MODULE module_sf_noahdrv 2
!-------------------------------
USE module_sf_noahlsm
, only: SFLX, XLF, XLV, CP, R_D, RHOWATER, NATURAL, SHDTBL, LUTYPE, SLTYPE, STBOLT, &
& KARMAN, LUCATS, NROTBL, RSTBL, RGLTBL, HSTBL, SNUPTBL, MAXALB, LAIMINTBL, &
& LAIMAXTBL, Z0MINTBL, Z0MAXTBL, ALBEDOMINTBL, ALBEDOMAXTBL, EMISSMINTBL, &
& EMISSMAXTBL, TOPT_DATA, CMCMAX_DATA, CFACTR_DATA, RSMAX_DATA, BARE, NLUS, &
& SLCATS, BB, DRYSMC, F11, MAXSMC, REFSMC, SATPSI, SATDK, SATDW, WLTSMC, QTZ, &
& NSLTYPE, SLPCATS, SLOPE_DATA, SBETA_DATA, FXEXP_DATA, CSOIL_DATA, &
& SALP_DATA, REFDK_DATA, REFKDT_DATA, FRZK_DATA, ZBOT_DATA, CZIL_DATA, &
& SMLOW_DATA, SMHIGH_DATA, LVCOEF_DATA, NSLOPE, &
& FRH2O,ZTOPVTBL,ZBOTVTBL, &
& LOW_DENSITY_RESIDENTIAL, HIGH_DENSITY_RESIDENTIAL, HIGH_INTENSITY_INDUSTRIAL
USE module_sf_urban, only: urban, oasis, IRI_SCHEME
USE module_sf_noahlsm_glacial_only, only: sflx_glacial
USE module_sf_bep, only: bep
USE module_sf_bep_bem, only: bep_bem
USE module_ra_gfdleta, only: cal_mon_day
#if ( WRF_CHEM == 1 )
USE module_data_gocart_dust
#endif
!-------------------------------
!
CONTAINS
!
!----------------------------------------------------------------
! Urban related variable are added to arguments - urban
!----------------------------------------------------------------
SUBROUTINE lsm(DZ8W,QV3D,P8W3D,T3D,TSK, & 1,9
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,opt_thcnd, &
! Noah UA changes
ua_phys,flx4_2d,fvb_2d,fbur_2d,fgsn_2d, &
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, &
CMGR_SFCDIF,CHGR_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
CMCR_URB2D,TGR_URB2D,TGRL_URB3D,SMR_URB3D, & !H urban
DRELR_URB2D,DRELB_URB2D,DRELG_URB2D, & !H urban
FLXHUMR_URB2D,FLXHUMB_URB2D,FLXHUMG_URB2D, & !H urban
julian, julyr, & !H urban
FRC_URB2D,UTYPE_URB2D, & !O
num_urban_layers, & !I multi-layer urban
num_urban_hi, & !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
lp_urb2d,hi_urb2d,lb_urb2d,hgt_urb2d, & !H multi-layer urban
mh_urb2d,stdh_urb2d,lf_urb2d, & !SLUCM
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,sfcheadrt,INFXSRT, soldrain & !O multi-layer urban
,SDA_HFX, SDA_QFX, HFX_BOTH, QFX_BOTH, QNORM, fasdas & !fasdas
) !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 (m)
!-- 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
INTEGER, INTENT(IN ) :: julian, julyr !urban
!added by Wei Yu for routing
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(INOUT) :: sfcheadrt,INFXSRT,soldrain
real :: etpnd1
!end added
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
INTEGER, INTENT(IN) :: OPT_THCND
! Noah UA changes
LOGICAL, INTENT(IN) :: UA_PHYS
REAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: FLX4_2D,FVB_2D,FBUR_2D,FGSN_2D
REAL :: FLX4,FVB,FBUR,FGSN
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) :: CMGR_SFCDIF
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CHGR_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
!===Yang,2014/10/08,hydrological variable for single layer UCM===
INTEGER :: jmonth, jday, tloc
INTEGER :: IRIOPTION, USOIL, DSOIL
REAL :: AOASIS, OMG
REAL :: DRELR_URB
REAL :: DRELB_URB
REAL :: DRELG_URB
REAL :: FLXHUMR_URB
REAL :: FLXHUMB_URB
REAL :: FLXHUMG_URB
REAL :: CMCR_URB
REAL :: TGR_URB
REAL, DIMENSION(1:num_roof_layers) :: SMR_URB ! green roof layer moisture
REAL, DIMENSION(1:num_roof_layers) :: TGRL_URB ! green roof layer temp [K]
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: DRELR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: DRELB_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: DRELG_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: FLXHUMR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: FLXHUMB_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: FLXHUMG_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CMCR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: TGR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_roof_layers, jms:jme ), INTENT(INOUT) :: TGRL_URB3D
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_roof_layers, jms:jme ), INTENT(INOUT) :: SMR_URB3D
! 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
! NUDAPT Parameters urban --> lam
REAL :: mh_urb
REAL :: stdh_urb
REAL :: lp_urb
REAL :: hgt_urb
REAL, DIMENSION(4) :: lf_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
INTEGER, INTENT(IN ) :: NUM_URBAN_HI
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, 1:num_urban_hi, jms:jme ), INTENT(IN) :: hi_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: lp_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: lb_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: hgt_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: mh_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: stdh_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, 4, jms:jme ), INTENT(IN) :: lf_urb2d
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( its:ite, jts:jte ) :: HFX_RURAL,LH_RURAL,GRDFLX_RURAL ! ,RN_RURAL
REAL, DIMENSION( its:ite, jts:jte ) :: QFX_RURAL ! ,QSFC_RURAL,UMOM_RURAL,VMOM_RURAL
REAL, DIMENSION( its:ite, jts:jte ) :: ALB_RURAL,EMISS_RURAL,TSK_RURAL ! ,UST_RURAL
! REAL, DIMENSION( ims:ime, jms:jme ) :: QSFC_URB
REAL, DIMENSION( its:ite, jts:jte ) :: HFX_URB,UMOM_URB,VMOM_URB
REAL, DIMENSION( its:ite, jts:jte ) :: QFX_URB
! REAL, DIMENSION( ims:ime, jms:jme ) :: ALBEDO_URB,EMISS_URB,UMOM,VMOM,UST
REAL, DIMENSION(its:ite,jts:jte) ::EMISS_URB
REAL, DIMENSION(its:ite,jts:jte) :: RL_UP_URB
REAL, DIMENSION(its:ite,jts:jte) ::RS_ABS_URB
REAL, DIMENSION(its:ite,jts:jte) ::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, CMGR_URB, CHGR_URB
REAL :: frc_urb,lb_urb
REAL :: check
! ----------------------------------------------------------------------
! DECLARATIONS END - urban
! ----------------------------------------------------------------------
REAL, PARAMETER :: CAPA=R_D/CP
REAL :: APELM,APES,SFCTH2,PSFC
real, intent(in) :: xice_threshold
character(len=80) :: message_text
!
! FASDAS
!
REAL, DIMENSION( ims:ime, jms:jme ), OPTIONAL, &
INTENT(INOUT) :: SDA_HFX, SDA_QFX, HFX_BOTH, QFX_BOTH, QNORM
INTEGER, INTENT(IN ) :: fasdas
! local vars
REAL :: XSDA_HFX, XSDA_QFX, XQNORM
REAL :: HFX_PHY, QFX_PHY
REAL :: DZQ
REAL :: HCPCT_FASDAS
HFX_PHY = 0.0 ! initialize
QFX_PHY = 0.0
XQNORM = 0.0
XSDA_HFX = 0.0
XSDA_QFX = 0.0
!
! END FASDAS
!
FLX4 = 0.0 !BSINGH - Initialized to 0.0
FVB = 0.0 !BSINGH - Initialized to 0.0
FBUR = 0.0 !BSINGH - Initialized to 0.0
FGSN = 0.0 !BSINGH - Initialized to 0.0
SOILW = 0.0 !BSINGH - Initialized to 0.0
! 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
JLOOP : 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
!-----------------------------------------------------------------------
ILOOP : DO 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
! V3.8 add condition for SWDOWN to restrict condition to positive forcing (JD)
IF(T1 .GT. 273. .AND. SNOWC(I,J) .GT. 0. .AND. SWDOWN(I,J) .GT. 10.)DQSDT2=DQSDT2*(1.-SNOWC(I,J))
ENDIF
! Land-ice or land points use the usual deep-soil temperature.
TBOT=TMN(I,J)
IF(ISURBAN.EQ.1) THEN
! assumes these only need to be set for USGS land data
IF(VEGTYP.EQ.25) SHDFAC=0.0000
IF(VEGTYP.EQ.26) SHDFAC=0.0000
IF(VEGTYP.EQ.27) SHDFAC=0.0000
ENDIF
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 NS=1,NSOIL
SMC(NS)=SMOIS(I,NS,J)
STC(NS)=TSLB(I,NS,J) !STEMP
SWC(NS)=SH2O(I,NS,J)
ENDDO
!
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) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) 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) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
VEGTYP = ISURBAN
ENDIF
ENDIF
!===Yang, 2014/10/08, hydrological processes for urban vegetation in single layer UCM===
AOASIS = 1.0
USOIL = 1
DSOIL = 2
IRIOPTION=IRI_SCHEME
IF(SF_URBAN_PHYSICS == 1) THEN
OMG= OMG_URB2D(I,J)
tloc=mod(int(OMG/3.14159*180./15.+12.+0.5 ),24)
if (tloc.lt.0) tloc=tloc+24
if (tloc==0) tloc=24
CALL cal_mon_day(julian,julyr,jmonth,jday)
IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
AOASIS = oasis ! urban oasis effect
IF (IRIOPTION ==1) THEN
IF (tloc==21 .or. tloc==22) THEN !irrigation on vegetaion in urban area, MAY-SEP, 9-10pm
IF (jmonth==5 .or. jmonth==6 .or. jmonth==7 .or. jmonth==8 .or. jmonth==9) THEN
! IF (SMC(USOIL) .LT. SMCREF) SMC(USOIL)= SMCREF
! IF (SMC(DSOIL) .LT. SMCREF) SMC(DSOIL)= SMCREF
IF (SMC(USOIL) .LT. SMCREF) SMC(USOIL)= REFSMC(ISLTYP(I,J))
IF (SMC(DSOIL) .LT. SMCREF) SMC(DSOIL)= REFSMC(ISLTYP(I,J))
ENDIF
ENDIF
ENDIF
ENDIF
ENDIF
IF(SF_URBAN_PHYSICS == 2 .or. SF_URBAN_PHYSICS == 3) THEN
IF(AOASIS > 1.0) THEN
CALL wrf_error_fatal('Urban oasis option is for SF_URBAN_PHYSICS == 1 only')
ENDIF
IF(IRIOPTION == 1) THEN
CALL wrf_error_fatal('Urban irrigation option is for SF_URBAN_PHYSICS == 1 only')
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
IF ( ICE == 1 ) THEN
! Sea-ice case
DO NS = 1, NSOIL
SH2O(I,NS,J) = 1.0
ENDDO
LAI(I,J) = 0.01
CYCLE ILOOP
ELSEIF (ICE == 0) THEN
! Non-glacial land
!
! FASDAS
!
