! !-- Module for Gravity Wave Drag (GWD) and Mountain Blocking (MB) ! !-- Initially incorporated into the WRF NMM from the GFS by B. Ferrier ! in April/May 2007. ! ! Search for "ORIGINAL DOCUMENTATION BLOCK" for further description. ! !####################################################################### ! MODULE module_gwd ! ! USE MODULE_DM ! to get processor element USE MODULE_EXT_INTERNAL ! to assign fortan unit number ! !-- Contains subroutines GWD_init, GWD_driver, and GWD_col ! !####################################################################### ! INTEGER, PARAMETER :: KIND_PHYS=SELECTED_REAL_KIND(13,60) ! the '60' maps to 64-bit real INTEGER,PRIVATE,SAVE :: IMX, NMTVR, IDBG, JDBG REAL,PRIVATE,SAVE :: RAD_TO_DEG !-- Convert radians to degrees REAL,PRIVATE,SAVE :: DEG_TO_RAD !-- Convert degrees to radians REAL (KIND=KIND_PHYS),PRIVATE,SAVE :: DELTIM,RDELTIM REAL(kind=kind_phys),PRIVATE,PARAMETER :: SIGFAC=0.0 !-- Key tunable parameter !dbg real,private,save :: dumin,dumax,dvmin,dvmax !dbg ! CONTAINS ! !-- Initialize variables used in GWD + MB ! SUBROUTINE GWD_init (DTPHS,DELX,DELY,CEN_LAT,CEN_LON,RESTRT & & ,GLAT,GLON,CROT,SROT,HANGL & & ,IDS,IDE,JDS,JDE,KDS,KDE & & ,IMS,IME,JMS,JME,KMS,KME & & ,ITS,ITE,JTS,JTE,KTS,KTE ) ! IMPLICIT NONE ! !== INPUT: !-- DELX, DELY - DX, DY grid resolutions in zonal, meridional directions (m) !-- CEN_LAT, CEN_LON - central latitude, longitude (degrees) !-- RESTRT - logical flag for restart file (true) or WRF input file (false) !-- GLAT, GLON - central latitude, longitude at mass points (radians) !-- CROT, SROT - cosine and sine of the angle between Earth and model coordinates !-- HANGL - angle of the mountain range w/r/t east (convert to degrees) ! !-- Saved variables within module: !-- IMX - in the GFS it is an equivalent number of points along a latitude ! circle (e.g., IMX=3600 for a model resolution of 0.1 deg) ! => Calculated at start of model integration in GWD_init !-- NMTVR - number of input 2D orographic fields !-- GRAV = gravitational acceleration !-- DELTIM - physics time step (s) !-- RDELTIM - reciprocal of physics time step (s) ! !== INPUT indices: !-- ids start index for i in domain !-- ide end index for i in domain !-- jds start index for j in domain !-- jde end index for j in domain !-- kds start index for k in domain !-- kde end index for k in domain !-- ims start index for i in memory !-- ime end index for i in memory !-- jms start index for j in memory !-- jme end index for j in memory !-- kms start index for k in memory !-- kme end index for k in memory !-- its start index for i in tile !-- ite end index for i in tile !-- jts start index for j in tile !-- jte end index for j in tile !-- kts start index for k in tile !-- kte end index for k in tile ! REAL, INTENT(IN) :: DTPHS,DELX,DELY,CEN_LAT,CEN_LON LOGICAL, INTENT(IN) :: RESTRT REAL, INTENT(IN), DIMENSION (ims:ime,jms:jme) :: GLON,GLAT REAL, INTENT(OUT), DIMENSION (ims:ime,jms:jme) :: CROT,SROT REAL, INTENT(INOUT), DIMENSION (ims:ime,jms:jme) :: HANGL INTEGER, INTENT(IN) :: IDS,IDE,JDS,JDE,KDS,KDE & & ,IMS,IME,JMS,JME,KMS,KME & & ,ITS,ITE,JTS,JTE,KTS,KTE ! !-- Local variables: ! REAL, PARAMETER :: POS1=1.,NEG1=-1. REAL :: DX,DTR,LAT0,LoN0,CLAT0,SLAT0,CLAT,DLON,X,Y,TLON,ROT INTEGER :: I,J !dbg !dbg real :: xdbg,ydbg,d_x,d_y,dist,dist_min !dbg data xdbg,ydbg / -118.3,36 / ! 118.3W 36 N ! !----------------------------------------------------------------------- ! DX=SQRT((DELX)**2+(DELY)**2) !-- Model resolution in degrees !-- IMX is the number of grid points along a latitude circle in the GFS IMX=INT(360./DX+.5) !dbg IMX=1152 !dbg -- Match the grid point printed from GFS run NMTVR=14 !-- 14 input fields for orography DELTIM=DTPHS RDELTIM=1./DTPHS ! !-- Calculate angle of rotation (ROT) between Earth and model coordinates, ! but pass back out cosine (CROT) and sine (SROT) of this angle ! DTR=ACOS(-1.)/180. !-- convert from degrees to radians DEG_TO_RAD=DTR !-- save conversion from degrees to radians ! LAT0=DTR*CEN_LON !-- central latitude of grid in radians LoN0=DTR*CEN_LAT !-- central longitude of grid in radians ! DTR=1./DTR !-- convert from radians to degrees RAD_TO_DEG=DTR !-- save conversion from radians to degrees ! CLAT0=COS(LAT0) SLAT0=SIN(LAT0) DO J=JTS,JTE DO I=ITS,ITE CLAT=COS(GLAT(I,J)) DLON=GLON(I,J)-LoN0 X=CLAT0*CLAT*COS(DLON)+SLAT0*SIN(GLAT(I,J)) Y=-CLAT*SIN(DLON) TLON=ATAN(Y/X) !-- model longitude X=SLAT0*SIN(TLON)/CLAT Y=MIN(POS1, MAX(NEG1, X) ) ROT=ASIN(Y) !-- angle between geodetic & model coordinates CROT(I,J)=COS(ROT) SROT(I,J)=SIN(ROT) ENDDO !-- I ENDDO !-- J IF (.NOT.RESTRT) THEN !-- Convert from radians to degrees for WRF input files only DO J=JTS,JTE DO I=ITS,ITE HANGL(I,J)=DTR*HANGL(I,J) !-- convert to degrees (+/-90 deg) ENDDO !-- I ENDDO !-- J ENDIF !dbg !dbg dumin=-1. !dbg dumax=1. !dbg dvmin=-1. !dbg dvmax=1. !dbg print *,'delx=',delx,' dely=',dely,' dx=',dx,' imx=',imx !dbg dtr=1./dtr !-- convert from degrees back to radians !dbg dist_min=dtr*DX !-- grid length in radians !dbg xdbg=dtr*xdbg !-- convert xdbg to radians !dbg ydbg=dtr*ydbg !-- convert ydbg to radians !dbg idbg=-100 !dbg jdbg=-100 !dbg print *,'dtr,dx,dist_min,xdbg,ydbg=',dtr,dx,dist_min,xdbg,ydbg !dbg do j=jts,jte !dbg do i=its,ite !dbg !-- Find i,j for xdbg, ydbg !dbg d_x=cos(glat(i,j))*(glon(i,j)-xdbg) !dbg d_y=(glat(i,j)-ydbg) !dbg dist=sqrt(d_x*d_x+d_y*d_y) !dbg !! print *,'i,j,glon,glat,d_x,d_y,dist=',i,j,glon(i,j),glat(i,j),d_x,d_y,dist !dbg if (dist < dist_min) then !dbg dist_min=dist !dbg idbg=i !dbg jdbg=j !dbg print *,'dist_min,idbg,jdbg=',dist_min,idbg,jdbg !dbg endif !dbg enddo !-- I !dbg enddo !-- J !dbg if (idbg>0 .and. jdbg>0) print *,'idbg=',idbg,' jdbg=',jdbg ! END SUBROUTINE GWD_init ! !----------------------------------------------------------------------- ! SUBROUTINE GWD_driver(U,V,T,Q,Z,DP,PINT,PMID,EXNR, KPBL, ITIME & & ,HSTDV,HCNVX,HASYW,HASYS,HASYSW,HASYNW & & ,HLENW,HLENS,HLENSW,HLENNW & & ,HANGL,HANIS,HSLOP,HZMAX,CROT,SROT & & ,DUDT,DVDT,UGWDsfc,VGWDsfc & & ,IDS,IDE,JDS,JDE,KDS,KDE & & ,IMS,IME,JMS,JME,KMS,KME & & ,ITS,ITE,JTS,JTE,KTS,KTE ) ! !== INPUT: !-- U, V - zonal (U), meridional (V) winds at mass points (m/s) !-- T, Q - temperature (C), specific humidity (kg/kg) !-- DP - pressure thickness (Pa) !-- Z - geopotential height (m) !-- PINT, PMID - interface and midlayer pressures, respectively (Pa) !-- EXNR - (p/p0)**(Rd/Cp) !-- KPBL - vertical index at PBL top !-- ITIME - model time step (=NTSD) !-- HSTDV - orographic standard deviation !-- HCNVX - normalized 4th moment of the orographic convexity !