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Glossary of WSA attributes
This Glossary alphabetically lists all attributes used in the UKIDSSDR11 database(s) held in the WSA. If you would like to have more information about the schema tables please use the UKIDSSDR11 Schema Browser (other Browser versions).

A

B

C

D

E

F

G

H

I

J

K

L

M

N

O

P

Q

R

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T

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V

W

X

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Z

J
Name	Schema Table	Database	Description	Type	Length	Unit	Default Value	Unified Content Descriptor
j_1AperMag3	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Default point source J_1 aperture corrected mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
j_1AperMag3	lasSource	WSA	Default point source J_1 aperture corrected mag (2.0 arcsec aperture diameter) If in doubt use this flux estimator	real	4	mag	-0.9999995e9	PHOT_MAG
j_1AperMag3Err	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in default point source J_1 mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
j_1AperMag4	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Point source J_1 aperture corrected mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
j_1AperMag4Err	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in point source J_1 mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
j_1AperMag6	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Point source J_1 aperture corrected mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
j_1AperMag6Err	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in point source J_1 mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
j_1Class	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	discrete image classification flag in J_1	smallint	2		-9999	CLASS_MISC
j_1ClassStat	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	N(0,1) stellarness-of-profile statistic in J_1	real	4		-0.9999995e9	STAT_PROP
j_1Deblend	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	placeholder flag indicating parent/child relation in J_1	int	4		-99999999	CODE_MISC
j_1Deblend	lasSource	WSA	placeholder flag indicating parent/child relation in J_1	int	4		-99999999	CODE_MISC
			This CASU pipeline processing source extraction flag is a placeholder only, and is always set to zero in all passbands in the merged source lists. If you need to know when a particular image detection is a component of a deblend or not, test bit 4 of attribute ppErrBits (see corresponding glossary entry) which is set by WFAU's post-processing software based on testing the areal profiles aprof2-8 (these are set by CASU to -1 for deblended components, or positive values for non-deblended detections). We encode this in an information bit of ppErrBits for convenience when querying the merged source tables.
j_1Ell	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	1-b/a, where a/b=semi-major/minor axes in J_1	real	4		-0.9999995e9	PHYS_ELLIPTICITY
j_1eNum	lasMergeLog, lasYJHKmergeLog	WSA	the extension number of this J_1 frame	tinyint	1			NUMBER
j_1ErrBits	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	processing warning/error bitwise flags in J_1	int	4		-99999999	CODE_MISC
j_1ErrBits	lasSource	WSA	processing warning/error bitwise flags in J_1	int	4		-99999999	CODE_MISC
			Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
j_1Eta	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Offset of J_1 detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
j_1Eta	lasSource	WSA	Offset of J_1 detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
j_1Gausig	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	RMS of axes of ellipse fit in J_1	real	4	pixels	-0.9999995e9	MORPH_PARAM
j_1HallMag	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Total point source J_1 mag	real	4	mag	-0.9999995e9	PHOT_MAG
j_1HallMagErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in total point source J_1 mag	real	4	mag	-0.9999995e9	ERROR
j_1mfID	lasMergeLog, lasYJHKmergeLog	WSA	the UID of the relevant J_1 multiframe	bigint	8			ID_FRAME
j_1mhExt	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Extended source colour J_1-H (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
j_1mhExt	lasSource	WSA	Extended source colour J_1-H (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.
j_1mhExtErr	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Error on extended source colour J_1-H	real	4	mag	-0.9999995e9	ERROR
j_1mhExtErr	lasSource	WSA	Error on extended source colour J_1-H	real	4	mag	-0.9999995e9	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.
j_1mhPnt	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Point source colour J_1-H (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
j_1mhPnt	lasSource	WSA	Point source colour J_1-H (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.
j_1mhPntErr	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Error on point source colour J_1-H	real	4	mag	-0.9999995e9	ERROR
j_1mhPntErr	lasSource	WSA	Error on point source colour J_1-H	real	4	mag	-0.9999995e9	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.
j_1PA	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	ellipse fit celestial orientation in J_1	real	4	Degrees	-0.9999995e9	POS_POS-ANG
j_1PetroMag	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Extended source J_1 mag (Petrosian)	real	4	mag	-0.9999995e9	PHOT_MAG
j_1PetroMagErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in extended source J_1 mag (Petrosian)	real	4	mag	-0.9999995e9	ERROR
j_1ppErrBits	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	additional WFAU post-processing error bits in J_1	int	4		0	CODE_MISC
j_1ppErrBits	lasSource	WSA	additional WFAU post-processing error bits in J_1	int	4		0	CODE_MISC
			Post-processing error quality bit flags assigned (NB: from UKIDSS DR2 release onwards) in the WSA 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: Byte Bit Detection quality issue Threshold or bit mask Applies to Decimal Hexadecimal 0 4 Deblended 16 0x00000010 All VDFS catalogues 0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues 1 15 Source in poor flat field region 32768 0x00008000 All but mosaics 2 16 Close to saturated 65536 0x00010000 All VDFS catalogues (though deeps excluded prior to DR8) 2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 GPS only 2 19 Possible crosstalk artefact/contamination 524288 0x00080000 All but GPS 2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All but mosaics 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 K band sources in the LAS 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.
j_1PsfMag	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Point source profile-fitted J_1 mag	real	4	mag	-0.9999995e9	PHOT_MAG
j_1PsfMagErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in point source profile-fitted J_1 mag	real	4	mag	-0.9999995e9	ERROR
j_1SeqNum	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	the running number of the J_1 detection	int	4		-99999999	ID_NUMBER
j_1SerMag2D	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Extended source J_1 mag (profile-fitted)	real	4	mag	-0.9999995e9	PHOT_MAG
j_1SerMag2DErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in extended source J_1 mag (profile-fitted)	real	4	mag	-0.9999995e9	ERROR
j_1Xi	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Offset of J_1 detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
j_1Xi	lasSource	WSA	Offset of J_1 detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
j_2AperMag3	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Default point source J_2 aperture corrected mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
j_2AperMag3	lasSource	WSA	Default point source J_2 aperture corrected mag (2.0 arcsec aperture diameter) If in doubt use this flux estimator	real	4	mag	-0.9999995e9	PHOT_MAG
j_2AperMag3Err	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in default point source J_2 mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
j_2AperMag4	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Point source J_2 aperture corrected mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
j_2AperMag4Err	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in point source J_2 mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
j_2AperMag6	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Point source J_2 aperture corrected mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
j_2AperMag6Err	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in point source J_2 mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
j_2Class	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	discrete image classification flag in J_2	smallint	2		-9999	CLASS_MISC
j_2ClassStat	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	N(0,1) stellarness-of-profile statistic in J_2	real	4		-0.9999995e9	STAT_PROP
j_2Deblend	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	placeholder flag indicating parent/child relation in J_2	int	4		-99999999	CODE_MISC
j_2Deblend	lasSource	WSA	placeholder flag indicating parent/child relation in J_2	int	4		-99999999	CODE_MISC
			This CASU pipeline processing source extraction flag is a placeholder only, and is always set to zero in all passbands in the merged source lists. If you need to know when a particular image detection is a component of a deblend or not, test bit 4 of attribute ppErrBits (see corresponding glossary entry) which is set by WFAU's post-processing software based on testing the areal profiles aprof2-8 (these are set by CASU to -1 for deblended components, or positive values for non-deblended detections). We encode this in an information bit of ppErrBits for convenience when querying the merged source tables.
j_2Ell	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	1-b/a, where a/b=semi-major/minor axes in J_2	real	4		-0.9999995e9	PHYS_ELLIPTICITY
j_2eNum	lasMergeLog, lasYJHKmergeLog	WSA	the extension number of this J_2 frame	tinyint	1			NUMBER
j_2ErrBits	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	processing warning/error bitwise flags in J_2	int	4		-99999999	CODE_MISC
j_2ErrBits	lasSource	WSA	processing warning/error bitwise flags in J_2	int	4		-99999999	CODE_MISC
			Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
j_2Eta	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Offset of J_2 detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
j_2Eta	lasSource	WSA	Offset of J_2 detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
j_2Gausig	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	RMS of axes of ellipse fit in J_2	real	4	pixels	-0.9999995e9	MORPH_PARAM
j_2HallMag	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Total point source J_2 mag	real	4	mag	-0.9999995e9	PHOT_MAG
j_2HallMagErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in total point source J_2 mag	real	4	mag	-0.9999995e9	ERROR
j_2mfID	lasMergeLog, lasYJHKmergeLog	WSA	the UID of the relevant J_2 multiframe	bigint	8			ID_FRAME
j_2mhExt	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Extended source colour J_2-H (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
j_2mhExt	lasSource	WSA	Extended source colour J_2-H (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.
j_2mhExtErr	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Error on extended source colour J_2-H	real	4	mag	-0.9999995e9	ERROR
j_2mhExtErr	lasSource	WSA	Error on extended source colour J_2-H	real	4	mag	-0.9999995e9	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.
j_2mhPnt	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Point source colour J_2-H (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
j_2mhPnt	lasSource	WSA	Point source colour J_2-H (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.
j_2mhPntErr	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Error on point source colour J_2-H	real	4	mag	-0.9999995e9	ERROR
j_2mhPntErr	lasSource	WSA	Error on point source colour J_2-H	real	4	mag	-0.9999995e9	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.
j_2mrat	twomass_scn	2MASS	J-band average 2nd image moment ratio.	real	4			FIT_PARAM_VALUE
j_2mrat	twomass_sixx2_scn	2MASS	J band average 2nd image moment ratio for scan	real	4
j_2PA	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	ellipse fit celestial orientation in J_2	real	4	Degrees	-0.9999995e9	POS_POS-ANG
j_2PetroMag	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Extended source J_2 mag (Petrosian)	real	4	mag	-0.9999995e9	PHOT_MAG
j_2PetroMagErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in extended source J_2 mag (Petrosian)	real	4	mag	-0.9999995e9	ERROR
j_2ppErrBits	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	additional WFAU post-processing error bits in J_2	int	4		0	CODE_MISC
j_2ppErrBits	lasSource	WSA	additional WFAU post-processing error bits in J_2	int	4		0	CODE_MISC
			Post-processing error quality bit flags assigned (NB: from UKIDSS DR2 release onwards) in the WSA 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: Byte Bit Detection quality issue Threshold or bit mask Applies to Decimal Hexadecimal 0 4 Deblended 16 0x00000010 All VDFS catalogues 0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues 1 15 Source in poor flat field region 32768 0x00008000 All but mosaics 2 16 Close to saturated 65536 0x00010000 All VDFS catalogues (though deeps excluded prior to DR8) 2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 GPS only 2 19 Possible crosstalk artefact/contamination 524288 0x00080000 All but GPS 2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All but mosaics 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 K band sources in the LAS 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.
