MODULE module_radiation_driver CONTAINS SUBROUTINE radiation_driver ( & ACFRCV ,ACFRST ,ALBEDO & ,CFRACH ,CFRACL ,CFRACM & ,CUPPT ,CZMEAN ,DT & ,DZ8W ,EMISS ,GLW & ,GMT ,GSW ,HBOT & ,HTOP ,HBOTR ,HTOPR & ,ICLOUD & ,ITIMESTEP,JULDAY, JULIAN & ,JULYR ,LW_PHYSICS & ,NCFRCV ,NCFRST ,NPHS & ,O3INPUT, O3RAD & ,AER_OPT, aerod & ,swint_opt & ,P8W ,P ,PI & ,RADT ,RA_CALL_OFFSET & ,RHO ,RLWTOA & ,RSWTOA ,RTHRATEN & ,RTHRATENLW ,RTHRATENSW & ,SNOW ,STEPRA ,SWDOWN & ,SWDOWNC ,SW_PHYSICS & ,T8W ,T ,TAUCLDC & ,TAUCLDI ,TSK ,VEGFRA & ,WARM_RAIN ,XICE ,XLAND & ,XLAT ,XLONG ,YR & ,DECLINX ,SOLCONX ,COSZEN ,HRANG & , CEN_LAT & ,Z & ,ALEVSIZ, no_src_types & ,LEVSIZ, N_OZMIXM & ,N_AEROSOLC & ,PAERLEV ,ID & ,CAM_ABS_DIM1, CAM_ABS_DIM2 & ,CAM_ABS_FREQ_S & ,XTIME & ,CURR_SECS, ADAPT_STEP_FLAG & ,IDS,IDE, JDS,JDE, KDS,KDE & ,IMS,IME, JMS,JME, KMS,KME & ,i_start,i_end & ,j_start,j_end & ,kts, kte & ,num_tiles & , TLWDN, TLWUP & , SLWDN, SLWUP & , TSWDN, TSWUP & , SSWDN, SSWUP & , CLDFRA,CLDFRA_MP_ALL & , re_cloud, re_ice, re_snow & , has_reqc, has_reqi, has_reqs & , PB & , F_ICE_PHY,F_RAIN_PHY & , QV, F_QV & , QC, F_QC & , QR, F_QR & , QI, F_QI & , QS, F_QS & , QG, F_QG & , QNDROP, F_QNDROP & ,ACSWUPT ,ACSWUPTC & ,ACSWDNT ,ACSWDNTC & ,ACSWUPB ,ACSWUPBC & ,ACSWDNB ,ACSWDNBC & ,ACLWUPT ,ACLWUPTC & ,ACLWDNT ,ACLWDNTC & ,ACLWUPB ,ACLWUPBC & ,ACLWDNB ,ACLWDNBC & ,SWUPT ,SWUPTC & ,SWDNT ,SWDNTC & ,SWUPB ,SWUPBC & ,SWDNB ,SWDNBC & ,LWUPT ,LWUPTC & ,LWDNT ,LWDNTC & ,LWUPB ,LWUPBC & ,LWDNB ,LWDNBC & ,LWCF & ,SWCF & ,OLR & ,aerodm, PINA, aodtot & ,OZMIXM, PIN & ,M_PS_1, M_PS_2, AEROSOLC_1 & ,AEROSOLC_2, M_HYBI0 & ,ABSTOT, ABSNXT, EMSTOT & ,CU_RAD_FEEDBACK & ,AER_RA_FEEDBACK & ,QC_ADJUST , QI_ADJUST & ,PM2_5_DRY, PM2_5_WATER & ,PM2_5_DRY_EC & ,TAUAER300, TAUAER400 & ,TAUAER600, TAUAER999 & ,GAER300, GAER400, GAER600, GAER999 & ,WAER300, WAER400, WAER600, WAER999 & ,TAUAERlw1, TAUAERlw2 & ,TAUAERlw3, TAUAERlw4 & ,TAUAERlw5, TAUAERlw6 & ,TAUAERlw7, TAUAERlw8 & ,TAUAERlw9, TAUAERlw10 & ,TAUAERlw11, TAUAERlw12 & ,TAUAERlw13, TAUAERlw14 & ,TAUAERlw15, TAUAERlw16 & ,progn & ,slope_rad,topo_shading & ,shadowmask,ht,dx,dy & ,SWUPFLX,SWUPFLXC,SWDNFLX,SWDNFLXC & ,LWUPFLX,LWUPFLXC,LWDNFLX,LWDNFLXC & ,radtacttime & ,ALSWVISDIR, ALSWVISDIF, ALSWNIRDIR, ALSWNIRDIF & ,SWVISDIR, SWVISDIF, SWNIRDIR, SWNIRDIF & ,SF_SURFACE_PHYSICS, IS_CAMMGMP_USED & ,EXPLICIT_CONVECTION & ,swddir,swddni,swddif & ,swdown_ref,swddir_ref,coszen_ref,Gx,gg,Bx,bb & ) USE module_state_description, ONLY : RRTMSCHEME, GFDLLWSCHEME & ,RRTMG_LWSCHEME, RRTMG_SWSCHEME & ,SWRADSCHEME, GSFCSWSCHEME & ,GFDLSWSCHEME, CAMLWSCHEME, CAMSWSCHEME & ,HELDSUAREZ & ,goddardlwscheme & ,goddardswscheme & ,CAMMGMPSCHEME & ,FLGLWSCHEME, FLGSWSCHEME USE module_model_constants USE module_wrf_error , ONLY : wrf_err_message USE module_ra_sw , ONLY : swrad USE module_ra_gsfcsw , ONLY : gsfcswrad USE module_ra_rrtm , ONLY : rrtmlwrad USE module_ra_rrtmg_lw , ONLY : rrtmg_lwrad USE module_ra_rrtmg_sw , ONLY : rrtmg_swrad USE module_ra_cam , ONLY : camrad USE module_ra_gfdleta , ONLY : etara USE module_ra_hs , ONLY : hsrad USE module_ra_goddard , ONLY : goddardrad USE module_ra_flg , ONLY : RAD_FLG IMPLICIT NONE LOGICAL, OPTIONAL, INTENT(IN) :: explicit_convection LOGICAL :: expl_conv INTEGER, INTENT(IN ) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & kts,kte, & num_tiles INTEGER, INTENT(IN) :: lw_physics, sw_physics INTEGER, OPTIONAL, INTENT(IN) :: o3input, aer_opt INTEGER, INTENT(IN) :: id integer, intent(in) :: swint_opt INTEGER, DIMENSION(num_tiles), INTENT(IN) :: & i_start,i_end,j_start,j_end INTEGER, INTENT(IN ) :: STEPRA,ICLOUD,ra_call_offset INTEGER, INTENT(IN ) :: alevsiz, no_src_types INTEGER, INTENT(IN ) :: levsiz, n_ozmixm INTEGER, INTENT(IN ) :: paerlev, n_aerosolc, cam_abs_dim1, cam_abs_dim2 REAL, INTENT(IN ) :: cam_abs_freq_s LOGICAL, INTENT(IN ) :: warm_rain LOGICAL, INTENT(IN ) :: is_CAMMGMP_used REAL, INTENT(IN ) :: RADT REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN ) :: XLAND, & XICE, & TSK, & VEGFRA, & SNOW REAL, DIMENSION( ims:ime, levsiz, jms:jme, n_ozmixm ), OPTIONAL, & INTENT(IN ) :: OZMIXM REAL, DIMENSION( ims:ime, alevsiz, jms:jme, no_src_types, n_ozmixm-1 ), OPTIONAL, & INTENT(IN ) :: AERODM REAL, DIMENSION( ims:ime, kms:kme, jms:jme, no_src_types ), OPTIONAL, & INTENT(INOUT) :: AEROD REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL, & INTENT(INOUT) :: AODTOT REAL, DIMENSION( ims:ime, levsiz, jms:jme, n_ozmixm ) :: OZFLG REAL, DIMENSION(levsiz), OPTIONAL, INTENT(IN ) :: PIN REAL, DIMENSION(alevsiz), OPTIONAL, INTENT(IN ) :: PINA REAL, DIMENSION(ims:ime,jms:jme), OPTIONAL, INTENT(IN ) :: m_ps_1,m_ps_2 REAL, DIMENSION( ims:ime, paerlev, jms:jme, n_aerosolc ), OPTIONAL, & INTENT(IN ) :: aerosolc_1, aerosolc_2 REAL, DIMENSION(paerlev), OPTIONAL, & INTENT(IN ) :: m_hybi0 REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(INOUT) :: HTOP, & HBOT, & HTOPR, & HBOTR, & CUPPT INTEGER, INTENT(IN ) :: julyr REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(IN ) :: dz8w, & z, & p8w, & p, & pi, & t, & t8w, & rho REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), OPTIONAL , & INTENT(IN ) :: tauaer300,tauaer400,tauaer600,tauaer999, & gaer300,gaer400,gaer600,gaer999, & waer300,waer400,waer600,waer999, & qc_adjust, qi_adjust REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), OPTIONAL , & INTENT(IN ) :: tauaerlw1,tauaerlw2,tauaerlw3,tauaerlw4, & tauaerlw5,tauaerlw6,tauaerlw7,tauaerlw8, & tauaerlw9,tauaerlw10,tauaerlw11,tauaerlw12, & tauaerlw13,tauaerlw14,tauaerlw15,tauaerlw16 LOGICAL, INTENT(IN) :: cu_rad_feedback INTEGER, INTENT(IN ), OPTIONAL :: aer_ra_feedback INTEGER, OPTIONAL, INTENT(IN ) :: progn REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), OPTIONAL , & INTENT(IN ) :: pm2_5_dry, & pm2_5_water, & pm2_5_dry_ec REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(INOUT) :: RTHRATEN, & RTHRATENLW, & RTHRATENSW REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL, INTENT(INOUT) ::& ACSWUPT,ACSWUPTC,ACSWDNT,ACSWDNTC, & ACSWUPB,ACSWUPBC,ACSWDNB,ACSWDNBC, & ACLWUPT,ACLWUPTC,ACLWDNT,ACLWDNTC, & ACLWUPB,ACLWUPBC,ACLWDNB,ACLWDNBC REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL, INTENT(INOUT) ::& SWUPT, SWUPTC, SWDNT, SWDNTC, & SWUPB, SWUPBC, SWDNB, SWDNBC, & LWUPT, LWUPTC, LWDNT, LWDNTC, & LWUPB, LWUPBC, LWDNB, LWDNBC REAL, DIMENSION( ims:ime, kms:kme+2, jms:jme ), & OPTIONAL, INTENT(INOUT) :: & SWUPFLX,SWUPFLXC,SWDNFLX,SWDNFLXC, & LWUPFLX,LWUPFLXC,LWDNFLX,LWDNFLXC REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL , & INTENT(INOUT) :: SWCF, & LWCF, & OLR REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL , & INTENT(IN ) :: ALSWVISDIR, & ALSWVISDIF, & ALSWNIRDIR, & ALSWNIRDIF REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL , & INTENT(OUT ) :: SWVISDIR, & SWVISDIF, & SWNIRDIR, & SWNIRDIF INTEGER, OPTIONAL, INTENT(IN ) :: sf_surface_physics REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN ) :: XLAT, & XLONG, & ALBEDO, & EMISS REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(INOUT) :: GSW, & GLW REAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: SWDOWN REAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: swddir, & swddni, & swddif REAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: Gx,Bx,gg,bb, & swdown_ref, & swddir_ref, & coszen_ref REAL, INTENT(IN ) :: GMT,dt, & julian, xtime INTEGER, INTENT(IN ),OPTIONAL :: YR INTEGER, INTENT(IN ) :: JULDAY, itimestep REAL, INTENT(IN ),OPTIONAL :: CURR_SECS LOGICAL, INTENT(IN ),OPTIONAL :: ADAPT_STEP_FLAG INTEGER,INTENT(IN) :: NPHS REAL, DIMENSION( ims:ime, jms:jme ),INTENT(OUT) :: & CFRACH, & CFRACL, & CFRACM, & CZMEAN REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(INOUT) :: & RLWTOA, & RSWTOA, & ACFRST, & ACFRCV INTEGER,DIMENSION( ims:ime, jms:jme ),INTENT(INOUT) :: & NCFRST, & NCFRCV REAL, DIMENSION(IMS:IME, JMS:JME, 1:8) :: ERBE_out REAL, DIMENSION(IMS:IME, JMS:JME), OPTIONAL, INTENT(INOUT) :: & TLWDN, TLWUP, & SLWDN, SLWUP, & TSWDN, TSWUP, & SSWDN, SSWUP REAL, DIMENSION( ims:ime, kms:kme, cam_abs_dim2, jms:jme ), OPTIONAL ,& INTENT(INOUT) :: abstot REAL, DIMENSION( ims:ime, kms:kme, cam_abs_dim1, jms:jme ), OPTIONAL ,& INTENT(INOUT) :: absnxt REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), OPTIONAL ,& INTENT(INOUT) :: emstot REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & OPTIONAL, & INTENT(INOUT) :: CLDFRA REAL, DIMENSION(ims:ime,kms:kme,jms:jme), INTENT(IN):: re_cloud, re_ice, re_snow INTEGER, INTENT(IN):: has_reqc, has_reqi, has_reqs REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & OPTIONAL, & INTENT(IN ) :: & F_ICE_PHY, & F_RAIN_PHY, & CLDFRA_MP_ALL REAL, DIMENSION( ims:ime, jms:jme ), & OPTIONAL, & INTENT(OUT) :: SWDOWNC REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & OPTIONAL, & INTENT(INOUT ) :: & pb & ,qv,qc,qr,qi,qs,qg,qndrop LOGICAL, OPTIONAL :: f_qv,f_qc,f_qr,f_qi,f_qs,f_qg,f_qndrop REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & OPTIONAL, & INTENT(INOUT) :: taucldi,taucldc REAL, OPTIONAL, INTENT(IN) :: dx,dy INTEGER, OPTIONAL, INTENT(IN) :: slope_rad,topo_shading REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL, INTENT(IN) :: ht INTEGER, DIMENSION( ims:ime, jms:jme ), OPTIONAL, INTENT(IN) :: shadowmask REAL , OPTIONAL, INTENT(INOUT) :: radtacttime REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & OPTIONAL, & INTENT(INOUT) :: o3rad REAL, DIMENSION( ims:ime, jms:jme ) :: GLAT,GLON REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) :: CEMISS REAL, DIMENSION( ims:ime, jms:jme ) :: coszr REAL, DIMENSION( ims:ime, levsiz, jms:jme ) :: ozmixt REAL, DIMENSION( ims:ime, alevsiz, jms:jme, 1:no_src_types ) :: aerodt REAL :: DECLIN,SOLCON,XXLAT,TLOCTM,XT24, CEN_LAT INTEGER :: i,j,k,its,ite,jts,jte,ij INTEGER :: STEPABS LOGICAL :: gfdl_lw,gfdl_sw LOGICAL :: doabsems LOGICAL, EXTERNAL :: wrf_dm_on_monitor INTEGER :: s REAL :: OBECL,SINOB,SXLONG,ARG,DECDEG, & DJUL,RJUL,ECCFAC REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) :: qi_temp,qc_temp REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) :: qi_save,qc_save REAL :: next_rad_time LOGICAL :: run_param , doing_adapt_dt , decided LOGICAL :: flg_lw, flg_sw REAL, OPTIONAL, INTENT(OUT) :: DECLINX,SOLCONX REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme), INTENT(OUT) :: COSZEN REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme), INTENT(OUT) :: HRANG real :: swdown_0,swddir_0,coszen_0,ioh,kt,airmass,kd real, dimension(ims:ime,jms:jme) :: coszen_loc,hrang_loc if(present(explicit_convection)) then expl_conv=explicit_convection else expl_conv=.true. endif CALL wrf_debug (1, 'Top of Radiation Driver') if (lw_physics .eq. 0 .and. sw_physics .eq. 0) return doing_adapt_dt = .FALSE. IF ( PRESENT(adapt_step_flag) ) THEN IF ( adapt_step_flag ) THEN doing_adapt_dt = .TRUE. IF ( radtacttime .eq. 0. ) THEN radtacttime = CURR_SECS + radt*60. END IF END IF END IF run_param = .FALSE. decided = .FALSE. IF ( ( .NOT. decided ) .AND. & ( itimestep .EQ. 1 ) ) THEN run_param = .TRUE. decided = .TRUE. END IF IF ( ( .NOT. decided ) .AND. & ( ( radt .EQ. 0. ) .OR. ( stepra .EQ. 1 ) ) ) THEN run_param = .TRUE. decided = .TRUE. END IF IF ( ( .NOT. decided ) .AND. & ( .NOT. doing_adapt_dt ) .AND. & ( MOD(itimestep,stepra) .EQ. 1+ra_call_offset ) ) THEN run_param = .TRUE. decided = .TRUE. END IF IF ( ( .NOT. decided ) .AND. & ( doing_adapt_dt ) .AND. & ( curr_secs .GE. radtacttime ) ) THEN run_param = .TRUE. decided = .TRUE. radtacttime = curr_secs + radt*60 END IF if(swint_opt.eq.1) then DO ij = 1 , num_tiles its = i_start(ij) ite = i_end(ij) jts = j_start(ij) jte = j_end(ij) CALL radconst(XTIME,DECLIN,SOLCON,JULIAN, & DEGRAD,DPD ) call calc_coszen(ims,ime,jms,jme,its,ite,jts,jte, & julian,xtime,gmt,declin,degrad, & xlong,xlat,coszen_loc,hrang_loc) end do end if Radiation_step: IF ( run_param ) then STEPABS = nint(cam_abs_freq_s/(dt*STEPRA))*STEPRA IF (itimestep .eq. 1 .or. mod(itimestep,STEPABS) .eq. 1 + ra_call_offset & .or. STEPABS .eq. 1 ) THEN doabsems = .true. ELSE doabsems = .false. ENDIF IF (PRESENT(adapt_step_flag)) THEN IF ((adapt_step_flag)) THEN IF ( (itimestep .EQ. 1) .OR. (cam_abs_freq_s .EQ. 0) .OR. & ( CURR_SECS + dt >= ( INT( CURR_SECS / ( cam_abs_freq_s ) + 1 ) * cam_abs_freq_s) ) ) THEN doabsems = .true. ELSE doabsems = .false. ENDIF ENDIF ENDIF gfdl_lw = .false. gfdl_sw = .false. DO ij = 1 , num_tiles its = i_start(ij) ite = i_end(ij) jts = j_start(ij) jte = j_end(ij) CALL radconst(XTIME,DECLIN,SOLCON,JULIAN, & DEGRAD,DPD ) IF(PRESENT(declinx).AND.PRESENT(solconx))THEN declinx=declin solconx=solcon ENDIF IF(PRESENT(coszen).AND.PRESENT(hrang))THEN call calc_coszen(ims,ime,jms,jme,its,ite,jts,jte, & julian,xtime+radt*0.5,gmt, & declin,degrad,xlong,xlat,coszen,hrang) ENDIF ENDDO !$OMP PARALLEL DO & !$OMP PRIVATE ( ij ,i,j,k,its,ite,jts,jte) DO ij = 1 , num_tiles its = i_start(ij) ite = i_end(ij) jts = j_start(ij) jte = j_end(ij) if ((itimestep.eq.1).and.(swint_opt.eq.1)) then do j=jts,jte do i=its,ite Bx(i,j)=0. bb(i,j)=0. Gx(i,j)=0. gg(i,j)=0. end do end do end if DO j=jts,jte DO i=its,ite GSW(I,J)=0. GLW(I,J)=0. SWDOWN(I,J)=0. swddir(i,j)=0. swddni(i,j)=0. swddif(i,j)=0. GLAT(I,J)=XLAT(I,J)*DEGRAD GLON(I,J)=XLONG(I,J)*DEGRAD ENDDO ENDDO DO j=jts,jte DO k=kts,kte+1 DO i=its,ite RTHRATEN(I,K,J)=0. RTHRATENLW(I,K,J)=0. RTHRATENSW(I,K,J)=0. CEMISS(I,K,J)=0.0 ENDDO ENDDO ENDDO IF ( PRESENT( SWUPFLX ) ) THEN DO j=jts,jte DO k=kts,kte+2 DO i=its,ite SWUPFLX(I,K,J) = 0.0 SWDNFLX(I,K,J) = 0.0 SWUPFLXC(I,K,J) = 0.0 SWDNFLXC(I,K,J) = 0.0 LWUPFLX(I,K,J) = 0.0 LWDNFLX(I,K,J) = 0.0 LWUPFLXC(I,K,J) = 0.0 LWDNFLXC(I,K,J) = 0.0 ENDDO ENDDO ENDDO ENDIF IF ( PRESENT( qc ) .AND. PRESENT( qc_adjust ) .AND. cu_rad_feedback ) THEN DO j=jts,jte DO k=kts,kte DO i=its,ite qc_save(i,k,j) = qc(i,k,j) qc(i,k,j) = qc(i,k,j) + qc_adjust(i,k,j) ENDDO ENDDO ENDDO ENDIF IF ( PRESENT( qi ) .AND. PRESENT( qi_adjust ) .AND. cu_rad_feedback ) THEN DO j=jts,jte DO k=kts,kte DO i=its,ite qi_save(i,k,j) = qi(i,k,j) qi(i,k,j) = qi(i,k,j) + qi_adjust(i,k,j) ENDDO ENDDO ENDDO ENDIF if(PRESENT(qc) .and. PRESENT(F_QC)) then DO j=jts,jte DO k=kts,kte DO i=its,ite qc_temp(I,K,J)=qc(I,K,J) ENDDO ENDDO ENDDO else DO j=jts,jte DO k=kts,kte DO i=its,ite qc_temp(I,K,J)=0. ENDDO ENDDO ENDDO endif lwrad_cldfra_select: SELECT CASE(lw_physics) CASE (GFDLLWSCHEME) CASE (CAMLWSCHEME) IF ( PRESENT ( CLDFRA ) .AND. & PRESENT(F_QC) .AND. PRESENT ( F_QI ) ) THEN CALL cal_cldfra2(CLDFRA,qv,qc,qi,qs, & F_QV,F_QC,F_QI,F_QS,t,p, & F_ICE_PHY,F_RAIN_PHY, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) ENDIF CASE (RRTMG_LWSCHEME) IF ( PRESENT ( CLDFRA ) .AND. & PRESENT(F_QC) .AND. PRESENT ( F_QI ) ) THEN CALL cal_cldfra2(CLDFRA,qv,qc,qi,qs, & F_QV,F_QC,F_QI,F_QS,t,p, & F_ICE_PHY,F_RAIN_PHY, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) IF ( PRESENT (cldfra_mp_all) ) THEN IF (is_CAMMGMP_used) THEN IF (itimestep .NE. 1) THEN DO j=jts,jte DO k=kts,kte DO i=its,ite CLDFRA(i,k,j) = CLDFRA_MP_ALL(I,K,J) if (CLDFRA(i,k,j) .lt. 0.01) CLDFRA(i,k,j) = 0. ENDDO ENDDO ENDDO ENDIF ENDIF ENDIF ENDIF CASE DEFAULT IF ( PRESENT ( CLDFRA ) .AND. & PRESENT(F_QC) .AND. PRESENT ( F_QI ) ) THEN CALL cal_cldfra(CLDFRA,qc,qi,F_QC,F_QI, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) ENDIF