#if (NMM_NEST == 1) !=========================================================================== ! ! E-GRID NESTING UTILITIES: This is gopal's doing ! !=========================================================================== SUBROUTINE med_nest_egrid_configure ( parent , nest ) USE module_domain USE module_configure USE module_timing IMPLICIT NONE TYPE(domain) , POINTER :: parent , nest REAL, PARAMETER :: ERAD=6371200. REAL, PARAMETER :: DTR=0.01745329 REAL, PARAMETER :: DTAD=1.0 REAL, PARAMETER :: CP=1004.6 INTEGER :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER :: IMS,IME,JMS,JME,KMS,KME INTEGER :: ITS,ITE,JTS,JTE,KTS,KTE CHARACTER(LEN=255) :: message !---------------------------------------------------------------------------- ! PURPOSE: ! - Initialize nested domain configurations including setting up ! wbd,sbd and some other variables and 1D arrays. ! - Note that in order to obtain coincident grid points, which ! is a basic requirement for RSL, WRF infrastructure, we use ! western and southern boundaries of nested domain (nest%wbd0 ! and nest%sbd0 derived from the parent domain. In this case ! the nested domain may be considered as a part of the parent ! domain with a higher resolution (telescoping ?). ! - Also note that in this case, the central lat/lons for nested ! domain should coincide with the central lat/lons of the parent, ! although the nested domain NEED NOT be located at the center of ! the domain. !---------------------------------------------------------------------------- ! ! BASIC TEST FOR PARENT DOMAIN: CHECK IF JMAX IS ODD. SINCE JDE IN THE NAMELIST ! IS JMAX + 1, WE NEED TO CHECK IF JDE IS EVEN IN WRF CONTEXT IF(MOD(parent%ed32,2) .NE. 0)THEN CALL wrf_error_fatal("PARENT DOMAIN: JMAX IS EVEN, INCREASE e_sn IN THE namelist.input BY 1") ENDIF ! BASIC TEST FOR NESTED DOMAIN: CHECK IF JMAX IS ODD. SINCE JDE IN THE NAMELIST ! IS JMAX + 1, WE NEED TO CHECK IF JDE IS EVEN IN WRF CONTEXT IF(MOD(nest%ed32,2) .NE. 0)THEN CALL wrf_error_fatal("NESTED DOMAIN: JMAX IS EVEN, INCREASE e_sn IN THE namelist.input BY 1") ENDIF ! Parent grid configuration, including, western and southern boundary IDS = parent%sd31 IDE = parent%ed31 JDS = parent%sd32 JDE = parent%ed32 KDS = parent%sd33 KDE = parent%ed33 IMS = parent%sm31 IME = parent%em31 JMS = parent%sm32 JME = parent%em32 KMS = parent%sm33 KME = parent%em33 ITS = parent%sp31 ITE = parent%ep31 JTS = parent%sp32 JTE = parent%ep32 KTS = parent%sp33 KTE = parent%ep33 ! grid configuration ! calculate wbd0 and sbd0 only for MOAD i.e. grid with parent_id == 0 if (parent%parent_id == 0 ) then ! Dusan's doing parent%wbd0 = -(IDE-2)*parent%dx ! WBD0: in degrees;factor 2 takes care of dummy last column parent%sbd0 = -((JDE-1)/2)*parent%dy ! SBD0: in degrees; note that JDE-1 should be odd end if nest%wbd0 = parent%wbd0 + (nest%i_parent_start-1)*2.*parent%dx + mod(nest%j_parent_start+1,2)*parent%dx nest%sbd0 = parent%sbd0 + (nest%j_parent_start-1)*parent%dy nest%dx = parent%dx/nest%parent_grid_ratio nest%dy = parent%dy/nest%parent_grid_ratio write(message,*)" - i_parent_start = ",nest%i_parent_start CALL wrf_message(trim(message)) write(message,*)" - j_parent_start = ",nest%j_parent_start CALL wrf_message(trim(message)) write(message,*)" - parent%wbd0 = ",parent%wbd0 CALL wrf_message(trim(message)) write(message,*)" - parent%sbd0 = ",parent%sbd0 CALL wrf_message(trim(message)) write(message,*)" - nest%wbd0 = ",nest%wbd0 CALL wrf_message(trim(message)) write(message,*)" - nest%sbd0 = ",nest%sbd0 CALL wrf_message(trim(message)) write(message,*)" - nest%dx = ",nest%dx CALL wrf_message(trim(message)) write(message,*)" - nest%dy = ",nest%dy CALL wrf_message(trim(message)) ! CALL nl_set_dx (nest%id , nest%dx) ! for output purpose CALL nl_set_dy (nest%id , nest%dy) ! for output purpose ! set lat-lons; parent set to nested domain CALL nl_get_cen_lat (parent%id, parent%cen_lat) ! cen_lat of parent set to nested domain CALL nl_get_cen_lon (parent%id, parent%cen_lon) ! cen_lon of parent set to nested domain nest%cen_lat=parent%cen_lat nest%cen_lon=parent%cen_lon ! CALL nl_set_cen_lat ( nest%id , nest%cen_lat) ! for output purpose CALL nl_set_cen_lon ( nest%id , nest%cen_lon) ! for output purpose write(message,*)" - nest%cen_lat = ",nest%cen_lat CALL wrf_message(trim(message)) write(message,*)" - nest%cen_lon = ",nest%cen_lon CALL wrf_message(trim(message)) ! soil configuration #ifdef HWRF !zhang if ( .not.nest%analysis ) then #endif nest%sldpth = parent%sldpth nest%dzsoil = parent%dzsoil nest%rtdpth = parent%rtdpth #ifdef HWRF endif #endif ! numerical set up nest%deta = parent%deta nest%aeta = parent%aeta nest%etax = parent%etax nest%dfl = parent%dfl nest%deta1 = parent%deta1 nest%aeta1 = parent%aeta1 nest%eta1 = parent%eta1 nest%deta2 = parent%deta2 nest%aeta2 = parent%aeta2 nest%eta2 = parent%eta2 nest%pdtop = parent%pdtop nest%pt = parent%pt nest%dfrlg = parent%dfrlg nest%num_soil_layers = parent%num_soil_layers nest%num_moves = parent%num_moves ! Unfortunately, some of the single value constants in used in module_initialize have ! to be defiend here instead of the usual spot in med_initialize_nest_nmm. There ! appears to be a problem in Registry and related code in this area. ! ! state logical upstrm - dyn_nmm - - - nest%dlmd = nest%dx nest%dphd = nest%dy nest%dy_nmm = erad*(nest%dphd*dtr) nest%cpgfv = -nest%dt/(48.*nest%dy_nmm) nest%en = nest%dt/( 4.*nest%dy_nmm)*dtad nest%ent = nest%dt/(16.*nest%dy_nmm)*dtad nest%f4d = -.5*nest%dt*dtad nest%f4q = -nest%dt*dtad nest%ef4t = .5*nest%dt/cp ! Other output configurations that will make grads happy CALL nl_get_truelat1 (parent%id, parent%truelat1 ) CALL nl_get_truelat2 (parent%id, parent%truelat2 ) #ifdef HWRF ! bao : to make the restart output identical at the restart initial time for stand_lon CALL nl_get_stand_lon (parent%id, parent%stand_lon ) #endif CALL nl_get_map_proj (parent%id, parent%map_proj ) CALL nl_get_iswater (parent%id, parent%iswater ) nest%truelat1=parent%truelat1 nest%truelat2=parent%truelat2 !bao nest%stand_lon=parent%stand_lon !bao nest%map_proj=parent%map_proj nest%iswater=parent%iswater CALL nl_set_truelat1(nest%id, nest%truelat1) CALL nl_set_truelat2(nest%id, nest%truelat2) !bao CALL nl_set_stand_lon(nest%id, nest%stand_lon) !bao CALL nl_set_map_proj(nest%id, nest%map_proj) CALL nl_set_iswater(nest%id, nest%iswater) ! physics and other configurations ! CALL nl_get_iswater (parent%id, nest%iswater) ! iswater is just based on parents ! CALL nl_get_bl_surface_physics (nest%id, nest%bl_surface_physics ) ! CALL nl_get_num_soil_layers( parent%num_soil_layers ) ! CALL nl_get_real_data_init_type (parent%real_data_init_type) END SUBROUTINE med_nest_egrid_configure SUBROUTINE med_construct_egrid_weights ( parent , nest ) USE module_domain USE module_configure USE module_timing IMPLICIT NONE TYPE(domain) , POINTER :: parent , nest LOGICAL, EXTERNAL :: wrf_dm_on_monitor INTEGER :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER :: IMS,IME,JMS,JME,KMS,KME INTEGER :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER :: I,J,II,JJ,NII,NJJ REAL :: parent_CLAT,parent_CLON,parent_WBD,parent_SBD,parent_DLMD,parent_DPHD REAL :: nest_WBD,nest_SBD,nest_DLMD,nest_DPHD REAL :: SW_LATD,SW_LOND REAL :: ADDSUM1,ADDSUM2 REAL :: xr,zr,xc !----------------------------------------------------------------------------------------------------------- ! PURPOSE: ! - Initialize lat-lons and determine weights ! !---------------------------------------------------------------------------------------------------------- ! First obtain central latitude and longitude for the parent domain CALL nl_get_cen_lat (parent%ID, parent_CLAT) CALL nl_get_cen_lon (parent%ID, parent_CLON) ! Parent grid configuration, including, western and southern boundary IDS = parent%sd31 IDE = parent%ed31 JDS = parent%sd32 JDE = parent%ed32 KDS = parent%sd33 KDE = parent%ed33 IMS = parent%sm31 IME = parent%em31 JMS = parent%sm32 JME = parent%em32 KMS = parent%sm33 KME = parent%em33 ITS = parent%sp31 ITE = parent%ep31 JTS = parent%sp32 JTE = parent%ep32 KTS = parent%sp33 KTE = parent%ep33 ! parent_DLMD = parent%dx ! DLMD: dlamda in degrees parent_DPHD = parent%dy ! DPHD: dphi in degrees parent_WBD = parent%wbd0 parent_SBD = parent%sbd0 ! Now compute Geodetic lat/lon (Positive East) of parent grid in degrees CALL EARTH_LATLON ( parent%HLAT,parent%HLON,parent%VLAT,parent%VLON, & !output parent_DLMD,parent_DPHD,parent_WBD,parent_SBD, & !inputs parent_CLAT,parent_CLON, & IDS,IDE,JDS,JDE,KDS,KDE, & IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! Nested grid configuration, including, western and southern boundary IDS = nest%sd31 IDE = nest%ed31 JDS = nest%sd32 JDE = nest%ed32 KDS = nest%sd33 KDE = nest%ed33 IMS = nest%sm31 IME = nest%em31 JMS = nest%sm32 JME = nest%em32 KMS = nest%sm33 KME = nest%em33 ITS = nest%sp31 ITE = nest%ep31 JTS = nest%sp32 JTE = nest%ep32 KTS = nest%sp33 KTE = nest%ep33 ! nest_DLMD = nest%dx nest_DPHD = nest%dy nest_WBD = nest%wbd0 nest_SBD = nest%sbd0 ! ! Now compute Geodetic lat/lon (Positive East) of nest in degrees, with the same central lat-lon ! as the parent grid ! CALL EARTH_LATLON ( nest%HLAT,nest%HLON,nest%VLAT,nest%VLON, & ! output nest_DLMD,nest_DPHD,nest_WBD,nest_SBD, & ! nest inputs parent_CLAT,parent_CLON, & ! parent central lat/lon IDS,IDE,JDS,JDE,KDS,KDE, & ! nested domain dimension IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! Determine the weights of nested grid h points nearest to H points of parent domain #ifdef HWRFX CALL G2T2H_new( nest%IIH,nest%JJH, & ! output grid index in parent grid nest%HBWGT1,nest%HBWGT2, & ! output weights in terms of parent grid nest%HBWGT3,nest%HBWGT4, & nest%I_PARENT_START,nest%J_PARENT_START, & ! nest start I, J in parent domain 3, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) #else CALL G2T2H( nest%IIH,nest%JJH, & ! output grid index on nested grid nest%HBWGT1,nest%HBWGT2, & ! output weights on the nested grid nest%HBWGT3,nest%HBWGT4, & nest%HLAT,nest%HLON, & ! target (nest) input lat lon in degrees parent_DLMD,parent_DPHD,parent_WBD,parent_SBD, & ! parent res, western and south boundaries parent_CLAT,parent_CLON, & ! parent central lat,lon, all in degrees parent%ed31,parent%ed32, & ! parent imax and jmax IDS,IDE,JDS,JDE,KDS,KDE, & ! IMS,IME,JMS,JME,KMS,KME, & ! nested grid configuration ITS,ITE,JTS,JTE,KTS,KTE ) ! #endif ! Determine the weights of nested grid v points nearest to V points of parent domain #ifdef HWRFX CALL G2T2V_new( nest%IIV,nest%JJV, & ! output grid index in parent grid nest%VBWGT1,nest%VBWGT2, & ! output weights in terms of parent grid nest%VBWGT3,nest%VBWGT4, & nest%I_PARENT_START,nest%J_PARENT_START, & ! nest start I, J in parent domain 3, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) #else CALL G2T2V( nest%IIV,nest%JJV, & ! output grid index on nested grid nest%VBWGT1,nest%VBWGT2, & ! output weights on the nested grid nest%VBWGT3,nest%VBWGT4, & nest%VLAT,nest%VLON, & ! target (nest) input lat lon in degrees parent_DLMD,parent_DPHD,parent_WBD,parent_SBD, & ! parent res, western and south boundaries parent_CLAT,parent_CLON, & ! parent central lat,lon, all in degrees parent%ed31,parent%ed32, & ! parent imax and jmax IDS,IDE,JDS,JDE,KDS,KDE, & ! IMS,IME,JMS,JME,KMS,KME, & ! nested grid configuration ITS,ITE,JTS,JTE,KTS,KTE ) ! #endif !*** CHECK WEIGHTS AT MASS AND VELOCITY POINTS CALL WEIGTS_CHECK(nest%HBWGT1,nest%HBWGT2, & ! output weights on the nested grid nest%HBWGT3,nest%HBWGT4, & nest%VBWGT1,nest%VBWGT2, & ! output weights on the nested grid nest%VBWGT3,nest%VBWGT4, & IDS,IDE,JDS,JDE,KDS,KDE, & ! IMS,IME,JMS,JME,KMS,KME, & ! nested grid configuration ITS,ITE,JTS,JTE,KTS,KTE ) !