-- Template for the next two sets of 4 arrays: ! NWD 1 2 3 4 5 6 7 8 ! WD W S SW NW E N NE SE !-- Orographic asymmetry (HASYx, x=1-4) for upstream & downstream flow (4 planes) !-- * HASYW - orographic asymmetry for upstream & downstream flow in W-E plane !-- * HASYS - orographic asymmetry for upstream & downstream flow in S-N plane !-- * HASYSW - orographic asymmetry for upstream & downstream flow in SW-NE plane !-- * HASYNW - orographic asymmetry for upstream & downstream flow in NW-SE plane !-- Orographic length scale or mountain width (4 planes) !-- * HLENW - orographic length scale for upstream & downstream flow in W-E plane !-- * HLENS - orographic length scale for upstream & downstream flow in S-N plane !-- * HLENSW - orographic length scale for upstream & downstream flow in SW-NE plane !-- * HLENNW - orographic length scale for upstream & downstream flow in NW-SE plane !-- HANGL - angle (degrees) of the mountain range w/r/t east !-- HANIS - anisotropy/aspect ratio of orography !-- HSLOP - slope of orography !-- HZMAX - max height above mean orography !-- CROT, SROT - cosine & sine of the angle between Earth & model coordinates ! !== OUTPUT: !-- DUDT, DVDT - zonal, meridional wind tendencies !-- UGWDsfc, VGWDsfc - zonal, meridional surface wind stresses (N/m**2) ! !== INPUT indices: !-- ids start index for i in domain !-- ide end index for i in domain !-- jds start index for j in domain !-- jde end index for j in domain !-- kds start index for k in domain !-- kde end index for k in domain !-- ims start index for i in memory !-- ime end index for i in memory !-- jms start index for j in memory !-- jme end index for j in memory !-- kms start index for k in memory !-- kme end index for k in memory !-- its start i index for tile !-- ite end i index for tile !-- jts start j index for tile !-- jte end j index for tile !-- kts start index for k in tile !-- kte end index for k in tile ! !-- INPUT variables: ! REAL, INTENT(IN), DIMENSION (ims:ime, kms:kme, jms:jme) :: & & U,V,T,Q,Z,DP,PINT,PMID,EXNR REAL, INTENT(IN), DIMENSION (ims:ime, jms:jme) :: HSTDV,HCNVX & & ,HASYW,HASYS,HASYSW,HASYNW,HLENW,HLENS,HLENSW,HLENNW,HANGL & & ,HANIS,HSLOP,HZMAX,CROT,SROT INTEGER, INTENT(IN), DIMENSION (ims:ime, jms:jme) :: KPBL INTEGER, INTENT(IN) :: ids,ide,jds,jde,kds,kde & &, ims,ime,jms,jme,kms,kme & &, its,ite,jts,jte,kts,kte,ITIME ! !-- OUTPUT variables: ! REAL, INTENT(OUT), DIMENSION (ims:ime, kms:kme, jms:jme) :: & & DUDT,DVDT REAL, INTENT(OUT), DIMENSION (ims:ime, jms:jme) :: UGWDsfc,VGWDsfc ! !-- Local variables !-- DUsfc, DVsfc - zonal, meridional wind stresses (diagnostics) ! INTEGER, PARAMETER :: IM=1 !-- Reduces changes in subroutine GWPDS REAL(KIND=KIND_PHYS), PARAMETER :: G=9.806, GHALF=.5*G & &, THRESH=1.E-6, dtlarge=1. !dbg INTEGER, DIMENSION (IM) :: LPBL REAL(KIND=KIND_PHYS), DIMENSION (IM,4) :: OA4,CLX4 REAL(KIND=KIND_PHYS), DIMENSION (IM) :: DUsfc,DVsfc & &, HPRIME,OC,THETA,SIGMA,GAMMA,ELVMAX REAL(KIND=KIND_PHYS), DIMENSION (IM,KTS:KTE) :: DUDTcol,DVDTcol & &, Ucol,Vcol,Tcol,Qcol,DPcol,Pcol,EXNcol,PHIcol REAL(KIND=KIND_PHYS), DIMENSION (IM,KTS:KTE+1) :: PINTcol,PHILIcol INTEGER :: I,J,IJ,K,Imid,Jmid REAL :: Ugeo,Vgeo,Umod,Vmod, TERRtest,TERRmin REAL(KIND=KIND_PHYS) :: TEST CHARACTER(LEN=255) :: message !dbg logical :: lprnt !dbg character (len=26) :: label integer :: kpblmin,kpblmax, mype, iunit real :: hzmaxmin,hzmaxmax,hanglmin,hanglmax,hslopmin,hslopmax,hanismin,hanismax & ,hstdvmin,hstdvmax,hcnvxmin,hcnvxmax,hasywmin,hasywmax,hasysmin,hasysmax & ,hasyswmin,hasyswmax,hasynwmin,hasynwmax,hlenwmin,hlenwmax,hlensmin,hlensmax & ,hlenswmin,hlenswmax,hlennwmin,hlennwmax,zsmin,zsmax,delu,delv ! Added this declaration real :: helvmin,helvmax !dbg ! !-------------------------- Executable below ------------------------- ! lprnt=.false. !dbg if (itime <= 1) then CALL WRF_GET_MYPROC(MYPE) !-- Get processor number kpblmin=100 kpblmax=-100 hzmaxmin=1.e6 hzmaxmax=-1.e6 hanglmin=1.e6 hanglmax=-1.e6 hslopmin=1.e6 hslopmax=-1.e6 hanismin=1.e6 hanismax=-1.e6 hstdvmin=1.e6 hstdvmax=-1.e6 hcnvxmin=1.e6 hcnvxmax=-1.e6 hasywmin=1.e6 hasywmax=-1.e6 hasysmin=1.e6 hasysmax=-1.e6 hasyswmin=1.e6 hasyswmax=-1.e6 hasynwmin=1.e6 hasynwmax=-1.e6 hlenwmin=1.e6 hlenwmax=-1.e6 hlensmin=1.e6 hlensmax=-1.e6 hlenswmin=1.e6 hlenswmax=-1.e6 hlennwmin=1.e6 hlennwmax=-1.e6 zsmin=1.e6 zsmax=-1.e6 ! Added initialization of helvmin and helvmax helvmin=1.e6 helvmax=-1.e6 do j=jts,jte do i=its,ite kpblmin=min(kpblmin,kpbl(i,j)) kpblmax=max(kpblmax,kpbl(i,j)) helvmin=min(helvmin,hzmax(i,j)) helvmax=max(helvmax,hzmax(i,j)) hanglmin=min(hanglmin,hangl(i,j)) hanglmax=max(hanglmax,hangl(i,j)) hslopmin=min(hslopmin,hslop(i,j)) hslopmax=max(hslopmax,hslop(i,j)) hanismin=min(hanismin,hanis(i,j)) hanismax=max(hanismax,hanis(i,j)) hstdvmin=min(hstdvmin,hstdv(i,j)) hstdvmax=max(hstdvmax,hstdv(i,j)) hcnvxmin=min(hcnvxmin,hcnvx(i,j)) hcnvxmax=max(hcnvxmax,hcnvx(i,j)) hasywmin=min(hasywmin,hasyw(i,j)) hasywmax=max(hasywmax,hasyw(i,j)) hasysmin=min(hasysmin,hasys(i,j)) hasysmax=max(hasysmax,hasys(i,j)) hasyswmin=min(hasyswmin,hasysw(i,j)) hasyswmax=max(hasyswmax,hasysw(i,j)) hasynwmin=min(hasynwmin,hasynw(i,j)) hasynwmax=max(hasynwmax,hasynw(i,j)) hlenwmin=min(hlenwmin,hlenw(i,j)) hlenwmax=max(hlenwmax,hlenw(i,j)) hlensmin=min(hlensmin,hlens(i,j)) hlensmax=max(hlensmax,hlens(i,j)) hlenswmin=min(hlenswmin,hlensw(i,j)) hlenswmax=max(hlenswmax,hlensw(i,j)) hlennwmin=min(hlennwmin,hlennw(i,j)) hlennwmax=max(hlennwmax,hlennw(i,j)) zsmin=min(zsmin,z(i,1,j)) zsmax=max(zsmax,z(i,1,j)) enddo enddo write(message,*) 'Maximum and minimum values within GWD-driver for MYPE=',MYPE write(message,"(i3,2(a,e12.5))") mype,': deltim=',deltim,' rdeltim=',rdeltim CALL wrf_message(trim(message)) write(message,"(i3,2(a,i3))") mype,': kpblmin=',kpblmin,' kpblmax=',kpblmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': helvmin=',helvmin,' helvmax=',helvmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hanglmin=',hanglmin,' hanglmax=',hanglmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hslopmin=',hslopmin,' hslopmax=',hslopmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hanismin=',hanismin,' hanismax=',hanismax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hstdvmin=',hstdvmin,' hstdvmax=',hstdvmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hcnvxmin=',hcnvxmin,' hcnvxmax=',hcnvxmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hasywmin=',hasywmin,' hasywmax=',hasywmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hasysmin=',hasysmin,' hasysmax=',hasysmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hasyswmin=',hasyswmin,' hasyswmax=',hasyswmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hasynwmin=',hasynwmin,' hasynwmax=',hasynwmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hlenwmin=',hlenwmin,' hlenwmax=',hlenwmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hlensmin=',hlensmin,' hlensmax=',hlensmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hlenswmin=',hlenswmin,' hlenswmax=',hlenswmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': hlennwmin=',hlennwmin,' hlennwmax=',hlennwmax CALL wrf_message(trim(message)) write(message,"(i3,2(a,e12.5))") mype,': zsmin=',zsmin,' zsmax=',zsmax CALL wrf_message(trim(message)) endif ! if (itime <= 1) then !dbg ! !