END SELECT lwrad_cldfra_select IF ( PRESENT( O3RAD ) ) THEN IF ( o3input .EQ. 2 .AND. id .EQ. 1 ) THEN call ozn_time_int(julday,julian,ozmixm,ozmixt,levsiz,n_ozmixm, & ids , ide , jds , jde , kds , kde , & ims , ime , jms , jme , kms , kme , & its , ite , jts , jte , kts , kte ) call ozn_p_int(p ,pin, levsiz, ozmixt, o3rad, & ids , ide , jds , jde , kds , kde , & ims , ime , jms , jme , kms , kme , & its , ite , jts , jte , kts , kte ) ENDIF ENDIF IF ( PRESENT( AEROD ) ) THEN IF ( aer_opt .EQ. 1 .AND. id .EQ. 1 ) THEN call aer_time_int(julday,julian,aerodm,aerodt,alevsiz,n_ozmixm-1,no_src_types, & ids , ide , jds , jde , kds , kde , & ims , ime , jms , jme , kms , kme , & its , ite , jts , jte , kts , kte ) call aer_p_int(p ,pina, alevsiz, aerodt, aerod, no_src_types, p8w, AODTOT, & ids , ide , jds , jde , kds , kde , & ims , ime , jms , jme , kms , kme , & its , ite , jts , jte , kts , kte ) ENDIF ENDIF lwrad_select: SELECT CASE(lw_physics) CASE (RRTMSCHEME) CALL wrf_debug (100, 'CALL rrtm') CALL RRTMLWRAD( & RTHRATEN=RTHRATEN,GLW=GLW,OLR=RLWTOA,EMISS=EMISS & ,QV3D=QV & ,QC3D=QC & ,QR3D=QR & ,QI3D=QI & ,QS3D=QS & ,QG3D=QG & ,P8W=p8w,P3D=p,PI3D=pi,DZ8W=dz8w,TSK=tsk,T3D=t & ,T8W=t8w,RHO3D=rho, CLDFRA3D=CLDFRA,R=R_d,G=G & ,F_QV=F_QV,F_QC=F_QC,F_QR=F_QR & ,F_QI=F_QI,F_QS=F_QS,F_QG=F_QG & ,ICLOUD=icloud,WARM_RAIN=warm_rain & ,YR=YR,JULIAN=JULIAN & ,IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde & ,IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme & ,ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte & ) CASE (goddardlwscheme) CALL wrf_debug (100, 'CALL goddard longwave radiation scheme ') IF (itimestep.eq.1) then call wrf_message('running goddard lw radiation') ENDIF CALL goddardrad(sw_or_lw='lw' & ,rthraten=rthraten,gsf=glw,xlat=xlat,xlong=xlong & ,alb=albedo,t3d=t,p3d=p,p8w3d=p8w,pi3d=pi & ,dz8w=dz8w,rho_phy=rho,emiss=emiss & ,cldfra3d=cldfra & ,gmt=gmt,cp=cp,g=g,t8w=t8w & ,julday=julday,xtime=xtime & ,declin=declin,solcon=solcon & , center_lat = cen_lat & ,radfrq=radt,degrad=degrad & ,taucldi=taucldi,taucldc=taucldc & ,warm_rain=warm_rain & ,ids=ids,ide=ide, jds=jds,jde=jde, kds=kds,kde=kde & ,ims=ims,ime=ime, jms=jms,jme=jme, kms=kms,kme=kme & ,its=its,ite=ite, jts=jts,jte=jte, kts=kts,kte=kte & ,qv3d=qv & ,qc3d=qc & ,qr3d=qr & ,qi3d=qi & ,qs3d=qs & ,qg3d=qg & ,f_qv=f_qv,f_qc=f_qc,f_qr=f_qr & ,f_qi=f_qi,f_qs=f_qs,f_qg=f_qg & ,erbe_out=erbe_out & ) CASE (GFDLLWSCHEME) CALL wrf_debug (100, 'CALL gfdllw') IF ( PRESENT(F_QV) .AND. PRESENT(F_QC) .AND. & PRESENT(F_QS) .AND. PRESENT(qs) .AND. & PRESENT(qv) .AND. PRESENT(qc) ) THEN IF ( F_QV .AND. F_QC .AND. F_QS) THEN gfdl_lw = .true. CALL ETARA( & DT=dt,XLAND=xland & ,P8W=p8w,DZ8W=dz8w,RHO_PHY=rho,P_PHY=p,T=t & ,QV=qv,QW=qc_temp,QI=qi,QS=qs & ,TSK2D=tsk,GLW=GLW,RSWIN=SWDOWN,GSW=GSW & ,RSWINC=SWDOWNC,CLDFRA=CLDFRA,PI3D=pi & ,GLAT=glat,GLON=glon,HTOP=htop,HBOT=hbot & ,HBOTR=hbotr, HTOPR=htopr & ,ALBEDO=albedo,CUPPT=cuppt & ,VEGFRA=vegfra,SNOW=snow,G=g,GMT=gmt & ,NSTEPRA=stepra,NPHS=nphs,ITIMESTEP=itimestep & ,XTIME=xtime,JULIAN=julian & ,JULYR=julyr,JULDAY=julday & ,GFDL_LW=gfdl_lw,GFDL_SW=gfdl_sw & ,CFRACL=cfracl,CFRACM=cfracm,CFRACH=cfrach & ,ACFRST=acfrst,NCFRST=ncfrst & ,ACFRCV=acfrcv,NCFRCV=ncfrcv & ,RSWTOA=rswtoa,RLWTOA=rlwtoa,CZMEAN=czmean & ,THRATEN=rthraten,THRATENLW=rthratenlw & ,THRATENSW=rthratensw & ,IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde & ,IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme & ,ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte & ) ELSE CALL wrf_error_fatal3("",1104,& 'Can not call ETARA (1a). Missing moisture fields.') ENDIF ELSE CALL wrf_error_fatal3("",1108,& 'Can not call ETARA (1b). Missing moisture fields.') ENDIF CASE (CAMLWSCHEME) CALL wrf_debug(100, 'CALL camrad lw') IF ( PRESENT( OZMIXM ) .AND. PRESENT( PIN ) .AND. & PRESENT(M_PS_1) .AND. PRESENT(M_PS_2) .AND. & PRESENT(M_HYBI0) .AND. PRESENT(AEROSOLC_1) & .AND. PRESENT(AEROSOLC_2).AND. PRESENT(ALSWVISDIR) ) THEN CALL CAMRAD(RTHRATENLW=RTHRATEN,RTHRATENSW=RTHRATENSW, & dolw=.true.,dosw=.false., & SWUPT=SWUPT,SWUPTC=SWUPTC, & SWDNT=SWDNT,SWDNTC=SWDNTC, & LWUPT=LWUPT,LWUPTC=LWUPTC, & LWDNT=LWDNT,LWDNTC=LWDNTC, & SWUPB=SWUPB,SWUPBC=SWUPBC, & SWDNB=SWDNB,SWDNBC=SWDNBC, & LWUPB=LWUPB,LWUPBC=LWUPBC, & LWDNB=LWDNB,LWDNBC=LWDNBC, & SWCF=SWCF,LWCF=LWCF,OLR=RLWTOA,CEMISS=CEMISS, & TAUCLDC=TAUCLDC,TAUCLDI=TAUCLDI,COSZR=COSZR, & GSW=GSW,GLW=GLW,XLAT=XLAT,XLONG=XLONG, & ALBEDO=ALBEDO,t_phy=t,TSK=TSK,EMISS=EMISS & ,QV3D=qv & ,QC3D=qc & ,QR3D=qr & ,QI3D=qi & ,QS3D=qs & ,QG3D=qg & ,ALSWVISDIR=alswvisdir ,ALSWVISDIF=alswvisdif & ,ALSWNIRDIR=alswnirdir ,ALSWNIRDIF=alswnirdif & ,SWVISDIR=swvisdir ,SWVISDIF=swvisdif & ,SWNIRDIR=swnirdir ,SWNIRDIF=swnirdif & ,SF_SURFACE_PHYSICS=sf_surface_physics & ,F_QV=f_qv,F_QC=f_qc,F_QR=f_qr & ,F_QI=f_qi,F_QS=f_qs,F_QG=f_qg & ,f_ice_phy=f_ice_phy,f_rain_phy=f_rain_phy & ,p_phy=p,p8w=p8w,z=z,pi_phy=pi,rho_phy=rho, & dz8w=dz8w, & CLDFRA=CLDFRA,XLAND=XLAND,XICE=XICE,SNOW=SNOW, & ozmixm=ozmixm,pin0=pin,levsiz=levsiz, & num_months=n_ozmixm, & m_psp=m_ps_1,m_psn=m_ps_2,aerosolcp=aerosolc_1, & aerosolcn=aerosolc_2,m_hybi0=m_hybi0, & paerlev=paerlev, naer_c=n_aerosolc, & cam_abs_dim1=cam_abs_dim1, cam_abs_dim2=cam_abs_dim2, & GMT=GMT,JULDAY=JULDAY,JULIAN=JULIAN,YR=YR,DT=DT,XTIME=XTIME,DECLIN=DECLIN, & SOLCON=SOLCON,RADT=RADT,DEGRAD=DEGRAD,n_cldadv=3 & ,abstot_3d=abstot,absnxt_3d=absnxt,emstot_3d=emstot & ,doabsems=doabsems & ,IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde & ,IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme & ,ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte & ) ELSE CALL wrf_error_fatal3("",1167,& 'arguments not present for calling cam radiation' ) ENDIF CASE (RRTMG_LWSCHEME) CALL wrf_debug (100, 'CALL rrtmg_lw') CALL RRTMG_LWRAD( & RTHRATENLW=RTHRATEN, & LWUPT=LWUPT,LWUPTC=LWUPTC, & LWDNT=LWDNT,LWDNTC=LWDNTC, & LWUPB=LWUPB,LWUPBC=LWUPBC, & LWDNB=LWDNB,LWDNBC=LWDNBC, & GLW=GLW,OLR=RLWTOA,LWCF=LWCF, & EMISS=EMISS, & P8W=p8w,P3D=p,PI3D=pi,DZ8W=dz8w,TSK=tsk,T3D=t, & T8W=t8w,RHO3D=rho,R=R_d,G=G, & ICLOUD=icloud,WARM_RAIN=warm_rain,CLDFRA3D=CLDFRA,& F_ICE_PHY=F_ICE_PHY,F_RAIN_PHY=F_RAIN_PHY, & XLAND=XLAND,XICE=XICE,SNOW=SNOW, & QV3D=QV,QC3D=QC,QR3D=QR, & QI3D=QI,QS3D=QS,QG3D=QG, & O3INPUT=O3INPUT,O33D=O3RAD, & F_QV=F_QV,F_QC=F_QC,F_QR=F_QR, & F_QI=F_QI,F_QS=F_QS,F_QG=F_QG, & RE_CLOUD=re_cloud,RE_ICE=re_ice,RE_SNOW=re_snow, & has_reqc=has_reqc,has_reqi=has_reqi,has_reqs=has_reqs, & QNDROP3D=qndrop,F_QNDROP=f_qndrop, & YR=YR,JULIAN=JULIAN, & IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde,& IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme,& ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte,& LWUPFLX=LWUPFLX,LWUPFLXC=LWUPFLXC, & LWDNFLX=LWDNFLX,LWDNFLXC=LWDNFLXC & ) CASE (HELDSUAREZ) CALL wrf_debug (100, 'CALL heldsuarez') CALL HSRAD(RTHRATEN,p8w,p,pi,dz8w,t, & t8w, rho, R_d,G,CP, dt, xlat, degrad, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) CASE (FLGLWSCHEME) CALL wrf_debug (100, 'CALL Fu-Liou-Gu') flg_lw = .true. ozflg = 0. CALL RAD_FLG( & peven=p8w,podd=p,t8w=t8w,degrees=t & ,pi3d=pi,o3=ozflg & ,G=G,CP=CP & ,albedo=ALBEDO,tskin=tsk & ,h2o=QV,cld_iccld=QI,cld_wlcld=QC & ,cld_prwc=QR,cld_pgwc=QG,cld_snow=QS & ,F_QV=F_QV,F_QC=F_QC,F_QR=F_QR & ,F_QI=F_QI,F_QS=F_QS,F_QG=F_QG & ,warm_rain=warm_rain & ,cloudstrf=CLDFRA & ,emiss=EMISS & ,air_den=rho & ,dz3d=dz8w & ,SOLCON=SOLCON & ,declin=DECLIN & ,xtime=xtime, xlong=xlong, xlat=xlat & ,JULDAY=JULDAY & ,gmt=gmt, radt=radt, degrad=degrad & ,dtcolumn=dt & ,ids=ids,ide=ide,jds=jds,jde=jde & ,kds=kds,kde=kde & ,ims=ims,idim=ime,jms=jms,jdim=jme & ,kms=kms,kmax=kme & ,its=its,ite=ite,jts=jts,jte=jte & ,kts=kts,kte=kte & ,uswtop=RSWTOA,ulwtop=RLWTOA & ,NETSWBOT=GSW,DLWBOT=GLW & ,DSWBOT=SWDOWN,deltat=RTHRATEN & ,dtshort=RTHRATENSW,dtlongwv=RTHRATENLW & ) CALL wrf_debug(100, 'a4 Fu_Liou-Gu') CASE DEFAULT WRITE( wrf_err_message , * ) 'The longwave option does not exist: lw_physics = ', lw_physics CALL wrf_error_fatal3("",1260,& wrf_err_message ) END SELECT lwrad_select IF (lw_physics .gt. 0 .and. .not.gfdl_lw) THEN DO j=jts,jte DO k=kts,kte DO i=its,ite RTHRATENLW(I,K,J)=RTHRATEN(I,K,J) IF(PRESENT(OLR) .AND. K .EQ. 1)OLR(I,J)=RLWTOA(I,J) ENDDO ENDDO ENDDO ENDIF IF (lw_physics .eq. goddardlwscheme) THEN IF ( PRESENT (tlwdn) ) THEN DO j=jts,jte DO i=its,ite tlwdn(i,j) = erbe_out(i,j,1) tlwup(i,j) = erbe_out(i,j,2) slwdn(i,j) = erbe_out(i,j,3) slwup(i,j) = erbe_out(i,j,4) ENDDO ENDDO ENDIF ENDIF swrad_cldfra_select: SELECT CASE(sw_physics) CASE (CAMSWSCHEME) IF ( PRESENT ( CLDFRA ) .AND. & PRESENT(F_QC) .AND. PRESENT ( F_QI ) ) THEN CALL cal_cldfra2(CLDFRA,qv,qc,qi,qs, & F_QV,F_QC,F_QI,F_QS,t,p, & F_ICE_PHY,F_RAIN_PHY, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) ENDIF CASE (RRTMG_SWSCHEME) IF ( PRESENT ( CLDFRA ) .AND. & PRESENT(F_QC) .AND. PRESENT ( F_QI ) ) THEN CALL cal_cldfra2(CLDFRA,qv,qc,qi,qs, & F_QV,F_QC,F_QI,F_QS,t,p, & F_ICE_PHY,F_RAIN_PHY, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) ENDIF CASE DEFAULT END SELECT swrad_cldfra_select swrad_select: SELECT CASE(sw_physics) CASE (SWRADSCHEME) CALL wrf_debug(100, 'CALL swrad') CALL SWRAD( & DT=dt,RTHRATEN=rthraten,GSW=gsw & ,XLAT=xlat,XLONG=xlong,ALBEDO=albedo & ,RHO_PHY=rho,T3D=t & ,P3D=p,PI3D=pi,DZ8W=dz8w,GMT=gmt & ,R=r_d,CP=cp,G=g,JULDAY=julday & ,XTIME=xtime,DECLIN=declin,SOLCON=solcon & ,RADFRQ=radt,ICLOUD=icloud,DEGRAD=degrad & ,warm_rain=warm_rain & ,IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde & ,IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme & ,ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte & ,QV3D=qv & ,QC3D=qc & ,QR3D=qr & ,QI3D=qi & ,QS3D=qs & ,QG3D=qg & ,F_QV=f_qv,F_QC=f_qc,F_QR=f_qr & ,F_QI=f_qi,F_QS=f_qs,F_QG=f_qg & ,coszen=coszen,julian=julian ) CASE (GSFCSWSCHEME) CALL wrf_debug(100, 'CALL gsfcswrad') CALL GSFCSWRAD( & RTHRATEN=rthraten,GSW=gsw,XLAT=xlat,XLONG=xlong & ,ALB=albedo,T3D=t,P3D=p,P8W3D=p8w,pi3D=pi & ,DZ8W=dz8w,RHO_PHY=rho & ,CLDFRA3D=cldfra,RSWTOA=rswtoa & ,GMT=gmt,CP=cp,G=g & ,JULDAY=julday,XTIME=xtime & ,DECLIN=declin,SOLCON=solcon & ,RADFRQ=radt,DEGRAD=degrad & ,TAUCLDI=taucldi,TAUCLDC=taucldc & ,WARM_RAIN=warm_rain & ,IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde & ,IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme & ,ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte & ,QV3D=qv & ,QC3D=qc & ,QR3D=qr & ,QI3D=qi & ,QS3D=qs & ,QG3D=qg & ,QNDROP3D=qndrop & ,F_QV=f_qv,F_QC=f_qc,F_QR=f_qr & ,F_QI=f_qi,F_QS=f_qs,F_QG=f_qg & ,F_QNDROP=f_qndrop & ) CASE (goddardswscheme) CALL wrf_debug(100, 'CALL goddard shortwave radiation scheme ') IF (itimestep.eq.1) then call wrf_message('running goddard sw radiation') ENDIF CALL goddardrad(sw_or_lw='sw' & ,rthraten=rthraten,gsf=gsw,xlat=xlat,xlong=xlong & ,alb=albedo,t3d=t,p3d=p,p8w3d=p8w,pi3d=pi & ,dz8w=dz8w,rho_phy=rho,emiss=emiss & ,cldfra3d=cldfra & ,gmt=gmt,cp=cp,g=g,t8w=t8w & ,julday=julday,xtime=xtime & ,declin=declin,solcon=solcon & ,center_lat = cen_lat & ,radfrq=radt,degrad=degrad & ,taucldi=taucldi,taucldc=taucldc & ,warm_rain=warm_rain & ,ids=ids,ide=ide, jds=jds,jde=jde, kds=kds,kde=kde & ,ims=ims,ime=ime, jms=jms,jme=jme, kms=kms,kme=kme & ,its=its,ite=ite, jts=jts,jte=jte, kts=kts,kte=kte & ,qv3d=qv & ,qc3d=qc & ,qr3d=qr & ,qi3d=qi & ,qs3d=qs & ,qg3d=qg & ,f_qv=f_qv,f_qc=f_qc,f_qr=f_qr & ,f_qi=f_qi,f_qs=f_qs,f_qg=f_qg & ,erbe_out=erbe_out & ,swddir=swddir,swddni=swddni,swddif=swddif & ,coszen=coszen,julian=julian & ) CASE (CAMSWSCHEME) CALL wrf_debug(100, 'CALL camrad sw') IF ( PRESENT( OZMIXM ) .AND. PRESENT( PIN ) .AND. & PRESENT(M_PS_1) .AND. PRESENT(M_PS_2) .AND. & PRESENT(M_HYBI0) .AND. PRESENT(AEROSOLC_1) & .AND. PRESENT(AEROSOLC_2) .AND. PRESENT(ALSWVISDIR)) THEN CALL CAMRAD(RTHRATENLW=RTHRATEN,RTHRATENSW=RTHRATENSW, & dolw=.false.,dosw=.true., & SWUPT=SWUPT,SWUPTC=SWUPTC, & SWDNT=SWDNT,SWDNTC=SWDNTC, & LWUPT=LWUPT,LWUPTC=LWUPTC, & LWDNT=LWDNT,LWDNTC=LWDNTC, & SWUPB=SWUPB,SWUPBC=SWUPBC, & SWDNB=SWDNB,SWDNBC=SWDNBC, & LWUPB=LWUPB,LWUPBC=LWUPBC, & LWDNB=LWDNB,LWDNBC=LWDNBC, & SWCF=SWCF,LWCF=LWCF,OLR=RLWTOA,CEMISS=CEMISS, & TAUCLDC=TAUCLDC,TAUCLDI=TAUCLDI,COSZR=COSZR, & GSW=GSW,GLW=GLW,XLAT=XLAT,XLONG=XLONG, & ALBEDO=ALBEDO,t_phy=t,TSK=TSK,EMISS=EMISS & ,QV3D=qv & ,QC3D=qc & ,QR3D=qr & ,QI3D=qi & ,QS3D=qs & ,QG3D=qg & ,ALSWVISDIR=alswvisdir ,ALSWVISDIF=alswvisdif & ,ALSWNIRDIR=alswnirdir ,ALSWNIRDIF=alswnirdif & ,SWVISDIR=swvisdir ,SWVISDIF=swvisdif & ,SWNIRDIR=swnirdir ,SWNIRDIF=swnirdif & ,SF_SURFACE_PHYSICS=sf_surface_physics & ,F_QV=f_qv,F_QC=f_qc,F_QR=f_qr & ,F_QI=f_qi,F_QS=f_qs,F_QG=f_qg & ,f_ice_phy=f_ice_phy,f_rain_phy=f_rain_phy & ,p_phy=p,p8w=p8w,z=z,pi_phy=pi,rho_phy=rho, & dz8w=dz8w, & CLDFRA=CLDFRA,XLAND=XLAND,XICE=XICE,SNOW=SNOW, & ozmixm=ozmixm,pin0=pin,levsiz=levsiz, & num_months=n_ozmixm, & m_psp=m_ps_1,m_psn=m_ps_2,aerosolcp=aerosolc_1, & aerosolcn=aerosolc_2,m_hybi0=m_hybi0, & paerlev=paerlev, naer_c=n_aerosolc, & cam_abs_dim1=cam_abs_dim1, cam_abs_dim2=cam_abs_dim2, & GMT=GMT,JULDAY=JULDAY,JULIAN=JULIAN,YR=YR,DT=DT,XTIME=XTIME,DECLIN=DECLIN, & SOLCON=SOLCON,RADT=RADT,DEGRAD=DEGRAD,n_cldadv=3 & ,abstot_3d=abstot,absnxt_3d=absnxt,emstot_3d=emstot & ,doabsems=doabsems & ,IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde & ,IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme & ,ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte & ) ELSE CALL wrf_error_fatal3("",1466,& 'arguments not present for calling cam radiation' ) ENDIF DO j=jts,jte DO k=kts,kte DO i=its,ite RTHRATEN(I,K,J)=RTHRATEN(I,K,J)+RTHRATENSW(I,K,J) ENDDO ENDDO ENDDO CASE (RRTMG_SWSCHEME) CALL wrf_debug(100, 'CALL rrtmg_sw') CALL RRTMG_SWRAD( & RTHRATENSW=RTHRATENSW, & SWUPT=SWUPT,SWUPTC=SWUPTC, & SWDNT=SWDNT,SWDNTC=SWDNTC, & SWUPB=SWUPB,SWUPBC=SWUPBC, & SWDNB=SWDNB,SWDNBC=SWDNBC, & SWCF=SWCF,GSW=GSW, & XTIME=XTIME,GMT=GMT,XLAT=XLAT,XLONG=XLONG, & RADT=RADT,DEGRAD=DEGRAD,DECLIN=DECLIN, & COSZR=COSZR,JULDAY=JULDAY,SOLCON=SOLCON, & ALBEDO=ALBEDO,t3d=t,t8w=t8w,TSK=TSK, & p3d=p,p8w=p8w,pi3d=pi,rho3d=rho, & dz8w=dz8w,CLDFRA3D=CLDFRA,R=R_D,G=G, & ICLOUD=icloud,WARM_RAIN=warm_rain, & F_ICE_PHY=F_ICE_PHY,F_RAIN_PHY=F_RAIN_PHY, & XLAND=XLAND,XICE=XICE,SNOW=SNOW, & QV3D=qv,QC3D=qc,QR3D=qr, & QI3D=qi,QS3D=qs,QG3D=qg, & O3INPUT=O3INPUT,O33D=O3RAD, & AER_OPT=AER_OPT,aerod=aerod,no_src=no_src_types, & ALSWVISDIR=alswvisdir ,ALSWVISDIF=alswvisdif, & ALSWNIRDIR=alswnirdir ,ALSWNIRDIF=alswnirdif, & SWVISDIR=swvisdir ,SWVISDIF=swvisdif, & SWNIRDIR=swnirdir ,SWNIRDIF=swnirdif, & SF_SURFACE_PHYSICS=sf_surface_physics, & F_QV=f_qv,F_QC=f_qc,F_QR=f_qr, & F_QI=f_qi,F_QS=f_qs,F_QG=f_qg, & RE_CLOUD=re_cloud,RE_ICE=re_ice,RE_SNOW=re_snow, & has_reqc=has_reqc,has_reqi=has_reqi,has_reqs=has_reqs, & QNDROP3D=qndrop,F_QNDROP=f_qndrop, & IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde,& IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme,& ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte,& SWUPFLX=SWUPFLX,SWUPFLXC=SWUPFLXC, & SWDNFLX=SWDNFLX,SWDNFLXC=SWDNFLXC, & swddir=swddir,swddni=swddni,swddif=swddif, & xcoszen=coszen,julian=julian ) DO j=jts,jte DO k=kts,kte DO i=its,ite RTHRATEN(I,K,J)=RTHRATEN(I,K,J)+RTHRATENSW(I,K,J) ENDDO ENDDO ENDDO CASE (GFDLSWSCHEME) CALL wrf_debug (100, 'CALL