,PARAMETER :: H24E3=2400.
REAL,PARAMETER :: H20788E3=2078.8
REAL,PARAMETER :: H2075E3=2075.
REAL,PARAMETER :: H18E3=1800.
REAL,PARAMETER :: H1224E3=1224.
REAL,PARAMETER :: H67390E2=673.9057
REAL,PARAMETER :: H5E2=500.
REAL,PARAMETER :: H3082E2=308.2
REAL,PARAMETER :: H3E2=300.
REAL,PARAMETER :: H2945E2=294.5
REAL,PARAMETER :: H29316E2=293.16
REAL,PARAMETER :: H26E2=260.0
REAL,PARAMETER :: H25E2=250.
REAL,PARAMETER :: H23E2=230.
REAL,PARAMETER :: H2E2=200.0
REAL,PARAMETER :: H15E2=150.
REAL,PARAMETER :: H1386E2=138.6
REAL,PARAMETER :: H1036E2=103.6
REAL,PARAMETER :: H8121E1=81.21
REAL,PARAMETER :: H35E1=35.
REAL,PARAMETER :: H3116E1=31.16
REAL,PARAMETER :: H28E1=28.
REAL,PARAMETER :: H181E1=18.1
REAL,PARAMETER :: H18E1=18.
REAL,PARAMETER :: H161E1=16.1
REAL,PARAMETER :: H16E1=16.
REAL,PARAMETER :: H1226E1=12.26
REAL,PARAMETER :: H9P94=9.94
REAL,PARAMETER :: H6P08108=6.081081081
REAL,PARAMETER :: H3P6=3.6
REAL,PARAMETER :: H3P5=3.5
REAL,PARAMETER :: H2P9=2.9
REAL,PARAMETER :: H2P8=2.8
REAL,PARAMETER :: H2P5=2.5
REAL,PARAMETER :: H1P8=1.8
REAL,PARAMETER :: H1P4387=1.4387
REAL,PARAMETER :: H1P41819=1.418191
REAL,PARAMETER :: H1P4=1.4
REAL,PARAMETER :: H1P25892=1.258925411
REAL,PARAMETER :: H1P082=1.082
REAL,PARAMETER :: HP816=0.816
REAL,PARAMETER :: HP805=0.805
REAL,PARAMETER :: HP8=0.8
REAL,PARAMETER :: HP60241=0.60241
REAL,PARAMETER :: HP602409=0.60240964
REAL,PARAMETER :: HP6=0.6
REAL,PARAMETER :: HP526315=0.52631579
REAL,PARAMETER :: HP518=0.518
REAL,PARAMETER :: HP5048=0.5048
REAL,PARAMETER :: HP3795=0.3795
REAL,PARAMETER :: HP369=0.369
REAL,PARAMETER :: HP26=0.26
REAL,PARAMETER :: HP228=0.228
REAL,PARAMETER :: HP219=0.219
REAL,PARAMETER :: HP166666=.166666
REAL,PARAMETER :: HP144=0.144
REAL,PARAMETER :: HP118666=0.118666192
REAL,PARAMETER :: HP1=0.1
! (NEGATIVE EXPONENTIALS BEGIN HERE)
REAL,PARAMETER :: H658M2=0.0658
REAL,PARAMETER :: H625M2=0.0625
REAL,PARAMETER :: H44871M2=4.4871E-2
REAL,PARAMETER :: H44194M2=.044194
REAL,PARAMETER :: H42M2=0.042
REAL,PARAMETER :: H41666M2=0.0416666
REAL,PARAMETER :: H28571M2=.02857142857
REAL,PARAMETER :: H2118M2=0.02118
REAL,PARAMETER :: H129M2=0.0129
REAL,PARAMETER :: H1M2=.01
REAL,PARAMETER :: H559M3=5.59E-3
REAL,PARAMETER :: H3M3=0.003
REAL,PARAMETER :: H235M3=2.35E-3
REAL,PARAMETER :: H1M3=1.0E-3
REAL,PARAMETER :: H987M4=9.87E-4
REAL,PARAMETER :: H323M4=0.000323
REAL,PARAMETER :: H3M4=0.0003
REAL,PARAMETER :: H285M4=2.85E-4
REAL,PARAMETER :: H1M4=0.0001
REAL,PARAMETER :: H75826M4=7.58265E-4
REAL,PARAMETER :: H6938M5=6.938E-5
REAL,PARAMETER :: H394M5=3.94E-5
REAL,PARAMETER :: H37412M5=3.7412E-5
REAL,PARAMETER :: H15M5=1.5E-5
REAL,PARAMETER :: H1439M5=1.439E-5
REAL,PARAMETER :: H128M5=1.28E-5
REAL,PARAMETER :: H102M5=1.02E-5
REAL,PARAMETER :: H1M5=1.0E-5
REAL,PARAMETER :: H7M6=7.E-6
REAL,PARAMETER :: H4999M6=4.999E-6
REAL,PARAMETER :: H451M6=4.51E-6
REAL,PARAMETER :: H25452M6=2.5452E-6
REAL,PARAMETER :: H1M6=1.E-6
REAL,PARAMETER :: H391M7=3.91E-7
REAL,PARAMETER :: H1174M7=1.174E-7
REAL,PARAMETER :: H8725M8=8.725E-8
REAL,PARAMETER :: H327M8=3.27E-8
REAL,PARAMETER :: H257M8=2.57E-8
REAL,PARAMETER :: H1M8=1.0E-8
REAL,PARAMETER :: H23M10=2.3E-10
REAL,PARAMETER :: H14M10=1.4E-10
REAL,PARAMETER :: H11M10=1.1E-10
REAL,PARAMETER :: H1M10=1.E-10
REAL,PARAMETER :: H83M11=8.3E-11
REAL,PARAMETER :: H82M11=8.2E-11
REAL,PARAMETER :: H8M11=8.E-11
REAL,PARAMETER :: H77M11=7.7E-11
REAL,PARAMETER :: H72M11=7.2E-11
REAL,PARAMETER :: H53M11=5.3E-11
REAL,PARAMETER :: H48M11=4.8E-11
REAL,PARAMETER :: H44M11=4.4E-11
REAL,PARAMETER :: H42M11=4.2E-11
REAL,PARAMETER :: H37M11=3.7E-11
REAL,PARAMETER :: H35M11=3.5E-11
REAL,PARAMETER :: H32M11=3.2E-11
REAL,PARAMETER :: H3M11=3.0E-11
REAL,PARAMETER :: H28M11=2.8E-11
REAL,PARAMETER :: H24M11=2.4E-11
REAL,PARAMETER :: H23M11=2.3E-11
REAL,PARAMETER :: H2M11=2.E-11
REAL,PARAMETER :: H18M11=1.8E-11
REAL,PARAMETER :: H15M11=1.5E-11
REAL,PARAMETER :: H14M11=1.4E-11
REAL,PARAMETER :: H114M11=1.14E-11
REAL,PARAMETER :: H11M11=1.1E-11
REAL,PARAMETER :: H1M11=1.E-11
REAL,PARAMETER :: H96M12=9.6E-12
REAL,PARAMETER :: H93M12=9.3E-12
REAL,PARAMETER :: H77M12=7.7E-12
REAL,PARAMETER :: H74M12=7.4E-12
REAL,PARAMETER :: H65M12=6.5E-12
REAL,PARAMETER :: H62M12=6.2E-12
REAL,PARAMETER :: H6M12=6.E-12
REAL,PARAMETER :: H45M12=4.5E-12
REAL,PARAMETER :: H44M12=4.4E-12
REAL,PARAMETER :: H4M12=4.E-12
REAL,PARAMETER :: H38M12=3.8E-12
REAL,PARAMETER :: H37M12=3.7E-12
REAL,PARAMETER :: H3M12=3.E-12
REAL,PARAMETER :: H29M12=2.9E-12
REAL,PARAMETER :: H28M12=2.8E-12
REAL,PARAMETER :: H24M12=2.4E-12
REAL,PARAMETER :: H21M12=2.1E-12
REAL,PARAMETER :: H16M12=1.6E-12
REAL,PARAMETER :: H14M12=1.4E-12
REAL,PARAMETER :: H12M12=1.2E-12
REAL,PARAMETER :: H8M13=8.E-13
REAL,PARAMETER :: H46M13=4.6E-13
REAL,PARAMETER :: H36M13=3.6E-13
REAL,PARAMETER :: H135M13=1.35E-13
REAL,PARAMETER :: H12M13=1.2E-13
REAL,PARAMETER :: H1M13=1.E-13
REAL,PARAMETER :: H3M14=3.E-14
REAL,PARAMETER :: H15M14=1.5E-14
REAL,PARAMETER :: H14M14=1.4E-14
!
!******FOLLOWING ARE NEGATIVE FLOATING POINT CONSTANTS (HM'S)
! ARRANGED IN DESCENDING ORDER
REAL,PARAMETER :: HM2M2=-.02
REAL,PARAMETER :: HM6666M2=-.066667
REAL,PARAMETER :: HMP5=-0.5
REAL,PARAMETER :: HMP575=-0.575
REAL,PARAMETER :: HMP66667=-.66667
REAL,PARAMETER :: HMP805=-0.805
REAL,PARAMETER :: HM1EZ=-1.
REAL,PARAMETER :: HM13EZ=-1.3
REAL,PARAMETER :: HM19EZ=-1.9
REAL,PARAMETER :: HM1E1=-10.
REAL,PARAMETER :: HM1597E1=-15.97469413
REAL,PARAMETER :: HM161E1=-16.1
REAL,PARAMETER :: HM1797E1=-17.97469413
REAL,PARAMETER :: HM181E1=-18.1
REAL,PARAMETER :: HM8E1=-80.
REAL,PARAMETER :: HM1E2=-100.
!
REAL,PARAMETER :: H1M16=1.0E-16
REAL,PARAMETER :: H1M20=1.E-20
REAL,PARAMETER :: HP98=0.98
REAL,PARAMETER :: Q19001=19.001
REAL,PARAMETER :: DAYSEC=1.1574E-5
REAL,PARAMETER :: HSIGMA=5.673E-5
REAL,PARAMETER :: TWENTY=20.0
REAL,PARAMETER :: HP537=0.537
REAL,PARAMETER :: HP2=0.2
REAL,PARAMETER :: RCO2=3.3E-4
REAL,PARAMETER :: Q14330=1.43306E-6
REAL,PARAMETER :: H3M6=3.0E-6
REAL,PARAMETER :: PI=3.1415927
REAL,PARAMETER :: DEGRAD=180.0/PI
REAL,PARAMETER :: H74E1=74.0
REAL,PARAMETER :: H15E1=15.0
REAL, PARAMETER:: B0 = -.51926410E-4
REAL, PARAMETER:: B1 = -.18113332E-3
REAL, PARAMETER:: B2 = -.10680132E-5
REAL, PARAMETER:: B3 = -.67303519E-7
REAL, PARAMETER:: AWIDE = 0.309801E+01
REAL, PARAMETER:: BWIDE = 0.495357E-01
REAL, PARAMETER:: BETAWD = 0.347839E+02
REAL, PARAMETER:: BETINW = 0.766811E+01
! REAL, INTENT(OUT) :: EM1(28,180),EM1WDE(28,180),TABLE1(28,180), &
! TABLE2(28,180),TABLE3(28,180),EM3(28,180), &
! SOURCE(28,NBLY), DSRCE(28,NBLY)
!
REAL :: ARNDM(NBLW),BRNDM(NBLW),BETAD(NBLW)
REAL :: BANDLO(NBLW),BANDHI(NBLW)
INTEGER :: IBAND(40)
REAL :: BANDL1(64),BANDL2(64),BANDL3(35)
REAL :: BANDH1(64),BANDH2(64),BANDH3(35)
! REAL :: AB15WD,SKO2D,SKC1R,SKO3R
! REAL :: AWIDE,BWIDE,BETAWD,BETINW
! DATA AWIDE / 0.309801E+01/
! DATA BWIDE / 0.495357E-01/
! DATA BETAWD / 0.347839E+02/
! DATA BETINW / 0.766811E+01/
!
!% #NPADL = #PAGE*#NPAGE - 4*28*180 - 2*181 - 7*28 - 180 ;
!% #NPADL = #NPADL - 11*28 - 2*180 - 2*30 ;
! PARAMETER (NPADL = #NPADL - 28*NBLX - 2*28*NBLW - 7*NBLW)
REAL :: &
SUM(28,180),PERTSM(28,180),SUM3(28,180), &
SUMWDE(28,180),SRCWD(28,NBLX),SRC1NB(28,NBLW), &
DBDTNB(28,NBLW)
REAL :: &
ZMASS(181),ZROOT(181),SC(28),DSC(28),XTEMV(28), &
TFOUR(28),FORTCU(28),X(28),X1(28),X2(180),SRCS(28), &
SUM4(28),SUM6(28),SUM7(28),SUM8(28),SUM4WD(28), &
R1T(28),R2(28),S2(28),T3(28),R1WD(28)
REAL :: EXPO(180),FAC(180)
REAL :: CNUSB(30),DNUSB(30)
REAL :: ALFANB(NBLW),AROTNB(NBLW)
REAL :: ANB(NBLW),BNB(NBLW),CENTNB(NBLW),DELNB(NBLW), &
BETANB(NBLW)
REAL :: AB15(2)
REAL :: ARNDM1(64),ARNDM2(64),ARNDM3(35)
REAL :: BRNDM1(64),BRNDM2(64),BRNDM3(35)
REAL :: BETAD1(64),BETAD2(64),BETAD3(35)
EQUIVALENCE (ARNDM1(1),ARNDM(1)),(ARNDM2(1),ARNDM(65)), &
(ARNDM3(1),ARNDM(129))
EQUIVALENCE (BRNDM1(1),BRNDM(1)),(BRNDM2(1),BRNDM(65)), &
(BRNDM3(1),BRNDM(129))
EQUIVALENCE (BETAD1(1),BETAD(1)),(BETAD2(1),BETAD(65)), &
(BETAD3(1),BETAD(129))
!---------------------------------------------------------------
REAL :: CENT,DEL,BDLO,BDHI,C1,ANU,tmp
INTEGER :: N,I,ICNT,I1,I2E,I2
INTEGER :: J,JP,NSUBDS,NSB,IA
!---------------------------------------------------------------
DATA IBAND / &
2, 1, 2, 2, 1, 2, 1, 3, 2, 2, &
3, 2, 2, 4, 2, 4, 2, 3, 3, 2, &
4, 3, 4, 3, 7, 5, 6, 7, 6, 5, &
7, 6, 7, 8, 6, 6, 8, 8, 8, 8/
DATA BANDL1 / &
0.000000E+00, 0.100000E+02, 0.200000E+02, 0.300000E+02, &
0.400000E+02, 0.500000E+02, 0.600000E+02, 0.700000E+02, &
0.800000E+02, 0.900000E+02, 0.100000E+03, 0.110000E+03, &
0.120000E+03, 0.130000E+03, 0.140000E+03, 0.150000E+03, &
0.160000E+03, 0.170000E+03, 0.180000E+03, 0.190000E+03, &
0.200000E+03, 0.210000E+03, 0.220000E+03, 0.230000E+03, &
0.240000E+03, 0.250000E+03, 0.260000E+03, 0.270000E+03, &
0.280000E+03, 0.290000E+03, 0.300000E+03, 0.310000E+03, &
0.320000E+03, 0.330000E+03, 0.340000E+03, 0.350000E+03, &
0.360000E+03, 0.370000E+03, 0.380000E+03, 0.390000E+03, &
0.400000E+03, 0.410000E+03, 0.420000E+03, 0.430000E+03, &
0.440000E+03, 0.450000E+03, 0.460000E+03, 0.470000E+03, &
0.480000E+03, 0.490000E+03, 0.500000E+03, 0.510000E+03, &
0.520000E+03, 0.530000E+03, 0.540000E+03, 0.550000E+03, &
0.560000E+03, 0.670000E+03, 0.800000E+03, 0.900000E+03, &
0.990000E+03, 0.107000E+04, 0.120000E+04, 0.121000E+04/
DATA BANDL2 / &
0.122000E+04, 0.123000E+04, 0.124000E+04, 0.125000E+04, &
0.126000E+04, 0.127000E+04, 0.128000E+04, 0.129000E+04, &
0.130000E+04, 0.131000E+04, 0.132000E+04, 0.133000E+04, &
0.134000E+04, 0.135000E+04, 0.136000E+04, 0.137000E+04, &
0.138000E+04, 0.139000E+04, 0.140000E+04, 0.141000E+04, &
0.142000E+04, 0.143000E+04, 0.144000E+04, 0.145000E+04, &
0.146000E+04, 0.147000E+04, 0.148000E+04, 0.149000E+04, &
0.150000E+04, 0.151000E+04, 0.152000E+04, 0.153000E+04, &
0.154000E+04, 0.155000E+04, 0.156000E+04, 0.157000E+04, &
0.158000E+04, 0.159000E+04, 0.160000E+04, 0.161000E+04, &
0.162000E+04, 0.163000E+04, 0.164000E+04, 0.165000E+04, &
0.166000E+04, 0.167000E+04, 0.168000E+04, 0.169000E+04, &
0.170000E+04, 0.171000E+04, 0.172000E+04, 0.173000E+04, &
0.174000E+04, 0.175000E+04, 0.176000E+04, 0.177000E+04, &
0.178000E+04, 0.179000E+04, 0.180000E+04, 0.181000E+04, &
0.182000E+04, 0.183000E+04, 0.184000E+04, 0.185000E+04/
DATA BANDL3 / &
0.186000E+04, 0.187000E+04, 0.188000E+04, 0.189000E+04, &
0.190000E+04, 0.191000E+04, 0.192000E+04, 0.193000E+04, &
0.194000E+04, 0.195000E+04, 0.196000E+04, 0.197000E+04, &
0.198000E+04, 0.199000E+04, 0.200000E+04, 0.201000E+04, &
0.202000E+04, 0.203000E+04, 0.204000E+04, 0.205000E+04, &
0.206000E+04, 0.207000E+04, 0.208000E+04, 0.209000E+04, &
0.210000E+04, 0.211000E+04, 0.212000E+04, 0.213000E+04, &
0.214000E+04, 0.215000E+04, 0.216000E+04, 0.217000E+04, &
0.218000E+04, 0.219000E+04, 0.227000E+04/
DATA BANDH1 / &
0.100000E+02, 0.200000E+02, 0.300000E+02, 0.400000E+02, &
0.500000E+02, 0.600000E+02, 0.700000E+02, 0.800000E+02, &
0.900000E+02, 0.100000E+03, 0.110000E+03, 0.120000E+03, &
0.130000E+03, 0.140000E+03, 0.150000E+03, 0.160000E+03, &
0.170000E+03, 0.180000E+03, 0.190000E+03, 0.200000E+03, &
0.210000E+03, 0.220000E+03, 0.230000E+03, 0.240000E+03, &
0.250000E+03, 0.260000E+03, 0.270000E+03, 0.280000E+03, &
0.290000E+03, 0.300000E+03, 0.310000E+03, 0.320000E+03, &
0.330000E+03, 0.340000E+03, 0.350000E+03, 0.360000E+03, &
0.370000E+03, 0.380000E+03, 0.390000E+03, 0.400000E+03, &
0.410000E+03, 0.420000E+03, 0.430000E+03, 0.440000E+03, &
0.450000E+03, 0.460000E+03, 0.470000E+03, 0.480000E+03, &
0.490000E+03, 0.500000E+03, 0.510000E+03, 0.520000E+03, &
0.530000E+03, 0.540000E+03, 0.550000E+03, 0.560000E+03, &
0.670000E+03, 0.800000E+03, 0.900000E+03, 0.990000E+03, &
0.107000E+04, 0.120000E+04, 0.121000E+04, 0.122000E+04/
DATA BANDH2 / &
0.123000E+04, 0.124000E+04, 0.125000E+04, 0.126000E+04, &
0.127000E+04, 0.128000E+04, 0.129000E+04, 0.130000E+04, &
0.131000E+04, 0.132000E+04, 0.133000E+04, 0.134000E+04, &
0.135000E+04, 0.136000E+04, 0.137000E+04, 0.138000E+04, &
0.139000E+04, 0.140000E+04, 0.141000E+04, 0.142000E+04, &
0.143000E+04, 0.144000E+04, 0.145000E+04, 0.146000E+04, &
0.147000E+04, 0.148000E+04, 0.149000E+04, 0.150000E+04, &
0.151000E+04, 0.152000E+04, 0.153000E+04, 0.154000E+04, &
0.155000E+04, 0.156000E+04, 0.157000E+04, 0.158000E+04, &
0.159000E+04, 0.160000E+04, 0.161000E+04, 0.162000E+04, &
0.163000E+04, 0.164000E+04, 0.165000E+04, 0.166000E+04, &
0.167000E+04, 0.168000E+04, 0.169000E+04, 0.170000E+04, &
0.171000E+04, 0.172000E+04, 0.173000E+04, 0.174000E+04, &
0.175000E+04, 0.176000E+04, 0.177000E+04, 0.178000E+04, &
0.179000E+04, 0.180000E+04, 0.181000E+04, 0.182000E+04, &
0.183000E+04, 0.184000E+04, 0.185000E+04, 0.186000E+04/
DATA BANDH3 / &
0.187000E+04, 0.188000E+04, 0.189000E+04, 0.190000E+04, &
0.191000E+04, 0.192000E+04, 0.193000E+04, 0.194000E+04, &
0.195000E+04, 0.196000E+04, 0.197000E+04, 0.198000E+04, &
0.199000E+04, 0.200000E+04, 0.201000E+04, 0.202000E+04, &
0.203000E+04, 0.204000E+04, 0.205000E+04, 0.206000E+04, &
0.207000E+04, 0.208000E+04, 0.209000E+04, 0.210000E+04, &
0.211000E+04, 0.212000E+04, 0.213000E+04, 0.214000E+04, &
0.215000E+04, 0.216000E+04, 0.217000E+04, 0.218000E+04, &
0.219000E+04, 0.220000E+04, 0.238000E+04/
!