IF( fasdas == 1 ) THEN
DZQ = DZ8W(I,1,J)
XSDA_HFX= SDA_HFX(I,J)*RHO(I,1,J)*CPM(I,J)*DZQ ! W/m^2
! TWG2015 Bugfix remove factor of 1000.0 for correct units
XSDA_QFX= SDA_QFX(I,J)*RHO(I,1,J)*DZQ ! Kg/m2/s of water
XQNORM = QNORM(I,J)
ENDIF
!
! END FASDAS
!
CALL SFLX (I,J,FFROZP, 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
FLX4,FVB,FBUR,FGSN,UA_PHYS, & !UA
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, &
sfcheadrt(i,j), & !I
INFXSRT(i,j),ETPND1,OPT_THCND,AOASIS & !O
,XSDA_QFX, HFX_PHY, QFX_PHY, XQNORM, fasdas, HCPCT_FASDAS & ! fasdas
)
#ifdef WRF_HYDRO
soldrain(i,j) = RUNOFF2*DT*1000.0
#endif
ELSEIF (ICE == -1) THEN
!
! Set values that the LSM is expected to update,
! but don't get updated for glacial points.
!
SOILM = 0.0 !BSINGH(PNNL)- SOILM is undefined for this case, it is used for diagnostics so setting it to zero
XLAI = 0.01 ! KWM Should this be Zero over land ice? Does this value matter?
RUNOFF2 = 0.0
RUNOFF3 = 0.0
DO NS = 1, NSOIL
SWC(NS) = 1.0
SMC(NS) = 1.0
SMAV(NS) = 1.0
ENDDO
!
! FASDAS
!
IF( fasdas == 1 ) THEN
DZQ = DZ8W(I,1,J)
XSDA_HFX= SDA_HFX(I,J)*RHO(I,1,J)*CPM(I,J)*DZQ ! W/m^2
XSDA_QFX= 0.0 ! Kg/m2/s of water
XQNORM = 0.0
ENDIF
!
! END FASDAS
!
CALL SFLX_GLACIAL(I,J,ISICE,FFROZP,DT,ZLVL,NSOIL,SLDPTH, & !C
& LWDN,SOLNET,SFCPRS,PRCP,SFCTMP,Q2K, & !F
& TH2,Q2SAT,DQSDT2, & !I
& ALBBRD, SNOALB1,TBOT, Z0BRD, Z0K, EMISSI, EMBRD, & !S
& T1,STC(1:NSOIL),SNOWHK,SNEQV,ALBEDOK,CHK, & !H
& ETA,SHEAT,ETA_KINEMATIC,FDOWN, & !O
& ESNOW,DEW, & !O
& ETP,SSOIL, & !O
& FLX1,FLX2,FLX3, & !O
& SNOMLT,SNCOVR, & !O
& RUNOFF1, & !O
& Q1, & !D
& SNOTIME1, &
& RIBB)
ENDIF
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
!
! FASDAS
!
! Update Skin Temperature
IF( fasdas == 1 ) THEN
XSDA_QFX= XSDA_QFX*ELWV*XQNORM
!TWG2015 Bugfix to multiply Heat Capacity by Soil Depth for correct
!units
T1 = T1 + (XSDA_HFX-XSDA_QFX)*DT/(HCPCT_FASDAS*DZS(1))
END IF
!
! END FASDAS
!
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
#ifdef WRF_HYDRO
!added by Wei Yu
! QFX(I,J) = QFX(I,J) + ETPND1
! ETA = ETA + ETPND1/2.501E6*dt
!end added by Wei Yu
#endif
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)
! ww: comment out this change to avoid Q2 drop due to change of radiative flux
! 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
FLX4_2D(I,J) = FLX4
FVB_2D(I,J) = FVB
FBUR_2D(I,J) = FBUR
FGSN_2D(I,J) = FGSN
!
! Residual of surface energy balance equation terms
!
IF ( UA_PHYS ) THEN
noahres(i,j) = ( solnet + lwdn ) - sheat + ssoil - eta &
- ( emissi * STBOLT * (t1**4) ) - flx1 - flx2 - flx3 - flx4
ELSE
noahres(i,j) = ( solnet + lwdn ) - sheat + ssoil - eta &
- ( emissi * STBOLT * (t1**4) ) - flx1 - flx2 - flx3
ENDIF
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) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL ) 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)
TGR_URB = TGR_URB2D(I,J)
CMCR_URB = CMCR_URB2D(I,J)
FLXHUMR_URB = FLXHUMR_URB2D(I,J)
FLXHUMB_URB = FLXHUMB_URB2D(I,J)
FLXHUMG_URB = FLXHUMG_URB2D(I,J)
DRELR_URB = DRELR_URB2D(I,J)
DRELB_URB = DRELB_URB2D(I,J)
DRELG_URB = DRELG_URB2D(I,J)
DO K = 1,num_roof_layers
TRL_URB(K) = TRL_URB3D(I,K,J)
SMR_URB(K) = SMR_URB3D(I,K,J)
TGRL_URB(K)= TGRL_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)
CMGR_URB = CMGR_SFCDIF(I,J)
CHGR_URB = CHGR_SFCDIF(I,J)
CMC_URB = CMC_SFCDIF(I,J)
CHC_URB = CHC_SFCDIF(I,J)
ENDIF
! NUDAPT for SLUCM
mh_urb = mh_urb2d(I,J)
stdh_urb = stdh_urb2d(I,J)
lp_urb = lp_urb2d(I,J)
hgt_urb = hgt_urb2d(I,J)
lf_urb = 0.0
DO K = 1,4
lf_urb(K)=lf_urb2d(I,K,J)
ENDDO
frc_urb = frc_urb2d(I,J)
lb_urb = lb_urb2d(I,J)
check = 0
if (I.eq.73.and.J.eq.125)THEN
check = 1
end if
!
! Call urban
CALL cal_mon_day(julian,julyr,jmonth,jday)
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,mh_urb, stdh_urb, lf_urb, lp_urb, & ! 0
hgt_urb,frc_urb,lb_urb, check,CMCR_URB,TGR_URB, & ! H
TGRL_URB,SMR_URB,CMGR_URB,CHGR_URB,jmonth, & ! H
DRELR_URB,DRELB_URB, & ! H
DRELG_URB,FLXHUMR_URB,FLXHUMB_URB,FLXHUMG_URB)
#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
TGR_URB2D(I,J) =TGR_URB
CMCR_URB2D(I,J)=CMCR_URB
FLXHUMR_URB2D(I,J)=FLXHUMR_URB
FLXHUMB_URB2D(I,J)=FLXHUMB_URB
FLXHUMG_URB2D(I,J)=FLXHUMG_URB
DRELR_URB2D(I,J) = DRELR_URB
DRELB_URB2D(I,J) = DRELB_URB
DRELG_URB2D(I,J) = DRELG_URB
DO K = 1,num_roof_layers
TRL_URB3D(I,K,J) = TRL_URB(K)
SMR_URB3D(I,K,J) = SMR_URB(K)
TGRL_URB3D(I,K,J)= TGRL_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
CMGR_SFCDIF(I,J) = CMGR_URB
CHGR_SFCDIF(I,J) = CHGR_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
ENDDO ILOOP ! of I loop
ENDDO JLOOP ! 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,num_urban_hi, &
trb_urb4d,tw1_urb4d,tw2_urb4d,tgb_urb4d, &
sfw1_urb3d,sfw2_urb3d,sfr_urb3d,sfg_urb3d, &
lp_urb2d,hi_urb2d,lb_urb2d,hgt_urb2d, &
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, &
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,num_urban_hi, &
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, &
lp_urb2d,hi_urb2d,lb_urb2d,hgt_urb2d, &
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) == LOW_DENSITY_RESIDENTIAL .or. &
! IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) 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, & 2,7
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(LEN=80) :: err_message
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
! GAC-->
! 20130219 - No longer need these - see module_data_gocart_dust
!#if ( WRF_CHEM == 1 )
!!
!! need this parameter for dust parameterization in wrf/chem
!!
! do I=1,NSLTYPE
! porosity(i)=maxsmc(i)
! drypoint(i)=drysmc(i)
! enddo
!#endif
! <--GAC
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_noahdrv.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
#if ( HWRF == 1 )
CALL wrf_message( "WARNING: message only; was fatal. module_sf_noahdrv.F: lsminit: out of range value "// &
"of ISLTYP. Is this field in the input?" )
#else
CALL wrf_error_fatal( "module_sf_noahdrv.F: lsminit: out of range value "// &
"of ISLTYP. Is this field in the input?" )
#endif
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) 1,78
!-----------------------------------------------------------------
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
character*256 :: a_string
logical, external :: wrf_dm_on_monitor
integer , parameter :: loop_max = 10
integer :: loop_count
!-----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
loop_count = 0
READ (19,FMT='(A)',END=2002) a_string
FIND_LUTYPE : DO WHILE (LUMATCH == 0)
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
loop_count = loop_count+1
call wrf_message ( "Skipping over LUTYPE = " // TRIM ( LUTYPE ) )
FIND_VEGETATION_PARAMETER_FLAG : DO
READ (19,FMT='(A)', END=2002) a_string
IF ( a_string(1:21) .EQ. 'Vegetation Parameters' ) THEN
EXIT FIND_VEGETATION_PARAMETER_FLAG
ELSE IF ( loop_count .GE. loop_max ) THEN
CALL wrf_error_fatal ( 'Too many loops in VEGPARM.TBL')
ENDIF
ENDDO FIND_VEGETATION_PARAMETER_FLAG
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(ZTOPVTBL) < LUCATS .OR. &
SIZE(ZBOTVTBL) < 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),&
ZTOPVTBL(LC), ZBOTVTBL(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
READ (19,*)
READ (19,*)
READ (19,FMT='(A)') a_string
IF ( a_string(1:21) .EQ. 'Vegetation Parameters' ) THEN
CALL wrf_message ("Expected low and high density residential, and high density industrial information in VEGPARM.TBL")
CALL wrf_error_fatal ("This could be caused by using an older VEGPARM.TBL file with a newer WRF source code.")
ENDIF
READ (19,*)LOW_DENSITY_RESIDENTIAL
READ (19,*)
READ (19,*)HIGH_DENSITY_RESIDENTIAL
READ (19,*)
READ (19,*)HIGH_INTENSITY_INDUSTRIAL
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 ( ZTOPVTBL , NLUS )
CALL wrf_dm_bcast_real ( ZBOTVTBL , 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 )
CALL wrf_dm_bcast_integer ( LOW_DENSITY_RESIDENTIAL , 1 )
CALL wrf_dm_bcast_integer ( HIGH_DENSITY_RESIDENTIAL , 1 )
CALL wrf_dm_bcast_integer ( HIGH_INTENSITY_INDUSTRIAL , 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
!-----------------------------------------------------------------
!===========================================================================
!
! subroutine lsm_mosaic: a tiling approach for Noah LSM
!