gfdlsw') IF ( PRESENT(F_QV) .AND. PRESENT(F_QC) .AND. & PRESENT(F_QS) .AND. PRESENT(qs) .AND. & PRESENT(qv) .AND. PRESENT(qc) ) THEN IF ( F_QV .AND. F_QC .AND. F_QS ) THEN gfdl_sw = .true. CALL ETARA( & DT=dt,XLAND=xland & ,P8W=p8w,DZ8W=dz8w,RHO_PHY=rho,P_PHY=p,T=t & ,QV=qv,QW=qc_temp,QI=qi,QS=qs & ,TSK2D=tsk,GLW=GLW,RSWIN=SWDOWN,GSW=GSW & ,RSWINC=SWDOWNC,CLDFRA=CLDFRA,PI3D=pi & ,GLAT=glat,GLON=glon,HTOP=htop,HBOT=hbot & ,HBOTR=hbotr, HTOPR=htopr & ,ALBEDO=albedo,CUPPT=cuppt & ,VEGFRA=vegfra,SNOW=snow,G=g,GMT=gmt & ,NSTEPRA=stepra,NPHS=nphs,ITIMESTEP=itimestep & ,XTIME=xtime,JULIAN=julian & ,JULYR=julyr,JULDAY=julday & ,GFDL_LW=gfdl_lw,GFDL_SW=gfdl_sw & ,CFRACL=cfracl,CFRACM=cfracm,CFRACH=cfrach & ,ACFRST=acfrst,NCFRST=ncfrst & ,ACFRCV=acfrcv,NCFRCV=ncfrcv & ,RSWTOA=rswtoa,RLWTOA=rlwtoa,CZMEAN=czmean & ,THRATEN=rthraten,THRATENLW=rthratenlw & ,THRATENSW=rthratensw & ,IDS=ids,IDE=ide, JDS=jds,JDE=jde, KDS=kds,KDE=kde & ,IMS=ims,IME=ime, JMS=jms,JME=jme, KMS=kms,KME=kme & ,ITS=its,ITE=ite, JTS=jts,JTE=jte, KTS=kts,KTE=kte & ) ELSE CALL wrf_error_fatal3("",1559,& 'Can not call ETARA (2a). Missing moisture fields.') ENDIF ELSE CALL wrf_error_fatal3("",1563,& 'Can not call ETARA (2b). Missing moisture fields.') ENDIF CASE (0) IF (lw_physics /= HELDSUAREZ) THEN WRITE( wrf_err_message , * ) & 'You have selected a longwave radiation option, but not a shortwave option (sw_physics = 0, lw_physics = ',lw_physics,')' CALL wrf_error_fatal3("",1575,& wrf_err_message ) END IF CASE (FLGSWSCHEME) flg_sw = .true. CASE DEFAULT WRITE( wrf_err_message , * ) 'The shortwave option does not exist: sw_physics = ', sw_physics CALL wrf_error_fatal3("",1589,& wrf_err_message ) END SELECT swrad_select IF (sw_physics .eq. goddardswscheme) THEN IF ( PRESENT (tswdn) ) THEN DO j=jts,jte DO i=its,ite tswdn(i,j) = erbe_out(i,j,5) tswup(i,j) = erbe_out(i,j,6) sswdn(i,j) = erbe_out(i,j,7) sswup(i,j) = erbe_out(i,j,8) ENDDO ENDDO ENDIF ENDIF IF (sw_physics .gt. 0 .and. .not.gfdl_sw) THEN DO j=jts,jte DO k=kts,kte DO i=its,ite RTHRATENSW(I,K,J)=RTHRATEN(I,K,J)-RTHRATENLW(I,K,J) ENDDO ENDDO ENDDO DO j=jts,jte DO i=its,ite SWDOWN(I,J)=GSW(I,J)/(1.-ALBEDO(I,J)) ENDDO ENDDO ENDIF if ((sw_physics .ne. rrtmg_swscheme) .and. (sw_physics .ne. goddardswscheme)) then do j=jts,jte do i=its,ite ioh=solcon*coszen(i,j) kt=swdown(i,j)/max(ioh,1e-3) airmass=exp(-ht(i,j)/8434.5)/(coszen(i,j)+ & 0.50572*((1.5707963267948966-acos(coszen(i,j)))*57.295779513082323+6.07995)**-1.6364) kt=kt/(0.1+1.031*exp(-1.4/(0.9+(9.4/max(airmass,1e-3))))) kd=0.952-1.041*exp(-exp(2.300-4.702*kt)) swddif(i,j)=kd*swdown(i,j) swddir(i,j)=(1.-kd)*swdown(i,j) swddni(i,j)=swddir(i,j)/max(coszen(i,j),1e-4) end do end do end if IF ( PRESENT( qc ) .AND. PRESENT( qc_adjust ) .AND. cu_rad_feedback ) THEN DO j=jts,jte DO k=kts,kte DO i=its,ite qc(i,k,j) = qc_save(i,k,j) ENDDO ENDDO ENDDO ENDIF IF ( PRESENT( qi ) .AND. PRESENT( qi_adjust ) .AND. cu_rad_feedback ) THEN DO j=jts,jte DO k=kts,kte DO i=its,ite qi(i,k,j) = qi_save(i,k,j) ENDDO ENDDO ENDDO ENDIF if (swint_opt.eq.1) then do j=jts,jte do i=its,ite if ((coszen(i,j).gt.1e-4) .and. (coszen_loc(i,j).gt.1e-4)) then if (Bx(i,j).le.0) then swddir_0 =(coszen_loc(i,j)/coszen(i,j))*swddir(i,j) coszen_0 =coszen_loc(i,j) else swddir_0 =swddir_ref(i,j) coszen_0 =coszen_ref(i,j) end if if ((coszen(i,j)/coszen_0).lt.1.) then bb(i,j) =log(max(1.,swddir(i,j))/max(1.,swddir_0)) / log(min(1.-1e-4,coszen(i,j)/coszen_0)) elseif ((coszen(i,j)/coszen_0).gt.1) then bb(i,j) =log(max(1.,swddir(i,j))/max(1.,swddir_0)) / log(max(1.+1e-4,coszen(i,j)/coszen_0)) else bb(i,j) =0. end if bb(i,j) =max(-.5,min(2.5,bb(i,j))) Bx(i,j) =swddir(i,j)/(coszen(i,j)**bb(i,j)) if (Gx(i,j).le.0) then swdown_0 =(coszen_loc(i,j)/coszen(i,j))*swdown(i,j) coszen_0 =coszen_loc(i,j) else swdown_0 =swdown_ref(i,j) coszen_0 =coszen_ref(i,j) end if if ((coszen(i,j)/coszen_0).lt.1.) then gg(i,j) =log(max(1.,swdown(i,j))/max(1.,swdown_0)) / log(min(1.-1e-4,coszen(i,j)/coszen_0)) elseif ((coszen(i,j)/coszen_0).gt.1) then gg(i,j) =log(max(1.,swdown(i,j))/max(1.,swdown_0)) / log(max(1.+1e-4,coszen(i,j)/coszen_0)) else gg(i,j) =0. end if gg(i,j) =max(-.5,min(2.5,gg(i,j))) Gx(i,j) =swdown(i,j)/(coszen(i,j)**gg(i,j)) coszen_ref(i,j) =coszen(i,j) swdown_ref(i,j) =swdown(i,j) swddir_ref(i,j) =swddir(i,j) else Bx(i,j) =0. bb(i,j) =0. Gx(i,j) =0. gg(i,j) =0. end if end do end do end if ENDDO !$OMP END PARALLEL DO ENDIF Radiation_step if (swint_opt .eq. 1) then call wrf_debug(100,'SW surface irradiance interpolation') !$OMP PARALLEL DO & !$OMP PRIVATE ( ij ,i,j,k,its,ite,jts,jte) do ij = 1,num_tiles its = i_start(ij) ite = i_end(ij) jts = j_start(ij) jte = j_end(ij) do j=jts,jte do i=its,ite if ((coszen_ref(i,j).gt.1e-4) .and. (coszen_loc(i,j).gt.1e-4)) then if ((bb(i,j).eq.-0.5).or.(bb(i,j).eq.2.5)) then swddir(i,j) =(coszen_loc(i,j)/coszen_ref(i,j))*swddir_ref(i,j) else swddir(i,j) =Bx(i,j)*(coszen_loc(i,j)**bb(i,j)) end if if ((gg(i,j).eq.-0.5).or.(gg(i,j).eq.2.5)) then swdown(i,j) =(coszen_loc(i,j)/coszen_ref(i,j))*swdown_ref(i,j) else swdown(i,j) =Gx(i,j)*(coszen_loc(i,j)**gg(i,j)) end if swddif(i,j) =swdown(i,j)-swddir(i,j) swddni(i,j) =swddir(i,j)/coszen_loc(i,j) gsw(i,j) =swdown(i,j)*(1.-albedo(i,j)) else swddir(i,j) =0. swdown(i,j) =0. swddif(i,j) =0. swddni(i,j) =0. gsw(i,j) =0. end if end do end do enddo !$OMP END PARALLEL DO end if accumulate_lw_select: SELECT CASE(lw_physics) CASE (CAMLWSCHEME,RRTMG_LWSCHEME) IF(PRESENT(LWUPTC))THEN !$OMP PARALLEL DO & !$OMP PRIVATE ( ij ,i,j,k,its,ite,jts,jte) DO ij = 1 , num_tiles its = i_start(ij) ite = i_end(ij) jts = j_start(ij) jte = j_end(ij) DO j=jts,jte DO i=its,ite ACLWUPT(I,J) = ACLWUPT(I,J) + LWUPT(I,J)*DT ACLWUPTC(I,J) = ACLWUPTC(I,J) + LWUPTC(I,J)*DT ACLWDNT(I,J) = ACLWDNT(I,J) + LWDNT(I,J)*DT ACLWDNTC(I,J) = ACLWDNTC(I,J) + LWDNTC(I,J)*DT ACLWUPB(I,J) = ACLWUPB(I,J) + LWUPB(I,J)*DT ACLWUPBC(I,J) = ACLWUPBC(I,J) + LWUPBC(I,J)*DT ACLWDNB(I,J) = ACLWDNB(I,J) + LWDNB(I,J)*DT ACLWDNBC(I,J) = ACLWDNBC(I,J) + LWDNBC(I,J)*DT ENDDO ENDDO ENDDO !$OMP END PARALLEL DO ENDIF CASE DEFAULT END SELECT accumulate_lw_select accumulate_sw_select: SELECT CASE(sw_physics) CASE (CAMSWSCHEME,RRTMG_SWSCHEME) IF(PRESENT(SWUPTC))THEN !$OMP PARALLEL DO & !$OMP PRIVATE ( ij ,i,j,k,its,ite,jts,jte) DO ij = 1 , num_tiles its = i_start(ij) ite = i_end(ij) jts = j_start(ij) jte = j_end(ij) DO j=jts,jte DO i=its,ite ACSWUPT(I,J) = ACSWUPT(I,J) + SWUPT(I,J)*DT ACSWUPTC(I,J) = ACSWUPTC(I,J) + SWUPTC(I,J)*DT ACSWDNT(I,J) = ACSWDNT(I,J) + SWDNT(I,J)*DT ACSWDNTC(I,J) = ACSWDNTC(I,J) + SWDNTC(I,J)*DT ACSWUPB(I,J) = ACSWUPB(I,J) + SWUPB(I,J)*DT ACSWUPBC(I,J) = ACSWUPBC(I,J) + SWUPBC(I,J)*DT ACSWDNB(I,J) = ACSWDNB(I,J) + SWDNB(I,J)*DT ACSWDNBC(I,J) = ACSWDNBC(I,J) + SWDNBC(I,J)*DT ENDDO ENDDO ENDDO !$OMP END PARALLEL DO ENDIF CASE DEFAULT END SELECT accumulate_sw_select END SUBROUTINE radiation_driver SUBROUTINE pre_radiation_driver ( grid, config_flags & ,itimestep, ra_call_offset & ,XLAT, XLONG, GMT, julian, xtime, RADT, STEPRA & ,ht,dx,dy,sina,cosa,shadowmask,slope_rad ,topo_shading & ,shadlen,ht_shad,ht_loc & ,ht_shad_bxs, ht_shad_bxe & ,ht_shad_bys, ht_shad_bye & ,nested, min_ptchsz & ,spec_bdy_width & ,ids, ide, jds, jde, kds, kde & ,ims, ime, jms, jme, kms, kme & ,ips, ipe, jps, jpe, kps, kpe & ,i_start, i_end & ,j_start, j_end & ,kts, kte & ,num_tiles ) USE module_domain , ONLY : domain USE module_dm , ONLY : ntasks_x,ntasks_y,local_communicator,mytask,ntasks,wrf_dm_minval_integer USE module_comm_dm , ONLY : halo_toposhad_sub USE module_bc USE module_model_constants IMPLICIT NONE INTEGER, INTENT(IN ) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & ips,ipe, jps,jpe, kps,kpe, & kts,kte, & num_tiles TYPE(domain) , INTENT(INOUT) :: grid TYPE(grid_config_rec_type ) , INTENT(IN ) :: config_flags INTEGER, INTENT(IN ) :: itimestep, ra_call_offset, stepra, & slope_rad, topo_shading, & spec_bdy_width INTEGER, INTENT(INOUT) :: min_ptchsz INTEGER, DIMENSION(num_tiles), INTENT(IN) :: & i_start,i_end,j_start,j_end REAL, INTENT(IN ) :: GMT, radt, julian, xtime, dx, dy, shadlen REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN ) :: XLAT, & XLONG, & HT, & SINA, & COSA REAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: ht_shad,ht_loc REAL, DIMENSION( jms:jme , kds:kde , spec_bdy_width ), & INTENT(IN ) :: ht_shad_bxs, ht_shad_bxe REAL, DIMENSION( ims:ime , kds:kde , spec_bdy_width ), & INTENT(IN ) :: ht_shad_bys, ht_shad_bye INTEGER, DIMENSION( ims:ime, jms:jme ), & INTENT(INOUT) :: shadowmask LOGICAL, INTENT(IN ) :: nested INTEGER :: niter,ni,psx,psy,idum,jdum,i,j,ij REAL :: DECLIN,SOLCON if (itimestep .eq. 1) then psx = ipe-ips+1 psy = jpe-jps+1 min_ptchsz = min(psx,psy) idum = 0 jdum = 0 endif if (itimestep .eq. 1) then call wrf_dm_minval_integer (psx,idum,jdum) call wrf_dm_minval_integer (psy,idum,jdum) min_ptchsz = min(psx,psy) endif if ((topo_shading.eq.1).and.(itimestep .eq. 1 .or. & mod(itimestep,STEPRA) .eq. 1 + ra_call_offset)) then CALL radconst(XTIME,DECLIN,SOLCON,JULIAN,DEGRAD,DPD) do j=jms,jme do i=ims,ime ht_loc(i,j) = ht(i,j) enddo enddo if ((ids.eq.ips).and.(ide.eq.ipe).and.(jds.eq.jps).and.(jde.eq.jpe)) then niter = 1 else niter = int(shadlen/(dx*min_ptchsz)+3) endif IF( nested ) THEN !$OMP PARALLEL DO & !$OMP PRIVATE ( ij ) DO ij = 1 , num_tiles CALL spec_bdyfield(ht_shad, & ht_shad_bxs, ht_shad_bxe, & ht_shad_bys, ht_shad_bye, & 'm', config_flags, spec_bdy_width, 2,& ids,ide, jds,jde, 1 ,1 , & ims,ime, jms,jme, 1 ,1 , & ips,ipe, jps,jpe, 1 ,1 , & i_start(ij), i_end(ij), & j_start(ij), j_end(ij), & 1 , 1 ) ENDDO ENDIF do ni = 1, niter !$OMP PARALLEL DO & !$OMP PRIVATE ( ij,i,j ) do ij = 1 , num_tiles call toposhad_init (ht_shad,ht_loc, & shadowmask,nested,ni, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & ips,min(ipe,ide-1), jps,min(jpe,jde-1), kps,kpe, & i_start(ij),min(i_end(ij), ide-1),j_start(ij),& min(j_end(ij), jde-1), kts, kte ) enddo !$OMP END PARALLEL DO !$OMP PARALLEL DO & !$OMP PRIVATE ( ij,i,j ) do ij = 1 , num_tiles call toposhad (xlat,xlong,sina,cosa,xtime,gmt,radt,declin, & dx,dy,ht_shad,ht_loc,ni, & shadowmask,shadlen, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & ips,min(ipe,ide-1), jps,min(jpe,jde-1), kps,kpe, & i_start(ij),min(i_end(ij), ide-1),j_start(ij),& min(j_end(ij), jde-1), kts, kte ) enddo !$OMP END PARALLEL DO CALL HALO_TOPOSHAD_sub ( grid, & local_communicator, & mytask, ntasks, ntasks_x, ntasks_y, & ids, ide, jds, jde, kds, kde, & ims, ime, jms, jme, kms, kme, & ips, ipe, jps, jpe, kps, kpe ) enddo endif END SUBROUTINE pre_radiation_driver SUBROUTINE radconst(XTIME,DECLIN,SOLCON,JULIAN, & DEGRAD,DPD ) USE module_wrf_error IMPLICIT NONE REAL, INTENT(IN ) :: DEGRAD,DPD,XTIME,JULIAN REAL, INTENT(OUT ) :: DECLIN,SOLCON REAL :: OBECL,SINOB,SXLONG,ARG, & DECDEG,DJUL,RJUL,ECCFAC DECLIN=0. SOLCON=0. OBECL=23.5*DEGRAD SINOB=SIN(OBECL) IF(JULIAN.GE.80.)SXLONG=DPD*(JULIAN-80.) IF(JULIAN.LT.80.)SXLONG=DPD*(JULIAN+285.) SXLONG=SXLONG*DEGRAD ARG=SINOB*SIN(SXLONG) DECLIN=ASIN(ARG) DECDEG=DECLIN/DEGRAD DJUL=JULIAN*360./365. RJUL=DJUL*DEGRAD ECCFAC=1.000110+0.034221*COS(RJUL)+0.001280*SIN(RJUL)+0.000719* & COS(2*RJUL)+0.000077*SIN(2*RJUL) SOLCON=1370.*ECCFAC END SUBROUTINE radconst SUBROUTINE calc_coszen(ims,ime,jms,jme,its,ite,jts,jte, & julian,xtime,gmt, & declin,degrad,xlon,xlat,coszen,hrang) implicit none integer, intent(in) :: ims,ime,jms,jme,its,ite,jts,jte real, intent(in) :: julian,declin,xtime,gmt,degrad real, dimension(ims:ime,jms:jme), intent(in) :: xlat,xlon real, dimension(ims:ime,jms:jme), intent(inout) :: coszen,hrang integer :: i,j real :: da,eot,xt24,tloctm,xxlat da=6.2831853071795862*(julian-1)/365. eot=(0.000075+0.001868*cos(da)-0.032077*sin(da) & -0.014615*cos(2*da)-0.04089*sin(2*da))*(229.18) xt24=mod(xtime,1440.)+eot do j=jts,jte do i=its,ite tloctm=gmt+xt24/60.+xlon(i,j)/15. hrang(i,j)=15.*(tloctm-12.)*degrad xxlat=xlat(i,j)*degrad coszen(i,j)=sin(xxlat)*sin(declin) & +cos(xxlat)*cos(declin) *cos(hrang(i,j)) enddo enddo END SUBROUTINE calc_coszen SUBROUTINE cal_cldfra(CLDFRA,QC,QI,F_QC,F_QI, & 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, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(OUT ) :: & CLDFRA REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN ) :: & QI, & QC LOGICAL,INTENT(IN) :: F_QC,F_QI REAL thresh INTEGER:: i,j,k thresh=1.0e-6 IF ( f_qi .AND. f_qc ) THEN DO j = jts,jte DO k = kts,kte DO i = its,ite IF ( QC(i,k,j)+QI(I,k,j) .gt. thresh) THEN CLDFRA(i,k,j)=1. ELSE CLDFRA(i,k,j)=0. ENDIF ENDDO ENDDO ENDDO ELSE IF ( f_qc ) THEN DO j = jts,jte DO k = kts,kte DO i = its,ite IF ( QC(i,k,j) .gt. thresh) THEN CLDFRA(i,k,j)=1. ELSE CLDFRA(i,k,j)=0. ENDIF ENDDO ENDDO ENDDO ELSE DO j = jts,jte DO k = kts,kte DO i = its,ite CLDFRA(i,k,j)=0. ENDDO ENDDO ENDDO ENDIF END SUBROUTINE cal_cldfra SUBROUTINE cal_cldfra2(CLDFRA, QV, QC, QI, QS, & F_QV, F_QC, F_QI, F_QS, t_phy, p_phy, & F_ICE_PHY,F_RAIN_PHY, & 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, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(OUT ) :: & CLDFRA REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN ) :: & QV, & QI, & QC, & QS, & t_phy, & p_phy REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & OPTIONAL, & INTENT(IN ) :: & F_ICE_PHY, & F_RAIN_PHY LOGICAL,OPTIONAL,INTENT(IN) :: F_QC,F_QI,F_QV,F_QS INTEGER:: i,j,k REAL :: RHUM, tc, esw, esi, weight, qvsw, qvsi, qvs_weight, QIMID, QWMID, QCLD, DENOM, ARG, SUBSAT REAL ,PARAMETER :: ALPHA0=100., GAMMA=0.49, QCLDMIN=1.E-12, & PEXP=0.25, RHGRID=1.0 REAL , PARAMETER :: SVP1=0.61078 REAL , PARAMETER :: SVP2=17.2693882 REAL , PARAMETER :: SVPI2=21.8745584 REAL , PARAMETER :: SVP3=35.86 REAL , PARAMETER :: SVPI3=7.66 REAL , PARAMETER :: SVPT0=273.15 REAL , PARAMETER :: r_d = 287. REAL , PARAMETER :: r_v = 461.6 REAL , PARAMETER :: ep_2=r_d/r_v DO j = jts,jte DO k = kts,kte DO i = its,ite tc = t_phy(i,k,j) - SVPT0 esw = 1000.0 * SVP1 * EXP( SVP2 * tc / ( t_phy(i,k,j) - SVP3 ) ) esi = 1000.0 * SVP1 * EXP( SVPI2 * tc / ( t_phy(i,k,j) - SVPI3 ) ) QVSW = EP_2 * esw / ( p_phy(i,k,j) - esw ) QVSI = EP_2 * esi / ( p_phy(i,k,j) - esi ) IF ( PRESENT(F_QI) .and. PRESENT(F_QC) .and. PRESENT(F_QS) ) THEN IF ( F_QI .and. F_QC .and. F_QS) THEN QCLD = QI(i,k,j)+QC(i,k,j)+QS(i,k,j) IF (QCLD .LT. QCLDMIN) THEN weight = 0. ELSE weight = (QI(i,k,j)+QS(i,k,j)) / QCLD ENDIF ENDIF IF ( F_QC .and. .not. F_QI .and. .not. F_QS ) THEN QCLD = QC(i,k,j) IF (QCLD .LT. QCLDMIN) THEN weight = 0. ELSE if (t_phy(i,k,j) .gt. 273.15) weight = 0. if (t_phy(i,k,j) .le. 273.15) weight = 1. ENDIF ENDIF IF ( F_QC .and. .not. F_QI .and. F_QS .and. PRESENT(F_ICE_PHY) ) THEN QIMID = QS(i,k,j) QWMID = QC(i,k,j) QCLD=QWMID+QIMID IF (QCLD .LT. QCLDMIN) THEN weight = 0. ELSE weight = F_ICE_PHY(i,k,j) ENDIF ENDIF ELSE CLDFRA(i,k,j)=0. ENDIF QVS_WEIGHT = (1-weight)*QVSW + weight*QVSI RHUM=QV(i,k,j)/QVS_WEIGHT IF (QCLD .LT. QCLDMIN) THEN CLDFRA(i,k,j)=0. ELSEIF(RHUM.GE.RHGRID)THEN CLDFRA(i,k,j)=1. ELSE SUBSAT=MAX(1.E-10,RHGRID*QVS_WEIGHT-QV(i,k,j)) DENOM=(SUBSAT)**GAMMA ARG=MAX(-6.9, -ALPHA0*QCLD/DENOM) RHUM=MAX(1.E-10, RHUM) CLDFRA(i,k,j)=(RHUM/RHGRID)**PEXP*(1.-EXP(ARG)) IF (CLDFRA(i,k,j) .LT. .01) CLDFRA(i,k,j)=0. ENDIF ENDDO ENDDO ENDDO END SUBROUTINE cal_cldfra2 SUBROUTINE toposhad_init(ht_shad,ht_loc,shadowmask,nested,iter, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & ips,ipe, jps,jpe, kps,kpe, & its,ite, jts,jte, kts,kte ) USE module_model_constants implicit none INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & ips,ipe, jps,jpe, kps,kpe, & its,ite, jts,jte, kts,kte LOGICAL, INTENT(IN) :: nested REAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: ht_shad, ht_loc INTEGER, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: shadowmask INTEGER, INTENT(IN) :: iter INTEGER :: i, j if (iter.eq.1) then do j=jts,jte do i=its,ite shadowmask(i,j) = 0 ENDDO ENDDO IF ( nested ) THEN do j=max(jts,jds+2),min(jte,jde-3) do i=max(its,ids+2),min(ite,ide-3) ht_shad(i,j) = ht_loc(i,j)-0.001 ENDDO ENDDO ELSE do j=jts,jte do i=its,ite ht_shad(i,j) = ht_loc(i,j)-0.001 ENDDO ENDDO ENDIF IF ( nested ) THEN if (its.eq.ids) then do j=jts,jte if (ht_shad(its,j) .gt. ht_loc(its,j)) then shadowmask(its,j) = 1 ht_loc(its,j) = ht_shad(its,j) endif if (ht_shad(its+1,j) .gt. ht_loc(its+1,j)) then shadowmask(its+1,j) = 1 ht_loc(its+1,j) = ht_shad(its+1,j) endif enddo endif if (ite.eq.ide-1) then do j=jts,jte if (ht_shad(ite,j) .gt. ht_loc(ite,j)) then shadowmask(ite,j) = 1 ht_loc(ite,j) = ht_shad(ite,j) endif if (ht_shad(ite-1,j) .gt. ht_loc(ite-1,j)) then shadowmask(ite-1,j) = 1 ht_loc(ite-1,j) = ht_shad(ite-1,j) endif enddo endif if (jts.eq.jds) then do i=its,ite if (ht_shad(i,jts) .gt. ht_loc(i,jts)) then shadowmask(i,jts) = 1 ht_loc(i,jts) = ht_shad(i,jts) endif if (ht_shad(i,jts+1) .gt. ht_loc(i,jts+1)) then shadowmask(i,jts+1) = 1 ht_loc(i,jts+1) = ht_shad(i,jts+1) endif enddo endif if (jte.eq.jde-1) then do i=its,ite if (ht_shad(i,jte) .gt. ht_loc(i,jte)) then shadowmask(i,jte) = 1 ht_loc(i,jte) = ht_shad(i,jte) endif if (ht_shad(i,jte-1) .gt. ht_loc(i,jte-1)) then shadowmask(i,jte-1) = 1 ht_loc(i,jte-1) = ht_shad(i,jte-1) endif enddo endif ENDIF else if ((its.ne.ids).and.(its.eq.ips)) then do j=jts-2,jte+2 ht_loc(its-1,j) = max(ht_loc(its-1,j),ht_shad(its-1,j)) ht_loc(its-2,j) = max(ht_loc(its-2,j),ht_shad(its-2,j)) enddo endif if ((ite.ne.ide-1).and.(ite.eq.ipe)) then do j=jts-2,jte+2 ht_loc(ite+1,j) = max(ht_loc(ite+1,j),ht_shad(ite+1,j)) ht_loc(ite+2,j) = max(ht_loc(ite+2,j),ht_shad(ite+2,j)) enddo endif if ((jts.ne.jds).and.(jts.eq.jps)) then do i=its-2,ite+2 ht_loc(i,jts-1) = max(ht_loc(i,jts-1),ht_shad(i,jts-1)) ht_loc(i,jts-2) = max(ht_loc(i,jts-2),ht_shad(i,jts-2)) enddo endif if ((jte.ne.jde-1).and.(jte.eq.jpe)) then do i=its-2,ite+2 ht_loc(i,jte+1) = max(ht_loc(i,jte+1),ht_shad(i,jte+1)) ht_loc(i,jte+2) = max(ht_loc(i,jte+2),ht_shad(i,jte+2)) enddo endif endif END SUBROUTINE toposhad_init SUBROUTINE toposhad(xlat,xlong,sina,cosa,xtime,gmt,radfrq,declin, & dx,dy,ht_shad,ht_loc,iter, & shadowmask,shadlen, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & ips,ipe, jps,jpe, kps,kpe, & its,ite, jts,jte, kts,kte ) USE module_model_constants implicit none INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & ips,ipe, jps,jpe, kps,kpe, & its,ite, jts,jte, kts,kte INTEGER, INTENT(IN) :: iter REAL, INTENT(IN) :: RADFRQ,XTIME,DECLIN,dx,dy,gmt,shadlen REAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: XLAT, XLONG, sina, cosa REAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: ht_shad,ht_loc INTEGER, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: shadowmask REAL :: pi, xt24, wgt, ri, rj, argu, sol_azi, topoelev, dxabs, tloctm, hrang, xxlat, csza INTEGER :: gpshad, ii, jj, i1, i2, j1, j2, i, j XT24=MOD(XTIME+RADFRQ*0.5,1440.) pi = 4.*atan(1.) gpshad = int(shadlen/dx+1.) if (iter.eq.1) then j_loop1: DO J=jts,jte i_loop1: DO I=its,ite TLOCTM=GMT+XT24/60.+XLONG(i,j)/15. HRANG=15.*(TLOCTM-12.)*DEGRAD XXLAT=XLAT(i,j)*DEGRAD CSZA=SIN(XXLAT)*SIN(DECLIN)+COS(XXLAT)*COS(DECLIN)*COS(HRANG) if (csza.lt.1.e-2) then shadowmask(i,j) = 0 ht_shad(i,j) = ht_loc(i,j)-0.001 goto 120 endif argu=(csza*sin(XXLAT)-sin(DECLIN))/(sin(acos(csza))*cos(XXLAT)) if (argu.gt.1) argu = 1 if (argu.lt.-1) argu = -1 sol_azi = sign(acos(argu),sin(HRANG))+pi if (cosa(i,j).ge.0) then sol_azi = sol_azi + asin(sina(i,j)) else sol_azi = sol_azi + pi - asin(sina(i,j)) endif if ((sol_azi.gt.1.75*pi).or.(sol_azi.lt.0.25*pi)) then do jj = j+1,j+gpshad ri = i + (jj-j)*tan(sol_azi) i1 = int(ri) i2 = i1+1 wgt = ri-i1 dxabs = sqrt((dy*(jj-j))**2+(dx*(ri-i))**2) if ((jj.ge.jpe+1).or.(i1.le.ips-1).or.(i2.ge.ipe+1)) then if (shadowmask(i,j).eq.0) shadowmask(i,j) = -1 goto 120 endif topoelev=atan((wgt*ht_loc(i2,jj)+(1.-wgt)*ht_loc(i1,jj)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo else if (sol_azi.lt.0.75*pi) then do ii = i+1,i+gpshad rj = j - (ii-i)*tan(pi/2.+sol_azi) j1 = int(rj) j2 = j1+1 wgt = rj-j1 dxabs = sqrt((dx*(ii-i))**2+(dy*(rj-j))**2) if ((ii.ge.ipe+1).or.(j1.le.jps-1).or.(j2.ge.jpe+1)) then if (shadowmask(i,j).eq.0) shadowmask(i,j) = -1 goto 120 endif topoelev=atan((wgt*ht_loc(ii,j2)+(1.-wgt)*ht_loc(ii,j1)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo else if (sol_azi.lt.1.25*pi) then do jj = j-1,j-gpshad,-1 ri = i + (jj-j)*tan(sol_azi) i1 = int(ri) i2 = i1+1 wgt = ri-i1 dxabs = sqrt((dy*(jj-j))**2+(dx*(ri-i))**2) if ((jj.le.jps-1).or.(i1.le.ips-1).or.(i2.ge.ipe+1)) then if (shadowmask(i,j).eq.0) shadowmask(i,j) = -1 goto 120 endif topoelev=atan((wgt*ht_loc(i2,jj)+(1.-wgt)*ht_loc(i1,jj)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo else do ii = i-1,i-gpshad,-1 rj = j - (ii-i)*tan(pi/2.+sol_azi) j1 = int(rj) j2 = j1+1 wgt = rj-j1 dxabs = sqrt((dx*(ii-i))**2+(dy*(rj-j))**2) if ((ii.le.ips-1).or.(j1.le.jps-1).or.(j2.ge.jpe+1)) then if (shadowmask(i,j).eq.0) shadowmask(i,j) = -1 goto 120 endif topoelev=atan((wgt*ht_loc(ii,j2)+(1.-wgt)*ht_loc(ii,j1)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo endif 120 continue ENDDO i_loop1 ENDDO j_loop1 else j_loop2: DO J=jts,jte i_loop2: DO I=its,ite TLOCTM=GMT+XT24/60.+XLONG(i,j)/15. HRANG=15.*(TLOCTM-12.)*DEGRAD XXLAT=XLAT(i,j)*DEGRAD CSZA=SIN(XXLAT)*SIN(DECLIN)+COS(XXLAT)*COS(DECLIN)*COS(HRANG) argu=(csza*sin(XXLAT)-sin(DECLIN))/(sin(acos(csza))*cos(XXLAT)) if (argu.gt.1) argu = 1 if (argu.lt.-1) argu = -1 sol_azi = sign(acos(argu),sin(HRANG))+pi if (cosa(i,j).ge.0) then sol_azi = sol_azi + asin(sina(i,j)) else sol_azi = sol_azi + pi - asin(sina(i,j)) endif if ((sol_azi.gt.1.75*pi).or.(sol_azi.lt.0.25*pi)) then do jj = j+1,j+gpshad ri = i + (jj-j)*tan(sol_azi) i1 = int(ri) i2 = i1+1 wgt = ri-i1 dxabs = sqrt((dy*(jj-j))**2+(dx*(ri-i))**2) if ((jj.ge.min(jde,jpe+3)).or.(i1.le.max(ids-1,ips-3)).or.(i2.ge.min(ide,ipe+3))) goto 220 topoelev=atan((wgt*ht_loc(i2,jj)+(1.-wgt)*ht_loc(i1,jj)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo else if (sol_azi.lt.0.75*pi) then do ii = i+1,i+gpshad rj = j - (ii-i)*tan(pi/2.+sol_azi) j1 = int(rj) j2 = j1+1 wgt = rj-j1 dxabs = sqrt((dx*(ii-i))**2+(dy*(rj-j))**2) if ((ii.ge.min(ide,ipe+3)).or.(j1.le.max(jds-1,jps-3)).or.(j2.ge.min(jde,jpe+3))) goto 220 topoelev=atan((wgt*ht_loc(ii,j2)+(1.-wgt)*ht_loc(ii,j1)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo else if (sol_azi.lt.1.25*pi) then do jj = j-1,j-gpshad,-1 ri = i + (jj-j)*tan(sol_azi) i1 = int(ri) i2 = i1+1 wgt = ri-i1 dxabs = sqrt((dy*(jj-j))**2+(dx*(ri-i))**2) if ((jj.le.max(jds-1,jps-3)).or.(i1.le.max(ids-1,ips-3)).or.(i2.ge.min(ide,ipe+3))) goto 220 topoelev=atan((wgt*ht_loc(i2,jj)+(1.-wgt)*ht_loc(i1,jj)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo else do ii = i-1,i-gpshad,-1 rj = j - (ii-i)*tan(pi/2.+sol_azi) j1 = int(rj) j2 = j1+1 wgt = rj-j1 dxabs = sqrt((dx*(ii-i))**2+(dy*(rj-j))**2) if ((ii.le.max(ids-1,ips-3)).or.(j1.le.max(jds-1,jps-3)).or.