C----------------------------------------------------------------------- SUBROUTINE POLATES1(IPOPT,KGDSI,KGDSO,MI,MO,KM,IBI,LI,GI, & NO,RLAT,RLON,IBO,LO,GO,IRET) C$$$ SUBPROGRAM DOCUMENTATION BLOCK C C SUBPROGRAM: POLATES1 INTERPOLATE SCALAR FIELDS (BICUBIC) C PRGMMR: IREDELL ORG: W/NMC23 DATE: 96-04-10 C C ABSTRACT: THIS SUBPROGRAM PERFORMS BICUBIC INTERPOLATION C FROM ANY GRID TO ANY GRID FOR SCALAR FIELDS. C IT REQUIRES THAT NO INPUT FIELDS HAVE BITMAPS (IBI=0). C OPTIONS ALLOW CHOICES BETWEEN STRAIGHT BICUBIC (IPOPT(1)=0) C AND CONSTRAINED BICUBIC (IPOPT(1)=1) WHERE THE VALUE IS C CONFINED WITHIN THE RANGE OF THE SURROUNDING 4 POINTS. C BILINEAR USED WITHIN ONE GRID LENGTH OF BOUNDARIES. C ONLY HORIZONTAL INTERPOLATION IS PERFORMED. C THE GRIDS ARE DEFINED BY THEIR GRID DESCRIPTION SECTIONS C (PASSED IN INTEGER FORM AS DECODED BY SUBPROGRAM W3FI63). C THE CURRENT CODE RECOGNIZES THE FOLLOWING PROJECTIONS: C (KGDS(1)=000) EQUIDISTANT CYLINDRICAL C (KGDS(1)=001) MERCATOR CYLINDRICAL C (KGDS(1)=003) LAMBERT CONFORMAL CONICAL C (KGDS(1)=004) GAUSSIAN CYLINDRICAL (SPECTRAL NATIVE) C (KGDS(1)=005) POLAR STEREOGRAPHIC AZIMUTHAL C (KGDS(1)=202) ROTATED EQUIDISTANT CYLINDRICAL (ETA NATIVE) C WHERE KGDS COULD BE EITHER INPUT KGDSI OR OUTPUT KGDSO. C AS AN ADDED BONUS THE NUMBER OF OUTPUT GRID POINTS C AND THEIR LATITUDES AND LONGITUDES ARE ALSO RETURNED. C ON THE OTHER HAND, THE OUTPUT CAN BE A SET OF STATION POINTS C IF KGDSO(1)<0, IN WHICH CASE THE NUMBER OF POINTS C AND THEIR LATITUDES AND LONGITUDES MUST BE INPUT. C OUTPUT BITMAPS WILL ONLY BE CREATED WHEN THE OUTPUT GRID C EXTENDS OUTSIDE OF THE DOMAIN OF THE INPUT GRID. C THE OUTPUT FIELD IS SET TO 0 WHERE THE OUTPUT BITMAP IS OFF. C C PROGRAM HISTORY LOG: C 96-04-10 IREDELL C C USAGE: CALL POLATES1(IPOPT,KGDSI,KGDSO,MI,MO,KM,IBI,LI,GI, C & NO,RLAT,RLON,IBO,LO,GO,IRET) C C INPUT ARGUMENT LIST: C IPOPT - INTEGER (20) INTERPOLATION OPTIONS C IPOPT(1)=0 FOR STRAIGHT BICUBIC; C IPOPT(1)=1 FOR CONSTRAINED BICUBIC WHERE VALUE IS C CONFINED WITHIN THE RANGE OF THE