!===========================================================================
SUBROUTINE lsm_mosaic(DZ8W,QV3D,P8W3D,T3D,TSK, & 1,14
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,OPT_THCND, &
NLCAT,landusef,landusef2, & ! danli mosaic
sf_surface_mosaic,mosaic_cat,mosaic_cat_index, & ! danli mosaic
TSK_mosaic,QSFC_mosaic, & ! danli mosaic
TSLB_mosaic,SMOIS_mosaic,SH2O_mosaic, & ! danli mosaic
CANWAT_mosaic,SNOW_mosaic, & ! danli mosaic
SNOWH_mosaic,SNOWC_mosaic, & ! danli mosaic
ALBEDO_mosaic,ALBBCK_mosaic, & ! danli mosaic
EMISS_mosaic, EMBCK_mosaic, & ! danli mosaic
ZNT_mosaic, Z0_mosaic, & ! danli mosaic
HFX_mosaic,QFX_mosaic, & ! danli mosaic
LH_mosaic, GRDFLX_mosaic, SNOTIME_mosaic, & ! danli mosaic
! Noah UA changes
ua_phys,flx4_2d,fvb_2d,fbur_2d,fgsn_2d, &
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, &
CMGR_SFCDIF,CHGR_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
TR_URB2D_mosaic,TB_URB2D_mosaic, & !H urban danli mosaic
TG_URB2D_mosaic,TC_URB2D_mosaic, & !H urban danli mosaic
QC_URB2D_mosaic,UC_URB2D_mosaic, & !H urban danli mosaic
TRL_URB3D_mosaic,TBL_URB3D_mosaic, & !H urban danli mosaic
TGL_URB3D_mosaic, & !H urban danli mosaic
SH_URB2D_mosaic,LH_URB2D_mosaic, & !H urban danli mosaic
G_URB2D_mosaic,RN_URB2D_mosaic, & !H urban danli mosaic
TS_URB2D_mosaic, & !H urban danli mosaic
TS_RUL2D_mosaic, & !H urban danli mosaic
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
CMCR_URB2D,TGR_URB2D,TGRL_URB3D,SMR_URB3D, & !H urban
julian,julyr, & !H urban
DRELR_URB2D,DRELB_URB2D,DRELG_URB2D, & !H urban
FLXHUMR_URB2D,FLXHUMB_URB2D,FLXHUMG_URB2D, & !H urban
FRC_URB2D,UTYPE_URB2D, & !O
num_urban_layers, & !I multi-layer urban
num_urban_hi, & !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
lp_urb2d,hi_urb2d,lb_urb2d,hgt_urb2d, & !H multi-layer urban
mh_urb2d,stdh_urb2d,lf_urb2d, & !SLUCM
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
,sfcheadrt,INFXSRT, soldrain & !hydro
,SDA_HFX, SDA_QFX, HFX_BOTH, QFX_BOTH, QNORM, fasdas & !fasdas
)
!----------------------------------------------------------------
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 (m)
!-- 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
INTEGER, INTENT(IN ) :: julian,julyr
!added by Wei Yu for routing
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(INOUT) :: sfcheadrt,INFXSRT,soldrain
real :: etpnd1
!end added
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(IN ) :: TMN, &
XLAND, &
XICE, &
VEGFRA, &
SHDMIN, &
SHDMAX, &
SNOALB, &
GSW, &
SWDOWN, & !added 10 jan 2007
GLW, &
RAINBL, &
SR
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(INOUT) :: ALBBCK, &
Z0, &
EMBCK ! danli mosaic
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 ) :: ISLTYP
INTEGER, DIMENSION( ims:ime, jms:jme ) , &
INTENT(INOUT ) :: IVGTYP ! for mosaic danli
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
INTEGER, INTENT(IN) :: OPT_THCND
! Noah UA changes
LOGICAL, INTENT(IN) :: UA_PHYS
REAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: FLX4_2D,FVB_2D,FBUR_2D,FGSN_2D
REAL :: FLX4,FVB,FBUR,FGSN
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) :: CMGR_SFCDIF
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CHGR_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
!===Yang,2014/10/08,hydrological variable for single layer UCM===
INTEGER :: jmonth, jday, tloc
INTEGER :: IRIOPTION, USOIL, DSOIL
REAL :: AOASIS, OMG
REAL :: DRELR_URB
REAL :: DRELB_URB
REAL :: DRELG_URB
REAL :: FLXHUMR_URB
REAL :: FLXHUMB_URB
REAL :: FLXHUMG_URB
REAL :: CMCR_URB
REAL :: TGR_URB
REAL, DIMENSION(1:num_roof_layers) :: SMR_URB ! green roof layer moisture
REAL, DIMENSION(1:num_roof_layers) :: TGRL_URB ! green roof layer temp [K]
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: DRELR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: DRELB_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: DRELG_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: FLXHUMR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: FLXHUMB_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: FLXHUMG_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: CMCR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: TGR_URB2D
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_roof_layers, jms:jme ), INTENT(INOUT) :: TGRL_URB3D
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_roof_layers, jms:jme ), INTENT(INOUT) :: SMR_URB3D
! 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(INOUT) :: FRC_URB2D ! change this to inout, danli mosaic
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
! NUDAPT Parameters urban --> lam
REAL :: mh_urb
REAL :: stdh_urb
REAL :: lp_urb
REAL :: hgt_urb
REAL, DIMENSION(4) :: lf_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
INTEGER, INTENT(IN ) :: NUM_URBAN_HI
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, 1:num_urban_hi, jms:jme ), INTENT(IN) :: hi_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: lp_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: lb_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: hgt_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: mh_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: stdh_urb2d
REAL, OPTIONAL, DIMENSION( ims:ime, 4, jms:jme ), INTENT(IN) :: lf_urb2d
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( its:ite, jts:jte ) :: HFX_RURAL,LH_RURAL,GRDFLX_RURAL ! ,RN_RURAL
REAL, DIMENSION( its:ite, jts:jte ) :: QFX_RURAL ! ,QSFC_RURAL,UMOM_RURAL,VMOM_RURAL
REAL, DIMENSION( its:ite, jts:jte ) :: ALB_RURAL,EMISS_RURAL,TSK_RURAL ! ,UST_RURAL
! REAL, DIMENSION( ims:ime, jms:jme ) :: QSFC_URB
REAL, DIMENSION( its:ite, jts:jte ) :: HFX_URB,UMOM_URB,VMOM_URB
REAL, DIMENSION( its:ite, jts:jte ) :: QFX_URB
! REAL, DIMENSION( ims:ime, jms:jme ) :: ALBEDO_URB,EMISS_URB,UMOM,VMOM,UST
REAL, DIMENSION(its:ite,jts:jte) ::EMISS_URB
REAL, DIMENSION(its:ite,jts:jte) :: RL_UP_URB
REAL, DIMENSION(its:ite,jts:jte) ::RS_ABS_URB
REAL, DIMENSION(its:ite,jts:jte) ::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, CMGR_URB, CHGR_URB
REAL :: frc_urb,lb_urb
REAL :: check
! ----------------------------------------------------------------------
! DECLARATIONS END - urban
! ----------------------------------------------------------------------
!-------------------------------------------------
! Noah-mosaic related variables are added to declaration (danli)
!-------------------------------------------------
INTEGER, INTENT(IN) :: sf_surface_mosaic
INTEGER, INTENT(IN) :: mosaic_cat, NLCAT
REAL, DIMENSION( ims:ime, NLCAT, jms:jme ), INTENT(IN) :: landusef
REAL, DIMENSION( ims:ime, NLCAT, jms:jme ), INTENT(INOUT) ::landusef2
INTEGER, DIMENSION( ims:ime, NLCAT, jms:jme ), INTENT(INOUT) :: mosaic_cat_index
REAL, DIMENSION( ims:ime, 1:mosaic_cat, jms:jme ) , OPTIONAL, INTENT(INOUT):: &
TSK_mosaic, QSFC_mosaic, CANWAT_mosaic, SNOW_mosaic,SNOWH_mosaic, SNOWC_mosaic
REAL, DIMENSION( ims:ime, 1:mosaic_cat, jms:jme ) , OPTIONAL, INTENT(INOUT):: &
ALBEDO_mosaic,ALBBCK_mosaic, EMISS_mosaic, EMBCK_mosaic, ZNT_mosaic, Z0_mosaic, &
HFX_mosaic,QFX_mosaic, LH_mosaic, GRDFLX_mosaic,SNOTIME_mosaic
REAL, DIMENSION( ims:ime, 1:num_soil_layers*mosaic_cat, jms:jme ), OPTIONAL, INTENT(INOUT):: &
TSLB_mosaic,SMOIS_mosaic,SH2O_mosaic
REAL, DIMENSION( ims:ime, jms:jme ) :: TSK_mosaic_avg, QSFC_mosaic_avg, CANWAT_mosaic_avg,SNOW_mosaic_avg,SNOWH_mosaic_avg, &
SNOWC_mosaic_avg, HFX_mosaic_avg, QFX_mosaic_avg, LH_mosaic_avg, GRDFLX_mosaic_avg, &
ALBEDO_mosaic_avg, ALBBCK_mosaic_avg, EMISS_mosaic_avg, EMBCK_mosaic_avg, &
ZNT_mosaic_avg, Z0_mosaic_avg, SNOTIME_mosaic_avg, FAREA_mosaic_avg
REAL, DIMENSION( ims:ime, 1:num_soil_layers, jms:jme ) :: &
TSLB_mosaic_avg,SMOIS_mosaic_avg,SH2O_mosaic_avg
REAL, DIMENSION( ims:ime, 1:mosaic_cat, jms:jme ) , OPTIONAL, INTENT(INOUT):: &
TR_URB2D_mosaic, TB_URB2D_mosaic, TG_URB2D_mosaic, TC_URB2D_mosaic,QC_URB2D_mosaic, UC_URB2D_mosaic, &
SH_URB2D_mosaic,LH_URB2D_mosaic,G_URB2D_mosaic,RN_URB2D_mosaic,TS_URB2D_mosaic, TS_RUL2D_mosaic
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_roof_layers*mosaic_cat, jms:jme ), INTENT(INOUT) :: TRL_URB3D_mosaic
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_wall_layers*mosaic_cat, jms:jme ), INTENT(INOUT) :: TBL_URB3D_mosaic
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_road_layers*mosaic_cat, jms:jme ), INTENT(INOUT) :: TGL_URB3D_mosaic
INTEGER, DIMENSION( ims:ime, jms:jme ) :: IVGTYP_dominant
INTEGER :: mosaic_i, URBAN_METHOD, zo_avg_option
REAL :: FAREA
LOGICAL :: IPRINT_mosaic, Noah_call
!-------------------------------------------------
! Noah-mosaic related variables declaration end (danli)
!-------------------------------------------------
REAL, PARAMETER :: CAPA=R_D/CP
REAL :: APELM,APES,SFCTH2,PSFC
real, intent(in) :: xice_threshold
character(len=80) :: message_text
!
! FASDAS: it doesn't work for mosaic, but we need the variables to call sflx
!
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(INOUT) :: SDA_HFX, SDA_QFX, HFX_BOTH, QFX_BOTH, QNORM
INTEGER, INTENT(IN ) :: fasdas
REAL :: XSDA_HFX, XSDA_QFX, XQNORM
REAL :: HFX_PHY, QFX_PHY
REAL :: DZQ
REAL :: HCPCT_FASDAS
HFX_PHY = 0.0 ! initialize
QFX_PHY = 0.0
XQNORM = 0.0
XSDA_HFX = 0.0
XSDA_QFX = 0.0
!
! END FASDAS
!
! MEK MAY 2007
FDTLIW=DT/ROWLIW
! MEK JUL2007
FDTW=DT/(XLV*RHOWATER)
! debug printout
IPRINT=.false.
IPRINT_mosaic=.false.
! SLOPETYP=2
SLOPETYP=1
! SHDMIN=0.00
NSOIL=num_soil_layers
DO NS=1,NSOIL
SLDPTH(NS)=DZS(NS)
ENDDO
JLOOP : 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
!-----------------------------------------------------------------------
ILOOP : DO I=its,ite
IF (((XLAND(I,J)-1.5).LT.0.) .AND. (XICE(I,J) < XICE_THRESHOLD) ) THEN
IVGTYP_dominant(I,J)=IVGTYP(I,J) ! save this
! INITIALIZE THE AREA-AVERAGED FLUXES
TSK_mosaic_avg(i,j)= 0 ! from 3D to 2D
QSFC_mosaic_avg(i,j)= 0
CANWAT_mosaic_avg(i,j)= 0
SNOW_mosaic_avg(i,j)= 0
SNOWH_mosaic_avg(i,j)= 0
SNOWC_mosaic_avg(i,j)= 0
DO NS=1,NSOIL
TSLB_mosaic_avg(i,NS,j)=0
SMOIS_mosaic_avg(i,NS,j)=0
SH2O_mosaic_avg(i,NS,j)=0
ENDDO
HFX_mosaic_avg(i,j)= 0
QFX_mosaic_avg(i,j)= 0
LH_mosaic_avg(i,j)= 0
GRDFLX_mosaic_avg(i,j)= 0
ALBEDO_mosaic_avg(i,j)=0
ALBBCK_mosaic_avg(i,j)=0
EMISS_mosaic_avg(i,j)=0
EMBCK_mosaic_avg(i,j)=0
ZNT_mosaic_avg(i,j)=0
Z0_mosaic_avg(i,j)=0
FAREA_mosaic_avg(i,j)=0
! add a new loop for the mosaic_cat
DO mosaic_i = mosaic_cat, 1, -1
! if (mosaic_cat_index(I,mosaic_i,J) .EQ. 16 ) then
! PRINT*, 'you still have water tiles at','i=',i,'j=',j, 'mosaic_i',mosaic_i
! PRINT*, 'xland',xland(i,j),'xice',xice(i,j)
! endif
IVGTYP(I,J)=mosaic_cat_index(I,mosaic_i,J) ! replace it with the mosaic one
TSK(I,J)=TSK_mosaic(I,mosaic_i,J) ! from 3D to 2D
QSFC(i,j)=QSFC_mosaic(I,mosaic_i,J)
CANWAT(i,j)=CANWAT_mosaic(i,mosaic_i,j)
SNOW(i,j)=SNOW_mosaic(i,mosaic_i,j)
SNOWH(i,j)=SNOWH_mosaic(i,mosaic_i,j)
SNOWC(i,j)=SNOWC_mosaic(i,mosaic_i,j)
ALBEDO(i,j) = ALBEDO_mosaic(i,mosaic_i,j)
ALBBCK(i,j)= ALBBCK_mosaic(i,mosaic_i,j)
EMISS(i,j)= EMISS_mosaic(i,mosaic_i,j)
EMBCK(i,j)= EMBCK_mosaic(i,mosaic_i,j)
ZNT(i,j)= ZNT_mosaic(i,mosaic_i,j)
Z0(i,j)= Z0_mosaic(i,mosaic_i,j)
SNOTIME(i,j)= SNOTIME_mosaic(i,mosaic_i,j)
DO NS=1,NSOIL
TSLB(i,NS,j)=TSLB_mosaic(i,NSOIL*(mosaic_i-1)+NS,j)
SMOIS(i,NS,j)=SMOIS_mosaic(i,NSOIL*(mosaic_i-1)+NS,j)
SH2O(i,NS,j)=SH2O_mosaic(i,NSOIL*(mosaic_i-1)+NS,j)
ENDDO
IF(IPRINT_mosaic) THEN
print*, 'BEFORE SFLX, in Noahdrv.F'
print*, 'mosaic_cat', mosaic_cat, 'IVGTYP',IVGTYP(i,j), 'TSK',TSK(i,j),'HFX',HFX(i,j), 'QSFC', QSFC(i,j), &
'CANWAT', CANWAT(i,j), 'SNOW',SNOW(i,j), 'ALBEDO',ALBEDO(i,j), 'TSLB',TSLB(i,1,j),'CHS',CHS(i,j),'ZNT',ZNT(i,j)
ENDIF
!-----------------------------------------------------------------------
! insert the NOAH model here for the non-urban one and the urban one DANLI
!-----------------------------------------------------------------------
! 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
! Land-ice or land points use the usual deep-soil temperature.
TBOT=TMN(I,J)
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 NS=1,NSOIL
SMC(NS)=SMOIS(I,NS,J)
STC(NS)=TSLB(I,NS,J) !STEMP
SWC(NS)=SH2O(I,NS,J)
ENDDO
!
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) == LOW_DENSITY_RESIDENTIAL .or. &
! IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) 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) == LOW_DENSITY_RESIDENTIAL .or. &
! IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
! VEGTYP = ISURBAN
! ENDIF
! ENDIF
Noah_call=.TRUE.
If ( SF_URBAN_PHYSICS == 0 ) THEN ! ONLY NOAH
IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
Noah_call = .TRUE.
VEGTYP = ISURBAN
ENDIF
ENDIF
IF(SF_URBAN_PHYSICS == 1) THEN
IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
Noah_call = .TRUE.
VEGTYP = NATURAL
SHDFAC = SHDTBL(NATURAL)
ALBEDOK =0.2 ! 0.2
ALBBRD =0.2 ! 0.2
EMISSI = 0.98 ! for VEGTYP=5
T1= TS_RUL2D_mosaic(I,mosaic_i,J)
ENDIF
ENDIF
!===Yang, 2014/10/08, hydrological processes for urban vegetation in single layer UCM===
AOASIS = 1.0
USOIL = 1
DSOIL = 2
IRIOPTION=IRI_SCHEME
OMG= OMG_URB2D(I,J)
tloc=mod(int(OMG/3.14159*180./15.+12.+0.5 ),24)
if (tloc.lt.0) tloc=tloc+24
if (tloc==0) tloc=24
CALL cal_mon_day(julian,julyr,jmonth,jday)
IF(SF_URBAN_PHYSICS == 1) THEN
IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
AOASIS = oasis ! urban oasis effect
IF (IRIOPTION ==1) THEN
IF (tloc==21 .or. tloc==22) THEN !irrigation on vegetaion in urban area, MAY-SEP, 9-10pm
IF (jmonth==5 .or. jmonth==6 .or. jmonth==7 .or. jmonth==8 .or. jmonth==9) THEN
IF (SMC(USOIL) .LT. SMCREF) SMC(USOIL)= REFSMC(ISLTYP(I,J))
IF (SMC(DSOIL) .LT. SMCREF) SMC(DSOIL)= REFSMC(ISLTYP(I,J))
ENDIF
ENDIF
ENDIF
ENDIF
ENDIF
IF(SF_URBAN_PHYSICS == 2 .or. SF_URBAN_PHYSICS == 3) THEN
IF(AOASIS > 1.0) THEN
CALL wrf_error_fatal('Urban oasis option is for SF_URBAN_PHYSICS == 1 only')
ENDIF
IF(IRIOPTION == 1) THEN
CALL wrf_error_fatal('Urban irrigation option is for SF_URBAN_PHYSICS == 1 only')
ENDIF
ENDIF
IF( SF_URBAN_PHYSICS==2.OR.SF_URBAN_PHYSICS==3 ) THEN
! print*, 'MOSAIC is not designed to work with SF_URBAN_PHYSICS=2 or SF_URBAN_PHYSICS=3'
ENDIF
IF (Noah_call) THEN
#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
IF ( ICE == 1 ) THEN
! Sea-ice case
DO NS = 1, NSOIL
SH2O(I,NS,J) = 1.0
ENDDO
LAI(I,J) = 0.01
CYCLE ILOOP
ELSEIF (ICE == 0) THEN
! Non-glacial land
CALL SFLX (I,J,FFROZP, 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
FLX4,FVB,FBUR,FGSN,UA_PHYS, & !UA
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, &
sfcheadrt(i,j), & !I
INFXSRT(i,j),ETPND1,OPT_THCND,AOASIS & !O
,XSDA_QFX, HFX_PHY, QFX_PHY, XQNORM, fasdas, HCPCT_FASDAS & ! fasdas vars
)
#ifdef WRF_HYDRO
soldrain(i,j) = RUNOFF2*DT*1000.0
#endif
ELSEIF (ICE == -1) THEN
!
! Set values that the LSM is expected to update,
! but don't get updated for glacial points.
!
SOILM = 0.0 !BSINGH(PNNL)- SOILM is undefined for this case, it is used for diagnostics so setting it to zero
XLAI = 0.01 ! KWM Should this be Zero over land ice? Does this value matter?
RUNOFF2 = 0.0
RUNOFF3 = 0.0
DO NS = 1, NSOIL
SWC(NS) = 1.0
SMC(NS) = 1.0
SMAV(NS) = 1.0
ENDDO
CALL SFLX_GLACIAL(I,J,ISICE,FFROZP,DT,ZLVL,NSOIL,SLDPTH, & !C
& LWDN,SOLNET,SFCPRS,PRCP,SFCTMP,Q2K, & !F
& TH2,Q2SAT,DQSDT2, & !I
& ALBBRD, SNOALB1,TBOT, Z0BRD, Z0K, EMISSI, EMBRD, & !S
& T1,STC(1:NSOIL),SNOWHK,SNEQV,ALBEDOK,CHK, & !H
& ETA,SHEAT,ETA_KINEMATIC,FDOWN, & !O
& ESNOW,DEW, & !O
& ETP,SSOIL, & !O
& FLX1,FLX2,FLX3, & !O
& SNOMLT,SNCOVR, & !O
& RUNOFF1, & !O
& Q1, & !D
& SNOTIME1, &
& RIBB)
ENDIF
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
#ifdef WRF_HYDRO
!added by Wei Yu
! QFX(I,J) = QFX(I,J) + ETPND1
! ETA = ETA + ETPND1/2.501E6*dt
!end added by Wei Yu
#endif
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 81 NS=1,NSOIL
SMOIS(I,NS,J)=SMC(NS)
TSLB(I,NS,J)=STC(NS) ! STEMP
SH2O(I,NS,J)=SWC(NS)
81 CONTINUE
! ENDIF
FLX4_2D(I,J) = FLX4
FVB_2D(I,J) = FVB
FBUR_2D(I,J) = FBUR
FGSN_2D(I,J) = FGSN
!
! Residual of surface energy balance equation terms
!
