FORTRAN Generation
(/./ftp/cats/J/AZh/80/458)

Conversion of standardized ReadMe file for file /./ftp/cats/J/AZh/80/458 into FORTRAN code for loading all data files into arrays.

Note that special values are assigned to unknown or unspecified numbers (also called NULL numbers); when necessary, the coordinate components making up the right ascension and declination are converted into floating-point numbers representing these angles in degrees.



      program load_ReadMe
C=============================================================================
C  F77-compliant program generated by readme2f_1.81 (2015-09-23), on 2024-Mar-28
C=============================================================================
*  This code was generated from the ReadMe file documenting a catalogue
*  according to the "Standard for Documentation of Astronomical Catalogues"
*  currently in use by the Astronomical Data Centers (CDS, ADC, A&A)
*  (see full documentation at URL http://vizier.u-strasbg.fr/doc/catstd.htx)
*  Please report problems or questions to   
C=============================================================================

      implicit none
*  Unspecified or NULL values, generally corresponding to blank columns,
*  are assigned one of the following special values:
*     rNULL__    for unknown or NULL floating-point values
*     iNULL__    for unknown or NULL   integer      values
      real*4     rNULL__
      integer*4  iNULL__
      parameter  (rNULL__=--2147483648.)  	! NULL real number
      parameter  (iNULL__=(-2147483647-1))	! NULL int  number
      integer    idig			! testing NULL number

C=============================================================================
Cat. J/AZh/80/458        Sodium abundances in stellar atmospheres  (Mishenina+, 2003)
*================================================================================
*Sodium abundances in in stellar atmospheres  with differing metallicities.
*    Mishenina T.V., Kovtyukh V.V., Korotin S.A., Soubiran C.
*   <Astron. Zh. 80, 458 (2003)>
*   =2003AZh....80..458M
*   =2003ARep...47..422M
C=============================================================================

C  Internal variables

      integer*4 i__

c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 

C  Declarations for 'objects.dat'	! Object positions, from Simbad

      integer*4 nr__
      parameter (nr__=100)	! Number of records
      character*53 ar__   	! Full-size record

C  2000 position composed of: RAh RAm RAs DE- DEd DEm DEs
      real*8        RAdeg      (nr__) ! (deg) Right Ascension 2000
      real*8        DEdeg      (nr__) ! (deg)     Declination 2000
C  ---------------------------------- ! (position vector(s) in degrees)

      integer*4     RAh        (nr__) ! (h) Right Ascension (2000) (hours)
      integer*4     RAm        (nr__) ! (min) Right Ascension (2000) (minutes)
      real*8        RAs        (nr__) ! (s) Right Ascension (2000) (seconds)
      character*1   DE_        (nr__) ! Declination (2000) (sign)
      integer*4     DEd        (nr__) ! (deg) Declination (2000) (degrees)
      integer*4     DEm        (nr__) ! (arcmin) Declination (2000) (minutes)
      real*4        DEs        (nr__) ! (arcsec) Declination (2000) (seconds)
      character*10  Name       (nr__) ! Star name

c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 

C  Declarations for 'table1.dat'	! Main atmospheric parameters, NaI equivalent widths,
                            and relative abundances of [O/Fe] and [Na/Fe]

      integer*4 nr__1
      parameter (nr__1=100)	! Number of records
      character*90 ar__1  	! Full-size record

      character*10  Name_1     (nr__1) ! Star name
      character*1   n_Name     (nr__1) ! [* ] *: atmospheric parameters of star are
*                                           determined in the paper
      real*4        Vmag       (nr__1) ! (mag) V magnitude
      real*4        B_V        (nr__1) ! (mag) ? B-V color index
      real*4        Mbol       (nr__1) ! (mag) Bolometric magnitude
      integer*4     Teff       (nr__1) ! (K) Effective temperature
      real*4        logg       (nr__1) ! ([cm/s2]) Gravity
      real*4        Vt         (nr__1) ! (km/s) Microturbulence velocity
      real*4        v_Fe_H_    (nr__1) ! ([Sun]) Metallicity
      real*4        v_O_Fe_    (nr__1) ! ([Sun]) ? Oxygen abundance
      real*4        v_Na_Fe_   (nr__1) ! ([Sun]) Sodium abundance
      real*4        NaI5682    (nr__1) ! (0.1nm) ? Equivalent width of NaI 5682 (Angstroems)
      real*4        NaI6154    (nr__1) ! (0.1nm) ? Equivalent width of NaI 6154 (Angstroems)
      real*4        NaI6160    (nr__1) ! (0.1nm) ? Equivalent width of NaI 6160 (Angstroems)

