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polates3.f
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polates3.f
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C-----------------------------------------------------------------------
SUBROUTINE POLATES3(IPOPT,KGDSI,KGDSO,MI,MO,KM,IBI,LI,GI,
& NO,RLAT,RLON,IBO,LO,GO,IRET)
C$$$ SUBPROGRAM DOCUMENTATION BLOCK
C
C SUBPROGRAM: POLATES3 INTERPOLATE SCALAR FIELDS (BUDGET)
C PRGMMR: IREDELL ORG: W/NMC23 DATE: 96-04-10
C
C ABSTRACT: THIS SUBPROGRAM PERFORMS BUDGET INTERPOLATION
C FROM ANY GRID TO ANY GRID FOR SCALAR FIELDS.
C IT MAY BE RUN FOR A WHOLE (KGDSO(1)>=0) OR A SUBSECTION
C OF AN OUTPUT GRID (SUBTRACT KGDSO(1) FROM 255 AND
C PASS IN THE LAT/LONS OF EACH POINT).
C THE ALGORITHM SIMPLY COMPUTES (WEIGHTED) AVERAGES
C OF BILINEARLY INTERPOLATED POINTS ARRANGED IN A SQUARE BOX
C CENTERED AROUND EACH OUTPUT GRID POINT AND STRETCHING
C NEARLY HALFWAY TO EACH OF THE NEIGHBORING GRID POINTS.
C OPTIONS ALLOW CHOICES OF NUMBER OF POINTS IN EACH RADIUS
C FROM THE CENTER POINT (IPOPT(1)) WHICH DEFAULTS TO 2
C (IF IPOPT(1)=-1) MEANING THAT 25 POINTS WILL BE AVERAGED;
C FURTHER OPTIONS ARE THE RESPECTIVE WEIGHTS FOR THE RADIUS
C POINTS STARTING AT THE CENTER POINT (IPOPT(2:2+IPOPT(1))
C WHICH DEFAULTS TO ALL 1 (IF IPOPT(1)=-1 OR IPOPT(2)=-1).
C A SPECIAL INTERPOLATION IS DONE IF IPOPT(2)=-2.
C IN THIS CASE, THE BOXES STRETCH NEARLY ALL THE WAY TO
C EACH OF THE NEIGHBORING GRID POINTS AND THE WEIGHTS
C ARE THE ADJOINT OF THE BILINEAR INTERPOLATION WEIGHTS.
C THIS CASE GIVES QUASI-SECOND-ORDER BUDGET INTERPOLATION.
C ANOTHER OPTION IS THE MINIMUM PERCENTAGE FOR MASK,
C I.E. PERCENT VALID INPUT DATA REQUIRED TO MAKE OUTPUT DATA,
C (IPOPT(3+IPOPT(1)) WHICH DEFAULTS TO 50 (IF -1).
C IN CASES WHERE THERE IS NO OR INSUFFICIENT VALID INPUT DATA,
C THE USER MAY CHOOSE TO SEARCH FOR THE NEAREST VALID DATA.
C THIS IS INVOKED BY SETTING IPOPT(20) TO THE WIDTH OF
C THE SEARCH SQUARE. THE DEFAULT IS 1 (NO SEARCH). SQUARES ARE
C SEARCHED FOR VALID DATA IN A SPIRAL PATTERN
C STARTING FROM THE CENTER. NO SEARCHING IS DONE WHERE
C THE OUTPUT GRID IS OUTSIDE THE INPUT GRID.
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 (KGDSO(1)>=0) THE NUMBER OF OUTPUT
C GRID POINTS AND THEIR LATITUDES AND LONGITUDES
C ARE ALSO RETURNED. INPUT BITMAPS WILL BE INTERPOLATED
C TO OUTPUT BITMAPS. OUTPUT BITMAPS WILL ALSO BE
C 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 1999-04-08 IREDELL SPLIT IJKGDS INTO TWO PIECES
C 1999-04-08 IREDELL ADDED BILINEAR OPTION IPOPT(2)=-2
C 2001-06-18 IREDELL INCLUDE MINIMUM MASK PERCENTAGE OPTION
C 2006-01-04 GAYNO ADDED OPTION TO DO SUBSECTION OF OUTPUT GRID.
C ADDED SPIRAL SEARCH OPTION.
C
C USAGE: CALL POLATES3(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) IS NUMBER OF RADIUS POINTS
C (DEFAULTS TO 2 IF IPOPT(1)=-1);
C IPOPT(2:2+IPOPT(1)) ARE RESPECTIVE WEIGHTS
C (DEFAULTS TO ALL 1 IF IPOPT(1)=-1 OR IPOPT(2)=-1).