*** CHECK DOMAIN BOUNDS BEFORE PROCEEDING TO INTERPOLATION ! CALL BOUNDS_CHECK( nest%IIH,nest%JJH,nest%IIV,nest%JJV, & nest%i_parent_start,nest%j_parent_start,nest%shw, & IDS,IDE,JDS,JDE,KDS,KDE, & ! IMS,IME,JMS,JME,KMS,KME, & ! nested grid configuration ITS,ITE,JTS,JTE,KTS,KTE ) !------------------------------------------------------------------------------------------ END SUBROUTINE med_construct_egrid_weights !====================================================================================== ! ! compute earth lat-lons for parent and the nest before interpolations !------------------------------------------------------------------------------ SUBROUTINE EARTH_LATLON ( HLAT,HLON,VLAT,VLON, & !Earth lat,lon at H and V points DLMD1,DPHD1,WBD1,SBD1, & !input res,west & south boundaries, CENTRAL_LAT,CENTRAL_LON, & ! central lat,lon, all in degrees IDS,IDE,JDS,JDE,KDS,KDE, & IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) !============================================================================ ! IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE REAL, INTENT(IN ) :: DLMD1,DPHD1,WBD1,SBD1 REAL, INTENT(IN ) :: CENTRAL_LAT,CENTRAL_LON REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HLAT,HLON,VLAT,VLON ! local INTEGER,PARAMETER :: KNUM=SELECTED_REAL_KIND(13) INTEGER :: I,J REAL(KIND=KNUM) :: WB,SB,DLM,DPH,TPH0,STPH0,CTPH0 REAL(KIND=KNUM) :: TDLM,TDPH,TLMH,TLMV,TLMH0,TLMV0,TPHH,TPHV,DTR REAL(KIND=KNUM) :: STPH,CTPH,STPV,CTPV,PI_2 REAL(KIND=KNUM) :: SPHH,CLMH,FACTH,SPHV,CLMV,FACTV REAL(KIND=KNUM), DIMENSION(IMS:IME,JMS:JME) :: GLATH,GLONH,GLATV,GLONV !------------------------------------------------------------------------- ! PI_2 = ACOS(0.) DTR = PI_2/90. WB = WBD1 * DTR ! WB: western boundary in radians SB = SBD1 * DTR ! SB: southern boundary in radians DLM = DLMD1 * DTR ! DLM: dlamda in radians DPH = DPHD1 * DTR ! DPH: dphi in radians TDLM = DLM + DLM ! TDLM: 2.0*dlamda TDPH = DPH + DPH ! TDPH: 2.0*DPH ! For earth lat lon only TPH0 = CENTRAL_LAT*DTR ! TPH0: central lat in radians STPH0 = SIN(TPH0) CTPH0 = COS(TPH0) ! .H DO J = JTS,MIN(JTE,JDE-1) ! H./ This loop takes care of zig-zag ! ! \.H starting points along j TLMH0 = WB - TDLM + MOD(J+1,2) * DLM ! ./ TLMH (rotated lats at H points) TLMV0 = WB - TDLM + MOD(J,2) * DLM ! H (//ly for V points) TPHH = SB + (J-1)*DPH ! TPHH (rotated lons at H points) are simple trans. TPHV = TPHH ! TPHV (rotated lons at V points) are simple trans. STPH = SIN(TPHH) CTPH = COS(TPHH) STPV = SIN(TPHV) CTPV = COS(TPHV) ! .H DO I = ITS,MIN(ITE,IDE-1) ! / TLMH = TLMH0 + I*TDLM ! \.H .U .H ! !H./ ----><---- SPHH = CTPH0 * STPH + STPH0 * CTPH * COS(TLMH) ! DLM + DLM GLATH(I,J)=ASIN(SPHH) ! GLATH: Earth Lat in radians CLMH = CTPH*COS(TLMH)/(COS(GLATH(I,J))*CTPH0) & - TAN(GLATH(I,J))*TAN(TPH0) IF(CLMH .GT. 1.) CLMH = 1.0 IF(CLMH .LT. -1.) CLMH = -1.0 FACTH = 1. IF(TLMH .GT. 0.) FACTH = -1. GLONH(I,J) = -CENTRAL_LON*DTR + FACTH*ACOS(CLMH) ENDDO DO I = ITS,MIN(ITE,IDE-1) TLMV = TLMV0 + I*TDLM SPHV = CTPH0 * STPV + STPH0 * CTPV * COS(TLMV) GLATV(I,J) = ASIN(SPHV) CLMV = CTPV*COS(TLMV)/(COS(GLATV(I,J))*CTPH0) & - TAN(GLATV(I,J))*TAN(TPH0) IF(CLMV .GT. 1.) CLMV = 1. IF(CLMV .LT. -1.) CLMV = -1. FACTV = 1. IF(TLMV .GT. 0.) FACTV = -1. GLONV(I,J) = -CENTRAL_LON*DTR + FACTV*ACOS(CLMV) ENDDO ENDDO ! Conversion to degrees (may not be required, eventually) DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) HLAT(I,J) = GLATH(I,J) / DTR HLON(I,J)= -GLONH(I,J)/DTR IF(HLON(I,J) .GT. 180.) HLON(I,J) = HLON(I,J) - 360. IF(HLON(I,J) .LT. -180.) HLON(I,J) = HLON(I,J) + 360. ! VLAT(I,J) = GLATV(I,J) / DTR VLON(I,J) = -GLONV(I,J) / DTR IF(VLON(I,J) .GT. 180.) VLON(I,J) = VLON(I,J) - 360. IF(VLON(I,J) .LT. -180.) VLON(I,J) = VLON(I,J) + 360. ENDDO ENDDO END SUBROUTINE EARTH_LATLON !----------------------------------------------------------------------------- SUBROUTINE G2T2H( IIH,JJH, & ! output grid index and weights HBWGT1,HBWGT2, & ! output weights in terms of parent grid HBWGT3,HBWGT4, & HLAT,HLON, & ! target (nest) input lat lon in degrees DLMD1,DPHD1,WBD1,SBD1, & ! parent res, west and south boundaries CENTRAL_LAT,CENTRAL_LON, & ! parent central lat,lon, all in degrees P_IDE,P_JDE, & ! parent imax and jmax IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dIMEnsions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! !*** Tom Black - Initial Version !*** Gopal - Revised Version for WRF (includes coincident grid points) !*** !*** GIVEN PARENT CENTRAL LAT-LONS, RESOLUTION AND WESTERN AND SOUTHERN BOUNDARY, !*** AND THE NESTED GRID LAT-LONS AT H POINTS, THIS ROUTINE FIRST LOCATES THE !*** INDICES,IIH,JJH, OF THE PARENT DOMAIN'S H POINTS THAT LIES CLOSEST TO THE !*** h POINTS OF THE NESTED DOMAIN ! !============================================================================ ! IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: P_IDE,P_JDE REAL, INTENT(IN ) :: DLMD1,DPHD1,WBD1,SBD1 REAL, INTENT(IN ) :: CENTRAL_LAT,CENTRAL_LON REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(IN) :: HLAT,HLON REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH ! local INTEGER,PARAMETER :: KNUM=SELECTED_REAL_KIND(13) INTEGER :: IMT,JMT,N2R,MK,K,I,J,DSLP0,DSLOPE INTEGER :: NROW,NCOL,KROWS REAL(KIND=KNUM) :: X,Y,Z,TLAT,TLON REAL(KIND=KNUM) :: PI_2,D2R,R2D,GLAT,GLON,DPH,DLM,TPH0,TLM0,WB,SB REAL(KIND=KNUM) :: ROW,COL,SLP0,TLATHC,TLONHC,DENOM,SLOPE REAL(KIND=KNUM) :: TLAT1,TLAT2,TLON1,TLON2,DLM1,DLM2,DLM3,DLM4,D1,D2 REAL(KIND=KNUM) :: DLA1,DLA2,DLA3,DLA4,S1,R1,DS1,AN1,AN2,AN3 ! Q REAL(KIND=KNUM) :: DL1,DL2,DL3,DL4,DL1I,DL2I,DL3I,DL4I,SUMDL,TLONO,TLATO REAL(KIND=KNUM) :: DTEMP REAL , DIMENSION(IMS:IME,JMS:JME) :: TLATHX,TLONHX INTEGER, DIMENSION(IMS:IME,JMS:JME) :: KOUTB !------------------------------------------------------------------------------- IMT=2*P_IDE-2 ! parent i dIMEnsions JMT=P_JDE/2 ! parent j dIMEnsions PI_2=ACOS(0.) D2R=PI_2/90. R2D=1./D2R DPH=DPHD1*D2R DLM=DLMD1*D2R TPH0= CENTRAL_LAT*D2R TLM0=-CENTRAL_LON*D2R ! NOTE THE MINUS HERE WB=WBD1*D2R ! CONVERT NESTED GRID H POINTS FROM GEODETIC SB=SBD1*D2R SLP0=DPHD1/DLMD1 DSLP0=NINT(R2D*ATAN(SLP0)) DS1=SQRT(DPH*DPH+DLM*DLM) ! Q AN1=ASIN(DLM/DS1) AN2=ASIN(DPH/DS1) DO J = JTS,MIN(JTE,JDE-1) DO I = ITS,MIN(ITE,IDE-1) !*** !*** LOCATE TARGET h POINTS (HLAT AND HLON) ON THE PARENT DOMAIN AND !*** DETERMINE THE INDICES IN TERMS OF THE PARENT DOMAIN. FIRST !*** CONVERT NESTED GRID h POINTS FROM GEODETIC TO TRANSFORMED !*** COORDINATE ON THE PARENT GRID ! GLAT=HLAT(I,J)*D2R GLON= (360. - HLON(I,J))*D2R X=COS(TPH0)*COS(GLAT)*COS(GLON-TLM0)+SIN(TPH0)*SIN(GLAT) Y=-COS(GLAT)*SIN(GLON-TLM0) Z=COS(TPH0)*SIN(GLAT)-SIN(TPH0)*COS(GLAT)*COS(GLON-TLM0) TLAT=R2D*ATAN(Z/SQRT(X*X+Y*Y)) TLON=R2D*ATAN(Y/X) ! ROW=TLAT/DPHD1+JMT ! JMT IS THE CENTRAL ROW OF THE PARENT DOMAIN ! COL=TLON/DLMD1+P_IDE-1 ! (P_IDE-1) IS THE CENTRAL COLUMN OF THE PARENT DOMAIN ROW=(TLAT-SBD1)/DPHD1+1 ! Dusan's doing COL=(TLON-WBD1)/DLMD1+1 ! Dusan's doing NROW=INT(ROW + 0.001) ! ROUND-OFF IS AVOIDED WITHOUT USING NINT ON PURPOSE NCOL=INT(COL + 0.001) TLAT=TLAT*D2R TLON=TLON*D2R !*** !*** !*** FIRST CONSIDER THE SITUATION WHERE THE POINT h IS AT !*** !*** V H !*** !*** !*** H !*** H V !*** !*** THEN LOCATE THE NEAREST H POINT ON THE PARENT GRID !*** IF(MOD(NROW,2).EQ.1.AND.MOD(NCOL,2).EQ.1.OR. & MOD(NROW,2).EQ.0.AND.MOD(NCOL,2).EQ.0)THEN TLAT1=(NROW-JMT)*DPH TLAT2=TLAT1+DPH TLON1=(NCOL-(P_IDE-1))*DLM TLON2=TLON1+DLM DLM1=TLON-TLON1 DLM2=TLON-TLON2 ! D1=ACOS(COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) ! D2=ACOS(COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) D1=ACOS(DTEMP) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) D2=ACOS(DTEMP) IF(D1.GT.D2)THEN NROW=NROW+1 ! FIND THE NEAREST H ROW NCOL=NCOL+1 ! FIND THE NEAREST H COLUMN ENDIF ELSE !*** !*** NOW CONSIDER THE SITUATION WHERE THE POINT h IS AT !*** !*** H V !*** !*** !*** H !*** V H !*** !*** THEN LOCATE THE NEAREST H POINT ON THE PARENT GRID !*** !*** TLAT1=(NROW+1-JMT)*DPH TLAT2=TLAT1-DPH TLON1=(NCOL-(P_IDE-1))*DLM TLON2=TLON1+DLM DLM1=TLON-TLON1 DLM2=TLON-TLON2 ! D1=ACOS(COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) ! D2=ACOS(COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) D1=ACOS(DTEMP) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) D2=ACOS(DTEMP) IF(D1.LT.D2)THEN NROW=NROW+1 ! FIND THE NEAREST H ROW ELSE NCOL=NCOL+1 ! FIND THE NEAREST H COLUMN ENDIF ENDIF KROWS=((NROW-1)/2)*IMT IF(MOD(NROW,2).EQ.1)THEN K=KROWS+(NCOL+1)/2 ELSE K=KROWS+P_IDE-1+NCOL/2 ENDIF !*** !*** WE NOW KNOW THAT THE INNER GRID POINT IN QUESTION IS !*** NEAREST TO THE CENTER K AS SEEN BELOW. WE MUST FIND !*** WHICH OF THE FOUR H-BOXES (OF WHICH THIS H POINT IS !*** A VERTEX) SURROUNDS THE INNER GRID h POINT IN QUESTION. !*** !** !*** H !*** !*** !*** !*** H V H !*** !*** !*** H !*** H V H V H !*** !*** !*** !*** H V H !*** !*** !*** !*** H !*** !*** !*** FIND THE SLOPE OF THE LINE CONNECTING h AND THE CENTER H. !*** N2R=K/IMT MK=MOD(K,IMT) ! IF(MK.EQ.0)THEN TLATHC=SB+(2*N2R-1)*DPH ELSE TLATHC=SB+(2*N2R+(MK-1)/(P_IDE-1))*DPH ENDIF ! IF(MK.LE.(P_IDE-1))THEN TLONHC=WB+2*(MK-1)*DLM ELSE TLONHC=WB+(2*(MK-(P_IDE-1))-1)*DLM ENDIF ! !*** EXECUTE CAUTION IF YOU NEED TO CHANGE THESE CONDITIONS. SINCE WE ARE !*** DEALING WITH SLOPES TO GENERATE DIAMOND SHAPE H BOXES, WE NEED TO BE !*** CAREFUL HERE ! IF(ABS(TLON-TLONHC) .LE. 1.E-4)TLONHC=TLON IF(ABS(TLAT-TLATHC) .LE. 1.E-4)TLATHC=TLAT DENOM=(TLON-TLONHC) ! !*** !***STORE THE LOCATION OF THE WESTERNMOST VERTEX OF THE H-BOX ON !***THE OUTER GRID THAT SURROUNDS THE h POINT ON THE INNER GRID. !*** !*** COINCIDENT CONDITIONS IF(DENOM.EQ.0.0)THEN IF(TLATHC.EQ.TLAT)THEN KOUTB(I,J)=K IIH(I,J) = NCOL JJH(I,J) = NROW TLATHX(I,J)=TLATHC TLONHX(I,J)=TLONHC HBWGT1(I,J)=1.0 HBWGT2(I,J)=0.0 HBWGT3(I,J)=0.0 HBWGT4(I,J)=0.0 ELSE ! SAME LONGITUDE BUT DIFFERENT LATS ! IF(TLATHC .GT. TLAT)THEN ! NESTED POINT SOUTH OF PARENT KOUTB(I,J)=K-(P_IDE-1) IIH(I,J) = NCOL-1 JJH(I,J) = NROW-1 TLATHX(I,J)=TLATHC-DPH TLONHX(I,J)=TLONHC-DLM ELSE ! NESTED POINT NORTH OF PARENT KOUTB(I,J)=K+(P_IDE-1)-1 IIH(I,J) = NCOL-1 JJH(I,J) = NROW+1 TLATHX(I,J)=TLATHC+DPH TLONHX(I,J)=TLONHC-DLM ENDIF !*** !*** !*** 4 !*** !*** H !*** 1 2 !*** !*** 3 !*** DL 1-4 ARE THE ANGULAR DISTANCES FROM h TO EACH VERTEX TLATO=TLATHX(I,J) TLONO=TLONHX(I,J) DLM1=TLON-TLONO DLA1=TLAT-TLATO ! Q ! DL1=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM1)+SIN(TLAT)*SIN(TLATO)) ! Q DL1=SQRT(DLM1*DLM1+DLA1*DLA1) ! Q ! TLATO=TLATHX(I,J) TLONO=TLONHX(I,J)+2.*DLM DLM2=TLON-TLONO DLA2=TLAT-TLATO ! Q ! DL2=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM2)+SIN(TLAT)*SIN(TLATO)) ! Q DL2=SQRT(DLM2*DLM2+DLA2*DLA2) ! Q ! TLATO=TLATHX(I,J)-DPH TLONO=TLONHX(I,J)+DLM DLM3=TLON-TLONO DLA3=TLAT-TLATO ! Q ! DL3=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM3)+SIN(TLAT)*SIN(TLATO)) ! Q DL3=SQRT(DLM3*DLM3+DLA3*DLA3) ! Q TLATO=TLATHX(I,J)+DPH TLONO=TLONHX(I,J)+DLM DLM4=TLON-TLONO DLA4=TLAT-TLATO ! Q ! DL4=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM4)+SIN(TLAT)*SIN(TLATO)) ! Q DL4=SQRT(DLM4*DLM4+DLA4*DLA4) ! Q ! THE BILINEAR WEIGHTS !*** !*** AN3=ATAN2(DLA1,DLM1) ! Q R1=DL1*SIN(AN2-AN3)/SIN(2.*AN1) S1=DL1*SIN(2.*PI_2-2*AN1-AN2+AN3)/SIN(2.*AN1) R1=R1/DS1 S1=S1/DS1 DL1I=(1.-R1)*(1.-S1) DL2I=R1*S1 DL3I=R1*(1.-S1) DL4I=(1.-R1)*S1 ! HBWGT1(I,J)=DL1I HBWGT2(I,J)=DL2I HBWGT3(I,J)=DL3I HBWGT4(I,J)=DL4I ! ENDIF ELSE ! !*** NON-COINCIDENT POINTS ! SLOPE=(TLAT-TLATHC)/DENOM DSLOPE=NINT(R2D*ATAN(SLOPE)) IF(DSLOPE.LE.DSLP0.AND.DSLOPE.GE.-DSLP0)THEN IF(TLON.GT.TLONHC)THEN IF(TLONHC.GE.