IF ( UA_PHYS ) THEN
noahres(i,j) = ( solnet + lwdn ) - sheat + ssoil - eta &
- ( emissi * STBOLT * (t1**4) ) - flx1 - flx2 - flx3 - flx4
ELSE
noahres(i,j) = ( solnet + lwdn ) - sheat + ssoil - eta &
- ( emissi * STBOLT * (t1**4) ) - flx1 - flx2 - flx3
ENDIF
ENDIF !ENDIF FOR Noah_call
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) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL ) THEN
! UTYPE_URB = UTYPE_URB2D(I,J) !urban type (low, high or industrial)
! this need to be changed in the mosaic danli
IF(IVGTYP(I,J)==ISURBAN) UTYPE_URB=2
IF(IVGTYP(I,J)==LOW_DENSITY_RESIDENTIAL) UTYPE_URB=1
IF(IVGTYP(I,J)==HIGH_DENSITY_RESIDENTIAL) UTYPE_URB=2
IF(IVGTYP(I,J)==HIGH_INTENSITY_INDUSTRIAL) UTYPE_URB=3
IF(UTYPE_URB==1) FRC_URB2D(I,J)=0.5
IF(UTYPE_URB==2) FRC_URB2D(I,J)=0.9
IF(UTYPE_URB==3) FRC_URB2D(I,J)=0.95
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.
! mosaic 3D to 2D
TR_URB2D(I,J)=TR_URB2D_mosaic(I,mosaic_i,J) ! replace it with the mosaic one
TB_URB2D(I,J)=TB_URB2D_mosaic(I,mosaic_i,J) ! replace it with the mosaic one
TG_URB2D(I,J)=TG_URB2D_mosaic(I,mosaic_i,J) ! replace it with the mosaic one
TC_URB2D(I,J)=TC_URB2D_mosaic(I,mosaic_i,J) ! replace it with the mosaic one
QC_URB2D(I,J)=QC_URB2D_mosaic(I,mosaic_i,J) ! replace it with the mosaic one
UC_URB2D(I,J)=UC_URB2D_mosaic(I,mosaic_i,J) ! replace it with the mosaic one
TS_URB2D(I,J)=TS_URB2D_mosaic(I,mosaic_i,J) ! replace it with the mosaic one
DO K = 1,num_roof_layers
TRL_URB3D(I,K,J) = TRL_URB3D_mosaic(I,K+(mosaic_i-1)*num_roof_layers,J)
END DO
DO K = 1,num_wall_layers
TBL_URB3D(I,K,J) = TBL_URB3D_mosaic(I,K+(mosaic_i-1)*num_roof_layers,J)
END DO
DO K = 1,num_road_layers
TGL_URB3D(I,K,J) = TGL_URB3D_mosaic(I,K+(mosaic_i-1)*num_roof_layers,J)
END DO
! mosaic 2D to 1D
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)
SMR_URB(K) = SMR_URB3D(I,K,J)
TGRL_URB(K)= TGRL_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
TGR_URB = TGR_URB2D(I,J)
CMCR_URB = CMCR_URB2D(I,J)
FLXHUMR_URB = FLXHUMR_URB2D(I,J)
FLXHUMB_URB = FLXHUMB_URB2D(I,J)
FLXHUMG_URB = FLXHUMG_URB2D(I,J)
DRELR_URB = DRELR_URB2D(I,J)
DRELB_URB = DRELB_URB2D(I,J)
DRELG_URB = DRELG_URB2D(I,J)
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)
CMGR_URB = CMGR_SFCDIF(I,J)
CHGR_URB = CHGR_SFCDIF(I,J)
CMC_URB = CMC_SFCDIF(I,J)
CHC_URB = CHC_SFCDIF(I,J)
ENDIF
! NUDAPT for SLUCM
mh_urb = mh_urb2d(I,J)
stdh_urb = stdh_urb2d(I,J)
lp_urb = lp_urb2d(I,J)
hgt_urb = hgt_urb2d(I,J)
lf_urb = 0.0
DO K = 1,4
lf_urb(K)=lf_urb2d(I,K,J)
ENDDO
frc_urb = frc_urb2d(I,J)
lb_urb = lb_urb2d(I,J)
check = 0
if (I.eq.73.and.J.eq.125)THEN
check = 1
end if
!
! Call urban
CALL cal_mon_day(julian,julyr,jmonth,jday)
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,mh_urb, stdh_urb, lf_urb, lp_urb, & ! 0
hgt_urb,frc_urb,lb_urb, check,CMCR_URB,TGR_URB, & ! H
TGRL_URB,SMR_URB,CMGR_URB,CHGR_URB,jmonth, & ! H
DRELR_URB,DRELB_URB, & ! H
DRELG_URB,FLXHUMR_URB,FLXHUMB_URB,FLXHUMG_URB)
#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]
ZNT(I,J)= EXP(FRC_URB2D(I,J)*ALOG(ZNT_URB)+(1-FRC_URB2D(I,J))* ALOG(ZNT(I,J))) ! ADD BY DAN
#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)
SMR_URB3D(I,K,J) = SMR_URB(K)
TGRL_URB3D(I,K,J)= TGRL_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
TGR_URB2D(I,J) =TGR_URB
CMCR_URB2D(I,J)=CMCR_URB
FLXHUMR_URB2D(I,J)=FLXHUMR_URB
FLXHUMB_URB2D(I,J)=FLXHUMB_URB
FLXHUMG_URB2D(I,J)=FLXHUMG_URB
DRELR_URB2D(I,J) = DRELR_URB
DRELB_URB2D(I,J) = DRELB_URB
DRELG_URB2D(I,J) = DRELG_URB
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
CMGR_SFCDIF(I,J) = CMGR_URB
CHGR_SFCDIF(I,J) = CHGR_URB
CMC_SFCDIF(I,J) = CMC_URB
CHC_SFCDIF(I,J) = CHC_URB
ENDIF
! 2D to 3D mosaic danli
TR_URB2D_mosaic(I,mosaic_i,J)=TR_URB2D(I,J)
TB_URB2D_mosaic(I,mosaic_i,J)=TB_URB2D(I,J)
TG_URB2D_mosaic(I,mosaic_i,J)=TG_URB2D(I,J)
TC_URB2D_mosaic(I,mosaic_i,J)=TC_URB2D(I,J)
QC_URB2D_mosaic(I,mosaic_i,J)=QC_URB2D(I,J)
UC_URB2D_mosaic(I,mosaic_i,J)=UC_URB2D(I,J)
TS_URB2D_mosaic(I,mosaic_i,J)=TS_URB2D(I,J)
TS_RUL2D_mosaic(I,mosaic_i,J)=T1
DO K = 1,num_roof_layers
TRL_URB3D_mosaic(I,K+(mosaic_i-1)*num_roof_layers,J)=TRL_URB3D(I,K,J)
END DO
DO K = 1,num_wall_layers
TBL_URB3D_mosaic(I,K+(mosaic_i-1)*num_roof_layers,J)=TBL_URB3D(I,K,J)
END DO
DO K = 1,num_road_layers
TGL_URB3D_mosaic(I,K+(mosaic_i-1)*num_roof_layers,J)=TGL_URB3D(I,K,J)
END DO
SH_URB2D_mosaic(I,mosaic_i,J) = SH_URB2D(I,J)
LH_URB2D_mosaic(I,mosaic_i,J) = LH_URB2D(I,J)
G_URB2D_mosaic(I,mosaic_i,J) = G_URB2D(I,J)
RN_URB2D_mosaic(I,mosaic_i,J) = RN_URB2D(I,J)
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
!-----------------------------------------------------------------------
! Done with the Noah-UCM MOSAIC DANLI
!-----------------------------------------------------------------------
TSK_mosaic(i,mosaic_i,j)=TSK(i,j) ! from 2D to 3D
QSFC_mosaic(i,mosaic_i,j)=QSFC(i,j)
CANWAT_mosaic(i,mosaic_i,j)=CANWAT(i,j)
SNOW_mosaic(i,mosaic_i,j)=SNOW(i,j)
SNOWH_mosaic(i,mosaic_i,j)=SNOWH(i,j)
SNOWC_mosaic(i,mosaic_i,j)=SNOWC(i,j)
ALBEDO_mosaic(i,mosaic_i,j)=ALBEDO(i,j)
ALBBCK_mosaic(i,mosaic_i,j)=ALBBCK(i,j)
EMISS_mosaic(i,mosaic_i,j)=EMISS(i,j)
EMBCK_mosaic(i,mosaic_i,j)=EMBCK(i,j)
ZNT_mosaic(i,mosaic_i,j)=ZNT(i,j)
Z0_mosaic(i,mosaic_i,j)=Z0(i,j)
HFX_mosaic(i,mosaic_i,j)=HFX(i,j)
QFX_mosaic(i,mosaic_i,j)=QFX(i,j)
LH_mosaic(i,mosaic_i,j)=LH(i,j)
GRDFLX_mosaic(i,mosaic_i,j)=GRDFLX(i,j)
SNOTIME_mosaic(i,mosaic_i,j)=SNOTIME(i,j)
DO NS=1,NSOIL
TSLB_mosaic(i,NSOIL*(mosaic_i-1)+NS,j)=TSLB(i,NS,j)
SMOIS_mosaic(i,NSOIL*(mosaic_i-1)+NS,j)=SMOIS(i,NS,j)
SH2O_mosaic(i,NSOIL*(mosaic_i-1)+NS,j)=SH2O(i,NS,j)
ENDDO
#if 0
IF(TSK_mosaic(i,mosaic_i,j) > 350 .OR. TSK_mosaic(i,mosaic_i,j) < 250 .OR. abs(HFX_mosaic(i,mosaic_i,j)) > 700 ) THEN
print*, 'I', I, 'J', J, 'MOSAIC_I', MOSAIC_I
print*, 'mosaic_cat_index',mosaic_cat_index(I,mosaic_i,J), 'landusef2',landusef2(i,mosaic_i,j)
print*, 'TSK_mosaic', TSK_mosaic(i,mosaic_i,j), 'HFX_mosaic', HFX_mosaic(i,mosaic_i,j), &
'LH_mosaic',LH_mosaic(i,mosaic_i,j),'GRDFLX_mosaic',GRDFLX_mosaic(i,mosaic_i,j)
print*, 'ZNT_mosaic', ZNT_mosaic(i, mosaic_i,j), 'Z0_mosaic', Z0_mosaic(i,mosaic_i,j)
print*, 'FRC_URB2D',FRC_URB2D(I,J)
print*, 'TS_URB',TS_URB2D(I,J),'T1',T1
print*, 'SH_URB2D',SH_URB2D(I,J),'SHEAT',SHEAT
print*, 'LH_URB',LH_URB2D(I,J),'ETA',ETA
print*, 'TS_RUL2D',TS_RUL2D_mosaic(I,mosaic_i,J)
ENDIF
#endif
!-----------------------------------------------------------------------
! Now let's do the grid-averaging
!-----------------------------------------------------------------------
FAREA = landusef2(i,mosaic_i,j)
TSK_mosaic_avg(i,j) = TSK_mosaic_avg(i,j) + (EMISS_mosaic(i,mosaic_i,j)*TSK_mosaic(i,mosaic_i,j)**4)*FAREA ! conserve the longwave radiation
QSFC_mosaic_avg(i,j) = QSFC_mosaic_avg(i,j) + QSFC_mosaic(i,mosaic_i,j)*FAREA
CANWAT_mosaic_avg(i,j) = CANWAT_mosaic_avg(i,j) + CANWAT_mosaic(i,mosaic_i,j)*FAREA
SNOW_mosaic_avg(i,j) = SNOW_mosaic_avg(i,j) + SNOW_mosaic(i,mosaic_i,j)*FAREA
SNOWH_mosaic_avg(i,j) = SNOWH_mosaic_avg(i,j) + SNOWH_mosaic(i,mosaic_i,j)*FAREA