SURROUNDING 4 POINTS. C KGDSI - INTEGER (200) INPUT GDS PARAMETERS AS DECODED BY W3FI63 C KGDSO - INTEGER (200) OUTPUT GDS PARAMETERS C (KGDSO(1)<0 IMPLIES RANDOM STATION POINTS) C MI - INTEGER SKIP NUMBER BETWEEN INPUT GRID FIELDS IF KM>1 C OR DIMENSION OF INPUT GRID FIELDS IF KM=1 C MO - INTEGER SKIP NUMBER BETWEEN OUTPUT GRID FIELDS IF KM>1 C OR DIMENSION OF OUTPUT GRID FIELDS IF KM=1 C KM - INTEGER NUMBER OF FIELDS TO INTERPOLATE C IBI - INTEGER (KM) INPUT BITMAP FLAGS (MUST BE ALL 0) C LI - LOGICAL*1 (MI,KM) INPUT BITMAPS (IF SOME IBI(K)=1) C GI - REAL (MI,KM) INPUT FIELDS TO INTERPOLATE C NO - INTEGER NUMBER OF OUTPUT POINTS (ONLY IF KGDSO(1)<0) C RLAT - REAL (NO) OUTPUT LATITUDES IN DEGREES (IF KGDSO(1)<0) C RLON - REAL (NO) OUTPUT LONGITUDES IN DEGREES (IF KGDSO(1)<0) C C OUTPUT ARGUMENT LIST: C NO - INTEGER NUMBER OF OUTPUT POINTS (ONLY IF KGDSO(1)>=0) C RLAT - REAL (MO) OUTPUT LATITUDES IN DEGREES (IF KGDSO(1)>=0) C RLON - REAL (MO) OUTPUT LONGITUDES IN DEGREES (IF KGDSO(1)>=0) C IBO - INTEGER (KM) OUTPUT BITMAP FLAGS C LO - LOGICAL*1 (MO,KM) OUTPUT BITMAPS (ALWAYS OUTPUT) C GO - REAL (MO,KM) OUTPUT FIELDS INTERPOLATED C IRET - INTEGER RETURN CODE C 0 SUCCESSFUL INTERPOLATION C 2 UNRECOGNIZED INPUT GRID OR NO GRID OVERLAP C 3 UNRECOGNIZED OUTPUT GRID C 11 INVALID INPUT BITMAPS C C SUBPROGRAMS CALLED: C GDSWIZ GRID DESCRIPTION SECTION WIZARD C (IJKGDS) RETURN FIELD POSITION FOR A GIVEN GRID POINT C POLFIXS MAKE MULTIPLE POLE SCALAR VALUES CONSISTENT C C ATTRIBUTES: C LANGUAGE: FORTRAN 77 C C$$$ CFPP$ EXPAND(IJKGDS) INTEGER IPOPT(20) INTEGER KGDSI(200),KGDSO(200) INTEGER IBI(KM),IBO(KM) LOGICAL*1 LI(MI,KM),LO(MO,KM) REAL GI(MI,KM),GO(MO,KM) REAL RLAT(MO),RLON(MO) REAL XPTS(MO),YPTS(MO) INTEGER N11(MO),N21(MO),N12(MO),N22(MO) REAL W11(MO),W21(MO),W12(MO),W22(MO) PARAMETER(FILL=-9999.) C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C COMPUTE NUMBER OF OUTPUT POINTS AND THEIR LATITUDES AND LONGITUDES. IRET=0 IF(KGDSO(1).GE.0) THEN CALL GDSWIZ(KGDSO, 0,MO,FILL,XPTS,YPTS,RLON,RLAT,NO,0,DUM,DUM) IF(NO.EQ.0) IRET=3 