Conversion of standardized ReadMe file for
file /./ftp/cats/J/AJ/151/74 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-Apr-19 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/AJ/151/74 VLA/VLBA obscured radio-loud active galactic nuclei (Yan+, 2016) *================================================================================ *Invisible active galactic nuclei. *II. Radio morphologies and five new H I 21cm absorption line detectors. * Yan T., Stocke J.T., Darling J., Momjian E., Sharma S., Kanekar N. * <Astron. J., 151, 74 (2016)> * =2016AJ....151...74Y (SIMBAD/NED BibCode) C============================================================================= C Internal variables integer*4 i__ c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C Declarations for 'table1.dat' ! Observing Summary integer*4 nr__ parameter (nr__=81) ! Number of records character*75 ar__ ! Full-size record character*10 Name (nr__) ! Object name (JHHMM+DDMM) character*12 Radio (nr__) ! Radio name character*11 Date4_9 (nr__) ! ("date") Date of observation at 4.9 GHz integer*4 r_Date4_9 (nr__) ! [1/15]? Reference for Date4.9 (1) character*11 Date8_5 (nr__) ! ("date") Date of observation at 8.5 GHz integer*4 r_Date8_5 (nr__) ! [1/17]? Reference for Date8.5 (1) character*11 DateVLBI (nr__) ! ("date") Date of VLBI observation integer*4 r_DateVLBI (nr__) ! [1/19]? Reference for DateVLBI (1) character*6 Note (nr__) ! Note(s) (2) *Note (1): Reference as follows: * 1 = This work (VLA project AY0052 and VLBA project BY 0020); * 2 = VLA project AA052; * 3 = VLA project AA073; * 4 = VLA project AB375; * 5 = VLA project AB568; * 6 = VLA project AB611; * 7 = VLA project AB922; * 8 = VLA project AH167; * 9 = VLA project AS704; * 10 = Cai et al. (2002A&A...381..401C); * 11 = Chambers et al. (1996ApJS..106..247C); * 12 = Dallacasa et al. (2002A&A...389..126D); * 13 = Fanti et al. (2001, J/A+A/369/380); * 14 = Helmboldt et al. (2007, J/ApJ/658/203); * 15 = Lehar et al. (1997AJ....114...48L); * 16 = Myers et al. (2003, Cat. VIII/72); * 17 = Patnaik et al. (1992, Cat. VIII/60); * 18 = Peck & Taylor (2000ApJ...534...90P); * 19 = Perlman et al. (2002AJ....124.2401P). *Note (2): Note as follows: * N1 = No flux calibration on the VLA-A 4.9 GHz image; * N2 = No flux calibration on the VLA-A 8.5 GHz image; * N3 = Not detected on the VLA-A 4.9 GHz image; * N4 = Not detected on the VLBA 1.4 GHz image; * N5 = All data are flagged on the VLA-A 4.9 GHz image. c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C Declarations for 'table2.dat' ! Summary of Radio Galaxy Properties integer*4 nr__1 parameter (nr__1=80) ! Number of records character*97 ar__1 ! Full-size record character*10 Name_1 (nr__1) ! Object name (JHHMM+DDMM) real*4 z (nr__1) ! [0.122/3.200]? Redshift character*1 n_z (nr__1) ! [*abc] Note on z (1) character*1 u_z (nr__1) ! [:] Uncertainty flag on z character*5 SEDType (nr__1) ! Optical+NIR SED type from Yan et al. * (2012AJ....144..124Y) (2) character*2 GType (nr__1) ! Hubble type for pure "G"-type objects in column * "SEDType" (3) real*4 S365MHz (nr__1) ! (Jy) [0.25/8.31] Flux density at 365 MHz real*4 S1_4GHz (nr__1) ! (Jy) [0.32/4.86] Flux density at 1.4 GHz real*4 S4_9CHz (nr__1) ! (Jy) [0.07/3.09] Flux density at 4.9 GHz real*4 alphal (nr__1) ! [0.02/1.28] Low-frequency spectral index, * {alpha}_l_, between 365 MHz and 1.4 GHz real*4 alphah (nr__1) ! [-1.41/0.37] High-frequency spectral index, * {alpha}_h_, between 1.4 and 4.9 GHz character*3 Class (nr__1) ! Radio spectral classification (4) character*1 n_Class (nr__1) ! [a] Note on Class (5) character*1 u_Class (nr__1) ! [:] Uncertainty flag on Class real*4 LAS (nr__1) ! (arcsec) [0.002/6.6] Largest angular size between major * components character*1 u_LAS (nr__1) ! [:] Uncertainty flag on LAS real*4 LLS (nr__1) ! (kpc) [0.014/45.7] Largest linear size character*1 n_LLS (nr__1) ! [<~] Note on LLS (6) real*4 Freq (nr__1) ! (GHz) [1.4/8.5] Frequency with which the LAS and LLS * are measured character*5 Tel (nr__1) ! Telescope with which the LAS and LLS are * measured character*6 Morph (nr__1) ! Radio source morphological classification (7) character*1 Eval1 (nr__1) ! [YN] Whether the object remains a good * candidate for an absorption-line search at * radio frequencies (Y=Yes, N=No) character*2 Eval2 (nr__1) ! Whether the object is an intervening system (I) * or candidate (I:) *Note (1): Note as follows: * * = Photometric redshift fit by its optical+NIR SED in Yan et al. * (2012AJ....144..124Y); * a = The redshift listed is for a background radio source that has an SDSS * detected Galaxy in the foreground; * b = The redshift listed is for a background radio source that is * gravitationally lensed by a foreground Galaxy at z=0.349; * c = This is an intervening system with a foreground Galaxy at z=0.206. The * radio source redshift is unknown. *Note (2): The optical+NIR SEDs were divided into four classes in Yan et al. * (2012AJ....144..124Y): * G = Pure galaxy; * G+Q = Galaxy with a quasar signature in the bluer bands; * Q = Quasar; * Q+abs = Quasar with extinction signatures in the bluer bands. *Note (3): We fit the G-type objects with template spectra of five Hubble types * (E, S0, Sa, Sb, and Sc), and give the best-fit Hubble types. *Note (4): Classification as follows: * SS = Steep Spectrum; * FS = Flat Spectrum; * USS = Ultra-Steep Spectrum; * GPS = Giga-Hertz Peak Spectrum. *Note (5): Note as follows: * a = The classification has been modified using additional information to the * spectral indices in columns "alphal" and "alphah". *Note (6): Note as follows: * ~ = A photometric redshift is used; * < = z=1.6 is used to obtain the largest size possible. *Note (7): Morphological classification as follows: * CPLX = Complex; * CJ = Core-jet; * GA = Gravitational arc; * PS = Point source; * SL = Single lobe; * CSO = Compact symmetric object; * CSO: = CSO candidate; * LSO = Large symmetric object; * MSO = Medium-size symmetric object. c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C Declarations for 'table10.dat' ! Basic Observing Results integer*4 nr__2 parameter (nr__2=80) ! Number of records character*98 ar__2 ! Full-size record character*10 Name_2 (nr__2) ! Object name (JHHMM+DDMM) real*4 MajAxis4_9 (nr__2) ! (arcsec) [0.42/0.97]? Major axis size at 4.9 GHz real*4 MinAxis4_9 (nr__2) ! (arcsec) [0.40/0.49]? Minor axis size at 4.9 GHz real*4 PA4_9 (nr__2) ! (deg) [-89.4/87.8]? Position angle of the * restored beam at 4.9 GHz real*4 rms4_9 (nr__2) ! (mJy/beam) [0.12/0.77]? Map rms ({sigma}) in * the vicinity of the source at 4.9 GHz character*1 n_rms4_9 (nr__2) ! [*] Note on rms4.9 (G1) real*4 Smax4_9 (nr__2) ! (mJy/beam) [21.6/578.7]? Maximum flux density in * the map at 4.9 GHz character*1 n_Smax4_9 (nr__2) ! [*] Note on Smax4.9 (G1) real*4 MajAxis8_5 (nr__2) ! (arcsec) [0.24/0.74]? Major axis size at 8.5 GHz real*4 MinAxis8_5 (nr__2) ! (arcsec) [0.23/0.42]? Minor axis size at 8.5 GHz real*4 PA8_5 (nr__2) ! (deg) [-175.8/174.3]? Position angle of the * restored beam at 8.5 GHz real*4 rms8_5 (nr__2) ! (mJy/beam) [0.06/0.71]? Map rms ({sigma}) in the * vicinity of the source at 8.5 GHz character*1 n_rms8_5 (nr__2) ! [*] Note on rms8.5 (G1) real*4 Smax8_5 (nr__2) ! (mJy/beam) [10.0/605.1]? Maximum flux density in * the map at 8.5 GHz character*1 n_Smax8_5 (nr__2) ! [*] Note on Smax8.5 (G1) real*4 MajAxis1_4 (nr__2) ! (arcsec) [8.12/61.82]? Major axis size at 1.4 GHz real*4 MinAxis1_4 (nr__2) ! (arcsec) [4.86/55.91]? Minor axis size at 1.4 GHz real*4 PA1_4 (nr__2) ! (deg) [-33.9/78.2]? Position angle of the * restored beam at 1.4 GHz real*4 rms1_4 (nr__2) ! (mJy/beam) [0.11/3.50]? Map rms ({sigma}) in the * vicinity of the source at 1.4 GHz real*4 Smax1_4 (nr__2) ! (mJy/beam) [7.5/401.1]? Maximum flux density in * the map at 1.4 GHz c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C Declarations for 'table11.dat' ! VLA 4.9 GHz Gaussian Fit Results integer*4 nr__3 parameter (nr__3=123) ! Number of records character*79 ar__3 ! Full-size record C J2000 position composed of: RAh RAm RAs DE- DEd DEm DEs real*8 RAdeg (nr__3) ! (deg) Right Ascension J2000 real*8 DEdeg (nr__3) ! (deg) Declination J2000 C ---------------------------------- ! (position vector(s) in degrees) character*10 Name_3 (nr__3) ! Object name (JHHMM+DDMM) character*2 m_Name (nr__3) ! Multiplicity index on Name integer*4 RAh (nr__3) ! (h) ? Hour of Right Ascension (J2000) (1) integer*4 RAm (nr__3) ! (min) ? Minute of Right Ascension (J2000) real*8 RAs (nr__3) ! (s) ? Second of Right Ascension (J2000) character*1 DE_ (nr__3) ! ? Sign of the Declination (J2000) integer*4 DEd (nr__3) ! (deg) ? Degree of Declination (J2000) integer*4 DEm (nr__3) ! (arcmin) ? Arcminute of Declination (J2000) real*4 DEs (nr__3) ! (arcsec) ? Arcsecond of Declination (J2000) real*4 Speak (nr__3) ! (mJy/beam) [0.4/650.6] Peak flux density character*1 n_Speak (nr__3) ! [*] Note on Speak (not in table 13) (G1) real*4 Sint (nr__3) ! (mJy) [1.8/929.4] Integrated flux density character*1 n_Sint (nr__3) ! [*] Note on Sint (not in table 13) (G1) real*4 MajAxis (nr__3) ! (arcsec) [0.03/109] Deconvolved major axis real*4 MinAxis (nr__3) ! (arcsec) [0.00/63] Deconvolved minor axis real*4 PA (nr__3) ! (deg) [0.1/179.2] Position angle of the Gaussian * component real*4 alpha (nr__3) ! [-3.6/3.1]? Spectral index ({alpha}) * calculated between 4.9 and 8.5 GHz * (only in table 12) *Note (1): No position in Table 12. c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C Declarations for 'table12.dat' ! VLA 8.5 GHz Gaussian Fit Results integer*4 nr__4 parameter (nr__4=102) ! Number of records character*79 ar__4 ! Full-size record C J2000 position composed of: RAh RAm RAs DE- DEd DEm DEs real*8 RAdeg_1 (nr__4) ! (deg) Right Ascension J2000 real*8 DEdeg_1 (nr__4) ! (deg) Declination J2000 C ---------------------------------- ! (position vector(s) in degrees) character*10 Name_4 (nr__4) ! Object name (JHHMM+DDMM) character*2 m_Name_1 (nr__4) ! Multiplicity index on Name integer*4 RAh_1 (nr__4) ! (h) ? Hour of Right Ascension (J2000) (1) integer*4 RAm_1 (nr__4) ! (min) ? Minute of Right Ascension (J2000) real*8 RAs_1 (nr__4) ! (s) ? Second of Right Ascension (J2000) character*1 DE__1 (nr__4) ! ? Sign of the Declination (J2000) integer*4 DEd_1 (nr__4) ! (deg) ? Degree of Declination (J2000) integer*4 DEm_1 (nr__4) ! (arcmin) ? Arcminute of Declination (J2000) real*4 DEs_1 (nr__4) ! (arcsec) ? Arcsecond of Declination (J2000) real*4 Speak_1 (nr__4) ! (mJy/beam) [0.4/650.6] Peak flux density character*1 n_Speak_1 (nr__4) ! [*] Note on Speak (not in table 13) (G1) real*4 Sint_1 (nr__4) ! (mJy) [1.8/929.4] Integrated flux density character*1 n_Sint_1 (nr__4) ! [*] Note on Sint (not in table 13) (G1) real*4 MajAxis_1 (nr__4) ! (arcsec) [0.03/109] Deconvolved major axis real*4 MinAxis_1 (nr__4) ! (arcsec) [0.00/63] Deconvolved minor axis real*4 PA_1 (nr__4) ! (deg) [0.1/179.2] Position angle of the Gaussian * component real*4 alpha_1 (nr__4) ! [-3.6/3.1]? Spectral index ({alpha}) * calculated between 4.9 and 8.5 GHz * (only in table 12) *Note (1): No position in Table 12. c - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - C Declarations for 'table13.dat' ! VLBA 1.4 GHz Gaussian Fit Results integer*4 nr__5 parameter (nr__5=76) ! Number of records character*79 ar__5 ! Full-size record C J2000 position composed of: RAh RAm RAs DE- DEd DEm DEs real*8 RAdeg_2 (nr__5) ! (deg) Right Ascension J2000 real*8 DEdeg_2 (nr__5) ! (deg) Declination J2000 C ---------------------------------- ! (position vector(s) in degrees) character*10 Name_5 (nr__5) ! Object name (JHHMM+DDMM) character*2 m_Name_2 (nr__5) ! Multiplicity index on Name integer*4 RAh_2 (nr__5) ! (h) ? Hour of Right Ascension (J2000) (1) integer*4 RAm_2 (nr__5) ! (min) ? Minute of Right Ascension (J2000) real*8 RAs_2 (nr__5) ! (s) ? Second of Right Ascension (J2000) character*1 DE__2 (nr__5) ! ? Sign of the Declination (J2000) integer*4 DEd_2 (nr__5) ! (deg) ? Degree of Declination (J2000) integer*4 DEm_2 (nr__5) ! (arcmin) ? Arcminute of Declination (J2000) real*4 DEs_2 (nr__5) ! (arcsec) ? Arcsecond of Declination (J2000) real*4 Speak_2 (nr__5) ! (mJy/beam) [0.4/650.6] Peak flux density character*1 n_Speak_2 (nr__5) ! [*] Note on Speak (not in table 13) (G1) real*4 Sint_2 (nr__5) ! (mJy) [1.8/929.4] Integrated flux density character*1 n_Sint_2 (nr__5) ! [*] Note on Sint (not in table 13) (G1) real*4 MajAxis_2 (nr__5) ! (arcsec) [0.03/109] Deconvolved major axis real*4 MinAxis_2 (nr__5) ! (arcsec) [0.00/63] Deconvolved minor axis real*4 PA_2 (nr__5) ! (deg) [0.1/179.2] Position angle of the Gaussian * component real*4 alpha_2 (nr__5) ! [-3.6/3.1]? Spectral index ({alpha}) * calculated between 4.9 and 8.5 GHz * (only in table 12) *Note (1): No position in Table 12. C============================================================================= C Loading file 'table1.dat' ! Observing Summary C Format for file interpretation 1 format(A10,1X,A12,1X,A11,1X,I2,1X,A11,1X,I2,1X,A11,1X,I2,1X,A6) C Effective file loading open(unit=1,status='old',file= +'table1.dat') write(6,*) '....Loading file: table1.dat' do i__=1,81 read(1,'(A75)')ar__ read(ar__,1) + Name(i__),Radio(i__),Date4_9(i__),r_Date4_9(i__),Date8_5(i__), + r_Date8_5(i__),DateVLBI(i__),r_DateVLBI(i__),Note(i__) if(ar__(37:38) .EQ. '') r_Date4_9(i__) = iNULL__ if(ar__(52:53) .EQ. '') r_Date8_5(i__) = iNULL__ if(ar__(67:68) .EQ. '') r_DateVLBI(i__) = iNULL__ c ..............Just test output........... write(6,1) + Name(i__),Radio(i__),Date4_9(i__),r_Date4_9(i__),Date8_5(i__), + r_Date8_5(i__),DateVLBI(i__),r_DateVLBI(i__),Note(i__) c .......End.of.Just test output........... end do close(1) C============================================================================= C Loading file 'table2.dat' ! Summary of Radio Galaxy Properties C Format for file interpretation 2 format( + A10,1X,F5.3,A1,A1,1X,A5,1X,A2,1X,F4.2,1X,F4.2,1X,F4.2,1X,F4.2, + 1X,F5.2,1X,A3,A1,A1,1X,F5.3,A1,1X,F6.3,A1,1X,F4.2,1X,A5,1X,A6, + 1X,A1,1X,A2) C Effective file loading open(unit=1,status='old',file= +'table2.dat') write(6,*) '....Loading file: table2.dat' do i__=1,80 read(1,'(A97)')ar__1 read(ar__1,2) + Name_1(i__),z(i__),n_z(i__),u_z(i__),SEDType(i__),GType(i__), + S365MHz(i__),S1_4GHz(i__),S4_9CHz(i__),alphal(i__), + alphah(i__),Class(i__),n_Class(i__),u_Class(i__),LAS(i__), + u_LAS(i__),LLS(i__),n_LLS(i__),Freq(i__),Tel(i__),Morph(i__), + Eval1(i__),Eval2(i__) if(ar__1(12:16) .EQ. '') z(i__) = rNULL__ c ..............Just test output........... write(6,2) + Name_1(i__),z(i__),n_z(i__),u_z(i__),SEDType(i__),GType(i__), + S365MHz(i__),S1_4GHz(i__),S4_9CHz(i__),alphal(i__), + alphah(i__),Class(i__),n_Class(i__),u_Class(i__),LAS(i__), + u_LAS(i__),LLS(i__),n_LLS(i__),Freq(i__),Tel(i__),Morph(i__), + Eval1(i__),Eval2(i__) c .......End.of.Just test output........... end do close(1) C============================================================================= C Loading file 'table10.dat' ! Basic Observing Results C Format for file interpretation 3 format( + A10,1X,F4.2,1X,F4.2,1X,F5.1,1X,F4.2,A1,1X,F5.1,A1,1X,F4.2,1X, + F4.2,1X,F6.1,1X,F4.2,A1,1X,F5.1,A1,1X,F5.2,1X,F5.2,1X,F5.1,1X, + F4.2,1X,F5.1) C Effective file loading open(unit=1,status='old',file= +'table10.dat') write(6,*) '....Loading file: table10.dat' do i__=1,80 read(1,'(A98)')ar__2 read(ar__2,3) + Name_2(i__),MajAxis4_9(i__),MinAxis4_9(i__),PA4_9(i__), + rms4_9(i__),n_rms4_9(i__),Smax4_9(i__),n_Smax4_9(i__), + MajAxis8_5(i__),MinAxis8_5(i__),PA8_5(i__),rms8_5(i__), + n_rms8_5(i__),Smax8_5(i__),n_Smax8_5(i__),MajAxis1_4(i__), + MinAxis1_4(i__),PA1_4(i__),rms1_4(i__),Smax1_4(i__) if(ar__2(12:15) .EQ. '') MajAxis4_9(i__) = rNULL__ if(ar__2(17:20) .EQ. '') MinAxis4_9(i__) = rNULL__ if(ar__2(22:26) .EQ. '') PA4_9(i__) = rNULL__ if(ar__2(28:31) .EQ. '') rms4_9(i__) = rNULL__ if(ar__2(34:38) .EQ. '') Smax4_9(i__) = rNULL__ if(ar__2(41:44) .EQ. '') MajAxis8_5(i__) = rNULL__ if(ar__2(46:49) .EQ. '') MinAxis8_5(i__) = rNULL__ if(ar__2(51:56) .EQ. '') PA8_5(i__) = rNULL__ if(ar__2(58:61) .EQ. '') rms8_5(i__) = rNULL__ if(ar__2(64:68) .EQ. '') Smax8_5(i__) = rNULL__ if(ar__2(71:75) .EQ. '') MajAxis1_4(i__) = rNULL__ if(ar__2(77:81) .EQ. '') MinAxis1_4(i__) = rNULL__ if(ar__2(83:87) .EQ. '') PA1_4(i__) = rNULL__ if(ar__2(89:92) .EQ. '') rms1_4(i__) = rNULL__ if(ar__2(94:98) .EQ. '') Smax1_4(i__) = rNULL__ c ..............Just test output........... write(6,3) + Name_2(i__),MajAxis4_9(i__),MinAxis4_9(i__),PA4_9(i__), + rms4_9(i__),n_rms4_9(i__),Smax4_9(i__),n_Smax4_9(i__), + MajAxis8_5(i__),MinAxis8_5(i__),PA8_5(i__),rms8_5(i__), + n_rms8_5(i__),Smax8_5(i__),n_Smax8_5(i__),MajAxis1_4(i__), + MinAxis1_4(i__),PA1_4(i__),rms1_4(i__),Smax1_4(i__) c .......End.of.Just test output........... end do close(1) C============================================================================= C Loading file 'table11.dat' ! VLA 4.9 GHz Gaussian Fit Results C Format for file interpretation 4 format( + A10,1X,A2,1X,I2,1X,I2,1X,F7.4,1X,A1,I2,1X,I2,1X,F6.3,1X,F5.1, + A1,1X,F5.1,A1,1X,F6.2,1X,F5.2,1X,F5.1,1X,F4.1) C Effective file loading open(unit=1,status='old',file= +'table11.dat') write(6,*) '....Loading file: table11.dat' do i__=1,123 read(1,'(A79)')ar__3 read(ar__3,4) + Name_3(i__),m_Name(i__),RAh(i__),RAm(i__),RAs(i__),DE_(i__), + DEd(i__),DEm(i__),DEs(i__),Speak(i__),n_Speak(i__),Sint(i__), + n_Sint(i__),MajAxis(i__),MinAxis(i__),PA(i__),alpha(i__) if(ar__3(15:16) .EQ. '') RAh(i__) = iNULL__ if(ar__3(18:19) .EQ. '') RAm(i__) = iNULL__ if(ar__3(21:27) .EQ. '') RAs(i__) = rNULL__ if(ar__3(30:31) .EQ. '') DEd(i__) = iNULL__ if(ar__3(33:34) .EQ. '') DEm(i__) = iNULL__ if(ar__3(36:41) .EQ. '') DEs(i__) = rNULL__ if(ar__3(76:79) .EQ. '') alpha(i__) = rNULL__ 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(6,4) + Name_3(i__),m_Name(i__),RAh(i__),RAm(i__),RAs(i__),DE_(i__), + DEd(i__),DEm(i__),DEs(i__),Speak(i__),n_Speak(i__),Sint(i__), + n_Sint(i__),MajAxis(i__),MinAxis(i__),PA(i__),alpha(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 'table12.dat' ! VLA 8.5 GHz Gaussian Fit Results C Format for file interpretation 5 format( + A10,1X,A2,1X,I2,1X,I2,1X,F7.4,1X,A1,I2,1X,I2,1X,F6.3,1X,F5.1, + A1,1X,F5.1,A1,1X,F6.2,1X,F5.2,1X,F5.1,1X,F4.1) C Effective file loading open(unit=1,status='old',file= +'table12.dat') write(6,*) '....Loading file: table12.dat' do i__=1,102 read(1,'(A79)')ar__4 read(ar__4,5) + Name_4(i__),m_Name_1(i__),RAh_1(i__),RAm_1(i__),RAs_1(i__), + DE__1(i__),DEd_1(i__),DEm_1(i__),DEs_1(i__),Speak_1(i__), + n_Speak_1(i__),Sint_1(i__),n_Sint_1(i__),MajAxis_1(i__), + MinAxis_1(i__),PA_1(i__),alpha_1(i__) if(ar__4(15:16) .EQ. '') RAh_1(i__) = iNULL__ if(ar__4(18:19) .EQ. '') RAm_1(i__) = iNULL__ if(ar__4(21:27) .EQ. '') RAs_1(i__) = rNULL__ if(ar__4(30:31) .EQ. '') DEd_1(i__) = iNULL__ if(ar__4(33:34) .EQ. '') DEm_1(i__) = iNULL__ if(ar__4(36:41) .EQ. '') DEs_1(i__) = rNULL__ if(ar__4(76:79) .EQ. '') alpha_1(i__) = rNULL__ RAdeg_1(i__) = rNULL__ DEdeg_1(i__) = rNULL__ c Derive coordinates RAdeg_1 and DEdeg_1 from input data c (RAdeg_1 and DEdeg_1 are set to rNULL__ when unknown) if(RAh_1(i__) .GT. -180) RAdeg_1(i__)=RAh_1(i__)*15. if(RAm_1(i__) .GT. -180) RAdeg_1(i__)=RAdeg_1(i__)+RAm_1(i__)/4. if(RAs_1(i__) .GT. -180) RAdeg_1(i__)=RAdeg_1(i__)+RAs_1(i__)/240. if(DEd_1(i__) .GE. 0) DEdeg_1(i__)=DEd_1(i__) if(DEm_1(i__) .GE. 0) DEdeg_1(i__)=DEdeg_1(i__)+DEm_1(i__)/60. if(DEs_1(i__) .GE. 0) DEdeg_1(i__)=DEdeg_1(i__)+DEs_1(i__)/3600. if(DE__1(i__).EQ.'-'.AND.DEdeg_1(i__).GE.0) DEdeg_1(i__)=-DEdeg_1(i__) c ..............Just test output........... write(6,5) + Name_4(i__),m_Name_1(i__),RAh_1(i__),RAm_1(i__),RAs_1(i__), + DE__1(i__),DEd_1(i__),DEm_1(i__),DEs_1(i__),Speak_1(i__), + n_Speak_1(i__),Sint_1(i__),n_Sint_1(i__),MajAxis_1(i__), + MinAxis_1(i__),PA_1(i__),alpha_1(i__) write(6,'(6H Pos: 2F8.4)') RAdeg_1(i__),DEdeg_1(i__) c .......End.of.Just test output........... end do close(1) C============================================================================= C Loading file 'table13.dat' ! VLBA 1.4 GHz Gaussian Fit Results C Format for file interpretation 6 format( + A10,1X,A2,1X,I2,1X,I2,1X,F7.4,1X,A1,I2,1X,I2,1X,F6.3,1X,F5.1, + A1,1X,F5.1,A1,1X,F6.2,1X,F5.2,1X,F5.1,1X,F4.1) C Effective file loading open(unit=1,status='old',file= +'table13.dat') write(6,*) '....Loading file: table13.dat' do i__=1,76 read(1,'(A79)')ar__5 read(ar__5,6) + Name_5(i__),m_Name_2(i__),RAh_2(i__),RAm_2(i__),RAs_2(i__), + DE__2(i__),DEd_2(i__),DEm_2(i__),DEs_2(i__),Speak_2(i__), + n_Speak_2(i__),Sint_2(i__),n_Sint_2(i__),MajAxis_2(i__), + MinAxis_2(i__),PA_2(i__),alpha_2(i__) if(ar__5(15:16) .EQ. '') RAh_2(i__) = iNULL__ if(ar__5(18:19) .EQ. '') RAm_2(i__) = iNULL__ if(ar__5(21:27) .EQ. '') RAs_2(i__) = rNULL__ if(ar__5(30:31) .EQ. '') DEd_2(i__) = iNULL__ if(ar__5(33:34) .EQ. '') DEm_2(i__) = iNULL__ if(ar__5(36:41) .EQ. '') DEs_2(i__) = rNULL__ if(ar__5(76:79) .EQ. '') alpha_2(i__) = rNULL__ RAdeg_2(i__) = rNULL__ DEdeg_2(i__) = rNULL__ c Derive coordinates RAdeg_2 and DEdeg_2 from input data c (RAdeg_2 and DEdeg_2 are set to rNULL__ when unknown) if(RAh_2(i__) .GT. -180) RAdeg_2(i__)=RAh_2(i__)*15. if(RAm_2(i__) .GT. -180) RAdeg_2(i__)=RAdeg_2(i__)+RAm_2(i__)/4. if(RAs_2(i__) .GT. -180) RAdeg_2(i__)=RAdeg_2(i__)+RAs_2(i__)/240. if(DEd_2(i__) .GE. 0) DEdeg_2(i__)=DEd_2(i__) if(DEm_2(i__) .GE. 0) DEdeg_2(i__)=DEdeg_2(i__)+DEm_2(i__)/60. if(DEs_2(i__) .GE. 0) DEdeg_2(i__)=DEdeg_2(i__)+DEs_2(i__)/3600. if(DE__2(i__).EQ.'-'.AND.DEdeg_2(i__).GE.0) DEdeg_2(i__)=-DEdeg_2(i__) c ..............Just test output........... write(6,6) + Name_5(i__),m_Name_2(i__),RAh_2(i__),RAm_2(i__),RAs_2(i__), + DE__2(i__),DEd_2(i__),DEm_2(i__),DEs_2(i__),Speak_2(i__), + n_Speak_2(i__),Sint_2(i__),n_Sint_2(i__),MajAxis_2(i__), + MinAxis_2(i__),PA_2(i__),alpha_2(i__) write(6,'(6H Pos: 2F8.4)') RAdeg_2(i__),DEdeg_2(i__) c .......End.of.Just test output........... end do close(1) C============================================================================= stop end