-- Initialize variables ! DO J=JMS,JME DO K=KMS,KME DO I=IMS,IME DUDT(I,K,J)=0. DVDT(I,K,J)=0. ENDDO ENDDO ENDDO ! DO J=JMS,JME DO I=IMS,IME UGWDsfc(I,J)=0. VGWDsfc(I,J)=0. ENDDO ENDDO ! !-- For debugging, find approximate center point within each tile ! !dbg Imid=.5*(ITS+ITE) !dbg Jmid=.5*(JTS+JTE) ! DO J=JTS,JTE DO I=ITS,ITE if (kpbl(i,j)kte) go to 100 ! !-- Initial test to see if GWD calculations should be made, otherwise skip ! TERRtest=HZMAX(I,J)+SIGFAC*HSTDV(I,J) TERRmin=Z(I,2,J)-Z(I,1,J) IF (TERRtest < TERRmin) GO TO 100 ! !-- For debugging: ! !dbg lprnt=.false. !dbg if (i==idbg .and. j==jdbg .and. itime<=1) lprnt=.true. !dbg ! 200 CONTINUE ! DO K=KTS,KTE DUDTcol(IM,K)=0. DVDTcol(IM,K)=0. ! !-- Transform/rotate winds from model to geodetic (Earth) coordinates ! Ucol(IM,K)=U(I,K,J)*CROT(I,J)+V(I,K,J)*SROT(I,J) Vcol(IM,K)=V(I,K,J)*CROT(I,J)-U(I,K,J)*SROT(I,J) ! Tcol(IM,K)=T(I,K,J) Qcol(IM,K)=Q(I,K,J) ! !-- Convert from Pa to centibars, which is what's used in subroutine GWD_col ! DPcol(IM,K)=.001*DP(I,K,J) PINTcol(IM,K)=.001*PINT(I,K,J) Pcol(IM,K)=.001*PMID(I,K,J) EXNcol(IM,K)=EXNR(I,K,J) ! !-- Next 2 fields are geopotential above the surface at the lower interface ! and at midlayer ! PHILIcol(IM,K)=G*(Z(I,K,J)-Z(I,1,J)) PHIcol(IM,K)=GHALF*(Z(I,K,J)+Z(I,K+1,J))-G*Z(I,1,J) ENDDO !- K ! PINTcol(IM,KTE+1)=.001*PINT(I,KTE+1,J) PHILIcol(IM,KTE+1)=G*(Z(I,KTE+1,J)-Z(I,1,J)) ! !-- Terrain-specific inputs: ! HPRIME(IM)=HSTDV(I,J) !-- standard deviation of orography OC(IM)=HCNVX(I,J) !-- Normalized convexity OA4(IM,1)=HASYW(I,J) !-- orographic asymmetry in W-E plane OA4(IM,2)=HASYS(I,J) !-- orographic asymmetry in S-N plane OA4(IM,3)=HASYSW(I,J) !-- orographic asymmetry in SW-NE plane OA4(IM,4)=HASYNW(I,J) !-- orographic asymmetry in NW-SE plane CLX4(IM,1)=HLENW(I,J) !-- orographic length scale in W-E plane CLX4(IM,2)=HLENS(I,J) !-- orographic length scale in S-N plane CLX4(IM,3)=HLENSW(I,J) !-- orographic length scale in SW-NE plane CLX4(IM,4)=HLENNW(I,J) !-- orographic length scale in NW-SE plane THETA(IM)=HANGL(I,J) ! SIGMA(IM)=HSLOP(I,J) ! GAMMA(IM)=HANIS(I,J) ! ELVMAX(IM)=HZMAX(I,J) ! LPBL(IM)=KPBL(I,J) ! !dbg IF (LPBL(IM)KTE) & !dbg & print *,'Wacky values for KPBL: I,J,N,LPBL=',I,J,ITIME,LPBL(IM) ! !-- Output (diagnostics) ! DUsfc(IM)=0. !-- U wind stress DVsfc(IM)=0. !-- V wind stress ! !dbg !dbg if (LPRNT) then !dbg ! !dbg !-- Following code is for ingesting GFS-derived inputs for final testing !dbg ! !dbg CALL INT_GET_FRESH_HANDLE(iunit) !dbg close(iunit) !dbg open(unit=iunit,file='gfs_gwd.input',form='formatted',iostat=ier) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (Ucol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (Vcol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (Tcol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (Qcol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (PINTcol(im,k), k=kts,kte+1) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (DPcol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (Pcol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (EXNcol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (PHILIcol(im,k), k=kts,kte+1) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (PHIcol(im,k), k=kts,kte) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) hprime(im) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) oc(im) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (oa4(im,k), k=1,4) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) (clx4(im,k), k=1,4) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) theta(im) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) sigma(im) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) gamma(im) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) elvmax(im) !dbg read(iunit,*) ! skip line !dbg read(iunit,*) lpbl(im) !dbg close(iunit) write(label,"('GWD:i,j,n=',2i5,i6)") I,J,ITIME !dbg write(6,"(2a)") LABEL,' in GWD_driver: K U V T Q Pi DP P EX PHIi PHI' !dbg do k=kts,kte !dbg write(6,"(i3,10e12.4)") k,Ucol(im,k),Vcol(im,k),Tcol(im,k) & !dbg ,Qcol(im,k),PINTcol(im,k),DPcol(im,k),Pcol(im,k),EXNcol(im,k) & !dbg ,PHILIcol(im,k),PHIcol(im,k) !dbg enddo !dbg write(6,"(2(a,e12.4),2(a,4e12.4/),4(a,e12.4),a,i3) )") & !dbg 'GWD_driver: hprime(im)=',hprime(im),' oc(im)=',oc(im) & !dbg ,' oa4(im,1-4)=',(oa4(im,k),k=1,4) & !dbg ,' clx4(im,1-4)=',(clx4(im,k),k=1,4) & !dbg ,' theta=',theta(im),' sigma(im)=',sigma(im) & !dbg ,' gamma(im)=',gamma(im),' elvmax(im)=',elvmax(im) & !dbg ,' lpbl(im)=',lpbl(im) !dbg endif !dbg !======================================================================= ! CALL GWD_col(DVDTcol,DUDTcol, DUsfc,DVsfc & ! Output &, Ucol,Vcol,Tcol,Qcol,PINTcol,DPcol,Pcol,EXNcol & ! Met input &, PHILIcol,PHIcol & ! Met input &, HPRIME,OC,OA4,CLX4,THETA,SIGMA,GAMMA,ELVMAX & ! Topo input &, LPBL,IM,KTS,KTE,LABEL,LPRNT ) ! Indices + debugging ! !======================================================================= ! !dbg !dbg ! !dbg ! IF (.NOT.LPRNT) THEN !dbg ! TEST=0. !dbg ! DO K=KTS,KTE !dbg ! TEST=MAX( TEST, ABS(DUDTcol(IM,K)), ABS(DVDTcol(IM,K)) ) !dbg ! if ( ABS(DUDTcol(IM,K)) > RDELTIM) print *,'k,DUDTcol=',k,DUDTcol(IM,K) !dbg ! if ( ABS(DVDTcol(IM,K)) > RDELTIM) print *,'k,DVDTcol=',k,DVDTcol(IM,K) !dbg ! ENDDO !dbg ! IF (TEST>RDELTIM) THEN !dbg ! LPRNT=.TRUE. !dbg ! Imid=I !dbg ! Jmid=J !dbg ! GO TO 200 !dbg ! ENDIF !dbg ! ENDIF !dbg ! TEST=ABS(DUsfc(IM))+ABS(DVsfc(IM)) !dbg ! if (.not.lprnt) then !dbg ! do k=kts,kte !dbg ! du=DUDTcol(IM,K)*DELTIM !dbg ! dv=DVDTcol(IM,K)*DELTIM !dbg ! if (du < dumin) then !dbg ! lprnt=.true. !dbg ! dumin=1.5*du !dbg ! endif !dbg ! if (du > dumax) then !dbg ! lprnt=.true. !dbg ! dumax=1.5*du !dbg ! endif !dbg ! if (dv < dvmin) then !dbg ! lprnt=.true. !dbg ! dvmin=1.5*dv !dbg ! endif !dbg ! if (dv > dvmax) then !dbg ! lprnt=.true. !dbg ! dvmax=1.5*dv !dbg ! endif !dbg ! enddo !dbg ! if (lprnt) go to 200 !dbg ! else !dbg if (lprnt) then !dbg print *,'DUsfc,DVsfc,CROT,SROT,DELTIM=',DUsfc(IM),DVsfc(IM) & !dbg &,CROT(I,J),SROT(I,J),DELTIM !dbg print *,' K P | Ucol Ugeo DUDTcol*DT U Umod DU=DUDT*DT ' & !dbg ,'| Vcol Vgeo DVDTcol*DT V Vmod DV=DVDT*DT' !dbg ENDIF DO K=KTS,KTE TEST=ABS(DUDTcol(IM,K))+ABS(DVDTcol(IM,K)) IF (TEST > THRESH) THEN !dbg !dbg if (lprnt) then !dbg !dbg DUDTcol(IM,K)=0. !