Conversion of standardized ReadMe file for
file /./ftp/cats/J/A_A/707/A13 into FORTRAN code for reading data files line by line.
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 2026-May-17
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/A+A/707/A13 Tracing ionized gas kinematics in LBAs (Leon Contreras+, 2026)
*================================================================================
*Tracing ionized gas kinematics in Lyman-Break Analogs.
*Implications for star formation compactness and outflow properties.
* Leon Contreras A., Amorin R., Llerena M., Fernandez V.
* <Astron. Astrophys. 707, A13 (2026)>
* =2026A&A...707A..13L (SIMBAD/NED BibCode)
C=============================================================================
C Internal variables
integer*4 i__
c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C Declarations for 'table1.dat' ! Information on the selected sample
integer*4 nr__
parameter (nr__=14) ! Number of records
character*67 ar__ ! Full-size record
C J2000 position composed of: RAh RAm RAs DE- DEd DEm DEs
real*8 RAdeg ! (deg) Right Ascension J2000
real*8 DEdeg ! (deg) Declination J2000
C ---------------------------------- ! (position vector(s) in degrees)
character*10 ID ! Galaxy identifier
integer*4 RAh ! (h) Right ascension (J2000)
integer*4 RAm ! (min) Right ascension (J2000)
real*4 RAs ! (s) Right ascension (J2000)
character*1 DE_ ! Declination sign (J2000)
integer*4 DEd ! (deg) Declination (J2000)
integer*4 DEm ! (arcmin) Declination (J2000)
real*4 DEs ! (arcsec) Declination (J2000)
real*4 z ! Redshift (1)
character*24 Name ! Galaxy name
*Note (1): The redshift was obtained from the SDSS spectra by Heckman et al.
* (2015ApJ...809..147H).
c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
C Declarations for 'table2.dat' ! Kinematic parameters
integer*4 nr__1
parameter (nr__1=254) ! Number of records
character*66 ar__1 ! Full-size record
character*10 ID_1 ! Galaxy identifier
integer*4 lambda0 ! (0.1nm) Rest-frame wavelength
* (nominal laboratory value)
character*6 Ion ! Ion species
character*2 Comp ! Component flag (1)
real*4 sigmaint ! (km/s) Intrinsic velocity dispersion
real*4 e_sigmaint ! (km/s) Uncertainty in sigma_int
real*4 RV ! (km/s) Radial velocity relative to
* systemic velocity (2)
real*4 e_RV ! (km/s) Uncertainty in RV
real*4 Flux ! (10-20W/m2) Flux of the component
* (in 10^-17^erg/s/cm^2^ unit)
real*4 e_Flux ! (10-20W/m2) Uncertainty in flux
* (in 10^-17^erg/s/cm^2^ unit)
real*4 EM ! (%) Emission-measure fraction (3)
*Note (1): Component flag:
* B, B1, B2 : Broad components
* N, N1-N4 : Narrow components
*Note (2): sigmaint and RV are corrected for instrumental and thermal broadening.
*Note (3): EM is the fractional contribution of each Gaussian component.
C=============================================================================
C Loading file 'table1.dat' ! Information on the selected sample
C Format for file interpretation
1 format(
+ A10,1X,I2,1X,I2,1X,F5.2,1X,A1,I2,1X,I2,1X,F5.2,1X,F6.4,1X,A24)
C Effective file loading
open(unit=1,status='old',file=
+'table1.dat')
write(6,*) '....Loading file: table1.dat'
do i__=1,14
read(1,'(A67)')ar__
read(ar__,1)ID,RAh,RAm,RAs,DE_,DEd,DEm,DEs,z,Name
RAdeg = rNULL__
DEdeg = rNULL__
c Derive coordinates RAdeg and DEdeg from input data
c (RAdeg and DEdeg are set to rNULL__ when unknown)
if(RAh .GT. -180) RAdeg=RAh*15.
if(RAm .GT. -180) RAdeg=RAdeg+RAm/4.
if(RAs .GT. -180) RAdeg=RAdeg+RAs/240.
if(DEd .GE. 0) DEdeg=DEd
if(DEm .GE. 0) DEdeg=DEdeg+DEm/60.
if(DEs .GE. 0) DEdeg=DEdeg+DEs/3600.
if(DE_.EQ.'-'.AND.DEdeg.GE.0) DEdeg=-DEdeg
c ..............Just test output...........
write(6,1)ID,RAh,RAm,RAs,DE_,DEd,DEm,DEs,z,Name
write(6,'(6H Pos: 2F8.4)') RAdeg,DEdeg
c .......End.of.Just test output...........
end do
close(1)
C=============================================================================
C Loading file 'table2.dat' ! Kinematic parameters
C Format for file interpretation
2 format(
+ A10,1X,I4,1X,A6,1X,A2,1X,F5.1,1X,F4.1,1X,F6.1,1X,F4.1,1X,F6.1,
+ 1X,F4.1,1X,F5.1)
C Effective file loading
open(unit=1,status='old',file=
+'table2.dat')
write(6,*) '....Loading file: table2.dat'
do i__=1,254
read(1,'(A66)')ar__1
read(ar__1,2)
+ ID_1,lambda0,Ion,Comp,sigmaint,e_sigmaint,RV,e_RV,Flux,e_Flux,
+ EM
c ..............Just test output...........
write(6,2)
+ ID_1,lambda0,Ion,Comp,sigmaint,e_sigmaint,RV,e_RV,Flux,e_Flux,
+ EM
c .......End.of.Just test output...........
end do
close(1)
C=============================================================================
stop
end