!***THE FOLLOWING DATA STATEMENTS ARE BAND PARAMETERS OBTAINED USING
! THE 1982 AFGL CATALOG ON THE SPECIFIED BANDS
DATA ARNDM1 / &
0.354693E+00, 0.269857E+03, 0.167062E+03, 0.201314E+04, &
0.964533E+03, 0.547971E+04, 0.152933E+04, 0.599429E+04, &
0.699329E+04, 0.856721E+04, 0.962489E+04, 0.233348E+04, &
0.127091E+05, 0.104383E+05, 0.504249E+04, 0.181227E+05, &
0.856480E+03, 0.136354E+05, 0.288635E+04, 0.170200E+04, &
0.209761E+05, 0.126797E+04, 0.110096E+05, 0.336436E+03, &
0.491663E+04, 0.863701E+04, 0.540389E+03, 0.439786E+04, &
0.347836E+04, 0.130557E+03, 0.465332E+04, 0.253086E+03, &
0.257387E+04, 0.488041E+03, 0.892991E+03, 0.117148E+04, &
0.125880E+03, 0.458852E+03, 0.142975E+03, 0.446355E+03, &
0.302887E+02, 0.394451E+03, 0.438112E+02, 0.348811E+02, &
0.615503E+02, 0.143165E+03, 0.103958E+02, 0.725108E+02, &
0.316628E+02, 0.946456E+01, 0.542675E+02, 0.351557E+02, &
0.301797E+02, 0.381010E+01, 0.126319E+02, 0.548010E+01, &
0.600199E+01, 0.640803E+00, 0.501549E-01, 0.167961E-01, &
0.178110E-01, 0.170166E+00, 0.273514E-01, 0.983767E+00/
DATA ARNDM2 / &
0.753946E+00, 0.941763E-01, 0.970547E+00, 0.268862E+00, &
0.564373E+01, 0.389794E+01, 0.310955E+01, 0.128235E+01, &
0.196414E+01, 0.247113E+02, 0.593435E+01, 0.377552E+02, &
0.305173E+02, 0.852479E+01, 0.116780E+03, 0.101490E+03, &
0.138939E+03, 0.324228E+03, 0.683729E+02, 0.471304E+03, &
0.159684E+03, 0.427101E+03, 0.114716E+03, 0.106190E+04, &
0.294607E+03, 0.762948E+03, 0.333199E+03, 0.830645E+03, &
0.162512E+04, 0.525676E+03, 0.137739E+04, 0.136252E+04, &
0.147164E+04, 0.187196E+04, 0.131118E+04, 0.103975E+04, &
0.621637E+01, 0.399459E+02, 0.950648E+02, 0.943161E+03, &
0.526821E+03, 0.104150E+04, 0.905610E+03, 0.228142E+04, &
0.806270E+03, 0.691845E+03, 0.155237E+04, 0.192241E+04, &
0.991871E+03, 0.123907E+04, 0.457289E+02, 0.146146E+04, &
0.319382E+03, 0.436074E+03, 0.374214E+03, 0.778217E+03, &
0.140227E+03, 0.562540E+03, 0.682685E+02, 0.820292E+02, &
0.178779E+03, 0.186150E+03, 0.383864E+03, 0.567416E+01/
DATA ARNDM3 / &
0.225129E+03, 0.473099E+01, 0.753149E+02, 0.233689E+02, &
0.339802E+02, 0.108855E+03, 0.380016E+02, 0.151039E+01, &
0.660346E+02, 0.370165E+01, 0.234169E+02, 0.440206E+00, &
0.615283E+01, 0.304077E+02, 0.117769E+01, 0.125248E+02, &
0.142652E+01, 0.241831E+00, 0.483721E+01, 0.226357E-01, &
0.549835E+01, 0.597067E+00, 0.404553E+00, 0.143584E+01, &
0.294291E+00, 0.466273E+00, 0.156048E+00, 0.656185E+00, &
0.172727E+00, 0.118349E+00, 0.141598E+00, 0.588581E-01, &
0.919409E-01, 0.155521E-01, 0.537083E-02/
DATA BRNDM1 / &
0.789571E-01, 0.920256E-01, 0.696960E-01, 0.245544E+00, &
0.188503E+00, 0.266127E+00, 0.271371E+00, 0.330917E+00, &
0.190424E+00, 0.224498E+00, 0.282517E+00, 0.130675E+00, &
0.212579E+00, 0.227298E+00, 0.138585E+00, 0.187106E+00, &
0.194527E+00, 0.177034E+00, 0.115902E+00, 0.118499E+00, &
0.142848E+00, 0.216869E+00, 0.149848E+00, 0.971585E-01, &
0.151532E+00, 0.865628E-01, 0.764246E-01, 0.100035E+00, &
0.171133E+00, 0.134737E+00, 0.105173E+00, 0.860832E-01, &
0.148921E+00, 0.869234E-01, 0.106018E+00, 0.184865E+00, &
0.767454E-01, 0.108981E+00, 0.123094E+00, 0.177287E+00, &
0.848146E-01, 0.119356E+00, 0.133829E+00, 0.954505E-01, &
0.155405E+00, 0.164167E+00, 0.161390E+00, 0.113287E+00, &
0.714720E-01, 0.741598E-01, 0.719590E-01, 0.140616E+00, &
0.355356E-01, 0.832779E-01, 0.128680E+00, 0.983013E-01, &
0.629660E-01, 0.643346E-01, 0.717082E-01, 0.629730E-01, &
0.875182E-01, 0.857907E-01, 0.358808E+00, 0.178840E+00/
DATA BRNDM2 / &
0.254265E+00, 0.297901E+00, 0.153916E+00, 0.537774E+00, &
0.267906E+00, 0.104254E+00, 0.400723E+00, 0.389670E+00, &
0.263701E+00, 0.338116E+00, 0.351528E+00, 0.267764E+00, &
0.186419E+00, 0.238237E+00, 0.210408E+00, 0.176869E+00, &
0.114715E+00, 0.173299E+00, 0.967770E-01, 0.172565E+00, &
0.162085E+00, 0.157782E+00, 0.886832E-01, 0.242999E+00, &
0.760298E-01, 0.164248E+00, 0.221428E+00, 0.166799E+00, &
0.312514E+00, 0.380600E+00, 0.353828E+00, 0.269500E+00, &
0.254759E+00, 0.285408E+00, 0.159764E+00, 0.721058E-01, &
0.170528E+00, 0.231595E+00, 0.307184E+00, 0.564136E-01, &
0.159884E+00, 0.147907E+00, 0.185666E+00, 0.183567E+00, &
0.182482E+00, 0.230650E+00, 0.175348E+00, 0.195978E+00, &
0.255323E+00, 0.198517E+00, 0.195500E+00, 0.208356E+00, &
0.309603E+00, 0.112011E+00, 0.102570E+00, 0.128276E+00, &
0.168100E+00, 0.177836E+00, 0.105533E+00, 0.903330E-01, &
0.126036E+00, 0.101430E+00, 0.124546E+00, 0.221406E+00/
DATA BRNDM3 / &
0.137509E+00, 0.911365E-01, 0.724508E-01, 0.795788E-01, &
0.137411E+00, 0.549175E-01, 0.787714E-01, 0.165544E+00, &
0.136484E+00, 0.146729E+00, 0.820496E-01, 0.846211E-01, &
0.785821E-01, 0.122527E+00, 0.125359E+00, 0.101589E+00, &
0.155756E+00, 0.189239E+00, 0.999086E-01, 0.480993E+00, &
0.100233E+00, 0.153754E+00, 0.130780E+00, 0.136136E+00, &
0.159353E+00, 0.156634E+00, 0.272265E+00, 0.186874E+00, &
0.192090E+00, 0.135397E+00, 0.131497E+00, 0.127463E+00, &
0.227233E+00, 0.190562E+00, 0.214005E+00/
DATA BETAD1 / &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.234879E+03, 0.217419E+03, 0.201281E+03, 0.186364E+03, &
0.172576E+03, 0.159831E+03, 0.148051E+03, 0.137163E+03, &
0.127099E+03, 0.117796E+03, 0.109197E+03, 0.101249E+03, &
0.939031E+02, 0.871127E+02, 0.808363E+02, 0.750349E+02, &
0.497489E+02, 0.221212E+02, 0.113124E+02, 0.754174E+01, &
0.589554E+01, 0.495227E+01, 0.000000E+00, 0.000000E+00/
DATA BETAD2 / &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00/
DATA BETAD3 / &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00, 0.000000E+00, &
0.000000E+00, 0.000000E+00, 0.000000E+00/
!---------------------------------------------------------------
! EQUIVALENCE (BANDL1(1),BANDLO(1)),(BANDL2(1),BANDLO(65)), &
! (BANDL3(1),BANDLO(129))
! L = kme-1
! LP1 = L+1
! LP1V = LP1*(1+2*L/2)
! IMAX = ite
! LP2 = L + 2
DO I = 1,64
BANDLO(I)=BANDL1(I)
ENDDO
DO I = 65,128
BANDLO(I)=BANDL2(I-64)
ENDDO
DO I = 129,163
BANDLO(I)=BANDL3(I-128)
ENDDO
DO I = 1,64
BANDHI(I)=BANDH1(I)
ENDDO
DO I = 65,128
BANDHI(I)=BANDH2(I-64)
ENDDO
DO I = 129,163
BANDHI(I)=BANDH3(I-128)
ENDDO
!****************************************
!***COMPUTE LOCAL QUANTITIES AND AO3,BO3,AB15
!....FOR NARROW-BANDS...
DO 101 N=1,NBLW
ANB(N)=ARNDM(N)
BNB(N)=BRNDM(N)
CENTNB(N)=HAF*(BANDLO(N)+BANDHI(N))
DELNB(N)=BANDHI(N)-BANDLO(N)
BETANB(N)=BETAD(N)
101 CONTINUE
AB15(1)=ANB(57)*BNB(57)
AB15(2)=ANB(58)*BNB(58)
!....FOR WIDE BANDS...
AB15WD=AWIDE*BWIDE
!
!***COMPUTE INDICES: IND,INDX2,KMAXV
!SH ICNT=0
!SH DO 113 I1=1,L
!SH I2E=LP1-I1
!SH DO 115 I2=1,I2E
!SH ICNT=ICNT+1
!SH INDX2(ICNT)=LP1*(I2-1)+LP2*I1
!SH115 CONTINUE
!SH113 CONTINUE
!SH KMAXV(1)=1
!SH DO 117 I=2,L
!SH KMAXV(I)=KMAXV(I-1)+(LP2-I)
117 CONTINUE
!SH KMAXVM=KMAXV(L)
!***COMPUTE RATIOS OF CONT. COEFFS
SKC1R=BETAWD/BETINW
SKO3R=BETAD(61)/BETINW
SKO2D=ONE/BETINW
!
!****BEGIN TABLE COMPUTATIONS HERE***
!***COMPUTE TEMPS, MASSES FOR TABLE ENTRIES
!---NOTE: THE DIMENSIONING AND INITIALIZATION OF XTEMV AND OTHER ARRAYS
! WITH DIMENSION OF 28 IMPLY A RESTRICTION OF MODEL TEMPERATURES FROM
! 100K TO 370K.
!---THE DIMENSIONING OF ZMASS,ZROOT AND OTHER ARRAYS WITH DIMENSION OF
! 180 IMPLY A RESTRICTION OF MODEL H2O AMOUNTS SUCH THAT OPTICAL PATHS
! ARE BETWEEN 10**-16 AND 10**2, IN CGS UNITS.
ZMASS(1)=H1M16
DO 201 J=1,180
JP=J+1
ZROOT(J)=SQRT(ZMASS(J))
ZMASS(JP)=ZMASS(J)*H1P25892
201 CONTINUE
DO 203 I=1,28
XTEMV(I)=HNINETY+TEN*I
TFOUR(I)=XTEMV(I)*XTEMV(I)*XTEMV(I)*XTEMV(I)
FORTCU(I)=FOUR*XTEMV(I)*XTEMV(I)*XTEMV(I)
203 CONTINUE
!******THE COMPUTATION OF SOURCE,DSRCE IS NEEDED ONLY
! FOR THE COMBINED WIDE-BAND CASE.TO OBTAIN THEM,THE SOURCE
! MUST BE COMPUTED FOR EACH OF THE (NBLX) WIDE BANDS(=SRCWD)
! THEN COMBINED (USING IBAND) INTO SOURCE.
DO 205 N=1,NBLY
DO 205 I=1,28
SOURCE(I,N)=ZERO
205 CONTINUE
DO 207 N=1,NBLX
DO 207 I=1,28
SRCWD(I,N)=ZERO
207 CONTINUE
!---BEGIN FREQ. LOOP (ON N)
DO 211 N=1,NBLX
IF (N.LE.46) THEN
!***THE 160-1200 BAND CASES
CENT=CENTNB(N+16)
DEL=DELNB(N+16)
BDLO=BANDLO(N+16)
BDHI=BANDHI(N+16)
ENDIF
IF (N.EQ.NBLX) THEN
!***THE 2270-2380 BAND CASE
CENT=CENTNB(NBLW)
DEL=DELNB(NBLW)
BDLO=BANDLO(NBLW)
BDHI=BANDHI(NBLW)
ENDIF
!***FOR PURPOSES OF ACCURACY, ALL EVALUATIONS OF PLANCK FCTNS ARE MADE
! ON 10 CM-1 INTERVALS, THEN SUMMED INTO THE (NBLX) WIDE BANDS.
NSUBDS=(DEL-H1M3)/10+1
DO 213 NSB=1,NSUBDS
IF (NSB.NE.NSUBDS) THEN
CNUSB(NSB)=TEN*(NSB-1)+BDLO+FIVE
DNUSB(NSB)=TEN
ELSE
CNUSB(NSB)=HAF*(TEN*(NSB-1)+BDLO+BDHI)
DNUSB(NSB)=BDHI-(TEN*(NSB-1)+BDLO)
ENDIF
C1=(H37412M5)*CNUSB(NSB)**3
!---BEGIN TEMP. LOOP (ON I)
DO 215 I=1,28
X(I)=H1P4387*CNUSB(NSB)/XTEMV(I)
X1(I)=EXP(X(I))
SRCS(I)=C1/(X1(I)-ONE)
SRCWD(I,N)=SRCWD(I,N)+SRCS(I)*DNUSB(NSB)
215 CONTINUE
213 CONTINUE
211 CONTINUE
!***THE FOLLOWING LOOPS CREATE THE COMBINED WIDE BAND QUANTITIES SOURCE
! AND DSRCE
DO 221 N=1,40
DO 221 I=1,28
SOURCE(I,IBAND(N))=SOURCE(I,IBAND(N))+SRCWD(I,N)
221 CONTINUE
DO 223 N=9,NBLY
DO 223 I=1,28
SOURCE(I,N)=SRCWD(I,N+32)
223 CONTINUE
DO 225 N=1,NBLY
DO 225 I=1,27
DSRCE(I,N)=(SOURCE(I+1,N)-SOURCE(I,N))*HP1
225 CONTINUE
DO 231 N=1,NBLW
ALFANB(N)=BNB(N)*ANB(N)
AROTNB(N)=SQRT(ALFANB(N))
231 CONTINUE
!***FIRST COMPUTE PLANCK FCTNS (SRC1NB) AND DERIVATIVES (DBDTNB) FOR
! USE IN TABLE EVALUATIONS. THESE ARE DIFFERENT FROM SOURCE,DSRCE
! BECAUSE DIFFERENT FREQUENCY PTS ARE USED IN EVALUATION, THE FREQ.
! RANGES ARE DIFFERENT, AND THE DERIVATIVE ALGORITHM IS DIFFERENT.
!
DO 301 N=1,NBLW
CENT=CENTNB(N)
DEL=DELNB(N)
!---NOTE: AT PRESENT, THE IA LOOP IS ONLY USED FOR IA=2. THE LOOP STRUCT
! IS KEPT SO THAT IN THE FUTURE, WE MAY USE A QUADRATURE SCHEME FOR
! THE PLANCK FCTN EVALUATION, RATHER THAN USE THE MID-BAND FREQUENCY.
#if 0
DO 303 IA=1,3
#else
!jm -- getting floating point exceptions for IA=1, since 2 is only
! used anyway, I disabled the looping.
DO 303 IA=2,2
#endif
ANU=CENT+HAF*(IA-2)*DEL
C1=(H37412M5)*ANU*ANU*ANU+H1M20
!---TEMPERATURE LOOP---
DO 305 I=1,28
X(I)=H1P4387*ANU/XTEMV(I)
X1(I)=EXP(X(I))
!#$ tmp=max((X1(I)-ONE),H1M20)
!#$ SC(I)=C1/tmp
SC(I)=C1/((X1(I)-ONE)+H1M20)
!#$ DSC(I)=X(I)*SC(I)*SC(I)*X1(I)/(XTEMV(I)*C1)
DSC(I)=SC(I)*SC(I)*X(I)*X1(I)/(XTEMV(I)*C1)
305 CONTINUE
IF (IA.EQ.2) THEN
DO 307 I=1,28
SRC1NB(I,N)=DEL*SC(I)
DBDTNB(I,N)=DEL*DSC(I)
307 CONTINUE
ENDIF
303 CONTINUE
301 CONTINUE
!***NEXT COMPUTE R1T,R2,S2,AND T3- COEFFICIENTS USED FOR E3 FUNCTION
! WHEN THE OPTICAL PATH IS LESS THAN 10-4. IN THIS CASE, WE ASSUME A
! DIFFERENT DEPENDENCE ON (ZMASS).
