MODULE module_sf_noahdrv !------------------------------- USE module_sf_noahlsm USE module_sf_urban USE module_sf_bep USE module_sf_bep_bem #ifdef WRF_CHEM USE module_data_gocart_dust #endif !------------------------------- ! CONTAINS ! !---------------------------------------------------------------- ! Urban related variable are added to arguments - urban !---------------------------------------------------------------- SUBROUTINE lsm(DZ8W,QV3D,P8W3D,T3D,TSK, & HFX,QFX,LH,GRDFLX, QGH,GSW,SWDOWN,GLW,SMSTAV,SMSTOT, & SFCRUNOFF, UDRUNOFF,IVGTYP,ISLTYP,ISURBAN,ISICE,VEGFRA, & ALBEDO,ALBBCK,ZNT,Z0,TMN,XLAND,XICE,EMISS,EMBCK, & SNOWC,QSFC,RAINBL,MMINLU, & num_soil_layers,DT,DZS,ITIMESTEP, & SMOIS,TSLB,SNOW,CANWAT, & CHS,CHS2,CQS2,CPM,ROVCP,SR,chklowq,lai,qz0, & !H myj,frpcpn, & SH2O,SNOWH, & !H U_PHY,V_PHY, & !I SNOALB,SHDMIN,SHDMAX, & !I SNOTIME, & !? ACSNOM,ACSNOW, & !O SNOPCX, & !O POTEVP, & !O SMCREL, & !O XICE_THRESHOLD, & RDLAI2D,USEMONALB, & RIB, & !? NOAHRES, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte, & sf_urban_physics, & CMR_SFCDIF,CHR_SFCDIF,CMC_SFCDIF,CHC_SFCDIF, & !Optional Urban TR_URB2D,TB_URB2D,TG_URB2D,TC_URB2D,QC_URB2D, & !H urban UC_URB2D, & !H urban XXXR_URB2D,XXXB_URB2D,XXXG_URB2D,XXXC_URB2D, & !H urban TRL_URB3D,TBL_URB3D,TGL_URB3D, & !H urban SH_URB2D,LH_URB2D,G_URB2D,RN_URB2D,TS_URB2D, & !H urban PSIM_URB2D,PSIH_URB2D,U10_URB2D,V10_URB2D, & !O urban GZ1OZ0_URB2D, AKMS_URB2D, & !O urban TH2_URB2D,Q2_URB2D, UST_URB2D, & !O urban DECLIN_URB,COSZ_URB2D,OMG_URB2D, & !I urban XLAT_URB2D, & !I urban num_roof_layers, num_wall_layers, & !I urban num_road_layers, DZR, DZB, DZG, & !I urban FRC_URB2D,UTYPE_URB2D, & !O num_urban_layers, & !I multi-layer urban trb_urb4d,tw1_urb4d,tw2_urb4d,tgb_urb4d, & !H multi-layer urban tlev_urb3d,qlev_urb3d, & !H multi-layer urban tw1lev_urb3d,tw2lev_urb3d, & !H multi-layer urban tglev_urb3d,tflev_urb3d, & !H multi-layer urban sf_ac_urb3d,lf_ac_urb3d,cm_ac_urb3d, & !H multi-layer urban sfvent_urb3d,lfvent_urb3d, & !H multi-layer urban sfwin1_urb3d,sfwin2_urb3d, & !H multi-layer urban sfw1_urb3d,sfw2_urb3d,sfr_urb3d,sfg_urb3d, & !H multi-layer urban th_phy,rho,p_phy,ust, & !I multi-layer urban gmt,julday,xlong,xlat, & !I multi-layer urban a_u_bep,a_v_bep,a_t_bep,a_q_bep, & !O multi-layer urban a_e_bep,b_u_bep,b_v_bep, & !O multi-layer urban b_t_bep,b_q_bep,b_e_bep,dlg_bep, & !O multi-layer urban dl_u_bep,sf_bep,vl_bep ) !O multi-layer urban !---------------------------------------------------------------- IMPLICIT NONE !---------------------------------------------------------------- !---------------------------------------------------------------- ! --- atmospheric (WRF generic) variables !-- DT time step (seconds) !-- DZ8W thickness of layers (m) !-- T3D temperature (K) !-- QV3D 3D water vapor mixing ratio (Kg/Kg) !-- P3D 3D pressure (Pa) !-- FLHC exchange coefficient for heat (m/s) !-- FLQC exchange coefficient for moisture (m/s) !-- PSFC surface pressure (Pa) !-- XLAND land mask (1 for land, 2 for water) !-- QGH saturated mixing ratio at 2 meter !-- GSW downward short wave flux at ground surface (W/m^2) !-- GLW downward long wave flux at ground surface (W/m^2) !-- History variables !-- CANWAT canopy moisture content (mm) !-- TSK surface temperature (K) !-- TSLB soil temp (k) !-- SMOIS total soil moisture content (volumetric fraction) !-- SH2O unfrozen soil moisture content (volumetric fraction) ! note: frozen soil moisture (i.e., soil ice) = SMOIS - SH2O !-- SNOWH actual snow depth (m) !-- SNOW liquid water-equivalent snow depth (m) !-- ALBEDO time-varying surface albedo including snow effect (unitless fraction) !-- ALBBCK background surface albedo (unitless fraction) !-- CHS surface exchange coefficient for heat and moisture (m s-1); !-- CHS2 2m surface exchange coefficient for heat (m s-1); !-- CQS2 2m surface exchange coefficient for moisture (m s-1); ! --- soil variables !-- num_soil_layers the number of soil layers !-- ZS depths of centers of soil layers (m) !-- DZS thicknesses of soil layers (m) !-- SLDPTH thickness of each soil layer (m, same as DZS) !-- TMN soil temperature at lower boundary (K) !-- SMCWLT wilting point (volumetric) !-- SMCDRY dry soil moisture threshold where direct evap from ! top soil layer ends (volumetric) !-- SMCREF soil moisture threshold below which transpiration begins to ! stress (volumetric) !-- SMCMAX porosity, i.e. saturated value of soil moisture (volumetric) !-- NROOT number of root layers, a function of veg type, determined ! in subroutine redprm. !-- SMSTAV Soil moisture availability for evapotranspiration ( ! fraction between SMCWLT and SMCMXA) !-- SMSTOT Total soil moisture content frozen+unfrozen) in the soil column (mm) ! --- snow variables !-- SNOWC fraction snow coverage (0-1.0) ! --- vegetation variables !-- SNOALB upper bound on maximum albedo over deep snow !-- SHDMIN minimum areal fractional coverage of annual green vegetation !-- SHDMAX maximum areal fractional coverage of annual green vegetation !-- XLAI leaf area index (dimensionless) !-- Z0BRD Background fixed roughness length (M) !-- Z0 Background vroughness length (M) as function !-- ZNT Time varying roughness length (M) as function !-- ALBD(IVGTPK,ISN) background albedo reading from a table ! --- LSM output !-- HFX upward heat flux at the surface (W/m^2) !-- QFX upward moisture flux at the surface (kg/m^2/s) !-- LH upward moisture flux at the surface (W m-2) !-- GRDFLX(I,J) ground heat flux (W m-2) !-- FDOWN radiation forcing at the surface (W m-2) = SOLDN*(1-alb)+LWDN !---------------------------------------------------------------------------- !-- EC canopy water evaporation ((W m-2) !-- EDIR direct soil evaporation (W m-2) !-- ET plant transpiration from a particular root layer (W m-2) !-- ETT total plant transpiration (W m-2) !-- ESNOW sublimation from (or deposition to if <0) snowpack (W m-2) !-- DRIP through-fall of precip and/or dew in excess of canopy ! water-holding capacity (m) !-- DEW dewfall (or frostfall for t<273.15) (M) !-- SMAV Soil Moisture Availability for each layer, as a fraction ! between SMCWLT and SMCMAX (dimensionless fraction) ! ---------------------------------------------------------------------- !-- BETA ratio of actual/potential evap (dimensionless) !-- ETP potential evaporation (W m-2) ! ---------------------------------------------------------------------- !-- FLX1 precip-snow sfc (W m-2) !-- FLX2 freezing rain latent heat flux (W m-2) !-- FLX3 phase-change heat flux from snowmelt (W m-2) ! ---------------------------------------------------------------------- !-- ACSNOM snow melt (mm) (water equivalent) !-- ACSNOW accumulated snow fall (mm) (water equivalent) !-- SNOPCX snow phase change heat flux (W/m^2) !-- POTEVP accumulated potential evaporation (W/m^2) !-- RIB Documentation needed!!! ! ---------------------------------------------------------------------- !-- RUNOFF1 surface runoff (m s-1), not infiltrating the surface !-- RUNOFF2 subsurface runoff (m s-1), drainage out bottom of last ! soil layer (baseflow) ! important note: here RUNOFF2 is actually the sum of RUNOFF2 and RUNOFF3 !-- RUNOFF3 numerical trunctation in excess of porosity (smcmax) ! for a given soil layer at the end of a time step (m s-1). !SFCRUNOFF Surface Runoff (mm) !UDRUNOFF Total Underground Runoff (mm), which is the sum of RUNOFF2 and RUNOFF3 ! ---------------------------------------------------------------------- !