SNOWC_mosaic_avg(i,j) = SNOWC_mosaic_avg(i,j) + SNOWC_mosaic(i,mosaic_i,j)*FAREA
DO NS=1,NSOIL
TSLB_mosaic_avg(i,NS,j)=TSLB_mosaic_avg(i,NS,j) + TSLB_mosaic(i,NS*mosaic_i,j)*FAREA
SMOIS_mosaic_avg(i,NS,j)=SMOIS_mosaic_avg(i,NS,j) + SMOIS_mosaic(i,NS*mosaic_i,j)*FAREA
SH2O_mosaic_avg(i,NS,j)=SH2O_mosaic_avg(i,NS,j) + SH2O_mosaic(i,NS*mosaic_i,j)*FAREA
ENDDO
FAREA_mosaic_avg(i,j)=FAREA_mosaic_avg(i,j)+FAREA
HFX_mosaic_avg(i,j) = HFX_mosaic_avg(i,j) + HFX_mosaic(i,mosaic_i,j)*FAREA
QFX_mosaic_avg(i,j) = QFX_mosaic_avg(i,j) + QFX_mosaic(i,mosaic_i,j)*FAREA
LH_mosaic_avg(i,j) = LH_mosaic_avg(i,j) + LH_mosaic(i,mosaic_i,j)*FAREA
GRDFLX_mosaic_avg(i,j)=GRDFLX_mosaic_avg(i,j)+GRDFLX_mosaic(i,mosaic_i,j)*FAREA
ALBEDO_mosaic_avg(i,j)=ALBEDO_mosaic_avg(i,j)+ALBEDO_mosaic(i,mosaic_i,j)*FAREA
ALBBCK_mosaic_avg(i,j)=ALBBCK_mosaic_avg(i,j)+ALBBCK_mosaic(i,mosaic_i,j)*FAREA
EMISS_mosaic_avg(i,j)=EMISS_mosaic_avg(i,j)+EMISS_mosaic(i,mosaic_i,j)*FAREA
EMBCK_mosaic_avg(i,j)=EMBCK_mosaic_avg(i,j)+EMBCK_mosaic(i,mosaic_i,j)*FAREA
ZNT_mosaic_avg(i,j)=ZNT_mosaic_avg(i,j)+ALOG(ZNT_mosaic(i,mosaic_i,j))*FAREA
Z0_mosaic_avg(i,j)=Z0_mosaic_avg(i,j)+ALOG(Z0_mosaic(i,mosaic_i,j))*FAREA
ENDDO ! ENDDO FOR mosaic_i = 1, mosaic_cat
!-----------------------------------------------------------------------
! Now let's send the 3D values to the 2D variables that might be needed in other routines
!-----------------------------------------------------------------------
IVGTYP(I,J)=IVGTYP_dominant(I,J) ! the dominant vege category
ALBEDO(i,j)=ALBEDO_mosaic_avg(i,j)
ALBBCK(i,j)=ALBBCK_mosaic_avg(i,j)
EMISS(i,j)= EMISS_mosaic_avg(i,j)
EMBCK(i,j)= EMBCK_mosaic_avg(i,j)
ZNT(i,j)= EXP(ZNT_mosaic_avg(i,j)/FAREA_mosaic_avg(i,j))
Z0(i,j)= EXP(Z0_mosaic_avg(i,j)/FAREA_mosaic_avg(i,j))
TSK(i,j)=(TSK_mosaic_avg(I,J)/EMISS_mosaic_avg(I,J))**(0.25) ! from 3D to 2D
QSFC(i,j)=QSFC_mosaic_avg(I,J)
CANWAT(i,j) = CANWAT_mosaic_avg(i,j)
SNOW(i,j) = SNOW_mosaic_avg(i,j)
SNOWH(i,j) = SNOWH_mosaic_avg(i,j)
SNOWC(i,j) = SNOWC_mosaic_avg(i,j)
HFX(i,j) = HFX_mosaic_avg(i,j)
QFX(i,j) = QFX_mosaic_avg(i,j)
LH(i,j) = LH_mosaic_avg(i,j)
GRDFLX(i,j)=GRDFLX_mosaic_avg(i,j)
DO NS=1,NSOIL
TSLB(i,NS,j)=TSLB_mosaic_avg(i,NS,j)
SMOIS(i,NS,j)=SMOIS_mosaic_avg(i,NS,j)
SH2O(i,NS,j)=SH2O_mosaic_avg(i,NS,j)
ENDDO
ELSE ! This corresponds to IF ((sf_surface_mosaic == 1) .AND. ((XLAND(I,J)-1.5).LT.0.) .AND. (XICE(I,J) < XICE_THRESHOLD) ) THEN
! 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
! Land-ice or land points use the usual deep-soil temperature.
TBOT=TMN(I,J)
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 NS=1,NSOIL
SMC(NS)=SMOIS(I,NS,J)
STC(NS)=TSLB(I,NS,J) !STEMP
SWC(NS)=SH2O(I,NS,J)
ENDDO
!
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) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) 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) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
VEGTYP = ISURBAN
ENDIF
ENDIF
!===Yang, 2014/10/08, hydrological processes for urban vegetation in single layer UCM===
AOASIS = 1.0
USOIL = 1
DSOIL = 2
IRIOPTION=IRI_SCHEME
OMG= OMG_URB2D(I,J)
tloc=mod(int(OMG/3.14159*180./15.+12.+0.5 ),24)
if (tloc.lt.0) tloc=tloc+24
if (tloc==0) tloc=24
CALL cal_mon_day(julian,julyr,jmonth,jday)
IF(SF_URBAN_PHYSICS == 1) THEN
IF( IVGTYP(I,J) == ISURBAN .or. IVGTYP(I,J) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) THEN
AOASIS = oasis ! urban oasis effect
IF (IRIOPTION ==1) THEN
IF (tloc==21 .or. tloc==22) THEN !irrigation on vegetaion in urban area, MAY-SEP, 9-10pm
IF (jmonth==5 .or. jmonth==6 .or. jmonth==7 .or. jmonth==8 .or. jmonth==9) THEN
IF (SMC(USOIL) .LT. SMCREF) SMC(USOIL)= REFSMC(ISLTYP(I,J))
IF (SMC(DSOIL) .LT. SMCREF) SMC(DSOIL)= REFSMC(ISLTYP(I,J))
ENDIF
ENDIF
ENDIF
ENDIF
ENDIF
IF(SF_URBAN_PHYSICS == 2 .or. SF_URBAN_PHYSICS == 3) THEN
IF(AOASIS > 1.0) THEN
CALL wrf_error_fatal('Urban oasis option is for SF_URBAN_PHYSICS == 1 only')
ENDIF
IF(IRIOPTION == 1) THEN
CALL wrf_error_fatal('Urban irrigation option is for SF_URBAN_PHYSICS == 1 only')
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
IF ( ICE == 1 ) THEN
! Sea-ice case
DO NS = 1, NSOIL
SH2O(I,NS,J) = 1.0
ENDDO
LAI(I,J) = 0.01
CYCLE ILOOP
ELSEIF (ICE == 0) THEN
! Non-glacial land
CALL SFLX (I,J,FFROZP, 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
FLX4,FVB,FBUR,FGSN,UA_PHYS, & !UA
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, &
sfcheadrt(i,j), & !I
INFXSRT(i,j),ETPND1,OPT_THCND,AOASIS & !O
,XSDA_QFX, HFX_PHY, QFX_PHY, XQNORM, fasdas, HCPCT_FASDAS & ! fasdas vars
)
#ifdef WRF_HYDRO
soldrain(i,j) = RUNOFF2*DT*1000.0
#endif
ELSEIF (ICE == -1) THEN
!
! Set values that the LSM is expected to update,
! but don't get updated for glacial points.
!
SOILM = 0.0 !BSINGH(PNNL)- SOILM is undefined for this case, it is used for diagnostics so setting it to zero
XLAI = 0.01 ! KWM Should this be Zero over land ice? Does this value matter?
RUNOFF2 = 0.0
RUNOFF3 = 0.0
DO NS = 1, NSOIL
SWC(NS) = 1.0
SMC(NS) = 1.0
SMAV(NS) = 1.0
ENDDO
CALL SFLX_GLACIAL(I,J,ISICE,FFROZP,DT,ZLVL,NSOIL,SLDPTH, & !C
& LWDN,SOLNET,SFCPRS,PRCP,SFCTMP,Q2K, & !F
& TH2,Q2SAT,DQSDT2, & !I
& ALBBRD, SNOALB1,TBOT, Z0BRD, Z0K, EMISSI, EMBRD, & !S
& T1,STC(1:NSOIL),SNOWHK,SNEQV,ALBEDOK,CHK, & !H
& ETA,SHEAT,ETA_KINEMATIC,FDOWN, & !O
& ESNOW,DEW, & !O
& ETP,SSOIL, & !O
& FLX1,FLX2,FLX3, & !O
& SNOMLT,SNCOVR, & !O
& RUNOFF1, & !O
& Q1, & !D
& SNOTIME1, &
& RIBB)
ENDIF
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
#ifdef WRF_HYDRO
!added by Wei Yu
! QFX(I,J) = QFX(I,J) + ETPND1
! ETA = ETA + ETPND1/2.501E6*dt
!end added by Wei Yu
#endif
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
FLX4_2D(I,J) = FLX4
FVB_2D(I,J) = FVB
FBUR_2D(I,J) = FBUR
FGSN_2D(I,J) = FGSN
!
! Residual of surface energy balance equation terms
!
IF ( UA_PHYS ) THEN
noahres(i,j) = ( solnet + lwdn ) - sheat + ssoil - eta &
- ( emissi * STBOLT * (t1**4) ) - flx1 - flx2 - flx3 - flx4
ELSE
noahres(i,j) = ( solnet + lwdn ) - sheat + ssoil - eta &
- ( emissi * STBOLT * (t1**4) ) - flx1 - flx2 - flx3
ENDIF
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) == LOW_DENSITY_RESIDENTIAL .or. &
IVGTYP(I,J) == HIGH_DENSITY_RESIDENTIAL .or. IVGTYP(I,J) == HIGH_INTENSITY_INDUSTRIAL) 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)
SMR_URB(K) = SMR_URB3D(I,K,J)
TGRL_URB(K)= TGRL_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
TGR_URB = TGR_URB2D(I,J)
CMCR_URB = CMCR_URB2D(I,J)
FLXHUMR_URB = FLXHUMR_URB2D(I,J)
FLXHUMB_URB = FLXHUMB_URB2D(I,J)
FLXHUMG_URB = FLXHUMG_URB2D(I,J)
DRELR_URB = DRELR_URB2D(I,J)
DRELB_URB = DRELB_URB2D(I,J)
DRELG_URB = DRELG_URB2D(I,J)
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)
CMGR_URB = CMGR_SFCDIF(I,J)
CHGR_URB = CHGR_SFCDIF(I,J)
CMC_URB = CMC_SFCDIF(I,J)
CHC_URB = CHC_SFCDIF(I,J)
ENDIF
! NUDAPT for SLUCM
mh_urb = mh_urb2d(I,J)
stdh_urb = stdh_urb2d(I,J)
lp_urb = lp_urb2d(I,J)
hgt_urb = hgt_urb2d(I,J)
lf_urb = 0.0
DO K = 1,4
lf_urb(K)=lf_urb2d(I,K,J)
ENDDO
frc_urb = frc_urb2d(I,J)
lb_urb = lb_urb2d(I,J)
check = 0
if (I.eq.73.and.J.eq.125)THEN
check = 1
end if
!
