SUBROUTINE FSIZER1(NRECL,KSIZE,NRFILE,NAMFIL) C sbr_pleph.f entsteht aus testeph.f durch loeschen des Hauptprogrammes 11.02.15 C++++++++++++++++++++++++ C C Version 1.0 uses the INQUIRE statement to find out the the record length C of the direct access file before opening it. This procedure is non-standard, C but seems to work for VAX machines. C C THE SUBROUTINE ALSO SETS THE VALUES OF NRECL, NRFILE, AND NAMFIL. C ***************************************************************** C ***************************************************************** C C THE PARAMETERS NAMFIL, NRECL, AND NRFILE ARE TO BE SET BY THE USER C C ***************************************************************** C NAMFIL IS THE EXTERNAL NAME OF THE BINARY EPHEMERIS FILE CHARACTER*80 NAMFIL c NAMFIL='JPLEPH' C ***************************************************************** C NRECL=1 IF "RECL" IN THE OPEN STATEMENT IS THE RECORD LENGTH IN S.P. WORDS C NRECL=4 IF "RECL" IN THE OPEN STATEMENT IS THE RECORD LENGTH IN BYTES C (for a VAX, it is probably 1) C C NRECL= NRECL= 4 11.02.15 ==> s.o. C ***************************************************************** C NRFILE IS THE INTERNAL UNIT NUMBER USED FOR THE EPHEMERIS FILE c NRFILE=12 C ***************************************************************** C FIND THE RECORD SIZE USING THE INQUIRE STATEMENT c IRECSZ=0 INQUIRE(FILE=NAMFIL,RECL=IRECSZ) C IF 'INQUIRE' DOES NOT WORK, USUALLY IRECSZ WILL BE LEFT AT 0 C IF(IRECSZ .LE. 0) write(*,*) IF(IRECSZ .LE. 0) write(6,*) 11.02.15 . ' INQUIRE STATEMENT PROBABLY DID NOT WORK' KSIZE=IRECSZ/NRECL RETURN END C++++++++++++++++++++++++ C SUBROUTINE FSIZER2(NRECL,KSIZE,NRFILE,NAMFIL) C C++++++++++++++++++++++++ C THIS SUBROUTINE OPENS THE FILE, 'NAMFIL', WITH A PHONY RECORD LENGTH, READS C THE FIRST RECORD, AND USES THE INFO TO COMPUTE KSIZE, THE NUMBER OF SINGLE C PRECISION WORDS IN A RECORD. C C THE SUBROUTINE ALSO SETS THE VALUES OF NRECL, NRFILE, AND NAMFIL. IMPLICIT DOUBLE PRECISION(A-H,O-Z) SAVE INTEGER OLDMAX PARAMETER (OLDMAX = 400) INTEGER NMAX PARAMETER (NMAX = 1000) CHARACTER*6 TTL(14,3),CNAM(NMAX) CHARACTER*80 NAMFIL DIMENSION SS(3) INTEGER IPT(3,13) C ***************************************************************** C ***************************************************************** C C THE PARAMETERS NRECL, NRFILE, AND NAMFIL ARE TO BE SET BY THE USER C C ***************************************************************** C NRECL=1 IF "RECL" IN THE OPEN STATEMENT IS THE RECORD LENGTH IN S.P. WORDS C NRECL=4 IF "RECL" IN THE OPEN STATEMENT IS THE RECORD LENGTH IN BYTES C (for UNIX, it is probably 4) C C NRECL= NRECL= 4 11.02.15 C NRFILE IS THE INTERNAL UNIT NUMBER USED FOR THE EPHEMERIS FILE NRFILE=12 C NAMFIL IS THE EXTERNAL NAME OF THE BINARY EPHEMERIS FILE NAMFIL='JPLEPH' C ***************************************************************** C ***************************************************************** C ** OPEN THE DIRECT-ACCESS FILE AND GET THE POINTERS IN ORDER TO C ** DETERMINE THE SIZE OF THE EPHEMERIS RECORD MRECL=NRECL*1000 OPEN(NRFILE, * FILE=NAMFIL, * ACCESS='DIRECT', * FORM='UNFORMATTED', * RECL=MRECL, * STATUS='OLD') READ(NRFILE,REC=1)TTL,(CNAM(K),K=1,OLDMAX),SS,NCON,AU,EMRAT, & ((IPT(I,J),I=1,3),J=1,12),NUMDE,(IPT(I,13),I=1,3) CLOSE(NRFILE) C FIND THE NUMBER OF EPHEMERIS COEFFICIENTS FROM THE POINTERS KMX = 0 KHI = 0 DO I = 1,13 IF (IPT(1,I) .GT. KMX) THEN KMX = IPT(1,I) KHI = I ENDIF ENDDO ND = 3 IF (KHI .EQ. 12) ND=2 KSIZE = 2*(IPT(1,KHI)+ND*IPT(2,KHI)*IPT(3,KHI)-1) RETURN END C++++++++++++++++++++++++ C SUBROUTINE FSIZER3(NRECL,KSIZE,NRFILE,NAMFIL) C C++++++++++++++++++++++++ C C THE SUBROUTINE SETS THE VALUES OF NRECL, KSIZE, NRFILE, AND NAMFIL. SAVE CHARACTER*80 NAMFIL C ***************************************************************** C ***************************************************************** C C THE PARAMETERS NRECL, NRFILE, AND NAMFIL ARE TO BE SET BY THE USER C ***************************************************************** C NRECL=1 IF "RECL" IN THE OPEN STATEMENT IS THE RECORD LENGTH IN S.P. WORDS C NRECL=4 IF "RECL" IN THE OPEN STATEMENT IS THE RECORD LENGTH IN BYTES C NRECL= NRECL= 4 11.02.15 C ***************************************************************** C NRFILE IS THE INTERNAL UNIT NUMBER USED FOR THE EPHEMERIS FILE (DEFAULT: 12) NRFILE=12 C ***************************************************************** C NAMFIL IS THE EXTERNAL NAME OF THE BINARY EPHEMERIS FILE NAMFIL='JPLEPH' 07.04.15 C NAMFIL='/work/Tux3/lenhardt/5/DE430-Test/JPLEPH' 11.02.15 C NAMFIL='/work/Tux3/lenhardt/5/DE430/JPLEPH' 12.02.15 Umbenennung C NAMFIL='/work/Tux3/lenhardt/APFS-WEB/apfs/src/JPLEPH' 01.04.15 lokaler Bezug auf svn C ***************************************************************** C KSIZE must be set by the user according to the ephemeris to be read C For de200, set KSIZE to 1652 C For de405, set KSIZE to 2036 C For de406, set KSIZE to 1456 C For de414, set KSIZE to 2036 C For de418, set KSIZE to 2036 C For de421, set KSIZE to 2036 C For de422, set KSIZE to 2036 C For de423, set KSIZE to 2036 C For de424, set KSIZE to 2036 C For de430, set KSIZE to 2036 C KSIZE = KSIZE = 2036 11.02.15 C ******************************************************************* RETURN END C++++++++++++++++++++++++++ C SUBROUTINE PLEPH ( ET, NTARG, NCENT, RRD ) C C++++++++++++++++++++++++++ C NOTE : Over the years, different versions of PLEPH have had a fifth argument: C sometimes, an error return statement number; sometimes, a logical denoting C whether or not the requested date is covered by the ephemeris. We apologize C for this inconsistency; in this present version, we use only the four necessary C arguments and do the testing outside of the subroutine. C C THIS SUBROUTINE READS THE JPL PLANETARY EPHEMERIS C AND GIVES THE POSITION AND VELOCITY OF THE POINT 'NTARG' C WITH RESPECT TO 'NCENT'. C C CALLING SEQUENCE PARAMETERS: C C ET = D.P. JULIAN EPHEMERIS DATE AT WHICH INTERPOLATION C IS WANTED. C C ** NOTE THE ENTRY DPLEPH FOR A DOUBLY-DIMENSIONED TIME ** C THE REASON FOR THIS OPTION IS DISCUSSED IN THE C SUBROUTINE STATE C C NTARG = INTEGER NUMBER OF 'TARGET' POINT. C C NCENT = INTEGER NUMBER OF CENTER POINT. C C THE NUMBERING CONVENTION FOR 'NTARG' AND 'NCENT' IS: C C 1 = MERCURY 8 = NEPTUNE C 2 = VENUS 9 = PLUTO C 3 = EARTH 10 = MOON C 4 = MARS 11 = SUN C 5 = JUPITER 12 = SOLAR-SYSTEM BARYCENTER C 6 = SATURN 13 = EARTH-MOON BARYCENTER C 7 = URANUS 14 = NUTATIONS (LONGITUDE AND OBLIQ) C 15 = LIBRATIONS, IF ON EPH FILE C C (IF NUTATIONS ARE WANTED, SET NTARG = 14. FOR LIBRATIONS, C SET NTARG = 15. SET NCENT=0.) C C RRD = OUTPUT 6-WORD D.P. ARRAY CONTAINING POSITION AND VELOCITY C OF POINT 'NTARG' RELATIVE TO 'NCENT'. THE UNITS ARE AU AND C AU/DAY. FOR LIBRATIONS THE UNITS ARE RADIANS AND RADIANS C PER DAY. IN THE CASE OF NUTATIONS THE FIRST FOUR WORDS OF C RRD WILL BE SET TO NUTATIONS AND RATES, HAVING UNITS OF C RADIANS AND RADIANS/DAY. C C The option is available to have the units in km and km/sec. C For this, set km=.true. in the STCOMX common block. C IMPLICIT DOUBLE PRECISION (A-H,O-Z) INTEGER NMAX PARAMETER (NMAX = 1000) DIMENSION RRD(6),ET2Z(2),ET2(2),PV(6,13) DIMENSION PVST(6,11),PNUT(4) DIMENSION SS(3),CVAL(NMAX),PVSUN(6),ZIPS(2) DATA ZIPS/2*0.d0/ LOGICAL BSAVE,KM,BARY LOGICAL FIRST DATA FIRST/.TRUE./ INTEGER LIST(12),IPT(39),DENUM COMMON/EPHHDR/CVAL,SS,AU,EMRAT,DENUM,NCON,IPT COMMON/STCOMX/KM,BARY,PVSUN C INITIALIZE ET2 FOR 'STATE' AND SET UP COMPONENT COUNT C ET2(1)=ET ET2(2)=0.D0 GO TO 11 C ENTRY POINT 'DPLEPH' FOR DOUBLY-DIMENSIONED TIME ARGUMENT C (SEE THE DISCUSSION IN THE SUBROUTINE STATE) ENTRY DPLEPH(ET2Z,NTARG,NCENT,RRD) ET2(1)=ET2Z(1) ET2(2)=ET2Z(2) 11 IF(FIRST) CALL STATE(ZIPS,LIST,PVST,PNUT) FIRST=.FALSE. 96 IF(NTARG .EQ. NCENT) RETURN DO I=1,12 LIST(I)=0 ENDDO C CHECK FOR NUTATION CALL IF(NTARG.NE.14) GO TO 97 IF(IPT(35).GT.0) THEN LIST(11)=2 CALL STATE(ET2,LIST,PVST,PNUT) DO I=1,4 RRD(I)=PNUT(I) ENDDO RRD(5) = 0.d0 RRD(6) = 0.d0 RETURN ELSE DO I=1,4 RRD(I)=0.d0 ENDDO WRITE(6,297) 297 FORMAT(' ***** NO NUTATIONS ON THE EPHEMERIS FILE *****') STOP ENDIF C CHECK FOR LIBRATIONS 97 CONTINUE DO I=1,6 RRD(I)=0.d0 ENDDO IF(NTARG.NE.15) GO TO 98 IF(IPT(38).GT.0) THEN LIST(12)=2 CALL STATE(ET2,LIST,PVST,PNUT) DO I=1,6 RRD(I)=PVST(I,11) ENDDO RETURN ELSE WRITE(6,298) 298 FORMAT(' ***** NO LIBRATIONS ON THE EPHEMERIS FILE *****') STOP ENDIF C FORCE BARYCENTRIC OUTPUT BY 'STATE' 98 BSAVE=BARY BARY=.TRUE. C SET UP PROPER ENTRIES IN 'LIST' ARRAY FOR STATE CALL DO I=1,2 K=NTARG IF(I .EQ. 2) K=NCENT IF(K .LE. 10) LIST(K)=2 IF(K .EQ. 10) LIST(3)=2 IF(K .EQ. 3) LIST(10)=2 IF(K .EQ. 13) LIST(3)=2 ENDDO C MAKE CALL TO STATE CALL STATE(ET2,LIST,PVST,PNUT) DO I=1,10 DO J = 1,6 PV(J,I) = PVST(J,I) ENDDO ENDDO IF(NTARG .EQ. 11 .OR. NCENT .EQ. 11) THEN DO I=1,6 PV(I,11)=PVSUN(I) ENDDO ENDIF IF(NTARG .EQ. 12 .OR. NCENT .EQ. 12) THEN DO I=1,6 PV(I,12)=0.D0 ENDDO ENDIF IF(NTARG .EQ. 13 .OR. NCENT .EQ. 13) THEN DO I=1,6 PV(I,13) = PVST(I,3) ENDDO ENDIF IF(NTARG*NCENT .EQ. 30 .AND. NTARG+NCENT .EQ. 13) THEN DO I=1,6 PV(I,3)=0.D0 ENDDO GO TO 99 ENDIF IF(LIST(3) .EQ. 2) THEN DO I=1,6 PV(I,3)=PVST(I,3)-PVST(I,10)/(1.D0+EMRAT) ENDDO ENDIF IF(LIST(10) .EQ. 2) THEN DO I=1,6 PV(I,10) = PV(I,3)+PVST(I,10) ENDDO ENDIF 99 DO I=1,6 RRD(I)=PV(I,NTARG)-PV(I,NCENT) ENDDO BARY=BSAVE RETURN END C+++++++++++++++++++++++++++++++++ C SUBROUTINE INTERP(BUF,T,NCF,NCM,NA,IFL,PV) C C+++++++++++++++++++++++++++++++++ C C THIS SUBROUTINE DIFFERENTIATES AND INTERPOLATES A C SET OF CHEBYSHEV COEFFICIENTS TO GIVE POSITION AND VELOCITY C C CALLING SEQUENCE PARAMETERS: C C INPUT: C C BUF 1ST LOCATION OF ARRAY OF D.P. CHEBYSHEV COEFFICIENTS OF POSITION C C T T(1) IS DP FRACTIONAL TIME IN INTERVAL COVERED BY C COEFFICIENTS AT WHICH INTERPOLATION IS WANTED C (0 .LE. T(1) .LE. 1). T(2) IS DP LENGTH OF WHOLE C INTERVAL IN INPUT TIME UNITS. C C NCF # OF COEFFICIENTS PER COMPONENT C C NCM # OF COMPONENTS PER SET OF COEFFICIENTS C C NA # OF SETS OF COEFFICIENTS IN FULL ARRAY C (I.E., # OF SUB-INTERVALS IN FULL INTERVAL) C C IFL INTEGER FLAG: =1 FOR POSITIONS ONLY C =2 FOR POS AND VEL C C C OUTPUT: C C PV INTERPOLATED QUANTITIES REQUESTED. DIMENSION C EXPECTED IS PV(NCM,IFL), DP. C C IMPLICIT DOUBLE PRECISION (A-H,O-Z) C SAVE C DOUBLE PRECISION BUF(NCF,NCM,*),T(2),PV(NCM,*),PC(18),VC(18) C DATA NP/2/ DATA NV/3/ DATA TWOT/0.D0/ DATA PC(1),PC(2)/1.D0,0.D0/ DATA VC(2)/1.D0/ C C ENTRY POINT. GET CORRECT SUB-INTERVAL NUMBER FOR THIS SET C OF COEFFICIENTS AND THEN GET NORMALIZED CHEBYSHEV TIME C WITHIN THAT SUBINTERVAL. C DNA=DBLE(NA) DT1=DINT(T(1)) TEMP=DNA*T(1) L=IDINT(TEMP-DT1)+1 C TC IS THE NORMALIZED CHEBYSHEV TIME (-1 .LE. TC .LE. 1) TC=2.D0*(DMOD(TEMP,1.D0)+DT1)-1.D0 C CHECK TO SEE WHETHER CHEBYSHEV TIME HAS CHANGED, C AND COMPUTE NEW POLYNOMIAL VALUES IF IT HAS. C (THE ELEMENT PC(2) IS THE VALUE OF T1(TC) AND HENCE C CONTAINS THE VALUE OF TC ON THE PREVIOUS CALL.) IF(TC.NE.PC(2)) THEN NP=2 NV=3 PC(2)=TC TWOT=TC+TC ENDIF C C BE SURE THAT AT LEAST 'NCF' POLYNOMIALS HAVE BEEN EVALUATED C AND ARE STORED IN THE ARRAY 'PC'. C IF(NP.LT.NCF) THEN DO 1 I=NP+1,NCF PC(I)=TWOT*PC(I-1)-PC(I-2) 1 CONTINUE NP=NCF ENDIF C C INTERPOLATE TO GET POSITION FOR EACH COMPONENT C DO 2 I=1,NCM PV(I,1)=0.D0 DO 3 J=NCF,1,-1 PV(I,1)=PV(I,1)+PC(J)*BUF(J,I,L) 3 CONTINUE 2 CONTINUE IF(IFL.LE.1) RETURN C C IF VELOCITY INTERPOLATION IS WANTED, BE SURE ENOUGH C DERIVATIVE POLYNOMIALS HAVE BEEN GENERATED AND STORED. C VFAC=(DNA+DNA)/T(2) VC(3)=TWOT+TWOT IF(NV.LT.NCF) THEN DO 4 I=NV+1,NCF VC(I)=TWOT*VC(I-1)+PC(I-1)+PC(I-1)-VC(I-2) 4 CONTINUE NV=NCF ENDIF C C INTERPOLATE TO GET VELOCITY FOR EACH COMPONENT C DO 5 I=1,NCM PV(I,2)=0.D0 DO 6 J=NCF,2,-1 PV(I,2)=PV(I,2)+VC(J)*BUF(J,I,L) 6 CONTINUE PV(I,2)=PV(I,2)*VFAC 5 CONTINUE C RETURN C END C+++++++++++++++++++++++++ C SUBROUTINE SPLIT(TT,FR) C C+++++++++++++++++++++++++ C C THIS SUBROUTINE BREAKS A D.P. NUMBER INTO A D.P. INTEGER C AND A D.P. FRACTIONAL PART. C C CALLING SEQUENCE PARAMETERS: C C TT = D.P. INPUT NUMBER C C FR = D.P. 2-WORD OUTPUT ARRAY. C FR(1) CONTAINS INTEGER PART C FR(2) CONTAINS FRACTIONAL PART C C FOR NEGATIVE INPUT NUMBERS, FR(1) CONTAINS THE NEXT C MORE NEGATIVE INTEGER; FR(2) CONTAINS A POSITIVE FRACTION. C C CALLING SEQUENCE DECLARATIONS C IMPLICIT DOUBLE PRECISION (A-H,O-Z) DIMENSION FR(2) C MAIN ENTRY -- GET INTEGER AND FRACTIONAL PARTS FR(1)=DINT(TT) FR(2)=TT-FR(1) IF(TT.GE.0.D0 .OR. FR(2).EQ.0.D0) RETURN C MAKE ADJUSTMENTS FOR NEGATIVE INPUT NUMBER FR(1)=FR(1)-1.D0 FR(2)=FR(2)+1.D0 RETURN END C++++++++++++++++++++++++++++++++ C SUBROUTINE STATE(ET2,LIST,PV,PNUT) C C++++++++++++++++++++++++++++++++ C C THIS SUBROUTINE READS AND INTERPOLATES THE JPL PLANETARY EPHEMERIS FILE C C CALLING SEQUENCE PARAMETERS: C C INPUT: C C ET2 DP 2-WORD JULIAN EPHEMERIS EPOCH AT WHICH INTERPOLATION C IS WANTED. ANY COMBINATION OF ET2(1)+ET2(2) WHICH FALLS C WITHIN THE TIME SPAN ON THE FILE IS A PERMISSIBLE EPOCH. C C A. FOR EASE IN PROGRAMMING, THE USER MAY PUT THE C ENTIRE EPOCH IN ET2(1) AND SET ET2(2)=0. C C B. FOR MAXIMUM INTERPOLATION ACCURACY, SET ET2(1) = C THE MOST RECENT MIDNIGHT AT OR BEFORE INTERPOLATION C EPOCH AND SET ET2(2) = FRACTIONAL PART OF A DAY C ELAPSED BETWEEN ET2(1) AND EPOCH. C C C. AS AN ALTERNATIVE, IT MAY PROVE CONVENIENT TO SET C ET2(1) = SOME FIXED EPOCH, SUCH AS START OF INTEGRATION, C AND ET2(2) = ELAPSED INTERVAL BETWEEN THEN AND EPOCH. C C LIST 12-WORD INTEGER ARRAY SPECIFYING WHAT INTERPOLATION C IS WANTED FOR EACH OF THE BODIES ON THE FILE. C C LIST(I)=0, NO INTERPOLATION FOR BODY I C =1, POSITION ONLY C =2, POSITION AND VELOCITY C C THE DESIGNATION OF THE ASTRONOMICAL BODIES BY I IS: C C I = 1: MERCURY C = 2: VENUS C = 3: EARTH-MOON BARYCENTER C = 4: MARS C = 5: JUPITER C = 6: SATURN C = 7: URANUS C = 8: NEPTUNE C = 9: PLUTO C =10: GEOCENTRIC MOON C =11: NUTATIONS IN LONGITUDE AND OBLIQUITY C =12: LUNAR LIBRATIONS (IF ON FILE) C C OUTPUT: C C PV DP 6 X 11 ARRAY THAT WILL CONTAIN REQUESTED INTERPOLATED C QUANTITIES (OTHER THAN NUTATION, STOERD IN PNUT). C THE BODY SPECIFIED BY LIST(I) WILL HAVE ITS C STATE IN THE ARRAY STARTING AT PV(1,I). C (ON ANY GIVEN CALL, ONLY THOSE WORDS IN 'PV' WHICH ARE C AFFECTED BY THE FIRST 10 'LIST' ENTRIES, AND BY LIST(12) C IF LIBRATIONS ARE ON THE FILE, ARE SET. C THE REST OF THE 'PV' ARRAYIS UNTOUCHED.) C THE ORDER OF COMPONENTS STARTING IN PV(1,I) IS: X,Y,Z,DX,DY,DZ. C C ALL OUTPUT VECTORS ARE REFERENCED TO THE EARTH MEAN C EQUATOR AND EQUINOX OF J2000 IF THE DE NUMBER IS 200 OR C GREATER; OF B1950 IF THE DE NUMBER IS LESS THAN 200. C C THE MOON STATE IS ALWAYS GEOCENTRIC; THE OTHER NINE STATES C ARE EITHER HELIOCENTRIC OR SOLAR-SYSTEM BARYCENTRIC, C DEPENDING ON THE SETTING OF COMMON FLAGS (SEE BELOW). C C LUNAR LIBRATIONS, IF ON FILE, ARE PUT INTO PV(K,11) IF C LIST(12) IS 1 OR 2. C C NUT DP 4-WORD ARRAY THAT WILL CONTAIN NUTATIONS AND RATES, C DEPENDING ON THE SETTING OF LIST(11). THE ORDER OF C QUANTITIES IN NUT IS: C C D PSI (NUTATION IN LONGITUDE) C D EPSILON (NUTATION IN OBLIQUITY) C D PSI DOT C D EPSILON DOT C C * STATEMENT # FOR ERROR RETURN, IN CASE OF EPOCH OUT OF C RANGE OR I/O ERRORS. C C COMMON AREA STCOMX: C C KM LOGICAL FLAG DEFINING PHYSICAL UNITS OF THE OUTPUT C STATES. KM = .TRUE., KM AND KM/SEC C = .FALSE., AU AND AU/DAY C DEFAULT VALUE = .FALSE. (KM DETERMINES TIME UNIT C FOR NUTATIONS AND LIBRATIONS. ANGLE UNIT IS ALWAYS RADIANS.) C C BARY LOGICAL FLAG DEFINING OUTPUT CENTER. C ONLY THE 9 PLANETS ARE AFFECTED. C BARY = .TRUE. =\ CENTER IS SOLAR-SYSTEM BARYCENTER C = .FALSE. =\ CENTER IS SUN C DEFAULT VALUE = .FALSE. C C PVSUN DP 6-WORD ARRAY CONTAINING THE BARYCENTRIC POSITION AND C VELOCITY OF THE SUN. C C IMPLICIT DOUBLE PRECISION (A-H,O-Z) SAVE INTEGER OLDMAX PARAMETER ( OLDMAX = 400) INTEGER NMAX PARAMETER ( NMAX = 1000) DIMENSION ET2(2),PV(6,11),PNUT(4),T(2),PJD(4),BUF(1500), . SS(3),CVAL(NMAX),PVSUN(6) INTEGER LIST(12),IPT(3,13) LOGICAL FIRST DATA FIRST/.TRUE./ CHARACTER*6 TTL(14,3),CNAM(NMAX) CHARACTER*80 NAMFIL LOGICAL KM,BARY COMMON/EPHHDR/CVAL,SS,AU,EMRAT,NUMDE,NCON,IPT COMMON/CHRHDR/CNAM,TTL COMMON/STCOMX/KM,BARY,PVSUN C C ENTRY POINT - 1ST TIME IN, GET POINTER DATA, ETC., FROM EPH FILE C IF(FIRST) THEN FIRST=.FALSE. C ************************************************************************ C ************************************************************************ C THE USER MUST SELECT ONE OF THE FOLLOWING BY DELETING THE 'C' IN COLUMN 1 C ************************************************************************ C CALL FSIZER1(NRECL,KSIZE,NRFILE,NAMFIL) C CALL FSIZER2(NRECL,KSIZE,NRFILE,NAMFIL) C CALL FSIZER3(NRECL,KSIZE,NRFILE,NAMFIL) CALL FSIZER3(NRECL,KSIZE,NRFILE,NAMFIL) 11.02.15 IF(NRECL .EQ. 0) WRITE(*,*)' ***** FSIZER IS NOT WORKING *****' C ************************************************************************ C ************************************************************************ IRECSZ=NRECL*KSIZE NCOEFFS=KSIZE/2 OPEN(NRFILE, * FILE=NAMFIL, * ACCESS='DIRECT', * FORM='UNFORMATTED', * RECL=IRECSZ, * STATUS='OLD') READ(NRFILE,REC=1)TTL,(CNAM(K),K=1,OLDMAX),SS,NCON,AU,EMRAT, & ((IPT(I,J),I=1,3),J=1,12),NUMDE,(IPT(I,13),I=1,3) & ,(CNAM(L),L=OLDMAX+1,NCON) IF(NCON .LE. OLDMAX)THEN READ(NRFILE,REC=2)(CVAL(I),I=1,OLDMAX) ELSE READ(NRFILE,REC=2)(CVAL(I),I=1,NCON) ENDIF NRL=0 ENDIF C ********** MAIN ENTRY POINT ********** IF(ET2(1) .EQ. 0.D0) RETURN S=ET2(1)-.5D0 CALL SPLIT(S,PJD(1)) CALL SPLIT(ET2(2),PJD(3)) PJD(1)=PJD(1)+PJD(3)+.5D0 