!---ALSO OBTAIN R1WD, WHICH IS R1T SUMMED OVER THE 160-560 CM-1 RANGE
DO 311 I=1,28
SUM4(I)=ZERO
SUM6(I)=ZERO
SUM7(I)=ZERO
SUM8(I)=ZERO
SUM4WD(I)=ZERO
311 CONTINUE
DO 313 N=1,NBLW
CENT=CENTNB(N)
!***PERFORM SUMMATIONS FOR FREQ. RANGES OF 0-560,1200-2200 CM-1 FOR SUM4
! SUM6,SUM7,SUM8
IF (CENT.LT.560. .OR. CENT.GT.1200..AND.CENT.LE.2200.) THEN
DO 315 I=1,28
SUM4(I)=SUM4(I)+SRC1NB(I,N)
SUM6(I)=SUM6(I)+DBDTNB(I,N)
SUM7(I)=SUM7(I)+DBDTNB(I,N)*AROTNB(N)
SUM8(I)=SUM8(I)+DBDTNB(I,N)*ALFANB(N)
315 CONTINUE
ENDIF
!***PERFORM SUMMATIONS OVER 160-560 CM-1 FREQ RANGE FOR E1 CALCS (SUM4WD
IF (CENT.GT.160. .AND. CENT.LT.560.) THEN
DO 316 I=1,28
SUM4WD(I)=SUM4WD(I)+SRC1NB(I,N)
316 CONTINUE
ENDIF
313 CONTINUE
DO 317 I=1,28
R1T(I)=SUM4(I)/TFOUR(I)
R2(I)=SUM6(I)/FORTCU(I)
S2(I)=SUM7(I)/FORTCU(I)
T3(I)=SUM8(I)/FORTCU(I)
R1WD(I)=SUM4WD(I)/TFOUR(I)
317 CONTINUE
DO 401 J=1,180
DO 401 I=1,28
SUM(I,J)=ZERO
PERTSM(I,J)=ZERO
SUM3(I,J)=ZERO
SUMWDE(I,J)=ZERO
401 CONTINUE
!---FREQUENCY LOOP BEGINS---
DO 411 N=1,NBLW
CENT=CENTNB(N)
!***PERFORM CALCULATIONS FOR FREQ. RANGES OF 0-560,1200-2200 CM-1
IF (CENT.LT.560. .OR. CENT.GT.1200..AND.CENT.LE.2200.) THEN
DO 413 J=1,180
X2(J)=AROTNB(N)*ZROOT(J)
EXPO(J)=EXP(-X2(J))
413 CONTINUE
DO 415 J=1,180
IF (X2(J).GE.HUNDRED) THEN
EXPO(J)=ZERO
ENDIF
415 CONTINUE
DO 417 J=121,180
FAC(J)=ZMASS(J)*(ONE-(ONE+X2(J))*EXPO(J))/(X2(J)*X2(J))
417 CONTINUE
DO 419 J=1,180
DO 419 I=1,28
SUM(I,J)=SUM(I,J)+SRC1NB(I,N)*EXPO(J)
PERTSM(I,J)=PERTSM(I,J)+DBDTNB(I,N)*EXPO(J)
419 CONTINUE
DO 421 J=121,180
DO 421 I=1,28
SUM3(I,J)=SUM3(I,J)+DBDTNB(I,N)*FAC(J)
421 CONTINUE
ENDIF
!---COMPUTE SUM OVER 160-560 CM-1 RANGE FOR USE IN E1 CALCS (SUMWDE)
IF (CENT.GT.160. .AND. CENT.LT.560.) THEN
DO 420 J=1,180
DO 420 I=1,28
SUMWDE(I,J)=SUMWDE(I,J)+SRC1NB(I,N)*EXPO(J)
420 CONTINUE
ENDIF
411 CONTINUE
DO 431 J=1,180
DO 431 I=1,28
EM1(I,J)=SUM(I,J)/TFOUR(I)
TABLE1(I,J)=PERTSM(I,J)/FORTCU(I)
431 CONTINUE
DO 433 J=121,180
DO 433 I=1,28
EM3(I,J)=SUM3(I,J)/FORTCU(I)
433 CONTINUE
DO 441 J=1,179
DO 441 I=1,28
TABLE2(I,J)=(TABLE1(I,J+1)-TABLE1(I,J))*TEN
441 CONTINUE
DO 443 J=1,180
DO 443 I=1,27
TABLE3(I,J)=(TABLE1(I+1,J)-TABLE1(I,J))*HP1
443 CONTINUE
DO 445 I=1,28
TABLE2(I,180)=ZERO
445 CONTINUE
DO 447 J=1,180
TABLE3(28,J)=ZERO
447 CONTINUE
DO 449 J=1,2
DO 449 I=1,28
EM1(I,J)=R1T(I)
449 CONTINUE
DO 451 J=1,120
DO 451 I=1,28
EM3(I,J)=R2(I)/TWO-S2(I)*SQRT(ZMASS(J))/THREE+T3(I)*ZMASS(J)/EIGHT
451 CONTINUE
DO 453 J=121,180
DO 453 I=1,28
EM3(I,J)=EM3(I,J)/ZMASS(J)
453 CONTINUE
!***NOW COMPUTE E1 TABLES FOR 160-560 CM-1 BANDS ONLY.
! WE USE R1WD AND SUMWDE OBTAINED ABOVE.
DO 501 J=1,180
DO 501 I=1,28
EM1WDE(I,J)=SUMWDE(I,J)/TFOUR(I)
501 CONTINUE
DO 503 J=1,2
DO 503 I=1,28
EM1WDE(I,J)=R1WD(I)
503 CONTINUE
END SUBROUTINE TABLE
!---------------------------------------------------------------------
SUBROUTINE SOLARD(IHRST,IDAY,MONTH,JULYR) 3
!---------------------------------------------------------------------
IMPLICIT NONE
!---------------------------------------------------------------------
!$$$ SUBPROGRAM DOCUMENTATION BLOCK
! . . . .
! SUBPROGRAM: SOLARD COMPUTE THE SOLAR-EARTH DISTANCE
! PRGRMMR: Q.ZHAO ORG: W/NMC2 DATE: 96-7-23
!
! ABSTRACT:
! SOLARD CALCULATES THE SOLAR-EARTH DISTANCE ON EACH DAY
! FOR USE IN SHORT-WAVE RADIATION.
!
! PROGRAM HISTORY LOG:
! 96-07-23 Q.ZHAO - ORIGINATOR
! 98-10-09 Q.ZHAO - CHANGED TO USE IW3JDN IN W3LIB TO
! CALCULATE JD.
!
! USAGE: CALL SOLARD FROM SUBROUTINE INIT
!
! INPUT ARGUMENT LIST:
! NONE
!
! OUTPUT ARGUMENT LIST:
! R1 - THE NON-DIMENSIONAL DISTANCE BETWEEN SUN AND THE EARTH
! (LESS THAN 1.0 IN SUMMER AND LARGER THAN 1.0 IN WINTER).
!
! INPUT FILES:
! NONE
!
! OUTPUT FILES:
! NONE
!
! SUBPROGRAMS CALLED:
!
! UNIQUE: NONE
!
! LIBRARY: IW3JDN
!
! COMMON BLOCKS: CTLBLK
!
! ATTRIBUTES:
! LANGUAGE: FORTRAN 90
! MACHINE : IBM SP
!***********************************************************************
REAL, PARAMETER :: PI=3.1415926,PI2=2.*PI
!-----------------------------------------------------------------------
! INTEGER, INTENT(IN ) :: IHRST,IDAT(3)
INTEGER, INTENT(IN ) :: IHRST,IDAY,MONTH,JULYR
! REAL , INTENT(OUT) :: R1
!-----------------------------------------------------------------------
INTEGER :: NDM(12),JYR19,JMN
REAL :: CCR
DATA JYR19/1900/, JMN/0/, CCR/1.3E-6/
DATA NDM/0,31,59,90,120,151,181,212,243,273,304,334/
!.....TPP = DAYS BETWEEN EPOCH AND PERIHELION PASSAGE OF 1900
!.....JDOR1 = JD OF DECEMBER 30, 1899 AT 12 HOURS UT
!.....JDOR2 = JD OF EPOCH WHICH IS JANUARY 0, 1990 AT 12 HOURS UT
!
REAL :: TPP
DATA TPP/1.55/
INTEGER :: JDOR2,JDOR1
DATA JDOR2/2415020/, JDOR1/2415019/
REAL :: DAYINC,DAT,T,YEAR,DATE,EM,E,EC,EP,CR,FJD,FJD1
INTEGER :: JYR,JMNTH,JDAY,JHRJD,JHR,JD,ITER
!
! LIBRARY: IW3JDN
!
! --------------------------------------------------------------------
! COMPUTES JULIAN DAY AND FRACTION FROM YEAR, MONTH, DAY AND TIME UT
! ACCURATE ONLY BETWEEN MARCH 1, 1900 AND FEBRUARY 28, 2100
! BASED ON JULIAN CALENDAR CORRECTED TO CORRESPOND TO GREGORIAN
! CALENDAR DURING THIS PERIOD
! --------------------------------------------------------------------
! JYR=IDAT(3)
! JMNTH=IDAT(1)
! JDAY=IDAT(2)
JHR=IHRST
!
JD=IDAY-32075 &
+1461*(JULYR+4800+(MONTH-14)/12)/4 &
+367*(MONTH-2-(MONTH-14)/12*12)/12 &
-3*((JULYR+4900+(MONTH-14)/12)/100)/4
IF(JHR.LT.12)THEN
JD=JD-1
FJD=.5+.041666667*REAL(JHR)+.00069444444*REAL(JMN)
ELSE
7 FJD=.041666667E0*FLOAT(JHR-12)+.00069444444E0*FLOAT(JMN)
END IF
DAYINC=JHR/24.0
FJD1=JD+FJD+DAYINC
JD=FJD1
FJD=FJD1-JD
!***
!*** CALCULATE THE SOLAR-EARTH DISTANCE
!***
DAT=REAL(JD-JDOR2)-TPP+FJD
!***
! COMPUTES TIME IN JULIAN CENTURIES AFTER EPOCH
!***
T=FLOAT(JD-JDOR2)/36525.E0
!***
! COMPUTES LENGTH OF ANOMALISTIC AND TROPICAL YEARS (MINUS 365 DAYS)
!***
YEAR=.25964134E0+.304E-5*T
!***
! COMPUTES ORBIT ECCENTRICITY FROM T
!***
EC=.01675104E0-(.418E-4+.126E-6*T)*T
YEAR=YEAR+365.E0
!***
! DATE=DAYS SINCE LAST PERIHELION PASSAGE
!***
DATE = MOD(DAT,YEAR)
!***
! SOLVE ORBIT EQUATIONS BY NEWTON'S METHOD
!***
EM=PI2*DATE/YEAR
E=1.E0
ITER = 0
31 EP=E-(E-EC*SIN(E)-EM)/(1.E0-EC*COS(E))
CR=ABS(E-EP)
E=EP
ITER = ITER + 1
IF(ITER.GT.10) GOTO 1031
IF(CR.GT.CCR) GO TO 31
1031 CONTINUE
R1=1.E0-EC*COS(E)
!
! WRITE(6,1000)JYR,JMNTH,JDAY,JHR,R1
! WRITE(6,*)JHR,R1
1000 FORMAT('SUN-EARTH DISTANCE CALCULATION FINISHED IN SOLARD'/ &
'YEAR=',I5,' MONTH=',I3,' DAY=',I3,' HOUR=' &
, I3,' R1=',F9.4)
!***
! RETURN TO RADTN
!***
END SUBROUTINE SOLARD
!---------------------------------------------------------------------
SUBROUTINE CAL_MON_DAY(JULDAY,julyr,Jmonth,Jday) 4
!---------------------------------------------------------------------
IMPLICIT NONE
!-----------------------------------------------------------------------
INTEGER, INTENT(IN) :: JULDAY,julyr
INTEGER, INTENT(OUT) :: Jmonth,Jday
LOGICAL :: LEAP,NOT_FIND_DATE
INTEGER :: MONTH (12),itmpday,itmpmon,i
!-----------------------------------------------------------------------
DATA MONTH/31,28,31,30,31,30,31,31,30,31,30,31/
!***********************************************************************
NOT_FIND_DATE = .true.
itmpday = JULDAY
itmpmon = 1
LEAP=.FALSE.
IF(MOD(julyr,4).EQ.0)THEN
MONTH(2)=29
LEAP=.TRUE.
ENDIF
i = 1
DO WHILE (NOT_FIND_DATE)
IF(itmpday.GT.MONTH(i))THEN
itmpday=itmpday-MONTH(i)
ELSE
Jday=itmpday
Jmonth=i
NOT_FIND_DATE = .false.
ENDIF
i = i+1
END DO
END SUBROUTINE CAL_MON_DAY
!!================================================================================
! CO2 initialization code
FUNCTION ANTEMP(L,Z) 12
REAL :: ZB(10,7),C(11,7),DELTA(10,7),TSTAR(7)
! ************** TROPICAL SOUNDING **************************
DATA (ZB(N,1),N=1,10)/ 2.0, 3.0, 16.5, 21.5, 45.0, &
51.0, 70.0, 100., 200., 300./
DATA (C(N,1),N=1,11)/ -6.0, -4.0, -6.7, 4.0, 2.2, &
1.0, -2.8, -.27, 0.0, 0.0, 0.0/
DATA (DELTA(N,1),N=1,10)/.5, .5, .3, .5, 1.0, &
1.0, 1.0, 1.0, 1.0, 1.0/
! ************** SUB-TROPICAL SUMMER ************************
DATA (ZB(N,2),N=1,10)/ 1.5, 6.5, 13.0, 18.0, 26.0, &
36.0, 48.0, 50.0, 70.0, 100./
DATA (C(N,2),N=1,11)/ -4.0, -6.0, -6.5, 0.0, 1.2, &
2.2, 2.5, 0.0, -3.0, -0.25, 0.0/
DATA (DELTA(N,2),N=1,10)/ .5, 1.0, .5, .5, 1.0, &
1.0, 2.5, .5, 1.0, 1.0/
! ************** SUB-TROPICAL WINTER ************************
DATA (ZB(N,3),N=1,10)/ 3.0, 10.0, 19.0, 25.0, 32.0, &
44.5, 50.0, 71.0, 98.0, 200.0/
DATA (C(N,3),N=1,11)/ -3.5, -6.0, -0.5, 0.0, 0.4, &
3.2, 1.6, -1.8, -0.7, 0.0, 0.0/
DATA (DELTA(N,3),N=1,10)/ .5, .5, 1.0, 1.0, 1.0, &
1.0, 1.0, 1.0, 1.0, 1.0/
! ************* SUB-ARCTIC SUMMER *************************
DATA (ZB(N,4),N=1,10)/ 4.7, 10.0, 23.0, 31.8, 44.0, &
50.2, 69.2, 100.0, 102.0, 103.0/
DATA (C(N,4),N=1,11)/ -5.3, -7.0, 0.0, 1.4, 3.0, &
0.7, -3.3, -0.2, 0.0, 0.0, 0.0/
DATA (DELTA(N,4),N=1,10)/ .5, .3, 1.0, 1.0, 2.0, &
1.0, 1.5, 1.0, 1.0, 1.0/
! ************ SUB-ARCTIC WINTER *****************************
DATA (ZB(N,5),N=1,10)/ 1.0, 3.2, 8.5, 15.5, 25.0, &
30.0, 35.0, 50.0, 70.0, 100.0/
DATA (C(N,5),N=1,11)/ 3.0, -3.2, -6.8, 0.0, -0.6, &
1.0, 1.2, 2.5, -0.7, -1.2, 0.0/
DATA (DELTA(N,5),N=1,10)/ .4, 1.5, .3 , .5, 1.0, &
1.0, 1.0, 1.0, 1.0, 1.0/
! ************ US STANDARD 1976 ******************************
DATA (ZB(N,6),N=1,10)/ 11.0, 20.0, 32.0, 47.0, 51.0, &
71.0, 84.8520, 90.0, 91.0, 92.0/
DATA (C(N,6),N=1,11)/ -6.5, 0.0, 1.0, 2.80, 0.0, &
-2.80, -2.00, 0.0, 0.0, 0.0, 0.0/
DATA (DELTA(N,6),N=1,10)/ 0.3, 1.0, 1.0, 1.0, 1.0, &
1.0, 1.0, 1.0, 1.0, 1.0/
!
! ************ ENLARGED US STANDARD 1976 **********************
DATA (ZB(N,7),N=1,10)/ 11.0, 20.0, 32.0, 47.0, 51.0, &
71.0, 84.8520, 90.0, 91.0, 92.0/
DATA (C(N,7),N=1,11)/ -6.5, 0.0, 1.0, 2.80, 0.0, &
-2.80, -2.00, 0.0, 0.0, 0.0, 0.0/
DATA (DELTA(N,7),N=1,10)/ 0.3, 1.0, 1.0, 1.0, 1.0, &
1.0, 1.0, 1.0, 1.0, 1.0/
!
DATA TSTAR/ 300.0, 294.0, 272.2, 287.0, 257.1, 2*288.15/
!
NLAST=10
TEMP=TSTAR(L)+C(1,L)*Z
DO 20 N=1,NLAST
EXPO=(Z-ZB(N,L))/DELTA(N,L)
EXPP=ZB(N,L)/DELTA(N,L)
!JD single-precision change
! FAC=EXP(EXPP)+EXP(-EXPP)
!mp write(6,*) '.........................................'
!mp what in the hell does the next line do?
!mp
!mp apparently if statement <0 or =0 then 23, else 24
!mp IF(ABS(EXPO)-100.0) 23,23,24
!
! changed to a more reasonable value for the workstation
!
IF(ABS(EXPO)-50.0) 23,23,24
23 X=EXP(EXPO)
Y=X+1.0/X
ZLOG=ALOG(Y)
GO TO 25
24 ZLOG=ABS(EXPO)
!mp 25 IF(EXPP-100.0) 27,27,28
25 IF(EXPP-50.0) 27,27,28
!JD single-precision change
27 FAC=EXP(EXPP)+EXP(-EXPP)
FACLOG=ALOG(FAC)
GO TO 29
28 FACLOG=EXPP
! TEMP=TEMP+(C(N+1,L)-C(N,L))*0.5*(Z+DELTA(N,L)*
! 1 ALOG((EXP(EXPO)+EXP(-EXPO))/FAC))
29 TEMP=TEMP+(C(N+1,L)-C(N,L))*0.5*(Z+DELTA(N,L)* &
(ZLOG-FACLOG))
!mp write(6,*) 'ANTEMP pieces (C,C,ZLOG,FACLOG)', C(N+1,L),C(N,L),
!mp + ZLOG,FACLOG
20 CONTINUE
ANTEMP=TEMP
END FUNCTION ANTEMP
!CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCc
SUBROUTINE COEINT(RAT,IR) 2,6
! **********************************************************************
!
!
! THE TRANSMISSION FUNCTION BETWEEN P1 AND P2 IS ASSUMED TO
! THE FUNCTIONAL FORM
! TAU(P1,P2)= 1.0-SQRT(C*LOG(1.0+X*PATH)),
! WHERE
! PATH(P1,P2)=((P1-P2)**2)*(P1+P2+CORE)/
! (ETA*(P1+P2+CORE)+(P1-P2))
!
!
! THE PARAMETERS C AND X ARE FUNCTIONS OF P2, AND ARE TO BE DETER
! WHILE CORE IS A PRESPECIFIED NUMBER.ETA IS A FUNCTION OF THE TH
! PRODUCT (CX);IT IS OBTAITED ITERATIVELY. THE DERIVATION OF ALL
! VALUES WILL BE EXPLAINED IN A FORTHCOMING PAPER.
! SUBROUTINE COEINT DETERMINES C(I) AND X(I) BY USING THE ACT
! VALUES OF TAU(P(I-2),P(I)) AND TAU(P(I-1),P(I)) AND THE PREVIOU
! ITERATION VALUE OF ETA.
! DEFINE:
! PATHA=PATH(P(I),P(I-2),CORE,ETA)
! PATHB=PATH(P(I),P(I-1),CORE,ETA);
! THEN
! R=(1-TAU(P(I),P(I-2)))/(1-TAU(P(I),P(I-1)))
! = SQRT(LOG(1+X*PATHA)/LOG(1+X*PATHB)),
! SO THAT
! R**2= LOG(1+X*PATHA)/LOG(1+X*PATHB).
! THIS EQUATION CAN BE SOLVED BY NEWTON S METHOD FOR X AND THEN T
! RESULT USED TO FIND C. THIS IS REPEATED FOR EACH VALUE OF I GRE
! THAN 2 TO GIVE THE ARRAYS X(I) AND C(I).
! NEWTON S METHOD FOR SOLVING THE EQUATION
! F(X)=0
! MAKES USE OF THE LOOP XNEW= XOLD-F(XOLD)/FPRIME(XOLD).
! THIS IS ITERATED 20 TIMES, WHICH IS PROBABLY EXCESSIVE.
! THE FIRST GUESS FOR ETA IS 3.2E-4*EXP(-P(I)/1000),WHICH HAS
! BEEN FOUND TO BE FAIRLY REALISTIC BY EXPERIMENT; WE ITERATE 5 T
! (AGAIN,PROBABLY EXCESSIVELY) TO OBTAIN THE VALUES FOR C,X,ETA T
! USED FOR INTERPOLATION.
! THERE ARE SEVERAL POSSIBLE PITFALLS:
! 1) IN THE COURSE OF ITERATION, X MAY REACH A VALUE WHICH
! 1+X*PATHA NEGATIVE; IN THIS CASE THE ITERATION IS STOP
! AND AN ERROR MESSAGE IS PRINTED OUT.
! 2) EVEN IF (1) DOES NOT OCCUR, IT IS STILL POSSIBLE THAT
! BE NEGATIVE AND LARGE ENOUGH TO MAKE 1+X*PATH(P(I),0,C
! NEGATIVE. THIS IS CHECKED FOR IN A FINAL LOOP, AND IF
! A WARNING IS PRINTED OUT.
!
! *********************************************************************
!....