C IPOPT(3+IPOPT(1)) IS MINIMUM PERCENTAGE FOR MASK
C (DEFAULTS TO 50 IF IPOPT(3+IPOPT(1)=-1)
C KGDSI - INTEGER (200) INPUT GDS PARAMETERS AS DECODED BY W3FI63
C KGDSO - INTEGER (200) OUTPUT GDS PARAMETERS
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
C LI - LOGICAL*1 (MI,KM) INPUT BITMAPS (IF SOME IBI(K)=1)
C GI - REAL (MI,KM) INPUT FIELDS TO INTERPOLATE
C
C OUTPUT ARGUMENT LIST:
C NO - INTEGER NUMBER OF OUTPUT POINTS
C RLAT - REAL (MO) OUTPUT LATITUDES IN DEGREES
C RLON - REAL (MO) OUTPUT LONGITUDES IN DEGREES
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 32 INVALID BUDGET METHOD PARAMETERS
C
C SUBPROGRAMS CALLED:
C GDSWIZ GRID DESCRIPTION SECTION WIZARD
C IJKGDS0 SET UP PARAMETERS FOR IJKGDS1
C (IJKGDS1) 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(IJKGDS1)
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)
REAL XPTB(MO),YPTB(MO),RLOB(MO),RLAB(MO)
INTEGER N11(MO),N21(MO),N12(MO),N22(MO)
REAL W11(MO),W21(MO),W12(MO),W22(MO)
REAL WO(MO,KM)
INTEGER IJKGDSA(20)
PARAMETER(FILL=-9999.)
C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C COMPUTE NUMBER OF OUTPUT POINTS AND THEIR LATITUDES AND LONGITUDES.
C DO SUBSECTION OF GRID IF KGDSO(1) IS SUBTRACTED FROM 255.
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
ELSE
KGDSO(1)=255+KGDSO(1)
CALL GDSWIZ(KGDSO,-1,MO,FILL,XPTS,YPTS,RLON,RLAT,NO,0,DUM,DUM)
IF(NO.EQ.0) IRET=3
ENDIF
C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C SET PARAMETERS
IF(IPOPT(1).GT.16) IRET=32
MSPIRAL=MAX(IPOPT(20),1)
NB1=IPOPT(1)
IF(NB1.EQ.-1) NB1=2
IF(IRET.EQ.0.AND.NB1.LT.0) IRET=32
LSW=1
IF(IPOPT(2).EQ.-2) LSW=2
IF(IPOPT(1).EQ.-1.OR.IPOPT(2).EQ.-1) LSW=0
IF(IRET.EQ.0.AND.LSW.EQ.1.AND.NB1.GT.15) IRET=32
MP=IPOPT(3+IPOPT(1))
IF(MP.EQ.-1.OR.MP.EQ.0) MP=50
IF(MP.LT.0.OR.MP.GT.100) IRET=32
PMP=MP*0.01
IF(IRET.EQ.0) THEN
NB2=2*NB1+1
RB2=1./NB2
NB3=NB2*NB2
NB4=NB3
IF(LSW.EQ.2) THEN
RB2=1./(NB1+1)
NB4=(NB1+1)**4
ELSEIF(LSW.EQ.1) THEN
NB4=IPOPT(2)
DO IB=1,NB1
NB4=NB4+8*IB*IPOPT(2+IB)
ENDDO
ENDIF
ELSE
NB3=0
NB4=1
ENDIF
CMIC$ DO ALL AUTOSCOPE
DO K=1,KM
DO N=1,NO
GO(N,K)=0.
WO(N,K)=0.
ENDDO
ENDDO
C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C LOOP OVER SAMPLE POINTS IN OUTPUT GRID BOX
CALL IJKGDS0(KGDSI,IJKGDSA)
DO NB=1,NB3
C LOCATE INPUT POINTS AND COMPUTE THEIR WEIGHTS
JB=(NB-1)/NB2-NB1
IB=NB-(JB+NB1)*NB2-NB1-1
LB=MAX(ABS(IB),ABS(JB))
WB=1
IF(LSW.EQ.2) THEN
WB=(NB1+1-ABS(IB))*(NB1+1-ABS(JB))
ELSEIF(LSW.EQ.1) THEN
WB=IPOPT(2+LB)
ENDIF
IF(WB.NE.0) THEN
DO N=1,NO
XPTB(N)=XPTS(N)+IB*RB2
YPTB(N)=YPTS(N)+JB*RB2
ENDDO
CALL GDSWIZ(KGDSO, 1,NO,FILL,XPTB,YPTB,RLOB,RLAB,NV,0,DUM,DUM)
CALL GDSWIZ(KGDSI,-1,NO,FILL,XPTB,YPTB,RLOB,RLAB,NV,0,DUM,DUM)
IF(IRET.EQ.0.AND.NV.EQ.0.AND.LB.EQ.0) IRET=2
DO N=1,NO
XI=XPTB(N)
YI=YPTB(N)
IF(XI.NE.FILL.AND.YI.NE.FILL) THEN
I1=XI
I2=I1+1
J1=YI
J2=J1+1
XF=XI-I1
YF=YI-J1
N11(N)=IJKGDS1(I1,J1,IJKGDSA)
N21(N)=IJKGDS1(I2,J1,IJKGDSA)
N12(N)=IJKGDS1(I1,J2,IJKGDSA)
N22(N)=IJKGDS1(I2,J2,IJKGDSA)
IF(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
C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C INTERPOLATE WITH OR WITHOUT BITMAPS
CMIC$ DO ALL AUTOSCOPE
DO K=1,KM
DO N=1,NO
IF(N11(N).GT.0) THEN
IF(IBI(K).EQ.0) THEN
GB=W11(N)*GI(N11(N),K)+W21(N)*GI(N21(N),K)
& +W12(N)*GI(N12(N),K)+W22(N)*GI(N22(N),K)
GO(N,K)=GO(N,K)+WB*GB
WO(N,K)=WO(N,K)+WB
ELSE
IF(LI(N11(N),K)) THEN
GO(N,K)=GO(N,K)+WB*W11(N)*GI(N11(N),K)
WO(N,K)=WO(N,K)+WB*W11(N)
ENDIF
IF(LI(N21(N),K)) THEN
GO(N,K)=GO(N,K)+WB*W21(N)*GI(N21(N),K)
WO(N,K)=WO(N,K)+WB*W21(N)
ENDIF
IF(LI(N12(N),K)) THEN
GO(N,K)=GO(N,K)+WB*W12(N)*GI(N12(N),K)
WO(N,K)=WO(N,K)+WB*W12(N)
ENDIF
IF(LI(N22(N),K)) THEN
GO(N,K)=GO(N,K)+WB*W22(N)*GI(N22(N),K)
WO(N,K)=WO(N,K)+WB*W22(N)
ENDIF
ENDIF
ENDIF
ENDDO
ENDDO
ENDIF
ENDDO ! sub-grid points
C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C COMPUTE OUTPUT BITMAPS AND FIELDS
CMIC$ DO ALL AUTOSCOPE
KM_LOOP : DO K=1,KM
IBO(K)=IBI(K)
N_LOOP : DO N=1,NO
LO(N,K)=WO(N,K).GE.PMP*NB4
IF(LO(N,K)) THEN
GO(N,K)=GO(N,K)/WO(N,K)
ELSEIF (MSPIRAL.GT.1) THEN
CALL GDSWIZ(KGDSI,-1,1,FILL,XX,YY,RLON(N),RLAT(N),NV,0,
& DUM,DUM)
IF (NV.EQ.1)THEN
I1=NINT(XX)
J1=NINT(YY)
IXS=SIGN(1.,XX-I1)
JXS=SIGN(1.,YY-J1)
SPIRAL_LOOP : DO MX=2,MSPIRAL**2
KXS=SQRT(4*MX-2.5)
KXT=MX-(KXS**2/4+1)
SELECT CASE(MOD(KXS,4))
CASE(1)
IX=I1-IXS*(KXS/4-KXT)
JX=J1-JXS*KXS/4
CASE(2)
IX=I1+IXS*(1+KXS/4)
JX=J1-JXS*(KXS/4-KXT)
CASE(3)
IX=I1+IXS*(1+KXS/4-KXT)
JX=J1+JXS*(1+KXS/4)
CASE DEFAULT
IX=I1-IXS*KXS/4
JX=J1+JXS*(KXS/4-KXT)
END SELECT
NX=IJKGDS1(IX,JX,IJKGDSA)
IF(NX.GT.0.)THEN
IF(LI(NX,K).OR.IBI(K).EQ.0) THEN
GO(N,K)=GI(NX,K)
LO(N,K)=.TRUE.
CYCLE N_LOOP
ENDIF
ENDIF
ENDDO SPIRAL_LOOP
IBO(K)=1
GO(N,K)=0.
ELSE
IBO(K)=1
GO(N,K)=0.
ENDIF
ELSE ! no spiral search option
IBO(K)=1
GO(N,K)=0.
ENDIF
ENDDO N_LOOP
ENDDO KM_LOOP
IF(KGDSO(1).EQ.0) CALL POLFIXS(NO,MO,KM,RLAT,RLON,IBO,LO,GO)
C - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
END