-- Test rotation !dbg !dbg DVDTcol(IM,K)=0. !-- Test rotation !dbg !-- Now replace with the original winds before they were written over by !dbg ! the values from the GFS !dbg Ucol(IM,K)=U(I,K,J)*CROT(I,J)+V(I,K,J)*SROT(I,J) !dbg Vcol(IM,K)=V(I,K,J)*CROT(I,J)-U(I,K,J)*SROT(I,J) !dbg endif ! !-- First update winds in geodetic coordinates ! Ugeo=Ucol(IM,K)+DUDTcol(IM,K)*DELTIM Vgeo=Vcol(IM,K)+DVDTcol(IM,K)*DELTIM ! !-- Transform/rotate winds from geodetic back to model coordinates ! Umod=Ugeo*CROT(I,J)-Vgeo*SROT(I,J) Vmod=Ugeo*SROT(I,J)+Vgeo*CROT(I,J) ! !-- Calculate wind tendencies from the updated model winds ! DUDT(I,K,J)=RDELTIM*(Umod-U(I,K,J)) DVDT(I,K,J)=RDELTIM*(Vmod-V(I,K,J)) ! !dbg test=abs(dudt(i,k,j))+abs(dvdt(i,k,j)) if (test > dtlarge) write(6,"(2a,i2,2(a,e12.4))") & label,' => k=',k,' dudt=',dudt(i,k,j),' dvdt=',dvdt(i,k,j) !dbg if (lprnt) write(6,"(i2,f8.2,2(' | ',6f10.4)") K,10.*Pcol(IM,K) & !dbg ,Ucol(IM,K),Ugeo,DUDTcol(IM,K)*DELTIM,U(I,K,J),Umod,DUDT(I,K,J)*DELTIM & !dbg ,Vcol(IM,K),Vgeo,DVDTcol(IM,K)*DELTIM,V(I,K,J),Vmod,DVDT(I,K,J)*DELTIM !dbg ENDIF !- IF (TEST > THRESH) THEN ! ENDDO !- K ! !-- Transform/rotate surface wind stresses from geodetic to model coordinates ! UGWDsfc(I,J)=DUsfc(IM)*CROT(I,J)-DVsfc(IM)*SROT(I,J) VGWDsfc(I,J)=DUsfc(IM)*SROT(I,J)+DVsfc(IM)*CROT(I,J) ! 100 CONTINUE ENDDO !- I ENDDO !- J ! END SUBROUTINE GWD_driver ! !----------------------------------------------------------------------- ! !-- "A", "B" (from GFS) in GWD_col are DVDTcol, DUDTcol, respectively in GWD_driver ! SUBROUTINE GWD_col (A,B, DUsfc,DVsfc & !-- Output &, U1,V1,T1,Q1, PRSI,DEL,PRSL,PRSLK, PHII,PHIL & !-- Met inputs &, HPRIME,OC,OA4,CLX4,THETA,SIGMA,GAMMA,ELVMAX & !-- Topo inputs &, KPBL,IM,KTS,KTE, LABEL,LPRNT ) !-- Input indices, debugging ! !=== Output fields ! !-- A (DUDT), B (DVDT) - output zonal & meridional wind tendencies in Earth coordinates (m s^-2) !-- DUsfc, DVsfc - surface zonal meridional wind stresses in Earth coordinates (m s^-1?) ! !=== Input fields ! !-- U1, V1 - zonal, meridional wind (m/s) !-- T1 - temperature (deg K) !-- Q1 - specific humidity (kg/kg) !-- PRSI - lower interface pressure in centibars (1000 Pa) !-- DEL - pressure thickness of layer in centibars (1000 Pa) !-- PRSL - midlayer pressure in centibars (1000 Pa) !-- PRSLK - Exner function, (P/P0)**(Rd/CP) !-- PHII - lower interface geopotential in mks units !-- PHIL - midlayer geopotential in mks units !-- KDT - number of time steps into integration for diagnostics !-- HPRIME - orographic standard deviation !-- OC - normalized 4th moment of the orographic convexity !-- OA4 - orographic asymmetry for upstream & downstream flow measured ! along 4 vertical planes (W-E, S-N, SW-NE, NW-SE) !-- CLX4 - orographic length scale or mountain width measured along ! 4 vertical planes (W-E, S-N, SW-NE, NW-SE) !-- THETA - angle of the mountain range w/r/t east !-- SIGMA - slope of orography !-- GAMMA - anisotropy/aspect ratio !-- ELVMAX - max height above mean orography !-- KPBL(IM) - vertical index at the top of the PBL !-- KM - number of vertical levels ! !== For diagnostics !-- LABEL - character string for diagnostic prints !-- LPRNT - logical flag for prints ! !####################################################################### !################## ORIGINAL DOCUMENTATION BLOCK ##################### !###### The following comments are from the original GFS code ######## !####################################################################### ! ******************************************************************** ! -----> I M P L E M E N T A T I O N V E R S I O N <---------- ! ! --- Not in this code -- History of GWDP at NCEP---- ! ---------------- ----------------------- ! VERSION 3 MODIFIED FOR GRAVITY WAVES, LOCATION: .FR30(V3GWD) *J* !--- 3.1 INCLUDES VARIABLE SATURATION FLUX PROFILE CF ISIGST !--- 3.G INCLUDES PS COMBINED W/ PH (GLAS AND GFDL) !----- ALSO INCLUDED IS RI SMOOTH OVER A THICK LOWER LAYER !----- ALSO INCLUDED IS DECREASE IN DE-ACC AT TOP BY 1/2 !----- THE NMC GWD INCORPORATING BOTH GLAS(P&S) AND GFDL(MIGWD) !----- MOUNTAIN INDUCED GRAVITY WAVE DRAG !----- CODE FROM .FR30(V3MONNX) FOR MONIN3 !----- THIS VERSION (06 MAR 1987) !----- THIS VERSION (26 APR 1987) 3.G !----- THIS VERSION (01 MAY 1987) 3.9 !----- CHANGE TO FORTRAN 77 (FEB 1989) --- HANN-MING HENRY JUANG !----- ! ! VERSION 4 ! ----- This code ----- ! !----- MODIFIED TO IMPLEMENT THE ENHANCED LOW TROPOSPHERIC GRAVITY !----- WAVE DRAG DEVELOPED BY KIM AND ARAKAWA(JAS, 1995). ! Orographic Std Dev (hprime), Convexity (OC), Asymmetry (OA4) ! and Lx (CLX4) are input topographic statistics needed. ! !----- PROGRAMMED AND DEBUGGED BY HONG, ALPERT AND KIM --- JAN 1996. !----- debugged again - moorthi and iredell --- may 1998. !----- ! Further Cleanup, optimization and modification ! - S. Moorthi May 98, March 99. !----- modified for usgs orography data (ncep office note 424) ! and with several bugs fixed - moorthi and hong --- july 1999. ! !----- Modified & implemented into NRL NOGAPS ! - Young-Joon Kim, July 2000 !----- ! VERSION lm MB (6): oz fix 8/2003 ! ----- This code ----- ! !------ Changed to include the Lott and Miller Mtn Blocking ! with some modifications by (*j*) 4/02 ! From a Principal Coordinate calculation using the ! Hi Res 8 minute orography, the Angle of the ! mtn with that to the East (x) axis is THETA, the slope ! parameter SIGMA. The anisotropy is in GAMMA - all are input ! topographic statistics needed. These are calculated off-line ! as a function of model resolution in the fortran code ml01rg2.f, ! with script mlb2.sh. (*j*) !----- gwdps_mb.f version (following lmi) elvmax < hncrit (*j*) ! MB3a expt to enhance elvmax mtn hgt see sigfac & hncrit !----- !----------------------------------------------------------------------C !==== Below in "!GFS " are the original subroutine call and comments from ! /nwprod/sorc/global_fcst.fd/gwdps_v.f as of April 2007 !GFS SUBROUTINE GWDPS(IM,IX,IY,KM,A,B,U1,V1,T1,Q1,KPBL, !GFS & PRSI,DEL,PRSL,PRSLK,PHII, PHIL,RCL,DELTIM,KDT, !GFS & HPRIME,OC,OA4,CLX4,THETA,SIGMA,GAMMA,ELVMAX, !GFS & DUsfc,DVsfc,G, CP, RD, RV, IMX, !GFS & nmtvr, me, lprnt, ipr) !GFS !