! IMPLICIT DOUBLE PRECISION (A-H,O-Z)
! COMMON/PRESS/PA(109)
REAL RAT,SINV
! REAL PA,CORE,TRANSA,PATH,UEXP,SEXP,ETA,SEXPV
REAL PA2
! COMMON/TRAN/ TRANSA(109,109)
! COMMON/COEFS/XA(109),CA(109),ETA(109),SEXPV(109),CORE,UEXP,SEXP
DIMENSION PATH0(109),ETAP(109),XAP(109),CAP(109)
DIMENSION SINV(4)
INTEGER :: IERR
DATA SINV/2.74992,2.12731,4.38111,0.0832926/
!NOV89 DIMENSION SINV(3)
!NOV89 DATA SINV/2.74992,2.12731,4.38111/
!O222 OLD CODE USED 2.7528 RATHER THAN 2.74992 ---K.A.C. OCTOBER 1988
!O222 WHEN 2.7528 WAS USED,WE EXACTLY REPRODUCED THE MRF CO2 ARRAYS
CORE=5.000
UEXP=0.90
! P0=0.7
DO 902 I=1,109
PA2=PA(I)*PA(I)
SEXPV(I)=.505+2.0E-5*PA(I)+.035*(PA2-.25)/(PA2+.25)
902 CONTINUE
DO 900 I=1,109
ETA(I)=3.2E-4*EXP(-PA(I)/500.)
ETAP(I)=ETA(I)
900 CONTINUE
DO 1200 NP=1,10
DO 1000 I=3,109
SEXP=SEXPV(I)
R=(1.0D0-TRANSA(I,I-2))/(1.0D0-TRANSA(I,I-1))
REXP=R**(UEXP/SEXP)
arg1=path(pa(i),pa(i-2),core,eta(i))
arg2=path(pa(i),pa(i-1),core,eta(i))
PATHA=(PATH(PA(I),PA(I-2),CORE,ETA(I)))**UEXP
PATHB=(PATH(PA(I),PA(I-1),CORE,ETA(I)))**UEXP
XX=2.0D0*(PATHB*REXP-PATHA)/(PATHB*PATHB*REXP-PATHA*PATHA)
DO 1010 LL=1,20
F1=DLOG(1.0D0+XX*PATHA)
F2=DLOG(1.0D0+XX*PATHB)
F=F1/F2-REXP
FPRIME=(F2*PATHA/(1.0D0+XX*PATHA)-F1*PATHB/(1.0D0+XX*PATHB))/ &
(F2*F2)
XX=XX-F/FPRIME
CHECK=1.0D0+XX*PATHA
!!!! IF (CHECK) 1020,1020,1025
IF(CHECK.LE.0.)THEN
WRITE(errmess,360)I,LL,CHECK
WRITE(errmess,*)' xx=',xx,' patha=',patha
360 FORMAT(' ERROR,I=',I3,'LL=',I3,'CHECK=',F20.10)
CALL wrf_error_fatal ( errmess )
ENDIF
1010 CONTINUE
CA(I)=(1.0D0-TRANSA(I,I-2))**(UEXP/SEXP)/ &
(DLOG(1.0D0+XX*PATHA)+1.0D-20)
XA(I)=XX
1000 CONTINUE
XA(2)=XA(3)
XA(1)=XA(3)
CA(2)=CA(3)
CA(1)=CA(3)
DO 1100 I=3,109
PATH0(I)=(PATH(PA(I),0.,CORE,ETA(I)))**UEXP
PATH0(I)=1.0D0+XA(I)*PATH0(I)
!+++ IF (PATH0(I).LT.0.) WRITE (6,361) I,PATH0(I),XA(I)
1100 CONTINUE
DO 1035 I=1,109
SEXP=SEXPV(I)
ETAP(I)=ETA(I)
ETA(I)=(SINV(IR)/RAT)**(1./SEXP)* &
(CA(I)*XA(I))**(1./UEXP)
1035 CONTINUE
!
! THE ETA FORMULATION IS DETAILED IN SCHWARZKOPF AND FELS(1985).
! THE QUANTITY SINV=(G*DELTANU)/(RCO2*D*S)
! IN CGS UNITS,WITH D,THE DIFFUSICITY FACTOR=2, AND
! S,THE SUM OF CO2 LINE STRENGTHS OVER THE 15UM CO2 BAND
! ALSO,THE DENOMINATOR IS MULTIPLIED BY
! 1000 TO PERMIT USE OF MB UNITS FOR PRESSURE.
! S IS ACTUALLY WEIGHTED BY B(250) AT 10 CM-1 WIDE INTERVALS,IN
! ORDER TO BE CONSISTENT WITH THE METHODS USED TO OBTAIN THE LBL
! 1-BAND CONSOLIDATED TRANCMISSION FUNCTIONS.
! FOR THE 490-850 INTERVAL (DELTANU=360,IR=1) SINV=2.74992.
! (SLIGHTLY DIFFERENT FROM 2.7528 USED IN EARLIER VERSIONS)
! FOR THE 490-670 INTERVAL (IR=2) SINV=2.12731
! FOR THE 670-850 INTERVAL (IR=3) SINV=4.38111
! FOR THE 2270-2380 INTERVAL (IR=4) SINV=0.0832926
! SINV HAS BEEN OBTAINED USING THE 1982 AFGL CATALOG FOR CO2
! RAT IS THE ACTUAL CO2 MIXING RATIO IN UNITS OF 330 PPMV,
! LETTING USE OF THIS FORMULATION FOR ANY CO2 CONCENTRATION.
!
! WRITE (6,366) (NP,I,CA(I),XA(I),ETA(I),SEXPV(I),I=1,109)
!366 FORMAT (2I4,4E20.12)
1200 CONTINUE
361 FORMAT (' **WARNING:** 1+XA*PATH(PA(I),0) IS NEGATIVE,I= ',I3,/ &
20X,'PATH0(I)=',F16.6,' XA(I)=',F16.6)
RETURN
END SUBROUTINE COEINT
!--------------
!CCC PROGRAM CO2INS
SUBROUTINE CO2INS(T22,T23,T66,IQ,L,LP1,iflag) 6
! *********************************************************
! SAVE DATA ON PERMANENT DATA SET DENOTED BY CO222 ******
! ..... K.CAMPANA MARCH 1988,OCTOBER 1988...
! ..... K.CAMPANA DECEMBER 1988-CLEANED UP FOR LAUNCHER
! ..... K.CAMPANA NOVEMBER 1989-ALTERED FOR NEW RADIATION
! *********************************************************
DIMENSION T22(LP1,LP1,3),T23(LP1,LP1,3),T66(LP1,LP1,6)
DIMENSION DCDT8(LP1,LP1),DCDT10(LP1,LP1),CO2PO(LP1,LP1), &
CO2800(LP1,LP1),CO2PO1(LP1,LP1),CO2801(LP1,LP1),CO2PO2(LP1,LP1), &
CO2802(LP1,LP1),N(LP1),D2CT8(LP1,LP1),D2CT10(LP1,LP1)
!CC ITIN=22
!CC ITIN1=23
!O222 LATEST CODE HAD IQ=1
!CC IQ=4
1011 FORMAT (4F20.14)
!CC READ (ITIN,1011) ((CO2PO(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN1,1011) ((CO2800(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN,1011) ((CO2PO1(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN1,1011) ((CO2801(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN,1011) ((CO2PO2(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN1,1011) ((CO2802(I,J),I=1,LP1),J=1,LP1)
DO 300 J=1,LP1
DO 300 I=1,LP1
CO2PO(I,J) = T22(I,J,1)
!NOV89
IF (IQ.EQ.5) GO TO 300
!NOV89
CO2PO1(I,J) = T22(I,J,2)
CO2PO2(I,J) = T22(I,J,3)
300 CONTINUE
DO 301 J=1,LP1
DO 301 I=1,LP1
CO2800(I,J) = T23(I,J,1)
!NOV89
IF (IQ.EQ.5) GO TO 301
!NOV89
CO2801(I,J) = T23(I,J,2)
CO2802(I,J) = T23(I,J,3)
301 CONTINUE
!***THE FOLLOWING CODE IS REWRITTEN SO THAT THE RADIATIVE BANDS
! ARE:
! IQ=1 560-800 (CONSOL.=490-850)
! IQ=2 560-670 (CONSOL.=490-670)
! IQ=3 670-800 (CONSOL.=670-850)
! IQ=4 560-760 (ORIGINAL CODE) (CONSOL.=490-850)
!NOV89
! IQ=5 2270-2380 (CONSOL.=2270-2380)
!NOV89
! THE FOLLOWING LOOP OBTAINS TRANSMISSION FUNCTIONS FOR BANDS
! USED IN RADIATIVE MODEL CALCULATIONS,WITH THE EQUIVALENT
! WIDTHS KEPT FROM THE ORIGINAL CONSOLIDATED CO2 TF S.
!NOV89
! NOTE: ALTHOUGH THE BAND TRANSMISSION FUNCTIONS ARE
! COMPUTED FOR ALL RADIATIVE BANDS, AS OF 9/28/88, THEY
! ARE WRITTEN OUT IN FULL ONLY FOR THE FULL 15 UM BAND CASES
! (IQ=1,4). IN OTHER CASES, THE TRANSMISSIVITIES (1,K) ARE
! WRITTEN OUT, AS THESE ARE THE ONLY ONES NEEDED FOR CTS
! CALCULATIONS. ALSO, FOR THE 4.3 UM BAND (IQ=5) THE TEMP.
! DERIVATIVE TERMS ARE NOT WRITTEN OUT, AS THEY ARE UNUSED.
!NOV89
IF (IQ.EQ.1) THEN
C1=1.5
C2x=0.5
ENDIF
IF (IQ.EQ.2) THEN
C1=18./11.
C2x=7./11.
ENDIF
IF (IQ.EQ.3) THEN
C1=18./13.
C2x=5./13.
ENDIF
IF (IQ.EQ.4) THEN
C1=1.8
C2x=0.8
ENDIF
!NOV89
IF (IQ.EQ.5) THEN
C1=1.0
C2x=0.0
ENDIF
!NOV89
DO 1021 I=1,LP1
DO 1021 J=1,LP1
CO2PO(J,I)=C1*CO2PO(J,I)-C2x
CO2800(J,I)=C1*CO2800(J,I)-C2x
!NOV89
IF (IQ.EQ.5) GO TO 1021
!NOV89
CO2PO1(J,I)=C1*CO2PO1(J,I)-C2x
CO2801(J,I)=C1*CO2801(J,I)-C2x
CO2PO2(J,I)=C1*CO2PO2(J,I)-C2x
CO2802(J,I)=C1*CO2802(J,I)-C2x
1021 CONTINUE
!NOV89
IF (IQ.GE.1.AND.IQ.LE.4) THEN
!NOV89
DO 1 J=1,LP1
DO 1 I=1,LP1
DCDT8(I,J)=.02*(CO2801(I,J)-CO2802(I,J))*100.
DCDT10(I,J)=.02*(CO2PO1(I,J)-CO2PO2(I,J))*100.
D2CT8(I,J)=.0016*(CO2801(I,J)+CO2802(I,J)-2.*CO2800(I,J))*1000.
D2CT10(I,J)=.0016*(CO2PO1(I,J)+CO2PO2(I,J)-2.*CO2PO(I,J))*1000.
1 CONTINUE
!NOV89
ENDIF
!NOV89
!O222 *********************************************************
!CC REWIND 66
! SAVE CDT51,CO251,C2D51,CDT58,CO258,C2D58..ON TEMPO FILE
!CC WRITE (66) DCDT10
!CC WRITE (66) CO2PO
!CC WRITE (66) D2CT10
!CC WRITE (66) DCDT8
!CC WRITE (66) CO2800
!CC WRITE (66) D2CT8
!CC REWIND 66
!NOV89
IF (IQ.EQ.1.OR.IQ.EQ.4) THEN
!NOV89
DO 400 J=1,LP1
DO 400 I=1,LP1
T66(I,J,1) = DCDT10(I,J)
T66(I,J,2) = CO2PO(I,J)
T66(I,J,3) = D2CT10(I,J)
T66(I,J,4) = DCDT8(I,J)
T66(I,J,5) = CO2800(I,J)
T66(I,J,6) = D2CT8(I,J)
400 CONTINUE
!NOV89
ELSE
DO 409 I=1,LP1
T66(I,1,2) = CO2PO(1,I)
T66(I,1,5) = CO2800(1,I)
IF (IQ.EQ.5) GO TO 409
T66(I,1,1) = DCDT10(1,I)
T66(I,1,3) = D2CT10(1,I)
T66(I,1,4) = DCDT8(1,I)
T66(I,1,6) = D2CT8(1,I)
409 CONTINUE
ENDIF
!NOV89
!O222 *********************************************************
RETURN
END SUBROUTINE CO2INS
!O222 PROGRAM CO2INT(INPUT,TAPE5=INPUT)
!NOV89
SUBROUTINE CO2INT(ITAPE,T15A,T15B,T22,RATIO,IR,NMETHD,NLEVLS,NLP1,NLP2) 16,10
!NOV89
! *********************************************************
! CHANGES TO DATA READ AND FORMAT SEE CO222 ***
! ..... K.CAMPANA MARCH 1988,OCTOBER 1988
! CHANGES TO PASS ITAPE,AND IF IR=4,READ 1 CO2 REC..KAC NOV89
! *********************************************************
! CO2INT INTERPOLATES CARBON DIOXIDE TRANSMISSION FUNCTIONS
! FROM THE 109 LEVEL GRID,FOR WHICH THE TRANSMISSION FUNCTIONS
! HAVE BEEN PRE-CALCULATED, TO THE GRID STRUCTURE SPECIFIED BY THE
! USER.
!
! METHOD:
!
! CO2INT IS EMPLOYABLE FOR TWO PURPOSES: 1) TO OBTAIN TRANSMIS-
! SIVITIES BETWEEN ANY 2 OF AN ARRAY OF USER-DEFINED PRESSURES; AND
! 2) TO OBTAIN LAYER-MEAN TRANSMISSIVITIES BETWEEN ANY 2 OF AN ARRAY
! OF USER-DEFINED PRESSURE LAYERS.TO CLARIFY THESE TWO PURPOSES,SEE
! THE DIAGRAM AND DISCUSSION BELOW.
! CO2INT MAY BE USED TO EXECUTE ONLY ONE PURPOSE AT ONE TIME.
!
! LET P BE AN ARRAY OF USER-DEFINED PRESSURES
! AND PD BE USER-DEFINED PRESSURE LAYERS.
!
! - - - - - - - - - PD(I-1) ---
! ^
! ----------------- P(I) ^ PRESSURE LAYER I (PLM(I))
! ^
! - - - - - - - - - PD(I) ---
! ^
! ----------------- P(I+1) ^ PRESSURE LAYER I+1 (PLM(I+1))
! ^
! - - - - - - - - - PD(I+1)---
! ... (THE NOTATION USED IS
! ... CONSISTENT WITH THE CODE)
! ...
! - - - - - - - - - PD(J-1)
!
! ----------------- P(J)
!
! - - - - - - - - - PD(J)
!
! PURPOSE 1: THE TRANSMISSIVITY BETWEEN SPECIFIC PRESSURES
! P(I) AND P(J) ,TAU(P(I),P(J)) IS COMPUTED BY THIS PROGRAM.
! IN THIS MODE,THERE IS NO REFERENCE TO LAYER PRESSURES PD
! (PD,PLM ARE NOT INPUTTED).
!
! PURPOSE 2: THE LAYER-MEAN TRANSMISSIVITY BETWEEN A LAYER-
! MEAN PRESSURE PLM(J) AND PRESSURE LAYER I IS GIVEN BY
! TAULM(PLM(I),PLM(J)). IT IS COMPUTED BY THE INTEGRAL
!
! PD(I)
! ----
! 1 ^
! ------------- * ^ TAU ( P',PLM(J) ) DP'
! PD(I)-PD(I-1) ^
! ----
! PD(I-1)
!
! THE LAYER-MEAN PRESSURE PLM(I) IS SPECIFIED BY THE USER.
! FOR MANY PURPOSES,PLM WILL BE CHOSEN TO BE THE AVERAGE
! PRESSURE IN THE LAYER-IE,PLM(I)=0.5*(PD(I-1)+PD(I)).
! FOR LAYER-MEAN TRANSMISSIVITIES,THE USER THUS INPUTS
! A PRESSURE ARRAY (PD) DEFINING THE PRESSURE LAYERS AND AN
! ARRAY (PLM) DEFINING THE LAYER-MEAN PRESSURES.THE CALCULATION
! DOES NOT DEPEND ON THE P ARRAY USED FOR PURPOSE 1 (P IS NOT
! INPUTTED).
!
! THE FOLLOWING PARAGRAPHS DEPICT THE UTILIZATION OF THIS
! CODE WHEN USED TO COMPUTE TRANSMISSIVITIES BETWEEN SPECIFIC
! PRESSURES. LATER PARAGRAPHS DESCRIBE ADDITIONAL FEATURES NEEDED
! FOR LAYER-MEAN TRANSMISSIVITIES.
!
! FOR A GIVEN CO2 MIXING RATIO AND STANDARD TEMPERATURE
! PROFILE,A TABLE OF TRANSMISSION FUNCTIONS FOR A FIXED GRID
! OF ATMOSPHERIC PRESSURES HAS BEEN PRE-CALCULATED.
! THE STANDARD TEMPERATURE PROFILE IS COMPUTED FROM THE US
! STANDARD ATMOSPHERE (1977) TABLE.ADDITIONALLY, THE
! SAME TRANSMISSION FUNCTIONS HAVE BEEN PRE-CALCULATED FOR A
! TEMPERATURE PROFILE INCREASED AND DECREASED (AT ALL LEVELS)
! BY 25 DEGREES.
! THIS PROGRAM READS IN THE PRESPECIFIED TRANSMISSION FUNCTIONS
! AND A USER-SUPPLIED PRESSURE GRID (P(I)) AND CALCULATES TRANS-
! MISSION FUNCTIONS ,TAU(P(I),P(J)), FOR ALL P(I) S AND P(J) S.
! A LOGARITHMIC INTERPOLATION SCHEME IS USED.
! THIS METHOD IS REPEATED FOR THE THREE TEMPERATURE PROFILES
! GIVEN ABOVE .THEREFORE OUTPUTS FROM THE PROGRAM ARE THREE TABLES
! OF TRANSMISSION FUNCTIONS FOR THE USER-SUPPLIED PRESSURE GRID.
! THE EXISTENCE OF THE THREE TABLES PERMITS SUBSEQUENT INTERPO-
! LATION TO A USER-SUPPLIED TEMPERATURE PROFILE USING THE METHOD
! DESCRIBED IN THE REFERENCE.SEE LIMITATIONS SECTION IF THE
! USER DESIRES TO OBTAIN ONLY 1 TABLE OF TRANSMISSIVITIES.
!
! MODIFICATIONS FOR LAYER-MEAN TRANSMISSIVITIES:
! THE PRESSURES INPUTTED ARE THE LAYER-MEAN PRESSURES,PD,
! AND THE LAYER-MEAN PRESSURES ,PLM. A SERIES OF TRANSMISSIVITIES
! (TAU(P'',PLM(J)) ARE COMPUTED AND THE INTEGRAL GIVEN IN THE
! DISCUSSION OF PURPOSE 2 IS COMPUTED.FOR PLM(I) NOT EQUAL TO
! PLM(J) SIMPSON S RULE IS USED WITH 5 POINTS. IF PLM(I)=PLM(J)
! (THE -NEARBY LAYER- CASE) A 49-POINT QUADRATURE IS USED FOR
! GREATER ACCURACY.THE OUTPUT IS IN TAULM(PLM(I),PLM(J)).
! NOTE:
! TAULM IS NOT A SYMMETRICAL MATRIX. FOR THE ARRAY ELEMENT
! TAULM(PLM(I),PLM(J)),THE INNER(FIRST,MOST RAPIDLY VARYING)
! DIMENSION IS THE VARYING LAYER-MEAN PRESSURE,PLM(I);THE OUTER
! (SECOND) DIMENSION IS THE FIXED LAYER-MEAN PRESSURE PLM(J).
! THUS THE ELEMENT TAULM(2,3) IS THE TRANSMISSION FUNCTION BETWEEN
! THE FIXED PRESSURE PLM(3) AND THE PRESSURE LAYER HAVING AN AVERAG
! PRESSURE OF PLM(2).
! ALSO NOTE THAT NO QUADRATURE IS PERFORMED OVER THE LAYER
! BETWEEN THE SMALLEST NONZERO PRESSURE AND ZERO PRESSURE;
! TAULM IS TAULM(0,PLM(J)) IN THIS CASE,AND TAULM(0,0)=1.
!
!
! REFERENCE:
! S.B.FELS AND M.D.SCHWARZKOPF,-AN EFFICIENT ACCURATE
! ALGORITHM FOR CALCULATING CO2 15 UM BAND COOLING RATES-,JOURNAL
! OF GEOPHYSICAL RESEARCH,VOL.86,NO. C2, PP.1205-1232,1981.
! MODIFICATIONS TO THE ALGORITHM HAVE BEEN MADE BY THE AUTHORS;
! CONTACT S.B.F.OR M.D.S. FOR FURTHER DETAILS.A NOTE TO J.G.R.
! IS PLANNED TO DOCUMENT THESE CHANGES.
!
! AUTHOR: M.DANIEL SCHWARZKOPF
!
! DATE: 14 JULY 1983
!
! ADDRESS:
!
! G.F.D.L.
! P.O.BOX 308
! PRINCETON,N.J.08540
! U.S.A.
! TELEPHONE: (609) 452-6521
!
! INFORMATION ON TAPE: THIS SOURCE IS THE FIRST FILE
! ON THIS TAPE.THE SIX FILES THAT FOLLOW ARE CO2 TRANS-
! MISSIVITIES FOR THE 500-850 CM-1 INTERVAL FOR CO2
! CONCENTRATIONS OF 330 PPMV (1X) ,660 PPMV (2X), AND
! 1320 PPMV (4X). THE FILES ARE ARRANGED AS FOLLOWS:
! FILE 2 1X,CONSOLIDATED USING B(250) WEIGHTING FCTN.
! FILE 3 1X,CONSOLIDATED WITH NO WEIGHTING FCTN.
! FILE 4 2X,CONSOLIDATED USING B(250) WEIGHTING FCTN.
! FILE 5 2X,CONSOLIDATED WITH NO WEIGHTING FCTN.
! FILE 6 4X,CONSOLIDATED USING B(250) WEIGHTING FCTN.
! FILE 7 4X,CONSOLIDATED WITH NO WEIGHTING FCTN.
! FILES 2,4,6 ARE RECOMMENDED FOR USE IN OBTAINING
! TRANSMISSION FUNCTIONS FOR USE IN HEATING RATE
! COMPUTATIONS;THEY CORRESPOND TO THE TRANSMISSIVITIES
! DISCUSSED IN THE 1980 PAPER.FILES 3,5,7 ARE PROVIDED
! TO FACILITATE COMPARISON WITH OBSERVATION AND WITH OTHER
! CALCULATIONS.
!
! PROGRAM LANGUAGE: FORTRAN 1977,INCLUDING PARAMETER
! AND PROGRAM STATEMENTS.THE PROGRAM IS WRITTEN ON A
! CYBER 170-730.SEE THE SECTION ON LIMITATIONS FOR
! ADAPTATIONS TO OTHER MACHINES.
!
! INPUT UNITS,FORMATS AND FORMAT STATEMENT NOS:
!
! UNIT NO VARIABLES FORMAT STATEMENT NO. TYPE
! 5 P (PURPOSE 1) (5E16.9) 201 CARDS
! 5 PD (PURPOSE 2) (5E16.9) 201 CARDS
! 5 PLM(PURPOSE 2) (5E16.9) 201 CARDS
! 5 NMETHD (I3) 202 CARDS
! 20 TRANSA (4F20.14) 102 TAPE
!NOV89
! ITAPE TRANSA (4F20.14) 102 TAPE
!NOV89
!
! OUTPUT UNITS,FORMATS AND FORMAT STATEMENT NOS:
!
! UNIT NO VARIABLES FORMAT STATEMENT NO.
! 6 TRNFCT (1X,8F15.8) 301 PRINT
! 22 TRNFCT (4F20.14) 102 TAPE
!
! PARAMETER INPUTS:
! A) NLEVLS : NLEVLS IS AN (INTEGER) PARAMETER DENOTING
! THE NUMBER OF NONZERO PRESSURE LEVELS FOR PURPOSE 1
! OR THE NUMBER OF NONZERO LAYER PRESSURES NEEDED TO
! SPECIFY THE PRESSURE LAYERS(PURPOSE 2) IN THE OUTPUT
! GRID. FOR EXAMPLE,IN PURPOSE 1,IF P=0,100,1000,NLEVLS=2.
! IF,IN PURPOSE 2,PD=0,100,500,1000,THE NUMBER OF NONZERO
! PRESSURE LAYERS=2,SO NLEVLS=2
! IN THE CODE AS WRITTEN,NLEVLS=40; THE USER SHOULD
! CHANGE THIS VALUE TO A USER-SPECIFIED VALUE.
! B) NLP1,NLP2 : INTEGER PARAMETERS DEFINED AS: NLP1=NLEVLS+1;
! NLP2=NLEVLS+2.
! SEE LIMITATIONS FOR CODE MODIFICATIONS IF PARAMETER
! STATEMENTS ARE NOT ALLOWED ON YOUR MACHINE.
!
! INPUTS:
!
! A) TRANSA : THE 109X109 GRID OF TRANSMISSION FUNCTIONS
! TRANSA IS A DOUBLE PRECISION REAL ARRAY.
!
! TRANSA IS READ FROM FILE 20. THIS FILE CONTAINS 3
! RECORDS,AS FOLLOWS:
! 1) TRANSA, STANDARD TEMPERATURE PROFILE
! 3) TRANSA, STANDARD TEMPERATURES + 25 DEG
! 5) TRANSA, STANDARD TEMPERATURES - 25 DEG
!
! B) NMETHD: AN INTEGER WHOSE VALUE IS EITHER 1 (IF CO2INT IS
! TO BE USED FOR PURPOSE 1) OR 2 (IF CO2INT IS TO BE USED FOR
! PURPOSE 2).
!
! C) P,PD,PLM :
! P IS A REAL ARRAY (LENGTH NLP1) SPECIFYING THE PRESSURE
! GRID AT WHICH TRANSMISSION FUNCTIONS ARE TO BE COMPUTED FOR
! PURPOSE 1.THE DIMENSION OF P IS IN MILLIBARS.THE
! FOLLOWING LIMITATIONS WILL BE EXPLAINED MORE
! IN THE SECTION ON LIMITATIONS: P(1) MUST BE ZERO; P(NLP1),THE
! LARGEST PRESSURE, MUST NOT EXCEED 1165 MILLIBARS.
! PD IS A REAL ARRAY (LENGTH NLP2) SPECIFYING THE PRESSURE
! LAYERS FOR WHICH LAYER-AVERAGED TRANSMISSION FUNCTIONS ARE
! TO BE COMPUTED.THE DIMENSION OF PD IS MILLIBARS.THE LIMITATIONS
! FOR PD ARE THE SAME AS FOR P,AND ARE GIVEN IN THE SECTION ON
! LIMITATIONS.
! PLM IS A REAL ARRAY (LENGTH NLP2) SPECIFYING THE LAYER-MEAN
! PRESSURES. THE DIMENSION OF PLM IS MILLIBARS. THE LIMITATIONS
! FOR PLM ARE THE SAME AS FOR P,AND ARE GIVEN IN THE SECTION ON
! LIMITATIONS.PD IS READ IN BEFORE PLM.
!
! NOTE: AGAIN,WE NOTE THAT THE USER WILL INPUT EITHER P (FOR
! PURPOSE 1) OR PD AND PLM(FOR PURPOSE 2) BUT NOT BOTH.
!
!
!
!
! LIMITATIONS:
! 1) P(1)=0.,PD(1)=0.,PLM(1)=0. THE TOP PRESSURE LEVEL
! MUST BE ZERO,OR THE TOP PRESSURE LAYER MUST BE BOUNDED BY ZERO.
! THE TOP LAYER-MEAN PRESSURE (PLM(1)) MUST BE ZERO; NO
! QUADRATURE IS DONE ON THE TOP PRESSURE LAYER.EVEN IF ONE IS
! NOT INTERESTED IN THE TRANSMISSION FUNCTION BETWEEN 0 AND P(J),
! ONE MUST INCLUDE SUCH A LEVEL.
! 2) PD(NLP2)=P(NLP1) IS LESS THAN OR EQUAL TO 1165 MB.
! EXTRAPOLATION TO HIGHER PRESSURES IS NOT POSSIBLE.
! 3) IF PROGRAM IS NOT PERMITTED ON YOUR COMPILER,
! SIMPLY DELETE THE LINE.
! 4) IF PARAMETER IS NOT PERMITTED,DO THE FOLLOWING:
! 1) DELETE ALL PARAMETER STATEMENTS IN CO2INT
! 2) AT THE POINT WHERE NMETHOD IS READ IN,ADD:
! READ (5,202) NLEVLS
! NLP1=NLEVLS+1
! NLP2=NLEVLS+2
! 3) CHANGE DIMENSION AND/OR COMMON STATEMENTS DEFINING
! ARRAYS TRNS,DELTA,P,PD,TRNFCT,PS,PDS,PLM IN CO2INT.
! THE NUMERICAL VALUE OF (NLEVLS+1) SHOULD BE INSERTED
! IN DIMENSION OR COMMON STATEMENTS FOR TRNS,DELTA,
! P,TRNFCT,PS,PLM; THE NUMERICAL VALUE OF (NLEVLS+2)
! IN DIMENSION OR COMMON STATEMENTS FOR PD,PDS.
! 5) PARAMETER (NLEVLS=40) AND THE OTHER PARAMETER
! STATEMENTS ARE WRITTEN IN CDC FORTRAN; ON OTHER MACHINES THE
! SAME STATEMENT MAY BE WRITTEN DIFFERENTLY,FOR EXAMPLE AS
! PARAMETER NLEVLS=40
! 6) -DOUBLE PRECISION- IS USED INSTEAD OF -REAL*8- ,DUE TO
! REQUIREMENTS OF CDC FORTAN.
! 7) THE STATEMENT -DO 400 KKK=1,3- CONTROLS THE NUMBER OF
! TRANSMISSIVITY OUTPUT MATRICES PORDUCED BY THE PROGRAM.TO
! PRODUCE 1 OUTPUT MATRIX,DELETE THIS STATEMENT.
!
! OUTPUT:
! A) TRNFCT IS AN (NLP1,NLP1) REAL ARRAY OF THE TRANSMISSION
! FUNCTIONS APPROPRIATE TO YOUR ARRAY. IT IS TO BE SAVED ON FILE 22.
! THE PROCEDURE FOR SAVING MAY BE MODIFIED; AS GIVEN HERE,THE
! OUTPUT IS IN CARD IMAGE FORM WITH A FORMAT OF (4F20.14).
!
! B) PRINTED OUTPUT IS A LISTING OF TRNFCT ON UNIT 6, IN
! THE FORMAT (1X,8F15.8) (FORMAT STATEMENT 301). THE USER MAY
! MODIFY OR ELIMINATE THIS AT WILL.
!
! ************ FUNCTION INTERPOLATER ROUTINE *****************
!
!
! ****** THE FOLLOWING PARAMETER GIVES THE NUMBER OF *******
! ****** DATA LEVELS IN THE MODEL *******
! ****************************************************************
! ****************************************************************
COMMON/INPUT/P1,P2,TRNSLO,IA,JA,N
! COMMON/PRESS/PA(109)
! COMMON/TRAN/ TRANSA(109,109)
! COMMON / OUTPUT / TRNS(NLP1,NLP1)
! COMMON/INPUTP/P(NLP1),PD(NLP2)
DIMENSION TRNS(NLP1,NLP1)
DIMENSION P(NLP1),PD(NLP2)
DIMENSION PS(NLP1),PDS(NLP2),PLM(NLP1)
DIMENSION NRTAB(3)
DIMENSION T15A(NLP2,2),T15B(NLP1)
DIMENSION T22(NLP1,NLP1,3)
LOGICAL , EXTERNAL :: wrf_dm_on_monitor
DATA NRTAB/1,2,4/
!***********************************
! THE FOLLOWING ARE THE INPUT FORMATS
100 FORMAT (4F20.14)
743 FORMAT (F20.14)
201 FORMAT (5E16.9)
202 FORMAT (I3)
!O222 203 FORMAT (F12.6,I2)
203 FORMAT (F12.6)
! THE FOLLOWING ARE THE OUTPUT FORMATS
102 FORMAT (4F20.14)
301 FORMAT (1X,8F15.8)
!
!CC REWIND 15
!CC REWIND 20
!NOV89
REWIND ITAPE
!NOV89
!CC REWIND 22
!
! CALCULATION OF PA -THE -TABLE- OF 109 GRID PRESSURES
! NOTE-THIS CODE MUST NOT BE CHANGED BY THE USER^^^^^^^^^
PA(1)=0.
FACT15=10.**(1./15.)
FACT30=10.**(1./30.)
PA(2)=1.0E-3
DO 231 I=2,76
PA(I+1)=PA(I)*FACT15
231 CONTINUE
DO 232 I=77,108
PA(I+1)=PA(I)*FACT30
232 CONTINUE
!
N=25
NLV=NLEVLS
NLP1V=NLP1
NLP2V=NLP2
! READ IN THE CO2 MIXING RATIO(IN UNITS OF 330 PPMV),AND AN INDEX
! GIVING THE FREQUENCY RANGE OF THE LBL DATA
!O222 READ (5,203) RATIO,IR
!CC IR = 1
!CC READ (5,203) RATIO
!O222 ***********************************
!***VALUES FOR IR*****
! IR=1 CONSOL. LBL TRANS. =490-850
! IR=2 CONSOL. LBL TRANS. =490-670
! IR=3 CONSOL. LBL TRANS. =670-850
! IR=4 CONSOL. LBL TRANS. =2270-2380
!*** IR MUST BE 1,2,3 OR 4 FOR THE PGM. TO WORK
! ALSO READ IN THE METHOD NO.(1 OR 2)
!CC READ (5,202) NMETHD
IF (RATIO.EQ.1.0) GO TO 621
CALL wrf_error_fatal( 'SUBROUTINE CO2INT: 8746' )
!NOV89 621 ITAP1=20
621 ITAP1=ITAPE
!NOV89
NTAP=1
IF (NMETHD.EQ.2) GO TO 502
! *****CARDS FOR PURPOSE 1(NMETHD=1)
!CC READ (15,201) (P(I),I=1,NLP1)
DO 300 I=1,NLP1
P(I)=T15B(I)
300 CONTINUE
DO 801 I=1,NLP1
PS(I)=P(I)
801 CONTINUE
GO TO 503
502 CONTINUE
! *****CARDS FOR PURPOSE 2(NMETHD=2)
!CC READ (15,201) (PD(I),I=1,NLP2)
!CC READ (15,201) (PLM(I),I=1,NLP1)
DO 303 I=1,NLP2
PD(I)=T15A(I,1)
303 CONTINUE
DO 302 I=1,NLP1
PLM(I)=T15A(I,2)
302 CONTINUE
DO 802 I=1,NLP1
PDS(I)=PD(I+1)
PS(I)=PLM(I)
802 CONTINUE
!
503 CONTINUE
! *****DO LOOP CONTROLLING NUMBER OF OUTPUT MATRICES
!NOV89
!NOV89 DO 400 KKK=1,3
ICLOOP = 3
IF (IR.EQ.4) ICLOOP = 1
DO 400 KKK=1,ICLOOP
!NOV89
! **********************
IF (NMETHD.EQ.2) GO TO 505
! *****CARDS FOR PURPOSE 1(NMETHD=1)
DO 803 I=1,NLP1
P(I)=PS(I)
803 CONTINUE
GO TO 506
505 CONTINUE
! *****CARDS FOR PURPOSE 2(NMETHD=2)
DO 804 I=1,NLP1
PD(I)=PDS(I)
P(I)=PS(I)
804 CONTINUE
!
506 CONTINUE
IA=108
IAP=IA+1
!NOV89 IF (NTAP.EQ.1) READ (20,100) ((TRANSA(I,J),I=1,109),J=1,109)
!mp IF (NTAP.EQ.1) READ (ITAPE,100) ((TRANSA(I,J),I=1,109),J=1,109)
IF (NTAP.EQ.1) THEN
IF ( wrf_dm_on_monitor() ) READ (ITAPE,743) ((TRANSA(I,J),I=1,109),J=1,109)
CALL wrf_dm_bcast_bytes ( TRANSA , size ( TRANSA ) * RWORDSIZE )
ENDIF
!mp IF (NTAP.EQ.1) READ (ITAPE,100) (tmp(I),I=1,11881
!mp
do J=109,1,-6
!mp write(6,697)(TRANSA(I,J),I=5,105,10)
enddo
697 format(11(f5.3,1x))
!mp
!NOV89
DO 4 I=1,IAP
TRANSA(I,I)=1.0
4 CONTINUE
CALL COEINT(RATIO,IR)
DO 805 I=1,NLP1
DO 805 J=1,NLP1
TRNS(J,I)=1.00
805 CONTINUE
DO 10 I=1,NLP1
DO 20 J=1,I
IF (I.EQ.J) GO TO 20
P1=P(J)
P2=P(I)
CALL SINTR2
TRNS(J,I)=TRNSLO
20 CONTINUE
10 CONTINUE
DO 47 I=1,NLP1
DO 47 J=I,NLP1
TRNS(J,I)=TRNS(I,J)
47 CONTINUE
! *****THIS IS THE END OF PURPOSE 1 CALCULATIONS
IF (NMETHD.EQ.1) GO TO 2872
!
DO 51 J=1,NLP1
DO 52 I=2,NLP1
IA=I
JA=J
N=25
IF (I.NE.J) N=3
CALL QUADSR(NLV,NLP1V,NLP2V,P,PD,TRNS)
52 CONTINUE
51 CONTINUE
! *****THIS IS THE END OF PURPOSE 2 CALCULATIONS
2872 CONTINUE
!
!+++ WRITE (6,301) ((TRNS(I,J),I=1,NLP1),J=1,NLP1)
!CC WRITE (22,102) ((TRNS(I,J),I=1,NLP1),J=1,NLP1)
DO 304 J=1,NLP1
DO 304 I=1,NLP1
T22(I,J,KKK) = TRNS(I,J)
304 CONTINUE
400 CONTINUE
RETURN
END SUBROUTINE CO2INT
!CCC PROGRAM CO2IN1
SUBROUTINE CO2IN1(T20,T21,T66,IQ,L,LP1) 2
! CO2IN1=CO2INS FOR METHOD 1
! *********************************************************
! SAVE DATA ON PERMANENT DATA SET DENOTED BY CO222 ***
! ..... K.CAMPANA MARCH 1988,OCTOBER 1988
! ..... K.CAMPANA DECEMBER 88 CLEANED UP FOR LAUNCHER
! *********************************************************
DIMENSION T20(LP1,LP1,3),T21(LP1,LP1,3),T66(L,6)
DIMENSION DCDT8(LP1,LP1),DCDT10(LP1,LP1),CO2PO(LP1,LP1), &
CO2800(LP1,LP1),CO2PO1(LP1,LP1),CO2801(LP1,LP1),CO2PO2(LP1,LP1), &
CO2802(LP1,LP1),N(LP1),D2CT8(LP1,LP1),D2CT10(LP1,LP1)
ITIN=20
ITIN1=21
!O222 LATEST CODE HAS IQ=1
!CC IQ=4
1011 FORMAT (4F20.14)
!CC READ (ITIN,1011) ((CO2PO(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN1,1011) ((CO2800(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN,1011) ((CO2PO1(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN1,1011) ((CO2801(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN,1011) ((CO2PO2(I,J),I=1,LP1),J=1,LP1)
!CC READ (ITIN1,1011) ((CO2802(I,J),I=1,LP1),J=1,LP1)
DO 300 J=1,LP1
DO 300 I=1,LP1
CO2PO(I,J) = T20(I,J,1)
!NOV89
IF (IQ.EQ.5) GO TO 300
!NOV89
CO2PO1(I,J) = T20(I,J,2)
CO2PO2(I,J) = T20(I,J,3)
300 CONTINUE
DO 301 J=1,LP1
DO 301 I=1,LP1
CO2800(I,J) = T21(I,J,1)
!NOV89
IF (IQ.EQ.5) GO TO 301
!NOV89
CO2801(I,J) = T21(I,J,2)
CO2802(I,J) = T21(I,J,3)
301 CONTINUE
!***THE FOLLOWING CODE IS REWRITTEN SO THAT THE RADIATIVE BANDS
! ARE:
! IQ=1 560-800 (CONSOL.=490-850)
! IQ=2 560-670 (CONSOL.=490-670)
! IQ=3 670-800 (CONSOL.=670-850)
! IQ=4 560-760 (ORIGINAL CODE) (CONSOL.=490-850)
!NOV89
! IQ=5 2270-2380 (CONSOL.=2270-2380)
!NOV89
! THE FOLLOWING LOOP OBTAINS TRANSMISSION FUNCTIONS FOR BANDS
! USED IN RADIATIVE MODEL CALCULATIONS,WITH THE EQUIVALENT
! WIDTHS KEPT FROM THE ORIGINAL CONSOLIDATED CO2 TF S.
IF (IQ.EQ.1) THEN
C1=1.5
C2x=0.5
ENDIF
IF (IQ.EQ.2) THEN
C1=18./11.
C2x=7./11.
ENDIF
IF (IQ.EQ.3) THEN
C1=18./13.
C2x=5./13.