-- RC canopy resistance (s m-1) !-- PC plant coefficient (unitless fraction, 0-1) where PC*ETP = actual transp !-- RSMIN minimum canopy resistance (s m-1) !-- RCS incoming solar rc factor (dimensionless) !-- RCT air temperature rc factor (dimensionless) !-- RCQ atmos vapor pressure deficit rc factor (dimensionless) !-- RCSOIL soil moisture rc factor (dimensionless) !-- EMISS surface emissivity (between 0 and 1) !-- EMBCK Background surface emissivity (between 0 and 1) !-- ROVCP R/CP ! (R_d/R_v) (dimensionless) !-- ids start index for i in domain !-- ide end index for i in domain !-- jds start index for j in domain !-- jde end index for j in domain !-- kds start index for k in domain !-- kde end index for k in domain !-- ims start index for i in memory !-- ime end index for i in memory !-- jms start index for j in memory !-- jme end index for j in memory !-- kms start index for k in memory !-- kme end index for k in memory !-- its start index for i in tile !-- ite end index for i in tile !-- jts start index for j in tile !-- jte end index for j in tile !-- kts start index for k in tile !-- kte end index for k in tile ! !-- SR fraction of frozen precip (0.0 to 1.0) !---------------------------------------------------------------- ! IN only INTEGER, INTENT(IN ) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte INTEGER, INTENT(IN ) :: sf_urban_physics !urban INTEGER, INTENT(IN ) :: isurban INTEGER, INTENT(IN ) :: isice REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(IN ) :: TMN, & XLAND, & XICE, & VEGFRA, & SHDMIN, & SHDMAX, & SNOALB, & GSW, & SWDOWN, & !added 10 jan 2007 GLW, & RAINBL, & EMBCK, & SR REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(INOUT) :: ALBBCK, & Z0 CHARACTER(LEN=*), INTENT(IN ) :: MMINLU REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , & INTENT(IN ) :: QV3D, & p8w3D, & DZ8W, & T3D REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(IN ) :: QGH, & CPM INTEGER, DIMENSION( ims:ime, jms:jme ) , & INTENT(IN ) :: IVGTYP, & ISLTYP INTEGER, INTENT(IN) :: num_soil_layers,ITIMESTEP REAL, INTENT(IN ) :: DT,ROVCP REAL, DIMENSION(1:num_soil_layers), INTENT(IN)::DZS ! IN and OUT REAL, DIMENSION( ims:ime , 1:num_soil_layers, jms:jme ), & INTENT(INOUT) :: SMOIS, & ! total soil moisture SH2O, & ! new soil liquid TSLB ! TSLB STEMP REAL, DIMENSION( ims:ime , 1:num_soil_layers, jms:jme ), & INTENT(OUT) :: SMCREL REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(INOUT) :: TSK, & !was TGB (temperature) HFX, & QFX, & LH, & GRDFLX, & QSFC,& CQS2,& CHS, & CHS2,& SNOW, & SNOWC, & SNOWH, & !new CANWAT, & SMSTAV, & SMSTOT, & SFCRUNOFF, & UDRUNOFF, & ACSNOM, & ACSNOW, & SNOTIME, & SNOPCX, & EMISS, & RIB, & POTEVP, & ALBEDO, & ZNT REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(OUT) :: NOAHRES REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(OUT) :: CHKLOWQ REAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: LAI REAL,DIMENSION(IMS:IME,JMS:JME),INTENT(IN) :: QZ0 REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CMR_SFCDIF REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CHR_SFCDIF REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CMC_SFCDIF REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CHC_SFCDIF ! Local variables (moved here from driver to make routine thread safe, 20031007 jm) REAL, DIMENSION(1:num_soil_layers) :: ET REAL, DIMENSION(1:num_soil_layers) :: SMAV REAL :: BETA, ETP, SSOIL,EC, EDIR, ESNOW, ETT, & FLX1,FLX2,FLX3, DRIP,DEW,FDOWN,RC,PC,RSMIN,XLAI, & ! RCS,RCT,RCQ,RCSOIL RCS,RCT,RCQ,RCSOIL,FFROZP LOGICAL, INTENT(IN ) :: myj,frpcpn ! DECLARATIONS - LOGICAL ! ---------------------------------------------------------------------- LOGICAL, PARAMETER :: LOCAL=.false. LOGICAL :: FRZGRA, SNOWNG LOGICAL :: IPRINT ! ---------------------------------------------------------------------- ! DECLARATIONS - INTEGER ! ---------------------------------------------------------------------- INTEGER :: I,J, ICE,NSOIL,SLOPETYP,SOILTYP,VEGTYP INTEGER :: NROOT INTEGER :: KZ ,K INTEGER :: NS ! ---------------------------------------------------------------------- ! DECLARATIONS - REAL ! ---------------------------------------------------------------------- REAL :: SHMIN,SHMAX,DQSDT2,LWDN,PRCP,PRCPRAIN, & Q2SAT,Q2SATI,SFCPRS,SFCSPD,SFCTMP,SHDFAC,SNOALB1, & SOLDN,TBOT,ZLVL, Q2K,ALBBRD, ALBEDOK, ETA, ETA_KINEMATIC, & EMBRD, & Z0K,RUNOFF1,RUNOFF2,RUNOFF3,SHEAT,SOLNET,E2SAT,SFCTSNO, & ! mek, WRF testing, expanded diagnostics SOLUP,LWUP,RNET,RES,Q1SFC,TAIRV,SATFLG ! MEK MAY 2007 REAL :: FDTLIW ! MEK JUL2007 for pot. evap. REAL :: RIBB REAL :: FDTW REAL :: EMISSI REAL :: SNCOVR,SNEQV,SNOWHK,CMC, CHK,TH2 REAL :: SMCDRY,SMCMAX,SMCREF,SMCWLT,SNOMLT,SOILM,SOILW,Q1,T1 REAL :: SNOTIME1 ! LSTSNW1 INITIAL NUMBER OF TIMESTEPS SINCE LAST SNOWFALL REAL :: DUMMY,Z0BRD ! REAL :: COSZ, SOLARDIRECT ! REAL, DIMENSION(1:num_soil_layers):: SLDPTH, STC,SMC,SWC ! REAL, DIMENSION(1:num_soil_layers) :: ZSOIL, RTDIS REAL, PARAMETER :: TRESH=.95E0, A2=17.67,A3=273.15,A4=29.65, & T0=273.16E0, ELWV=2.50E6, A23M4=A2*(A3-A4) ! MEK MAY 2007 REAL, PARAMETER :: ROW=1.E3,ELIW=XLF,ROWLIW=ROW*ELIW ! ---------------------------------------------------------------------- ! DECLARATIONS START - urban ! ---------------------------------------------------------------------- ! input variables surface_driver --> lsm INTEGER, INTENT(IN) :: num_roof_layers INTEGER, INTENT(IN) :: num_wall_layers INTEGER, INTENT(IN) :: num_road_layers REAL, OPTIONAL, DIMENSION(1:num_roof_layers), INTENT(IN) :: DZR REAL, OPTIONAL, DIMENSION(1:num_wall_layers), INTENT(IN) :: DZB REAL, OPTIONAL, DIMENSION(1:num_road_layers), INTENT(IN) :: DZG REAL, OPTIONAL, INTENT(IN) :: DECLIN_URB REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: COSZ_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: OMG_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: XLAT_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN) :: U_PHY REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN) :: V_PHY REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN) :: TH_PHY REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN) :: P_PHY REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN) :: RHO REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: UST LOGICAL, intent(in) :: rdlai2d LOGICAL, intent(in) :: USEMONALB ! input variables lsm --> urban INTEGER :: UTYPE_URB ! urban type [urban=1, suburban=2, rural=3] REAL :: TA_URB ! potential temp at 1st atmospheric level [K] REAL :: QA_URB ! mixing ratio at 1st atmospheric level [kg/kg] REAL :: UA_URB ! wind speed at 1st atmospheric level [m/s] REAL :: U1_URB ! u at 1st atmospheric level [m/s] REAL :: V1_URB ! v at 1st atmospheric level [m/s] REAL :: SSG_URB ! downward total short wave radiation [W/m/m] REAL :: LLG_URB ! downward long wave radiation [W/m/m] REAL :: RAIN_URB ! precipitation [mm/h] REAL :: RHOO_URB ! air density [kg/m^3] REAL :: ZA_URB ! first atmospheric level [m] REAL :: DELT_URB ! time step [s] REAL :: SSGD_URB ! downward direct short wave radiation [W/m/m] REAL :: SSGQ_URB ! downward diffuse short wave radiation [W/m/m] REAL :: XLAT_URB ! latitude [deg] REAL :: COSZ_URB ! cosz REAL :: OMG_URB ! hour angle REAL :: ZNT_URB ! roughness length [m] REAL :: TR_URB REAL :: TB_URB REAL :: TG_URB REAL :: TC_URB REAL :: QC_URB REAL :: UC_URB REAL :: XXXR_URB REAL :: XXXB_URB REAL :: XXXG_URB REAL :: XXXC_URB REAL, DIMENSION(1:num_roof_layers) :: TRL_URB ! roof layer temp [K] REAL, DIMENSION(1:num_wall_layers) :: TBL_URB ! wall layer temp [K] REAL, DIMENSION(1:num_road_layers) :: TGL_URB ! road layer temp [K] LOGICAL :: LSOLAR_URB ! state variable surface_driver <--> lsm <--> urban REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: TR_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: TB_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: TG_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: TC_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: QC_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: UC_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: XXXR_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: XXXB_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: XXXG_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: XXXC_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: SH_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: LH_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: G_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: RN_URB2D ! REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: TS_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_roof_layers, jms:jme ), INTENT(INOUT) :: TRL_URB3D REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_wall_layers, jms:jme ), INTENT(INOUT) :: TBL_URB3D REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_road_layers, jms:jme ), INTENT(INOUT) :: TGL_URB3D ! output variable lsm --> surface_driver REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: PSIM_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: PSIH_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: GZ1OZ0_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: U10_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: V10_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: TH2_URB2D REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: Q2_URB2D ! REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: AKMS_URB2D ! REAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: UST_URB2D REAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: FRC_URB2D INTEGER, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: UTYPE_URB2D ! output variables urban --> lsm REAL :: TS_URB ! surface radiative temperature [K] REAL :: QS_URB ! surface humidity [-] REAL :: SH_URB ! sensible heat flux [W/m/m] REAL :: LH_URB ! latent heat flux [W/m/m] REAL :: LH_KINEMATIC_URB ! latent heat flux, kinetic [kg/m/m/s] REAL :: SW_URB ! upward short wave radiation flux [W/m/m] REAL :: ALB_URB ! time-varying albedo [fraction] REAL :: LW_URB ! upward long wave radiation flux [W/m/m] REAL :: G_URB ! heat flux into the ground [W/m/m] REAL :: RN_URB ! net radiation [W/m/m] REAL :: PSIM_URB ! shear f for momentum [-] REAL :: PSIH_URB ! shear f for heat [-] REAL :: GZ1OZ0_URB ! shear f for heat [-] REAL :: U10_URB ! wind u component at 10 m [m/s] REAL :: V10_URB ! wind v component at 10 m [m/s] REAL :: TH2_URB ! potential temperature at 2 m [K] REAL :: Q2_URB ! humidity at 2 m [-] REAL :: CHS_URB REAL :: CHS2_URB REAL :: UST_URB ! Variables for multi-layer UCM (Martilli et al. 2002) REAL, OPTIONAL, INTENT(IN ) :: GMT INTEGER, OPTIONAL, INTENT(IN ) :: JULDAY REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN ) ::XLAT, XLONG INTEGER, INTENT(IN ) :: NUM_URBAN_LAYERS REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: trb_urb4d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tw1_urb4d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tw2_urb4d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tgb_urb4d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tlev_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: qlev_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tw1lev_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tw2lev_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tglev_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: tflev_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: lf_ac_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: sf_ac_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: cm_ac_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: sfvent_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: lfvent_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: sfwin1_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: sfwin2_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: sfw1_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: sfw2_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: sfr_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_urban_layers, jms:jme ), INTENT(INOUT) :: sfg_urb3d REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::a_u_bep !Implicit momemtum component X-direction REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::a_v_bep !Implicit momemtum component Y-direction REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::a_t_bep !Implicit component pot. temperature REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::a_q_bep !Implicit momemtum component X-direction REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::a_e_bep !Implicit component TKE REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::b_u_bep !Explicit momentum component X-direction REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::b_v_bep !Explicit momentum component Y-direction REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::b_t_bep !Explicit component pot. temperature REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::b_q_bep !Implicit momemtum component Y-direction REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::b_e_bep !Explicit component TKE REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::vl_bep !Fraction air volume in grid cell REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::dlg_bep !Height above ground REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::sf_bep !Fraction air at the face of grid cell REAL, OPTIONAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(INOUT) ::dl_u_bep !Length scale ! Local variables for multi-layer UCM (Martilli et al. 2002) REAL, DIMENSION( ims:ime, jms:jme ) :: HFX_RURAL,LH_RURAL,GRDFLX_RURAL,RN_RURAL REAL, DIMENSION( ims:ime, jms:jme ) :: QFX_RURAL,QSFC_RURAL,UMOM_RURAL,VMOM_RURAL REAL, DIMENSION( ims:ime, jms:jme ) :: ALB_RURAL,EMISS_RURAL,UST_RURAL,TSK_RURAL ! REAL, DIMENSION( ims:ime, jms:jme ) :: GRDFLX_URB ! REAL, DIMENSION( ims:ime, jms:jme ) :: QFX_URB,QSFC_URB,UMOM_URB,VMOM_URB REAL, DIMENSION( ims:ime, jms:jme ) :: HFX_URB,UMOM_URB,VMOM_URB REAL, DIMENSION( ims:ime, jms:jme ) :: QFX_URB ! REAL, DIMENSION( ims:ime, jms:jme ) :: ALBEDO_URB,EMISS_URB,UMOM,VMOM,UST REAL, DIMENSION(ims:ime,jms:jme) ::EMISS_URB REAL, DIMENSION(ims:ime,jms:jme) :: RL_UP_URB REAL, DIMENSION(ims:ime,jms:jme) ::RS_ABS_URB REAL, DIMENSION(ims:ime,jms:jme) ::GRDFLX_URB REAL :: SIGMA_SB,RL_UP_RURAL,RL_UP_TOT,RS_ABS_TOT,UMOM,VMOM REAL :: r1,r2,r3 REAL :: CMR_URB, CHR_URB, CMC_URB, CHC_URB ! ---------------------------------------------------------------------- ! DECLARATIONS END - urban ! ---------------------------------------------------------------------- REAL, PARAMETER :: CAPA=R_D/CP REAL :: APELM,APES,SFCTH2,PSFC real, intent(in) :: xice_threshold character(len=80) :: message_text ! MEK MAY 2007 FDTLIW=DT/ROWLIW ! MEK JUL2007 FDTW=DT/(XLV*RHOWATER) ! debug printout IPRINT=.false. ! SLOPETYP=2 SLOPETYP=1 ! SHDMIN=0.00 NSOIL=num_soil_layers DO NS=1,NSOIL SLDPTH(NS)=DZS(NS) ENDDO DO J=jts,jte IF(ITIMESTEP.EQ.1)THEN DO 50 I=its,ite !