------------------------------------------------------------------ !GFS ! USE !GFS ! ROUTINE IS CALLED FROM GBPHYS (AFTER CALL TO MONNIN) !GFS ! !GFS ! PURPOSE !GFS ! USING THE GWD PARAMETERIZATIONS OF PS-GLAS AND PH- !GFS ! GFDL TECHNIQUE. THE TIME TENDENCIES OF U V !GFS ! ARE ALTERED TO INCLUDE THE EFFECT OF MOUNTAIN INDUCED !GFS ! GRAVITY WAVE DRAG FROM SUB-GRID SCALE OROGRAPHY INCLUDING !GFS ! CONVECTIVE BREAKING, SHEAR BREAKING AND THE PRESENCE OF !GFS ! CRITICAL LEVELS !GFS ! !GFS ! INPUT !GFS ! A(IY,KM) NON-LIN TENDENCY FOR V WIND COMPONENT !GFS ! B(IY,KM) NON-LIN TENDENCY FOR U WIND COMPONENT !GFS ! U1(IX,KM) ZONAL WIND / SQRT(RCL) M/SEC AT T0-DT !GFS ! V1(IX,KM) MERIDIONAL WIND / SQRT(RCL) M/SEC AT T0-DT !GFS ! T1(IX,KM) TEMPERATURE DEG K AT T0-DT !GFS ! Q1(IX,KM) SPECIFIC HUMIDITY AT T0-DT !GFS ! !GFS ! RCL A scaling factor = RECIPROCAL OF SQUARE OF COS(LAT) !GFS ! FOR MRF GFS. !GFS ! DELTIM TIME STEP SECS !GFS ! SI(N) P/PSFC AT BASE OF LAYER N !GFS ! SL(N) P/PSFC AT MIDDLE OF LAYER N !GFS ! DEL(N) POSITIVE INCREMENT OF P/PSFC ACROSS LAYER N !GFS ! KPBL(IM) is the index of the top layer of the PBL !GFS ! ipr & lprnt for diagnostics !GFS ! !GFS ! OUTPUT !GFS ! A, B AS AUGMENTED BY TENDENCY DUE TO GWDPS !GFS ! OTHER INPUT VARIABLES UNMODIFIED. !GFS ! ******************************************************************** ! IMPLICIT NONE ! !-- INPUT: ! INTEGER, INTENT(IN) :: IM,KTS,KTE REAL(kind=kind_phys), INTENT(IN), DIMENSION(IM,KTS:KTE) :: & & U1,V1,T1,Q1,DEL,PRSL,PRSLK,PHIL REAL(kind=kind_phys), INTENT(IN), DIMENSION(IM,KTS:KTE+1) :: & & PRSI,PHII REAL(kind=kind_phys), INTENT(IN), DIMENSION(IM,4) :: OA4,CLX4 REAL(kind=kind_phys), INTENT(IN), DIMENSION(IM) :: & & HPRIME,OC,THETA,SIGMA,GAMMA,ELVMAX INTEGER, INTENT(IN), DIMENSION(IM) :: KPBL CHARACTER (LEN=26), INTENT(IN) :: LABEL LOGICAL, INTENT(IN) :: LPRNT ! !-- OUTPUT: ! REAL(kind=kind_phys), INTENT(INOUT), DIMENSION(IM,KTS:KTE) :: A,B REAL(kind=kind_phys), INTENT(INOUT), DIMENSION(IM) :: DUsfc,DVsfc ! !----------------------------------------------------------------------- !-- LOCAL variables: !----------------------------------------------------------------------- ! ! Some constants ! ! REAL(kind=kind_phys), PARAMETER :: PI=3.1415926535897931 & &, G=9.806, CP=1004.6, RD=287.04, RV=461.6 & &, FV=RV/RD-1., RDI=1./RD, GOR=G/RD, GR2=G*GOR, GOCP=G/CP & &, ROG=1./G, ROG2=ROG*ROG & &, DW2MIN=1., RIMIN=-100., RIC=0.25, BNV2MIN=1.0E-5 & &, EFMIN=0.0, EFMAX=10.0, hpmax=200.0 & ! or hpmax=2500.0 &, FRC=1.0, CE=0.8, CEOFRC=CE/FRC, frmax=100. & &, CG=0.5, GMAX=1.0, CRITAC=5.0E-4, VELEPS=1.0 & &, FACTOP=0.5, RLOLEV=500.0, HZERO=0., HONE=1. & ! or RLOLEV=0.5 &, HE_4=.0001, HE_2=.01 & ! !-- Lott & Miller mountain blocking => aka "lm mtn blocking" ! &, cdmb = 1.0 & ! non-dim sub grid mtn drag Amp (*j*) ! hncrit set to 8000m and sigfac added to enhance elvmax mtn hgt &, hncrit=8000. & ! Max value in meters for ELVMAX (*j*) !module top! &, sigfac=3.0 & ! MB3a expt test for ELVMAX factor (*j*) => control value is 0.1 !module top &, sigfac=0. & ! MB3a expt test for ELVMAX factor (*j*) => control value is 0.1 &, hminmt=50. & ! min mtn height (*j*) &, hstdmin=25. & ! min orographic std dev in height &, minwnd=0.1 & ! min wind component (*j*) &, dpmin=5.0 ! Minimum thickness of the reference layer (centibars) ! values of dpmin=0, 20 have also been used ! integer, parameter :: mdir=8 real(kind=kind_phys), parameter :: FDIR=mdir/(PI+PI) ! !-- Template: ! NWD 1 2 3 4 5 6 7 8 ! WD W S SW NW E N NE SE ! integer,save :: nwdir(mdir) data nwdir /6,7,5,8,2,3,1,4/ ! LOGICAL ICRILV(IM) ! !---- MOUNTAIN INDUCED GRAVITY WAVE DRAG ! ! ! for lm mtn blocking real(kind=kind_phys), DIMENSION(IM) :: WK,PE,EK,ZBK,UP,TAUB,XN & & ,YN,UBAR,VBAR,ULOW,OA,CLX,ROLL,ULOI,DTFAC,XLINV,DELKS,DELKS1 & & ,SCOR,BNV2bar, ELEVMX ! ,PSTAR ! real(kind=kind_phys), DIMENSION(IM,KTS:KTE) :: & & BNV2LM,DB,ANG,UDS,BNV2,RI_N,TAUD,RO,VTK,VTJ real(kind=kind_phys), DIMENSION(IM,KTS:KTE-1) :: VELCO real(kind=kind_phys), DIMENSION(IM,KTS:KTE+1) :: TAUP real(kind=kind_phys), DIMENSION(KTE-1) :: VELKO ! integer, DIMENSION(IM) :: & & kref,kint,iwk,iwk2,ipt,kreflm,iwklm,iptlm,idxzb ! ! for lm mtn blocking ! real(kind=kind_phys) :: ZLEN, DBTMP, R, PHIANG, DBIM & &, xl, rcsks, bnv, fr & &, brvf, cleff, tem, tem1, tem2, temc, temv & &, wdir, ti, rdz, dw2, shr2, bvf2 & &, rdelks, wtkbj, efact, coefm, gfobnv & &, scork, rscor, hd, fro, rim, sira & &, dtaux, dtauy, pkp1log, pklog ! integer :: ncnt, kmm1, kmm2, lcap, lcapp1, kbps, kbpsp1,kbpsm1 & &, kmps, kmpsp1, idir, nwd, i, j, k, klcap, kp1, kmpbl, npt, npr & &, idxm1, ktrial, klevm1, kmll,kmds, KM & ! &, ihit,jhit & &, ME !-- processor element for debugging real :: rcl,rcs !dbg ! !----------------------------------------------------------------------- ! KM = KTE npr = 0 DO I = 1, IM DUsfc(I) = 0. DVsfc(I) = 0. ! !-- ELEVMX is a local array that could be changed below ! ELEVMX(I) = ELVMAX(I) ENDDO ! !-- Note that A, B already set to zero as DUDTcol, DVDTcol in subroutine GWD_driver ! ipt = 0 npt = 0 IF (NMTVR >= 14) then DO I = 1,IM IF (elvmax(i) > HMINMT .AND. hprime(i) > HE_4) then npt = npt + 1 ipt(npt) = i ENDIF ENDDO ELSE DO I = 1,IM IF (hprime(i) > HE_4) then npt = npt + 1 ipt(npt) = i ENDIF ENDDO ENDIF !-- IF (NMTVR >= 14) then ! !dbg rcl=1. rcs=1. !dbg if (lprnt) then !dbg !-- Match what's in the GFS: !dbg !dbg rcl=1.53028780126139008 ! match GFS point at 36N !dbg !dbg rcs=sqrt(rcl) !dbg i=im !dbg write(6,"(a,a)") LABEL,' in GWD_col: K U V T Q Pi DP P EX PHIi PHI' !dbg do k=kts,kte !dbg write(6,"(i3,10e12.4)") k,U1(i,k),V1(i,k),T1(i,k),Q1(i,k),PRSI(i,k) & !dbg ,DEL(i,k),PRSL(i,k),PRSLK(i,k),PHII(i,k),PHIL(i,k) !dbg enddo !dbg write(6,"(2(a,e12.4),2(a,4e12.4/),4(a,e12.4),a,i3) )") & !dbg 'GWD_col: hprime(i)=',hprime(i),' oc(i)=',oc(i) & !dbg ,' oa4(i,1-4)=',(oa4(i,k),k=1,4) & !dbg ,' clx4(i,1-4)=',(clx4(i,k),k=1,4) & !dbg ,' theta(i)=',theta(i),' sigma(i)=',sigma(i) & !dbg ,' gamma(i)=',gamma(i),' elvmax(i)=',elvmax(i) & !dbg ,' lpbl(i)=',kpbl(i) !dbg endif !dbg if (lprnt) CALL WRF_GET_MYPROC(ME) ! !