ENDIF
IF (IQ.EQ.4) THEN
C1=1.8
C2x=0.8
ENDIF
!NOV89
IF (IQ.EQ.5) THEN
C1=1.0
C2x=0.0
ENDIF
!NOV89
DO 1021 I=1,LP1
DO 1021 J=1,LP1
CO2PO(J,I)=C1*CO2PO(J,I)-C2x
CO2800(J,I)=C1*CO2800(J,I)-C2x
!NOV89
IF (IQ.EQ.5) GO TO 1021
!NOV89
CO2PO1(J,I)=C1*CO2PO1(J,I)-C2x
CO2801(J,I)=C1*CO2801(J,I)-C2x
CO2PO2(J,I)=C1*CO2PO2(J,I)-C2x
CO2802(J,I)=C1*CO2802(J,I)-C2x
1021 CONTINUE
!NOV89
IF (IQ.GE.1.AND.IQ.LE.4) THEN
!NOV89
DO 1 J=1,LP1
DO 1 I=1,LP1
DCDT8(I,J)=.02*(CO2801(I,J)-CO2802(I,J))*100.
DCDT10(I,J)=.02*(CO2PO1(I,J)-CO2PO2(I,J))*100.
D2CT8(I,J)=.0016*(CO2801(I,J)+CO2802(I,J)-2.*CO2800(I,J))*1000.
D2CT10(I,J)=.0016*(CO2PO1(I,J)+CO2PO2(I,J)-2.*CO2PO(I,J))*1000.
1 CONTINUE
!NOV89
ENDIF
!NOV89
!O222 *********************************************************
!CC REWIND 66
! SAVE CDTM51,CO2M51,C2DM51,CDTM58,CO2M58,C2DM58..ON TEMPO FILE
!CC WRITE (66) (DCDT10(I,I+1),I=1,L)
!CC WRITE (66) (CO2PO(I,I+1),I=1,L)
!CC WRITE (66) (D2CT10(I,I+1),I=1,L)
!CC WRITE (66) (DCDT8(I,I+1),I=1,L)
!CC WRITE (66) (CO2800(I,I+1),I=1,L)
!CC WRITE (66) (D2CT8(I,I+1),I=1,L)
!CC REWIND 66
!O222 *********************************************************
DO 400 I=1,L
T66(I,2) = CO2PO(I,I+1)
T66(I,5) = CO2800(I,I+1)
!NOV89
IF (IQ.EQ.5) GO TO 400
!NOV89
T66(I,1) = DCDT10(I,I+1)
T66(I,3) = D2CT10(I,I+1)
T66(I,4) = DCDT8(I,I+1)
T66(I,6) = D2CT8(I,I+1)
400 CONTINUE
RETURN
END SUBROUTINE CO2IN1
!CCC PROGRAM PTZ - COURTESY OF DAN SCHWARZKOPF,GFDL DEC 1987....
SUBROUTINE CO2PTZ(SGTEMP,T41,T42,T43,T44,SGLVNU,SIGLNU, & 2,14
SFULL,SHALF,PPTOP,LREAD,NL,NLP,NLP2)
!
! ** THIS PROGRAM CALCULATES TEMPERATURES ,H2O MIXING RATIOS
! ** AND O3 MIXING RATIOS BY USING AN ANALYTICAL
! ** FUNCTION WHICH APPROXIMATES
! ** THE US STANDARD (1976). THIS IS
! ** CALCULATED IN FUNCTION 'ANTEMP', WHICH IS CALLED BY THE
! ** MAIN PROGRAM. THE FORM OF THE ANALYTICAL FUNCTION WAS
! ** SUGGESTED TO ME IN 1971 BY RICHARD S. LINDZEN.
! ******************************************************************
! CODE TO SAVE STEMP,GTEMP ON DATA SET,BRACKETED BY CO222 **
! ....K. CAMPANA MARCH 88,OCTOBER 88
DIMENSION SGTEMP(NLP,2),T41(NLP2,2),T42(NLP), &
T43(NLP2,2),T44(NLP)
DIMENSION SGLVNU(NLP),SIGLNU(NL)
DIMENSION SFULL(NLP),SHALF(NL)
! ******************************************************************
!
!*****THIS VERSION IS ONLY USABLE FOR 1976 US STD ATM AND OBTAINS
! QUANTITIES FOR CO2 INTERPOLATION AND INSERTION INTO OPERA-
! TIONAL RADIATION CODES
!
CHARACTER*20 PROFIL
DIMENSION PRESS(NLP),TEMP(NLP),ALT(NLP),WMIX(NLP),O3MIX(NLP)
DIMENSION WMXINT(NLP,4),WMXOUT(NLP2),OMXINT(NLP,4),OMXOUT(NLP2)
DIMENSION PD(NLP2),GTEMP(NLP)
DIMENSION PRS(NLP),TEMPS(NLP),PRSINT(NLP),TMPINT(NLP,4),A(NLP,4)
DIMENSION PROUT(NLP2),TMPOUT(NLP2),TMPFLX(NLP2),TMPMID(NLP2)
!
!
DATA PROFIL/ &
'US STANDARD 1976'/
DATA PSMAX/1013.250/
!
! ** NTYPE IS AN INTEGER VARIABLE WHICH HAS THE FOLLOWING
! ** VALUES: 0 =SIGMA LEVELS ARE USED; 1= SKYHI L40 LEVELS
! ** ARE USED; 2 = SKYHI L80 LEVELS ARE USED. DEFAULT: 0
!
NTYPE=0
!O222 READ (*,*) NTYPE
5 NLEV=NL
DELZAP=0.5
R=8.31432
G0=9.80665
ZMASS=28.9644
AA=6356.766
ALT(1)=0.0
TEMP(1)=ANTEMP(6,0.0)
!*******DETERMINE THE PRESSURES (PRESS)
PSTAR=PSMAX
!
!*** LTOP COMPUTATION MOVED FROM MODEL INITIALIZATION
!
LTOP(1)=0
LTOP(2)=0
LTOP(3)=0
DO 30 N=1,NL
PCLD=(PSTAR-PPTOP*10.)*SHALF(N)+PPTOP*10.
IF(PCLD.GE.642.)LTOP(1)=N
IF(PCLD.GE.350.)LTOP(2)=N
IF(PCLD.GE.150.)LTOP(3)=N
! PRINT *,N,PCLD,SHALF(N),PSTAR,PPTOP
30 CONTINUE
!
!O222 IF (NTYPE.EQ.1) CALL SKYP(PSTAR,PD,GTEMP)
!O222 IF (NTYPE.EQ.2) CALL SKY80P(PSTAR,PD,GTEMP)
!O222 IF (NTYPE.EQ.0) CALL SIGP(PSTAR,PD,GTEMP)
!CC---- CALL SIGP(PSTAR,PD,GTEMP)
NLM=NL-1
CALL SIGP(PSTAR,PD,GTEMP,T41,T42,T43,T44,SGLVNU,SIGLNU, &
SFULL,SHALF,PPTOP,LREAD,NL,NLP,NLM,NLP2)
PD(NLP2)=PSTAR
DO 40 N=1,NLP
PRSINT(N)=PD(NLP2+1-N)
40 CONTINUE
! *** CALCULATE TEMPS FOR SEVERAL PRESSURES TO DO QUADRATURE
DO 504 NQ=1,4
DO 505 N=2,NLP
505 PRESS(N)=PRSINT(N)+0.25*(NQ-1)*(PRSINT(N-1)-PRSINT(N))
PRESS(1)=PRSINT(1)
!*********************
DO 100 N=1,NLEV
!
! ** ESTABLISH COMPUTATATIONAL LEVELS BETWEEN USER LEVELS AT
! ** INTERVALS OF APPROXIMATELY 'DELZAP' KM.
!
DLOGP=7.0*ALOG(PRESS(N)/PRESS(N+1))
NINT=DLOGP/DELZAP
NINT=NINT+1
ZNINT=NINT
! G=G0
DZ=R*DLOGP/(7.0*ZMASS*G0*ZNINT)
HT=ALT(N)
!
! ** CALCULATE HEIGHT AT NEXT USER LEVEL BY MEANS OF
! ** RUNGE-KUTTA INTEGRATION.
!
DO 200 M=1,NINT
RK1=ANTEMP(6,HT)*DZ
RK2=ANTEMP(6,HT+0.5*RK1)*DZ
RK3=ANTEMP(6,HT+0.5*RK2)*DZ
RK4=ANTEMP(6,HT+RK3)*DZ
!mp write(6,*) 'RK values,DZ ', RK1,RK2,RK3,RK4,DZ
HT=HT+0.16666667*(RK1+RK2+RK2+RK3+RK3+RK4)
200 CONTINUE
ALT(N+1)=HT
TEMP(N+1)=ANTEMP(6,HT)
100 CONTINUE
DO 506 N=1,NLP
TMPINT(N,NQ)=TEMP(N)
A(N,NQ)=ALT(N)
506 CONTINUE
504 CONTINUE
!O222 *****************************************************
!***OUTPUT TEMPERATURES
!O222 *****************************************************
DO 901 N=1,NLP
SGTEMP(N,1) = TMPINT(NLP2-N,1)
901 CONTINUE
!O222 *****************************************************
!***OUTPUT GTEMP
!O222 *****************************************************
DO 902 N=1,NLP
SGTEMP(N,2) = GTEMP(N)
902 CONTINUE
!O222 *****************************************************
RETURN
END SUBROUTINE CO2PTZ
FUNCTION PATH(A,B,C,E) 4
!....
! DOUBLE PRECISION XA,CA
! COMMON/COEFS/XA(109),CA(109),ETA(109),SEXPV(109),CORE,UEXP,SEXP
PEXP=1./SEXP
PATH=((A-B)**PEXP*(A+B+C))/(E*(A+B+C)+(A-B)**(PEXP-1.))
RETURN
END FUNCTION PATH
!CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
SUBROUTINE QINTRP(XM,X0,XP,FM,F0,FP,X,F) 8
!....
! DOUBLE PRECISION FM,F0,FP,F,D1,D2,B,A,DEL
D1=(FP-F0)/(XP-X0)
D2=(FM-F0)/(XM-X0)
B=(D1-D2)/(XP-XM)
A=D1-B*(XP-X0)
DEL=(X-X0)
F=F0+DEL*(A+DEL*B)
RETURN
END SUBROUTINE QINTRP
SUBROUTINE QUADSR(NLV,NLP1V,NLP2V,P,PD,TRNS) 2,2
COMMON/INPUT/P1,P2,TRNSLO,IA,JA,N
DIMENSION P(NLP1V),PD(NLP2V),TRNS(NLP1V,NLP1V)
DIMENSION WT(101)
N2=2*N
N2P=2*N+1
! *****WEIGHTS ARE CALCULATED
WT(1)=1.
DO 21 I=1,N
WT(2*I)=4.
WT(2*I+1)=1.
21 CONTINUE
IF (N.EQ.1) GO TO 25
DO 22 I=2,N
WT(2*I-1)=2.
22 CONTINUE
25 CONTINUE
TRNSNB=0.
DP=(PD(IA)-PD(IA-1))/N2
PFIX=P(JA)
DO 1 KK=1,N2P
PVARY=PD(IA-1)+(KK-1)*DP
IF (PVARY.GE.PFIX) P2=PVARY
IF (PVARY.GE.PFIX) P1=PFIX
IF (PVARY.LT.PFIX) P1=PVARY
IF (PVARY.LT.PFIX) P2=PFIX
CALL SINTR2
TRNSNB=TRNSNB+TRNSLO*WT(KK)
1 CONTINUE
TRNS(IA,JA)=TRNSNB*DP/(3.*(PD(IA)-PD(IA-1)))
RETURN
END SUBROUTINE QUADSR
!---------------------------------------------------------------------
SUBROUTINE SIGP(PSTAR,PD,GTEMP,T41,T42,T43,T44,SGLVNU,SIGLNU, & 2
SIGLV,SIGLY,PPTOP,LREAD,KD,KP,KM,KP2)
DIMENSION Q(KD),QMH(KP),PD(KP2),PLM(KP),GTEMP(KP),PDT(KP2)
DIMENSION SIGLY(KD),SIGLV(KP)
DIMENSION CI(KP),SGLVNU(KP),DEL(KD),SIGLNU(KD),CL(KD),RPI(KM)
DIMENSION IDATE(4)
DIMENSION T41(KP2,2),T42(KP), &
T43(KP2,2),T44(KP)
! integer :: retval
! character(50) :: prsmid='prsmid'
!CC 18 LEVEL SIGMAS FOR NMC MRF(NEW) MODEL
!CC DATA Q/.021,.074,.124,.175,.225,.275,.325,.375,.425,.497, &
!CC .594,.688,.777,.856,.920,.960,.981,.995/
! FOR SIGMA MODELS,Q=SIGMA,QMH=0.5(Q(I)+Q(I+1),
! PD=Q*PSS,PLM=QMH*PSS.PSS=SURFACE PRESSURE(SPEC.)
!
!..... GET NMC SIGMA STRUCTURE
!CC IF (LREAD.GT.0) GO TO 914
!--- PPTOP IS MODEL TOP PRESSURE IN CB....
! SIGMA DATA IS BOTTOM OF ATMOSPHERE TO T.O.A.....
!cccc PPTOP=5.0
! READ(11,PPTOP,END=12321)
12321 CONTINUE
! WRITE(6,88221)PPTOP,KD,KP
!88221 FORMAT(' ENTER SIGP PPTOP=',E12.5,' KD=',I2,' KP=',I2)
! open(unit=23,file='fort.23',form='unformatted' &
! , access='sequential')
! REWIND 23
! READ(23)SIGLY
! DO KKK=1,KD
! SIGLY(KKK)=1.-(FLOAT(KKK)-0.5)/KD
! END DO
! WRITE(6,88222)
!88222 FORMAT(' READ AETA')
! DO 37821 LLL=1,KD
! WRITE(6,37820)LLL,SIGLY(LLL)
!37820 FORMAT(' L=',I2,' AETA=',E12.5)
!37821 CONTINUE
! READ(23)SIGLV
! DO KKK=1,KP
! SIGLV(KKK)=1.-(FLOAT(KKK-1))/KD
! END DO
! WRITE(6,88223)
!88223 FORMAT(' READ ETA')
! PRINT 704,(SIGLY(K),K=1,KD)
! PRINT 704,(SIGLV(K),K=1,KP)
! DO 37823 LLL=1,KP
! WRITE(6,37822)LLL,SIGLV(LLL)
!37822 FORMAT(' L=',I2,' ETA=',E12.5)
!37823 CONTINUE
701 FORMAT(F6.2)
702 FORMAT(7F10.6)
IF (PPTOP.LE.0.) GO TO 708
PSFC=100.
!--- IF PTOP NOT EQUAL TO ZERO ADJUST SIGMA SO AS TO GET PROPER STD ATM
! VERTICAL LOCATION
DO 706 K=1,KD
SIGLY(K) = (SIGLY(K)*(PSFC-PPTOP)+PPTOP)/PSFC
706 CONTINUE
DO 707 K=1,KP
SIGLV(K) = (SIGLV(K)*(PSFC-PPTOP)+PPTOP)/PSFC
707 CONTINUE
708 CONTINUE
! PRINT 703,PPTOP
! PRINT 704,(SIGLY(K),K=1,KD)
! PRINT 704,(SIGLV(K),K=1,KP)
703 FORMAT(1H ,'PTOP =',F6.2)
704 FORMAT(1H ,7F10.6)
DO 913 K=1,KP
SGLVNU(K) = SIGLV(K)
IF (K.LE.KD) SIGLNU(K) = SIGLY(K)
913 CONTINUE
DO 77 K=1,KD
Q(K) = SIGLNU(KD+1-K)
77 CONTINUE
PSS= 1013250.
QMH(1)=0.
QMH(KP)=1.
DO 1 K=2,KD
QMH(K)=0.5*(Q(K-1)+Q(K))
1 CONTINUE
PD(1)=0.
PD(KP2)=PSS
DO 2 K=2,KP
PD(K)=Q(K-1)*PSS
2 CONTINUE
! call int_get_fresh_handle(retval)
! close(retval)
! write(0,*)' before open in CO2O3'
! open(unit=retval,file=prsmid,form='UNFORMATTED',iostat=ier)
! write(0,*)' after open1'
! do k=1,62
! write(retval)pd(k)
! enddo
! close(retval)
PLM(1)=0.
DO 3 K=1,KM
PLM(K+1)=0.5*(PD(K+1)+PD(K+2))
3 CONTINUE
PLM(KP)=PSS
DO 4 K=1,KD
GTEMP(K)=PD(K+1)**0.2*(1.+PD(K+1)/30000.)**0.8/1013250.
4 CONTINUE
GTEMP(KP)=0.
!+++ WRITE (6,100) (GTEMP(K),K=1,KD)
!+++ WRITE (6,100) (PD(K),K=1,KP2)
!+++ WRITE (6,100) (PLM(K),K=1,KP)
!***TAPES 41,42 ARE OUTPUT TO THE CO2 INTERPOLATION PROGRAM (PS=1013MB)
! THE FOLLOWING PUTS P-DATA INTO MB
DO 11 I=1,KP
PD(I)=PD(I)*1.0E-3
PLM(I)=PLM(I)*1.0E-3
11 CONTINUE
PD(KP2)=PD(KP2)*1.0E-3
!CC WRITE (41,101) (PD(K),K=1,KP2)
!CC WRITE (41,101) (PLM(K),K=1,KP)
!CC WRITE (42,101) (PLM(K),K=1,KP)
DO 300 K=1,KP2
T41(K,1) = PD(K)
300 CONTINUE
DO 301 K=1,KP
T41(K,2) = PLM(K)
T42(K) = PLM(K)
301 CONTINUE
!***STORE AS PDT,SO THAT RIGHT PD IS RETURNED TO PTZ
DO 12 I=1,KP2
PDT(I)=PD(I)
12 CONTINUE
!***SECOND PASS: PSS=810MB,GTEMP NOT COMPUTED
PSS=0.8*1013250.
QMH(1)=0.
QMH(KP)=1.
DO 201 K=2,KD
QMH(K)=0.5*(Q(K-1)+Q(K))
201 CONTINUE
PD(1)=0.
PD(KP2)=PSS
DO 202 K=2,KP
PD(K)=Q(K-1)*PSS
202 CONTINUE
PLM(1)=0.
DO 203 K=1,KM
PLM(K+1)=0.5*(PD(K+1)+PD(K+2))
203 CONTINUE
PLM(KP)=PSS
!+++ WRITE (6,100) (PD(K),K=1,KP2)
!+++ WRITE (6,100) (PLM(K),K=1,KP)
!***TAPES 43,44 ARE OUTPUT TO THE CO2 INTERPOLATION PROGRAM(PS=810 MB)
! THE FOLLOWING PUTS P-DATA INTO MB
DO 211 I=1,KP
PD(I)=PD(I)*1.0E-3
PLM(I)=PLM(I)*1.0E-3
211 CONTINUE
PD(KP2)=PD(KP2)*1.0E-3
!CC WRITE (43,101) (PD(K),K=1,KP2)
!CC WRITE (43,101) (PLM(K),K=1,KP)
!CC WRITE (44,101) (PLM(K),K=1,KP)
DO 302 K=1,KP2
T43(K,1) = PD(K)
302 CONTINUE
DO 303 K=1,KP
T43(K,2) = PLM(K)
T44(K) = PLM(K)
303 CONTINUE
!***RESTORE PD
DO 212 I=1,KP2
PD(I)=PDT(I)
212 CONTINUE
100 FORMAT (1X,5E20.13)
101 FORMAT (5E16.9)
RETURN
END SUBROUTINE SIGP
!---------------------------------------------------------------------
SUBROUTINE SINTR2 4,8
!....