*** initialize soil conditions for IHOP 31 May case ! IF((XLAND(I,J)-1.5) < 0.)THEN ! if (I==108.and.j==85) then ! DO NS=1,NSOIL ! SMOIS(I,NS,J)=0.10 ! SH2O(I,NS,J)=0.10 ! enddo ! endif ! ENDIF !*** SET ZERO-VALUE FOR SOME OUTPUT DIAGNOSTIC ARRAYS IF((XLAND(I,J)-1.5).GE.0.)THEN ! check sea-ice point #if 0 IF( XICE(I,J).GE. XICE_THRESHOLD .and. IPRINT ) PRINT*, ' sea-ice at water point, I=',I,'J=',J #endif !*** Open Water Case SMSTAV(I,J)=1.0 SMSTOT(I,J)=1.0 DO NS=1,NSOIL SMOIS(I,NS,J)=1.0 TSLB(I,NS,J)=273.16 !STEMP SMCREL(I,NS,J)=1.0 ENDDO ELSE IF ( XICE(I,J) .GE. XICE_THRESHOLD ) THEN !*** SEA-ICE CASE SMSTAV(I,J)=1.0 SMSTOT(I,J)=1.0 DO NS=1,NSOIL SMOIS(I,NS,J)=1.0 SMCREL(I,NS,J)=1.0 ENDDO ENDIF ENDIF ! 50 CONTINUE ENDIF ! end of initialization over ocean !----------------------------------------------------------------------- DO 100 I=its,ite ! surface pressure PSFC=P8w3D(i,1,j) ! pressure in middle of lowest layer SFCPRS=(P8W3D(I,KTS+1,j)+P8W3D(i,KTS,j))*0.5 ! convert from mixing ratio to specific humidity Q2K=QV3D(i,1,j)/(1.0+QV3D(i,1,j)) ! ! Q2SAT=QGH(I,j) Q2SAT=QGH(I,J)/(1.0+QGH(I,J)) ! Q2SAT is sp humidity ! add check on myj=.true. ! IF((Q2K.GE.Q2SAT*TRESH).AND.Q2K.LT.QZ0(I,J))THEN IF((myj).AND.(Q2K.GE.Q2SAT*TRESH).AND.Q2K.LT.QZ0(I,J))THEN SATFLG=0. CHKLOWQ(I,J)=0. ELSE SATFLG=1.0 CHKLOWQ(I,J)=1. ENDIF SFCTMP=T3D(i,1,j) ZLVL=0.5*DZ8W(i,1,j) ! TH2=SFCTMP+(0.0097545*ZLVL) ! calculate SFCTH2 via Exner function vs lapse-rate (above) APES=(1.E5/PSFC)**CAPA APELM=(1.E5/SFCPRS)**CAPA SFCTH2=SFCTMP*APELM TH2=SFCTH2/APES ! EMISSI = EMISS(I,J) LWDN=GLW(I,J)*EMISSI ! SOLDN is total incoming solar SOLDN=SWDOWN(I,J) ! GSW is net downward solar ! SOLNET=GSW(I,J) ! use mid-day albedo to determine net downward solar (no solar zenith angle correction) SOLNET=SOLDN*(1.-ALBEDO(I,J)) PRCP=RAINBL(i,j)/DT VEGTYP=IVGTYP(I,J) SOILTYP=ISLTYP(I,J) SHDFAC=VEGFRA(I,J)/100. T1=TSK(I,J) CHK=CHS(I,J) SHMIN=SHDMIN(I,J)/100. !NEW SHMAX=SHDMAX(I,J)/100. !NEW ! convert snow water equivalent from mm to meter SNEQV=SNOW(I,J)*0.001 ! snow depth in meters SNOWHK=SNOWH(I,J) SNCOVR=SNOWC(I,J) ! if "SR" present, set frac of frozen precip ("FFROZP") = snow-ratio ("SR", range:0-1) ! SR from e.g. Ferrier microphysics ! otherwise define from 1st atmos level temperature IF(FRPCPN) THEN FFROZP=SR(I,J) ELSE IF (SFCTMP <= 273.15) THEN FFROZP = 1.0 ELSE FFROZP = 0.0 ENDIF ENDIF !*** IF((XLAND(I,J)-1.5).GE.0.)THEN ! begining of land/sea if block ! Open water points TSK_RURAL(I,J)=TSK(I,J) HFX_RURAL(I,J)=HFX(I,J) QFX_RURAL(I,J)=QFX(I,J) LH_RURAL(I,J)=LH(I,J) EMISS_RURAL(I,J)=EMISS(I,J) GRDFLX_RURAL(I,J)=GRDFLX(I,J) ELSE ! Land or sea-ice case IF (XICE(I,J) >= XICE_THRESHOLD) THEN ! Sea-ice point ICE = 1 ELSE IF ( VEGTYP == ISICE ) THEN ! Land-ice point ICE = -1 ELSE ! Neither sea ice or land ice. ICE=0 ENDIF DQSDT2=Q2SAT*A23M4/(SFCTMP-A4)**2 IF(SNOW(I,J).GT.0.0)THEN ! snow on surface (use ice saturation properties) SFCTSNO=SFCTMP E2SAT=611.2*EXP(6174.*(1./273.15 - 1./SFCTSNO)) Q2SATI=0.622*E2SAT/(SFCPRS-E2SAT) Q2SATI=Q2SATI/(1.0+Q2SATI) ! spec. hum. IF (T1 .GT. 273.14) THEN ! warm ground temps, weight the saturation between ice and water according to SNOWC Q2SAT=Q2SAT*(1.-SNOWC(I,J)) + Q2SATI*SNOWC(I,J) DQSDT2=DQSDT2*(1.-SNOWC(I,J)) + Q2SATI*6174./(SFCTSNO**2)*SNOWC(I,J) ELSE ! cold ground temps, use ice saturation only Q2SAT=Q2SATI DQSDT2=Q2SATI*6174./(SFCTSNO**2) ENDIF ! for snow cover fraction at 0 C, ground temp will not change, so DQSDT2 effectively zero IF(T1 .GT. 273. .AND. SNOWC(I,J) .GT. 0.)DQSDT2=DQSDT2*(1.-SNOWC(I,J)) ENDIF IF(ICE.EQ.1)THEN ! Sea-ice point has deep-level temperature of -2 C TBOT=271.16 ELSE ! Land-ice or land points have the usual deep-soil temperature. TBOT=TMN(I,J) ENDIF IF(VEGTYP.EQ.25) SHDFAC=0.0000 IF(VEGTYP.EQ.26) SHDFAC=0.0000 IF(VEGTYP.EQ.27) SHDFAC=0.0000 IF(SOILTYP.EQ.14.AND.XICE(I,J).EQ.0.)THEN #if 0 IF(IPRINT)PRINT*,' SOIL TYPE FOUND TO BE WATER AT A LAND-POINT' IF(IPRINT)PRINT*,i,j,'RESET SOIL in surfce.F' #endif SOILTYP=7 ENDIF SNOALB1 = SNOALB(I,J) CMC=CANWAT(I,J) !------------------------------------------- !*** convert snow depth from mm to meter ! ! IF(RDMAXALB) THEN ! SNOALB=ALBMAX(I,J)*0.01 ! ELSE ! SNOALB=MAXALB(IVGTPK)*0.01 ! ENDIF ! SNOALB1=0.80 ! SHMIN=0.00 ALBBRD=ALBBCK(I,J) Z0BRD=Z0(I,J) EMBRD=EMBCK(I,J) SNOTIME1 = SNOTIME(I,J) RIBB=RIB(I,J) !FEI: temporaray arrays above need to be changed later by using SI DO 70 NS=1,NSOIL SMC(NS)=SMOIS(I,NS,J) STC(NS)=TSLB(I,NS,J) !STEMP SWC(NS)=SH2O(I,NS,J) 70 CONTINUE ! if ( (SNEQV.ne.0..AND.SNOWHK.eq.0.).or.(SNOWHK.le.SNEQV) )THEN SNOWHK= 5.*SNEQV endif ! !Fei: urban. for urban surface, if calling UCM, redefine the natural surface in cities as ! the "NATURAL" category in the VEGPARM.TBL IF(SF_URBAN_PHYSICS == 1.OR. SF_URBAN_PHYSICS==2.OR.SF_URBAN_PHYSICS==3 ) THEN IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == 31 .or. & IVGTYP(I,J) == 32 .or. IVGTYP(I,J) == 33) THEN VEGTYP = NATURAL SHDFAC = SHDTBL(NATURAL) ALBEDOK =0.2 ! 0.2 ALBBRD =0.2 !0.2 EMISSI = 0.98 !for VEGTYP=5 IF ( FRC_URB2D(I,J) < 0.99 ) THEN if(sf_urban_physics.eq.1)then T1= ( TSK(I,J) -FRC_URB2D(I,J) * TS_URB2D (I,J) )/ (1-FRC_URB2D(I,J)) elseif((sf_urban_physics.eq.2).OR.(sf_urban_physics.eq.3))then r1= (tsk(i,j)**4.) r2= frc_urb2d(i,j)*(ts_urb2d(i,j)**4.) r3= (1.-frc_urb2d(i,j)) t1= ((r1-r2)/r3)**.25 endif ELSE T1 = TSK(I,J) ENDIF ENDIF ELSE IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == 31 .or. & IVGTYP(I,J) == 32 .or. IVGTYP(I,J) == 33) THEN VEGTYP = ISURBAN ENDIF ENDIF #if 0 IF(IPRINT) THEN ! print*, 'BEFORE SFLX, in Noahlsm_driver' print*, 'ICE', ICE, 'DT',DT, 'ZLVL',ZLVL, 'NSOIL', NSOIL, & 'SLDPTH', SLDPTH, 'LOCAL',LOCAL, 'LUTYPE',& LUTYPE, 'SLTYPE',SLTYPE, 'LWDN',LWDN, 'SOLDN',SOLDN, & 'SFCPRS',SFCPRS, 'PRCP',PRCP,'SFCTMP',SFCTMP,'Q2K',Q2K, & 'TH2',TH2,'Q2SAT',Q2SAT,'DQSDT2',DQSDT2,'VEGTYP', VEGTYP,& 'SOILTYP',SOILTYP, 'SLOPETYP',SLOPETYP, 'SHDFAC',SHDFAC,& 'SHMIN',SHMIN, 'ALBBRD',ALBBRD,'SNOALB1',SNOALB1,'TBOT',& TBOT, 'Z0BRD',Z0BRD, 'Z0K',Z0K, 'CMC',CMC, 'T1',T1,'STC',& STC, 'SMC',SMC, 'SWC',SWC,'SNOWHK',SNOWHK,'SNEQV',SNEQV,& 'ALBEDOK',ALBEDOK,'CHK',CHK,'ETA',ETA,'SHEAT',SHEAT, & 'ETA_KINEMATIC',ETA_KINEMATIC, 'FDOWN',FDOWN,'EC',EC, & 'EDIR',EDIR,'ET',ET,'ETT',ETT,'ESNOW',ESNOW,'DRIP',DRIP,& 'DEW',DEW,'BETA',BETA,'ETP',ETP,'SSOIL',SSOIL,'FLX1',FLX1,& 'FLX2',FLX2,'FLX3',FLX3,'SNOMLT',SNOMLT,'SNCOVR',SNCOVR,& 'RUNOFF1',RUNOFF1,'RUNOFF2',RUNOFF2,'RUNOFF3',RUNOFF3, & 'RC',RC, 'PC',PC,'RSMIN',RSMIN,'XLAI',XLAI,'RCS',RCS, & 'RCT',RCT,'RCQ',RCQ,'RCSOIL',RCSOIL,'SOILW',SOILW, & 'SOILM',SOILM,'Q1',Q1,'SMCWLT',SMCWLT,'SMCDRY',SMCDRY,& 'SMCREF',SMCREF,'SMCMAX',SMCMAX,'NROOT',NROOT endif #endif IF (rdlai2d) THEN xlai = lai(i,j) endif CALL SFLX (FFROZP, ICE, ISURBAN, DT,ZLVL,NSOIL,SLDPTH, & !C