-- Note important criterion for immediately exiting routine! ! IF (npt <= 0) RETURN ! No gwd/mb calculation done! ! do i=1,npt IDXZB(i) = 0 enddo ! DO K = 1, KM DO I = 1, IM DB(I,K) = 0. ANG(I,K) = 0. UDS(I,K) = 0. ENDDO ENDDO ! ! ! NCNT = 0 KMM1 = KM - 1 KMM2 = KM - 2 LCAP = KM LCAPP1 = LCAP + 1 ! ! IF (NMTVR .eq. 14) then ! ---- for lm and gwd calculation points ! ! --- iwklm is the level above the height of the mountain. ! --- idxzb is the level of the dividing streamline. ! INITIALIZE DIVIDING STREAMLINE (DS) CONTROL VECTOR ! do i=1,npt iwklm(i) = 2 kreflm(i) = 0 enddo ! ! ! start lm mtn blocking (mb) section ! !.............................. !.............................. ! ! (*j*) 11/03: test upper limit on KMLL=km - 1 ! then do not need hncrit -- test with large hncrit first. ! KMLL = km / 2 ! maximum mtnlm height : # of vertical levels / 2 KMLL = kmm1 ! --- No mtn should be as high as KMLL (so we do not have to start at ! --- the top of the model but could do calc for all levels). ! !dbg !dbg if (lprnt) print *,'k pkp1log pklog vtj(i,k) vtk(i,k) ro(i,k)' DO I = 1, npt j = ipt(i) ELEVMX(J) = min (ELEVMX(J) + sigfac * hprime(j), hncrit) !dbg !dbg if (lprnt) print *,'k=',k,' elevmx(j)=',elevmx(j),' elvmax(j)=',elvmax(j) & !dbg ,' sigfac*hprime(j)=',sigfac*hprime(j) ENDDO DO K = 1,KMLL DO I = 1, npt j = ipt(i) ! --- interpolate to max mtn height for index, iwklm(I) wk[gz] ! --- ELEVMX is limited to hncrit because to hi res topo30 orog. pkp1log = phil(j,k+1) * ROG pklog = phil(j,k) * ROG if ( ( ELEVMX(j) .le. pkp1log ) .and. & & ( ELEVMX(j) .ge. pklog ) ) THEN ! --- wk for diags but can be saved and reused. wk(i) = G * ELEVMX(j) / ( phil(j,k+1) - phil(j,k) ) iwklm(I) = MAX(iwklm(I), k+1 ) !dbg if (lprnt) print *,'k,wk(i),iwklm(i)=',k,wk(i),iwklm(i) !dbg endif ! ! --- find at prsl levels large scale environment variables ! --- these cover all possible mtn max heights VTJ(I,K) = T1(J,K) * (1.+FV*Q1(J,K)) ! virtual temperature VTK(I,K) = VTJ(I,K) / PRSLK(J,K) ! potential temperature RO(I,K) = RDI * PRSL(J,K) / VTJ(I,K) ! DENSITY (1.e-3 kg m^-3) !dbg if (lprnt) write(6,"(i2,5e12.4)") k,pkp1log,pklog,vtj(i,k),vtk(i,k),ro(i,k) !dbg ENDDO !-- DO I = 1, npt ! ENDDO !-- DO K = 1,KMLL ! ! testing for highest model level of mountain top ! ! ihit = 2 ! jhit = 0 ! do i = 1, npt ! j=ipt(i) ! if ( iwklm(i) .gt. ihit ) then ! ihit = iwklm(i) ! jhit = j ! endif ! enddo ! if (lprnt) print *, ' mb: kdt,max(iwklm),jhit,phil,me=', & ! & kdt,ihit,jhit,phil(jhit,ihit),me ! !dbg if (lprnt) print *,'k rdz bnv2lm(i,k)' !dbg klevm1 = KMLL - 1 DO K = 1, klevm1 DO I = 1, npt j = ipt(i) RDZ = g / ( phil(j,k+1) - phil(j,k) ) ! --- Brunt-Vaisala Frequency BNV2LM(I,K) = (G+G) * RDZ * ( VTK(I,K+1)-VTK(I,K) ) & & / ( VTK(I,K+1)+VTK(I,K) ) bnv2lm(i,k) = max( bnv2lm(i,k), bnv2min ) !dbg if (lprnt) write(6,"(i2,2e12.4)") k,rdz,bnv2lm(i,k) !dbg ENDDO ENDDO ! DO I = 1, npt J = ipt(i) DELKS(I) = 1.0 / (PRSI(J,1) - PRSI(J,iwklm(i))) DELKS1(I) = 1.0 / (PRSL(J,1) - PRSL(J,iwklm(i))) UBAR (I) = 0.0 VBAR (I) = 0.0 ROLL (I) = 0.0 PE (I) = 0.0 EK (I) = 0.0 BNV2bar(I) = (PRSL(J,1)-PRSL(J,2)) * DELKS1(I) * BNV2LM(I,1) ENDDO ! ! --- find the dividing stream line height ! --- starting from the level above the max mtn downward ! --- iwklm(i) is the k-index of mtn elevmx elevation ! DO Ktrial = KMLL, 1, -1 DO I = 1, npt IF ( Ktrial .LT. iwklm(I) .and. kreflm(I) .eq. 0 ) then kreflm(I) = Ktrial if (lprnt) print *,'Ktrial,iwklm(i),kreflm(i)=',Ktrial,iwklm(i),kreflm(I) ENDIF ENDDO ENDDO ! ! --- in the layer kreflm(I) to 1 find PE (which needs N, ELEVMX) ! --- make averages, guess dividing stream (DS) line layer. ! --- This is not used in the first cut except for testing and ! --- is the vert ave of quantities from the surface to mtn top. ! !dbg !dbg if (lprnt) print *,' k rdelks ubar vbar roll ' & !dbg ,'bnv2bar rcsks rcs' DO I = 1, npt DO K = 1, Kreflm(I) J = ipt(i) RDELKS = DEL(J,K) * DELKS(I) !dbg RCSKS = RCS * RDELKS UBAR(I) = UBAR(I) + RCSKS * U1(J,K) ! trial Mean U below VBAR(I) = VBAR(I) + RCSKS * V1(J,K) ! trial Mean V below ROLL(I) = ROLL(I) + RDELKS * RO(I,K) ! trial Mean RO below RDELKS = (PRSL(J,K)-PRSL(J,K+1)) * DELKS1(I) BNV2bar(I) = BNV2bar(I) + BNV2lm(I,K) * RDELKS ! --- these vert ave are for diags, testing and GWD to follow (*j*). !dbg !dbg if (lprnt) write(6,"(i2,7e12.4)") k,rdelks,ubar(i),vbar(i),roll(i) & !dbg ,bnv2bar(i),rcsks,rcs ENDDO ENDDO !dbg !dbg if (lprnt) print *, 'kreflm(npt)=',kreflm(npt) & !dbg ,' bnv2bar(npt)=',bnv2bar(npt) & !dbg ,' ubar(npt)=',ubar(npt) & !dbg ,' vbar(npt)=',vbar(npt) & !dbg ,' roll(npt)=',roll(npt) & !dbg ,' delks(npt)=',delks(npt) & !dbg ,' delks1(npt)=',delks1(npt) ! ! --- integrate to get PE in the trial layer. ! --- Need the first layer where PE>EK - as soon as ! --- IDXZB is not 0 we have a hit and Zb is found. ! DO I = 1, npt J = ipt(i) !dbg !dbg if (lprnt) print *,'k phiang u1(j,k) v1(j,k) theta(j)' & !dbg ,' ang(i,k) uds(i,k) pe(i) up(i) ek(i)' DO K = iwklm(I), 1, -1 PHIANG = RAD_TO_DEG*atan2(V1(J,K),U1(J,K)) ANG(I,K) = ( THETA(J) - PHIANG ) if ( ANG(I,K) .gt. 90. ) ANG(I,K) = ANG(I,K) - 180. if ( ANG(I,K) .lt. -90. ) ANG(I,K) = ANG(I,K) + 180. ! !dbg UDS(I,K) = & UDS(I,K) = rcs* & & MAX(SQRT(U1(J,K)*U1(J,K) + V1(J,K)*V1(J,K)), minwnd) ! --- Test to see if we found Zb previously IF (IDXZB(I) .eq. 0 ) then PE(I) = PE(I) + BNV2lm(I,K) * & & ( G * ELEVMX(J) - phil(J,K) ) * & & ( PHII(J,K+1) - PHII(J,K) ) * ROG2 !dbg !dbg & ( PHII(J,K+1) - PHII(J,K) ) / (G*G) !dbg if (lprnt) print *, & !dbg 'k=',k,' pe(i)=',pe(i),' bnv2lm(i,k)=',bnv2lm(i,k) & !dbg ,' g=',g,' elevmx(j)=',elevmx(j) & !dbg ,' g*elevmx(j)-phil(j,k)=',g*elevmx(j)-phil(j,k) & !dbg ,' (phii(j,k+1)-phi(j,k))/(g*g)=',(PHII(J,K+1)-PHII(J,K) )*ROG2 ! --- KE ! --- Wind projected on the line perpendicular to mtn range, U(Zb(K)). ! --- kinetic energy is at the layer Zb ! --- THETA ranges from -+90deg |_ to the mtn "largest topo variations" UP(I) = UDS(I,K) * cos(DEG_TO_RAD*ANG(I,K)) EK(I) = 0.5 * UP(I) * UP(I) ! --- Dividing Stream lime is found when PE =exceeds EK. IF ( PE(I) .ge. EK(I) ) IDXZB(I) = K ! --- Then mtn blocked flow is between Zb=k(IDXZB(I)) and surface ! ENDIF !-- IF (IDXZB(I) .eq. 0 ) then !dbg !dbg if (lprnt) write(6,"(i2,9e12.4)") & !dbg k,phiang,u1(j,k),v1(j,k),theta(j),ang(i,k),uds(i,k),pe(i),up(i),ek(i) ENDDO !-- DO K = iwklm(I), 1, -1 ENDDO !-- DO I = 1, npt ! DO I = 1, npt J = ipt(i) ! --- Calc if N constant in layers (Zb guess) - a diagnostic only. ZBK(I) = ELEVMX(J) - SQRT(UBAR(I)**2 + VBAR(I)**2)/BNV2bar(I) ENDDO ! !dbg !dbg if (lprnt) print *,'iwklm=',iwklm(npt),' ZBK=',ZBK(npt) ! ! --- The drag for mtn blocked flow ! !dbg !dbg if (lprnt) print *,'k phil(j,k) g*hprime(j) ' & !dbg ,'phil(j,idxzb(i))-phil(j,k) zlen r dbtmp db(i,k)' ! DO I = 1, npt J = ipt(i) ZLEN = 0. IF ( IDXZB(I) .gt. 0 ) then DO K = IDXZB(I), 1, -1 IF (PHIL(J,IDXZB(I)) > PHIL(J,K)) THEN ZLEN = SQRT( ( PHIL(J,IDXZB(I))-PHIL(J,K) ) / & & ( PHIL(J,K ) + G * hprime(J) ) ) ! --- lm eq 14: R = (cos(DEG_TO_RAD*ANG(I,K))**2 + GAMMA(J) * sin(DEG_TO_RAD*ANG(I,K))**2) / & & (gamma(J) * cos(DEG_TO_RAD*ANG(I,K))**2 + sin(DEG_TO_RAD*ANG(I,K))**2) ! --- (negative of DB -- see sign at tendency) DBTMP = 0.25 * CDmb * & & MAX( 2. - 1. / R, HZERO ) * sigma(J) * & & MAX(cos(DEG_TO_RAD*ANG(I,K)), gamma(J)*sin(DEG_TO_RAD*ANG(I,K))) * & & ZLEN / hprime(J) DB(I,K) = DBTMP * UDS(I,K) ! !dbg !dbg if (lprnt) write(6,"(i3,7e12.4)") & !dbg k,phil(j,k),g*hprime(j),phil(j,idxzb(i))-phil(j,k),zlen,r,dbtmp,db(i,k) ! ENDIF !