-WB-DLM)CALL wrf_error_fatal("1H:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K IIH(I,J) = NCOL JJH(I,J) = NROW TLATHX(I,J)=TLATHC TLONHX(I,J)=TLONHC ELSE IF(TLONHC.LE.WB+DLM)CALL wrf_error_fatal("2H:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K-1 IIH(I,J) = NCOL-2 JJH(I,J) = NROW TLATHX(I,J)=TLATHC TLONHX(I,J)=TLONHC -2.*DLM ENDIF ! ELSEIF(DSLOPE.GT.DSLP0)THEN IF(TLON.GT.TLONHC)THEN IF(TLATHC.GE.-SB-DPH)CALL wrf_error_fatal("3H:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K+(P_IDE-1)-1 IIH(I,J) = NCOL-1 JJH(I,J) = NROW+1 TLATHX(I,J)=TLATHC+DPH TLONHX(I,J)=TLONHC-DLM ELSE IF(TLATHC.LE.SB+DPH)CALL wrf_error_fatal("4H:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K-(P_IDE-1) IIH(I,J) = NCOL-1 JJH(I,J) = NROW-1 TLATHX(I,J)=TLATHC-DPH TLONHX(I,J)=TLONHC-DLM ENDIF ! ELSEIF(DSLOPE.LT.-DSLP0)THEN IF(TLON.GT.TLONHC)THEN IF(TLATHC.LE.SB+DPH)CALL wrf_error_fatal("5H:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K-(P_IDE-1) IIH(I,J) = NCOL-1 JJH(I,J) = NROW-1 TLATHX(I,J)=TLATHC-DPH TLONHX(I,J)=TLONHC-DLM ELSE IF(TLATHC.GE.-SB-DPH)CALL wrf_error_fatal("6H:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K+(P_IDE-1)-1 IIH(I,J) = NCOL-1 JJH(I,J) = NROW+1 TLATHX(I,J)=TLATHC+DPH TLONHX(I,J)=TLONHC-DLM ENDIF ENDIF ! !*** NOW WE WILL MOVE AS FOLLOWS: !*** !*** !*** 4 !*** !*** !*** !*** H !*** 1 2 !*** !*** !*** !*** !*** 3 !*** !*** !*** !*** DL 1-4 ARE THE ANGULAR DISTANCES FROM h TO EACH VERTEX TLATO=TLATHX(I,J) TLONO=TLONHX(I,J) DLM1=TLON-TLONO DLA1=TLAT-TLATO ! Q ! DL1=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM1)+SIN(TLAT)*SIN(TLATO)) ! Q DL1=SQRT(DLM1*DLM1+DLA1*DLA1) ! Q ! TLATO=TLATHX(I,J) ! redundant computations TLONO=TLONHX(I,J)+2.*DLM DLM2=TLON-TLONO DLA2=TLAT-TLATO ! Q ! DL2=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM2)+SIN(TLAT)*SIN(TLATO)) ! Q DL2=SQRT(DLM2*DLM2+DLA2*DLA2) ! Q ! TLATO=TLATHX(I,J)-DPH TLONO=TLONHX(I,J)+DLM DLM3=TLON-TLONO DLA3=TLAT-TLATO ! Q ! DL3=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM3)+SIN(TLAT)*SIN(TLATO)) ! Q DL3=SQRT(DLM3*DLM3+DLA3*DLA3) ! Q ! TLATO=TLATHX(I,J)+DPH TLONO=TLONHX(I,J)+DLM DLM4=TLON-TLONO DLA4=TLAT-TLATO ! Q ! DL4=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM4)+SIN(TLAT)*SIN(TLATO)) ! Q DL4=SQRT(DLM4*DLM4+DLA4*DLA4) ! Q ! THE BILINEAR WEIGHTS !*** AN3=ATAN2(DLA1,DLM1) ! Q R1=DL1*SIN(AN2-AN3)/SIN(2.*AN1) S1=DL1*SIN(2.*PI_2-2*AN1-AN2+AN3)/SIN(2.*AN1) R1=R1/DS1 S1=S1/DS1 DL1I=(1.-R1)*(1.-S1) DL2I=R1*S1 DL3I=R1*(1.-S1) DL4I=(1.-R1)*S1 ! HBWGT1(I,J)=DL1I HBWGT2(I,J)=DL2I HBWGT3(I,J)=DL3I HBWGT4(I,J)=DL4I ! ENDIF ! !*** FINALLY STORE IIH IN TERMS OF E-GRID INDEX ! IIH(I,J)=NINT(0.5*IIH(I,J)) HBWGT1(I,J)=MAX(HBWGT1(I,J),0.0) ! all weights must be GE zero (postive def) HBWGT2(I,J)=MAX(HBWGT2(I,J),0.0) ! all weights must be GE zero (postive def) HBWGT3(I,J)=MAX(HBWGT3(I,J),0.0) ! all weights must be GE zero (postive def) HBWGT4(I,J)=MAX(HBWGT4(I,J),0.0) ! all weights must be GE zero (postive def) ! write(message,105)"H WEIGHTS:",I,J,HBWGT1(I,J),HBWGT2(I,J),HBWGT3(I,J),HBWGT4(I,J), & ! HBWGT1(I,J)+HBWGT2(I,J)+HBWGT3(I,J)+HBWGT4(I,J),IIH(i,j),JJH(i,j) ! CALL wrf_message(trim(message)) ! 105 format(a,2i4,5f7.3,2i4) ENDDO ENDDO RETURN END SUBROUTINE G2T2H !======================================================================================== SUBROUTINE G2T2V( IIV,JJV, & ! output grid index and weights VBWGT1,VBWGT2, & ! output weights in terms of parent grid VBWGT3,VBWGT4, & VLAT,VLON, & ! target (nest) input lat lon in degrees DLMD1,DPHD1,WBD1,SBD1, & ! parent res, west and south boundaries CENTRAL_LAT,CENTRAL_LON, & ! parent central lat,lon, all in degrees P_IDE,P_JDE, & ! parent imax and jmax IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dIMEnsions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! !*** Tom Black - Initial Version !*** Gopal - Revised Version for WRF (includes coincIDEnt grid points) !*** !*** GIVEN PARENT CENTRAL LAT-LONS, RESOLUTION AND WESTERN AND SOUTHERN BOUNDARY, !*** AND THE NESTED GRID LAT-LONS AT V POINTS, THIS ROUTINE FIRST LOCATES THE !*** INDICES,IIV,JJV, OF THE PARENT DOMAIN'S V POINTS THAT LIES CLOSEST TO THE !*** V POINTS OF THE NESTED DOMAIN ! !============================================================================ IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: P_IDE,P_JDE REAL, INTENT(IN ) :: DLMD1,DPHD1,WBD1,SBD1 REAL, INTENT(IN ) :: CENTRAL_LAT,CENTRAL_LON REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(IN) :: VLAT,VLON REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV ! local INTEGER,PARAMETER :: KNUM=SELECTED_REAL_KIND(13) ! (6) single precision INTEGER :: IMT,JMT,N2R,MK,K,I,J,DSLP0,DSLOPE INTEGER :: NROW,NCOL,KROWS REAL(KIND=KNUM) :: X,Y,Z,TLAT,TLON REAL(KIND=KNUM) :: PI_2,D2R,R2D,GLAT,GLON,DPH,DLM,TPH0,TLM0,WB,SB REAL(KIND=KNUM) :: ROW,COL,SLP0,TLATVC,TLONVC,DENOM,SLOPE REAL(KIND=KNUM) :: TLAT1,TLAT2,TLON1,TLON2,DLM1,DLM2,DLM3,DLM4,D1,D2 REAL(KIND=KNUM) :: DLA1,DLA2,DLA3,DLA4,S1,R1,DS1,AN1,AN2,AN3 ! Q REAL(KIND=KNUM) :: DL1,DL2,DL3,DL4,DL1I,DL2I,DL3I,DL4I,SUMDL,TLONO,TLATO REAL(KIND=KNUM) :: DTEMP REAL , DIMENSION(IMS:IME,JMS:JME) :: TLATVX,TLONVX INTEGER, DIMENSION(IMS:IME,JMS:JME) :: KOUTB !------------------------------------------------------------------------------------- IMT=2*P_IDE-2 ! parent i dIMEnsions JMT=P_JDE/2 ! parent j dIMEnsions PI_2=ACOS(0.) D2R=PI_2/90. R2D=1./D2R DPH=DPHD1*D2R DLM=DLMD1*D2R TPH0= CENTRAL_LAT*D2R TLM0=-CENTRAL_LON*D2R ! NOTE THE MINUS HERE WB=WBD1*D2R ! DEGREES TO RADIANS SB=SBD1*D2R SLP0=DPHD1/DLMD1 DSLP0=NINT(R2D*ATAN(SLP0)) DS1=SQRT(DPH*DPH+DLM*DLM) ! Q AN1=ASIN(DLM/DS1) AN2=ASIN(DPH/DS1) DO J = JTS,MIN(JTE,JDE-1) DO I = ITS,MIN(ITE,IDE-1) !*** !*** LOCATE TARGET V POINTS (VLAT AND VLON) ON THE PARENT DOMAIN AND !*** DETERMINE THE INDICES IN TERMS OF THE PARENT DOMAIN. FIRST !*** CONVERT NESTED GRID V POINTS FROM GEODETIC TO TRANSFORMED !*** COORDINATE ON THE PARENT GRID ! GLAT=VLAT(I,J)*D2R GLON=(360. - VLON(I,J))*D2R X=COS(TPH0)*COS(GLAT)*COS(GLON-TLM0)+SIN(TPH0)*SIN(GLAT) Y=-COS(GLAT)*SIN(GLON-TLM0) Z=COS(TPH0)*SIN(GLAT)-SIN(TPH0)*COS(GLAT)*COS(GLON-TLM0) TLAT=R2D*ATAN(Z/SQRT(X*X+Y*Y)) TLON=R2D*ATAN(Y/X) ! ROW=TLAT/DPHD1+JMT ! JMT IS THE CENTRAL ROW OF THE PARENT DOMAIN ! COL=TLON/DLMD1+P_IDE-1 ! (P_IDE-1) IS THE CENTRAL COLUMN OF THE PARENT DOMAIN ROW=(TLAT-SBD1)/DPHD1+1 ! Dusan's doing COL=(TLON-WBD1)/DLMD1+1 ! Dusan's doing NROW=INT(ROW + 0.001) ! ROUND-OFF IS AVOIDED WITHOUT USING NINT ON PURPOSE NCOL=INT(COL + 0.001) TLAT=TLAT*D2R TLON=TLON*D2R !*** !*** !*** FIRST CONSIDER THE SITUATION WHERE THE POINT V IS AT !*** !*** H V !*** !*** !*** V !*** V H !*** !*** THEN LOCATE THE NEAREST V POINT ON THE PARENT GRID !*** IF(MOD(NROW,2).EQ.0.AND.MOD(NCOL,2).EQ.1.OR. & MOD(NROW,2).EQ.1.AND.MOD(NCOL,2).EQ.0)THEN TLAT1=(NROW-JMT)*DPH TLAT2=TLAT1+DPH TLON1=(NCOL-(P_IDE-1))*DLM TLON2=TLON1+DLM DLM1=TLON-TLON1 DLM2=TLON-TLON2 ! D1=ACOS(COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) ! D2=ACOS(COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) D1=ACOS(DTEMP) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) D2=ACOS(DTEMP) IF(D1.GT.D2)THEN NROW=NROW+1 ! FIND THE NEAREST V ROW NCOL=NCOL+1 ! FIND THE NEAREST V COLUMN ENDIF ELSE !*** !*** NOW CONSIDER THE SITUATION WHERE THE POINT V IS AT !*** !*** V H !*** !*** !*** V !*** H V !*** !*** THEN LOCATE THE NEAREST V POINT ON THE PARENT GRID !*** TLAT1=(NROW+1-JMT)*DPH TLAT2=TLAT1-DPH TLON1=(NCOL-(P_IDE-1))*DLM TLON2=TLON1+DLM DLM1=TLON-TLON1 DLM2=TLON-TLON2 ! D1=ACOS(COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) ! D2=ACOS(COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT1)*COS(DLM1)+SIN(TLAT)*SIN(TLAT1)) D1=ACOS(DTEMP) DTEMP=MIN(1.0_KNUM,COS(TLAT)*COS(TLAT2)*COS(DLM2)+SIN(TLAT)*SIN(TLAT2)) D2=ACOS(DTEMP) IF(D1.LT.D2)THEN NROW=NROW+1 ! FIND THE NEAREST H ROW ELSE NCOL=NCOL+1 ! FIND THE NEAREST H COLUMN ENDIF ENDIF KROWS=((NROW-1)/2)*IMT IF(MOD(NROW,2).EQ.1)THEN K=KROWS+NCOL/2 ELSE K=KROWS+P_IDE-2+(NCOL+1)/2 ! check this one should this not be P_IDE-2 ???? ENDIF !*** !*** WE NOW KNOW THAT THE INNER GRID POINT IN QUESTION IS !*** NEAREST TO THE CENTER K AS SEEN BELOW. WE MUST FIND !*** WHICH OF THE FOUR v-BOXES (OF WHICH THIS V POINT IS !*** A VERTEX) SURROUNDS THE INNER GRID V POINT IN QUESTION. !*** !*** !*** V !*** !*** !*** !*** V H V !*** !*** !*** V !*** V H V H V !*** !*** !*** !*** V H V !*** !*** !*** !*** V !*** !*** !*** FIND THE SLOPE OF THE LINE CONNECTING V AND THE CENTER v. !*** N2R=K/IMT MK=MOD(K,IMT) ! IF(MK.EQ.0)THEN TLATVC=SB+(2*N2R-1)*DPH ELSE TLATVC=SB+(2*N2R+MK/(P_IDE-1))*DPH ENDIF ! IF(MK.LE.(P_IDE-1)-1)THEN TLONVC=WB+(2*MK-1)*DLM ELSE TLONVC=WB+2*(MK-(P_IDE-1))*DLM ENDIF ! !*** EXECUTE CAUTION IF YOU NEED TO CHANGE THESE CONDITIONS. SINCE WE ARE !*** DEALING WITH SLOPES TO GENERATE DIAMOND SHAPE V BOXES, WE NEED TO BE !*** CAREFUL HERE ! IF(ABS(TLON-TLONVC) .LE. 1.E-4)TLONVC=TLON IF(ABS(TLAT-TLATVC) .LE. 1.E-4)TLATVC=TLAT DENOM=(TLON-TLONVC) ! !*** !***STORE THE LOCATION OF THE WESTERNMOST VERTEX OF THE H-BOX ON !***THE OUTER GRID THAT SURROUNDS THE h POINT ON THE INNER GRID. !*** !*** COINCIDENT CONDITIONS IF(DENOM.EQ.0.0)THEN IF(TLATVC.EQ.TLAT)THEN KOUTB(I,J)=K IIV(I,J) = NCOL JJV(I,J) = NROW TLATVX(I,J)=TLATVC TLONVX(I,J)=TLONVC VBWGT1(I,J)=1.0 VBWGT2(I,J)=0.0 VBWGT3(I,J)=0.0 VBWGT4(I,J)=0.0 ELSE ! SAME LONGITUDE BUT DIFFERENT LATS IF(TLATVC .GT. TLAT)THEN ! NESTED POINT SOUTH OF PARENT KOUTB(I,J)=K-(P_IDE-1) IIV(I,J) = NCOL-1 JJV(I,J) = NROW-1 TLATVX(I,J)=TLATVC-DPH TLONVX(I,J)=TLONVC-DLM ELSE ! NESTED POINT NORTH OF PARENT KOUTB(I,J)=K+(P_IDE-1)-1 IIV(I,J) = NCOL-1 JJV(I,J) = NROW+1 TLATVX(I,J)=TLATVC+DPH TLONVX(I,J)=TLONVC-DLM ENDIF !*** !*** !*** 4 !*** !*** V !*** 1 2 !*** !*** 3 !*** DL 1-4 ARE THE ANGULAR DISTANCES FROM h TO EACH VERTEX TLATO=TLATVX(I,J) TLONO=TLONVX(I,J) DLM1=TLON-TLONO DLA1=TLAT-TLATO ! Q ! DL1=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM1)+SIN(TLAT)*SIN(TLATO)) ! Q DL1=SQRT(DLM1*DLM1+DLA1*DLA1) ! Q ! TLATO=TLATVX(I,J) TLONO=TLONVX(I,J)+2.*DLM DLM2=TLON-TLONO DLA2=TLAT-TLATO ! Q ! DL2=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM2)+SIN(TLAT)*SIN(TLATO)) ! Q DL2=SQRT(DLM2*DLM2+DLA2*DLA2) ! Q TLATO=TLATVX(I,J)-DPH TLONO=TLONVX(I,J)+DLM DLM3=TLON-TLONO DLA3=TLAT-TLATO ! Q ! DL3=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM3)+SIN(TLAT)*SIN(TLATO)) ! Q DL3=SQRT(DLM3*DLM3+DLA3*DLA3) ! Q TLATO=TLATVX(I,J)+DPH TLONO=TLONVX(I,J)+DLM DLM4=TLON-TLONO DLA4=TLAT-TLATO ! Q ! DL4=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM4)+SIN(TLAT)*SIN(TLATO)) ! Q DL4=SQRT(DLM4*DLM4+DLA4*DLA4) ! Q ! THE BILINEAR WEIGHTS !*** AN3=ATAN2(DLA1,DLM1) ! Q R1=DL1*SIN(AN2-AN3)/SIN(2.*AN1) S1=DL1*SIN(2.*PI_2-2*AN1-AN2+AN3)/SIN(2.*AN1) R1=R1/DS1 S1=S1/DS1 DL1I=(1.-R1)*(1.-S1) DL2I=R1*S1 DL3I=R1*(1.-S1) DL4I=(1.-R1)*S1 ! VBWGT1(I,J)=DL1I VBWGT2(I,J)=DL2I VBWGT3(I,J)=DL3I VBWGT4(I,J)=DL4I ENDIF ELSE ! !*** NON-COINCIDENT POINTS ! SLOPE=(TLAT-TLATVC)/DENOM DSLOPE=NINT(R2D*ATAN(SLOPE)) IF(DSLOPE.LE.DSLP0.AND.DSLOPE.GE.-DSLP0)THEN IF(TLON.GT.TLONVC)THEN IF(TLONVC.GE.-WB-DLM)CALL wrf_error_fatal("1V:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K IIV(I,J)=NCOL JJV(I,J)=NROW TLATVX(I,J)=TLATVC TLONVX(I,J)=TLONVC ELSE IF(TLONVC.LE.WB+DLM)CALL wrf_error_fatal("2V:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K-1 IIV(I,J) = NCOL-2 JJV(I,J) = NROW TLATVX(I,J)=TLATVC TLONVX(I,J)=TLONVC-2.*DLM ENDIF ELSEIF(DSLOPE.GT.DSLP0)THEN IF(TLON.GT.TLONVC)THEN IF(TLATVC.GE.