C=============================================================================

C  Loading file 'objects.dat'	! Object positions, from Simbad

C  Format for file interpretation

    1 format(I2,1X,I2,1X,F7.4,1X,A1,I2,1X,I2,1X,F6.3,3X,A10)

C  Effective file loading

      open(unit=1,status='old',file=
     +'objects.dat')
      write(6,*) '....Loading file: objects.dat'
      do i__=1,100
        read(1,'(A53)')ar__
        read(ar__,1)
     +  RAh(i__),RAm(i__),RAs(i__),DE_(i__),DEd(i__),DEm(i__),
     +  DEs(i__),Name(i__)
        RAdeg(i__) = rNULL__
        DEdeg(i__) = rNULL__
c  Derive coordinates RAdeg and DEdeg from input data
c  (RAdeg and DEdeg are set to rNULL__ when unknown)
        if(RAh(i__) .GT. -180) RAdeg(i__)=RAh(i__)*15.
        if(RAm(i__) .GT. -180) RAdeg(i__)=RAdeg(i__)+RAm(i__)/4.
        if(RAs(i__) .GT. -180) RAdeg(i__)=RAdeg(i__)+RAs(i__)/240.
        if(DEd(i__) .GE. 0) DEdeg(i__)=DEd(i__)
        if(DEm(i__) .GE. 0) DEdeg(i__)=DEdeg(i__)+DEm(i__)/60.
        if(DEs(i__) .GE. 0) DEdeg(i__)=DEdeg(i__)+DEs(i__)/3600.
        if(DE_(i__).EQ.'-'.AND.DEdeg(i__).GE.0) DEdeg(i__)=-DEdeg(i__)
c    ..............Just test output...........
        write(6,1)
     +  RAh(i__),RAm(i__),RAs(i__),DE_(i__),DEd(i__),DEm(i__),
     +  DEs(i__),Name(i__)
        write(6,'(6H Pos: 2F8.4)') RAdeg(i__),DEdeg(i__)
c    .......End.of.Just test output...........
      end do
      close(1)

C=============================================================================

C  Loading file 'table1.dat'	! Main atmospheric parameters, NaI equivalent widths,
*                            and relative abundances of [O/Fe] and [Na/Fe]

C  Format for file interpretation

    2 format(
     +  A10,A1,F5.2,2X,F4.2,2X,F5.2,3X,I4,3X,F3.1,3X,F4.2,3X,F5.2,2X,
     +  F5.2,2X,F5.2,2X,F5.1,2X,F4.1,1X,F5.1)

C  Effective file loading

      open(unit=1,status='old',file=
     +'table1.dat')
      write(6,*) '....Loading file: table1.dat'
      do i__=1,100
        read(1,'(A90)')ar__1
        read(ar__1,2)
     +  Name_1(i__),n_Name(i__),Vmag(i__),B_V(i__),Mbol(i__),
     +  Teff(i__),logg(i__),Vt(i__),v_Fe_H_(i__),v_O_Fe_(i__),
     +  v_Na_Fe_(i__),NaI5682(i__),NaI6154(i__),NaI6160(i__)
        if(ar__1(19:22) .EQ. '') B_V(i__) = rNULL__
        if(ar__1(60:64) .EQ. '') v_O_Fe_(i__) = rNULL__
        if(ar__1(74:78) .EQ. '') NaI5682(i__) = rNULL__
        if(ar__1(81:84) .EQ. '') NaI6154(i__) = rNULL__
        if(ar__1(86:90) .EQ. '') NaI6160(i__) = rNULL__
c    ..............Just test output...........
        write(6,2)
     +  Name_1(i__),n_Name(i__),Vmag(i__),B_V(i__),Mbol(i__),
     +  Teff(i__),logg(i__),Vt(i__),v_Fe_H_(i__),v_O_Fe_(i__),
     +  v_Na_Fe_(i__),NaI5682(i__),NaI6154(i__),NaI6160(i__)
c    .......End.of.Just test output...........
      end do
      close(1)

C=============================================================================
      stop
      end