-- IF (PHIL(J,IDXZB(I)) > PHIL(J,K) .AND. DEN > 0.) THEN ENDDO !-- DO K = IDXZB(I), 1, -1 endif ENDDO !-- DO I = 1, npt ! !............................. !............................. ! end mtn blocking section ! ENDIF !-- IF ( NMTVR .eq. 14) then ! !............................. !............................. ! KMPBL = km / 2 ! maximum pbl height : # of vertical levels / 2 ! ! Scale cleff between IM=384*2 and 192*2 for T126/T170 and T62 ! if (imx .gt. 0) then ! cleff = 1.0E-5 * SQRT(FLOAT(IMX)/384.0) ! this is inverse of CLEFF! ! cleff = 1.0E-5 * SQRT(FLOAT(IMX)/192.0) ! this is inverse of CLEFF! cleff = 0.5E-5 * SQRT(FLOAT(IMX)/192.0) ! this is inverse of CLEFF! ! cleff = 2.0E-5 * SQRT(FLOAT(IMX)/192.0) ! this is inverse of CLEFF! ! cleff = 2.5E-5 * SQRT(FLOAT(IMX)/192.0) ! this is inverse of CLEFF! endif !dbg !dbg if (lprnt) print *,'imx, cleff, rcl, rcs=',imx,cleff,rcl,rcs !dbg if (lprnt) print *,' k vtj vtk ro' DO K = 1,KM DO I =1,npt J = ipt(i) VTJ(I,K) = T1(J,K) * (1.+FV*Q1(J,K)) VTK(I,K) = VTJ(I,K) / PRSLK(J,K) RO(I,K) = RDI * PRSL(J,K) / VTJ(I,K) ! DENSITY TAUP(I,K) = 0.0 !dbg !dbg if (lprnt) write(6,"(i2,3e12.4)") k,vtj(i,k),vtk(i,k),ro(i,k) !dbg ENDDO ENDDO !dbg !dbg if (lprnt) print *,' k ti tem rdz tem1' & !dbg ,' tem2 dw2 shr2 bvf2 ri_n(i,k) bnv2(i,k)' DO K = 1,KMM1 DO I =1,npt J = ipt(i) TI = 2.0 / (T1(J,K)+T1(J,K+1)) TEM = TI / (PRSL(J,K)-PRSL(J,K+1)) ! RDZ = GOR * PRSI(J,K+1) * TEM RDZ = g / (phil(j,k+1) - phil(j,k)) TEM1 = U1(J,K) - U1(J,K+1) TEM2 = V1(J,K) - V1(J,K+1) !dbg ! DW2 = TEM1*TEM1 + TEM2*TEM2 DW2 = rcl*(TEM1*TEM1 + TEM2*TEM2) SHR2 = MAX(DW2,DW2MIN) * RDZ * RDZ BVF2 = G*(GOCP+RDZ*(VTJ(I,K+1)-VTJ(I,K))) * TI ri_n(I,K) = MAX(BVF2/SHR2,RIMIN) ! Richardson number ! Brunt-Vaisala Frequency ! TEM = GR2 * (PRSL(J,K)+PRSL(J,K+1)) * TEM ! BNV2(I,K) = TEM * (VTK(I,K+1)-VTK(I,K))/(VTK(I,K+1)+VTK(I,K)) BNV2(I,K) = (G+G) * RDZ * (VTK(I,K+1)-VTK(I,K)) & & / (VTK(I,K+1)+VTK(I,K)) bnv2(i,k) = max( bnv2(i,k), bnv2min ) !dbg !dbg if (lprnt) write(6,"(i2,10e12.4)") & !dbg k,ti,tem,rdz,tem1,tem2,dw2,shr2,bvf2,ri_n(i,k),bnv2(i,k) ! ENDDO !-- DO K = 1,KMM1 ENDDO !-- DO I =1,npt ! !dbg !dbg if (lprnt) print *,'kmm1,bnv2=',kmm1,bnv2(npt,kmm1) ! ! Apply 3 point smoothing on BNV2 ! ! do k=1,km ! do i=1,im ! vtk(i,k) = bnv2(i,k) ! enddo ! enddo ! do k=2,kmm1 ! do i=1,im ! bnv2(i,k) = 0.25*(vtk(i,k-1)+vtk(i,k+1)) + 0.5*vtk(i,k) ! enddo ! enddo ! ! Finding the first interface index above 50 hPa level ! do i=1,npt iwk(i) = 2 enddo !dbg if (lprnt) print *,'kmpbl=',kmpbl !dbg DO K=3,KMPBL DO I=1,npt j = ipt(i) tem = (prsi(j,1) - prsi(j,k)) if (tem .lt. dpmin) iwk(i) = k enddo enddo ! KBPS = 1 KMPS = KM DO I=1,npt J = ipt(i) kref(I) = MAX(IWK(I), KPBL(J)+1 ) ! reference level DELKS(I) = 1.0 / (PRSI(J,1) - PRSI(J,kref(I))) DELKS1(I) = 1.0 / (PRSL(J,1) - PRSL(J,kref(I))) UBAR (I) = 0.0 VBAR (I) = 0.0 ROLL (I) = 0.0 KBPS = MAX(KBPS, kref(I)) KMPS = MIN(KMPS, kref(I)) ! BNV2bar(I) = (PRSL(J,1)-PRSL(J,2)) * DELKS1(I) * BNV2(I,1) ENDDO ! ! KBPSP1 = KBPS + 1 KBPSM1 = KBPS - 1 DO K = 1,KBPS DO I = 1,npt IF (K .LT. kref(I)) THEN J = ipt(i) RDELKS = DEL(J,K) * DELKS(I) !dbg ! UBAR(I) = UBAR(I) + RDELKS * U1(J,K) ! Mean U below kref ! VBAR(I) = VBAR(I) + RDELKS * V1(J,K) ! Mean V below kref RCSKS = RCS * RDELKS UBAR(I) = UBAR(I) + RCSKS * U1(J,K) ! Mean U below kref VBAR(I) = VBAR(I) + RCSKS * V1(J,K) ! Mean V below kref ! ROLL(I) = ROLL(I) + RDELKS * RO(I,K) ! Mean RO below kref RDELKS = (PRSL(J,K)-PRSL(J,K+1)) * DELKS1(I) BNV2bar(I) = BNV2bar(I) + BNV2(I,K) * RDELKS ENDIF ENDDO ENDDO ! !dbg !dbg if(lprnt) print *,'ubar(npt)=',ubar(npt) & !dbg ,' vbar(npt)=',vbar(npt),' roll(npt)=',roll(npt) & !dbg ,' bnv2bar(npt)=',bnv2bar(npt) ! ! FIGURE OUT LOW-LEVEL HORIZONTAL WIND DIRECTION AND FIND 'OA' ! ! NWD 1 2 3 4 5 6 7 8 ! WD W S SW NW E N NE SE ! DO I = 1,npt J = ipt(i) wdir = atan2(UBAR(I),VBAR(I)) + pi idir = mod(nint(fdir*wdir),mdir) + 1 nwd = nwdir(idir) OA(I) = (1-2*INT( (NWD-1)/4 )) * OA4(J,MOD(NWD-1,4)+1) CLX(I) = CLX4(J,MOD(NWD-1,4)+1) ENDDO ! !-----XN,YN "LOW-LEVEL" WIND PROJECTIONS IN ZONAL ! & MERIDIONAL DIRECTIONS !-----ULOW "LOW-LEVEL" WIND MAGNITUDE - (= U) !-----BNV2 BNV2 = N**2 !-----TAUB BASE MOMENTUM FLUX !-----= -(RO * U**3/(N*XL)*GF(FR) FOR N**2 > 0 !-----= 0. FOR N**2 < 0 !-----FR FROUDE = N*HPRIME / U !-----G GMAX*FR**2/(FR**2+CG/OC) ! !-----INITIALIZE SOME ARRAYS ! DO I = 1,npt XN(I) = 0.0 YN(I) = 0.0 TAUB (I) = 0.0 ULOW (I) = 0.0 DTFAC(I) = 1.0 ICRILV(I) = .FALSE. ! INITIALIZE CRITICAL LEVEL CONTROL VECTOR ! !----COMPUTE THE "LOW LEVEL" WIND MAGNITUDE (M/S) ! ULOW(I) = MAX(SQRT(UBAR(I)*UBAR(I) + VBAR(I)*VBAR(I)), HONE) ULOI(I) = 1.0 / ULOW(I) ENDDO !dbg !dbg if (lprnt) print *,'idir,nwd,wdir,oa,clx,ulow,uloi=' & !dbg ,idir,nwd,wdir,oa(npt),clx(npt),ulow(npt),uloi(npt) ! DO K = 1,KMM1 DO I = 1,npt J = ipt(i) !dbg ! VELCO(I,K) = 0.5* ((U1(J,K)+U1(J,K+1))*UBAR(I) & VELCO(I,K) = 0.5*rcs*((U1(J,K)+U1(J,K+1))*UBAR(I) & & + (V1(J,K)+V1(J,K+1))*VBAR(I)) VELCO(I,K) = VELCO(I,K) * ULOI(I) !dbg if (lprnt) write(6,"(a,i2,a,e12.4)") 'k=',k,' velco(i,k)=',velco(i,k) !dbg ! IF ((VELCO(I,K).LT.VELEPS) .AND. (VELCO(I,K).GT.0.)) THEN ! VELCO(I,K) = VELEPS ! ENDIF ENDDO ENDDO ! ! find the interface level of the projected wind where ! low levels & upper levels meet above pbl ! do i=1,npt kint(i) = km enddo do k = 1,kmm1 do i = 1,npt IF (K .GT. kref(I)) THEN if(velco(i,k) .lt. veleps .and. kint(i) .eq. km) then kint(i) = k+1 endif endif enddo enddo ! WARNING KINT = KREF !!!!!!!!! do i=1,npt kint(i) = kref(i) enddo ! ! DO I = 1,npt J = ipt(i) BNV = SQRT( BNV2bar(I) ) FR = BNV * ULOI(I) * min(HPRIME(J),hpmax) FR = MIN(FR, FRMAX) XN(I) = UBAR(I) * ULOI(I) YN(I) = VBAR(I) * ULOI(I) ! ! Compute the base level stress and store it in TAUB ! CALCULATE ENHANCEMENT FACTOR, NUMBER OF MOUNTAINS & ASPECT ! RATIO CONST. USE SIMPLIFIED RELATIONSHIP BETWEEN STANDARD ! DEVIATION & CRITICAL HGT ! EFACT = (OA(I) + 2.) ** (CEOFRC*FR) EFACT = MIN( MAX(EFACT,EFMIN), EFMAX ) ! COEFM = (1. + CLX(I)) ** (OA(I)+1.) ! XLINV(I) = COEFM * CLEFF ! TEM = FR * FR * OC(J) GFOBNV = GMAX * TEM / ((TEM + CG)*BNV) ! G/N0 ! TAUB(I) = XLINV(I) * ROLL(I) * ULOW(I) * ULOW(I) & & * ULOW(I) * GFOBNV * EFACT ! BASE FLUX Tau0 ! ! tem = min(HPRIME(I),hpmax) ! TAUB(I) = XLINV(I) * ROLL(I) * ULOW(I) * BNV * tem * tem ! K = MAX(1, kref(I)-1) TEM = MAX(VELCO(I,K)*VELCO(I,K), HE_4) SCOR(I) = BNV2(I,K) / TEM ! Scorer parameter below ref level ENDDO !