! Call urban
CALL cal_mon_day(julian,julyr,jmonth,jday)
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,mh_urb, stdh_urb, lf_urb, lp_urb, & ! 0
hgt_urb,frc_urb,lb_urb, check,CMCR_URB,TGR_URB, & ! H
TGRL_URB,SMR_URB,CMGR_URB,CHGR_URB,jmonth, & ! H
DRELR_URB,DRELB_URB, & ! H
DRELG_URB,FLXHUMR_URB,FLXHUMB_URB,FLXHUMG_URB)
#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)
SMR_URB3D(I,K,J) = SMR_URB(K)
TGRL_URB3D(I,K,J)= TGRL_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
TGR_URB2D(I,J) =TGR_URB
CMCR_URB2D(I,J)=CMCR_URB
FLXHUMR_URB2D(I,J)=FLXHUMR_URB
FLXHUMB_URB2D(I,J)=FLXHUMB_URB
FLXHUMG_URB2D(I,J)=FLXHUMG_URB
DRELR_URB2D(I,J) = DRELR_URB
DRELB_URB2D(I,J) = DRELB_URB
DRELG_URB2D(I,J) = DRELG_URB
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
CMGR_SFCDIF(I,J) = CMGR_URB
CHGR_SFCDIF(I,J) = CHGR_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
ENDIF ! ENDIF FOR MOSAIC DANLI ! This corresponds to IF ((sf_surface_mosaic == 1) .AND. ((XLAND(I,J)-1.5).LT.0.) .AND. (XICE(I,J) < XICE_THRESHOLD) ) THEN
ENDDO ILOOP ! of I loop
ENDDO JLOOP ! of J loop
!------------------------------------------------------
END SUBROUTINE lsm_mosaic
!------------------------------------------------------
!===========================================================================
!
! subroutine lsm_mosaic_init: initialization of mosaic state variables
!
!===========================================================================
SUBROUTINE lsm_mosaic_init(IVGTYP,ISWATER,ISURBAN,ISICE, XLAND, XICE,fractional_seaice, & 1,24
TSK,TSLB,SMOIS,SH2O,SNOW,SNOWC,SNOWH,CANWAT, &
ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte, restart, &
landusef,landusef2,NLCAT,num_soil_layers &
,sf_surface_mosaic, mosaic_cat &
,mosaic_cat_index &
,TSK_mosaic,TSLB_mosaic &
,SMOIS_mosaic,SH2O_mosaic &
,CANWAT_mosaic,SNOW_mosaic &
,SNOWH_mosaic,SNOWC_mosaic &
,ALBEDO,ALBBCK, EMISS, EMBCK,Z0 & !danli
,ALBEDO_mosaic,ALBBCK_mosaic, EMISS_mosaic & !danli
,EMBCK_mosaic, ZNT_mosaic, Z0_mosaic & !danli
,TR_URB2D_mosaic,TB_URB2D_mosaic & !danli mosaic
,TG_URB2D_mosaic,TC_URB2D_mosaic & !danli mosaic
,QC_URB2D_mosaic & !danli mosaic
,TRL_URB3D_mosaic,TBL_URB3D_mosaic & !danli mosaic
,TGL_URB3D_mosaic & !danli mosaic
,SH_URB2D_mosaic,LH_URB2D_mosaic & !danli mosaic
,G_URB2D_mosaic,RN_URB2D_mosaic & !danli mosaic
,TS_URB2D_mosaic & !danli mosaic
,TS_RUL2D_mosaic & !danli mosaic
)
INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte
INTEGER, INTENT(IN) :: NLCAT, num_soil_layers, ISWATER,ISURBAN, ISICE, fractional_seaice
LOGICAL , INTENT(IN) :: restart
! REAL, DIMENSION( num_soil_layers), INTENT(INOUT) :: ZS, DZS
REAL, DIMENSION( ims:ime, num_soil_layers, jms:jme ) , &
INTENT(IN) :: SMOIS, & !Total soil moisture
SH2O, & !liquid soil moisture
TSLB !STEMP
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(IN) :: SNOW, &
SNOWH, &
SNOWC, &
CANWAT, &
TSK, XICE, XLAND
INTEGER, INTENT(IN) :: sf_surface_mosaic
INTEGER, INTENT(IN) :: mosaic_cat
INTEGER, DIMENSION( ims:ime, jms:jme ),INTENT(IN) :: IVGTYP
REAL, DIMENSION( ims:ime, NLCAT, jms:jme ) , INTENT(IN):: LANDUSEF
REAL, DIMENSION( ims:ime, NLCAT, jms:jme ) , INTENT(INOUT):: LANDUSEF2
INTEGER, DIMENSION( ims:ime, NLCAT, jms:jme ), INTENT(INOUT) :: mosaic_cat_index
REAL, DIMENSION( ims:ime, 1:mosaic_cat, jms:jme ) , OPTIONAL, INTENT(INOUT):: &
TSK_mosaic, CANWAT_mosaic, SNOW_mosaic,SNOWH_mosaic, SNOWC_mosaic
REAL, DIMENSION( ims:ime, 1:num_soil_layers*mosaic_cat, jms:jme ), OPTIONAL, INTENT(INOUT):: &
TSLB_mosaic,SMOIS_mosaic,SH2O_mosaic
REAL, DIMENSION( ims:ime, jms:jme ) , INTENT(IN):: ALBEDO, ALBBCK, EMISS, EMBCK, Z0
REAL, DIMENSION( ims:ime, 1:mosaic_cat, jms:jme ) , OPTIONAL, INTENT(INOUT):: &
ALBEDO_mosaic,ALBBCK_mosaic, EMISS_mosaic, EMBCK_mosaic, ZNT_mosaic, Z0_mosaic
REAL, DIMENSION( ims:ime, 1:mosaic_cat, jms:jme ) , OPTIONAL, INTENT(INOUT):: &
TR_URB2D_mosaic, TB_URB2D_mosaic, TG_URB2D_mosaic, TC_URB2D_mosaic,QC_URB2D_mosaic, &
SH_URB2D_mosaic,LH_URB2D_mosaic,G_URB2D_mosaic,RN_URB2D_mosaic,TS_URB2D_mosaic, TS_RUL2D_mosaic
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_soil_layers*mosaic_cat, jms:jme ), INTENT(INOUT) :: TRL_URB3D_mosaic
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_soil_layers*mosaic_cat, jms:jme ), INTENT(INOUT) :: TBL_URB3D_mosaic
REAL, OPTIONAL, DIMENSION( ims:ime, 1:num_soil_layers*mosaic_cat, jms:jme ), INTENT(INOUT) :: TGL_URB3D_mosaic
INTEGER :: ij,i,j,mosaic_i,LastSwap,NumPairs,soil_k, Temp2,Temp5,Temp7, ICE,temp_index
REAL :: Temp, Temp3,Temp4,Temp6,xice_threshold
LOGICAL :: IPRINT
CHARACTER(len=256) :: message_text
IPRINT=.false.
if ( fractional_seaice == 0 ) then
xice_threshold = 0.5
else if ( fractional_seaice == 1 ) then
xice_threshold = 0.02
endif
IF(.not.restart)THEN
!===========================================================================
! CHOOSE THE TILES
!===========================================================================
itf=min0(ite,ide-1)
jtf=min0(jte,jde-1)
! simple test
DO i = its,itf
DO j = jts,jtf
IF ((xland(i,j).LT. 1.5 ) .AND. (IVGTYP(i,j) .EQ. ISWATER)) THEN
PRINT*, 'BEFORE MOSAIC_INIT'
CALL wrf_message("BEFORE MOSAIC_INIT")
WRITE(message_text,fmt='(a,2I6,2F8.2,2I6)') 'I,J,xland,xice,mosaic_cat_index,ivgtyp = ', &
I,J,xland(i,j),xice(i,j),mosaic_cat_index(I,1,J),IVGTYP(i,j)
CALL wrf_message(message_text)
ENDIF
ENDDO
ENDDO
DO i = its,itf
DO j = jts,jtf
DO mosaic_i=1,NLCAT
LANDUSEF2(i,mosaic_i,j)=LANDUSEF(i,mosaic_i,j)
mosaic_cat_index(i,mosaic_i,j)=mosaic_i
ENDDO
ENDDO
ENDDO
DO i = its,itf
DO j = jts,jtf
NumPairs=NLCAT-1
DO
IF (NumPairs == 0) EXIT
LastSwap = 1
DO mosaic_i=1, NumPairs
IF(LANDUSEF2(i,mosaic_i, j) < LANDUSEF2(i,mosaic_i+1, j) ) THEN
Temp = LANDUSEF2(i,mosaic_i, j)
LANDUSEF2(i,mosaic_i, j)=LANDUSEF2(i,mosaic_i+1, j)
LANDUSEF2(i,mosaic_i+1, j)=Temp
LastSwap = mosaic_i
Temp2 = mosaic_cat_index(i,mosaic_i,j)
mosaic_cat_index(i,mosaic_i,j)=mosaic_cat_index(i,mosaic_i+1,j)
mosaic_cat_index(i,mosaic_i+1,j)=Temp2
ENDIF
ENDDO
NumPairs = LastSwap - 1
ENDDO
ENDDO
ENDDO
!===========================================================================
! For non-seaice grids, eliminate the seaice-tiles
!===========================================================================
DO i = its,itf
DO j = jts,jtf
IF (XLAND(I,J).LT.1.5) THEN
ICE = 0
IF( XICE(I,J).GE. XICE_THRESHOLD ) THEN
WRITE (message_text,fmt='(a,2I5)') 'sea-ice at point, I and J = ', i,j
CALL wrf_message(message_text)
ICE = 1
ENDIF
IF (ICE == 1) Then ! sea-ice case , eliminate sea-ice if they are not the dominant ones
IF (IVGTYP(i,j) == isice) THEN ! if this grid cell is dominanted by ice, then do nothing
ELSE
DO mosaic_i=2,mosaic_cat
IF (mosaic_cat_index(i,mosaic_i,j) == isice ) THEN
Temp4=LANDUSEF2(i,mosaic_i,j)
Temp5=mosaic_cat_index(i,mosaic_i,j)
LANDUSEF2(i,mosaic_i:NLCAT-1,j)=LANDUSEF2(i,mosaic_i+1:NLCAT,j)
mosaic_cat_index(i,mosaic_i:NLCAT-1,j)=mosaic_cat_index(i,mosaic_i+1:NLCAT,j)
LANDUSEF2(i,NLCAT,j)=Temp4
mosaic_cat_index(i,NLCAT,j)=Temp5
ENDIF
ENDDO
ENDIF ! for (IVGTYP(i,j) == isice )
ELSEIF (ICE ==0) THEN
IF ((mosaic_cat_index(I,1,J) .EQ. ISWATER)) THEN
! xland < 1.5 but the dominant land use category based on our calculation is water
IF (IVGTYP(i,j) .EQ. ISWATER) THEN
! xland < 1.5 but the dominant land use category based on the geogrid calculation is water, this must be wrong
CALL wrf_message("IN MOSAIC_INIT")
WRITE(message_text,fmt='(a,3I6,2F8.2)') 'I,J,IVGTYP,XLAND,XICE = ',I,J,IVGTYP(I,J),xland(i,j),xice(i,j)
CALL wrf_message(message_text)
CALL wrf_message("xland < 1.5 but the dominant land use category based on our calculation is water."//&
"In addition, the dominant land use category based on the geogrid calculation is water, this must be wrong")
ENDIF ! for (IVGTYP(i,j) .EQ. ISWATER)
IF (IVGTYP(i,j) .NE. ISWATER) THEN
! xland < 1.5, the dominant land use category based on our calculation is water, but based on the geogrid calculation is not water, which might be due to the inconsistence between land use data and land-sea mask
Temp4=LANDUSEF2(i,1,j)
Temp5=mosaic_cat_index(i,1,j)
LANDUSEF2(i,1:NLCAT-1,j)=LANDUSEF2(i,2:NLCAT,j)
mosaic_cat_index(i,1:NLCAT-1,j)=mosaic_cat_index(i,2:NLCAT,j)
LANDUSEF2(i,NLCAT,j)=Temp4
mosaic_cat_index(i,NLCAT,j)=Temp5
CALL wrf_message("IN MOSAIC_INIT")
WRITE(message_text,fmt='(a,3I6,2F8.2)') 'I,J,IVGTYP,XLAND,XICE = ',I,J,IVGTYP(I,J),xland(i,j),xice(i,j)
CALL wrf_message(message_text)
CALL wrf_message("xland < 1.5 but the dominant land use category based on our calculation is water."//&
"this is fine as long as we change our calculation so that the dominant land use category is"//&
"stwiched back to not water.")