(j2.ge.min(jde,jpe+3))) goto 220 topoelev=atan((wgt*ht_loc(ii,j2)+(1.-wgt)*ht_loc(ii,j1)-ht_loc(i,j))/dxabs) if (sin(topoelev).ge.csza) then shadowmask(i,j) = 1 ht_shad(i,j) = max(ht_shad(i,j),ht_loc(i,j)+dxabs*(tan(topoelev)-tan(asin(csza)))) endif enddo endif 220 continue ENDDO i_loop2 ENDDO j_loop2 endif END SUBROUTINE toposhad SUBROUTINE ozn_time_int(julday,julian,ozmixm,ozmixt,levsiz,num_months, & 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 ) :: levsiz, num_months REAL, DIMENSION( ims:ime, levsiz, jms:jme, num_months ), & INTENT(IN ) :: ozmixm INTEGER, INTENT(IN ) :: JULDAY REAL, INTENT(IN ) :: JULIAN REAL, DIMENSION( ims:ime, levsiz, jms:jme ), & INTENT(OUT ) :: ozmixt REAL :: intJULIAN integer :: np1,np,nm,m,k,i,j integer :: IJUL integer, dimension(12) :: date_oz data date_oz/16, 45, 75, 105, 136, 166, 197, 228, 258, 289, 319, 350/ real, parameter :: daysperyear = 365. real :: cdayozp, cdayozm real :: fact1, fact2, deltat logical :: finddate logical :: ozncyc CHARACTER(LEN=256) :: msgstr ozncyc = .true. intJULIAN = JULIAN + 1.0 IJUL=INT(intJULIAN) intJULIAN=intJULIAN-FLOAT(IJUL) IJUL=MOD(IJUL,365) IF(IJUL.EQ.0)IJUL=365 intJULIAN=intJULIAN+IJUL np1=1 finddate=.false. do m=1,12 if(date_oz(m).gt.intjulian.and..not.finddate) then np1=m finddate=.true. endif enddo cdayozp=date_oz(np1) if(np1.gt.1) then cdayozm=date_oz(np1-1) np=np1 nm=np-1 else cdayozm=date_oz(12) np=np1 nm=12 endif if (ozncyc .and. np1 == 1) then deltat = cdayozp + daysperyear - cdayozm if (intjulian > cdayozp) then fact1 = (cdayozp + daysperyear - intjulian)/deltat fact2 = (intjulian - cdayozm)/deltat else fact1 = (cdayozp - intjulian)/deltat fact2 = (intjulian + daysperyear - cdayozm)/deltat end if else deltat = cdayozp - cdayozm fact1 = (cdayozp - intjulian)/deltat fact2 = (intjulian - cdayozm)/deltat end if do j=jts,jte do k=1,levsiz do i=its,ite ozmixt(i,k,j) = ozmixm(i,k,j,nm)*fact1 + ozmixm(i,k,j,np)*fact2 end do end do end do END SUBROUTINE ozn_time_int SUBROUTINE ozn_p_int(p ,pin, levsiz, ozmixt, o3vmr, & 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) :: levsiz real, intent(in) :: p(ims:ime,kms:kme,jms:jme) real, intent(in) :: pin(levsiz) real, intent(in) :: ozmixt(ims:ime,levsiz,jms:jme) real, intent(out) :: o3vmr(ims:ime,kms:kme,jms:jme) real pmid(its:ite,kts:kte) integer i,j integer k, kk, kkstart, kout integer kupper(its:ite) integer kount integer ncol, pver real dpu real dpl ncol = ite - its + 1 pver = kte - kts + 1 do j=jts,jte do i=its, ite kupper(i) = 1 end do do k = kts,kte kk = kte - k + kts do i = its,ite pmid(i,kk) = p(i,k,j) enddo enddo do k=1,pver kout = pver - k + 1 kkstart = levsiz do i=its,ite kkstart = min0(kkstart,kupper(i)) end do kount = 0 do kk=kkstart,levsiz-1 do i=its,ite if (pin(kk).lt.pmid(i,k) .and. pmid(i,k).le.pin(kk+1)) then kupper(i) = kk kount = kount + 1 end if end do if (kount.eq.ncol) then do i=its,ite dpu = pmid(i,k) - pin(kupper(i)) dpl = pin(kupper(i)+1) - pmid(i,k) o3vmr(i,kout,j) = (ozmixt(i,kupper(i),j)*dpl + & ozmixt(i,kupper(i)+1,j)*dpu)/(dpl + dpu) end do goto 35 end if end do do i=its,ite if (pmid(i,k) .lt. pin(1)) then o3vmr(i,kout,j) = ozmixt(i,1,j)*pmid(i,k)/pin(1) else if (pmid(i,k) .gt. pin(levsiz)) then o3vmr(i,kout,j) = ozmixt(i,levsiz,j) else dpu = pmid(i,k) - pin(kupper(i)) dpl = pin(kupper(i)+1) - pmid(i,k) o3vmr(i,kout,j) = (ozmixt(i,kupper(i),j)*dpl + & ozmixt(i,kupper(i)+1,j)*dpu)/(dpl + dpu) end if end do if (kount.gt.ncol) then call wrf_error_fatal3("",3013,& 'OZN_P_INT: Bad ozone data: non-monotonicity suspected') end if 35 continue end do end do return END SUBROUTINE ozn_p_int SUBROUTINE aer_time_int(julday,julian,aerodm,aerodt,levsiz,num_months,no_src, & 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 ) :: levsiz, num_months, no_src REAL, DIMENSION( ims:ime, levsiz, jms:jme, num_months, no_src ), & INTENT(IN ) :: aerodm INTEGER, INTENT(IN ) :: JULDAY REAL, INTENT(IN ) :: JULIAN REAL, DIMENSION( ims:ime, levsiz, jms:jme, no_src ), & INTENT(OUT ) :: aerodt REAL :: intJULIAN integer :: np1,np,nm,m,k,i,j,s integer :: IJUL integer, dimension(12) :: date_oz data date_oz/16, 45, 75, 105, 136, 166, 197, 228, 258, 289, 319, 350/ real, parameter :: daysperyear = 365. real :: cdayozp, cdayozm real :: fact1, fact2, deltat logical :: finddate logical :: ozncyc CHARACTER(LEN=256) :: msgstr ozncyc = .true. intJULIAN = JULIAN + 1.0 IJUL=INT(intJULIAN) intJULIAN=intJULIAN-FLOAT(IJUL) IJUL=MOD(IJUL,365) IF(IJUL.EQ.0)IJUL=365 intJULIAN=intJULIAN+IJUL np1=1 finddate=.false. do m=1,12 if(date_oz(m).gt.intjulian.and..not.finddate) then np1=m finddate=.true. endif enddo cdayozp=date_oz(np1) if(np1.gt.1) then cdayozm=date_oz(np1-1) np=np1 nm=np-1 else cdayozm=date_oz(12) np=np1 nm=12 endif if (ozncyc .and. np1 == 1) then deltat = cdayozp + daysperyear - cdayozm if (intjulian > cdayozp) then fact1 = (cdayozp + daysperyear - intjulian)/deltat fact2 = (intjulian - cdayozm)/deltat else fact1 = (cdayozp - intjulian)/deltat fact2 = (intjulian + daysperyear - cdayozm)/deltat end if else deltat = cdayozp - cdayozm fact1 = (cdayozp - intjulian)/deltat fact2 = (intjulian - cdayozm)/deltat end if do s=1, no_src do j=jts,jte do k=1,levsiz do i=its,ite aerodt(i,k,j,s) = aerodm(i,k,j,nm,s)*fact1 + aerodm(i,k,j,np,s)*fact2 end do end do end do end do END SUBROUTINE aer_time_int SUBROUTINE aer_p_int(p ,pin, levsiz, aerodt, aerod, no_src, pf, totaod, & 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) :: levsiz integer, intent(in) :: no_src real, intent(in) :: p(ims:ime,kms:kme,jms:jme) real, intent(in) :: pf(ims:ime,kms:kme,jms:jme) real, intent(in) :: pin(levsiz) real, intent(in) :: aerodt(ims:ime,levsiz,jms:jme,1:no_src) real, intent(out) :: aerod(ims:ime,kms:kme,jms:jme,1:no_src) real, intent(out) :: totaod(ims:ime,jms:jme) real pmid(its:ite,kts:kte) integer i,j integer k, kk, kkstart, kout integer kupper(its:ite) integer kount integer ncol, pver, s real dpu real dpl real dpm ncol = ite - its + 1 pver = kte - kts + 1 do s=1,no_src do j=jts,jte do i=its, ite kupper(i) = 1 end do do k = kts,kte kk = kte - k + kts do i = its,ite pmid(i,kk) = p(i,k,j)*0.01 enddo enddo do k=1,pver kout = pver - k + 1 kkstart = levsiz do i=its,ite kkstart = min0(kkstart,kupper(i)) end do kount = 0 do kk=kkstart,levsiz-1 do i=its,ite if (pin(kk).lt.pmid(i,k) .and. pmid(i,k).le.pin(kk+1)) then kupper(i) = kk kount = kount + 1 end if end do if (kount.eq.ncol) then do i=its,ite dpu = pmid(i,k) - pin(kupper(i)) dpl = pin(kupper(i)+1) - pmid(i,k) dpm = pf(i,kout,j) - pf(i,kout+1,j) aerod(i,kout,j,s) = (aerodt(i,kupper(i),j,s)*dpl + & aerodt(i,kupper(i)+1,j,s)*dpu)/(dpl + dpu) aerod(i,kout,j,s) = aerod(i,kout,j,s)*dpm end do goto 35 end if end do do i=its,ite if (pmid(i,k) .lt. pin(1)) then dpm = pf(i,kout,j) - pf(i,kout+1,j) aerod(i,kout,j,s) = aerodt(i,1,j,s)*pmid(i,k)/pin(1) aerod(i,kout,j,s) = aerod(i,kout,j,s)*dpm else if (pmid(i,k) .gt. pin(levsiz)) then dpm = pf(i,kout,j) - pf(i,kout+1,j) aerod(i,kout,j,s) = aerodt(i,levsiz,j,s) aerod(i,kout,j,s) = aerod(i,kout,j,s)*dpm else dpu = pmid(i,k) - pin(kupper(i)) dpl = pin(kupper(i)+1) - pmid(i,k) dpm = pf(i,kout,j) - pf(i,kout+1,j) aerod(i,kout,j,s) = (aerodt(i,kupper(i),j,s)*dpl + & aerodt(i,kupper(i)+1,j,s)*dpu)/(dpl + dpu) aerod(i,kout,j,s) = aerod(i,kout,j,s)*dpm end if end do if (kount.gt.ncol) then call wrf_error_fatal3("",3269,& 'AER_P_INT: Bad aerosol data: non-monotonicity suspected') end if 35 continue end do end do end do do s=1,no_src do j=jts,jte do k=1,pver do i=its,ite totaod(i,j) = totaod(i,j) + aerod(i,k,j,s) end do end do end do end do return END SUBROUTINE aer_p_int END MODULE module_radiation_driver