-SB-DPH)CALL wrf_error_fatal("3V:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K+(P_IDE-1)-1 IIV(I,J) = NCOL-1 JJV(I,J) = NROW+1 TLATVX(I,J)=TLATVC+DPH TLONVX(I,J)=TLONVC-DLM ELSE IF(TLATVC.LE.SB+DPH)CALL wrf_error_fatal("4V:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K-(P_IDE-1) IIV(I,J) = NCOL-1 JJV(I,J) = NROW-1 TLATVX(I,J)=TLATVC-DPH TLONVX(I,J)=TLONVC-DLM ENDIF ELSEIF(DSLOPE.LT.-DSLP0)THEN IF(TLON.GT.TLONVC)THEN IF(TLATVC.LE.SB+DPH)CALL wrf_error_fatal("5V:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K-(P_IDE-1) IIV(I,J) = NCOL-1 JJV(I,J) = NROW-1 TLATVX(I,J)=TLATVC-DPH TLONVX(I,J)=TLONVC-DLM ELSE IF(TLATVC.GE.-SB-DPH)CALL wrf_error_fatal("6V:NESTED DOMAIN TOO CLOSE TO THE BOUNDARY OF PARENT") KOUTB(I,J)=K+(P_IDE-1)-1 IIV(I,J) = NCOL-1 JJV(I,J) = NROW+1 TLATVX(I,J)=TLATVC+DPH TLONVX(I,J)=TLONVC-DLM ENDIF ENDIF ! !*** NOW WE WILL MOVE AS FOLLOWS: !*** !*** !*** 4 !*** !*** !*** !*** V !*** 1 2 !*** !*** !*** !*** !*** 3 !*** !*** !*** !*** DL 1-4 ARE THE ANGULAR DISTANCES FROM V TO EACH VERTEX TLATO=TLATVX(I,J) TLONO=TLONVX(I,J) DLM1=TLON-TLONO DLA1=TLAT-TLATO ! Q ! DL1=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM1)+SIN(TLAT)*SIN(TLATO)) ! Q DL1=SQRT(DLM1*DLM1+DLA1*DLA1) ! Q ! TLATO=TLATVX(I,J) TLONO=TLONVX(I,J)+2.*DLM DLM2=TLON-TLONO DLA2=TLAT-TLATO ! Q ! DL2=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM2)+SIN(TLAT)*SIN(TLATO)) ! Q DL2=SQRT(DLM2*DLM2+DLA2*DLA2) ! Q ! TLATO=TLATVX(I,J)-DPH TLONO=TLONVX(I,J)+DLM DLM3=TLON-TLONO DLA3=TLAT-TLATO ! Q ! DL3=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM3)+SIN(TLAT)*SIN(TLATO)) ! Q DL3=SQRT(DLM3*DLM3+DLA3*DLA3) ! Q ! TLATO=TLATVX(I,J)+DPH TLONO=TLONVX(I,J)+DLM DLM4=TLON-TLONO DLA4=TLAT-TLATO ! Q ! DL4=ACOS(COS(TLAT)*COS(TLATO)*COS(DLM4)+SIN(TLAT)*SIN(TLATO)) ! Q DL4=SQRT(DLM4*DLM4+DLA4*DLA4) ! Q ! THE BILINEAR WEIGHTS !*** AN3=ATAN2(DLA1,DLM1) ! Q R1=DL1*SIN(AN2-AN3)/SIN(2.*AN1) S1=DL1*SIN(2.*PI_2-2*AN1-AN2+AN3)/SIN(2.*AN1) R1=R1/DS1 S1=S1/DS1 DL1I=(1.-R1)*(1.-S1) DL2I=R1*S1 DL3I=R1*(1.-S1) DL4I=(1.-R1)*S1 ! VBWGT1(I,J)=DL1I VBWGT2(I,J)=DL2I VBWGT3(I,J)=DL3I VBWGT4(I,J)=DL4I ENDIF ! !*** FINALLY STORE IIH IN TERMS OF E-GRID INDEX ! IIV(I,J)=NINT(0.5*IIV(I,J)) VBWGT1(I,J)=MAX(VBWGT1(I,J),0.0) ! all weights must be GE zero (postive def) VBWGT2(I,J)=MAX(VBWGT2(I,J),0.0) ! all weights must be GE zero (postive def) VBWGT3(I,J)=MAX(VBWGT3(I,J),0.0) ! all weights must be GE zero (postive def) VBWGT4(I,J)=MAX(VBWGT4(I,J),0.0) ! all weights must be GE zero (postive def) ENDDO ENDDO RETURN END SUBROUTINE G2T2V !----------------------------------------------------------------------------- SUBROUTINE G2T2H_new( IIH,JJH, & ! output grid index and weights HBWGT1,HBWGT2, & ! output weights in terms of parent grid HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! !*** XUEJIN ZHANG --- Initial version (09/08/2008) !*** XUEJIN ZHANG --- Modified for parallel purpose (09/10/2009) !*** XUEJIN ZHANG --- Modified for parallel purpose (09/29/2009) !Function: Bilnear interpolation weight and indexing for E-grid ! IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH !LOCAL VARIABLES INTEGER :: I,J INTEGER :: JP !*** ARRANGEMENT OF 4 VERTEXES FROM PARENT DOMAIN !*** !*** 4 !*** !*** h !*** 1 2 !*** !*** !*** 3 ! !************************************************************* !*** POINT (i,j) SPANS 9 NESTED POINTS !*** A VERTEX IN THE NEST DOMAIN AND INDEXING FOR PARENT DOMAIN !*** !*** !*** H !*** !*** h h !*** / \ !*** h h h !*** / \ / \ !*** H h h H !*** \ / \ / !*** h h h !*** \ / !*** h h !*** !*** H !*** !*** !*** !************************************************************* !*** MOVING NEST ALWAYS STARTING FROM MASS GRID H !*** PLEASE REFER TO E-GRID ARRANGEMENT FIGURE FOR MASS POINTS DO J=JTS,MIN(JTE,JDE-1) DO I=ITS,MIN(ITE,IDE-1) JP = MOD(J,RATIO*2) SELECT CASE(JP) CASE ( 1 ) CALL SUB1H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 2 ) CALL SUB2H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 3 ) CALL SUB3H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 4 ) CALL SUB4H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 5 ) CALL SUB5H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 0 ) CALL SUB6H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) END SELECT write(0,105)"NEW H WEIGHTS:",I,J,IIH(i,j),JJH(i,j),HBWGT1(I,J),HBWGT2(I,J),HBWGT3(I,J),HBWGT4(I,J), & HBWGT1(I,J)+HBWGT2(I,J)+HBWGT3(I,J)+HBWGT4(I,J) 105 format(a,4i4,5f7.3) END DO END DO RETURN END SUBROUTINE G2T2H_new SUBROUTINE SUB1H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 1.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 0.0 HBWGT4(I,J) = 0.0 CASE ( 2 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 4.0/9.0 HBWGT2(I,J) = 1.0/9.0 HBWGT3(I,J) = 2.0/9.0 HBWGT4(I,J) = 2.0/9.0 CASE ( 0 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 1.0/9.0 HBWGT2(I,J) = 4.0/9.0 HBWGT3(I,J) = 2.0/9.0 HBWGT4(I,J) = 2.0/9.0 END SELECT RETURN END SUBROUTINE SUB1H SUBROUTINE SUB2H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 2.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 0.0 HBWGT4(I,J) = 1.0/3.0 CASE ( 2 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 2.0/9.0 HBWGT2(I,J) = 2.0/9.0 HBWGT3(I,J) = 1.0/9.0 HBWGT4(I,J) = 4.0/9.0 CASE ( 0 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO)+1 HBWGT1(I,J) = 1.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 2.0/3.0 HBWGT4(I,J) = 0.0 END SELECT RETURN END SUBROUTINE SUB2H SUBROUTINE SUB3H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO)-1 JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO)+1 HBWGT1(I,J) = 2.0/9.0 HBWGT2(I,J) = 2.0/9.0 HBWGT3(I,J) = 4.0/9.0 HBWGT4(I,J) = 1.0/9.0 CASE ( 2 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 1.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 0.0 HBWGT4(I,J) = 2.0/3.0 CASE ( 0 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO)+1 HBWGT1(I,J) = 2.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 1.0/3.0 HBWGT4(I,J) = 0.0 END SELECT RETURN END SUBROUTINE SUB3H SUBROUTINE SUB4H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO)-1 JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 1.0/9.0 HBWGT2(I,J) = 4.0/9.0 HBWGT3(I,J) = 2.0/9.0 HBWGT4(I,J) = 2.0/9.0 CASE ( 2 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 1.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 0.0 HBWGT4(I,J) = 0.0 CASE ( 0 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 4.0/9.0 HBWGT2(I,J) = 1.0/9.0 HBWGT3(I,J) = 2.0/9.0 HBWGT4(I,J) = 2.0/9.0 END SELECT RETURN END SUBROUTINE SUB4H SUBROUTINE SUB5H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO)-1 JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 2.0/9.0 HBWGT2(I,J) = 2.0/9.0 HBWGT3(I,J) = 1.0/9.0 HBWGT4(I,J) = 4.0/9.0 CASE ( 2 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO)+1 HBWGT1(I,J) = 1.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 2.0/3.0 HBWGT4(I,J) = 0.0 CASE ( 0 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 2.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 0.0 HBWGT4(I,J) = 1.0/3.0 END SELECT RETURN END SUBROUTINE SUB5H SUBROUTINE SUB6H(I,J,IIH,JJH,HBWGT1,HBWGT2,HBWGT3,HBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIH,JJH !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 HBWGT1(I,J) = 2.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 1.0/3.0 HBWGT4(I,J) = 0.0 CASE ( 2 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 HBWGT1(I,J) = 2.0/9.0 HBWGT2(I,J) = 2.0/9.0 HBWGT3(I,J) = 4.0/9.0 HBWGT4(I,J) = 1.0/9.0 CASE ( 0 ) IIH(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJH(I,J) = J_PARENT_START + INT((J-1)/RATIO) HBWGT1(I,J) = 1.0/3.0 HBWGT2(I,J) = 0.0 HBWGT3(I,J) = 0.0 HBWGT4(I,J) = 2.0/3.0 END SELECT RETURN END SUBROUTINE SUB6H !----------------------------------------------------------------------------- SUBROUTINE G2T2V_new( IIV,JJV, & ! output grid index and weights VBWGT1,VBWGT2, & ! output weights in terms of parent grid VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! !*** XUEJIN ZHANG --- Initial version (09/08/2008) !*** XUEJIN ZHANG --- Modified for parallel purpose (09/10/2009) !*** XUEJIN ZHANG --- Modified for parallel purpose (09/29/2009) !Function: Bilnear interpolation weight and indexing for E-grid ! IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV !LOCAL VARIABLES INTEGER :: I,J INTEGER :: JP !*** ARRANGEMENT OF 4 VERTEXES FROM PARENT DOMAIN !*** !*** 4 !*** !*** v !*** 1 2 !*** !*** !*** 3 ! !************************************************************* !*** POINT (i,j) SPANS 9 NESTED POINTS !*** A VERTEX IN THE NEST DOMAIN AND INDEXING FOR PARENT DOMAIN !*** !*** !*** V !*** !*** v h v !*** / \ !*** v h v h v !*** / \ / \ !*** V H v h v h V H !*** \ / \ / !*** v h v h v !*** \ / !*** v h v !*** !*** V !*** !*** !*** !************************************************************* !*** MOVING NEST ALWAYS STARTING FROM MASS GRID H !*** PLEASE REFER TO E-GRID ARRANGEMENT FIGURE FOR WIND POINTS DO J=JTS,MIN(JTE,JDE-1) DO I=ITS,MIN(ITE,IDE-1) JP = MOD(J,RATIO*2) SELECT CASE(JP) CASE ( 1 ) CALL SUB1V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 2 ) CALL SUB2V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 3 ) CALL SUB3V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 4 ) CALL SUB4V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 5 ) CALL SUB5V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) CASE ( 0 ) CALL SUB6V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) END SELECT ! WRITE(0,105)'NEW V WEIGHTS:',I,J,VBWGT1(I,J),VBWGT2(I,J),VBWGT3(I,J),VBWGT4(I,J), & ! VBWGT1(I,J)+VBWGT2(I,J)+VBWGT3(I,J)+VBWGT4(I,J),IIV(i,j),JJV(i,j) ! 105 format(a,2i4,5f7.3,2i4) END DO END DO RETURN END SUBROUTINE G2T2V_new SUBROUTINE SUB1V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) - 1 JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 1.0/9.0 VBWGT2(I,J) = 4.0/9.0 VBWGT3(I,J) = 2.0/9.0 VBWGT4(I,J) = 2.0/9.0 CASE ( 2 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 1.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 0.0 VBWGT4(I,J) = 0.0 CASE ( 0 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 4.0/9.0 VBWGT2(I,J) = 1.0/9.0 VBWGT3(I,J) = 2.0/9.0 VBWGT4(I,J) = 2.0/9.0 END SELECT RETURN END SUBROUTINE SUB1V SUBROUTINE SUB2V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) - 1 JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 2.0/9.0 VBWGT2(I,J) = 2.0/9.0 VBWGT3(I,J) = 1.0/9.0 VBWGT4(I,J) = 4.0/9.0 CASE ( 2 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 VBWGT1(I,J) = 1.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 2.0/3.0 VBWGT4(I,J) = 0.0 CASE ( 0 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 2.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 0.0 VBWGT4(I,J) = 1.0/3.0 END SELECT RETURN END SUBROUTINE SUB2V SUBROUTINE SUB3V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 VBWGT1(I,J) = 2.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 1.0/3.0 VBWGT4(I,J) = 0.0 CASE ( 2 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 VBWGT1(I,J) = 2.0/9.0 VBWGT2(I,J) = 2.0/9.0 VBWGT3(I,J) = 4.0/9.0 VBWGT4(I,J) = 1.0/9.0 CASE ( 0 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 1.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 0.0 VBWGT4(I,J) = 2.0/3.0 END SELECT RETURN END SUBROUTINE SUB3V SUBROUTINE SUB4V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 1.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 0.0 VBWGT4(I,J) = 0.0 CASE ( 2 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 4.0/9.0 VBWGT2(I,J) = 1.0/9.0 VBWGT3(I,J) = 2.0/9.0 VBWGT4(I,J) = 2.0/9.0 CASE ( 0 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 1.0/9.0 VBWGT2(I,J) = 4.0/9.0 VBWGT3(I,J) = 2.0/9.0 VBWGT4(I,J) = 2.0/9.0 END SELECT RETURN END SUBROUTINE SUB4V SUBROUTINE SUB5V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 2.