-- DO I = 1,npt ! !dbg !dbg if (lprnt) write(6,"(a,i2,10(a,e12.4))") & !dbg 'kint=',kint(npt),' bnv=',bnv,' fr=',fr,' xn=',xn(npt) & !dbg ,' yn=',yn(npt),' efact=',efact,' coefm=',coefm,' xlinv(npt)=',xlinv(npt) & !dbg ,' gfobnv=',gfobnv,' taub(npt)=',taub(npt),' scor(npt)=',scor(npt) ! !----SET UP BOTTOM VALUES OF STRESS ! DO K = 1, KBPS DO I = 1,npt IF (K .LE. kref(I)) TAUP(I,K) = TAUB(I) ENDDO ENDDO ! ! Now compute vertical structure of the stress. ! DO K = KMPS, KMM1 ! Vertical Level K Loop! KP1 = K + 1 DO I = 1, npt ! !-----UNSTABLE LAYER IF RI < RIC !-----UNSTABLE LAYER IF UPPER AIR VEL COMP ALONG SURF VEL <=0 (CRIT LAY) !---- AT (U-C)=0. CRIT LAYER EXISTS AND BIT VECTOR SHOULD BE SET (.LE.) ! IF (K .GE. kref(I)) THEN ICRILV(I) = ICRILV(I) .OR. ( ri_n(I,K) .LT. RIC) & & .OR. (VELCO(I,K) .LE. 0.0) ENDIF ENDDO ! DO I = 1,npt IF (K .GE. kref(I)) THEN !dbg !dbg if (lprnt) write(6,"(2(a,i2),a,L1,3(a,e12.4))") 'k=',k,' kref(i)=',kref(i) & !dbg ,' icrilv(i)=',icrilv(i),' taup(i,k)=',taup(i,k) & !dbg ,' ri_n(i,k)=',ri_n(i,k),' velco(i,k)=',velco(i,k) ! IF (.NOT.ICRILV(I) .AND. TAUP(I,K) .GT. 0.0 ) THEN TEMV = 1.0 / max(VELCO(I,K), HE_2) ! IF (OA(I) .GT. 0. .AND. PRSI(ipt(i),KP1).GT.RLOLEV) THEN IF (OA(I).GT.0. .AND. kp1 .lt. kint(i)) THEN SCORK = BNV2(I,K) * TEMV * TEMV RSCOR = MIN(HONE, SCORK / SCOR(I)) SCOR(I) = SCORK ELSE RSCOR = 1. ENDIF ! BRVF = SQRT(BNV2(I,K)) ! Brunt-Vaisala Frequency ! TEM1 = XLINV(I)*(RO(I,KP1)+RO(I,K))*BRVF*VELCO(I,K)*0.5 TEM1 = XLINV(I)*(RO(I,KP1)+RO(I,K))*BRVF*0.5 & & * max(VELCO(I,K),HE_2) HD = SQRT(TAUP(I,K) / TEM1) FRO = BRVF * HD * TEMV ! ! RIM is the MINIMUM-RICHARDSON NUMBER BY SHUTTS (1985) ! TEM2 = SQRT(ri_n(I,K)) TEM = 1. + TEM2 * FRO RIM = ri_n(I,K) * (1.-FRO) / (TEM * TEM) ! ! CHECK STABILITY TO EMPLOY THE SATURATION HYPOTHESIS ! OF LINDZEN (1981) EXCEPT AT TROPOSPHERIC DOWNSTREAM REGIONS ! ! ---------------------- !dbg !dbg if (lprnt) write(6,"(a,i2,10(a,e12.4))") & !dbg 'k=',k,' brvf=',brvf,' tem1=',tem1,' xlinv(i)=',xlinv(i) & !dbg ,'ROavg=',.5*(RO(I,KP1)+RO(I,K)),' hd=',hd,' temv=',temv,' fro=',fro & !dbg ,' tem2=',tem2,' tem=',tem,' rim=',rim ! IF (RIM .LE. RIC .AND. & ! & (OA(I) .LE. 0. .OR. PRSI(ipt(I),KP1).LE.RLOLEV )) THEN & (OA(I) .LE. 0. .OR. kp1 .ge. kint(i) )) THEN TEMC = 2.0 + 1.0 / TEM2 HD = VELCO(I,K) * (2.*SQRT(TEMC)-TEMC) / BRVF TAUP(I,KP1) = TEM1 * HD * HD ELSE TAUP(I,KP1) = TAUP(I,K) * RSCOR ENDIF taup(i,kp1) = min(taup(i,kp1), taup(i,k)) !dbg !dbg if (lprnt) write(6,"(a,i2,2(a,e12.4))") 'kp1=',kp1 & !dbg ,' taup(i,kp1)=',taup(i,kp1),' taup(i,k)=',taup(i,k) ENDIF !-- IF (.NOT.ICRILV(I) .AND. TAUP(I,K) .GT. 0.0 ) THEN ENDIF !-- IF (K .GE. kref(I)) THEN ENDDO !-- DO I = 1,npt ENDDO !-- DO K = KMPS, KMM1 ! ! DO I=1,IM ! taup(i,km+1) = taup(i,km) ! ENDDO ! IF(LCAP .LE. KM) THEN !dbg if (lprnt) print *,'lcap,lcapp1,km=',lcap,lcapp1,km !dbg DO KLCAP = LCAPP1, KM+1 DO I = 1,npt SIRA = PRSI(ipt(I),KLCAP) / PRSI(ipt(I),LCAP) TAUP(I,KLCAP) = SIRA * TAUP(I,LCAP) !dbg !dbg if (lprnt) write(6,"(a,i2,5(a,e12.4))") & !dbg 'klcap=',klcap,' sira=',sira,' prsi(ipt(i),klcap)=', prsi(ipt(i),klcap) & !dbg ,' prsi(ipt(i),lcap)=',prsi(ipt(i),lcap),' taup(i,lcap)=',taup(i,lcap) & !dbg ,' taup(i,klcap)=',taup(i,klcap) ! ENDDO ENDDO ENDIF ! ! Calculate - (g/p*)*d(tau)/d(sigma) and Decel terms DTAUX, DTAUY ! DO I=1,npt ! SCOR(I) = 1.0 / PSTAR(I) !dbg ! SCOR(I) = 1.0 SCOR(I) = 1.0/RCS ENDDO DO K = 1,KM DO I = 1,npt TAUD(I,K) = G * (TAUP(I,K+1) - TAUP(I,K)) * SCOR(I) & & / DEL(ipt(I),K) !dbg !dbg if (lprnt) write(6,"(a,i2,4(a,e12.4))") 'k=',k,' taud(i,k)=',taud(i,k) & !dbg ,' D(taup)=',TAUP(I,K+1)-TAUP(I,K),' del(ipt(i),k)=',del(ipt(i),k) & !dbg ,' scor(i)=',scor(i) ENDDO ENDDO ! !------LIMIT DE-ACCELERATION (MOMENTUM DEPOSITION ) AT TOP TO 1/2 VALUE !------THE IDEA IS SOME STUFF MUST GO OUT THE TOP ! DO KLCAP = LCAP, KM DO I = 1,npt TAUD(I,KLCAP) = TAUD(I,KLCAP) * FACTOP !dbg !dbg if (lprnt) write(6,"(a,i2,a,e12.4)") 'klcap=',klcap,' taud(i,klcap)=',taud(i,klcap) ENDDO ENDDO ! !------IF THE GRAVITY WAVE DRAG WOULD FORCE A CRITICAL LINE IN THE !------LAYERS BELOW SIGMA=RLOLEV DURING THE NEXT DELTIM TIMESTEP, !------THEN ONLY APPLY DRAG UNTIL THAT CRITICAL LINE IS REACHED. ! DO K = 1,KMM1 DO I = 1,npt IF (K .GT. kref(I) .and. PRSI(ipt(i),K) .GE. RLOLEV) THEN IF(TAUD(I,K).NE.0.) THEN !dbg ! TEM = DELTIM * TAUD(I,K) TEM = rcs*DELTIM * TAUD(I,K) DTFAC(I) = MIN(DTFAC(I),ABS(VELCO(I,K)/TEM)) !dbg !dbg if (lprnt) write(6,"(a,i2,2(a,e12.4))") 'k=',k & !dbg ,' tem=',tem,' dtfac(i)=',dtfac(i) ENDIF ENDIF ENDDO ENDDO ! if(lprnt .and. npr .gt. 0) then ! print *, before A=,A(npr,:) ! print *, before B=,B(npr,:) ! endif ! !dbg !dbg if (lprnt) write(6,"(a,i2,3(a,e12.4))") 'idxzb(npt)=',idxzb(npt) & !dbg ,' dtfac=',dtfac(npt),' xn=',xn(npt),' yn=',yn(npt) ! DO K = 1,KM DO I = 1,npt J = ipt(i) TAUD(I,K) = TAUD(I,K) * DTFAC(I) DTAUX = TAUD(I,K) * XN(I) DTAUY = TAUD(I,K) * YN(I) ! --- lm mb (*j*) changes overwrite GWD if ( K .lt. IDXZB(I) .AND. IDXZB(I) .ne. 0 ) then DBIM = DB(I,K) / (1.+DB(I,K)*DELTIM) A(J,K) = - DBIM * V1(J,K) + A(J,K) B(J,K) = - DBIM * U1(J,K) + B(J,K) DUsfc(J) = DUsfc(J) - DBIM * V1(J,K) * DEL(J,K) DVsfc(J) = DVsfc(J) - DBIM * U1(J,K) * DEL(J,K) !dbg !dbg if (lprnt .and. dbim > 0.) write(6,"(a,i2,4(a,e12.4))") & !dbg 'k=',k,' db(i,k)=',db(i,k),' dbim=',dbim & !dbg ,' dudt=',-dbim*u1(j,k),' dvdt=',-dbim*v1(j,k) ! else ! A(J,K) = DTAUY + A(J,K) B(J,K) = DTAUX + B(J,K) DUsfc(J) = DUsfc(J) + DTAUX * DEL(J,K) DVsfc(J) = DVsfc(J) + DTAUY * DEL(J,K) !dbg !dbg if (lprnt .and. dtaux+dtauy/=0.) write(6,"(a,i2,2(a,e12.4))") & !dbg ',k=',k,' dudt=dtaux=',dtaux,' dvdt=dtauy=',dtauy endif !dbg !dbg if (lprnt) write(6,"(a,i2,2(a,e12.4))") 'k=',k & !dbg ,' dusfc(j)=',dusfc(j),' dvsfc(j)=',dvsfc(j) ENDDO !-- DO I = 1,npt ENDDO !-- DO K = 1,KM ! if (lprnt) then ! print *, in gwdps_lm.f after A=,A(ipr,:) ! print *, in gwdps_lm.f after B=,B(ipr,:) ! print *, DB=,DB(ipr,:) ! endif DO I = 1,npt J = ipt(i) ! TEM = (-1.E3/G) * PSTAR(I) !dbg ! TEM = -1.E3/G TEM = -1.E3*ROG*rcs DUsfc(J) = TEM * DUsfc(J) DVsfc(J) = TEM * DVsfc(J) !dbg !dbg if (lprnt .and. i.eq.npr) write(6,"(3(a,e12.4))") 'tem=',tem & !dbg ,' dusfc(j)=',dusfc(j),' dvsfc(j)=',dvsfc(j) ENDDO ! END SUBROUTINE GWD_col ! !####################################################################### ! END MODULE module_gwd