LOCAL, & !L LUTYPE, SLTYPE, & !CL LWDN,SOLDN,SOLNET,SFCPRS,PRCP,SFCTMP,Q2K,DUMMY, & !F DUMMY,DUMMY, DUMMY, & !F PRCPRAIN not used TH2,Q2SAT,DQSDT2, & !I VEGTYP,SOILTYP,SLOPETYP,SHDFAC,SHMIN,SHMAX, & !I ALBBRD, SNOALB1,TBOT, Z0BRD, Z0K, EMISSI, EMBRD, & !S CMC,T1,STC,SMC,SWC,SNOWHK,SNEQV,ALBEDOK,CHK,dummy,& !H ETA,SHEAT, ETA_KINEMATIC,FDOWN, & !O EC,EDIR,ET,ETT,ESNOW,DRIP,DEW, & !O BETA,ETP,SSOIL, & !O FLX1,FLX2,FLX3, & !O SNOMLT,SNCOVR, & !O RUNOFF1,RUNOFF2,RUNOFF3, & !O RC,PC,RSMIN,XLAI,RCS,RCT,RCQ,RCSOIL, & !O SOILW,SOILM,Q1,SMAV, & !D RDLAI2D,USEMONALB, & SNOTIME1, & RIBB, & SMCWLT,SMCDRY,SMCREF,SMCMAX,NROOT) lai(i,j) = xlai #if 0 IF(IPRINT) THEN print*, 'AFTER SFLX, in Noahlsm_driver' print*, 'ICE', ICE, 'DT',DT, 'ZLVL',ZLVL, 'NSOIL', NSOIL, & 'SLDPTH', SLDPTH, 'LOCAL',LOCAL, 'LUTYPE',& LUTYPE, 'SLTYPE',SLTYPE, 'LWDN',LWDN, 'SOLDN',SOLDN, & 'SFCPRS',SFCPRS, 'PRCP',PRCP,'SFCTMP',SFCTMP,'Q2K',Q2K, & 'TH2',TH2,'Q2SAT',Q2SAT,'DQSDT2',DQSDT2,'VEGTYP', VEGTYP,& 'SOILTYP',SOILTYP, 'SLOPETYP',SLOPETYP, 'SHDFAC',SHDFAC,& 'SHDMIN',SHMIN, 'ALBBRD',ALBBRD,'SNOALB',SNOALB1,'TBOT',& TBOT, 'Z0BRD',Z0BRD, 'Z0K',Z0K, 'CMC',CMC, 'T1',T1,'STC',& STC, 'SMC',SMC, 'SWc',SWC,'SNOWHK',SNOWHK,'SNEQV',SNEQV,& 'ALBEDOK',ALBEDOK,'CHK',CHK,'ETA',ETA,'SHEAT',SHEAT, & 'ETA_KINEMATIC',ETA_KINEMATIC, 'FDOWN',FDOWN,'EC',EC, & 'EDIR',EDIR,'ET',ET,'ETT',ETT,'ESNOW',ESNOW,'DRIP',DRIP,& 'DEW',DEW,'BETA',BETA,'ETP',ETP,'SSOIL',SSOIL,'FLX1',FLX1,& 'FLX2',FLX2,'FLX3',FLX3,'SNOMLT',SNOMLT,'SNCOVR',SNCOVR,& 'RUNOFF1',RUNOFF1,'RUNOFF2',RUNOFF2,'RUNOFF3',RUNOFF3, & 'RC',RC, 'PC',PC,'RSMIN',RSMIN,'XLAI',XLAI,'RCS',RCS, & 'RCT',RCT,'RCQ',RCQ,'RCSOIL',RCSOIL,'SOILW',SOILW, & 'SOILM',SOILM,'Q1',Q1,'SMCWLT',SMCWLT,'SMCDRY',SMCDRY,& 'SMCREF',SMCREF,'SMCMAX',SMCMAX,'NROOT',NROOT endif #endif !*** UPDATE STATE VARIABLES CANWAT(I,J)=CMC SNOW(I,J)=SNEQV*1000. ! SNOWH(I,J)=SNOWHK*1000. SNOWH(I,J)=SNOWHK ! SNOWHK in meters ALBEDO(I,J)=ALBEDOK ALB_RURAL(I,J)=ALBEDOK ALBBCK(I,J)=ALBBRD Z0(I,J)=Z0BRD EMISS(I,J) = EMISSI EMISS_RURAL(I,J) = EMISSI ! Noah: activate time-varying roughness length (V3.3 Feb 2011) ZNT(I,J)=Z0K TSK(I,J)=T1 TSK_RURAL(I,J)=T1 HFX(I,J)=SHEAT HFX_RURAL(I,J)=SHEAT ! MEk Jul07 add potential evap accum POTEVP(I,J)=POTEVP(I,J)+ETP*FDTW QFX(I,J)=ETA_KINEMATIC QFX_RURAL(I,J)=ETA_KINEMATIC LH(I,J)=ETA LH_RURAL(I,J)=ETA GRDFLX(I,J)=SSOIL GRDFLX_RURAL(I,J)=SSOIL SNOWC(I,J)=SNCOVR CHS2(I,J)=CQS2(I,J) SNOTIME(I,J) = SNOTIME1 ! prevent diagnostic ground q (q1) from being greater than qsat(tsk) ! as happens over snow cover where the cqs2 value also becomes irrelevant ! by setting cqs2=chs in this situation the 2m q should become just qv(k=1) IF (Q1 .GT. QSFC(I,J)) THEN CQS2(I,J) = CHS(I,J) ENDIF ! QSFC(I,J)=Q1 ! Convert QSFC back to mixing ratio QSFC(I,J)= Q1/(1.0-Q1) ! QSFC_RURAL(I,J)= Q1/(1.0-Q1) ! Calculate momentum flux from rural surface for use with multi-layer UCM (Martilli et al. 2002) DO 80 NS=1,NSOIL SMOIS(I,NS,J)=SMC(NS) TSLB(I,NS,J)=STC(NS) ! STEMP SH2O(I,NS,J)=SWC(NS) 80 CONTINUE ! ENDIF ! ! Residual of surface energy balance equation terms ! noahres(i,j) = ( solnet + lwdn ) - sheat + ssoil - eta - ( emissi * STBOLT * (t1**4) ) - flx1 - flx2 - flx3 IF (SF_URBAN_PHYSICS == 1 ) THEN ! Beginning of UCM CALL if block !-------------------------------------- ! URBAN CANOPY MODEL START - urban !-------------------------------------- ! Input variables lsm --> urban IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == 31 .or. & IVGTYP(I,J) == 32 .or. IVGTYP(I,J) == 33 ) THEN ! Call urban ! UTYPE_URB = UTYPE_URB2D(I,J) !urban type (low, high or industrial) TA_URB = SFCTMP ! [K] QA_URB = Q2K ! [kg/kg] UA_URB = SQRT(U_PHY(I,1,J)**2.+V_PHY(I,1,J)**2.) U1_URB = U_PHY(I,1,J) V1_URB = V_PHY(I,1,J) IF(UA_URB < 1.) UA_URB=1. ! [m/s] SSG_URB = SOLDN ! [W/m/m] SSGD_URB = 0.8*SOLDN ! [W/m/m] SSGQ_URB = SSG_URB-SSGD_URB ! [W/m/m] LLG_URB = GLW(I,J) ! [W/m/m] RAIN_URB = RAINBL(I,J) ! [mm] RHOO_URB = SFCPRS / (287.04 * SFCTMP * (1.0+ 0.61 * Q2K)) ![kg/m/m/m] ZA_URB = ZLVL ! [m] DELT_URB = DT ! [sec] XLAT_URB = XLAT_URB2D(I,J) ! [deg] COSZ_URB = COSZ_URB2D(I,J) ! OMG_URB = OMG_URB2D(I,J) ! ZNT_URB = ZNT(I,J) LSOLAR_URB = .FALSE. TR_URB = TR_URB2D(I,J) TB_URB = TB_URB2D(I,J) TG_URB = TG_URB2D(I,J) TC_URB = TC_URB2D(I,J) QC_URB = QC_URB2D(I,J) UC_URB = UC_URB2D(I,J) DO K = 1,num_roof_layers TRL_URB(K) = TRL_URB3D(I,K,J) END DO DO K = 1,num_wall_layers TBL_URB(K) = TBL_URB3D(I,K,J) END DO DO K = 1,num_road_layers TGL_URB(K) = TGL_URB3D(I,K,J) END DO XXXR_URB = XXXR_URB2D(I,J) XXXB_URB = XXXB_URB2D(I,J) XXXG_URB = XXXG_URB2D(I,J) XXXC_URB = XXXC_URB2D(I,J) ! ! ! Limits to avoid dividing by small number if (CHS(I,J) < 1.0E-02) then CHS(I,J) = 1.0E-02 endif if (CHS2(I,J) < 1.0E-02) then CHS2(I,J) = 1.0E-02 endif if (CQS2(I,J) < 1.0E-02) then CQS2(I,J) = 1.0E-02 endif ! CHS_URB = CHS(I,J) CHS2_URB = CHS2(I,J) IF (PRESENT(CMR_SFCDIF)) THEN CMR_URB = CMR_SFCDIF(I,J) CHR_URB = CHR_SFCDIF(I,J) CMC_URB = CMC_SFCDIF(I,J) CHC_URB = CHC_SFCDIF(I,J) ENDIF ! ! Call urban CALL urban(LSOLAR_URB, & ! I num_roof_layers,num_wall_layers,num_road_layers, & ! C DZR,DZB,DZG, & ! C UTYPE_URB,TA_URB,QA_URB,UA_URB,U1_URB,V1_URB,SSG_URB, & ! I SSGD_URB,SSGQ_URB,LLG_URB,RAIN_URB,RHOO_URB, & ! I ZA_URB,DECLIN_URB,COSZ_URB,OMG_URB, & ! I XLAT_URB,DELT_URB,ZNT_URB, & ! I CHS_URB, CHS2_URB, & ! I TR_URB, TB_URB, TG_URB, TC_URB, QC_URB,UC_URB, & ! H TRL_URB,TBL_URB,TGL_URB, & ! H XXXR_URB, XXXB_URB, XXXG_URB, XXXC_URB, & ! H TS_URB,QS_URB,SH_URB,LH_URB,LH_KINEMATIC_URB, & ! O SW_URB,ALB_URB,LW_URB,G_URB,RN_URB,PSIM_URB,PSIH_URB, & ! O GZ1OZ0_URB, & !O CMR_URB, CHR_URB, CMC_URB, CHC_URB, & U10_URB, V10_URB, TH2_URB, Q2_URB, & ! O UST_URB) !O #if 0 IF(IPRINT) THEN print*, 'AFTER CALL URBAN' print*,'num_roof_layers',num_roof_layers, 'num_wall_layers', & num_wall_layers, & 'DZR',DZR,'DZB',DZB,'DZG',DZG,'UTYPE_URB',UTYPE_URB,'TA_URB', & TA_URB, & 'QA_URB',QA_URB,'UA_URB',UA_URB,'U1_URB',U1_URB,'V1_URB', & V1_URB, & 'SSG_URB',SSG_URB,'SSGD_URB',SSGD_URB,'SSGQ_URB',SSGQ_URB, & 'LLG_URB',LLG_URB,'RAIN_URB',RAIN_URB,'RHOO_URB',RHOO_URB, & 'ZA_URB',ZA_URB, 'DECLIN_URB',DECLIN_URB,'COSZ_URB',COSZ_URB,& 'OMG_URB',OMG_URB,'XLAT_URB',XLAT_URB,'DELT_URB',DELT_URB, & 'ZNT_URB',ZNT_URB,'TR_URB',TR_URB, 'TB_URB',TB_URB,'TG_URB',& TG_URB,'TC_URB',TC_URB,'QC_URB',QC_URB,'TRL_URB',TRL_URB, & 'TBL_URB',TBL_URB,'TGL_URB',TGL_URB,'XXXR_URB',XXXR_URB, & 'XXXB_URB',XXXB_URB,'XXXG_URB',XXXG_URB,'XXXC_URB',XXXC_URB,& 'TS_URB',TS_URB,'QS_URB',QS_URB,'SH_URB',SH_URB,'LH_URB', & LH_URB, 'LH_KINEMATIC_URB',LH_KINEMATIC_URB,'SW_URB',SW_URB,& 'ALB_URB',ALB_URB,'LW_URB',LW_URB,'G_URB',G_URB,'RN_URB', & RN_URB, 'PSIM_URB',PSIM_URB,'PSIH_URB',PSIH_URB, & 'U10_URB',U10_URB,'V10_URB',V10_URB,'TH2_URB',TH2_URB, & 'Q2_URB',Q2_URB,'CHS_URB',CHS_URB,'CHS2_URB',CHS2_URB endif #endif TS_URB2D(I,J) = TS_URB ALBEDO(I,J) = FRC_URB2D(I,J)*ALB_URB+(1-FRC_URB2D(I,J))*ALBEDOK ![-] HFX(I,J) = FRC_URB2D(I,J)*SH_URB+(1-FRC_URB2D(I,J))*SHEAT ![W/m/m] QFX(I,J) = FRC_URB2D(I,J)*LH_KINEMATIC_URB & + (1-FRC_URB2D(I,J))*ETA_KINEMATIC ![kg/m/m/s] LH(I,J) = FRC_URB2D(I,J)*LH_URB+(1-FRC_URB2D(I,J))*ETA ![W/m/m] GRDFLX(I,J) = FRC_URB2D(I,J)*G_URB+(1-FRC_URB2D(I,J))*SSOIL ![W/m/m] TSK(I,J) = FRC_URB2D(I,J)*TS_URB+(1-FRC_URB2D(I,J))*T1 ![K] Q1 = FRC_URB2D(I,J)*QS_URB+(1-FRC_URB2D(I,J))*Q1 ![-] ! Convert QSFC