ENDIF C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C LOCATE INPUT POINTS AND COMPUTE THEIR WEIGHTS CALL GDSWIZ(KGDSI,-1,NO,FILL,XPTS,YPTS,RLON,RLAT,NV,0,DUM,DUM) IF(IRET.EQ.0.AND.NV.EQ.0) IRET=2 DO K=1,KM IF(IBI(K).NE.0) IRET=11 ENDDO CMIC$ DO ALL AUTOSCOPE DO K=1,KM DO N=1,NO GO(N,K)=0. LO(N,K)=.FALSE. ENDDO ENDDO C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C COMPUTE CORNERS IF(IRET.EQ.0) THEN DO N=1,NO XI=XPTS(N) YI=YPTS(N) IF(XI.NE.FILL.AND.YI.NE.FILL) THEN I1=XI-1 I2=I1+3 J1=YI-1 J2=J1+3 XF=XI-I1-1 YF=YI-J1-1 N11(N)=IJKGDS(I1,J1,KGDSI) N21(N)=IJKGDS(I2,J1,KGDSI) N12(N)=IJKGDS(I1,J2,KGDSI) N22(N)=IJKGDS(I2,J2,KGDSI) IF(MIN(N11(N),N21(N),N12(N),N22(N)).GT.0) THEN W11(N)=XF*(1-XF)*(2-XF)*YF*(1-YF)*(2-YF)/36 W21(N)=XF*(1-XF)*(1+XF)*YF*(1-YF)*(2-YF)/36 W12(N)=XF*(1-XF)*(2-XF)*YF*(1-YF)*(1+YF)/36 W22(N)=XF*(1-XF)*(1+XF)*YF*(1-YF)*(1+YF)/36 ELSE N11(N)=0 N21(N)=0 N12(N)=0 N22(N)=0 ENDIF ELSE N11(N)=0 N21(N)=0 N12(N)=0 N22(N)=0 ENDIF ENDDO CMIC$ DO ALL AUTOSCOPE DO K=1,KM DO N=1,NO IF(N11(N).GT.0) THEN GO(N,K)=GO(N,K)+W11(N)*GI(N11(N),K)+W21(N)*GI(N21(N),K) & +W12(N)*GI(N12(N),K)+W22(N)*GI(N22(N),K) ENDIF ENDDO ENDDO C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C COMPUTE TOPS AND BOTTOMS DO N=1,NO XI=XPTS(N) YI=YPTS(N) IF(XI.NE.FILL.AND.YI.NE.FILL) THEN LP=N11(N) IF(LP.GT.0) THEN I1=XI I2=I1+1 J1=YI-1 J2=J1+3 XF=XI-I1 YF=YI-J1-1 N11(N)=IJKGDS(I1,J1,KGDSI) N21(N)=IJKGDS(I2,J1,KGDSI) N12(N)=IJKGDS(I1,J2,KGDSI) N22(N)=IJKGDS(I2,J2,KGDSI) W11(N)=-(1+XF)*(1-XF)*(2-XF)*YF*(1-YF)*(2-YF)/12 W21(N)=-XF*(2-XF)*(1+XF)*YF*(1-YF)*(2-YF)/12 W12(N)=-(1+XF)*(1-XF)*(2-XF)*YF*(1-YF)*(1+YF)/12 W22(N)=-XF*(2-XF)*(1+XF)*YF*(1-YF)*(1+YF)/12 ENDIF ELSE N11(N)=0 N21(N)=0 N12(N)=0 N22(N)=0 ENDIF ENDDO CMIC$ DO ALL AUTOSCOPE DO K=1,KM DO N=1,NO IF(N11(N).GT.0) THEN GO(N,K)=GO(N,K)+W11(N)*GI(N11(N),K)+W21(N)*GI(N21(N),K) & +W12(N)*GI(N12(N),K)+W22(N)*GI(N22(N),K) ENDIF ENDDO ENDDO C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C COMPUTE LEFTS AND RIGHTS DO N=1,NO XI=XPTS(N) YI=YPTS(N) IF(XI.NE.FILL.AND.YI.NE.FILL) THEN