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 0.0 VBWGT4(I,J) = 1.0/3.0 CASE ( 2 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 2.0/9.0 VBWGT2(I,J) = 2.0/9.0 VBWGT3(I,J) = 1.0/9.0 VBWGT4(I,J) = 4.0/9.0 CASE ( 0 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 VBWGT1(I,J) = 1.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 2.0/3.0 VBWGT4(I,J) = 0.0 END SELECT RETURN END SUBROUTINE SUB5V SUBROUTINE SUB6V(I,J,IIV,JJV,VBWGT1,VBWGT2,VBWGT3,VBWGT4, & I_PARENT_START,J_PARENT_START, & ! nest start I and J in parent domain RATIO, & ! Ratio of parent and child grid ( always = 3 for NMM) IDS,IDE,JDS,JDE,KDS,KDE, & ! target (nest) dimensions IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER, INTENT(IN ) :: I_PARENT_START,J_PARENT_START INTEGER, INTENT(IN ) :: RATIO REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 INTEGER, DIMENSION(IMS:IME,JMS:JME), INTENT(OUT) :: IIV,JJV !LOCAL VARIABLES INTEGER :: I,J INTEGER :: IP IP = MOD(I,RATIO) SELECT CASE(IP) CASE ( 1 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) - 1 JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 VBWGT1(I,J) = 2.0/9.0 VBWGT2(I,J) = 2.0/9.0 VBWGT3(I,J) = 4.0/9.0 VBWGT4(I,J) = 1.0/9.0 CASE ( 2 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) VBWGT1(I,J) = 1.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 0.0 VBWGT4(I,J) = 2.0/3.0 CASE ( 0 ) IIV(I,J) = I_PARENT_START + INT((I-1)/RATIO) JJV(I,J) = J_PARENT_START + INT((J-1)/RATIO) + 1 VBWGT1(I,J) = 2.0/3.0 VBWGT2(I,J) = 0.0 VBWGT3(I,J) = 1.0/3.0 VBWGT4(I,J) = 0.0 END SELECT RETURN END SUBROUTINE SUB6V !------------------------------------------------------------------------------ ! SUBROUTINE WEIGTS_CHECK(HBWGT1,HBWGT2,HBWGT3,HBWGT4, & VBWGT1,VBWGT2,VBWGT3,VBWGT4, & IDS,IDE,JDS,JDE,KDS,KDE, & IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN) :: IDS,IDE,JDS,JDE,KDS,KDE, & IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(IN) :: HBWGT1,HBWGT2,HBWGT3,HBWGT4 REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(IN) :: VBWGT1,VBWGT2,VBWGT3,VBWGT4 ! local REAL , PARAMETER :: EPSI=1.0E-3 INTEGER :: I,J REAL :: ADDSUM CHARACTER(LEN=255):: message !------------------------------------------------------------------------------------- ! DUE TO THE NEED FOR HALO EXCHANGES IN PARALLEL RUNS ONE HAS TO ENSURE CONSISTENT ! USAGE OF NUMBER OF PROCESSORS BEFORE ANY FURTHER COMPUTATIONS. WE INTRODUCE THIS ! CHECK FIRST IF((ITE-ITS) .LE. 5 .OR. (JTE-JTS) .LE. 5)THEN WRITE(message,*)'ITE-ITS=',ITE-ITS,'JTE-JTS=',JTE-JTS CALL wrf_message(trim(message)) CALL wrf_error_fatal ('NESTED DOMAIN:PLEASE OPTIMIZE THE NUMBER OF PROCESSES; TRY SQUARES OF NUMBERS') ENDIF ! ! NOW CHECK WEIGHTS ! ADDSUM=0. DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) ADDSUM=HBWGT1(I,J)+HBWGT2(I,J)+HBWGT3(I,J)+HBWGT4(I,J) IF(ABS(1.0-ADDSUM) .GE. EPSI)THEN WRITE(message,*)'I=',I,'J=',J,'WEIGHTS=',HBWGT1(I,J),HBWGT2(I,J),HBWGT3(I,J),HBWGT4(I,J),1-ADDSUM CALL wrf_message(trim(message)) CALL wrf_error_fatal ('NESTED DOMAIN:SOMETHING IS WRONG WITH WEIGHTS COMPUTATION AT MASS POINTS') ENDIF ENDDO ENDDO ADDSUM=0. DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) ADDSUM=VBWGT1(I,J)+VBWGT2(I,J)+VBWGT3(I,J)+VBWGT4(I,J) IF(ABS(1.0-ADDSUM) .GE. EPSI)THEN WRITE(message,*)'I=',I,'J=',J,'WEIGHTS=',VBWGT1(I,J),VBWGT2(I,J),VBWGT3(I,J),VBWGT4(I,J),1-ADDSUM CALL wrf_message(trim(message)) CALL wrf_error_fatal ('NESTED DOMAIN:SOMETHING IS WRONG WITH WEIGHTS COMPUTATION AT VELOCITY POINTS') ENDIF ENDDO ENDDO END SUBROUTINE WEIGTS_CHECK !----------------------------------------------------------------------------------- SUBROUTINE BOUNDS_CHECK( IIH,JJH,IIV,JJV, & IPOS,JPOS,SHW, & IDS,IDE,JDS,JDE,KDS,KDE, & ! IMS,IME,JMS,JME,KMS,KME, & ! nested grid configuration ITS,ITE,JTS,JTE,KTS,KTE ) IMPLICIT NONE INTEGER, INTENT(IN) :: IPOS,JPOS,SHW, & IDS,IDE,JDS,JDE,KDS,KDE, & IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE INTEGER, DIMENSION(IMS:IME,JMS:JME),INTENT(IN) :: IIH,JJH,IIV,JJV ! local variables INTEGER :: I,J CHARACTER(LEN=255) :: message !*** Gopal - Initial version !*** !*** CHECK DOMAIN BOUNDS BEFORE PROCEEDING TO INTERPOLATION ! !============================================================================ IF(IPOS .LE. SHW)CALL wrf_error_fatal('NESTED DOMAIN TOO CLOSE TO PARENTs X-BOUNDARY') IF(JPOS .LE. SHW)CALL wrf_error_fatal('NESTED DOMAIN TOO CLOSE TO PARENTs Y-BOUNDARY') DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) IF(IIH(I,J) .EQ. 0)CALL wrf_error_fatal ('IIH=0: SOMETHING IS WRONG') IF(JJH(I,J) .EQ. 0)CALL wrf_error_fatal ('JJH=0: SOMETHING IS WRONG') ENDDO ENDDO DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) IF(IIH(I,J) .LT. (IPOS-SHW) .OR. JJH(I,J) .LT. (JPOS-SHW) .OR. & IIV(I,J) .LT. (IPOS-SHW) .OR. JJV(I,J) .LT. (JPOS-SHW))THEN WRITE(message,*)I,J,IIH(I,J),IPOS,JJH(I,J),JPOS,SHW CALL wrf_message(trim(message)) WRITE(message,*)I,J,IIV(I,J),IPOS,JJV(I,J),JPOS,SHW CALL wrf_message(trim(message)) CALL wrf_error_fatal ('CHECK NESTED DOMAIN BOUNDS: TRY INCREASING STENCIL WIDTH') ENDIF ENDDO ENDDO END SUBROUTINE BOUNDS_CHECK !========================================================================================== SUBROUTINE BASE_STATE_PARENT ( Z3d,Q3d,T3d,PSTD, & PINT,T,Q,CWM, & FIS,QS,PD,PDTOP,PTOP, & ETA1,ETA2, & DETA1,DETA2, & IDS,IDE,JDS,JDE,KDS,KDE, & IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! USE MODULE_MODEL_CONSTANTS IMPLICIT NONE INTEGER, INTENT(IN ) :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER, INTENT(IN ) :: IMS,IME,JMS,JME,KMS,KME INTEGER, INTENT(IN ) :: ITS,ITE,JTS,JTE,KTS,KTE REAL, INTENT(IN ) :: PDTOP,PTOP REAL, DIMENSION(KMS:KME), INTENT(IN) :: ETA1,ETA2,DETA1,DETA2 REAL, DIMENSION(IMS:IME,JMS:JME), INTENT(IN) :: FIS,PD,QS REAL, DIMENSION(IMS:IME,JMS:JME,KMS:KME), INTENT(IN) :: PINT,T,Q,CWM REAL, DIMENSION(KMS:KME), INTENT(OUT):: PSTD REAL, DIMENSION(IMS:IME,JMS:JME,KMS:KME), INTENT(OUT):: Z3d,Q3d,T3d ! local INTEGER,PARAMETER :: JTB=134 INTEGER :: I,J,K,ILOC,JLOC REAL, PARAMETER :: LAPSR=6.5E-3, GI=1./G,D608=0.608 REAL, PARAMETER :: COEF3=287.05*GI*LAPSR, COEF2=-1./COEF3 REAL, PARAMETER :: TRG=2.0*R_D*GI,LAPSI=1.0/LAPSR REAL, PARAMETER :: P_REF=103000. REAL :: A,B,APELP,RTOPP,DZ,ZMID REAL, DIMENSION(IMS:IME,JMS:JME) :: SLP,TSFC,ZMSLP REAL, DIMENSION(IMS:IME,JMS:JME,KMS:KME) :: Z3d_IN REAL,DIMENSION(JTB) :: PIN,ZIN,Y2,PIO,ZOUT,DUM1,DUM2 REAL,DIMENSION(JTB) :: QIN,QOUT,TIN,TOUT !-------------------------------------------------------------------------------------- ! CLEAN Z3D ARRAY FIRST DO K=KDS,KDE DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) Z3d(I,J,K)=0.0 T3d(I,J,K)=0.0 Q3d(I,J,K)=0.0 ENDDO ENDDO ENDDO ! DETERMINE THE HEIGHTS ON THE PARENT DOMAIN DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) Z3d_IN(I,J,1)=FIS(I,J)*GI ENDDO ENDDO DO K = KDS,KDE-1 DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) APELP = (PINT(I,J,K+1)+PINT(I,J,K)) ! RTOPP = TRG*T(I,J,K)*(1.0+Q(I,J,K)*P608-CWM(I,J,K))/APELP RTOPP = TRG*T(I,J,K)*(1.0+Q(I,J,K)*P608)/APELP DZ = RTOPP*(DETA1(K)*PDTOP+DETA2(K)*PD(I,J)) ! (RTv/P_TOT)*D(P_HYDRO) Z3d_IN(I,J,K+1) = Z3d_IN(I,J,K) + DZ ENDDO ENDDO ENDDO ! CONSTRUCT STANDARD ISOBARIC SURFACES DO K=KDS,KDE ! target points in model interface levels (pint) PSTD(K) = ETA1(K)*PDTOP + ETA2(K)*(P_REF -PDTOP - PTOP) + PTOP ENDDO ! DETERMINE THE MSLP USE THAT TO CREATE HEIGHTS AT 1000. mb LEVEL. THESE HEIGHTS ! MAY ONLY BE USED IN VERTICAL INTERPOLATION TO ISOBARIC SURFACES WHICH ARE LOCATED ! BELOW GROUND LEVEL. DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) TSFC(I,J) = T(I,J,1)*(1.+D608*Q(I,J,1)) + LAPSR*(Z3d_IN(I,J,1)+Z3d_IN(I,J,2))*0.5 A = LAPSR*Z3d_IN(I,J,1)/TSFC(I,J) SLP(I,J) = PINT(I,J,1)*(1-A)**COEF2 ! sea level pressure B = (PSTD(1)/SLP(I,J))**COEF3 ZMSLP(I,J)= TSFC(I,J)*LAPSI*(1.0 - B) ! Height at 1000. mb level ENDDO ENDDO ! INTERPOLATE Z3d_IN TO STANDARD PRESSURE INTERFACES. FOR LEVELS BELOW ! GROUND USE ZMSLP(I,J) DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) ! ! clean local array before use of spline PIN=0.;ZIN=0.;Y2=0;PIO=0.;ZOUT=0.;DUM1=0.;DUM2=0. DO K=KDS,KDE ! inputs at model interfaces PIN(K) = PINT(I,J,KDE-K+1) ZIN(K) = Z3d_IN(I,J,KDE-K+1) ENDDO IF(PINT(I,J,1) .LE. PSTD(1))THEN PIN(KDE) = PSTD(1) ZIN(KDE) = ZMSLP(I,J) ENDIF ! Y2(1 )=0. Y2(KDE)=0. ! DO K=KDS,KDE PIO(K)=PSTD(K) ENDDO ! CALL SPLINE1(I,J,JTB,KDE,PIN,ZIN,Y2,KDE,PIO,ZOUT,DUM1,DUM2) ! interpolate ! DO K=KDS,KDE ! inputs at model interfaces Z3d(I,J,K)=ZOUT(K) ENDDO ENDDO ENDDO ! ! INTERPOLATE TEMPERATURE ONTO THE STANDARD PRESSURE LEVELS. FOR LEVELS BELOW ! GROUND USE A LAPSE RATE ATMOSPHERE ! DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) ! ! clean local array before use of spline or linear interpolation ! PIN=0.;TIN=0.;Y2=0;PIO=0.;TOUT=0.;DUM1=0.;DUM2=0. DO K=KDS+1,KDE ! inputs at model levels PIN(K-1) = EXP((ALOG(PINT(I,J,KDE-K+1))+ALOG(PINT(I,J,KDE-K+2)))*0.5) TIN(K-1) = T(I,J,KDE-K+1) ENDDO IF(PINT(I,J,1) .LE. PSTD(1))THEN PIN(KDE-1) = EXP((ALOG(PSTD(1))+ALOG(PSTD(2)))*0.5) ZMID = 0.5*(Z3d_IN(I,J,1)+Z3d_IN(I,J,2)) TIN(KDE-1) = T(I,J,1) + LAPSR*(ZMID-ZMSLP(I,J)) ENDIF ! Y2(1 )=0. Y2(KDE-1)=0. ! DO K=KDS,KDE-1 PIO(K)=EXP((ALOG(PSTD(K))+ALOG(PSTD(K+1)))*0.5) ENDDO CALL SPLINE1(I,J,JTB,KDE-1,PIN,TIN,Y2,KDE-1,PIO,TOUT,DUM1,DUM2) ! interpolate DO K=KDS,KDE-1 ! inputs at model levels T3d(I,J,K)=TOUT(K) ENDDO ENDDO ENDDO ! ! INTERPOLATE MOISTURE ONTO THE STANDARD PRESSURE LEVELS. FOR LEVELS BELOW ! GROUND USE THE SURFACE MOISTURE ! DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) ! ! clean local array before use of spline or linear interpolation PIN=0.;QIN=0.;Y2=0;PIO=0.;QOUT=0.;DUM1=0.;DUM2=0. DO K=KDS+1,KDE ! inputs at model levels PIN(K-1) = EXP((ALOG(PINT(I,J,KDE-K+1))+ALOG(PINT(I,J,KDE-K+2)))*0.5) QIN(K-1) = Q(I,J,KDE-K+1) ENDDO IF(PINT(I,J,1) .LE. PSTD(1))THEN PIN(KDE-1) = EXP((ALOG(PSTD(1))+ALOG(PSTD(2)))*0.5) ! QIN(KDE-1) = QS(I,J) ENDIF Y2(1 )=0. Y2(KDE-1)=0. ! DO K=KDS,KDE-1 PIO(K)=EXP((ALOG(PSTD(K))+ALOG(PSTD(K+1)))*0.5) ENDDO CALL SPLINE1(I,J,JTB,KDE-1,PIN,QIN,Y2,KDE-1,PIO,QOUT,DUM1,DUM2) ! interpolate DO K=KDS,KDE-1 ! inputs at model levels Q3d(I,J,K)=QOUT(K) ENDDO ENDDO ENDDO END SUBROUTINE BASE_STATE_PARENT !============================================================================= SUBROUTINE SPLINE1(I,J,JTBX,NOLD,XOLD,YOLD,Y2,NNEW,XNEW,YNEW,P,Q) ! ! ****************************************************************** ! * * ! * THIS IS A ONE-DIMENSIONAL CUBIC SPLINE FITTING ROUTINE * ! * PROGRAMED FOR A SMALL SCALAR MACHINE. * ! * * ! * PROGRAMER Z. JANJIC * ! * * ! * NOLD - NUMBER OF GIVEN VALUES OF THE FUNCTION. MUST BE GE 3. * ! * XOLD - LOCATIONS OF THE POINTS AT WHICH THE VALUES OF THE * ! * FUNCTION ARE GIVEN. MUST BE IN ASCENDING ORDER. * ! * YOLD - THE GIVEN VALUES OF THE FUNCTION AT THE POINTS XOLD. * ! * Y2 - THE SECOND DERIVATIVES AT THE POINTS XOLD. IF NATURAL * ! * SPLINE IS FITTED Y2(1)=0. AND Y2(NOLD)=0. MUST BE * ! * SPECIFIED. * ! * NNEW - NUMBER OF VALUES OF THE FUNCTION TO BE CALCULATED. * ! * XNEW - LOCATIONS OF THE POINTS AT WHICH THE VALUES OF THE * ! * FUNCTION ARE CALCULATED. XNEW(K) MUST BE GE XOLD(1) * ! * AND LE XOLD(NOLD). * ! * YNEW - THE VALUES OF THE FUNCTION TO BE CALCULATED. * ! * P, Q - AUXILIARY VECTORS OF THE LENGTH NOLD-2. * ! * * ! ****************************************************************** !--------------------------------------------------------------------- IMPLICIT NONE !--------------------------------------------------------------------- INTEGER,INTENT(IN) :: I,J,JTBX,NNEW,NOLD REAL,DIMENSION(JTBX),INTENT(IN) :: XNEW,XOLD,YOLD REAL,DIMENSION(JTBX),INTENT(INOUT) :: P,Q,Y2 REAL,DIMENSION(JTBX),INTENT(OUT) :: YNEW ! INTEGER :: II,JJ,K,K1,K2,KOLD,NOLDM1 REAL :: AK,BK,CK,DEN,DX,DXC,DXL,DXR,DYDXL,DYDXR & ,RDX,RTDXC,X,XK,XSQ,Y2K,Y2KP1 CHARACTER(LEN=255) :: message !--------------------------------------------------------------------- ! debug II=9999 !67 !35 !50 !4 JJ=9999 !31 !73 !115 !192 IF(I.eq.II.and.J.eq.JJ)THEN WRITE(message,*)'DEBUG in SPLINE1:HSO= ',xnew(1:nold) CALL wrf_debug(1,trim(message)) DO K=1,NOLD WRITE(message,*)'DEBUG in SPLINE1:L,ZETAI,PINTI= ' & ,K,YOLD(K),XOLD(K) CALL wrf_debug(1,trim(message)) ENDDO ENDIF ! NOLDM1=NOLD-1 ! DXL=XOLD(2)-XOLD(1) DXR=XOLD(3)-XOLD(2) DYDXL=(YOLD(2)-YOLD(1))/DXL DYDXR=(YOLD(3)-YOLD(2))/DXR RTDXC=0.5/(DXL+DXR) ! P(1)= RTDXC*(6.*(DYDXR-DYDXL)-DXL*Y2(1)) Q(1)=-RTDXC*DXR ! IF(NOLD.EQ.3)GO TO 150 !--------------------------------------------------------------------- K=3 ! 100 DXL=DXR DYDXL=DYDXR DXR=XOLD(K+1)-XOLD(K) DYDXR=(YOLD(K+1)-YOLD(K))/DXR DXC=DXL+DXR DEN=1./(DXL*Q(K-2)+DXC+DXC) ! P(K-1)= DEN*(6.*(DYDXR-DYDXL)-DXL*P(K-2)) Q(K-1)=-DEN*DXR ! K=K+1 IF(K.LT.NOLD)GO TO 100 !----------------------------------------------------------------------- 150 K=NOLDM1 ! 200 Y2(K)=P(K-1)+Q(K-1)*Y2(K+1) ! K=K-1 IF(K.GT.1)GO TO 200 !----------------------------------------------------------------------- K1=1 ! 300 XK=XNEW(K1) ! DO 400 K2=2,NOLD ! IF(XOLD(K2).GT.XK)THEN KOLD=K2-1 GO TO 450 ENDIF ! 400 CONTINUE ! YNEW(K1)=YOLD(NOLD) GO TO 600 ! 450 IF(K1.EQ.1)GO TO 500 IF(K.EQ.KOLD)GO TO 550 ! 500 K=KOLD ! Y2K=Y2(K) Y2KP1=Y2(K+1) DX=XOLD(K+1)-XOLD(K) RDX=1./DX ! AK=.1666667*RDX*(Y2KP1-Y2K) BK=0.5*Y2K CK=RDX*(YOLD(K+1)-YOLD(K))-.1666667*DX*(Y2KP1+Y2K+Y2K) ! 550 X=XK-XOLD(K) XSQ=X*X ! YNEW(K1)=AK*XSQ*X+BK*XSQ+CK*X+YOLD(K) ! debug if(i.eq.ii.and.j.eq.jj)then write(message,*) 'DEBUG:: k1,xnew(k1),ynew(k1): ', k1,xnew(k1),ynew(k1) CALL wrf_debug(1,trim(message)) endif ! 600 K1=K1+1 IF(K1.LE.NNEW)GO TO 300 RETURN END SUBROUTINE SPLINE1 !--------------------------------------------------------------------- SUBROUTINE NEST_TERRAIN ( nest, config_flags ) USE module_domain USE module_configure USE module_timing USE wrfsi_static IMPLICIT NONE TYPE(domain) , POINTER :: nest TYPE(grid_config_rec_type) , INTENT(IN) :: config_flags ! ! Local variables ! LOGICAL, EXTERNAL :: wrf_dm_on_monitor INTEGER :: ids,ide,jds,jde,kds,kde INTEGER :: ims,ime,jms,jme,kms,kme INTEGER :: its,ite,jts,jte,kts,kte INTEGER :: i_parent_start, j_parent_start INTEGER :: parent_grid_ratio INTEGER :: n,i,j,ii,jj,nnxp,nnyp INTEGER :: i_start,j_start,level REAL, ALLOCATABLE, DIMENSION(:,:) :: data1 ! for highres topo REAL, ALLOCATABLE, DIMENSION(:,:) :: avc_big, lnd_big, lah_big, loh_big REAL, ALLOCATABLE, DIMENSION(:,:) :: avc_nest, lnd_nest, lah_nest, loh_nest INTEGER :: im_big, jm_big, i_add INTEGER :: im, jm CHARACTER(LEN=6) :: nestpath integer :: input_type character(len=128) :: input_fname character (len=32) :: cname integer :: ndim character (len=3) :: memorder character (len=32) :: stagger integer, dimension(3) :: domain_start, domain_end integer :: wrftype character (len=128), dimension(3) :: dimnames integer :: istatus integer :: handle integer :: comm_1, comm_2 real, allocatable, dimension(:,:,:) :: real_domain character (len=10), dimension(24) :: name = (/ "XLAT_M ", & "XLONG_M ", & "XLAT_V ", & "XLONG_V ", & "E ", & "F ", & "LANDMASK ", & "LANDUSEF ", & "LU_INDEX ", & "HCNVX ", & "HSTDV ", & "HASYW ", & "HASYS ", & "HASYSW ", & "HASYNW ", & "HLENW ", & "HLENS ", & "HLENSW ", & "HLENNW ", & "HANIS ", & "HSLOP ", & "HANGL ", & "HZMAX ", & "HGT_M " /) integer, parameter :: IO_BIN=1, IO_NET=2 integer :: io_form_input CHARACTER(LEN=512) :: message write(message,*)"in NEST_TERRAIN config_flags%io_form_input = ", config_flags%io_form_input CALL wrf_message(trim(message)) write(message,*)"in NEST_TERRAIN config_flags%auxinput1_inname = ", config_flags%auxinput1_inname CALL wrf_message(trim(message)) io_form_input = config_flags%io_form_input if (config_flags%auxinput1_inname(1:7) == "met_nmm") then input_type = 2 else input_type = 1 end if !---------------------------------------------------------------------------------- IDS = nest%sd31 IDE = nest%ed31 JDS = nest%sd32 JDE = nest%ed32 KDS = nest%sd33 KDE = nest%ed33 IMS = nest%sm31 IME = nest%em31 JMS = nest%sm32 JME = nest%em32 KMS = nest%sm33 KME = nest%em33 ITS = nest%sp31 ITE = nest%ep31 JTS = nest%sp32 JTE = nest%ep32 KTS = nest%sp33 KTE = nest%ep33 i_parent_start = nest%i_parent_start j_parent_start = nest%j_parent_start parent_grid_ratio = nest%parent_grid_ratio NNXP=IDE-1 NNYP=JDE-1 ALLOCATE(DATA1(1:NNXP,1:NNYP)) ! ! !--- Read in high resolution topography ! IF ( wrf_dm_on_monitor() ) THEN ! first assign a status ! ! This part of the code is Dusan's doing. Extended by gopal for multiple nest (Feb 19,2005) ! call find_ijstart_level (nest,i_start,j_start,level) write(message,*)" nest%id =", nest%id , " i_start,j_start,level =", i_start,j_start,level CALL wrf_message(trim(message)) write(nestpath,"(a4,i1,a1)") 'nest',level,'/' if ( level > 0 ) then if (input_type == 1) then ! ! si version of the static file ! CALL get_wrfsi_static_dims(nestpath, im_big, jm_big) ALLOCATE (avc_big(im_big,jm_big)) ALLOCATE (lnd_big(im_big,jm_big)) ALLOCATE (lah_big(im_big,jm_big)) ALLOCATE (loh_big(im_big,jm_big)) CALL get_wrfsi_static_2d(nestpath, 'avc', avc_big) CALL get_wrfsi_static_2d(nestpath, 'lnd', lnd_big) CALL get_wrfsi_static_2d(nestpath, 'lah', lah_big) CALL get_wrfsi_static_2d(nestpath, 'loh', loh_big) else if (input_type == 2) then ! ! WPS version of the static file ! #ifdef INTIO if (io_form_input == IO_BIN) write(input_fname,"(A,I2.2,A)") "geo_nmm_nest.l",level,".int" #endif #ifdef NETCDF if (io_form_input == IO_NET) write(input_fname,"(A,I2.2,A)") "geo_nmm_nest.l",level,".nc" #endif comm_1 = 1 comm_2 = 1 #ifdef INTIO if (io_form_input == IO_BIN) & call ext_int_open_for_read(trim(input_fname), comm_1, comm_2, 'sysdep info', handle, istatus) #endif #ifdef NETCDF if (io_form_input == IO_NET) & call ext_ncd_open_for_read(trim(input_fname), comm_1, comm_2, 'sysdep info', handle, istatus) #endif if (istatus /= 0) CALL wrf_error_fatal('NEST_TERRAIN error after ext_XXX_open_for_read '//trim(input_fname)) do n=1,24 cname = name(n) domain_start = 1 domain_end = 1 #ifdef INTIO if (io_form_input == IO_BIN) & call ext_int_get_var_info(handle, cname, ndim, memorder, stagger, domain_start, domain_end, wrftype, istatus) #endif #ifdef NETCDF if (io_form_input == IO_NET) & call ext_ncd_get_var_info(handle, cname, ndim, memorder, stagger, domain_start, domain_end, wrftype, istatus) #endif print *, "cname=", cname print *, "istatus=", istatus print *, "ndim=", ndim print *, "memorder=", memorder print *, "stagger=", stagger print *, "domain_start=", domain_start print *, "domain_end=", domain_end print *, "wrftype=", wrftype if (allocated(real_domain)) deallocate(real_domain) allocate(real_domain(domain_start(1):domain_end(1), domain_start(2):domain_end(2), domain_start(3):domain_end(3))) #ifdef INTIO if (io_form_input == IO_BIN) then call ext_int_read_field(handle, '0000-00-00_00:00:00', cname, real_domain, wrftype, & 1, 1, 0, memorder, stagger, & dimnames, domain_start, domain_end, domain_start, domain_end, & domain_start, domain_end, istatus) end if #endif #ifdef NETCDF if (io_form_input == IO_NET) then call ext_ncd_read_field(handle, '0000-00-00_00:00:00', cname, real_domain, wrftype, & 1, 1, 0, memorder, stagger, & dimnames, domain_start, domain_end, domain_start, domain_end, & domain_start, domain_end, istatus) end if #endif print *, "istatus=", istatus im_big = domain_end(1) jm_big = domain_end(2) if (cname(1:10) == "XLAT_M ") then ALLOCATE (lah_big(im_big,jm_big)) do j=1,jm_big do i=1,im_big lah_big(i,j) = real_domain(i,j,1) end do end do else if (cname(1:10) == "XLONG_M ") then ALLOCATE (loh_big(im_big,jm_big)) do j=1,jm_big do i=1,im_big loh_big(i,j) = real_domain(i,j,1) end do end do else if (cname(1:10) == "LANDMASK ") then ALLOCATE (lnd_big(im_big,jm_big)) do j=1,jm_big do i=1,im_big lnd_big(i,j) = real_domain(i,j,1) end do end do else if (cname(1:10) == "HGT_M ") then ALLOCATE (avc_big(im_big,jm_big)) do j=1,jm_big do i=1,im_big avc_big(i,j) = real_domain(i,j,1) end do end do end if end do #ifdef INTIO if (io_form_input == IO_BIN) then call ext_int_ioclose(handle, istatus) end if #endif #ifdef NETCDF if (io_form_input == IO_NET) then call ext_ncd_ioclose(handle, istatus) end if #endif else CALL wrf_error_fatal('NEST_TERRAIN wrong input_type') end if else CALL wrf_error_fatal('this routine NEST_TERRAIN should not be called for top-level domain') end if ! select subdomain from big fine grid im = NNXP jm = NNYP ALLOCATE (avc_nest(im,jm)) ALLOCATE (lnd_nest(im,jm)) ALLOCATE (lah_nest(im,jm)) ALLOCATE (loh_nest(im,jm)) i_add = mod(j_start+1,2) DO j=1,jm DO i=1,im avc_nest(i,j) = avc_big(i_start+i-1 + mod(j+1,2)*i_add, j_start+j-1) lnd_nest(i,j) = lnd_big(i_start+i-1 + mod(j+1,2)*i_add, j_start+j-1) lah_nest(i,j) = lah_big(i_start+i-1 + mod(j+1,2)*i_add, j_start+j-1) loh_nest(i,j) = loh_big(i_start+i-1 + mod(j+1,2)*i_add, j_start+j-1) END DO END DO WRITE(message,*)'SOME MATCHING TEST i_parent_start, j_parent_start',i_parent_start,j_parent_start CALL wrf_message(trim(message)) CALL wrf_message('WRFSI LAT COMPUTED LAT') WRITE(message,*)lah_nest(1,1),nest%HLAT(1,1) CALL wrf_message(trim(message)) CALL wrf_message('WRFSI LON COMPUTED LON') WRITE(message,*)loh_nest(1,1),nest%HLON(1,1) CALL wrf_message(trim(message)) IF(ABS(lah_nest(1,1)-nest%HLAT(1,1)) .GE. 0.5 .OR. & ABS(loh_nest(1,1)-nest%HLON(1,1)) .GE. 0.5)THEN CALL wrf_message('CHECK WRFSI CONFIGURATION AND INPUT HIGH RESOLUTION TOPOGRAPHY AND/OR GRID RATIO') CALL wrf_error_fatal('LATLON MISMATCH: ERROR READING static FILE FOR THE NEST') ENDIF call smdhld(im,jm,avc_nest,1.0-lnd_nest,12,12) !-------------4-point averaging of mountains along inner boundary------- do i=1,im-1 avc_nest(i,2)=0.25*(avc_nest(i,1)+avc_nest(i+1,1)+ & & avc_nest(i,3)+avc_nest(i+1,3)) enddo do i=1,im-1 avc_nest(i,jm-1)=0.25*(avc_nest(i,jm-2)+avc_nest(i+1,jm-2)+ & & avc_nest(i,jm)+avc_nest(i+1,jm)) enddo do j=4,jm-3,2 avc_nest(1,j)=0.25*(avc_nest(1,j-1)+avc_nest(2,j-1)+ & & avc_nest(1,j+1)+avc_nest(2,j+1)) enddo do j=4,jm-3,2 avc_nest(im-1,j)=0.25*(avc_nest(im-1,j-1)+avc_nest(im,j-1)+ & & avc_nest(im-1,j+1)+avc_nest(im,j+1)) enddo DO J = 1,NNYP DO I = 1,NNXP DATA1(I,J) = 9.81*avc_nest(I,J) ENDDO ENDDO DEALLOCATE (avc_big,lnd_big) DEALLOCATE (avc_nest,lnd_nest) ! ENDIF CALL wrf_dm_bcast_bytes (DATA1,NNXP*NNYP*RWORDSIZE) DO J=JDS,JDE DO I =IDS,IDE IF(I.GE.ITS .AND. I .LE. MIN(ide-1,ite) .AND. J.GE.JTS .AND. J .LE. MIN(jde-1,jte))THEN nest%hres_fis(I,J)=DATA1(I,J) ENDIF ENDDO ENDDO DEALLOCATE(DATA1) CALL wrf_message('end of NEST_TERRAIN') END SUBROUTINE NEST_TERRAIN !=========================================================================================== SUBROUTINE med_init_domain_constants_nmm ( parent, nest) !, config_flags) ! Driver layer USE module_domain USE module_configure USE module_timing IMPLICIT NONE TYPE(domain) , POINTER :: parent, nest, grid ! ! INTERFACE SUBROUTINE med_initialize_nest_nmm ( grid & ! # include ! ) USE module_domain USE module_configure USE module_timing IMPLICIT NONE TYPE(domain) , POINTER :: grid #include END SUBROUTINE med_initialize_nest_nmm END INTERFACE !------------------------------------------------------------------------------ ! PURPOSE: ! - initialize some data, mainly 2D & 3D nmm arrays very similar to ! those done in ./dyn_nmm/module_initialize_real.f !