! IMPLICIT DOUBLE PRECISION (A-H,O-Z)
! REAL P1,P2,PA,TRNSLO,CORE,TRANSA,PATH,UEXP,SEXP,ETA,SEXPV
COMMON/INPUT/P1,P2,TRNSLO,IA,JA,N
! COMMON/PRESS/ PA(109)
! COMMON/TRAN/ TRANSA(109,109)
! COMMON/COEFS/XA(109),CA(109),ETA(109),SEXPV(109),CORE,UEXP,SEXP
DO 70 L=1,109
IP1=L
IF (P2-PA(L)) 65,65,70
70 CONTINUE
65 I=IP1-1
IF (IP1.EQ.1) IP1=2
IF (I.EQ.0) I=1
DO 80 L=1,109
JP1=L
IF (P1-PA(L)) 75,75,80
80 CONTINUE
75 J=JP1-1
IF (JP1.EQ.1) JP1=2
IF (J.EQ.0) J=1
JJJ=J
III=I
J=JJJ
JP1=J+1
I=III
IP1=I+1
! DETERMINE ETAP,THE VALUE OF ETA TO USE BY LINEAR INTERPOLATION
! FOR PETA(=0.5*(P1+P2))
PETA=P2
DO 90 L=1,109
IETAP1=L
IF (PETA-PA(L)) 85,85,90
90 CONTINUE
85 IETA=IETAP1-1
IF (IETAP1.EQ.1) IETAP1=2
IF (IETA.EQ.0) IETA=1
ETAP=ETA(IETA)+(PETA-PA(IETA))*(ETA(IETAP1)-ETA(IETA))/ &
(PA(IETAP1)-PA(IETA))
SEXP=SEXPV(IETA)+(PETA-PA(IETA))*(SEXPV(IETAP1)- &
SEXPV(IETA))/ (PA(IETAP1)-PA(IETA))
PIPMPI=PA(IP1)-PA(I)
UP2P1=(PATH(P2,P1,CORE,ETAP))**UEXP
IF (I-J) 126,126,127
126 CONTINUE
TRIP=(CA(IP1)*DLOG(1.0D0+XA(IP1)*UP2P1))**(SEXP/UEXP)
TRI=(CA(I)*DLOG(1.0D0+XA(I)*UP2P1))**(SEXP/UEXP)
TRNSLO=1.0D0-((PA(IP1)-P2)*TRI+(P2-PA(I))*TRIP)/PIPMPI
GO TO 128
127 TIJ=TRANSA(I,J)
TIPJ=TRANSA(I+1,J)
TIJP=TRANSA(I,J+1)
TIPJP=TRANSA(I+1,J+1)
UIJ=(PATH(PA(I),PA(J),CORE,ETAP))**UEXP
UIPJ=(PATH(PA(I+1),PA(J),CORE,ETAP))**UEXP
UIJP=(PATH(PA(I),PA(J+1),CORE,ETAP))**UEXP
UIPJP=(PATH(PA(I+1),PA(J+1),CORE,ETAP))**UEXP
PRODI=CA(I)*XA(I)
PRODIP=CA(I+1)*XA(I+1)
PROD=((PA(I+1)-P2)*PRODI+(P2-PA(I))*PRODIP)/PIPMPI
XINT=((PA(I+1)-P2)*XA(I)+(P2-PA(I))*XA(I+1))/PIPMPI
CINT=PROD/XINT
AIJ=(CINT*DLOG(1.0D0+XINT*UIJ))**(SEXP/UEXP)
AIJP=(CINT*DLOG(1.0D0+XINT*UIJP))**(SEXP/UEXP)
AIPJ=(CINT*DLOG(1.0D0+XINT*UIPJ))**(SEXP/UEXP)
AIPJP=(CINT*DLOG(1.0D0+XINT*UIPJP))**(SEXP/UEXP)
EIJ=TIJ+AIJ
EIPJ=TIPJ+AIPJ
EIJP=TIJP+AIJP
EIPJP=TIPJP+AIPJP
DTDJ=(EIJP-EIJ)/(PA(J+1)-PA(J))
DTDPJ=(EIPJP-EIPJ)/(PA(J+1)-PA(J))
EPIP1=EIJ+DTDJ*(P1-PA(J))
EPIPP1=EIPJ+DTDPJ*(P1-PA(J))
EPP2P1=((PA(I+1)-P2)*EPIP1+(P2-PA(I))*EPIPP1)/PIPMPI
TRNSLO=EPP2P1-(CINT*DLOG(1.0D0+XINT*UP2P1))**(SEXP/UEXP)
IF (I.GE.108.OR.J.GE.108) GO TO 350
IF (I-J-2) 350,350,355
355 CONTINUE
TIP2J=TRANSA(I+2,J)
TIP2JP=TRANSA(I+2,J+1)
TI2J2=TRANSA(I+2,J+2)
TIJP2=TRANSA(I,J+2)
TIPJP2=TRANSA(I+1,J+2)
UIP2J=(PATH(PA(I+2),PA(J),CORE,ETAP))**UEXP
UIJP2=(PATH(PA(I),PA(J+2),CORE,ETAP))**UEXP
UIPJP2=(PATH(PA(I+1),PA(J+2),CORE,ETAP))**UEXP
UI2J2=(PATH(PA(I+2),PA(J+2),CORE,ETAP))**UEXP
UIP2JP=(PATH(PA(I+2),PA(J+1),CORE,ETAP))**UEXP
AIJP2=(CINT*DLOG(1.0D0+XINT*UIJP2))**(SEXP/UEXP)
AIPJP2=(CINT*DLOG(1.0D0+XINT*UIPJP2))**(SEXP/UEXP)
AIP2J=(CINT*DLOG(1.0D0+XINT*UIP2J))**(SEXP/UEXP)
AIP2JP=(CINT*DLOG(1.0D0+XINT*UIP2JP))**(SEXP/UEXP)
AI2J2=(CINT*DLOG(1.0D0+XINT*UI2J2))**(SEXP/UEXP)
EIP2J=TIP2J+AIP2J
EIP2JP=TIP2JP+AIP2JP
EIJP2=TIJP2+AIJP2
EIPJP2=TIPJP2+AIPJP2
EI2J2=TI2J2+AI2J2
CALL QINTRP(PA(J),PA(J+1),PA(J+2),EIJ,EIJP,EIJP2,P1,EI)
CALL QINTRP(PA(J),PA(J+1),PA(J+2),EIPJ,EIPJP,EIPJP2,P1,EP)
CALL QINTRP(PA(J),PA(J+1),PA(J+2),EIP2J,EIP2JP,EI2J2,P1,EP2)
CALL QINTRP(PA(I),PA(I+1),PA(I+2),EI,EP,EP2,P2,EPSIL)
TRNSLO=EPSIL-(CINT*DLOG(1.0D0+XINT*UP2P1))**(SEXP/UEXP)
350 CONTINUE
128 CONTINUE
205 CONTINUE
RETURN
END SUBROUTINE SINTR2
SUBROUTINE CO2O3(SFULL,SHALF,PPTOP,L,LP1,LP2) 3,44
!CCC PROGRAM CO2O3 = CONSOLIDATION OF A NUMBER OF DAN SCHWARZKOPF,GFDL
! CODES TO PRODUCE A FILE OF CO2 HGT DATA
! FOR ANY VERTICAL COORDINATE (READ BY SUBROUTINE
! CONRAD IN THE GFDL RADIATION CODES)-K.A.C. JUN89.
!NOV89--UPDATED (NOV 89) FOR LATEST GFDL LW RADIATION.....K.A.C.
LOGICAL :: opened
LOGICAL , EXTERNAL :: wrf_dm_on_monitor
CHARACTER*80 errmess
! integer :: retval,kk,ka,kb
! character(50) :: co2='co2'
INTEGER etarad_unit61, etarad_unit62, etarad_unit63,IERROR
DIMENSION SGTEMP(LP1,2),CO2D1D(L,6),CO2D2D(LP1,LP1,6)
!NOV89
DIMENSION CO2IQ2(LP1,LP1,6),CO2IQ3(LP1,LP1,6),CO2IQ5(LP1,LP1,6)
!NOV89
DIMENSION T41(LP2,2),T42(LP1), &
T43(LP2,2),T44(LP1)
DIMENSION T20(LP1,LP1,3),T21(LP1,LP1,3)
DIMENSION T22(LP1,LP1,3),T23(LP1,LP1,3)
DIMENSION SGLVNU(LP1),SIGLNU(L)
DIMENSION SFULL(LP1),SHALF(L)
! DIMENSION STEMP(LP1),GTEMP(LP1)
! DIMENSION CDTM51(L),CO2M51(L),C2DM51(L)
! DIMENSION CDTM58(L),CO2M58(L),C2DM58(L)
! DIMENSION CDT51(LP1,LP1),CO251(LP1,LP1),C2D51(LP1,LP1)
! DIMENSION CDT58(LP1,LP1),CO258(LP1,LP1),C2D58(LP1,LP1)
!NOV89
! DIMENSION CDT31(LP1),CO231(LP1),C2D31(LP1)
! DIMENSION CDT38(LP1),CO238(LP1),C2D38(LP1)
! DIMENSION CDT71(LP1),CO271(LP1),C2D71(LP1)
! DIMENSION CDT78(LP1),CO278(LP1),C2D78(LP1)
! DIMENSION CO211(LP1),CO218(LP1)
! EQUIVALENCE (CDT31(1),CO2IQ2(1,1,1)),(CO231(1),CO2IQ2(1,1,2))
! EQUIVALENCE (C2D31(1),CO2IQ2(1,1,3)),(CDT38(1),CO2IQ2(1,1,4))
! EQUIVALENCE (CO238(1),CO2IQ2(1,1,5)),(C2D38(1),CO2IQ2(1,1,6))
! EQUIVALENCE (CDT71(1),CO2IQ3(1,1,1)),(CO271(1),CO2IQ3(1,1,2))
! EQUIVALENCE (C2D71(1),CO2IQ3(1,1,3)),(CDT78(1),CO2IQ3(1,1,4))
! EQUIVALENCE (CO278(1),CO2IQ3(1,1,5)),(C2D78(1),CO2IQ3(1,1,6))
! EQUIVALENCE (CO211(1),CO2IQ5(1,1,2)),(CO218(1),CO2IQ5(1,1,5))
!NOV89
! EQUIVALENCE (STEMP(1),SGTEMP(1,1)),(GTEMP(1),SGTEMP(1,2))
! EQUIVALENCE (CDTM51(1),CO2D1D(1,1)),(CO2M51(1),CO2D1D(1,2))
! EQUIVALENCE (C2DM51(1),CO2D1D(1,3)),(CDTM58(1),CO2D1D(1,4))
! EQUIVALENCE (CO2M58(1),CO2D1D(1,5)),(C2DM58(1),CO2D1D(1,6))
! EQUIVALENCE (CDT51(1,1),CO2D2D(1,1,1)),(CO251(1,1),CO2D2D(1,1,2))
! EQUIVALENCE (C2D51(1,1),CO2D2D(1,1,3)),(CDT58(1,1),CO2D2D(1,1,4))
! EQUIVALENCE (CO258(1,1),CO2D2D(1,1,5)),(C2D58(1,1),CO2D2D(1,1,6))
! Deallocate before reading. This is required for nested domain init.
!
IF(ALLOCATED (CO251))DEALLOCATE(CO251)
IF(ALLOCATED (CDT51))DEALLOCATE(CDT51)
IF(ALLOCATED (C2D51))DEALLOCATE(C2D51)
IF(ALLOCATED (CO258))DEALLOCATE(CO258)
IF(ALLOCATED (CDT58))DEALLOCATE(CDT58)
IF(ALLOCATED (C2D58))DEALLOCATE(C2D58)
IF(ALLOCATED (STEMP))DEALLOCATE(STEMP)
IF(ALLOCATED (GTEMP))DEALLOCATE(GTEMP)
IF(ALLOCATED (CO231))DEALLOCATE(CO231)
IF(ALLOCATED (CDT31))DEALLOCATE(CDT31)
IF(ALLOCATED (C2D31))DEALLOCATE(C2D31)
IF(ALLOCATED (CO238))DEALLOCATE(CO238)
IF(ALLOCATED (CDT38))DEALLOCATE(CDT38)
IF(ALLOCATED (C2D38))DEALLOCATE(C2D38)
IF(ALLOCATED (CO271))DEALLOCATE(CO271)
IF(ALLOCATED (CDT71))DEALLOCATE(CDT71)
IF(ALLOCATED (C2D71))DEALLOCATE(C2D71)
IF(ALLOCATED (CO278))DEALLOCATE(CO278)
IF(ALLOCATED (CDT78))DEALLOCATE(CDT78)
IF(ALLOCATED (C2D78))DEALLOCATE(C2D78)
IF(ALLOCATED (CO2M51))DEALLOCATE(CO2M51)
IF(ALLOCATED (CDTM51))DEALLOCATE(CDTM51)
IF(ALLOCATED (C2DM51))DEALLOCATE(C2DM51)
IF(ALLOCATED (CO2M58))DEALLOCATE(CO2M58)
IF(ALLOCATED (CDTM58))DEALLOCATE(CDTM58)
IF(ALLOCATED (C2DM58))DEALLOCATE(C2DM58)
ALLOCATE(CO251(LP1,LP1))
ALLOCATE(CDT51(LP1,LP1))
ALLOCATE(C2D51(LP1,LP1))
ALLOCATE(CO258(LP1,LP1))
ALLOCATE(CDT58(LP1,LP1))
ALLOCATE(C2D58(LP1,LP1))
ALLOCATE(STEMP(LP1))
ALLOCATE(GTEMP(LP1))
ALLOCATE(CO231(LP1))
ALLOCATE(CDT31(LP1))
ALLOCATE(C2D31(LP1))
ALLOCATE(CO238(LP1))
ALLOCATE(CDT38(LP1))
ALLOCATE(C2D38(LP1))
ALLOCATE(CO271(LP1))
ALLOCATE(CDT71(LP1))
ALLOCATE(C2D71(LP1))
ALLOCATE(CO278(LP1))
ALLOCATE(CDT78(LP1))
ALLOCATE(C2D78(LP1))
ALLOCATE(CO2M51(L))
ALLOCATE(CDTM51(L))
ALLOCATE(C2DM51(L))
ALLOCATE(CO2M58(L))
ALLOCATE(CDTM58(L))
ALLOCATE(C2DM58(L))
IF ( wrf_dm_on_monitor() ) THEN
DO i = 61,99
INQUIRE ( i , OPENED = opened )
IF ( .NOT. opened ) THEN
etarad_unit61 = i
GOTO 2061
ENDIF
ENDDO
etarad_unit61 = -1
2061 CONTINUE
DO i = 62,99
INQUIRE ( i , OPENED = opened )
IF ( .NOT. opened ) THEN
etarad_unit62 = i
GOTO 2062
ENDIF
ENDDO
etarad_unit62 = -1
2062 CONTINUE
DO i = 63,99
INQUIRE ( i , OPENED = opened )
IF ( .NOT. opened ) THEN
etarad_unit63 = i
GOTO 2063
ENDIF
ENDDO
etarad_unit63 = -1
2063 CONTINUE
ENDIF
CALL wrf_dm_bcast_bytes ( etarad_unit61 , IWORDSIZE )
IF ( etarad_unit61 < 0 ) THEN
CALL wrf_error_fatal ( 'module_ra_hwrf: co2o3: Can not find unused fortran unit to read in lookup table.' )
ENDIF
CALL wrf_dm_bcast_bytes ( etarad_unit62 , IWORDSIZE )
IF ( etarad_unit62 < 0 ) THEN
CALL wrf_error_fatal ( 'module_ra_hwrf: co2o3: Can not find unused fortran unit to read in lookup table.' )
ENDIF
CALL wrf_dm_bcast_bytes ( etarad_unit63 , IWORDSIZE )
IF ( etarad_unit63 < 0 ) THEN
CALL wrf_error_fatal ( 'module_ra_hwrf: co2o3: Can not find unused fortran unit to read in lookup table.' )
ENDIF
IF ( wrf_dm_on_monitor() ) THEN
OPEN(etarad_unit61,FILE='tr49t85', &
FORM='FORMATTED',STATUS='OLD',ERR=9061,IOSTAT=IERROR)
ENDIF
IF ( wrf_dm_on_monitor() ) THEN
OPEN(etarad_unit62,FILE='tr49t67', &
FORM='FORMATTED',STATUS='OLD',ERR=9062,IOSTAT=IERROR)
ENDIF
IF ( wrf_dm_on_monitor() ) THEN
OPEN(etarad_unit63,FILE='tr67t85', &
FORM='FORMATTED',STATUS='OLD',ERR=9063,IOSTAT=IERROR)
ENDIF
!===> GET SGTEMP AND OUTPUT WHICH USED TO BE ON UNITS 41,42,43,44....
LREAD = 0
! DO KKK=1,L
!JD READ(23)SIGLNU(KKK)
! SIGLNU(KKK)=1.-FLOAT(KKK)/LP1
! END DO
CALL CO2PTZ(SGTEMP,T41,T42,T43,T44,SGLVNU,SIGLNU, &
SFULL,SHALF,PPTOP,LREAD,L,LP1,LP2)
! call int_get_fresh_handle(retval)
! close(retval)
! open(unit=retval,file=co2,form='UNFORMATTED',iostat=ier)
! do kk=1,2
! write(retval)(sgtemp(k,kk),k=1,61)
! enddo
DO K=1,LP1
STEMP(K)=SGTEMP(K,1)
GTEMP(K)=SGTEMP(K,2)
ENDDO
!===> INTERPOLATE DESIRED CO2 DATA FROM THE DETAILED(109,109) GRID..
! IR=1,IQ=1 IS FOR COMMON /CO2BD3/ IN RADIATION CODE...
! FOR THE CONSOLIDATED 490-850 CM-1 BAND...
!NOV89
! ICO2TP=61
ICO2TP=etarad_unit61
!NOV89
IR = 1
RATIO = 1.0
NMETHD = 2
CALL CO2INT(ICO2TP,T41,T42,T22,RATIO,IR,NMETHD,L,LP1,LP2)
IR = 1
RATIO = 1.0
NMETHD = 1
CALL CO2INT(ICO2TP,T41,T42,T20,RATIO,IR,NMETHD,L,LP1,LP2)
IR = 1
RATIO = 1.0
NMETHD = 2
CALL CO2INT(ICO2TP,T43,T44,T23,RATIO,IR,NMETHD,L,LP1,LP2)
IR = 1
RATIO = 1.0
NMETHD = 1
CALL CO2INT(ICO2TP,T43,T44,T21,RATIO,IR,NMETHD,L,LP1,LP2)
!===> FILL UP THE CO2D1D ARRAY
! THE FOLLOWING GETS CO2 TRANSMISSION FUNCTIONS AND
! THEIR DERIVATIVES FOR TAU(I,I+1),I=1,LEVS,
! WHERE THE VALUES ARE NOT OBTAINED BY QUADRATURE BUT ARE THE
! ACTUAL TRANSMISSIVITIES,ETC,BETWEEN A PAIR OF PRESSURES. THESE
! ARE USED ONLY FOR NEARBY LAYER CALCULATIONS INCLUDING H2O..
!
IQ = 1
CALL CO2IN1(T20,T21,CO2D1D,IQ,L,LP1)
! do kk=1,6
! write(retval)(co2d1d(k,kk),k=1,60)
! enddo
DO K=1,L
CDTM51(K)=CO2D1D(K,1)
CO2M51(K)=CO2D1D(K,2)
C2DM51(K)=CO2D1D(K,3)
CDTM58(K)=CO2D1D(K,4)
CO2M58(K)=CO2D1D(K,5)
C2DM58(K)=CO2D1D(K,6)
ENDDO
!
!===> FILL UP THE CO2D2D ARRAY
! THE FOLLOWING GETS CO2 TRANSMISSION FUNCTIONS AND THEIR DERIVATIVES
! FROM 109-LEVEL LINE-BY-LINE CALCULATIONS MADE USING THE 1982
! MCCLATCHY TAPE (12511 LINES),CONSOLIDATED,INTERPOLATED
! TO THE MRF VERTICAL COORDINATE,AND RE-CONSOLIDATED TO A
! 200 CM-1 BANDWIDTH. THE INTERPOLATION METHOD IS DESCRIBED IN
! SCHWARZKOPF AND FELS (J.G.R.,1985).
!
CALL CO2INS(T22,T23,CO2D2D,IQ,L,LP1,1)
! do kk=1,6
! write(retval)((co2d2d(ka,kb,kk),ka=1,61),kb=1,61)
! enddo
DO K1=1,LP1
DO K2=1,LP1
CDT51(K1,K2)=CO2D2D(K1,K2,1)
CO251(K1,K2)=CO2D2D(K1,K2,2)
C2D51(K1,K2)=CO2D2D(K1,K2,3)
CDT58(K1,K2)=CO2D2D(K1,K2,4)
CO258(K1,K2)=CO2D2D(K1,K2,5)
C2D58(K1,K2)=CO2D2D(K1,K2,6)
ENDDO
ENDDO
!
!NOV89
!===> INTERPOLATE DESIRED CO2 DATA FROM THE DETAILED(109,109) GRID..
! IR=2,IQ=2 IS FOR COMMON /CO2BD2/ IN RADIATION CODE...
! FOR THE CONSOLIDATED 490-670 CM-1 BAND...
! ICO2TP=62
ICO2TP=etarad_unit62
IR = 2
RATIO = 1.0
NMETHD = 2
CALL CO2INT(ICO2TP,T41,T42,T22,RATIO,IR,NMETHD,L,LP1,LP2)
CALL CO2INT(ICO2TP,T43,T44,T23,RATIO,IR,NMETHD,L,LP1,LP2)
IQ = 2
CALL CO2INS(T22,T23,CO2IQ2,IQ,L,LP1,2)
! do kk=1,6
! write(retval)(co2iq2(k,1,kk),k=1,61)
! enddo
DO K=1,LP1
CDT31(K)=CO2IQ2(K,1,1)
CO231(K)=CO2IQ2(K,1,2)
C2D31(K)=CO2IQ2(K,1,3)
CDT38(K)=CO2IQ2(K,1,4)
CO238(K)=CO2IQ2(K,1,5)
C2D38(K)=CO2IQ2(K,1,6)
ENDDO
!===> INTERPOLATE DESIRED CO2 DATA FROM THE DETAILED(109,109) GRID..
! IR=3,IQ=3 IS FOR COMMON /CO2BD4/ IN RADIATION CODE...
! FOR THE CONSOLIDATED 670-850 CM-1 BAND...
! ICO2TP=63
ICO2TP=etarad_unit63
IR = 3
RATIO = 1.0
NMETHD = 2
CALL CO2INT(ICO2TP,T41,T42,T22,RATIO,IR,NMETHD,L,LP1,LP2)
CALL CO2INT(ICO2TP,T43,T44,T23,RATIO,IR,NMETHD,L,LP1,LP2)
IQ = 3
CALL CO2INS(T22,T23,CO2IQ3,IQ,L,LP1,3)
! do kk=1,6
! write(retval)(co2iq3(k,1,kk),k=1,61)
! enddo
! close(retval)
DO K=1,LP1
CDT71(K)=CO2IQ3(K,1,1)
CO271(K)=CO2IQ3(K,1,2)
C2D71(K)=CO2IQ3(K,1,3)
CDT78(K)=CO2IQ3(K,1,4)
CO278(K)=CO2IQ3(K,1,5)
C2D78(K)=CO2IQ3(K,1,6)
ENDDO
!--- FOLLOWING CODE NOT WORKING AND NOT NEEDED YET
!===> INTERPOLATE DESIRED CO2 DATA FROM THE DETAILED(109,109) GRID..
! IR=4,IQ=5 IS FOR COMMON /CO2BD5/ IN RADIATION CODE...
! FOR THE 4.3 MICRON BAND...
! NOT USED YET ICO2TP=65
! NOT USED YET IR = 4
! NOT USED YET RATIO = 1.0
! DAN SCHWARZ --- USE 300PPMV RATIO = 0.9091 (NOT TESTED YET).....
! NOT USED YET NMETHD = 2
! NOT USED YET CALL CO2INT(ICO2TP,T41,T42,T22,RATIO,IR,NMETHD)
! NOT USED YET CALL CO2INT(ICO2TP,T43,T44,T23,RATIO,IR,NMETHD)
! NOT USED YET IQ = 5
! NOT USED YET CALL CO2INS(T22,T23,CO2IQ5,IQ)
!NOV89
!... WRITE DATA TO DISK..
! ...SINCE THESE CODES ARE COMPILED WITH AUTODBL,THE CO2 DATA
! IS CONVERTED TO SINGLE PRECISION IN A LATER JOB STEP..
! NOT USED YET WRITE(66) CO211
! NOT USED YET WRITE(66) CO218
!NOV89
IF ( wrf_dm_on_monitor() ) THEN
CLOSE (etarad_unit61)
CLOSE (etarad_unit62)
CLOSE (etarad_unit63)
ENDIF
RETURN
9061 CONTINUE
WRITE( errmess , '(A49,I4)' ) 'module_ra_hwrf: error reading tr49t85 on unit ',etarad_unit61
write(0,*)' IERROR=',IERROR
CALL wrf_error_fatal(errmess)
9062 CONTINUE
WRITE( errmess , '(A49,I4)' ) 'module_ra_hwrf: error reading tr49t67 on unit ',etarad_unit62
write(0,*)' IERROR=',IERROR
CALL wrf_error_fatal(errmess)
9063 CONTINUE
WRITE( errmess , '(A49,I4)' ) 'module_ra_hwrf: error reading tr67t85 on unit ',etarad_unit63
write(0,*)' IERROR=',IERROR
CALL wrf_error_fatal(errmess)
END SUBROUTINE CO2O3
!!================================================================================
!----------------------------------------------------------------------
!----------------------------------------------------------------------
SUBROUTINE CONRAD(KDS,KDE,KMS,KME,KTS,KTE) 2,13
!----------------------------------------------------------------------
! *******************************************************************
! * C O N R A D *
! * READ CO2 TRANSMISSION DATA FROM UNIT(NFILE)FOR NEW VERTICAL *
! * COORDINATE TESTS ... *
! * THESE ARRAYS USED TO BE IN BLOCK DATA ...K.CAMPANA-MAR 90 *
! *******************************************************************
!
!----------------------------------------------------------------------
IMPLICIT NONE
!----------------------------------------------------------------------
INTEGER,INTENT(IN) :: KDS,KDE,KMS,KME,KTS,KTE
!----------------------------------------------------------------------
!
INTEGER :: I,I1,I2,IERROR,IRTN,J,K,KK,L,LP1,N,NUNIT_CO2,RSIZE
INTEGER,DIMENSION(3) :: RSZE
!
REAL,DIMENSION(KMS:KME-1,6) :: CO21D
REAL,DIMENSION(KMS:KME,2) :: SGTMP
REAL,DIMENSION(KMS:KME,6) :: CO21D3,CO21D7
REAL,DIMENSION(KMS:KME,KMS:KME,6) :: CO22D
REAL,DIMENSION((KME-KMS+1)*(KME-KMS+1)) :: DATA2
LOGICAL :: OPENED
LOGICAL,EXTERNAL :: wrf_dm_on_monitor
CHARACTER*80 errmess
!
!----------------------------------------------------------------------
!
! CO2 DATA TABLES FOR USER'S VERTICAL COORDINATE
!
! THE FOLLOWING COMMON BLOCKS CONTAIN PRETABULATED CO2 TRANSMISSION
! FUNCTIONS, EVALUATED USING THE METHODS OF FELS AND
! SCHWARZKOPF (1981) AND SCHWARZKOPF AND FELS (1985),
!----- THE 2-DIMENSIONAL ARRAYS ARE
! CO2 TRANSMISSION FUNCTIONS AND THEIR DERIVATIVES
! FROM 109-LEVEL LINE-BY-LINE CALCULATIONS MADE USING THE 1982
! MCCLATCHY TAPE (12511 LINES),CONSOLIDATED,INTERPOLATED
! TO THE NMC MRF VERTICAL COORDINATTE,AND RE-CONSOLIDATED TO A
! 200 CM-1 BANDWIDTH. THE INTERPOLATION METHOD IS DESCRIBED IN
! SCHWARZKOPF AND FELS (J.G.R.,1985).
!----- THE 1-DIM ARRAYS ARE
! CO2 TRANSMISSION FUNCTIONS AND THEIR DERIVATIVES
! FOR TAU(I,I+1),I=1,L,
! WHERE THE VALUES ARE NOT OBTAINED BY QUADRATURE,BUT ARE THE
! ACTUAL TRANSMISSIVITIES,ETC,BETWEEN A PAIR OF PRESSURES.
! THESE USED ONLY FOR NEARBY LAYER CALCULATIONS INCLUDING QH2O.
!----- THE WEIGHTING FUNCTION GTEMP=P(K)**0.2*(1.+P(K)/30000.)**0.8/
! 1013250.,WHERE P(K)=PRESSURE,NMC MRF(NEW) L18 DATA LEVELS FOR
! PSTAR=1013250.
!----- STEMP IS US STANDARD ATMOSPHERES,1976,AT DATA PRESSURE LEVELS
! USING NMC MRF SIGMAS,WHERE PSTAR=1013.25 MB (PTZ PROGRAM)
!
!***CO2 TRANSMISSION FUNCTIONS AND TEMPERATURE
! AND PRESSURE DERIVATIVES FOR THE 560-800 CM-1 BAND. ALSO INCLUDED
! ARE THE STANDARD TEMPERATURES AND THE WEIGHTING FUNCTION. THESE
! DATA ARE IN BLOCK DATA BD3:
! CO251 = TRANSMISSION FCTNS FOR T0 (STD. PROFILE)
! WITH P(SFC)=1013.25 MB
! CO258 = TRANSMISSION FCTNS. FOR T0 (STD. PROFILE)
! WITH P(SFC)= 810 MB
! CDT51 = FIRST TEMPERATURE DERIVATIVE OF CO251
! CDT58 = FIRST TEMPERATURE DERIVATIVE OF CO258
! C2D51 = SECOND TEMPERATURE DERIVATIVE OF CO251
! C2D58 = SECOND TEMPERATURE DERIVATIVE OF CO251
! CO2M51 = TRANSMISSION FCTNS FOR T0 FOR ADJACENT PRESSURE
! LEVELS, WITH NO PRESSURE QUADRATURE. USED FOR
! NEARBY LAYER COMPUTATIONS. P(SFC)=1013.25 MB
! CO2M58 = SAME AS CO2M51,WITH P(SFC)= 810 MB
! CDTM51 = FIRST TEMPERATURE DERIVATIVE OF CO2M51
! CDTM58 = FIRST TEMPERATURE DERIVATIVE OF CO2M58
! C2DM51 = SECOND TEMPERATURE DERIVATIVE OF CO2M51
! C2DM58 = SECOND TEMPERATURE DERIVATIVE OF CO2M58
! STEMP = STANDARD TEMPERATURES FOR MODEL PRESSURE LEVEL
! STRUCTURE WITH P(SFC)=1013.25 MB
! GTEMP = WEIGHTING FUNCTION FOR MODEL PRESSURE LEVEL
! STRUCTURE WITH P(SFC)=1013.25 MB.
!----- THE FOLLOWING ARE STILL IN BLOCK DATA
! B0 = TEMP. COEFFICIENT USED FOR CO2 TRANS. FCTN.
! CORRECTION FOR T(K). (SEE REF. 4 AND BD3)
! B1 = TEMP. COEFFICIENT, USED ALONG WITH B0
! B2 = TEMP. COEFFICIENT, USED ALONG WITH B0
! B3 = TEMP. COEFFICIENT, USED ALONG WITH B0
!
!***CO2 TRANSMISSION FUNCTIONS AND TEMPERATURE
! AND PRESSURE DERIVATIVES FOR THE 560-670 CM-1 PART OF THE 15 UM
! CO2 BAND. THESE DATA ARE IN BLOCK DATA BD2.
! FOR THE 560-670 CM-1 BAND,ONLY THE (1,I) VALUES ARE USED , SINCE
! THESE ARE USED FOR CTS COMPUTATIONS.
! CO231 = TRANSMISSION FCTNS FOR T0 (STD. PROFILE)
! WITH P(SFC)=1013.25 MB
! CO238 = TRANSMISSION FCTNS. FOR T0 (STD. PROFILE)
! WITH P(SFC)= 810 MB
! CDT31 = FIRST TEMPERATURE DERIVATIVE OF CO231
! CDT38 = FIRST TEMPERATURE DERIVATIVE OF CO238
! C2D31 = SECOND TEMPERATURE DERIVATIVE OF CO231
! C2D38 = SECOND TEMPERATURE DERIVATIVE OF CO231
!
!***CO2 TRANSMISSION FUNCTIONS AND TEMPERATURE
! AND PRESSURE DERIVATIVES FOR THE 670-800 CM-1 PART OF THE 15 UM
! CO2 BAND. THESE DATA ARE IN BLOCK DATA BD4.
! CO271 = TRANSMISSION FCTNS FOR T0 (STD. PROFILE)
! WITH P(SFC)=1013.25 MB
! CO278 = TRANSMISSION FCTNS. FOR T0 (STD. PROFILE)
! WITH P(SFC)= 810 MB
! CDT71 = FIRST TEMPERATURE DERIVATIVE OF CO271
! CDT78 = FIRST TEMPERATURE DERIVATIVE OF CO278
! C2D71 = SECOND TEMPERATURE DERIVATIVE OF CO271
! C2D78 = SECOND TEMPERATURE DERIVATIVE OF CO271
!
! *****THE FOLLOWING NOT USED IN CURRENT VERSION OF RADIATION *******
!
! --CO2 TRANSMISSION FUNCTIONS FOR THE 2270-
! 2380 PART OF THE 4.3 UM CO2 BAND.
! THESE DATA ARE IN BLOCK DATA BD5.
! CO211 = TRANSMISSION FCTNS FOR T0 (STD. PROFILE)
! WITH P(SFC)=1013.25 MB
! CO218 = TRANSMISSION FCTNS. FOR T0 (STD. PROFILE)
! WITH P(SFC)= 810 MB
!
! *****THE ABOVE NOT USED IN CURRENT VERSION OF RADIATION ***********
!----------------------------------------------------------------------
!
L=KME-KMS
LP1=KME-KMS+1
!
!----------------------------------------------------------------------
IF ( wrf_dm_on_monitor() ) THEN
DO i = 14,99
INQUIRE ( i , OPENED = opened )
IF ( .NOT. opened ) THEN
nunit_co2 = i
GOTO 2014
ENDIF
ENDDO
nunit_co2 = -1
2014 CONTINUE
ENDIF
IF ( wrf_dm_on_monitor() ) THEN
OPEN(nunit_co2,FILE='co2_trans', &
FORM='UNFORMATTED',STATUS='OLD',ERR=9014,IOSTAT=IERROR)
REWIND NUNIT_CO2
ENDIF
!----------------------------------------------------------------------
!
!*** READ IN PRE-COMPUTED CO2 TRANSMISSION DATA.
!
RSZE(1) = LP1
RSZE(2) = L
RSZE(3) = LP1*LP1
!----------------------------------------------------------------------
!
RSIZE = RSZE(1)
!
DO KK=1,2
IF( wrf_dm_on_monitor() )READ(NUNIT_CO2)(SGTMP(I,KK),I=1,RSIZE)
CALL wrf_dm_bcast_real( SGTMP(1,KK), RSIZE )
ENDDO
!
!----------------------------------------------------------------------
!
RSIZE = RSZE(2)
!
DO KK=1,6
IF( wrf_dm_on_monitor() )READ(NUNIT_CO2)(CO21D(I,KK),I=1,RSIZE)
CALL wrf_dm_bcast_real( CO21D(1,KK), RSIZE )
ENDDO
!
!----------------------------------------------------------------------
!
RSIZE = RSZE(3)
!
DO KK=1,6
IF( wrf_dm_on_monitor() )READ(NUNIT_CO2)(DATA2(I),I=1,RSIZE)
CALL wrf_dm_bcast_real( DATA2(1), RSIZE )
N=0
!
DO I1=1,LP1
DO I2=1,LP1
N=N+1
CO22D(I1,I2,KK)=DATA2(N)
ENDDO
ENDDO
!
ENDDO
!
! Deallocate before reading. This is required for nested domain init.
! This is gopal's doing
!
IF(ALLOCATED (CO251))DEALLOCATE(CO251)
IF(ALLOCATED (CDT51))DEALLOCATE(CDT51)
IF(ALLOCATED (C2D51))DEALLOCATE(C2D51)
IF(ALLOCATED (CO258))DEALLOCATE(CO258)
IF(ALLOCATED (CDT58))DEALLOCATE(CDT58)
IF(ALLOCATED (C2D58))DEALLOCATE(C2D58)
IF(ALLOCATED (STEMP))DEALLOCATE(STEMP)
IF(ALLOCATED (GTEMP))DEALLOCATE(GTEMP)
IF(ALLOCATED (CO231))DEALLOCATE(CO231)
IF(ALLOCATED (CDT31))DEALLOCATE(CDT31)
IF(ALLOCATED (C2D31))DEALLOCATE(C2D31)
IF(ALLOCATED (CO238))DEALLOCATE(CO238)
IF(ALLOCATED (CDT38))DEALLOCATE(CDT38)
IF(ALLOCATED (C2D38))DEALLOCATE(C2D38)
IF(ALLOCATED (CO271))DEALLOCATE(CO271)
IF(ALLOCATED (CDT71))DEALLOCATE(CDT71)
IF(ALLOCATED (C2D71))DEALLOCATE(C2D71)
IF(ALLOCATED (CO278))DEALLOCATE(CO278)
IF(ALLOCATED (CDT78))DEALLOCATE(CDT78)
IF(ALLOCATED (C2D78))DEALLOCATE(C2D78)
IF(ALLOCATED (CO2M51))DEALLOCATE(CO2M51)
IF(ALLOCATED (CDTM51))DEALLOCATE(CDTM51)
IF(ALLOCATED (C2DM51))DEALLOCATE(C2DM51)
IF(ALLOCATED (CO2M58))DEALLOCATE(CO2M58)
IF(ALLOCATED (CDTM58))DEALLOCATE(CDTM58)
IF(ALLOCATED (C2DM58))DEALLOCATE(C2DM58)
!
!----------------------------------------------------------------------
!
RSIZE = RSZE(1)
!
DO KK=1,6
IF( wrf_dm_on_monitor() )READ(NUNIT_CO2)(CO21D3(I,KK),I=1,RSIZE)
CALL wrf_dm_bcast_real( CO21D3(1,KK), RSIZE )
ENDDO
!
!----------------------------------------------------------------------
!
DO KK=1,6
IF( wrf_dm_on_monitor() )READ(NUNIT_CO2)(CO21D7(I,KK),I=1,RSIZE)
CALL wrf_dm_bcast_real ( CO21D7(1,KK), RSIZE )
ENDDO
!
!----------------------------------------------------------------------
ALLOCATE(CO251(LP1,LP1))
ALLOCATE(CDT51(LP1,LP1))
ALLOCATE(C2D51(LP1,LP1))
ALLOCATE(CO258(LP1,LP1))
ALLOCATE(CDT58(LP1,LP1))
ALLOCATE(C2D58(LP1,LP1))
ALLOCATE(STEMP(LP1))
ALLOCATE(GTEMP(LP1))
ALLOCATE(CO231(LP1))
ALLOCATE(CDT31(LP1))
ALLOCATE(C2D31(LP1))
ALLOCATE(CO238(LP1))
ALLOCATE(CDT38(LP1))
ALLOCATE(C2D38(LP1))
ALLOCATE(CO271(LP1))
ALLOCATE(CDT71(LP1))
ALLOCATE(C2D71(LP1))
ALLOCATE(CO278(LP1))
ALLOCATE(CDT78(LP1))
ALLOCATE(C2D78(LP1))
ALLOCATE(CO2M51(L))
ALLOCATE(CDTM51(L))
ALLOCATE(C2DM51(L))
ALLOCATE(CO2M58(L))
ALLOCATE(CDTM58(L))
ALLOCATE(C2DM58(L))
!----------------------------------------------------------------------
!
DO K=1,LP1
STEMP(K) = SGTMP(K,1)
GTEMP(K) = SGTMP(K,2)
ENDDO
!
DO K=1,L
CDTM51(K) = CO21D(K,1)
CO2M51(K) = CO21D(K,2)
C2DM51(K) = CO21D(K,3)
CDTM58(K) = CO21D(K,4)
CO2M58(K) = CO21D(K,5)
C2DM58(K) = CO21D(K,6)
ENDDO
!
DO J=1,LP1
DO I=1,LP1
CDT51(I,J) = CO22D(I,J,1)
CO251(I,J) = CO22D(I,J,2)
C2D51(I,J) = CO22D(I,J,3)
CDT58(I,J) = CO22D(I,J,4)
CO258(I,J) = CO22D(I,J,5)
C2D58(I,J) = CO22D(I,J,6)
ENDDO
ENDDO
!
DO K=1,LP1
CDT31(K) = CO21D3(K,1)
CO231(K) = CO21D3(K,2)
C2D31(K) = CO21D3(K,3)
CDT38(K) = CO21D3(K,4)
CO238(K) = CO21D3(K,5)
C2D38(K) = CO21D3(K,6)
ENDDO
!
DO K=1,LP1
CDT71(K) = CO21D7(K,1)
CO271(K) = CO21D7(K,2)
C2D71(K) = CO21D7(K,3)
CDT78(K) = CO21D7(K,4)
CO278(K) = CO21D7(K,5)
C2D78(K) = CO21D7(K,6)
ENDDO
!
!----------------------------------------------------------------------
IF(wrf_dm_on_monitor())WRITE(0,66)NUNIT_CO2
66 FORMAT('----READ CO2 TRANSMISSION FUNCTIONS FROM UNIT ',I2)
!----------------------------------------------------------------------
IF( wrf_dm_on_monitor() )THEN
CLOSE(nunit_co2)
ENDIF
RETURN
!
9014 CONTINUE
WRITE(errmess,'(A51,I4)')'module_ra_hwrf: error reading co2_trans on unit ',nunit_co2
CALL wrf_error_fatal(errmess)
!----------------------------------------------------------------------
END SUBROUTINE CONRAD
!----------------------------------------------------------------------
!
END MODULE module_RA_HWRF
!
!----------------------------------------------------------------------