LP=N11(N) IF(LP.GT.0) THEN I1=XI-1 I2=I1+3 J1=YI J2=J1+1 XF=XI-I1-1 YF=YI-J1 N11(N)=IJKGDS(I1,J1,KGDSI) N21(N)=IJKGDS(I2,J1,KGDSI) N12(N)=IJKGDS(I1,J2,KGDSI) N22(N)=IJKGDS(I2,J2,KGDSI) W11(N)=-XF*(1-XF)*(2-XF)*(1+YF)*(1-YF)*(2-YF)/12 W21(N)=-XF*(1-XF)*(1+XF)*(1+YF)*(1-YF)*(2-YF)/12 W12(N)=-XF*(1-XF)*(2-XF)*YF*(2-YF)*(1+YF)/12 W22(N)=-XF*(1-XF)*(1+XF)*YF*(2-YF)*(1+YF)/12 ENDIF ELSE N11(N)=0 N21(N)=0 N12(N)=0 N22(N)=0 ENDIF ENDDO CMIC$ DO ALL AUTOSCOPE DO K=1,KM DO N=1,NO IF(N11(N).GT.0) THEN GO(N,K)=GO(N,K)+W11(N)*GI(N11(N),K)+W21(N)*GI(N21(N),K) & +W12(N)*GI(N12(N),K)+W22(N)*GI(N22(N),K) ENDIF ENDDO ENDDO C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C COMPUTE CENTERS DO N=1,NO XI=XPTS(N) YI=YPTS(N) IF(XI.NE.FILL.AND.YI.NE.FILL) THEN LP=N11(N) I1=XI I2=I1+1 J1=YI J2=J1+1 XF=XI-I1 YF=YI-J1 N11(N)=IJKGDS(I1,J1,KGDSI) N21(N)=IJKGDS(I2,J1,KGDSI) N12(N)=IJKGDS(I1,J2,KGDSI) N22(N)=IJKGDS(I2,J2,KGDSI) IF(LP.GT.0) THEN W11(N)=(1+XF)*(1-XF)*(2-XF)*(1+YF)*(1-YF)*(2-YF)/4 W21(N)=XF*(2-XF)*(1+XF)*(1+YF)*(1-YF)*(2-YF)/4 W12(N)=(1+XF)*(1-XF)*(2-XF)*YF*(2-YF)*(1+YF)/4 W22(N)=XF*(2-XF)*(1+XF)*YF*(2-YF)*(1+YF)/4 ELSEIF(MIN(N11(N),N21(N),N12(N),N22(N)).GT.0) THEN W11(N)=(1-XF)*(1-YF) W21(N)=XF*(1-YF) W12(N)=(1-XF)*YF W22(N)=XF*YF ELSE N11(N)=0 N21(N)=0 N12(N)=0 N22(N)=0 ENDIF ELSE N11(N)=0 N21(N)=0 N12(N)=0 N22(N)=0 ENDIF ENDDO CMIC$ DO ALL AUTOSCOPE DO K=1,KM DO N=1,NO IF(N11(N).GT.0) THEN GO(N,K)=GO(N,K)+W11(N)*GI(N11(N),K)+W21(N)*GI(N21(N),K) & +W12(N)*GI(N12(N),K)+W22(N)*GI(N22(N),K) IF(IPOPT(1).GT.0) THEN GMIN=MIN(GI(N11(N),K),GI(N21(N),K), & GI(N12(N),K),GI(N22(N),K)) GMAX=MAX(GI(N11(N),K),GI(N21(N),K), & GI(N12(N),K),GI(N22(N),K)) GO(N,K)=MIN(MAX(GO(N,K),GMIN),GMAX) ENDIF LO(N,K)=.TRUE. ENDIF ENDDO ENDDO ENDIF C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - CMIC$ DO ALL AUTOSCOPE DO K=1,KM IBO(K)=IBI(K) DO N=1,NO IF(.NOT.LO(N,K)) THEN IBO(K)=1 GO(N,K)=0. ENDIF ENDDO ENDDO IF(KGDSO(1).EQ.0) CALL POLFIXS(NO,MO,KM,RLAT,RLON,IBO,LO,GO) C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - END