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Glossary of OSA attributes

This Glossary alphabetically lists all attributes used in the OSAv20230621 database(s) held in the OSA. If you would like to have more information about the schema tables please use the OSAv20230621 Schema Browser (other Browser versions).
A B C D E F G H I J K L M
N O P Q R S T U V W X Y Z

R

NameSchema TableDatabaseDescriptionTypeLengthUnitDefault ValueUnified Content Descriptor
R1mag_USNOB1 ravedr5Source RAVE R1 mag from USNO-B real 4 mag   phot.mag;em.opt.R
r21_g cepheid, rrlyrae GAIADR1 Fourier decomposition parameter r21G: A2/A1 (for G band) float 8     stat.Fourier
r21_g_error cepheid, rrlyrae GAIADR1 Uncertainty on Fourier decomposition parameter r21G float 8     stat.error
R2mag_USNOB1 ravedr5Source RAVE R2 mag from USNO-B real 4 mag   phot.mag;em.opt.R
r_1AperMag3 vphasSource VPHASDR3 Default point source R_1 aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1AperMag3 vphasSource VPHASv20160112 Default point source R_1 aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_1AperMag3 vphasSource VPHASv20170222 Default point source R_1 aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_1AperMag3Err vphasSource VPHASDR3 Error in default point/extended source R_1 mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_1AperMag3Err vphasSource VPHASv20160112 Error in default point/extended source R_1 mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1AperMag3Err vphasSource VPHASv20170222 Error in default point/extended source R_1 mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1AperMag4 vphasSource VPHASDR3 Point source R_1 aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1AperMag4 vphasSource VPHASv20160112 Point source R_1 aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AperMag4 vphasSource VPHASv20170222 Point source R_1 aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AperMag4Err vphasSource VPHASDR3 Error in point/extended source R_1 mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_1AperMag4Err vphasSource VPHASv20160112 Error in point/extended source R_1 mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1AperMag4Err vphasSource VPHASv20170222 Error in point/extended source R_1 mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1AperMag6 vphasSource VPHASDR3 Point source R_1 aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1AperMag6 vphasSource VPHASv20160112 Point source R_1 aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AperMag6 vphasSource VPHASv20170222 Point source R_1 aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AperMag6Err vphasSource VPHASDR3 Error in point/extended source R_1 mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_1AperMag6Err vphasSource VPHASv20160112 Error in point/extended source R_1 mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1AperMag6Err vphasSource VPHASv20170222 Error in point/extended source R_1 mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1AperMagNoAperCorr3 vphasSource VPHASDR3 Default extended source R_1 aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1AperMagNoAperCorr3 vphasSource VPHASv20160112 Default extended source R_1 aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_1AperMagNoAperCorr3 vphasSource VPHASv20170222 Default extended source R_1 aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_1AperMagNoAperCorr4 vphasSource VPHASDR3 Extended source R_1 aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1AperMagNoAperCorr4 vphasSource VPHASv20160112 Extended source R_1 aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AperMagNoAperCorr4 vphasSource VPHASv20170222 Extended source R_1 aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AperMagNoAperCorr6 vphasSource VPHASDR3 Extended source R_1 aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1AperMagNoAperCorr6 vphasSource VPHASv20160112 Extended source R_1 aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AperMagNoAperCorr6 vphasSource VPHASv20170222 Extended source R_1 aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_1AverageConf vphasSource VPHASDR3 average confidence in 2 arcsec diameter default aperture (aper3) R_1 real 4   -99999999 stat.likelihood;em.opt.R
r_1AverageConf vphasSource VPHASv20160112 average confidence in 2 arcsec diameter default aperture (aper3) R_1 real 4   -99999999 stat.likelihood
r_1AverageConf vphasSource VPHASv20170222 average confidence in 2 arcsec diameter default aperture (aper3) R_1 real 4   -99999999 stat.likelihood
r_1Class vphasSource VPHASDR3 discrete image classification flag in R_1 smallint 2   -9999 src.class;em.opt.R
r_1Class vphasSource VPHASv20160112 discrete image classification flag in R_1 smallint 2   -9999 src.class
r_1Class vphasSource VPHASv20170222 discrete image classification flag in R_1 smallint 2   -9999 src.class
r_1ClassStat vphasSource VPHASDR3 N(0,1) stellarness-of-profile statistic in R_1 real 4   -0.9999995e9 stat;em.opt.R
r_1ClassStat vphasSource VPHASv20160112 N(0,1) stellarness-of-profile statistic in R_1 real 4   -0.9999995e9 stat
r_1ClassStat vphasSource VPHASv20170222 N(0,1) stellarness-of-profile statistic in R_1 real 4   -0.9999995e9 stat
r_1Ell vphasSource VPHASDR3 1-b/a, where a/b=semi-major/minor axes in R_1 real 4   -0.9999995e9 src.ellipticity;em.opt.R
r_1Ell vphasSource VPHASv20160112 1-b/a, where a/b=semi-major/minor axes in R_1 real 4   -0.9999995e9 src.ellipticity
r_1Ell vphasSource VPHASv20170222 1-b/a, where a/b=semi-major/minor axes in R_1 real 4   -0.9999995e9 src.ellipticity
r_1eNum vphasMergeLog VPHASDR3 the extension number of this R_1 frame tinyint 1     meta.number;em.opt.R
r_1eNum vphasMergeLog VPHASv20160112 the extension number of this R_1 frame tinyint 1     meta.number
r_1eNum vphasMergeLog VPHASv20170222 the extension number of this R_1 frame tinyint 1     meta.number
r_1ErrBits vphasSource VPHASDR3 processing warning/error bitwise flags in R_1 int 4   -99999999 meta.code;em.opt.R
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
r_1ErrBits vphasSource VPHASv20160112 processing warning/error bitwise flags in R_1 int 4   -99999999 meta.code
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
r_1ErrBits vphasSource VPHASv20170222 processing warning/error bitwise flags in R_1 int 4   -99999999 meta.code
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
r_1Eta vphasSource VPHASDR3 Offset of R_1 detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_1Eta vphasSource VPHASv20160112 Offset of R_1 detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_1Eta vphasSource VPHASv20170222 Offset of R_1 detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_1Gausig vphasSource VPHASDR3 RMS of axes of ellipse fit in R_1 real 4 pixels -0.9999995e9 src.morph.param;em.opt.R
r_1Gausig vphasSource VPHASv20160112 RMS of axes of ellipse fit in R_1 real 4 pixels -0.9999995e9 src.morph.param
r_1Gausig vphasSource VPHASv20170222 RMS of axes of ellipse fit in R_1 real 4 pixels -0.9999995e9 src.morph.param
r_1mfID vphasMergeLog VPHASDR3 the UID of the relevant R_1 multiframe bigint 8     meta.id;obs.field;em.opt.R
r_1mfID vphasMergeLog VPHASv20160112 the UID of the relevant R_1 multiframe bigint 8     meta.id;obs.field
r_1mfID vphasMergeLog VPHASv20170222 the UID of the relevant R_1 multiframe bigint 8     meta.id;obs.field
r_1miExt vphasSource VPHASDR3 Extended source colour R_1-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miExt vphasSource VPHASv20160112 Extended source colour R_1-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miExt vphasSource VPHASv20170222 Extended source colour R_1-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miExtErr vphasSource VPHASDR3 Error on extended source colour R_1-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miExtErr vphasSource VPHASv20160112 Error on extended source colour R_1-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miExtErr vphasSource VPHASv20170222 Error on extended source colour R_1-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miPnt vphasSource VPHASDR3 Point source colour R_1-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miPnt vphasSource VPHASv20160112 Point source colour R_1-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miPnt vphasSource VPHASv20170222 Point source colour R_1-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miPntErr vphasSource VPHASDR3 Error on point source colour R_1-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miPntErr vphasSource VPHASv20160112 Error on point source colour R_1-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1miPntErr vphasSource VPHASv20170222 Error on point source colour R_1-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_1Mjd vphasSource VPHASDR3 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch;em.opt.R
r_1Mjd vphasSource VPHASv20160112 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch
r_1Mjd vphasSource VPHASv20170222 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch
r_1PA vphasSource VPHASDR3 ellipse fit celestial orientation in R_1 real 4 Degrees -0.9999995e9 pos.posAng;em.opt.R
r_1PA vphasSource VPHASv20160112 ellipse fit celestial orientation in R_1 real 4 Degrees -0.9999995e9 pos.posAng
r_1PA vphasSource VPHASv20170222 ellipse fit celestial orientation in R_1 real 4 Degrees -0.9999995e9 pos.posAng
r_1PetroMag vphasSource VPHASDR3 Extended source R_1 mag (Petrosian) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1PetroMag vphasSource VPHASv20160112 Extended source R_1 mag (Petrosian) real 4 mag -0.9999995e9 phot.mag
r_1PetroMag vphasSource VPHASv20170222 Extended source R_1 mag (Petrosian) real 4 mag -0.9999995e9 phot.mag
r_1PetroMagErr vphasSource VPHASDR3 Error in extended source R_1 mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_1PetroMagErr vphasSource VPHASv20160112 Error in extended source R_1 mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1PetroMagErr vphasSource VPHASv20170222 Error in extended source R_1 mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1ppErrBits vphasSource VPHASDR3 additional WFAU post-processing error bits in R_1 int 4   0 meta.code;em.opt.R
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
r_1ppErrBits vphasSource VPHASv20160112 additional WFAU post-processing error bits in R_1 int 4   0 meta.code
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
r_1ppErrBits vphasSource VPHASv20170222 additional WFAU post-processing error bits in R_1 int 4   0 meta.code
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
r_1PsfMag vphasSource VPHASDR3 Point source profile-fitted R_1 mag real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1PsfMag vphasSource VPHASv20160112 Point source profile-fitted R_1 mag real 4 mag -0.9999995e9 phot.mag
r_1PsfMag vphasSource VPHASv20170222 Point source profile-fitted R_1 mag real 4 mag -0.9999995e9 phot.mag
r_1PsfMagErr vphasSource VPHASDR3 Error in point source profile-fitted R_1 mag real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_1PsfMagErr vphasSource VPHASv20160112 Error in point source profile-fitted R_1 mag real 4 mag -0.9999995e9 stat.error;phot.mag
r_1PsfMagErr vphasSource VPHASv20170222 Error in point source profile-fitted R_1 mag real 4 mag -0.9999995e9 stat.error;phot.mag
r_1SeqNum vphasSource VPHASDR3 the running number of the R_1 detection int 4   -99999999 meta.number;em.opt.R
r_1SeqNum vphasSource VPHASv20160112 the running number of the R_1 detection int 4   -99999999 meta.number
r_1SeqNum vphasSource VPHASv20170222 the running number of the R_1 detection int 4   -99999999 meta.number
r_1SerMag2D vphasSource VPHASDR3 Extended source R_1 mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_1SerMag2D vphasSource VPHASv20160112 Extended source R_1 mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag
r_1SerMag2D vphasSource VPHASv20170222 Extended source R_1 mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag
r_1SerMag2DErr vphasSource VPHASDR3 Error in extended source R_1 mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_1SerMag2DErr vphasSource VPHASv20160112 Error in extended source R_1 mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1SerMag2DErr vphasSource VPHASv20170222 Error in extended source R_1 mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag
r_1Xi vphasSource VPHASDR3 Offset of R_1 detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_1Xi vphasSource VPHASv20160112 Offset of R_1 detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_1Xi vphasSource VPHASv20170222 Offset of R_1 detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_2AperMag3 vphasSource VPHASDR3 Default point source R_2 aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2AperMag3 vphasSource VPHASv20160112 Default point source R_2 aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_2AperMag3 vphasSource VPHASv20170222 Default point source R_2 aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_2AperMag3Err vphasSource VPHASDR3 Error in default point/extended source R_2 mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_2AperMag3Err vphasSource VPHASv20160112 Error in default point/extended source R_2 mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2AperMag3Err vphasSource VPHASv20170222 Error in default point/extended source R_2 mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2AperMag4 vphasSource VPHASDR3 Point source R_2 aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2AperMag4 vphasSource VPHASv20160112 Point source R_2 aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AperMag4 vphasSource VPHASv20170222 Point source R_2 aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AperMag4Err vphasSource VPHASDR3 Error in point/extended source R_2 mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_2AperMag4Err vphasSource VPHASv20160112 Error in point/extended source R_2 mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2AperMag4Err vphasSource VPHASv20170222 Error in point/extended source R_2 mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2AperMag6 vphasSource VPHASDR3 Point source R_2 aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2AperMag6 vphasSource VPHASv20160112 Point source R_2 aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AperMag6 vphasSource VPHASv20170222 Point source R_2 aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AperMag6Err vphasSource VPHASDR3 Error in point/extended source R_2 mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_2AperMag6Err vphasSource VPHASv20160112 Error in point/extended source R_2 mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2AperMag6Err vphasSource VPHASv20170222 Error in point/extended source R_2 mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2AperMagNoAperCorr3 vphasSource VPHASDR3 Default extended source R_2 aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2AperMagNoAperCorr3 vphasSource VPHASv20160112 Default extended source R_2 aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_2AperMagNoAperCorr3 vphasSource VPHASv20170222 Default extended source R_2 aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
r_2AperMagNoAperCorr4 vphasSource VPHASDR3 Extended source R_2 aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2AperMagNoAperCorr4 vphasSource VPHASv20160112 Extended source R_2 aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AperMagNoAperCorr4 vphasSource VPHASv20170222 Extended source R_2 aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AperMagNoAperCorr6 vphasSource VPHASDR3 Extended source R_2 aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2AperMagNoAperCorr6 vphasSource VPHASv20160112 Extended source R_2 aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AperMagNoAperCorr6 vphasSource VPHASv20170222 Extended source R_2 aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
r_2AverageConf vphasSource VPHASDR3 average confidence in 2 arcsec diameter default aperture (aper3) R_2 real 4   -99999999 stat.likelihood;em.opt.R
r_2AverageConf vphasSource VPHASv20160112 average confidence in 2 arcsec diameter default aperture (aper3) R_2 real 4   -99999999 stat.likelihood
r_2AverageConf vphasSource VPHASv20170222 average confidence in 2 arcsec diameter default aperture (aper3) R_2 real 4   -99999999 stat.likelihood
r_2Class vphasSource VPHASDR3 discrete image classification flag in R_2 smallint 2   -9999 src.class;em.opt.R
r_2Class vphasSource VPHASv20160112 discrete image classification flag in R_2 smallint 2   -9999 src.class
r_2Class vphasSource VPHASv20170222 discrete image classification flag in R_2 smallint 2   -9999 src.class
r_2ClassStat vphasSource VPHASDR3 N(0,1) stellarness-of-profile statistic in R_2 real 4   -0.9999995e9 stat;em.opt.R
r_2ClassStat vphasSource VPHASv20160112 N(0,1) stellarness-of-profile statistic in R_2 real 4   -0.9999995e9 stat
r_2ClassStat vphasSource VPHASv20170222 N(0,1) stellarness-of-profile statistic in R_2 real 4   -0.9999995e9 stat
r_2Ell vphasSource VPHASDR3 1-b/a, where a/b=semi-major/minor axes in R_2 real 4   -0.9999995e9 src.ellipticity;em.opt.R
r_2Ell vphasSource VPHASv20160112 1-b/a, where a/b=semi-major/minor axes in R_2 real 4   -0.9999995e9 src.ellipticity
r_2Ell vphasSource VPHASv20170222 1-b/a, where a/b=semi-major/minor axes in R_2 real 4   -0.9999995e9 src.ellipticity
r_2eNum vphasMergeLog VPHASDR3 the extension number of this R_2 frame tinyint 1     meta.number;em.opt.R
r_2eNum vphasMergeLog VPHASv20160112 the extension number of this R_2 frame tinyint 1     meta.number
r_2eNum vphasMergeLog VPHASv20170222 the extension number of this R_2 frame tinyint 1     meta.number
r_2ErrBits vphasSource VPHASDR3 processing warning/error bitwise flags in R_2 int 4   -99999999 meta.code;em.opt.R
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
r_2ErrBits vphasSource VPHASv20160112 processing warning/error bitwise flags in R_2 int 4   -99999999 meta.code
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
r_2ErrBits vphasSource VPHASv20170222 processing warning/error bitwise flags in R_2 int 4   -99999999 meta.code
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
r_2Eta vphasSource VPHASDR3 Offset of R_2 detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_2Eta vphasSource VPHASv20160112 Offset of R_2 detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_2Eta vphasSource VPHASv20170222 Offset of R_2 detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_2Gausig vphasSource VPHASDR3 RMS of axes of ellipse fit in R_2 real 4 pixels -0.9999995e9 src.morph.param;em.opt.R
r_2Gausig vphasSource VPHASv20160112 RMS of axes of ellipse fit in R_2 real 4 pixels -0.9999995e9 src.morph.param
r_2Gausig vphasSource VPHASv20170222 RMS of axes of ellipse fit in R_2 real 4 pixels -0.9999995e9 src.morph.param
r_2mass allwise_sc WISE Distance separating the positions of the WISE source and associated 2MASS PSC source within 3". This column is "null" if there is no associated 2MASS PSC source. float 8 arcsec    
r_2mass wise_allskysc WISE Distance separating the positions of the WISE source and associated 2MASS PSC source within 3", default if there is no associated 2MASS PSC source. real 4 arcsec -0.9999995e9  
r_2mass wise_prelimsc WISE Distance separating the positions of the WISE source and associated 2MASS PSC source within 3", default if there is no associated 2MASS PSC source real 4 arcsec -0.9999995e9  
r_2mfID vphasMergeLog VPHASDR3 the UID of the relevant R_2 multiframe bigint 8     meta.id;obs.field;em.opt.R
r_2mfID vphasMergeLog VPHASv20160112 the UID of the relevant R_2 multiframe bigint 8     meta.id;obs.field
r_2mfID vphasMergeLog VPHASv20170222 the UID of the relevant R_2 multiframe bigint 8     meta.id;obs.field
r_2miExt vphasSource VPHASDR3 Extended source colour R_2-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miExt vphasSource VPHASv20160112 Extended source colour R_2-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miExt vphasSource VPHASv20170222 Extended source colour R_2-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miExtErr vphasSource VPHASDR3 Error on extended source colour R_2-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miExtErr vphasSource VPHASv20160112 Error on extended source colour R_2-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miExtErr vphasSource VPHASv20170222 Error on extended source colour R_2-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miPnt vphasSource VPHASDR3 Point source colour R_2-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miPnt vphasSource VPHASv20160112 Point source colour R_2-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miPnt vphasSource VPHASv20170222 Point source colour R_2-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miPntErr vphasSource VPHASDR3 Error on point source colour R_2-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miPntErr vphasSource VPHASv20160112 Error on point source colour R_2-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2miPntErr vphasSource VPHASv20170222 Error on point source colour R_2-I real 4 mag -0.9999995e9 stat.error;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
r_2Mjd vphasSource VPHASDR3 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch;em.opt.R
r_2Mjd vphasSource VPHASv20160112 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch
r_2Mjd vphasSource VPHASv20170222 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch
r_2PA vphasSource VPHASDR3 ellipse fit celestial orientation in R_2 real 4 Degrees -0.9999995e9 pos.posAng;em.opt.R
r_2PA vphasSource VPHASv20160112 ellipse fit celestial orientation in R_2 real 4 Degrees -0.9999995e9 pos.posAng
r_2PA vphasSource VPHASv20170222 ellipse fit celestial orientation in R_2 real 4 Degrees -0.9999995e9 pos.posAng
r_2PetroMag vphasSource VPHASDR3 Extended source R_2 mag (Petrosian) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2PetroMag vphasSource VPHASv20160112 Extended source R_2 mag (Petrosian) real 4 mag -0.9999995e9 phot.mag
r_2PetroMag vphasSource VPHASv20170222 Extended source R_2 mag (Petrosian) real 4 mag -0.9999995e9 phot.mag
r_2PetroMagErr vphasSource VPHASDR3 Error in extended source R_2 mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_2PetroMagErr vphasSource VPHASv20160112 Error in extended source R_2 mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2PetroMagErr vphasSource VPHASv20170222 Error in extended source R_2 mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2ppErrBits vphasSource VPHASDR3 additional WFAU post-processing error bits in R_2 int 4   0 meta.code;em.opt.R
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
r_2ppErrBits vphasSource VPHASv20160112 additional WFAU post-processing error bits in R_2 int 4   0 meta.code
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
r_2ppErrBits vphasSource VPHASv20170222 additional WFAU post-processing error bits in R_2 int 4   0 meta.code
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
r_2PsfMag vphasSource VPHASDR3 Point source profile-fitted R_2 mag real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2PsfMag vphasSource VPHASv20160112 Point source profile-fitted R_2 mag real 4 mag -0.9999995e9 phot.mag
r_2PsfMag vphasSource VPHASv20170222 Point source profile-fitted R_2 mag real 4 mag -0.9999995e9 phot.mag
r_2PsfMagErr vphasSource VPHASDR3 Error in point source profile-fitted R_2 mag real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_2PsfMagErr vphasSource VPHASv20160112 Error in point source profile-fitted R_2 mag real 4 mag -0.9999995e9 stat.error;phot.mag
r_2PsfMagErr vphasSource VPHASv20170222 Error in point source profile-fitted R_2 mag real 4 mag -0.9999995e9 stat.error;phot.mag
r_2SeqNum vphasSource VPHASDR3 the running number of the R_2 detection int 4   -99999999 meta.number;em.opt.R
r_2SeqNum vphasSource VPHASv20160112 the running number of the R_2 detection int 4   -99999999 meta.number
r_2SeqNum vphasSource VPHASv20170222 the running number of the R_2 detection int 4   -99999999 meta.number
r_2SerMag2D vphasSource VPHASDR3 Extended source R_2 mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag;em.opt.R
r_2SerMag2D vphasSource VPHASv20160112 Extended source R_2 mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag
r_2SerMag2D vphasSource VPHASv20170222 Extended source R_2 mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag
r_2SerMag2DErr vphasSource VPHASDR3 Error in extended source R_2 mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
r_2SerMag2DErr vphasSource VPHASv20160112 Error in extended source R_2 mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2SerMag2DErr vphasSource VPHASv20170222 Error in extended source R_2 mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag
r_2Xi vphasSource VPHASDR3 Offset of R_2 detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_2Xi vphasSource VPHASv20160112 Offset of R_2 detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_2Xi vphasSource VPHASv20170222 Offset of R_2 detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
r_3sig twomass_xsc TWOMASS 3-sigma K isophotal semi-major axis. real 4 arcsec   stat.error
R_D mgcGalaxyStruct MGC Exponential Disk Scale Length real 4   99.99  
R_D_KPC mgcGalaxyStruct MGC Exponential Disk Scale Length real 4 kpc 99.99  
R_Dm mgcGalaxyStruct MGC Exponential Disk Scale Length error (-) real 4   99.99  
R_Dp mgcGalaxyStruct MGC Exponential Disk Scale Length error (+) real 4   99.99  
r_ext twomass_sixx2_xsc TWOMASS extrapolation/total radius real 4 arcsec    
r_ext twomass_xsc TWOMASS extrapolation/total radius. real 4 arcsec   phys.angSize;src
r_fc twomass_xsc TWOMASS K fiducial Kron circular aperture radius. real 4 arcsec   phys.angSize;src
r_fe twomass_xsc TWOMASS K fiducial Kron elliptical aperture semi-major axis. real 4 arcsec   phys.angSize;src
r_j21fc twomass_xsc TWOMASS 21mag/sq." isophotal J fiducial circular ap. radius. real 4 arcsec   phys.angSize;src
r_j21fe twomass_xsc TWOMASS 21mag/sq." isophotal J fiducial ell. ap. semi-major axis. real 4 arcsec   phys.angSize;src
r_k20fc twomass_xsc TWOMASS 20mag/sq." isophotal K fiducial circular ap. radius. real 4 arcsec   phys.angSize;src
r_k20fe twomass_sixx2_xsc TWOMASS 20mag/sq.″ isophotal K fiducial ell. ap. semi-major axis real 4 arcsec    
r_k20fe twomass_xsc TWOMASS 20mag/sq." isophotal K fiducial ell. ap. semi-major axis. real 4 arcsec   phys.angSize;src
RA twoxmm, twoxmm_v1_2, twoxmmi_dr3_v1_0, xmm3dr4 XMM Corrected Right Ascension of the detection in degrees (J2000) after statistical correlation of the emldetect coordinates, RA_UNC and DEC_UNC, with the USNO B1.0 optical source catalogue using the SAS task eposcorr. In case where the cross-correlation is determined to be unreliable no correction is applied and this value is therefore the same as RA_UNC. float 8 degrees    
ra RequiredStack ATLASDR1 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack ATLASDR2 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack ATLASDR3 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack ATLASDR4 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack ATLASDR5 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack ATLASv20131127 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack ATLASv20160425 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack ATLASv20180209 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack VPHASDR3 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack VPHASv20160112 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra RequiredStack VPHASv20170222 Right Ascension of stack centre float 8 degrees   pos.eq.ra;meta.main
ra allwise_sc WISE J2000 right ascension with respect to the 2MASS PSC reference frame from the non-moving source extraction. float 8 deg    
ra atlasDetection ATLASDR3 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasDetection ATLASDR4 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasDetection ATLASDR5 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasDetection ATLASv20131127 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasDetection ATLASv20160425 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasDetection ATLASv20180209 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasDetection, atlasDetectionUncorr ATLASDR2 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasDetection, atlasSource ATLASDR1 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra atlasMergeLog ATLASDR1 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra atlasMergeLog ATLASDR2 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra atlasMergeLog ATLASDR3 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra atlasMergeLog ATLASDR4 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra atlasMergeLog ATLASDR5 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra atlasMergeLog ATLASv20131127 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra atlasMergeLog ATLASv20160425 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra atlasMergeLog ATLASv20180209 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra aux_qso_icrf2_match, gaia_source, tgas_source GAIADR1 Celestial Right Ascension float 8 degrees   pos.eq.ra;meta.main
ra catwise_2020 WISE right ascension (ICRS) float 8 deg    
ra catwise_prelim WISE right ascension (J2000) float 8 deg    
ra first08Jul16Source, firstSource, firstSource12Feb16 FIRST J2000 Celestial Right Ascension float 8 degrees   pos.eq.ra;meta.main
ra glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca, glimpse_hrc_inter, glimpse_mca_inter GLIMPSE Right Ascension (J2000) float 8 degrees   pos.eq.ra;meta.main
ra hipparcos_new_reduction GAIADR1 Right Ascension in the ICRS at epoch 1991.25 float 8 degrees   meta.main;pos.eq.ra
ra igsl_source GAIADR1 Celestial Right Ascension at catalogue epoch float 8 degrees   pos.eq.ra;meta.main
ra iras_psc IRAS J2000 Celestial Right Ascension float 8 degrees   pos.eq.ra;meta.main
ra mgcDetection MGC Object right ascension (J2000) float 8 deg    
ra nvssSource NVSS J2000 Celestial Right Ascension float 8 degrees   pos.eq.ra;meta.main
ra rosat_bsc, rosat_fsc ROSAT Right Ascension (decimal degrees; J2000) float 8 degrees   pos.eq.ra;meta.main
ra twomass_psc TWOMASS J2000 right ascension with respect to the ICRS float 8 degrees   pos.eq.ra;meta.main
ra twomass_scn TWOMASS Right ascension of scan center for equinox J2000. float 8 degrees   pos.eq.ra;meta.main
ra twomass_sixx2_psc TWOMASS right ascension (J2000 decimal deg) float 8 deg    
ra twomass_sixx2_scn TWOMASS right ascension (J2000 decimal deg) of scan center float 8 deg    
ra twomass_sixx2_xsc TWOMASS right ascension (J2000 decimal deg) based on peak pixel float 8 deg    
ra twomass_xsc TWOMASS Right ascension (J2000 decimal deg) based on peak pixel. float 8 degrees   pos.eq.ra;meta.main
ra twompzPhotoz TWOMPZ R.A. (J2000) based on the peak pixel {image primary HDU keyword: RAJ2000} float 8 Degrees   pos.eq.ra;meta.main
ra tycho2 GAIADR1 Observed Tycho2 Right Ascension in ICRS float 8 degrees   meta.main;pos.eq.ra
ra ukirtFSstars ATLASDR1 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars ATLASDR2 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars ATLASDR3 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars ATLASDR4 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars ATLASDR5 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars ATLASv20131127 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars ATLASv20160425 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars ATLASv20180209 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars VPHASDR3 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars VPHASv20160112 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra ukirtFSstars VPHASv20170222 Right Ascension of star at Equinox J2000.0 float 8 degrees   pos.eq.ra;meta.main
ra vphasDetection VPHASv20160112 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra vphasDetection VPHASv20170222 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra vphasDetection, vphasDetectionUncorr, vphasSource VPHASDR3 Celestial Right Ascension float 8 Degrees   pos.eq.ra;meta.main
Celestial Right Ascension as computed in the processing pipeline, accurate to of order 0.1 arcsec.
Note that original catalogue data has only r*4 storage precision, accurate only to ≈ 50mas. RA and Dec in the database are derived more precisely from WCS in the header and x and y attributes.
ra vphasMergeLog VPHASDR3 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra vphasMergeLog VPHASv20160112 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra vphasMergeLog VPHASv20170222 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
ra wise_allskysc WISE J2000 right ascension with respect to the 2MASS PSC reference frame. float 8 degrees    
ra wise_prelimsc WISE J2000 right ascension with respect to the 2MASS PSC reference frame float 8 degrees    
ra_1 twomass_scn TWOMASS J2000 right ascension of the eastern corner at start of scan. float 8 degrees   pos.eq.ra;meta.main
ra_1 twomass_sixx2_scn TWOMASS right ascension (J2000 decimal deg) of scan corner 1 float 8 deg    
ra_2 twomass_scn TWOMASS J2000 right ascension of the western corner at start of scan. float 8 degrees   pos.eq.ra;meta.main
ra_2 twomass_sixx2_scn TWOMASS right ascension (J2000 decimal deg) of scan corner 2 float 8 deg    
ra_3 twomass_scn TWOMASS J2000 right ascension of the eastern corner at end of scan. float 8 degrees   pos.eq.ra;meta.main
ra_3 twomass_sixx2_scn TWOMASS right ascension (J2000 decimal deg) of scan corner 3 float 8 deg    
ra_4 twomass_scn TWOMASS J2000 right ascension of the western corner at end of scan. float 8 degrees   pos.eq.ra;meta.main
ra_4 twomass_sixx2_scn TWOMASS right ascension (J2000 decimal deg) of scan corner 4 float 8 deg    
ra_dec_corr aux_qso_icrf2_match, gaia_source, tgas_source GAIADR1 Correlation between Right Ascension and Declination real 4     stat.correlation
ra_dec_corr gaia_source GAIADR2 Correlation between Right Ascension and Declination real 4     stat.correlation;pos.eq.ra;pos.eq.dec
ra_deg tycho2 GAIADR1 Observed Tycho2 Right Ascension in ICRS float 8 degrees   pos.eq.ra
ra_epoch igsl_source GAIADR1 Mean Epoch of Right Ascension real 4 years   time.epoch
ra_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca, glimpse_hrc_inter, glimpse_mca_inter GLIMPSE Error in Right Ascension float 8 arcsec   stat.error
ra_error aux_qso_icrf2_match GAIADR1 Uncertainty on celestial Right Ascension float 8 milliarcseconds   stat.error;pos.eq.ra;meta.main
ra_error gaia_source GAIADR2 Standard error of Right Ascension float 8 milliarcsec   stat.error;pos.eq.ra
ra_error gaia_source, tgas_source GAIADR1 Standard error of Right Ascension float 8 milliarcsec   stat.error;pos.eq.ra
ra_error igsl_source GAIADR1 Standard error of Right Ascension real 4 milliarcsec   stat.error;pos.eq.ra
ra_m_deg tycho2 GAIADR1 Mean Right Ascension, ICRS, epoch = J2000 float 8 degrees   pos.eq.ra
ra_parallax_corr gaia_source GAIADR2 Correlation between Right Ascension and parallax real 4     stat.correlation;pos.eq.ra;pos.parallax
ra_parallax_corr gaia_source, tgas_source GAIADR1 Correlation between Right Ascension and parallax real 4     stat.correlation
ra_pm allwise_sc WISE Right ascension at epoch MJD=55400.0 (2010.5589) from the profile-fitting measurement model that includes motion. This column is null if the fit failed to converge or was not attempted. NOTE: This will be similar but not identical to the value of ra which is the measured right ascenscion of the source from the non-moving profile-fit. float 8 deg    
ra_pm catwise_2020, catwise_prelim WISE right ascension (J2000) float 8 deg    
ra_pmdec_corr gaia_source GAIADR2 Correlation between Right Ascension and proper motion in Declination real 4     stat.correlation;pos.eq.ra;pos.pm;pos.eq.dec
ra_pmdec_corr gaia_source, tgas_source GAIADR1 Correlation between Right Ascension and proper motion in Declination real 4     stat.correlation
ra_pmra_corr gaia_source GAIADR2 Correlation between Right Ascension and proper motion in Right Ascension real 4     stat.correlation;pos.eq.ra;pos.pm;pos.eq.ra
ra_pmra_corr gaia_source, tgas_source GAIADR1 Correlation between Right Ascension and proper motion in Right Ascension real 4     stat.correlation
ra_rad hipparcos_new_reduction GAIADR1 Right Ascension in the ICRS at epoch 1991.25 float 8 radians   pos.eq.ra
RA_TGAS ravedr5Source RAVE TGAS Right Ascension (epocflag= 2015) float 8 deg   pos.eq.ra
RA_UNC twoxmm, twoxmm_v1_2, twoxmmi_dr3_v1_0, xmm3dr4 XMM Right Ascension of the source in degrees (J2000) as determined by the SAS task emldetect by fitting a detection simultaneously in all cameras and energy bands. float 8 degrees    
raB1950 mgcDetection MGC Object right ascension (B1950) float 8 deg    
raBase Multiframe ATLASDR1 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe ATLASDR2 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe ATLASDR3 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe ATLASDR4 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe ATLASDR5 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe ATLASv20131127 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe ATLASv20160425 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe ATLASv20180209 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe VPHASDR3 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe VPHASv20160112 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raBase Multiframe VPHASv20170222 Right ascension of base position (J2000) {image primary HDU keyword: RA} real 4 hours -9.999995e+08  
raCentre StdFieldInfo ATLASDR1 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo ATLASDR2 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo ATLASDR3 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo ATLASDR4 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo ATLASDR5 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo ATLASv20131127 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo ATLASv20160425 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo ATLASv20180209 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo VPHASDR3 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo VPHASv20160112 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
raCentre StdFieldInfo VPHASv20170222 Right Ascension of field centre float 8 degrees   pos.eq.ra;meta.main
RAD_20KPC20 mgcGalaxyStruct MGC 1kpc radius at object distance (h=1) real 4 arcsecs 0.000  
RADEC_ERR twoxmm, twoxmm_v1_2, twoxmmi_dr3_v1_0, xmm3dr4 XMM Statistical 1 σ error on the detection position in arcseconds. real 4 arcsec    
raDecSys Multiframe ATLASDR1 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe ATLASDR2 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe ATLASDR3 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe ATLASDR4 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe ATLASDR5 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe ATLASv20131127 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe ATLASv20160425 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe ATLASv20180209 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe VPHASDR3 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe VPHASv20160112 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
raDecSys Multiframe VPHASv20170222 Coordinate reference frame {image primary HDU keyword: RADECSYS} varchar 4   NONE  
RAdeg denisDR3Source DENIS Right ascension (J2000) real 4 deg    
RAdeg ravedr5Source RAVE Right Ascension (J2000) float 8 deg   pos.eq.ra
radial_velocity gaia_source GAIADR2 Radial velocity real 4 km/s   spect.dopplerVeloc.opt
radial_velocity_error gaia_source GAIADR2 Standard error on the radial velocity real 4 km/s   stat.error;spect.dopplerVeloc.opt
radius1 iras_asc IRAS Radius Vector from IRAS Source to Association smallint 2 arcsec   phys.angSize;src
radius_percentile_lower gaia_source GAIADR2 Lower uncertainty on stellar radius real 4 Solar radius   phys.size.radius;stat.min
radius_percentile_upper gaia_source GAIADR2 Upper uncertainty on stellar radius real 4 Solar radius   phys.size.radius;stat.max
radius_val gaia_source GAIADR2 Stellar radius real 4 Solar radius   phys.size.radius
raMoon Multiframe ATLASDR1 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe ATLASDR2 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe ATLASDR3 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe ATLASDR4 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe ATLASDR5 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe ATLASv20131127 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe ATLASv20160425 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe ATLASv20180209 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe VPHASDR3 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe VPHASv20160112 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoon Multiframe VPHASv20170222 Geocentric J2000 FK5 Mean Right ascension of the Moon float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASDR1 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASDR2 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASDR3 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASDR4 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASDR5 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASv20131127 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASv20160425 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe ATLASv20180209 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe VPHASDR3 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe VPHASv20160112 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
raMoonTopo Multiframe VPHASv20170222 Apparent topocentric Right ascension of the Moon (including precession, nutation, and annual aberration) float 8 hours -0.9999995e9 pos.eq.ra;meta.main
random_index gaia_source GAIADR2 Random index used to select subsets bigint 8     meta.code
random_index gaia_source, tgas_source GAIADR1 Random index used to select subsets bigint 8     meta.code
range phot_variable_time_series_g_fov_statistical_parameters GAIADR1 Difference between the highest and lowest magnitude of the G-band time series float 8 mag   phot.mag;arith.diff
rAperMag3 atlasSource ATLASDR1 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
rAperMag3 atlasSource ATLASDR2 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
rAperMag3 atlasSource ATLASDR3 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag3 atlasSource ATLASDR4 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag3 atlasSource ATLASDR5 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag3 atlasSource ATLASv20131127 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
rAperMag3 atlasSource ATLASv20160425 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag3 atlasSource ATLASv20180209 Default point source R aperture corrected mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag3Err atlasSource ATLASDR1 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag3Err atlasSource ATLASDR2 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag3Err atlasSource ATLASDR3 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag3Err atlasSource ATLASDR4 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag3Err atlasSource ATLASDR5 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag3Err atlasSource ATLASv20131127 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag3Err atlasSource ATLASv20160425 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag3Err atlasSource ATLASv20180209 Error in default point/extended source R mag (2.0 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag4 atlasSource ATLASDR1 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMag4 atlasSource ATLASDR2 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMag4 atlasSource ATLASDR3 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag4 atlasSource ATLASDR4 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag4 atlasSource ATLASDR5 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag4 atlasSource ATLASv20131127 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMag4 atlasSource ATLASv20160425 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag4 atlasSource ATLASv20180209 Point source R aperture corrected mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag4Err atlasSource ATLASDR1 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag4Err atlasSource ATLASDR2 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag4Err atlasSource ATLASDR3 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag4Err atlasSource ATLASDR4 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag4Err atlasSource ATLASDR5 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag4Err atlasSource ATLASv20131127 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag4Err atlasSource ATLASv20160425 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag4Err atlasSource ATLASv20180209 Error in point/extended source R mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag6 atlasSource ATLASDR1 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMag6 atlasSource ATLASDR2 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMag6 atlasSource ATLASDR3 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag6 atlasSource ATLASDR4 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag6 atlasSource ATLASDR5 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag6 atlasSource ATLASv20131127 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMag6 atlasSource ATLASv20160425 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag6 atlasSource ATLASv20180209 Point source R aperture corrected mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMag6Err atlasSource ATLASDR1 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag6Err atlasSource ATLASDR2 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag6Err atlasSource ATLASDR3 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag6Err atlasSource ATLASDR4 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag6Err atlasSource ATLASDR5 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag6Err atlasSource ATLASv20131127 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error
rAperMag6Err atlasSource ATLASv20160425 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMag6Err atlasSource ATLASv20180209 Error in point/extended source R mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rAperMagNoAperCorr3 atlasSource ATLASDR1 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr3 atlasSource ATLASDR2 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr3 atlasSource ATLASDR3 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr3 atlasSource ATLASDR4 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr3 atlasSource ATLASDR5 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr3 atlasSource ATLASv20131127 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr3 atlasSource ATLASv20160425 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr3 atlasSource ATLASv20180209 Default extended source R aperture mag (2.0 arcsec aperture diameter)
If in doubt use this flux estimator
real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr4 atlasSource ATLASDR1 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr4 atlasSource ATLASDR2 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr4 atlasSource ATLASDR3 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr4 atlasSource ATLASDR4 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr4 atlasSource ATLASDR5 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr4 atlasSource ATLASv20131127 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr4 atlasSource ATLASv20160425 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr4 atlasSource ATLASv20180209 Extended source R aperture mag (2.8 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr6 atlasSource ATLASDR1 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr6 atlasSource ATLASDR2 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr6 atlasSource ATLASDR3 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr6 atlasSource ATLASDR4 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr6 atlasSource ATLASDR5 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr6 atlasSource ATLASv20131127 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag
rAperMagNoAperCorr6 atlasSource ATLASv20160425 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rAperMagNoAperCorr6 atlasSource ATLASv20180209 Extended source R aperture mag (5.7 arcsec aperture diameter) real 4 mag -0.9999995e9 phot.mag;em.opt.R
RAusno denisDR3Source DENIS Right Ascension of USNOA2.0 nearest match real 4 deg    
RAVE_OBS_ID ravedr5Source RAVE Unique Identifier for RAVE objects, Observation Date, Fieldname, Fibernumber varchar 22     meta.id
RAVEID ravedr5Source RAVE (J2000 GCS), see Note in DR4 varchar 20     meta.id
rAverageConf atlasSource ATLASDR1 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 meta.code
rAverageConf atlasSource ATLASDR2 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 meta.code
rAverageConf atlasSource ATLASDR3 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 stat.likelihood;em.opt.R
rAverageConf atlasSource ATLASDR4 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 stat.likelihood;em.opt.R
rAverageConf atlasSource ATLASDR5 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 stat.likelihood;em.opt.R
rAverageConf atlasSource ATLASv20131127 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 meta.code
rAverageConf atlasSource ATLASv20160425 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 stat.likelihood;em.opt.R
rAverageConf atlasSource ATLASv20180209 average confidence in 2 arcsec diameter default aperture (aper3) R real 4   -99999999 stat.likelihood;em.opt.R
rCalCorr twompzPhotoz TWOMPZ SuperCOSMOS RgCorMag corrected for Galactic dust extinction. Southern hemisphere [dec(1950)<2.5] have been corrected for a small colour dependent offset between UKST and POSS-II. {image primary HDU keyword: RcalCorr} real 4   -0.9999995e9  
rCalCorrErr twompzPhotoz TWOMPZ Estimated error in R band {image primary HDU keyword: errR} real 4 mag -0.9999995e9  
rch2w1 catwise_2020, catwise_prelim WISE chi-square for dw1mag (1 DF) real 4      
rch2w2 catwise_2020, catwise_prelim WISE chi-square for dw2mag (1 DF) real 4      
rchi2 allwise_sc WISE Combined reduced χ2 in all bands for the profile-fit photometry measurement. real 4      
rchi2 catwise_2020, catwise_prelim WISE reduced chi squared, total real 4      
rchi2 wise_allskysc WISE Combined reduced chi-squared of the profile-fit photometry measurement in all bands. real 4   -0.9999995e9  
rchi2 wise_prelimsc WISE Combined reduced chi-squared of the profile-fit photometry measurement in all bands real 4   -0.9999995e9  
rchi2_pm allwise_sc WISE Combined reduced χ2 in all bands for the profile-fit photometry measurement that includes source motion. This column is null if the motion fit failed to converge or was not attempted. real 4      
rchi2_pm catwise_2020, catwise_prelim WISE reduced chi squared, total real 4      
rClass atlasSource ATLASDR1 discrete image classification flag in R smallint 2   -9999 src.class
rClass atlasSource ATLASDR2 discrete image classification flag in R smallint 2   -9999 src.class
rClass atlasSource ATLASDR3 discrete image classification flag in R smallint 2   -9999 src.class;em.opt.R
rClass atlasSource ATLASDR4 discrete image classification flag in R smallint 2   -9999 src.class;em.opt.R
rClass atlasSource ATLASDR5 discrete image classification flag in R smallint 2   -9999 src.class;em.opt.R
rClass atlasSource ATLASv20131127 discrete image classification flag in R smallint 2   -9999 src.class
rClass atlasSource ATLASv20160425 discrete image classification flag in R smallint 2   -9999 src.class;em.opt.R
rClass atlasSource ATLASv20180209 discrete image classification flag in R smallint 2   -9999 src.class;em.opt.R
rClassStat atlasSource ATLASDR1 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat
rClassStat atlasSource ATLASDR2 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat
rClassStat atlasSource ATLASDR3 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat;em.opt.R
rClassStat atlasSource ATLASDR4 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat;em.opt.R
rClassStat atlasSource ATLASDR5 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat;em.opt.R
rClassStat atlasSource ATLASv20131127 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat
rClassStat atlasSource ATLASv20160425 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat;em.opt.R
rClassStat atlasSource ATLASv20180209 N(0,1) stellarness-of-profile statistic in R real 4   -0.9999995e9 stat;em.opt.R
rct1 rosat_fsc ROSAT number of nearby RASS detections with distances in range 0'-5' tinyint 1     meta.id
rct2 rosat_fsc ROSAT number of nearby RASS detections with distances in range 5'-10' tinyint 1     meta.id
rct3 rosat_fsc ROSAT number of nearby RASS detections with distances in range 10'-15' tinyint 1     meta.id
rd_flg twomass_psc TWOMASS Read flag. varchar 3     meta.code
rd_flg twomass_sixx2_psc TWOMASS source of JHK "default" mags (AKA "read flag") varchar 3      
RE_BULGE_KPC mgcGalaxyStruct MGC Bulge Effective Radius real 4 kpc 99.99  
recNo iras_asc IRAS Record Number of source in data file int 4     meta.record
ref_epoch aux_qso_icrf2_match GAIADR1 Reference epoch float 8 Julian years   time.epoch
ref_epoch gaia_source GAIADR2 Reference epoch real 4 Julian years   meta.ref;time.epoch
ref_epoch gaia_source, tgas_source GAIADR1 Reference epoch float 8 Julian years   meta.ref;time.epoch
REFCAT xmm3dr4 XMM An integer code reflecting the absolute astrometric reference catalogue which gave the statistically 'best' result for the field rectification process (from which the corrections are taken). It is 1 for the USNO B1.0 catalogue, 2 for 2MASS and 3 for SDSS (DR8). Where catcorr fails to produce a reliable solution, REFCAT is a negative number, indicating the cause of the failure. The failure codes are -1 = Too few matches (< 10), -2 = poor fit (goodness of fit parameter in catcorr < 5.0), -3 = error on the field positional rectification correction is > 0.75 arcseconds) smallint 2      
refDecShift01 CurrentAstrometry ATLASDR1 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry ATLASDR2 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry ATLASDR3 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry ATLASDR4 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry ATLASDR5 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry ATLASv20131127 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry ATLASv20160425 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry ATLASv20180209 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry VPHASDR3 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry VPHASv20160112 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift01 CurrentAstrometry VPHASv20170222 Ref Dec shift pass 0 to 1 (new - old) {image extension keyword: DECZP01} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASDR1 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASDR2 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASDR3 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASDR4 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASDR5 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASv20131127 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASv20160425 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry ATLASv20180209 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry VPHASDR3 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry VPHASv20160112 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift02 CurrentAstrometry VPHASv20170222 Ref Dec shift pass 0 to 2 (new - old) {image extension keyword: DECZP02} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASDR1 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASDR2 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASDR3 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASDR4 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASDR5 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASv20131127 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASv20160425 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry ATLASv20180209 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry VPHASDR3 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry VPHASv20160112 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift12 CurrentAstrometry VPHASv20170222 Ref Dec shift pass 1 to 2 (new - old) {image extension keyword: DECZP12} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASDR1 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASDR2 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASDR3 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASDR4 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASDR5 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASv20131127 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASv20160425 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry ATLASv20180209 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry VPHASDR3 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry VPHASv20160112 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
refDecShift22 CurrentAstrometry VPHASv20170222 Ref Dec shift pass 2 to 2 (new - old) {image extension keyword: DECZP22} float 8 arcsec -0.9999995e9 ??
reference Programme ATLASDR1 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme ATLASDR2 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme ATLASDR3 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme ATLASDR4 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme ATLASDR5 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme ATLASv20131127 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme ATLASv20160425 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme ATLASv20180209 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme VPHASDR3 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme VPHASv20160112 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
reference Programme VPHASv20170222 a reference for the programme, eg. "http://www.ukidss.org/surveys/surveys.html" varchar 256     meta.bib
refRaShift01 CurrentAstrometry ATLASDR1 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry ATLASDR2 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry ATLASDR3 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry ATLASDR4 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry ATLASDR5 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry ATLASv20131127 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry ATLASv20160425 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry ATLASv20180209 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry VPHASDR3 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry VPHASv20160112 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift01 CurrentAstrometry VPHASv20170222 Ref RA shift pass 0 to 1 (new - old) {image extension keyword: RAZP01} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASDR1 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASDR2 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASDR3 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASDR4 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASDR5 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASv20131127 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASv20160425 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry ATLASv20180209 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry VPHASDR3 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry VPHASv20160112 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift02 CurrentAstrometry VPHASv20170222 Ref RA shift pass 0 to 2 (new - old) {image extension keyword: RAZP02} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASDR1 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASDR2 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASDR3 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASDR4 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASDR5 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASv20131127 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASv20160425 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry ATLASv20180209 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry VPHASDR3 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry VPHASv20160112 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift12 CurrentAstrometry VPHASv20170222 Ref RA shift pass 1 to 2 (new - old) {image extension keyword: RAZP12} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASDR1 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASDR2 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASDR3 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASDR4 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASDR5 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASv20131127 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASv20160425 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry ATLASv20180209 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry VPHASDR3 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry VPHASv20160112 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
refRaShift22 CurrentAstrometry VPHASv20170222 Ref RA shift pass 2 to 2 (new - old) {image extension keyword: RAZP22} float 8 arcsec -0.9999995e9 ??
rejected_by_variability_processing phot_variable_time_series_g_fov GAIADR1 True when this FoV observation was excluded from the variability analysis bit 1     meta.code
rel allwise_sc WISE Small-separation, same-Tile (SSST) detection flag. Non-null values of this flag indicate that this Catalog/Reject Table entry is part of a group of detections with unphysically small separations that were extracted on the same Tile. SSST groups occurred when a faint, often spurious noise detection was shifted towards the position of a brighter nearby source during the chi-squared minimization profile-fit source extraction process. This resulted in two or more extractions on the same Tile that have nearly the same position and similar fluxes. SSST groups were identified and classified using the rel flag, and the classifications are used as part of Catalog source selection. varchar 1      
The possible values of the rel column are:
  • null - The extraction is not part of a SSST group, and is eligible for the AllWISE Catalog.
  • s - The extraction is part of an SSST group, and is the original, correct extraction that is eligible for the AllWISE Catalog.
  • c - The extraction is part of an SSST group amd is the original, correct extraction, but is inadvertantly flagged as a spurious artifact. It is eligible for inclusion in the AllWISE Catalog.
  • r - The extraction is part of an SSST group, but is the least reliable extraction in the group. It is not eligible for the Catalog. These are found only in the AllWISE Reject Table.
rel twomass_sixx2_psc, twomass_sixx2_xsc TWOMASS Reliability flag (A-F), with A being the highest and F being lowest reliability varchar 1      
rel0 twomass_scn TWOMASS Flag indicating whether the scan is contained in the TWOMASS Sampler Release. smallint 2     meta.code
rel1 twomass_scn TWOMASS Flag indicating whether the scan is contained in the TWOMASS First Incremental Data Release (IDR1). smallint 2     meta.code
rel2 twomass_scn TWOMASS Flag indicating whether the scan is contained in the TWOMASS Second Incremental Data Release (IDR2). smallint 2     meta.code
releaseDate Release ATLASDR1 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release ATLASDR2 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release ATLASDR3 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release ATLASDR4 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release ATLASDR5 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release ATLASv20131127 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release ATLASv20160425 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release ATLASv20180209 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release VPHASDR3 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release VPHASv20160112 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseDate Release VPHASv20170222 the release date datetime 8 MM-DD-YYYY 12-31-9999 time.epoch
releaseNum EpochFrameStatus ATLASDR4 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum EpochFrameStatus ATLASDR5 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum EpochFrameStatus ATLASv20160425 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum EpochFrameStatus ATLASv20180209 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum EpochFrameStatus VPHASDR3 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum EpochFrameStatus VPHASv20160112 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum EpochFrameStatus VPHASv20170222 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum EpochFrameStatus, ProgrammeFrame ATLASDR3 Release number of deep stack frame (or intermediate stack if used as a deep stack). {image primary HDU keyword: RELNUM} smallint 2   -9999  
releaseNum ExternalProduct ATLASDR2 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct ATLASDR3 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct ATLASDR4 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct ATLASDR5 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct ATLASv20131127 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct ATLASv20160425 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct ATLASv20180209 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct VPHASDR3 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct VPHASv20160112 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum ExternalProduct VPHASv20170222 Release number of deep stack frame (or intermediate stack if used as a deep stack). smallint 2   -9999  
releaseNum Release ATLASDR1 the release number smallint 2     meta.software
releaseNum Release ATLASDR2 the release number smallint 2     meta.software
releaseNum Release ATLASDR3 the release number smallint 2     meta.software
releaseNum Release ATLASDR4 the release number smallint 2     meta.software
releaseNum Release ATLASDR5 the release number smallint 2     meta.software
releaseNum Release ATLASv20131127 the release number smallint 2     meta.software
releaseNum Release ATLASv20160425 the release number smallint 2     meta.software
releaseNum Release ATLASv20180209 the release number smallint 2     meta.software
releaseNum Release VPHASDR3 the release number smallint 2     meta.software
releaseNum Release VPHASv20160112 the release number smallint 2     meta.software
releaseNum Release VPHASv20170222 the release number smallint 2     meta.software
rEll atlasSource ATLASDR1 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity
rEll atlasSource ATLASDR2 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity
rEll atlasSource ATLASDR3 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity;em.opt.R
rEll atlasSource ATLASDR4 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity;em.opt.R
rEll atlasSource ATLASDR5 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity;em.opt.R
rEll atlasSource ATLASv20131127 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity
rEll atlasSource ATLASv20160425 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity;em.opt.R
rEll atlasSource ATLASv20180209 1-b/a, where a/b=semi-major/minor axes in R real 4   -0.9999995e9 src.ellipticity;em.opt.R
relUnc_100 iras_psc IRAS percent relative 100 micron flux density uncertainties. smallint 2     stat.error
relUnc_12 iras_psc IRAS percent relative 12 micron flux density uncertainties. smallint 2     stat.error
relUnc_25 iras_psc IRAS percent relative 25 micron flux density uncertainties. smallint 2     stat.error
relUnc_60 iras_psc IRAS percent relative 60 micron flux density uncertainties. smallint 2     stat.error
reNum atlasMergeLog ATLASDR1 the extension number of this R frame tinyint 1     meta.number
reNum atlasMergeLog ATLASDR2 the extension number of this R frame tinyint 1     meta.number
reNum atlasMergeLog ATLASDR3 the extension number of this R frame tinyint 1     meta.number;em.opt.R
reNum atlasMergeLog ATLASDR4 the extension number of this R frame tinyint 1     meta.number;em.opt.R
reNum atlasMergeLog ATLASDR5 the extension number of this R frame tinyint 1     meta.id;em.opt.R
reNum atlasMergeLog ATLASv20131127 the extension number of this R frame tinyint 1     meta.number
reNum atlasMergeLog ATLASv20160425 the extension number of this R frame tinyint 1     meta.number;em.opt.R
reNum atlasMergeLog ATLASv20180209 the extension number of this R frame tinyint 1     meta.number;em.opt.R
Rep_Flag ravedr5Source RAVE 0 => single observation, 1 => more than one observation tinyint 1     meta.code.qual
reqMaxAirmass Multiframe ATLASDR1 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe ATLASDR2 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe ATLASDR3 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe ATLASDR4 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe ATLASDR5 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe ATLASv20131127 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe ATLASv20160425 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe ATLASv20180209 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe VPHASDR3 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe VPHASv20160112 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxAirmass Multiframe VPHASv20170222 Requested maximum airmass {image primary HDU keyword: HIERARCH ESO OBS AIRM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASDR1 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASDR2 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASDR3 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASDR4 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASDR5 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASv20131127 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASv20160425 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe ATLASv20180209 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe VPHASDR3 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe VPHASv20160112 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqMaxSeeing Multiframe VPHASv20170222 Requested maximum seeing {image primary HDU keyword: HIERARCH ESO OBS AMBI FWHM} real 4   -0.9999995e9  
reqSkyTrans Multiframe ATLASDR1 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe ATLASDR2 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe ATLASDR3 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe ATLASDR4 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe ATLASDR5 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe ATLASv20131127 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe ATLASv20160425 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe ATLASv20180209 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe VPHASDR3 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe VPHASv20160112 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
reqSkyTrans Multiframe VPHASv20170222 Requested sky transparency {image primary HDU keyword: HIERARCH ESO OBS AMBI TRANS} varchar 64   NONE  
rErrBits atlasSource ATLASDR1 processing warning/error bitwise flags in R int 4   -99999999 meta.code
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
rErrBits atlasSource ATLASDR2 processing warning/error bitwise flags in R int 4   -99999999 meta.code
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
rErrBits atlasSource ATLASDR3 processing warning/error bitwise flags in R int 4   -99999999 meta.code;em.opt.R
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
rErrBits atlasSource ATLASDR4 processing warning/error bitwise flags in R int 4   -99999999 meta.code;em.opt.R
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
rErrBits atlasSource ATLASDR5 processing warning/error bitwise flags in R int 4   -99999999 meta.code;em.opt.R
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
rErrBits atlasSource ATLASv20131127 processing warning/error bitwise flags in R int 4   -99999999 meta.code
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
rErrBits atlasSource ATLASv20160425 processing warning/error bitwise flags in R int 4   -99999999 meta.code;em.opt.R
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
rErrBits atlasSource ATLASv20180209 processing warning/error bitwise flags in R int 4   -99999999 meta.code;em.opt.R
Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
resFlux nvssSource NVSS Peak residual flux, in mJy/beam real 4 mJy   phot.flux.density;em.radio
resultsFile ArchiveCurationHistory ATLASDR1 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory ATLASDR2 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory ATLASDR3 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory ATLASDR4 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory ATLASDR5 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory ATLASv20131127 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory ATLASv20160425 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory ATLASv20180209 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory VPHASDR3 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory VPHASv20160112 filename of any results file varchar 256     meta.id;meta.file
resultsFile ArchiveCurationHistory VPHASv20170222 filename of any results file varchar 256     meta.id;meta.file
rEta atlasSource ATLASDR1 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rEta atlasSource ATLASDR2 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rEta atlasSource ATLASDR3 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rEta atlasSource ATLASDR4 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rEta atlasSource ATLASDR5 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rEta atlasSource ATLASv20131127 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rEta atlasSource ATLASv20160425 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rEta atlasSource ATLASv20180209 Offset of R detection from master position (+north/-south) real 4 arcsec -0.9999995e9 pos.eq.dec;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
REVOLUT twoxmm, twoxmm_v1_2, twoxmmi_dr3_v1_0 XMM The XMM-Newton revolution number. varchar 4 orbit    
REVOLUT xmm3dr4 XMM The XMM-Newton revolution number. varchar 50 orbit    
rFlag rosat_bsc, rosat_fsc ROSAT source counts and extraction radius recalculated varchar 1     meta.code
rGausig atlasSource ATLASDR1 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param
rGausig atlasSource ATLASDR2 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param
rGausig atlasSource ATLASDR3 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param;em.opt.R
rGausig atlasSource ATLASDR4 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param;em.opt.R
rGausig atlasSource ATLASDR5 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param;em.opt.R
rGausig atlasSource ATLASv20131127 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param
rGausig atlasSource ATLASv20160425 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param;em.opt.R
rGausig atlasSource ATLASv20180209 RMS of axes of ellipse fit in R real 4 pixels -0.9999995e9 src.morph.param;em.opt.R
rh twomass_scn TWOMASS Relative humidity of telescope enclosure at beginning of scan. smallint 2 %   meta.note;obs
rh twomass_sixx2_scn TWOMASS relative humidity (%) at beginning of scan smallint 2 %    
RHALF mgcGalaxyStruct MGC GIM2D HLR real 4   99.99  
rHlCorSMjRadAs atlasSource ATLASDR1 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;src
rHlCorSMjRadAs atlasSource ATLASDR2 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;src
rHlCorSMjRadAs atlasSource ATLASDR3 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;em.opt.R
rHlCorSMjRadAs atlasSource ATLASDR4 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;em.opt.R
rHlCorSMjRadAs atlasSource ATLASDR5 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;em.opt.R
rHlCorSMjRadAs atlasSource ATLASv20131127 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;src
rHlCorSMjRadAs atlasSource ATLASv20160425 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;em.opt.R
rHlCorSMjRadAs atlasSource ATLASv20180209 Seeing corrected half-light, semi-major axis in R band real 4 arcsec -0.9999995e9 phys.angSize;em.opt.R
rho12 allwise_sc WISE The correlation coefficient between the W1 and W2 single-exposure flux measurements. The value is a signed 2-digit integer, expressed as a percentage. Negative values indicate anticorrelation. rho12 is approximately equal to 100 times the J variability index of Stetson (1996 PASP, 108, 851) computed for W1 and W2. int 4 percent    
rho12 catwise_2020, catwise_prelim WISE W1W2 correlation coefficient int 4 %    
rho12 wise_allskysc WISE The correlation coefficient between the W1 and W2 single-exposure flux measurements.
The value is a signed 2-digit integer, expressed as a percentage. Negative values indicate anticorrelation.
smallint 2 % -9999  
rho23 allwise_sc WISE The correlation coefficient between the W2 and W3 single-exposure flux measurements. The value is a signed 2-digit integer, expressed as a percentage. Negative values indicate anticorrelation. rho23 is approximately equal to 100 times the J variability index of Stetson (1996 PASP, 108, 851) computed for W2 and W3. int 4 percent    
rho23 wise_allskysc WISE The correlation coefficient between the W2 and W4 single-exposure flux measurements.
The value is a signed 2-digit integer, expressed as a percentage. Negative values indicate anticorrelation.
smallint 2 % -9999  
rho34 allwise_sc WISE The correlation coefficient between the W3 and W4 single-exposure flux measurements. The value is a signed 2-digit integer, expressed as a percentage. Negative values indicate anticorrelation. rho34 is approximately equal to 100 times the J variability index of Stetson (1996 PASP, 108, 851) computed for W3 and W4. int 4 percent    
rho34 wise_allskysc WISE The correlation coefficient between the W3 and W4 single-exposure flux measurements.
The value is a signed 2-digit integer, expressed as a percentage. Negative values indicate anticorrelation.
smallint 2 % -9999  
rKronMag atlasSource ATLASDR4 Extended source R mag (Kron) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rKronMag atlasSource ATLASDR5 Extended source R mag (Kron) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rKronMag atlasSource ATLASv20180209 Extended source R mag (Kron) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rKronMagErr atlasSource ATLASDR4 Error in extended source R mag (Kron) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rKronMagErr atlasSource ATLASDR5 Error in extended source R mag (Kron) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rKronMagErr atlasSource ATLASv20180209 Error in extended source R mag (Kron) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rl rosat_fsc ROSAT reliability of source detection (0...99) tinyint 1     stat.fit.goodness
Rmag denisDR3Source DENIS R magnitude of USNOA2.0 nearest match float 8 mag    
rmfID atlasMergeLog ATLASDR1 the UID of the relevant R multiframe bigint 8     obs.field
rmfID atlasMergeLog ATLASDR2 the UID of the relevant R multiframe bigint 8     obs.field
rmfID atlasMergeLog ATLASDR3 the UID of the relevant R multiframe bigint 8     meta.id;obs.field;em.opt.R
rmfID atlasMergeLog ATLASDR4 the UID of the relevant R multiframe bigint 8     meta.id;obs.field;em.opt.R
rmfID atlasMergeLog ATLASDR5 the UID of the relevant R multiframe bigint 8     meta.id;obs.field;em.opt.R
rmfID atlasMergeLog ATLASv20131127 the UID of the relevant R multiframe bigint 8     obs.field
rmfID atlasMergeLog ATLASv20160425 the UID of the relevant R multiframe bigint 8     meta.id;obs.field;em.opt.R
rmfID atlasMergeLog ATLASv20180209 the UID of the relevant R multiframe bigint 8     meta.id;obs.field;em.opt.R
rmiExt atlasSource ATLASDR1 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 PHOT_COLOR
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExt atlasSource ATLASDR2 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 PHOT_COLOR
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExt atlasSource ATLASDR3 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExt atlasSource ATLASDR4 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExt atlasSource ATLASDR5 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExt atlasSource ATLASv20131127 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 PHOT_COLOR
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExt atlasSource ATLASv20160425 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExt atlasSource ATLASv20180209 Extended source colour R-I (using aperMagNoAperCorr3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASDR1 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASDR2 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASDR3 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASDR4 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASDR5 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASv20131127 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASv20160425 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiExtErr atlasSource ATLASv20180209 Error on extended source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASDR1 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 PHOT_COLOR
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASDR2 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 PHOT_COLOR
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASDR3 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASDR4 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASDR5 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASv20131127 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 PHOT_COLOR
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASv20160425 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPnt atlasSource ATLASv20180209 Point source colour R-I (using aperMag3) real 4 mag -0.9999995e9 phot.color;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASDR1 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASDR2 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASDR3 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASDR4 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASDR5 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASv20131127 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASv20160425 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rmiPntErr atlasSource ATLASv20180209 Error on point source colour R-I real 4 mag -0.9999995e9 stat.error;em.opt.R;em.opt.I
Default colours from pairs of adjacent passbands within a given set (e.g. Y-J, J-H and H-K for YJHK) are recorded in the merged source table for ease of querying and speedy querying via indexing of these attributes. Presently, the point-source colours and extended source colours are computed from the aperture corrected AperMag3 fixed 2 arcsec aperture diameter measures (for consistent measurement across all passbands) and generally good signal-to-noise. At some point in the future, this may be changed such that point-source colours will be computed from the PSF-fitted measures and extended source colours computed from the 2-d Sersic model profile fits.
rMjd atlasSource ATLASDR3 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch
rMjd atlasSource ATLASDR4 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch;em.opt.R
rMjd atlasSource ATLASDR5 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch;em.opt.R
rMjd atlasSource ATLASv20160425 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch
rMjd atlasSource ATLASv20180209 The mean Modified Julian Day of each detection float 8 day -0.9999995e9 time.epoch;em.opt.R
rms first08Jul16Source, firstSource, firstSource12Feb16 FIRST local noise estimate at the source position real 4 mJy   instr.det.noise
rolledBack ArchiveCurationHistory ATLASDR1 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory ATLASDR2 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory ATLASDR3 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory ATLASDR4 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory ATLASDR5 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory ATLASv20131127 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory ATLASv20160425 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory ATLASv20180209 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory VPHASDR3 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory VPHASv20160112 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rolledBack ArchiveCurationHistory VPHASv20170222 Flag for roll-back of this event: 0=no, 1 = yes tinyint 1     ??
rot_flag aux_qso_icrf2_match GAIADR1 Flag indicating how this source was used to fix the orientation of the reference frame of the Gaia DR1 solution int 4     meta.code
rp_mag_zero_oint_error ext_phot_zero_point GAIADR1 Uncertainty on RP magnitude zero point float 8 mag   stat.error;phot.mag;arith.zp
rp_mag_zero_point ext_phot_zero_point GAIADR1 RP magnitude zero point float 8 mag   phot.mag;arith.zp
rPA atlasSource ATLASDR1 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng
rPA atlasSource ATLASDR2 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng
rPA atlasSource ATLASDR3 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng;em.opt.R
rPA atlasSource ATLASDR4 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng;em.opt.R
rPA atlasSource ATLASDR5 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng;em.opt.R
rPA atlasSource ATLASv20131127 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng
rPA atlasSource ATLASv20160425 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng;em.opt.R
rPA atlasSource ATLASv20180209 ellipse fit celestial orientation in R real 4 Degrees -0.9999995e9 pos.posAng;em.opt.R
rPetroMag atlasSource ATLASDR1 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag
rPetroMag atlasSource ATLASDR2 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag
rPetroMag atlasSource ATLASDR3 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rPetroMag atlasSource ATLASDR4 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rPetroMag atlasSource ATLASDR5 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rPetroMag atlasSource ATLASv20131127 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag
rPetroMag atlasSource ATLASv20160425 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rPetroMag atlasSource ATLASv20180209 Extended source R mag (Petrosian) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rPetroMagErr atlasSource ATLASDR1 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error
rPetroMagErr atlasSource ATLASDR2 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error
rPetroMagErr atlasSource ATLASDR3 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rPetroMagErr atlasSource ATLASDR4 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rPetroMagErr atlasSource ATLASDR5 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rPetroMagErr atlasSource ATLASv20131127 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error
rPetroMagErr atlasSource ATLASv20160425 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rPetroMagErr atlasSource ATLASv20180209 Error in extended source R mag (Petrosian) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rpmag_APASSDR9 ravedr5Source RAVE r' magnitude from APASSDR9 real 4 mag   phot.mag;em.opt
rppErrBits atlasSource ATLASDR1 additional WFAU post-processing error bits in R int 4   0 meta.code
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rppErrBits atlasSource ATLASDR2 additional WFAU post-processing error bits in R int 4   0 meta.code
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rppErrBits atlasSource ATLASDR3 additional WFAU post-processing error bits in R int 4   0 meta.code;em.opt.R
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rppErrBits atlasSource ATLASDR4 additional WFAU post-processing error bits in R int 4   0 meta.code;em.opt.R
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rppErrBits atlasSource ATLASDR5 additional WFAU post-processing error bits in R int 4   0 meta.code;em.opt.R
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rppErrBits atlasSource ATLASv20131127 additional WFAU post-processing error bits in R int 4   0 meta.code
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rppErrBits atlasSource ATLASv20160425 additional WFAU post-processing error bits in R int 4   0 meta.code;em.opt.R
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rppErrBits atlasSource ATLASv20180209 additional WFAU post-processing error bits in R int 4   0 meta.code;em.opt.R
Post-processing error quality bit flags assigned to detections in the archive curation procedure for survey data. From least to most significant byte in the 4-byte integer attribute byte 0 (bits 0 to 7) corresponds to information on generally innocuous conditions that are nonetheless potentially significant as regards the integrity of that detection; byte 1 (bits 8 to 15) corresponds to warnings; byte 2 (bits 16 to 23) corresponds to important warnings; and finally byte 3 (bits 24 to 31) corresponds to severe warnings:
ByteBitDetection quality issue Threshold or bit mask Applies to
DecimalHexadecimal
0 4 Deblended 16 0x00000010 All VDFS catalogues
0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues
0 7 Low confidence in default aperture 128 0x00000080 All VDFS catalogues
1 12 Lies within detector 16 region of a tile 4096 0x00001000 All catalogues from tiles
2 16 Close to saturated 65536 0x00010000 All VDFS catalogues
2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 VVV only
2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All catalogues
2 23 Lies within the underexposed strip (or "ear") of a tile 8388608 0x00800000 All catalogues from tiles
3 24 Lies within an underexposed region of a tile due to missing detector 16777216 0x01000000 All catalogues from tiles

In this way, the higher the error quality bit flag value, the more likely it is that the detection is spurious. The decimal threshold (column 4) gives the minimum value of the quality flag for a detection having the given condition (since other bits in the flag may be set also; the corresponding hexadecimal value, where each digit corresponds to 4 bits in the flag, can be easier to compute when writing SQL queries to test for a given condition). For example, to exclude all Ks band sources in the VHS having any error quality condition other than informational ones, include a predicate ... AND kppErrBits ≤ 255. See the SQL Cookbook and other online pages for further information.
rPsfMag atlasSource ATLASDR1 Point source profile-fitted R mag real 4 mag -0.9999995e9 phot.mag
rPsfMag atlasSource ATLASDR2 Point source profile-fitted R mag real 4 mag -0.9999995e9 phot.mag
rPsfMag atlasSource ATLASDR3 Point source profile-fitted R mag real 4 mag -0.9999995e9 phot.mag;em.opt.R
rPsfMag atlasSource ATLASv20131127 Point source profile-fitted R mag real 4 mag -0.9999995e9 phot.mag
rPsfMag atlasSource ATLASv20160425 Point source profile-fitted R mag real 4 mag -0.9999995e9 phot.mag;em.opt.R
rPsfMagErr atlasSource ATLASDR1 Error in point source profile-fitted R mag real 4 mag -0.9999995e9 stat.error
rPsfMagErr atlasSource ATLASDR2 Error in point source profile-fitted R mag real 4 mag -0.9999995e9 stat.error
rPsfMagErr atlasSource ATLASDR3 Error in point source profile-fitted R mag real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rPsfMagErr atlasSource ATLASv20131127 Error in point source profile-fitted R mag real 4 mag -0.9999995e9 stat.error
rPsfMagErr atlasSource ATLASv20160425 Error in point source profile-fitted R mag real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rSeqNum atlasSource ATLASDR1 the running number of the R detection int 4   -99999999 meta.id
rSeqNum atlasSource ATLASDR2 the running number of the R detection int 4   -99999999 meta.id
rSeqNum atlasSource ATLASDR3 the running number of the R detection int 4   -99999999 meta.number;em.opt.R
rSeqNum atlasSource ATLASDR4 the running number of the R detection int 4   -99999999 meta.number;em.opt.R
rSeqNum atlasSource ATLASDR5 the running number of the R detection int 4   -99999999 meta.id;em.opt.R
rSeqNum atlasSource ATLASv20131127 the running number of the R detection int 4   -99999999 meta.id
rSeqNum atlasSource ATLASv20160425 the running number of the R detection int 4   -99999999 meta.number;em.opt.R
rSeqNum atlasSource ATLASv20180209 the running number of the R detection int 4   -99999999 meta.number;em.opt.R
rSerMag2D atlasSource ATLASDR1 Extended source R mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag
rSerMag2D atlasSource ATLASDR2 Extended source R mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag
rSerMag2D atlasSource ATLASDR3 Extended source R mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rSerMag2D atlasSource ATLASv20131127 Extended source R mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag
rSerMag2D atlasSource ATLASv20160425 Extended source R mag (profile-fitted) real 4 mag -0.9999995e9 phot.mag;em.opt.R
rSerMag2DErr atlasSource ATLASDR1 Error in extended source R mag (profile-fitted) real 4 mag -0.9999995e9 stat.error
rSerMag2DErr atlasSource ATLASDR2 Error in extended source R mag (profile-fitted) real 4 mag -0.9999995e9 stat.error
rSerMag2DErr atlasSource ATLASDR3 Error in extended source R mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rSerMag2DErr atlasSource ATLASv20131127 Error in extended source R mag (profile-fitted) real 4 mag -0.9999995e9 stat.error
rSerMag2DErr atlasSource ATLASv20160425 Error in extended source R mag (profile-fitted) real 4 mag -0.9999995e9 stat.error;phot.mag;em.opt.R
rv_nb_transits gaia_source GAIADR2 Number of transits used to compute the radial velocity int 4     meta.number
rv_template_fe_h gaia_source GAIADR2 Fe/H of the template used to compute radial velocity real 4 dex   stat.fit.param
rv_template_logg gaia_source GAIADR2 log g of the template used to compute the radial velocity real 4 log cgs   stat.fit.param
rv_template_teff gaia_source GAIADR2 Teff of the template used to compute radial velocity real 4 K   stat.fit.param
rXi atlasSource ATLASDR1 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rXi atlasSource ATLASDR2 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rXi atlasSource ATLASDR3 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rXi atlasSource ATLASDR4 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rXi atlasSource ATLASDR5 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rXi atlasSource ATLASv20131127 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rXi atlasSource ATLASv20160425 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.
rXi atlasSource ATLASv20180209 Offset of R detection from master position (+east/-west) real 4 arcsec -0.9999995e9 pos.eq.ra;arith.diff;em.opt.R
When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 1.0 arcseconds is used. Such a large association criterion can of course lead to spurious pairings in the merged sources lists (although note that between passband pairs, handshake pairing is done: both passbands must agree that the candidate pair is their nearest neighbour for the pair to propagate through into the merged source table). In order to help filter spurious pairings out, and assuming that large positional offsets between the different passband detections are not expected (e.g. because of source motion, or larger than usual positional uncertainties) then the attributes Xi and Eta can be used to filter any pairings with suspiciously large offsets in one or more bands. For example, for a clean sample of QSOs from the VHS, you might wish to insist that the offsets in the selected sample are all below 0.5 arcsecond: simply add WHERE clauses into the SQL sample selection script to exclude all Xi and Eta values larger than the threshold you want. NB: the master position is the position of the detection in the shortest passband in the set, rather than the ra/dec of the source as stored in source attributes of the same name. The former is used in the pairing process, while the latter is generally the optimally weighted mean position from an astrometric solution or other combinatorial process of all individual detection positions across the available passbands.



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27/06/2023