PJD(2)=PJD(2)+PJD(4) CALL SPLIT(PJD(2),PJD(3)) PJD(1)=PJD(1)+PJD(3) C ERROR RETURN FOR EPOCH OUT OF RANGE IF(PJD(1)+PJD(4).LT.SS(1) .OR. PJD(1)+PJD(4).GT.SS(2)) GO TO 98 C CALCULATE RECORD # AND RELATIVE TIME IN INTERVAL NR=IDINT((PJD(1)-SS(1))/SS(3))+3 IF(PJD(1).EQ.SS(2)) NR=NR-1 tmp1 = DBLE(NR-3)*SS(3) + SS(1) tmp2 = PJD(1) - tmp1 T(1) = (tmp2 + PJD(4))/SS(3) C READ CORRECT RECORD IF NOT IN CORE IF(NR.NE.NRL) THEN NRL=NR READ(NRFILE,REC=NR,ERR=99)(BUF(K),K=1,NCOEFFS) ENDIF IF(KM) THEN T(2)=SS(3)*86400.D0 AUFAC=1.D0 ELSE T(2)=SS(3) AUFAC=1.D0/AU ENDIF C INTERPOLATE SSBARY SUN CALL INTERP(BUF(IPT(1,11)),T,IPT(2,11),3,IPT(3,11),2,PVSUN) DO I=1,6 PVSUN(I)=PVSUN(I)*AUFAC ENDDO C CHECK AND INTERPOLATE WHICHEVER BODIES ARE REQUESTED DO 4 I=1,10 IF(LIST(I).EQ.0) GO TO 4 CALL INTERP(BUF(IPT(1,I)),T,IPT(2,I),3,IPT(3,I), & LIST(I),PV(1,I)) DO J=1,6 IF(I.LE.9 .AND. .NOT.BARY) THEN PV(J,I)=PV(J,I)*AUFAC-PVSUN(J) ELSE PV(J,I)=PV(J,I)*AUFAC ENDIF ENDDO 4 CONTINUE C DO NUTATIONS IF REQUESTED (AND IF ON FILE) IF(LIST(11).GT.0 .AND. IPT(2,12).GT.0) * CALL INTERP(BUF(IPT(1,12)),T,IPT(2,12),2,IPT(3,12), * LIST(11),PNUT) C GET LIBRATIONS IF REQUESTED (AND IF ON FILE) IF(LIST(12).GT.0 .AND. IPT(2,13).GT.0) * CALL INTERP(BUF(IPT(1,13)),T,IPT(2,13),3,IPT(3,13), * LIST(12),PV(1,11)) RETURN 98 WRITE(*,198)ET2(1)+ET2(2),SS(1),SS(2) 198 FORMAT(' *** Requested JED,',f12.2, * ' not within ephemeris limits,',2f12.2,' ***') STOP 99 WRITE(*,'(2F12.2,A80)')ET2,'ERROR RETURN IN STATE' STOP END C+++++++++++++++++++++++++++++ C SUBROUTINE CONST(NAM,VAL,SSS,N) C C+++++++++++++++++++++++++++++ C C THIS ENTRY OBTAINS THE CONSTANTS FROM THE EPHEMERIS FILE C C CALLING SEQEUNCE PARAMETERS (ALL OUTPUT): C C NAM = CHARACTER*6 ARRAY OF CONSTANT NAMES C C VAL = D.P. ARRAY OF VALUES OF CONSTANTS C C SSS = D.P. JD START, JD STOP, STEP OF EPHEMERIS C C N = INTEGER NUMBER OF ENTRIES IN 'NAM' AND 'VAL' ARRAYS C IMPLICIT DOUBLE PRECISION (A-H,O-Z) SAVE INTEGER NMAX PARAMETER (NMAX = 1000) CHARACTER*6 NAM(*),TTL(14,3),CNAM(NMAX) DOUBLE PRECISION VAL(*),SSS(3),SS(3),CVAL(NMAX),ZIPS(2) DOUBLE PRECISION PVST(6,11),PNUT(4) DATA ZIPS/2*0.d0/ INTEGER IPT(3,13),DENUM,LIST(12) logical first data first/.true./ COMMON/EPHHDR/CVAL,SS,AU,EMRAT,DENUM,NCON,IPT COMMON/CHRHDR/CNAM,TTL C CALL STATE TO INITIALIZE THE EPHEMERIS AND READ IN THE CONSTANTS IF(FIRST) CALL STATE(ZIPS,LIST,PVST,PNUT) first=.false. N=NCON DO I=1,3 SSS(I)=SS(I) ENDDO DO I=1,N NAM(I)=CNAM(I) VAL(I)=CVAL(I) ENDDO RETURN END