back to mixing ratio QSFC(I,J)= Q1/(1.0-Q1) UST(I,J)= FRC_URB2D(I,J)*UST_URB+(1-FRC_URB2D(I,J))*UST(I,J) ![m/s] #if 0 IF(IPRINT)THEN print*, ' FRC_URB2D', FRC_URB2D, & 'ALB_URB',ALB_URB, 'ALBEDOK',ALBEDOK, & 'ALBEDO(I,J)', ALBEDO(I,J), & 'SH_URB',SH_URB,'SHEAT',SHEAT, 'HFX(I,J)',HFX(I,J), & 'LH_KINEMATIC_URB',LH_KINEMATIC_URB,'ETA_KINEMATIC', & ETA_KINEMATIC, 'QFX(I,J)',QFX(I,J), & 'LH_URB',LH_URB, 'ETA',ETA, 'LH(I,J)',LH(I,J), & 'G_URB',G_URB,'SSOIL',SSOIL,'GRDFLX(I,J)', GRDFLX(I,J),& 'TS_URB',TS_URB,'T1',T1,'TSK(I,J)',TSK(I,J), & 'QS_URB',QS_URB,'Q1',Q1,'QSFC(I,J)',QSFC(I,J) endif #endif ! Renew Urban State Varialbes TR_URB2D(I,J) = TR_URB TB_URB2D(I,J) = TB_URB TG_URB2D(I,J) = TG_URB TC_URB2D(I,J) = TC_URB QC_URB2D(I,J) = QC_URB UC_URB2D(I,J) = UC_URB DO K = 1,num_roof_layers TRL_URB3D(I,K,J) = TRL_URB(K) END DO DO K = 1,num_wall_layers TBL_URB3D(I,K,J) = TBL_URB(K) END DO DO K = 1,num_road_layers TGL_URB3D(I,K,J) = TGL_URB(K) END DO XXXR_URB2D(I,J) = XXXR_URB XXXB_URB2D(I,J) = XXXB_URB XXXG_URB2D(I,J) = XXXG_URB XXXC_URB2D(I,J) = XXXC_URB SH_URB2D(I,J) = SH_URB LH_URB2D(I,J) = LH_URB G_URB2D(I,J) = G_URB RN_URB2D(I,J) = RN_URB PSIM_URB2D(I,J) = PSIM_URB PSIH_URB2D(I,J) = PSIH_URB GZ1OZ0_URB2D(I,J)= GZ1OZ0_URB U10_URB2D(I,J) = U10_URB V10_URB2D(I,J) = V10_URB TH2_URB2D(I,J) = TH2_URB Q2_URB2D(I,J) = Q2_URB UST_URB2D(I,J) = UST_URB AKMS_URB2D(I,J) = KARMAN * UST_URB2D(I,J)/(GZ1OZ0_URB2D(I,J)-PSIM_URB2D(I,J)) IF (PRESENT(CMR_SFCDIF)) THEN CMR_SFCDIF(I,J) = CMR_URB CHR_SFCDIF(I,J) = CHR_URB CMC_SFCDIF(I,J) = CMC_URB CHC_SFCDIF(I,J) = CHC_URB ENDIF END IF ENDIF ! end of UCM CALL if block !-------------------------------------- ! Urban Part End - urban !-------------------------------------- !*** DIAGNOSTICS SMSTAV(I,J)=SOILW SMSTOT(I,J)=SOILM*1000. DO NS=1,NSOIL SMCREL(I,NS,J)=SMAV(NS) ENDDO ! Convert the water unit into mm SFCRUNOFF(I,J)=SFCRUNOFF(I,J)+RUNOFF1*DT*1000.0 UDRUNOFF(I,J)=UDRUNOFF(I,J)+RUNOFF2*DT*1000.0 ! snow defined when fraction of frozen precip (FFROZP) > 0.5, IF(FFROZP.GT.0.5)THEN ACSNOW(I,J)=ACSNOW(I,J)+PRCP*DT ENDIF IF(SNOW(I,J).GT.0.)THEN ACSNOM(I,J)=ACSNOM(I,J)+SNOMLT*1000. ! accumulated snow-melt energy SNOPCX(I,J)=SNOPCX(I,J)-SNOMLT/FDTLIW ENDIF ENDIF ! endif of land-sea test 100 CONTINUE ! of I loop ENDDO ! of J loop IF (SF_URBAN_PHYSICS == 2) THEN do j=jts,jte do i=its,ite EMISS_URB(i,j)=0. RL_UP_URB(i,j)=0. RS_ABS_URB(i,j)=0. GRDFLX_URB(i,j)=0. b_q_bep(i,kts:kte,j)=0. end do end do CALL BEP(frc_urb2d,utype_urb2d,itimestep,dz8w,dt,u_phy,v_phy, & th_phy,rho,p_phy,swdown,glw, & gmt,julday,xlong,xlat,declin_urb,cosz_urb2d,omg_urb2d, & num_urban_layers, & trb_urb4d,tw1_urb4d,tw2_urb4d,tgb_urb4d, & sfw1_urb3d,sfw2_urb3d,sfr_urb3d,sfg_urb3d, & a_u_bep,a_v_bep,a_t_bep, & a_e_bep,b_u_bep,b_v_bep, & b_t_bep,b_e_bep,dlg_bep, & dl_u_bep,sf_bep,vl_bep, & rl_up_urb,rs_abs_urb,emiss_urb,grdflx_urb, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) ENDIF IF (SF_URBAN_PHYSICS == 3) THEN do j=jts,jte do i=its,ite EMISS_URB(i,j)=0. RL_UP_URB(i,j)=0. RS_ABS_URB(i,j)=0. GRDFLX_URB(i,j)=0. b_q_bep(i,kts:kte,j)=0. end do end do CALL BEP_BEM(frc_urb2d,utype_urb2d,itimestep,dz8w,dt,u_phy,v_phy, & th_phy,rho,p_phy,swdown,glw, & gmt,julday,xlong,xlat,declin_urb,cosz_urb2d,omg_urb2d, & num_urban_layers, & trb_urb4d,tw1_urb4d,tw2_urb4d,tgb_urb4d, & tlev_urb3d,qlev_urb3d,tw1lev_urb3d,tw2lev_urb3d, & tglev_urb3d,tflev_urb3d,sf_ac_urb3d,lf_ac_urb3d, & cm_ac_urb3d,sfvent_urb3d,lfvent_urb3d, & sfwin1_urb3d,sfwin2_urb3d, & sfw1_urb3d,sfw2_urb3d,sfr_urb3d,sfg_urb3d, & a_u_bep,a_v_bep,a_t_bep, & a_e_bep,b_u_bep,b_v_bep, & b_t_bep,b_e_bep,b_q_bep,dlg_bep, & dl_u_bep,sf_bep,vl_bep, & rl_up_urb,rs_abs_urb,emiss_urb,grdflx_urb,qv3d, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) ENDIF if((sf_urban_physics.eq.2).OR.(sf_urban_physics.eq.3))then !Bep begin ! fix the value of the Stefan-Boltzmann constant sigma_sb=5.67e-08 do j=jts,jte do i=its,ite UMOM_URB(I,J)=0. VMOM_URB(I,J)=0. HFX_URB(I,J)=0. QFX_URB(I,J)=0. do k=kts,kte a_u_bep(i,k,j)=a_u_bep(i,k,j)*frc_urb2d(i,j) a_v_bep(i,k,j)=a_v_bep(i,k,j)*frc_urb2d(i,j) a_t_bep(i,k,j)=a_t_bep(i,k,j)*frc_urb2d(i,j) a_q_bep(i,k,j)=0. a_e_bep(i,k,j)=0. b_u_bep(i,k,j)=b_u_bep(i,k,j)*frc_urb2d(i,j) b_v_bep(i,k,j)=b_v_bep(i,k,j)*frc_urb2d(i,j) b_t_bep(i,k,j)=b_t_bep(i,k,j)*frc_urb2d(i,j) b_q_bep(i,k,j)=b_q_bep(i,k,j)*frc_urb2d(i,j) b_e_bep(i,k,j)=b_e_bep(i,k,j)*frc_urb2d(i,j) HFX_URB(I,J)=HFX_URB(I,J)+B_T_BEP(I,K,J)*RHO(I,K,J)*CP* & DZ8W(I,K,J)*VL_BEP(I,K,J) QFX_URB(I,J)=QFX_URB(I,J)+B_Q_BEP(I,K,J)* & DZ8W(I,K,J)*VL_BEP(I,K,J) UMOM_URB(I,J)=UMOM_URB(I,J)+ (A_U_BEP(I,K,J)*U_PHY(I,K,J)+ & B_U_BEP(I,K,J))*DZ8W(I,K,J)*VL_BEP(I,K,J) VMOM_URB(I,J)=VMOM_URB(I,J)+ (A_V_BEP(I,K,J)*V_PHY(I,K,J)+ & B_V_BEP(I,K,J))*DZ8W(I,K,J)*VL_BEP(I,K,J) vl_bep(i,k,j)=(1.-frc_urb2d(i,j))+vl_bep(i,k,j)*frc_urb2d(i,j) sf_bep(i,k,j)=(1.-frc_urb2d(i,j))+sf_bep(i,k,j)*frc_urb2d(i,j) end do a_u_bep(i,1,j)=(1.-frc_urb2d(i,j))*(-ust(I,J)*ust(I,J))/dz8w(i,1,j)/ & ((u_phy(i,1,j)**2+v_phy(i,1,j)**2.)**.5)+a_u_bep(i,1,j) a_v_bep(i,1,j)=(1.-frc_urb2d(i,j))*(-ust(I,J)*ust(I,J))/dz8w(i,1,j)/ & ((u_phy(i,1,j)**2+v_phy(i,1,j)**2.)**.5)+a_v_bep(i,1,j) b_t_bep(i,1,j)=(1.-frc_urb2d(i,j))*hfx_rural(i,j)/dz8w(i,1,j)/rho(i,1,j)/CP+ & b_t_bep(i,1,j) b_q_bep(i,1,j)=(1.-frc_urb2d(i,j))*qfx_rural(i,j)/dz8w(i,1,j)/rho(i,1,j)+b_q_bep(i,1,j) umom=(1.-frc_urb2d(i,j))*ust(i,j)*ust(i,j)*u_phy(i,1,j)/ & ((u_phy(i,1,j)**2+v_phy(i,1,j)**2.)**.5)+umom_urb(i,j) vmom=(1.-frc_urb2d(i,j))*ust(i,j)*ust(i,j)*v_phy(i,1,j)/ & ((u_phy(i,1,j)**2+v_phy(i,1,j)**2.)**.5)+vmom_urb(i,j) sf_bep(i,1,j)=1. ! compute upward longwave radiation from the rural part and total ! rl_up_rural=-emiss_rural(i,j)*sigma_sb*(tsk_rural(i,j)**4.)-(1.-emiss_rural(i,j))*glw(i,j) ! rl_up_tot=(1.-frc_urb2d(i,j))*rl_up_rural+frc_urb2d(i,j)*rl_up_urb(i,j) ! emiss(i,j)=(1.-frc_urb2d(i,j))*emiss_rural(i,j)+frc_urb2d(i,j)*emiss_urb(i,j) ! using the emissivity and the total longwave upward radiation estimate the averaged skin temperature IF (FRC_URB2D(I,J).GT.0.) THEN rl_up_rural=-emiss_rural(i,j)*sigma_sb*(tsk_rural(i,j)**4.)-(1.-emiss_rural(i,j))*glw(i,j) rl_up_tot=(1.-frc_urb2d(i,j))*rl_up_rural+frc_urb2d(i,j)*rl_up_urb(i,j) emiss(i,j)=(1.-frc_urb2d(i,j))*emiss_rural(i,j)+frc_urb2d(i,j)*emiss_urb(i,j) ts_urb2d(i,j)=(max(0.,(-rl_up_urb(i,j)-(1.-emiss_urb(i,j))*glw(i,j))/emiss_urb(i,j)/sigma_sb))**0.25 tsk(i,j)=(max(0., (-1.*rl_up_tot-(1.-emiss(i,j))*glw(i,j) )/emiss(i,j)/sigma_sb))**.25 rs_abs_tot=(1.-frc_urb2d(i,j))*swdown(i,j)*(1.-albedo(i,j))+frc_urb2d(i,j)*rs_abs_urb(i,j) if(swdown(i,j).gt.0.)then albedo(i,j)=1.-rs_abs_tot/swdown(i,j) else albedo(i,j)=alb_rural(i,j) endif ! rename *_urb to sh_urb2d,lh_urb2d,g_urb2d,rn_urb2d grdflx(i,j)= (1.-frc_urb2d(i,j))*grdflx_rural(i,j)+frc_urb2d(i,j)*grdflx_urb(i,j) qfx(i,j)=(1.-frc_urb2d(i,j))*qfx_rural(i,j)+qfx_urb(i,j) ! lh(i,j)=(1.-frc_urb2d(i,j))*qfx_rural(i,j)*xlv lh(i,j)=qfx(i,j)*xlv HFX(I,J) = HFX_URB(I,J)+(1-FRC_URB2D(I,J))*HFX_RURAL(I,J) ![W/m/m] SH_URB2D(I,J) = HFX_URB(I,J)/FRC_URB2D(I,J) LH_URB2D(I,J) = qfx_urb(i,j)*xlv G_URB2D(I,J) = grdflx_urb(i,j) RN_URB2D(I,J) = rs_abs_urb(i,j)+emiss_urb(i,j)*glw(i,j)-rl_up_urb(i,j) ust(i,j)=(umom**2.+vmom**2.)