WRITE(message_text,fmt='(a,2I6)') 'land use category has been switched, before and after values are ', &
temp5,mosaic_cat_index(i,1,j)
CALL wrf_message(message_text)
WRITE(message_text,fmt='(a,2I6)') 'new dominant and second dominant cat are ', mosaic_cat_index(i,1,j),mosaic_cat_index(i,2,j)
CALL wrf_message(message_text)
ENDIF ! for (IVGTYP(i,j) .NE. ISWATER)
ELSE ! for (mosaic_cat_index(I,1,J) .EQ. ISWATER)
DO mosaic_i=2,mosaic_cat
IF (mosaic_cat_index(i,mosaic_i,j) == iswater ) THEN
Temp4=LANDUSEF2(i,mosaic_i,j)
Temp5=mosaic_cat_index(i,mosaic_i,j)
LANDUSEF2(i,mosaic_i:NLCAT-1,j)=LANDUSEF2(i,mosaic_i+1:NLCAT,j)
mosaic_cat_index(i,mosaic_i:NLCAT-1,j)=mosaic_cat_index(i,mosaic_i+1:NLCAT,j)
LANDUSEF2(i,NLCAT,j)=Temp4
mosaic_cat_index(i,NLCAT,j)=Temp5
ENDIF
ENDDO
ENDIF ! for (mosaic_cat_index(I,1,J) .EQ. ISWATER)
ENDIF ! for ICE == 1
ELSE ! FOR (XLAND(I,J).LT.1.5)
ICE = 0
IF( XICE(I,J).GE. XICE_THRESHOLD ) THEN
WRITE (message_text,fmt='(a,2I6)') 'sea-ice at water point, I and J = ', i,j
CALL wrf_message(message_text)
ICE = 1
ENDIF
IF ((mosaic_cat_index(I,1,J) .NE. ISWATER)) THEN
! xland > 1.5 and the dominant land use category based on our calculation is not water
IF (IVGTYP(i,j) .NE. ISWATER) THEN
! xland > 1.5 but the dominant land use category based on the geogrid calculation is not water, this must be wrong
CALL wrf_message("IN MOSAIC_INIT")
WRITE(message_text,fmt='(a,3I6,2F8.2)') 'I,J,IVGTYP,XLAND,XICE = ',I,J,IVGTYP(I,J),xland(i,j),xice(i,j)
CALL wrf_message(message_text)
CALL wrf_message("xland > 1.5 but the dominant land use category based on our calculation is not water."// &
"in addition, the dominant land use category based on the geogrid calculation is not water,"// &
"this must be wrong.")
ENDIF ! for (IVGTYP(i,j) .NE. ISWATER)
IF (IVGTYP(i,j) .EQ. ISWATER) THEN
! xland > 1.5, the dominant land use category based on our calculation is not water, but based on the geogrid calculation is water, which might be due to the inconsistence between land use data and land-sea mask
CALL wrf_message("IN MOSAIC_INIT")
WRITE(message_text,fmt='(a,3I6,2F8.2)') 'I,J,IVGTYP,XLAND,XICE = ',I,J,IVGTYP(I,J),xland(i,j),xice(i,j)
CALL wrf_message(message_text)
CALL wrf_message("xland > 1.5 but the dominant land use category based on our calculation is not water."// &
"however, the dominant land use category based on the geogrid calculation is water")
CALL wrf_message("This is fine. We do not need to do anyting because in the noaddrv, "//&
"we use xland as a criterion for whether using"// &
"mosaic or not when xland > 1.5, no mosaic will be used anyway")
ENDIF ! for (IVGTYP(i,j) .NE. ISWATER)
ENDIF ! for (mosaic_cat_index(I,1,J) .NE. ISWATER)
ENDIF ! FOR (XLAND(I,J).LT.1.5)
ENDDO
ENDDO
!===========================================================================
! normalize
!===========================================================================
DO i = its,itf
DO j = jts,jtf
Temp6=0
DO mosaic_i=1,mosaic_cat
Temp6=Temp6+LANDUSEF2(i,mosaic_i,j)
ENDDO
if (Temp6 .LT. 1e-5) then
Temp6 = 1e-5
WRITE (message_text,fmt='(a,e8.1)') 'the total land surface fraction is less than ', temp6
CALL wrf_message(message_text)
WRITE (message_text,fmt='(a,2I6,4F8.2)') 'some landusef values at i,j are ', &
i,j,landusef2(i,1,j),landusef2(i,2,j),landusef2(i,3,j),landusef2(i,4,j)
CALL wrf_message(message_text)
WRITE (message_text,fmt='(a,2I6,3I6)') 'some mosaic cat values at i,j are ', &
i,j,mosaic_cat_index(i,1,j),mosaic_cat_index(i,2,j),mosaic_cat_index(i,3,j)
CALL wrf_message(message_text)
endif
LANDUSEF2(i,1:mosaic_cat, j)=LANDUSEF2(i,1:mosaic_cat,j)*(1/Temp6)
ENDDO
ENDDO
!===========================================================================
! initilize the variables
!===========================================================================
DO i = its,itf
DO j = jts,jtf
DO mosaic_i=1,mosaic_cat
TSK_mosaic(i,mosaic_i,j)=TSK(i,j)
CANWAT_mosaic(i,mosaic_i,j)=CANWAT(i,j)
SNOW_mosaic(i,mosaic_i,j)=SNOW(i,j)
SNOWH_mosaic(i,mosaic_i,j)=SNOWH(i,j)
SNOWC_mosaic(i,mosaic_i,j)=SNOWC(i,j)
ALBEDO_mosaic(i,mosaic_i,j)=ALBEDO(i,j)
ALBBCK_mosaic(i,mosaic_i,j)=ALBBCK(i,j)
EMISS_mosaic(i,mosaic_i,j)=EMISS(i,j)
EMBCK_mosaic(i,mosaic_i,j)=EMBCK(i,j)
ZNT_mosaic(i,mosaic_i,j)=Z0(i,j)
Z0_mosaic(i,mosaic_i,j)=Z0(i,j)
DO soil_k=1,num_soil_layers
TSLB_mosaic(i,num_soil_layers*(mosaic_i-1)+soil_k,j)=TSLB(i,soil_k,j)
SMOIS_mosaic(i,num_soil_layers*(mosaic_i-1)+soil_k,j)=SMOIS(i,soil_k,j)
SH2O_mosaic(i,num_soil_layers*(mosaic_i-1)+soil_k,j)=SH2O(i,soil_k,j)
ENDDO
TR_URB2D_mosaic(i,mosaic_i,j)=TSK(i,j)
TB_URB2D_mosaic(i,mosaic_i,j)=TSK(i,j)
TG_URB2D_mosaic(i,mosaic_i,j)=TSK(i,j)
TC_URB2D_mosaic(i,mosaic_i,j)=TSK(i,j)
TS_URB2D_mosaic(i,mosaic_i,j)=TSK(i,j)
TS_RUL2D_mosaic(i,mosaic_i,j)=TSK(i,j)
QC_URB2D_mosaic(i,mosaic_i,j)=0.01
SH_URB2D_mosaic(i,mosaic_i,j)=0
LH_URB2D_mosaic(i,mosaic_i,j)=0
G_URB2D_mosaic(i,mosaic_i,j)=0
RN_URB2D_mosaic(i,mosaic_i,j)=0
TRL_URB3D_mosaic(I,4*(mosaic_i-1)+1,J)=TSLB(I,1,J)+0.
TRL_URB3D_mosaic(I,4*(mosaic_i-1)+2,J)=0.5*(TSLB(I,1,J)+TSLB(I,2,J))
TRL_URB3D_mosaic(I,4*(mosaic_i-1)+3,J)=TSLB(I,2,J)+0.
TRL_URB3D_mosaic(I,4*(mosaic_i-1)+4,J)=TSLB(I,2,J)+(TSLB(I,3,J)-TSLB(I,2,J))*0.29
TBL_URB3D_mosaic(I,4*(mosaic_i-1)+1,J)=TSLB(I,1,J)+0.
TBL_URB3D_mosaic(I,4*(mosaic_i-1)+2,J)=0.5*(TSLB(I,1,J)+TSLB(I,2,J))
TBL_URB3D_mosaic(I,4*(mosaic_i-1)+3,J)=TSLB(I,2,J)+0.
TBL_URB3D_mosaic(I,4*(mosaic_i-1)+4,J)=TSLB(I,2,J)+(TSLB(I,3,J)-TSLB(I,2,J))*0.29
TGL_URB3D_mosaic(I,4*(mosaic_i-1)+1,J)=TSLB(I,1,J)
TGL_URB3D_mosaic(I,4*(mosaic_i-1)+2,J)=TSLB(I,2,J)
TGL_URB3D_mosaic(I,4*(mosaic_i-1)+3,J)=TSLB(I,3,J)
TGL_URB3D_mosaic(I,4*(mosaic_i-1)+4,J)=TSLB(I,4,J)
ENDDO
ENDDO
ENDDO
! simple test
DO i = its,itf
DO j = jts,jtf
IF ((xland(i,j).LT. 1.5 ) .AND. (mosaic_cat_index(I,1,J) .EQ. ISWATER)) THEN
CALL wrf_message("After MOSAIC_INIT")
WRITE (message_text,fmt='(a,2I6,2F8.2,2I6)') 'weird xland,xice,mosaic_cat_index and ivgtyp at I,J = ', &
i,j,xland(i,j),xice(i,j),mosaic_cat_index(I,1,J),IVGTYP(i,j)
CALL wrf_message(message_text)
ENDIF
ENDDO
ENDDO
ENDIF ! for not restart
!--------------------------------
END SUBROUTINE lsm_mosaic_init
!--------------------------------
END MODULE module_sf_noahdrv