----------------------------------------------------------------------------- ! grid => nest CALL med_initialize_nest_nmm( grid & ! # include ! ) END SUBROUTINE med_init_domain_constants_nmm SUBROUTINE med_initialize_nest_nmm( grid & ! # include ! ) USE module_domain USE module_configure USE module_timing IMPLICIT NONE ! Local domain indices and counters. INTEGER :: ids, ide, jds, jde, kds, kde, & ims, ime, jms, jme, kms, kme, & its, ite, jts, jte, kts, kte, & i, j, k, nnxp, nnyp TYPE(domain) , POINTER :: grid ! Local data LOGICAL, EXTERNAL :: wrf_dm_on_monitor INTEGER :: KHH,KVH,JAM,JA,IHL, IHH, L INTEGER :: II,JJ,ISRCH,ISUM INTEGER, ALLOCATABLE, DIMENSION(:) :: KHL2,KVL2,KHH2,KVH2,KHLA,KHHA,KVLA,KVHA INTEGER,PARAMETER :: KNUM=SELECTED_REAL_KIND(13) ! REAL(KIND=KNUM) :: WB,SB,DLM,DPH,TPH0,STPH0,CTPH0 REAL(KIND=KNUM) :: STPH,CTPH,TDLM,TDPH,FP,TPH,TLM,TLM0 REAL :: TPH0D,TLM0D,ANBI,TSPH,DTAD,DTCF,DT REAL :: ACDT,CDDAMP,DXP REAL :: WBD,SBD,WBI,SBI,EBI REAL :: DY_NMM0 REAL :: RSNOW,SNOFAC REAL, ALLOCATABLE, DIMENSION(:) :: DXJ,WPDARJ,CPGFUJ,CURVJ, & FCPJ,FDIVJ,EMJ,EMTJ,FADJ, & HDACJ,DDMPUJ,DDMPVJ ! REAL, PARAMETER:: SALP=2.60 REAL, PARAMETER:: SNUP=0.040 REAL, PARAMETER:: W_NMM=0.08 REAL, PARAMETER:: COAC=0.75 REAL, PARAMETER:: CODAMP=6.4 REAL, PARAMETER:: TWOM=.00014584 REAL, PARAMETER:: CP=1004.6 REAL, PARAMETER:: DFC=1.0 REAL, PARAMETER:: DDFC=1.0 REAL, PARAMETER:: ROI=916.6 REAL, PARAMETER:: R=287.04 REAL, PARAMETER:: CI=2060.0 REAL, PARAMETER:: ROS=1500. REAL, PARAMETER:: CS=1339.2 REAL, PARAMETER:: DS=0.050 REAL, PARAMETER:: AKS=.0000005 REAL, PARAMETER:: DZG=2.85 REAL, PARAMETER:: DI=.1000 REAL, PARAMETER:: AKI=0.000001075 REAL, PARAMETER:: DZI=2.0 REAL, PARAMETER:: THL=210. REAL, PARAMETER:: PLQ=70000. REAL, PARAMETER:: ERAD=6371200. REAL, PARAMETER:: DTR=0.01745329 CHARACTER(LEN=255) :: message ! Definitions of dummy arguments to solve #include !#define COPY_IN !#include #ifdef DM_PARALLEL # include #endif CALL get_ijk_from_grid ( grid , & ids, ide, jds, jde, kds, kde, & ims, ime, jms, jme, kms, kme, & its, ite, jts, jte, kts, kte ) !================================================================================= ! ! DT=grid%dt !float(TIME_STEP)/parent_time_step_ratio NNXP=min(ITE,IDE-1) NNYP=min(JTE,JDE-1) JAM=6+2*((JDE-1)-10) ! this should be the fix instead of JAM=6+2*(NNYP-10) WRITE(message,*)'TIME STEP ON DOMAIN',grid%id,'==',dt CALL wrf_message(trim(message)) WRITE(message,*)'IDS,IDE ON DOMAIN',grid%id,'==',ids,ide CALL wrf_message(trim(message)) ! ALLOCATE(KHL2(JTS:NNYP),KVL2(JTS:NNYP),KHH2(JTS:NNYP),KVH2(JTS:NNYP)) ALLOCATE(DXJ(JTS:NNYP),WPDARJ(JTS:NNYP),CPGFUJ(JTS:NNYP),CURVJ(JTS:NNYP)) ALLOCATE(FCPJ(JTS:NNYP),FDIVJ(JTS:NNYP),FADJ(JTS:NNYP)) ALLOCATE(HDACJ(JTS:NNYP),DDMPUJ(JTS:NNYP),DDMPVJ(JTS:NNYP)) ALLOCATE(KHLA(JAM),KHHA(JAM)) ALLOCATE(KVLA(JAM),KVHA(JAM)) ! INITIALIZE SOME LAND/WATER SURFACE DATA ON THE BASIS OF INPUTS: SM, XICE, WEASD, ! INTERPOLATED FROM MOTHER (WRFSI) DOMAIN. THIS PART OF THE CODE HAS TO BE REVISITED ! LATER ON ! Since SM has been changed on parent domain to be 0 over sea ice it can not be used here ! to find where sea ice is. That's why alogirthm here is slightly different than the ! one used in module_initalize_real.f #ifdef HWRF !zhang's doing: added to AVOID THIS COMPUTATION IF THE NEST IS STARTED USING ANALYSIS FILE IF(.not. grid%analysis)THEN #endif DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) IF (grid%sm(I,J).GT.0.9) THEN ! OVER WATER SURFACE grid%epsr(I,J)= 0.97 grid%embck(I,J)= 0.97 grid%gffc(I,J)= 0. grid%albedo(I,J)=.06 grid%albase(I,J)=.06 ENDIF IF (grid%sice(I,J).GT.0.9) THEN ! OVER SEA-ICE grid%sm(I,J)=0. grid%si(I,J)=0. grid%gffc(I,J)=0. grid%albedo(I,J)=.60 grid%albase(I,J)=.60 ENDIF IF (grid%sm(I,J).LT.0.5.AND.grid%sice(I,J).LT.0.5) THEN ! OVER LAND SURFACE grid%si(I,J)=5.0*grid%weasd(I,J)/1000. ! SNOW WATER EQ (mm) OBTAINED FROM PARENT (grid%si) IS INTERPOLATED grid%epsr(I,J)=1.0 ! EMISSIVITY DEFINED OVER LAND IN THE NESTED DOMAIN grid%embck(I,J)=1.0 ! EMISSIVITY DEFINED OVER LAND IN THE NESTED DOMAIN grid%gffc(I,J)=0.0 ! just leave zero as irrelevant grid%sno(I,J)=grid%si(I,J)*.20 ! LAND-SNOW COVER ENDIF ENDDO ENDDO #if 0 DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) IF(grid%sm(I,J).GT.0.9) THEN ! OVER WATER SURFACE ! IF (XICE(I,J) .gt. 0)THEN ! XICE: SI INPUT ON PARENT, INTERPOLATED ONTO NEST grid%si(I,J)=1.0 ! INITIALIZE SI BASED ON XICE FROM INTERPOLATED INPUT ENDIF ! grid%epsr(I,J)= 0.97 ! VALID OVER SEA SURFACE grid%embck(I,J)= 0.97 ! VALID OVER SEA SURFACE grid%gffc(I,J)= 0. grid%albedo(I,J)=.06 grid%albase(I,J)=.06 ! IF(grid%si (I,J) .GT. 0.)THEN ! VALID OVER SEA-ICE grid%sm(I,J)=0. grid%si(I,J)=0. ! grid%sice(I,J)=1. grid%gffc(I,J)=0. ! just leave zero as irrelevant grid%albedo(I,J)=.60 ! DEFINE grid%albedo grid%albase(I,J)=.60 ENDIF ! ELSE ! OVER LAND SURFACE ! grid%si(I,J)=5.0*grid%weasd(I,J)/1000. ! SNOW WATER EQ (mm) OBTAINED FROM PARENT (grid%si) IS INTERPOLATED grid%epsr(I,J)=1.0 ! EMISSIVITY DEFINED OVER LAND IN THE NESTED DOMAIN grid%embck(I,J)=1.0 ! EMISSIVITY DEFINED OVER LAND IN THE NESTED DOMAIN grid%gffc(I,J)=0.0 ! just leave zero as irrelevant grid%sice(I,J)=0. ! SEA ICE grid%sno(I,J)=grid%si(I,J)*.20 ! LAND-SNOW COVER ! ENDIF ! ENDDO ENDDO #endif ! This may just be a fix and may need some Registry related changes, later on DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) grid%vegfra(I,J)=grid%vegfrc(I,J) ENDDO ENDDO ! DETERMINE ALBEDO OVER LAND ON THE BASIS OF INPUTS: SM, ALBASE, MXSNAL & VEGFRA ! INTERPOLATED FROM MOTHER (WRFSI) DOMAIN DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) IF(grid%sm(I,J).LT.0.9.AND.grid%sice(I,J).LT.0.9) THEN ! IF ( (grid%sno(I,J) .EQ. 0.0) .OR. & ! SNOWFREE ALBEDO (grid%albase(I,J) .GE. grid%mxsnal(I,J) ) ) THEN grid%albedo(I,J) = grid%albase(I,J) ELSE IF (grid%sno(I,J) .LT. SNUP) THEN ! MODIFY ALBEDO IF SNOWCOVER: RSNOW = grid%sno(I,J)/SNUP ! BELOW SNOWDEPTH THRESHOLD SNOFAC = 1. - ( EXP(-SALP*RSNOW) - RSNOW*EXP(-SALP)) ELSE SNOFAC = 1.0 ! ABOVE SNOWDEPTH THRESHOLD ENDIF grid%albedo(I,J) = grid%albase(I,J) & + (1.0-grid%vegfra(I,J))*SNOFAC*(grid%mxsnal(I,J)-grid%albase(I,J)) ENDIF ! END IF grid%si(I,J)=5.0*grid%weasd(I,J) grid%sno(I,J)=grid%weasd(I,J) ! this block probably superfluous. Meant to guarantee land/sea agreement IF (grid%sm(I,J) .gt. 0.5)THEN grid%landmask(I,J)=0.0 ELSE grid%landmask(I,J)=1.0 ENDIF IF (grid%sice(I,J) .eq. 1.0) then !!!! change vegtyp and sltyp to fit seaice (desireable??) grid%isltyp(I,J)=16 grid%ivgtyp(I,J)=24 ENDIF ENDDO ENDDO ! Check land water interface DO J = JTS, MIN(JTE,JDE-1) DO I = ITS,MIN(ITE,IDE-1) IF(grid%sm(I,J).GT.0.9 .AND. grid%vegfra(I,J) .NE. 0) THEN WRITE(message,*)'PROBLEM AT THE LAND-WATER INTERFACE (VEGFRA):', & I,J,grid%sm(I-1,J),grid%vegfra(I-1,j),grid%sm(I,J),grid%vegfra(I,J) CALL wrf_message(trim(message)) ENDIF ! #if defined(HWRF) ! HWRF should not perform the check below because the nmm_tsk is ! update with the correct skin temperature every timestep (on both ! land and sea points). #else IF(grid%sm(I,J).GT.0.9 .AND. grid%nmm_tsk(I,J) .NE. 0) THEN WRITE(message,*)'PROBLEM AT THE LAND-WATER INTERFACE (NMM_TSK):', & I,J,grid%sm(I-1,J),grid%nmm_tsk(I-1,J),grid%sm(I,J),grid%nmm_tsk(I,J) CALL wrf_message(trim(message)) ENDIF #endif ENDDO ENDDO ! hardwire root depth for time being grid%rtdpth=0. grid%rtdpth(1)=0.1 grid%rtdpth(2)=0.3 grid%rtdpth(3)=0.6 ! hardwire soil depth for time being grid%sldpth=0. grid%sldpth(1)=0.1 grid%sldpth(2)=0.3 grid%sldpth(3)=0.6 grid%sldpth(4)=1.0 #ifdef HWRF !zhang's doing: added to AVOID THIS COMPUTATION IF THE NEST IS STARTED USING ANALYSIS FILE ENDIF ! <------ for analysis set to false #endif !----------- END OF LAND SURFACE INITIALIZATION ------------------------------------- ! DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) grid%res(I,J)=1. ENDDO ENDDO ! INITIALIZE 2D BOUNDARY MASKS !! grid%hbm2: grid%hbm2=0. DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) IF((J .GE. 3 .and. J .LE. (JDE-1)-2) .AND. & (I .GE. 2 .and. I .LE. (IDE-1)-2+MOD(J,2))) THEN grid%hbm2(I,J)=1. ENDIF ENDDO ENDDO !! grid%hbm3: grid%hbm3=0. DO J=JTS,MIN(JTE,JDE-1) grid%ihwg(J)=mod(J+1,2)-1 IF (J .ge. 4 .and. J .le. (JDE-1)-3) THEN IHL=(IDS+1)-grid%ihwg(J) IHH=(IDE-1)-2 DO I=ITS,MIN(ITE,IDE-1) IF (I .ge. IHL .and. I .le. IHH) grid%hbm3(I,J)=1. ENDDO ENDIF ENDDO !! grid%vbm2 grid%vbm2=0. DO J=JTS,MIN(JTE,JDE-1) DO I=ITS,MIN(ITE,IDE-1) IF((J .ge. 3 .and. J .le. (JDE-1)-2) .AND. & (I .ge. 2 .and. I .le. (IDE-1)-1-MOD(J,2))) THEN grid%vbm2(I,J)=1. ENDIF ENDDO ENDDO !! grid%vbm3 grid%vbm3=0. DO J=JTS,MIN(JTE,JDE-1) DO I=ITS,MIN(ITE,IDE-1) IF((J .ge. 4 .and. J .le. (JDE-1)-3) .AND. & (I .ge. 3-MOD(J,2) .and. I .le. (IDE-1)-2)) THEN grid%vbm3(I,J)=1. ENDIF ENDDO ENDDO TPH0D = grid%CEN_LAT TLM0D = grid%CEN_LON TPH0 = TPH0D*DTR WBD = grid%WBD0 ! gopal's doing: may use Registry WBD0 now WB = WBD*DTR SBD = grid%SBD0 ! gopal's doing: may use Registry SBD0 now SB = SBD*DTR DLM = grid%dlmd*DTR ! input now from med_nest_egrid_configure DPH = grid%dphd*DTR ! input now from med_nest_egrid_configure TDLM = DLM+DLM TDPH = DPH+DPH WBI = WB+TDLM SBI = SB+TDPH EBI = WB+((ide-1)-2)*TDLM ! gopal's doing: check this for nested domain ANBI = SB+((jde-1)-3)*DPH ! gopal's doing: check this for nested domain STPH0 = SIN(TPH0) CTPH0 = COS(TPH0) TSPH = 3600./grid%DT DTAD = 1.0 DTCF = 4.0 DY_NMM0= grid%dy_nmm ! ERAD*DPH; input now from med_nest_egrid_configure ! CORIOLIS PARAMETER (There appears to be some roundoff in computing TLM & STPH and other terms, ! in the nested domain. The problem needs to be revisited DO J=JTS,MIN(JTE,JDE-1) TLM0=WB-TDLM+MOD(J,2)*DLM ! remember this is a wind point TPH =SB+float(J-1)*DPH STPH=SIN(TPH) CTPH=COS(TPH) DO I=ITS,MIN(ITE,IDE-1) TLM=TLM0 + I*TDLM FP=TWOM*(CTPH0*STPH+STPH0*CTPH*COS(TLM)) grid%f(I,J)=0.5*grid%DT*FP ENDDO ENDDO DO J=JTS,MIN(JTE,JDE-1) KHL2(J)=(IDE-1)*(J-1)-(J-1)/2+2 KVL2(J)=(IDE-1)*(J-1)-J/2+2 KHH2(J)=(IDE-1)*J-J/2-1 KVH2(J)=(IDE-1)*J-(J+1)/2-1 ENDDO TPH=SB-DPH DO J=JTS,MIN(JTE,JDE-1) TPH=SB+float(J-1)*DPH DXP=ERAD*DLM*COS(TPH) DXJ(J)=DXP WPDARJ(J)=-W_NMM*((ERAD*DLM*AMIN1(COS(ANBI),COS(SBI)))**2+DY_NMM0**2)/ & (grid%DT*32.*DXP*DY_NMM0) CPGFUJ(J)=-grid%DT/(48.*DXP) CURVJ(J)=.5*grid%DT*TAN(TPH)/ERAD FCPJ(J)=grid%DT/(CP*192.*DXP*DY_NMM0) FDIVJ(J)=1./(12.*DXP*DY_NMM0) FADJ(J)=-grid%DT/(48.*DXP*DY_NMM0)*DTAD ACDT=grid%DT*SQRT((ERAD*DLM*AMIN1(COS(ANBI),COS(SBI)))**2+DY_NMM0**2) CDDAMP=CODAMP*ACDT HDACJ(J)=COAC*ACDT/(4.*DXP*DY_NMM0) DDMPUJ(J)=CDDAMP/DXP DDMPVJ(J)=CDDAMP/DY_NMM0 ENDDO ! --------------DERIVED VERTICAL GRID CONSTANTS-------------------------- WRITE(message,*)'NEW CHANGE',grid%f4d,grid%ef4t,grid%f4q CALL wrf_message(trim(message)) DO L=KDS,KDE-1 grid%rdeta(L)=1./grid%deta(L) grid%f4q2(L)=-.25*grid%DT*DTAD/grid%deta(L) ENDDO DO J=JTS,MIN(JTE,JDE-1) DO I=ITS,MIN(ITE,IDE-1) grid%dx_nmm(I,J)=DXJ(J) grid%wpdar(I,J)=WPDARJ(J)*grid%hbm2(I,J) grid%cpgfu(I,J)=CPGFUJ(J)*grid%vbm2(I,J) grid%curv(I,J)=CURVJ(J)*grid%vbm2(I,J) grid%fcp(I,J)=FCPJ(J)*grid%hbm2(I,J) grid%fdiv(I,J)=FDIVJ(J)*grid%hbm2(I,J) grid%fad(I,J)=FADJ(J) grid%hdacv(I,J)=HDACJ(J)*grid%vbm2(I,J) grid%hdac(I,J)=HDACJ(J)*1.25*grid%hbm2(I,J) ENDDO ENDDO DO J=JTS, MIN(JTE,JDE-1) IF (J.LE.5.OR.J.GE.