**.25 ! if(tsk(i,j).gt.350)write(*,*)'tsk too big!',i,j,tsk(i,j) ! if(tsk(i,j).lt.260)write(*,*)'tsk too small!',i,j,tsk(i,j),rl_up_tot,rl_up_urb(i,j),rl_up_rural ! print*,'ivgtyp,i,j,sigma_sb',ivgtyp(i,j),i,j,sigma_sb ! print*,'hfx,lh,qfx,grdflx,ts_urb2d',hfx(i,j),lh(i,j),qfx(i,j),grdflx(i,j),ts_urb2d(i,j) ! print*,'tsk,albedo,emiss',tsk(i,j),albedo(i,j),emiss(i,j) ! if(i.eq.56.and.j.eq.29)then ! print*,'ivgtyp, qfx, hfx',ivgtyp(i,j),hfx_rural(i,j),qfx_rural(i,j) ! print*,'emiss_rural,emiss_urb',emiss_rural(i,j),emiss_urb(i,j) ! print*,'rl_up_rural,rl_up_urb(i,j)',rl_up_rural,rl_up_urb(i,j) ! print*,'tsk_rural,ts_urb2d(i,j),tsk',tsk_rural(i,j),ts_urb2d(i,j),tsk(i,j) ! print*,'reconstruction fei',((emiss(i,j)*tsk(i,j)**4.-frc_urb2d(i,j)*emiss_urb(i,j)*ts_urb2d(i,j)**4.)/(emiss_rural(i,j)*(1.-frc_urb2d(i,j))))**.25 ! print*,'ivgtyp,hfx,hfx_urb,hfx_rural',hfx(i,j),hfx_urb(i,j),hfx_rural(i,j) ! print*,'lh,lh_rural',lh(i,j),lh_rural(i,j) ! print*,'qfx',qfx(i,j) ! print*,'ts_urb2d',ts_urb2d(i,j) ! print*,'ust',ust(i,j) ! print*,'swdown,glw',swdown(i,j),glw(i,j) ! endif else SH_URB2D(I,J) = 0. LH_URB2D(I,J) = 0. G_URB2D(I,J) = 0. RN_URB2D(I,J) = 0. endif ! IF( IVGTYP(I,J) == 1 .or. IVGTYP(I,J) == 31 .or. & ! IVGTYP(I,J) == 32 .or. IVGTYP(I,J) == 33) THEN ! print*,'ivgtyp, qfx, hfx',ivgtyp(i,j),hfx_rural(i,j),qfx_rural(i,j) ! print*,'ivgtyp,hfx,hfx_urb,hfx_rural',hfx(i,j),hfx_urb(i,j),hfx_rural(i,j) ! print*,'lh,lh_rural',lh(i,j),lh_rural(i,j) ! print*,'qfx',qfx(i,j) ! print*,'ts_urb2d',ts_urb2d(i,j) ! print*,'ust',ust(i,j) ! endif enddo enddo endif !Bep end !------------------------------------------------------ END SUBROUTINE lsm !------------------------------------------------------ SUBROUTINE LSMINIT(VEGFRA,SNOW,SNOWC,SNOWH,CANWAT,SMSTAV, & SMSTOT, SFCRUNOFF,UDRUNOFF,ACSNOW, & ACSNOM,IVGTYP,ISLTYP,TSLB,SMOIS,SH2O,ZS,DZS, & MMINLU, & SNOALB, FNDSOILW, FNDSNOWH, RDMAXALB, & num_soil_layers, restart, & allowed_to_read , & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) INTEGER, INTENT(IN ) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte INTEGER, INTENT(IN) :: num_soil_layers LOGICAL , INTENT(IN) :: restart , allowed_to_read REAL, DIMENSION( num_soil_layers), INTENT(INOUT) :: ZS, DZS REAL, DIMENSION( ims:ime, num_soil_layers, jms:jme ) , & INTENT(INOUT) :: SMOIS, & !Total soil moisture SH2O, & !liquid soil moisture TSLB !STEMP REAL, DIMENSION( ims:ime, jms:jme ) , & INTENT(INOUT) :: SNOW, & SNOWH, & SNOWC, & SNOALB, & CANWAT, & SMSTAV, & SMSTOT, & SFCRUNOFF, & UDRUNOFF, & ACSNOW, & VEGFRA, & ACSNOM INTEGER, DIMENSION( ims:ime, jms:jme ) , & INTENT(IN) :: IVGTYP, & ISLTYP CHARACTER(LEN=*), INTENT(IN) :: MMINLU LOGICAL, INTENT(IN) :: FNDSOILW , & FNDSNOWH LOGICAL, INTENT(IN) :: RDMAXALB INTEGER :: L REAL :: BX, SMCMAX, PSISAT, FREE REAL, PARAMETER :: BLIM = 5.5, HLICE = 3.335E5, & GRAV = 9.81, T0 = 273.15 INTEGER :: errflag character*256 :: MMINSL MMINSL='STAS' ! ! initialize three Noah LSM related tables IF ( allowed_to_read ) THEN CALL wrf_message( 'INITIALIZE THREE Noah LSM RELATED TABLES' ) CALL SOIL_VEG_GEN_PARM( MMINLU, MMINSL ) ENDIF #ifdef WRF_CHEM ! ! need this parameter for dust parameterization in wrf/chem ! do I=1,NSLTYPE porosity(i)=maxsmc(i) enddo #endif IF(.not.restart)THEN itf=min0(ite,ide-1) jtf=min0(jte,jde-1) errflag = 0 DO j = jts,jtf DO i = its,itf IF ( ISLTYP( i,j ) .LT. 1 ) THEN errflag = 1 WRITE(err_message,*)"module_sf_noahlsm.F: lsminit: out of range ISLTYP ",i,j,ISLTYP( i,j ) CALL wrf_message(err_message) ENDIF IF(.not.RDMAXALB) THEN SNOALB(i,j)=MAXALB(IVGTYP(i,j))*0.01 ENDIF ENDDO ENDDO IF ( errflag .EQ. 1 ) THEN CALL wrf_error_fatal( "module_sf_noahlsm.F: lsminit: out of range value "// & "of ISLTYP. Is this field in the input?" ) ENDIF ! initialize soil liquid water content SH2O ! IF(.NOT.FNDSOILW) THEN ! If no SWC, do the following ! PRINT *,'SOIL WATER NOT FOUND - VALUE SET IN LSMINIT' DO J = jts,jtf DO I = its,itf BX = BB(ISLTYP(I,J)) SMCMAX = MAXSMC(ISLTYP(I,J)) PSISAT = SATPSI(ISLTYP(I,J)) if ((bx > 0.0).and.(smcmax > 0.0).and.(psisat > 0.0)) then DO NS=1, num_soil_layers ! ---------------------------------------------------------------------- !SH2O <= SMOIS for T < 273.149K (-0.001C) IF (TSLB(I,NS,J) < 273.149) THEN ! ---------------------------------------------------------------------- ! first guess following explicit solution for Flerchinger Eqn from Koren ! et al, JGR, 1999, Eqn 17 (KCOUNT=0 in FUNCTION FRH2O). ! ISLTPK is soil type BX = BB(ISLTYP(I,J)) SMCMAX = MAXSMC(ISLTYP(I,J)) PSISAT = SATPSI(ISLTYP(I,J)) IF ( BX > BLIM ) BX = BLIM FK=(( (HLICE/(GRAV*(-PSISAT))) * & ((TSLB(I,NS,J)-T0)/TSLB(I,NS,J)) )**(-1/BX) )*SMCMAX IF (FK < 0.02) FK = 0.02 SH2O(I,NS,J) = MIN( FK, SMOIS(I,NS,J) ) ! ---------------------------------------------------------------------- ! now use iterative solution for liquid soil water content using ! FUNCTION FRH2O with the initial guess for SH2O from above explicit ! first guess. CALL FRH2O (FREE,TSLB(I,NS,J),SMOIS(I,NS,J),SH2O(I,NS,J), & SMCMAX,BX,PSISAT) SH2O(I,NS,J) = FREE ELSE ! of IF (TSLB(I,NS,J) ! ---------------------------------------------------------------------- ! SH2O = SMOIS ( for T => 273.149K (-0.001C) SH2O(I,NS,J)=SMOIS(I,NS,J) ! ---------------------------------------------------------------------- ENDIF ! of IF (TSLB(I,NS,J) END DO ! of DO NS=1, num_soil_layers else ! of if ((bx > 0.0) DO NS=1, num_soil_layers SH2O(I,NS,J)=SMOIS(I,NS,J) END DO endif ! of if ((bx > 0.0) ENDDO ! DO I = its,itf ENDDO ! DO J = jts,jtf ! ENDIF ! of IF(.NOT.FNDSOILW)THEN ! initialize physical snow height SNOWH IF(.NOT.FNDSNOWH)THEN ! If no SNOWH do the following CALL wrf_message( 'SNOW HEIGHT NOT FOUND - VALUE DEFINED IN LSMINIT' ) DO J = jts,jtf DO I = its,itf SNOWH(I,J)=SNOW(I,J)*0.005 ! SNOW in mm and SNOWH in m ENDDO ENDDO ENDIF ! initialize canopy water to ZERO ! GO TO 110 ! print*,'Note that canopy water content (CANWAT) is set to ZERO in LSMINIT' DO J = jts,jtf DO I = its,itf CANWAT(I,J)=0.0 ENDDO ENDDO 110 CONTINUE ENDIF !------------------------------------------------------------------------------ END SUBROUTINE lsminit !------------------------------------------------------------------------------ !----------------------------------------------------------------- SUBROUTINE SOIL_VEG_GEN_PARM( MMINLU, MMINSL) !----------------------------------------------------------------- USE module_wrf_error IMPLICIT NONE CHARACTER(LEN=*), INTENT(IN) :: MMINLU, MMINSL integer :: LUMATCH, IINDEX, LC, NUM_SLOPE integer :: ierr INTEGER , PARAMETER :: OPEN_OK = 0 character*128 :: mess , message logical, external :: wrf_dm_on_monitor !-----SPECIFY VEGETATION RELATED CHARACTERISTICS : ! ALBBCK: SFC albedo (in percentage) ! Z0: Roughness length (m) ! SHDFAC: Green vegetation fraction (in percentage) ! Note: The ALBEDO, Z0, and SHDFAC values read from the following table ! ALBEDO, amd Z0 are specified in LAND-USE TABLE; and SHDFAC is ! the monthly green vegetation data ! CMXTBL: MAX CNPY Capacity (m) ! NROTBL: Rooting depth (layer) ! RSMIN: Mimimum stomatal resistance (s m-1) ! RSMAX: Max. stomatal resistance (s m-1) ! RGL: Parameters used in radiation stress function ! HS: Parameter used in vapor pressure deficit functio ! TOPT: Optimum transpiration air temperature. (K) ! CMCMAX: Maximum canopy water capacity ! CFACTR: Parameter used in the canopy inteception calculati ! SNUP: Threshold snow depth (in water equivalent m) that ! implies 100% snow cover ! LAI: Leaf area index (dimensionless) ! MAXALB: Upper bound on maximum albedo over deep snow ! !-----READ IN VEGETAION PROPERTIES FROM VEGPARM.TBL ! IF ( wrf_dm_on_monitor() ) THEN OPEN(19, FILE='VEGPARM.TBL',FORM='FORMATTED',STATUS='OLD',IOSTAT=ierr) IF(ierr .NE. OPEN_OK ) THEN WRITE(message,FMT='(A)') & 'module_sf_noahlsm.F: soil_veg_gen_parm: failure opening VEGPARM.TBL' CALL wrf_error_fatal ( message ) END IF LUMATCH=0 FIND_LUTYPE : DO WHILE (LUMATCH == 0) READ (19,*,END=2002) READ (19,*,END=2002)LUTYPE READ (19,*)LUCATS,IINDEX IF(LUTYPE.EQ.MMINLU)THEN WRITE( mess , * ) 'LANDUSE TYPE = ' // TRIM ( LUTYPE ) // ' FOUND', LUCATS,' CATEGORIES' CALL wrf_message( mess ) LUMATCH=1 ELSE call wrf_message ( "Skipping over LUTYPE = " // TRIM ( LUTYPE ) ) DO LC = 1, LUCATS+12 read(19,*) ENDDO ENDIF ENDDO FIND_LUTYPE ! prevent possible array overwrite, Bill Bovermann, IBM, May 6, 2008 IF ( SIZE(SHDTBL) < LUCATS .OR. & SIZE(NROTBL) < LUCATS .OR. & SIZE(RSTBL) < LUCATS .OR. & SIZE(RGLTBL) < LUCATS .OR. & SIZE(HSTBL) < LUCATS .OR. & SIZE(SNUPTBL) < LUCATS .OR. & SIZE(MAXALB) < LUCATS .OR. & SIZE(LAIMINTBL) < LUCATS .OR. & SIZE(LAIMAXTBL) < LUCATS .OR. & SIZE(Z0MINTBL) < LUCATS .OR. & SIZE(Z0MAXTBL) < LUCATS .OR. & SIZE(ALBEDOMINTBL) < LUCATS .OR. & SIZE(ALBEDOMAXTBL) < LUCATS .OR. & SIZE(EMISSMINTBL ) < LUCATS .OR. & SIZE(EMISSMAXTBL ) < LUCATS ) THEN CALL wrf_error_fatal('Table sizes too small for value of LUCATS in module_sf_noahdrv.F') ENDIF IF(LUTYPE.EQ.MMINLU)THEN DO LC=1,LUCATS READ (19,*)IINDEX,SHDTBL(LC), & NROTBL(LC),RSTBL(LC),RGLTBL(LC),HSTBL(LC), & SNUPTBL(LC),MAXALB(LC), LAIMINTBL(LC), & LAIMAXTBL(LC),EMISSMINTBL(LC), & EMISSMAXTBL(LC), ALBEDOMINTBL(LC), & ALBEDOMAXTBL(LC), Z0MINTBL(LC), Z0MAXTBL(LC) ENDDO ! READ (19,*) READ (19,*)TOPT_DATA READ (19,*) READ (19,*)CMCMAX_DATA READ (19,*) READ (19,*)CFACTR_DATA READ (19,*) READ (19,*)RSMAX_DATA READ (19,*) READ (19,*)BARE READ (19,*) READ (19,*)NATURAL ENDIF ! 2002 CONTINUE CLOSE (19) IF (LUMATCH == 0) then CALL wrf_error_fatal ("Land Use Dataset '"//MMINLU//"' not found in VEGPARM.TBL.") ENDIF ENDIF CALL wrf_dm_bcast_string ( LUTYPE , 4 ) CALL wrf_dm_bcast_integer ( LUCATS , 1 ) CALL wrf_dm_bcast_integer ( IINDEX , 1 ) CALL wrf_dm_bcast_integer ( LUMATCH , 1 ) CALL wrf_dm_bcast_real ( SHDTBL , NLUS ) CALL wrf_dm_bcast_real ( NROTBL , NLUS ) CALL wrf_dm_bcast_real ( RSTBL , NLUS ) CALL wrf_dm_bcast_real ( RGLTBL , NLUS ) CALL wrf_dm_bcast_real ( HSTBL , NLUS ) CALL wrf_dm_bcast_real ( SNUPTBL , NLUS ) CALL wrf_dm_bcast_real ( LAIMINTBL , NLUS ) CALL wrf_dm_bcast_real ( LAIMAXTBL , NLUS ) CALL wrf_dm_bcast_real ( Z0MINTBL , NLUS ) CALL wrf_dm_bcast_real ( Z0MAXTBL , NLUS ) CALL wrf_dm_bcast_real ( EMISSMINTBL , NLUS ) CALL wrf_dm_bcast_real ( EMISSMAXTBL , NLUS ) CALL wrf_dm_bcast_real ( ALBEDOMINTBL , NLUS ) CALL wrf_dm_bcast_real ( ALBEDOMAXTBL , NLUS ) CALL wrf_dm_bcast_real ( MAXALB , NLUS ) CALL wrf_dm_bcast_real ( TOPT_DATA , 1 ) CALL wrf_dm_bcast_real ( CMCMAX_DATA , 1 ) CALL wrf_dm_bcast_real ( CFACTR_DATA , 1 ) CALL wrf_dm_bcast_real ( RSMAX_DATA , 1 ) CALL wrf_dm_bcast_integer ( BARE , 1 ) CALL wrf_dm_bcast_integer ( NATURAL , 1 ) ! !-----READ IN SOIL PROPERTIES FROM SOILPARM.TBL ! IF ( wrf_dm_on_monitor() ) THEN OPEN(19, FILE='SOILPARM.TBL',FORM='FORMATTED',STATUS='OLD',IOSTAT=ierr) IF(ierr .NE. OPEN_OK ) THEN WRITE(message,FMT='(A)') & 'module_sf_noahlsm.F: soil_veg_gen_parm: failure opening SOILPARM.TBL' CALL wrf_error_fatal ( message ) END IF WRITE(mess,*) 'INPUT SOIL TEXTURE CLASSIFICATION = ', TRIM ( MMINSL ) CALL wrf_message( mess ) LUMATCH=0 READ (19,*) READ (19,2000,END=2003)SLTYPE 2000 FORMAT (A4) READ (19,*)SLCATS,IINDEX IF(SLTYPE.EQ.MMINSL)THEN WRITE( mess , * ) 'SOIL TEXTURE CLASSIFICATION = ', TRIM ( SLTYPE ) , ' FOUND', & SLCATS,' CATEGORIES' CALL wrf_message ( mess ) LUMATCH=1 ENDIF ! prevent possible array overwrite, Bill Bovermann, IBM, May 6, 2008 IF ( SIZE(BB ) < SLCATS .OR. & SIZE(DRYSMC) < SLCATS .OR. & SIZE(F11 ) < SLCATS .OR. & SIZE(MAXSMC) < SLCATS .OR. & SIZE(REFSMC) < SLCATS .OR. & SIZE(SATPSI) < SLCATS .OR. & SIZE(SATDK ) < SLCATS .OR. & SIZE(SATDW ) < SLCATS .OR. & SIZE(WLTSMC) < SLCATS .OR. & SIZE(QTZ ) < SLCATS ) THEN CALL wrf_error_fatal('Table sizes too small for value of SLCATS in module_sf_noahdrv.F') ENDIF IF(SLTYPE.EQ.MMINSL)THEN DO LC=1,SLCATS READ (19,*) IINDEX,BB(LC),DRYSMC(LC),F11(LC),MAXSMC(LC),& REFSMC(LC),SATPSI(LC),SATDK(LC), SATDW(LC), & WLTSMC(LC), QTZ(LC) ENDDO ENDIF 2003 CONTINUE CLOSE (19) ENDIF CALL wrf_dm_bcast_integer ( LUMATCH , 1 ) CALL wrf_dm_bcast_string ( SLTYPE , 4 ) CALL wrf_dm_bcast_string ( MMINSL , 4 ) ! since this is reset above, see oct2 ^ CALL wrf_dm_bcast_integer ( SLCATS , 1 ) CALL wrf_dm_bcast_integer ( IINDEX , 1 ) CALL wrf_dm_bcast_real ( BB , NSLTYPE ) CALL wrf_dm_bcast_real ( DRYSMC , NSLTYPE ) CALL wrf_dm_bcast_real ( F11 , NSLTYPE ) CALL wrf_dm_bcast_real ( MAXSMC , NSLTYPE ) CALL wrf_dm_bcast_real ( REFSMC , NSLTYPE ) CALL wrf_dm_bcast_real ( SATPSI , NSLTYPE ) CALL wrf_dm_bcast_real ( SATDK , NSLTYPE ) CALL wrf_dm_bcast_real ( SATDW , NSLTYPE ) CALL wrf_dm_bcast_real ( WLTSMC , NSLTYPE ) CALL wrf_dm_bcast_real ( QTZ , NSLTYPE ) IF(LUMATCH.EQ.0)THEN CALL wrf_message( 'SOIl TEXTURE IN INPUT FILE DOES NOT ' ) CALL wrf_message( 'MATCH SOILPARM TABLE' ) CALL wrf_error_fatal ( 'INCONSISTENT OR MISSING SOILPARM FILE' ) ENDIF ! !-----READ IN GENERAL PARAMETERS FROM GENPARM.TBL ! IF ( wrf_dm_on_monitor() ) THEN OPEN(19, FILE='GENPARM.TBL',FORM='FORMATTED',STATUS='OLD',IOSTAT=ierr) IF(ierr .NE. OPEN_OK ) THEN WRITE(message,FMT='(A)') & 'module_sf_noahlsm.F: soil_veg_gen_parm: failure opening GENPARM.TBL' CALL wrf_error_fatal ( message ) END IF READ (19,*) READ (19,*) READ (19,*) NUM_SLOPE SLPCATS=NUM_SLOPE ! prevent possible array overwrite, Bill Bovermann, IBM, May 6, 2008 IF ( SIZE(slope_data) < NUM_SLOPE ) THEN CALL wrf_error_fatal('NUM_SLOPE too large for slope_data array in module_sf_noahdrv') ENDIF DO LC=1,SLPCATS READ (19,*)SLOPE_DATA(LC) ENDDO READ (19,*) READ (19,*)SBETA_DATA READ (19,*) READ (19,*)FXEXP_DATA READ (19,*) READ (19,*)CSOIL_DATA READ (19,*) READ (19,*)SALP_DATA READ (19,*) READ (19,*)REFDK_DATA READ (19,*) READ (19,*)REFKDT_DATA READ (19,*) READ (19,*)FRZK_DATA READ (19,*) READ (19,*)ZBOT_DATA READ (19,*) READ (19,*)CZIL_DATA READ (19,*) READ (19,*)SMLOW_DATA READ (19,*) READ (19,*)SMHIGH_DATA READ (19,*) READ (19,*)LVCOEF_DATA CLOSE (19) ENDIF CALL wrf_dm_bcast_integer ( NUM_SLOPE , 1 ) CALL wrf_dm_bcast_integer ( SLPCATS , 1 ) CALL wrf_dm_bcast_real ( SLOPE_DATA , NSLOPE ) CALL wrf_dm_bcast_real ( SBETA_DATA , 1 ) CALL wrf_dm_bcast_real ( FXEXP_DATA , 1 ) CALL wrf_dm_bcast_real ( CSOIL_DATA , 1 ) CALL wrf_dm_bcast_real ( SALP_DATA , 1 ) CALL wrf_dm_bcast_real ( REFDK_DATA , 1 ) CALL wrf_dm_bcast_real ( REFKDT_DATA , 1 ) CALL wrf_dm_bcast_real ( FRZK_DATA , 1 ) CALL wrf_dm_bcast_real ( ZBOT_DATA , 1 ) CALL wrf_dm_bcast_real ( CZIL_DATA , 1 ) CALL wrf_dm_bcast_real ( SMLOW_DATA , 1 ) CALL wrf_dm_bcast_real ( SMHIGH_DATA , 1 ) CALL wrf_dm_bcast_real ( LVCOEF_DATA , 1 ) !----------------------------------------------------------------- END SUBROUTINE SOIL_VEG_GEN_PARM !----------------------------------------------------------------- END MODULE module_sf_noahdrv