(JDE-1)-4) THEN KHH=(IDE-1)-2+MOD(J,2) ! KHH is global...loop over I that have DO I=ITS,MIN(ITE,IDE-1) IF (I .ge. 2 .and. I .le. KHH) THEN grid%hdac(I,J)=grid%hdac(I,J)* DFC ENDIF ENDDO ELSE KHH=2+MOD(J,2) DO I=ITS,MIN(ITE,IDE-1) IF (I .ge. 2 .and. I .le. KHH) THEN grid%hdac(I,J)=grid%hdac(I,J)* DFC ENDIF ENDDO KHH=(IDE-1)-2+MOD(J,2) DO I=ITS,MIN(ITE,IDE-1) IF (I .ge. (IDE-1)-2 .and. I .le. KHH) THEN grid%hdac(I,J)=grid%hdac(I,J)* DFC ENDIF ENDDO ENDIF ENDDO DO J=JTS,min(JTE,JDE-1) DO I=ITS,min(ITE,IDE-1) grid%ddmpu(I,J)=DDMPUJ(J)*grid%vbm2(I,J) grid%ddmpv(I,J)=DDMPVJ(J)*grid%vbm2(I,J) grid%hdacv(I,J)=grid%hdacv(I,J)*grid%vbm2(I,J) ENDDO ENDDO ! --------------INCREASING DIFFUSION ALONG THE BOUNDARIES---------------- DO J=JTS,MIN(JTE,JDE-1) IF (J.LE.5.OR.J.GE.JDE-1-4) THEN KVH=(IDE-1)-1-MOD(J,2) DO I=ITS,MIN(ITE,IDE-1) IF (I .ge. 2 .and. I .le. KVH) THEN grid%ddmpu(I,J)=grid%ddmpu(I,J)*DDFC grid%ddmpv(I,J)=grid%ddmpv(I,J)*DDFC grid%hdacv(I,J)=grid%hdacv(I,J)*DFC ENDIF ENDDO ELSE KVH=3-MOD(J,2) DO I=ITS,MIN(ITE,IDE-1) IF (I .ge. 2 .and. I .le. KVH) THEN grid%ddmpu(I,J)=grid%ddmpu(I,J)*DDFC grid%ddmpv(I,J)=grid%ddmpv(I,J)*DDFC grid%hdacv(I,J)=grid%hdacv(I,J)*DFC ENDIF ENDDO KVH=(IDE-1)-1-MOD(J,2) DO I=ITS,MIN(ITE,IDE-1) IF (I .ge. IDE-1-2 .and. I .le. KVH) THEN grid%ddmpu(I,J)=grid%ddmpu(I,J)*DDFC grid%ddmpv(I,J)=grid%ddmpv(I,J)*DDFC grid%hdacv(I,J)=grid%hdacv(I,J)*DFC ENDIF ENDDO ENDIF ENDDO ! This one was left over for nested domain DO J = JTS, MIN(JTE,JDE-1) DO I = ITS, MIN(ITE,IDE-1) grid%GLAT(I,J)=grid%HLAT(I,J)*DTR grid%GLON(I,J)=grid%HLON(I,J)*DTR ENDDO ENDDO !! compute EMT, EM on global domain, and only on task 0. ! IF (wrf_dm_on_monitor()) THEN !!!! NECESSARY TO LIMIT THIS TO TASK ZERO? ALLOCATE(EMJ(JDS:JDE-1),EMTJ(JDS:JDE-1)) DO J=JDS,JDE-1 TPH=SB+float(J-1)*DPH DXP=ERAD*DLM*COS(TPH) EMJ(J)= grid%DT/( 4.*DXP)*DTAD EMTJ(J)=grid%DT/(16.*DXP)*DTAD ENDDO JA=0 DO 161 J=3,5 JA=JA+1 KHLA(JA)=2 KHHA(JA)=(IDE-1)-1-MOD(J+1,2) 161 grid%emt(JA)=EMTJ(J) DO 162 J=(JDE-1)-4,(JDE-1)-2 JA=JA+1 KHLA(JA)=2 KHHA(JA)=(IDE-1)-1-MOD(J+1,2) 162 grid%emt(JA)=EMTJ(J) DO 163 J=6,(JDE-1)-5 JA=JA+1 KHLA(JA)=2 KHHA(JA)=2+MOD(J,2) 163 grid%emt(JA)=EMTJ(J) DO 164 J=6,(JDE-1)-5 JA=JA+1 KHLA(JA)=(IDE-1)-2 KHHA(JA)=(IDE-1)-1-MOD(J+1,2) 164 grid%emt(JA)=EMTJ(J) ! --------------SPREADING OF UPSTREAM VELOCITY-POINT ADVECTION FACTOR---- JA=0 DO 171 J=3,5 JA=JA+1 KVLA(JA)=2 KVHA(JA)=(IDE-1)-1-MOD(J,2) 171 grid%em(JA)=EMJ(J) DO 172 J=(JDE-1)-4,(JDE-2)-2 JA=JA+1 KVLA(JA)=2 KVHA(JA)=(IDE-1)-1-MOD(J,2) 172 grid%em(JA)=EMJ(J) DO 173 J=6,(JDE-1)-5 JA=JA+1 KVLA(JA)=2 KVHA(JA)=2+MOD(J+1,2) 173 grid%em(JA)=EMJ(J) DO 174 J=6,(JDE-1)-5 JA=JA+1 KVLA(JA)=(IDE-1)-2 KVHA(JA)=(IDE-1)-1-MOD(J,2) 174 grid%em(JA)=EMJ(J) ! ENDIF ! wrf_dm_on_monitor !! must be a better place to put this, but will eliminate "phantom" !! wind points here (no wind point on eastern boundary of odd numbered rows) !! ! phantom IF (ABS(IDE-1-ITE) .eq. 1 ) THEN ! | CALL wrf_message('zero phantom winds') ! H [x] H V DO K=KDS,KDE-1 ! DO J=JDS,JDE-1,2 ! V [H] V H IF (J .ge. JTS .and. J .le. JTE) THEN ! grid%u(IDE-1,J,K)=0. ! H [x] H V grid%v(IDE-1,J,K)=0. ! ------ ------ ENDIF ! ide-1 ide ENDDO ! NMM/si WRF ENDDO ! domain domain ENDIF ! (dummy) ! just a test for gravity waves ! PD=62000. ! grid%u=0.0 ! grid%v=0.0 ! T=300. ! Q=0.0 ! Q2=0.0 ! CWM=0.0 ! FIS=0.0 ! testx ! DO J = JTS, MIN(JTE,JDE-1) ! DO K = KTS,KTE ! DO I = ITS, MIN(ITE,IDE-1) ! grid%sm(I,J)=I ! grid%u(I,K,J)=J ! ENDDO ! ENDDO ! ENDDO ! ! deallocs DEALLOCATE(KHL2,KVL2,KHH2,KVH2) DEALLOCATE(DXJ,WPDARJ,CPGFUJ,CURVJ) DEALLOCATE(FCPJ,FDIVJ,FADJ) DEALLOCATE(HDACJ,DDMPUJ,DDMPVJ) DEALLOCATE(KHLA,KHHA) DEALLOCATE(KVLA,KVHA) END SUBROUTINE med_initialize_nest_nmm !====================================================================== subroutine smdhld(ime,jme,h,s,lines,nsmud) character(len=255) :: message dimension ihw(jme),ihe(jme) dimension h(ime,jme),s(ime,jme) & & ,hbms(ime,jme),hne(ime,jme),hse(ime,jme) !----------------------------------------------------------------------- do j=1,jme ihw(j)=-mod(j,2) ihe(j)=ihw(j)+1 enddo !----------------------------------------------------------------------- do j=1,jme do i=1,ime hbms(i,j)=1.-s(i,j) enddo enddo ! jmelin=jme-lines+1 ibas=lines/2 m2l=mod(lines,2) ! do j=lines,jmelin ihl=ibas+mod(j,2)+m2l*mod(j+1,2) ihh=ime-ibas-m2l*mod(j+1,2) ! do i=ihl,ihh hbms(i,j)=0. enddo enddo !----------------------------------------------------------------------- do ks=1,nsmud write(message,*) 'H(1,1): ', h(1,1) CALL wrf_message(trim(message)) write(message,*) 'H(3,1): ', h(1,1) CALL wrf_message(trim(message)) !----------------------------------------------------------------------- do j=1,jme-1 do i=1,ime-1 hne(i,j)=h(i+ihe(j),j+1)-h(i,j) enddo enddo do j=2,jme do i=1,ime-1 hse(i,j)=h(i+ihe(j),j-1)-h(i,j) enddo enddo ! do j=2,jme-1 do i=1+mod(j,2),ime-1 h(i,j)=(hne(i,j)-hne(i+ihw(j),j-1) & & +hse(i,j)-hse(i+ihw(j),j+1))*hbms(i,j)*0.125+h(i,j) enddo enddo !----------------------------------------------------------------------- !!! smooth around boundary somehow? ! special treatment for four corners if (hbms(1,1) .eq. 1) then h(1,1)=0.75*h(1,1)+0.125*h(1+ihe(1),2)+ & & 0.0625*(h(2,1)+h(1,3)) endif if (hbms(ime,1) .eq. 1) then h(ime,1)=0.75*h(ime,1)+0.125*h(ime+ihw(1),2)+ & & 0.0625*(h(ime-1,1)+h(ime,3)) endif if (hbms(1,jme) .eq. 1) then h(1,jme)=0.75*h(1,jme)+0.125*h(1+ihe(jme),jme-1)+ & & 0.0625*(h(2,jme)+h(1,jme-2)) endif if (hbms(ime,jme) .eq. 1) then h(ime,jme)=0.75*h(ime,jme)+0.125*h(ime+ihw(jme),jme-1)+ & & 0.0625*(h(ime-1,jme)+h(ime,jme-2)) endif ! S bound J=1 do I=2,ime-1 if (hbms(I,J) .eq. 1) then h(I,J)=0.75*h(I,J)+0.125*(h(I+ihw(J),J+1)+h(I+ihe(J),J+1)) endif enddo ! N bound J=JME do I=2,ime-1 if (hbms(I,J) .eq. 1) then h(I,J)=0.75*h(I,J)+0.125*(h(I+ihw(J),J-1)+h(I+ihe(J),J-1)) endif enddo ! W bound I=1 do J=3,jme-2 if (hbms(I,J) .eq. 1) then h(I,J)=0.75*h(I,J)+0.125*(h(I+ihe(J),J+1)+h(I+ihe(J),J-1)) endif enddo ! E bound I=IME do J=3,jme-2 if (hbms(I,J) .eq. 1) then h(I,J)=0.75*h(I,J)+0.125*(h(I+ihw(J),J+1)+h(I+ihw(J),J-1)) endif enddo enddo ! end ks loop !----------------------------------------------------------------------- return end subroutine smdhld !-------------------------------------------------------------------------------------- #if 0 SUBROUTINE initial_nest_pivot ( parent , nest, iloc, jloc ) !========================================================================================== ! ! This program produces i_start and j_start for the nested domain depending on the ! central lat-lon of the storm. ! !========================================================================================== USE module_domain USE module_configure USE module_timing USE module_dm IMPLICIT NONE TYPE(domain) , POINTER :: parent , nest INTEGER, INTENT(OUT) :: ILOC,JLOC INTEGER :: IMS,IME,JMS,JME,KMS,KME INTEGER :: IDS,IDE,JDS,JDE,KDS,KDE INTEGER :: IMS,IME,JMS,JME,KMS,KME INTEGER :: ITS,ITE,JTS,JTE,KTS,KTE INTEGER :: NIDE,NJDE ! nest dimension INTEGER :: I,J,ITER,IDUM,JDUM REAL :: ALAT,ALON,DIFF1,DIFF2,ERR REAL :: parent_CLAT,parent_CLON,parent_SLAT,parent_SLON REAL :: parent_WBD,parent_SBD,parent_DLMD,parent_DPHD !======================================================================================== ! First obtain central latitude and longitude for the parent domain CALL nl_get_cen_lat (parent%ID, parent_CLAT) CALL nl_get_cen_lon (parent%ID, parent_CLON) ! CALL nl_get_storm_lat (parent%ID, parent_SLAT) ! CALL nl_get_storm_lon (parent%ID, parent_SLON) ! Parent grid configuration, including, western and southern boundary IDS = parent%sd31 IDE = parent%ed31 JDS = parent%sd32 JDE = parent%ed32 KDS = parent%sd33 KDE = parent%ed33 IMS = parent%sm31 IME = parent%em31 JMS = parent%sm32 JME = parent%em32 KMS = parent%sm33 KME = parent%em33 ITS = parent%sp31 ITE = parent%ep31 JTS = parent%sp32 JTE = parent%ep32 KTS = parent%sp33 KTE = parent%ep33 NIDE = nest%ed31 NJDE = nest%ed32 parent_DLMD = parent%dx ! DLMD: dlamda in degrees parent_DPHD = parent%dy ! DPHD: dphi in degrees parent_WBD = -(IDE-2)*parent%dx ! WBD0: in deg;factor 2 takes care of dummy last column parent_SBD = -((JDE-1)/2)*parent%dy ! SBD0: in degrees; note that JDE-1 should be odd ALAT = parent_SLAT - 0.5*(NJDE-2)*parent_DPHD/nest%parent_grid_ratio ALON = parent_SLON - 1.0*(NIDE-2)*parent_DLMD/nest%parent_grid_ratio CALL EARTH_LATLON ( parent%HLAT,parent%HLON,parent%VLAT,parent%VLON, & !output parent_DLMD,parent_DPHD,parent_WBD,parent_SBD, & !inputs parent_CLAT,parent_CLON, & IDS,IDE,JDS,JDE,KDS,KDE, & IMS,IME,JMS,JME,KMS,KME, & ITS,ITE,JTS,JTE,KTS,KTE ) ! start iteration ILOC=-99 JLOC=-99 ERR=0.1 ITER=1 100 CONTINUE DO J = JTS,min(JTE,JDE-1) DO I = ITS,min(ITE,IDE-1) DIFF1 = ABS(ALAT - parent%HLAT(I,J)) DIFF2 = ABS(ALON - parent%HLON(I,J)) IF(DIFF1 .LE. ERR .AND. DIFF2 .LE. ERR)THEN ILOC=I JLOC=J ENDIF ENDDO ENDDO CALL wrf_dm_maxval_integer ( ILOC, idum, jdum ) CALL wrf_dm_maxval_integer ( JLOC, idum, jdum ) IF(ILOC .EQ. -99 .AND. JLOC .EQ. -99)THEN ERR=ERR+0.1 ITER=ITER+1 IF(ITER .LE. 100)GO TO 100 ENDIF IF(ILOC .NE. -99 .AND. JLOC .NE. -99)THEN WRITE(message,*)'NOTE: I_PARENT_START AND J_PARENT_START FOUND FOR THE NESTED DOMAIN CONFIGURATION AT ITER=',ITER CALL wrf_message(trim(message)) WRITE(message,*)'istart=',ILOC CALL wrf_message(trim(message)) WRITE(message,*)'jstart=',JLOC CALL wrf_message(trim(message)) ELSE ILOC=IDE/3 JLOC=JDE/3 ! WRITE(message,*)'WARNING: COULD NOT LOCATE I_PARENT_START AND J_PARENT_START FROM INPUT STORM INFO' CALL wrf_message(trim(message)) WRITE(message,*)'ISTART=',IDE/3 CALL wrf_message(trim(message)) WRITE(message,*)'JSTART=',JDE/3 CALL wrf_message(trim(message)) ENDIF RETURN END SUBROUTINE initial_nest_pivot !============================================================================================ #endif LOGICAL FUNCTION cd_feedback_mask_orig( pig, ips_save, ipe_save , pjg, jps_save, jpe_save, xstag, ystag ) INTEGER, INTENT(IN) :: pig, ips_save, ipe_save , pjg, jps_save, jpe_save LOGICAL, INTENT(IN) :: xstag, ystag INTEGER ioff, joff ioff = 0 ; joff = 0 IF ( xstag ) ioff = 1 IF ( ystag ) joff = 1 cd_feedback_mask_orig = ( pig .ge. ips_save+1 .and. & pjg .ge. jps_save+1 .and. & pig .le. ipe_save-1 +ioff .and. & pjg .le. jpe_save-1 +joff ) END FUNCTION cd_feedback_mask_orig LOGICAL FUNCTION cd_feedback_mask( pig, ips_save, ipe_save , pjg, jps_save, jpe_save, xstag, ystag ) INTEGER, INTENT(IN) :: pig, ips_save, ipe_save , pjg, jps_save, jpe_save LOGICAL, INTENT(IN) :: xstag, ystag INTEGER ioff, joff ioff = 0 ; joff = 0 IF ( xstag ) ioff = 1 IF ( ystag ) joff = 1 cd_feedback_mask = ( pig .ge. ips_save+1 .and. & pjg .ge. jps_save+2 .and. & pig .le. ipe_save-1-mod(pjg-jps_save,2) .and. & pjg .le. jpe_save-2 ) END FUNCTION cd_feedback_mask LOGICAL FUNCTION cd_feedback_mask_v( pig, ips_save, ipe_save , pjg, jps_save, jpe_save, xstag, ystag ) INTEGER, INTENT(IN) :: pig, ips_save, ipe_save , pjg, jps_save, jpe_save LOGICAL, INTENT(IN) :: xstag, ystag INTEGER ioff, joff ioff = 0 ; joff = 0 IF ( xstag ) ioff = 1 IF ( ystag ) joff = 1 cd_feedback_mask_v = ( pig .ge. ips_save+1 .and. & pjg .ge. jps_save+2 .and. & pig .le. ipe_save-1-mod(pjg-jps_save+1,2) .and. & pjg .le. jpe_save-2 ) END FUNCTION cd_feedback_mask_v !---------------------------------------------------------------------------- #else SUBROUTINE stub_nmm_nest_stub END SUBROUTINE stub_nmm_nest_stub #endif RECURSIVE SUBROUTINE find_ijstart_level ( grid, i_start, j_start, level ) ! Dusan Jovic USE module_domain IMPLICIT NONE ! Input data. TYPE(domain) :: grid INTEGER, INTENT (OUT) :: i_start, j_start, level INTEGER :: iadd if (grid%parent_id == 0 ) then i_start = 1 j_start = 1 level = 0 else call find_ijstart_level ( grid%parents(1)%ptr, i_start, j_start, level ) if (level > 0) then iadd = (i_start-1)*3 if ( mod(j_start,2).ne.0 .and. mod(grid%j_parent_start,2).ne.0 ) iadd = iadd - 1 if ( mod(j_start,2).eq.0 .and. mod(grid%j_parent_start,2).eq.0 ) iadd = iadd + 2 else iadd = -mod(grid%j_parent_start,2) end if i_start = iadd + grid%i_parent_start*3 - 1 j_start = ( (j_start-1) + (grid%j_parent_start-1) ) * 3 + 1 level = level + 1 end if END SUBROUTINE find_ijstart_level