j_2PsfMag	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Point source profile-fitted J_2 mag	real	4	mag	-0.9999995e9	PHOT_MAG
j_2PsfMagErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in point source profile-fitted J_2 mag	real	4	mag	-0.9999995e9	ERROR
j_2SeqNum	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	the running number of the J_2 detection	int	4		-99999999	ID_NUMBER
j_2SerMag2D	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Extended source J_2 mag (profile-fitted)	real	4	mag	-0.9999995e9	PHOT_MAG
j_2SerMag2DErr	lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableLasPointSource	WSA	Error in extended source J_2 mag (profile-fitted)	real	4	mag	-0.9999995e9	ERROR
j_2Xi	lasExtendedSource, lasPointSource, lasYJHKsource, reliableLasPointSource	WSA	Offset of J_2 detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
j_2Xi	lasSource	WSA	Offset of J_2 detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
j_5sig_ba	twomass_xsc	2MASS	J minor/major axis ratio fit to the 5-sigma isophote.	real	4			PHYS_AXIS-RATIO
j_5sig_phi	twomass_xsc	2MASS	J angle to 5-sigma major axis (E of N).	smallint	2	degrees		ERROR
j_5surf	twomass_xsc	2MASS	J central surface brightness (r<=5).	real	4	mag		PHOT_SB_GENERAL
j_ba	twomass_xsc	2MASS	J minor/major axis ratio fit to the 3-sigma isophote.	real	4			PHYS_AXIS-RATIO
j_back	twomass_xsc	2MASS	J coadd median background.	real	4			CODE_MISC
j_bisym_chi	twomass_xsc	2MASS	J bi-symmetric cross-correlation chi.	real	4			FIT_PARAM_VALUE
j_bisym_rat	twomass_xsc	2MASS	J bi-symmetric flux ratio.	real	4			PHOT_FLUX_RATIO
j_bndg_amp	twomass_xsc	2MASS	J banding maximum FT amplitude on this side of coadd.	real	4	DN		FIT_PARAM_VALUE
j_bndg_per	twomass_xsc	2MASS	J banding Fourier Transf. period on this side of coadd.	int	4	arcsec		FIT_PARAM_VALUE
j_chif_ellf	twomass_xsc	2MASS	J % chi-fraction for elliptical fit to 3-sig isophote.	real	4			FIT_PARAM_VALUE
j_cmsig	twomass_psc	2MASS	Corrected photometric uncertainty for the default J-band magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_con_indx	twomass_xsc	2MASS	J concentration index r_75%/r_25%.	real	4			PHYS_CONCENT_INDEX
j_d_area	twomass_xsc	2MASS	J 5-sigma to 3-sigma differential area.	smallint	2			FIT_RESIDUAL
j_flg_10	twomass_xsc	2MASS	J confusion flag for 10 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_15	twomass_xsc	2MASS	J confusion flag for 15 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_20	twomass_xsc	2MASS	J confusion flag for 20 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_25	twomass_xsc	2MASS	J confusion flag for 25 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_30	twomass_xsc	2MASS	J confusion flag for 30 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_40	twomass_xsc	2MASS	J confusion flag for 40 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_5	twomass_xsc	2MASS	J confusion flag for 5 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_50	twomass_xsc	2MASS	J confusion flag for 50 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_60	twomass_xsc	2MASS	J confusion flag for 60 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_7	twomass_sixx2_xsc	2MASS	J confusion flag for 7 arcsec circular ap. mag	smallint	2
j_flg_7	twomass_xsc	2MASS	J confusion flag for 7 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_70	twomass_xsc	2MASS	J confusion flag for 70 arcsec circular ap. mag.	smallint	2			CODE_MISC
j_flg_c	twomass_xsc	2MASS	J confusion flag for Kron circular mag.	smallint	2			CODE_MISC
j_flg_e	twomass_xsc	2MASS	J confusion flag for Kron elliptical mag.	smallint	2			CODE_MISC
j_flg_fc	twomass_xsc	2MASS	J confusion flag for fiducial Kron circ. mag.	smallint	2			CODE_MISC
j_flg_fe	twomass_xsc	2MASS	J confusion flag for fiducial Kron ell. mag.	smallint	2			CODE_MISC
j_flg_i20c	twomass_xsc	2MASS	J confusion flag for 20mag/sq." iso. circ. mag.	smallint	2			CODE_MISC
j_flg_i20e	twomass_xsc	2MASS	J confusion flag for 20mag/sq." iso. ell. mag.	smallint	2			CODE_MISC
j_flg_i21c	twomass_xsc	2MASS	J confusion flag for 21mag/sq." iso. circ. mag.	smallint	2			CODE_MISC
j_flg_i21e	twomass_xsc	2MASS	J confusion flag for 21mag/sq." iso. ell. mag.	smallint	2			CODE_MISC
j_flg_j21fc	twomass_xsc	2MASS	J confusion flag for 21mag/sq." iso. fid. circ. mag.	smallint	2			CODE_MISC
j_flg_j21fe	twomass_xsc	2MASS	J confusion flag for 21mag/sq." iso. fid. ell. mag.	smallint	2			CODE_MISC
j_flg_k20fc	twomass_xsc	2MASS	J confusion flag for 20mag/sq." iso. fid. circ. mag.	smallint	2			CODE_MISC
j_flg_k20fe	twomass_sixx2_xsc	2MASS	J confusion flag for 20mag/sq.″ iso. fid. ell. mag	smallint	2
j_flg_k20fe	twomass_xsc	2MASS	J confusion flag for 20mag/sq." iso. fid. ell. mag.	smallint	2			CODE_MISC
j_h	twomass_sixx2_psc	2MASS	The J-H color, computed from the J-band and H-band magnitudes (j_m and h_m, respectively) of the source. In cases where the first or second digit in rd_flg is equal to either "0", "4", "6", or "9", no color is computed because the photometry in one or both bands is of lower quality or the source is not detected.	real	4
j_k	twomass_sixx2_psc	2MASS	The J-Ks color, computed from the J-band and Ks-band magnitudes (j_m and k_m, respectively) of the source. In cases where the first or third digit in rd_flg is equal to either "0", "4", "6", or "9", no color is computed because the photometry in one or both bands is of lower quality or the source is not detected.	real	4
j_m	twomass_psc	2MASS	Default J-band magnitude	real	4	mag		SPECT_FLUX_VALUE
j_m	twomass_sixx2_psc	2MASS	J selected "default" magnitude	real	4	mag
j_m_10	twomass_xsc	2MASS	J 10 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_15	twomass_xsc	2MASS	J 15 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_20	twomass_xsc	2MASS	J 20 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_25	twomass_xsc	2MASS	J 25 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_2mass	allwise_sc	WISE	2MASS J-band magnitude or magnitude upper limit of the associated 2MASS PSC source. This column is "null" if there is no associated 2MASS PSC source or if the 2MASS PSC J-band magnitude entry is "null".	float	8	mag
j_m_2mass	wise_allskysc	WISE	2MASS J-band magnitude or magnitude upper limit of the associated 2MASS PSC source. This column is default if there is no associated 2MASS PSC source or if the 2MASS PSC J-band magnitude entry is default.	real	4	mag	-0.9999995e9
j_m_2mass	wise_prelimsc	WISE	2MASS J-band magnitude or magnitude upper limit of the associated 2MASS PSC source This column is default if there is no associated 2MASS PSC source or if the 2MASS PSC J-band magnitude entry is default	real	4	mag	-0.9999995e9
j_m_30	twomass_xsc	2MASS	J 30 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_40	twomass_xsc	2MASS	J 40 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_5	twomass_xsc	2MASS	J 5 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_50	twomass_xsc	2MASS	J 50 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_60	twomass_xsc	2MASS	J 60 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_7	twomass_sixx2_xsc	2MASS	J 7 arcsec radius circular aperture magnitude	real	4	mag
j_m_7	twomass_xsc	2MASS	J 7 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_70	twomass_xsc	2MASS	J 70 arcsec radius circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_c	twomass_xsc	2MASS	J Kron circular aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_e	twomass_xsc	2MASS	J Kron elliptical aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_ext	twomass_sixx2_xsc	2MASS	J mag from fit extrapolation	real	4	mag
j_m_ext	twomass_xsc	2MASS	J mag from fit extrapolation.	real	4	mag		SPECT_FLUX_VALUE
j_m_fc	twomass_xsc	2MASS	J fiducial Kron circular magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_fe	twomass_xsc	2MASS	J fiducial Kron ell. mag aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_i20c	twomass_xsc	2MASS	J 20mag/sq." isophotal circular ap. magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_i20e	twomass_xsc	2MASS	J 20mag/sq." isophotal elliptical ap. magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_i21c	twomass_xsc	2MASS	J 21mag/sq." isophotal circular ap. magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_i21e	twomass_xsc	2MASS	J 21mag/sq." isophotal elliptical ap. magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_j21fc	twomass_xsc	2MASS	J 21mag/sq." isophotal fiducial circ. ap. mag.	real	4	mag		SPECT_FLUX_VALUE
j_m_j21fe	twomass_xsc	2MASS	J 21mag/sq." isophotal fiducial ell. ap. magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_k20fc	twomass_xsc	2MASS	J 20mag/sq." isophotal fiducial circ. ap. mag.	real	4	mag		SPECT_FLUX_VALUE
j_m_k20fe	twomass_sixx2_xsc	2MASS	J 20mag/sq.″ isophotal fiducial ell. ap. magnitude	real	4	mag
j_m_k20fe	twomass_xsc	2MASS	J 20mag/sq." isophotal fiducial ell. ap. magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_stdap	twomass_psc	2MASS	J-band "standard" aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_m_sys	twomass_xsc	2MASS	J system photometry magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_mnsurfb_eff	twomass_xsc	2MASS	J mean surface brightness at the half-light radius.	real	4	mag		PHOT_SB_GENERAL
j_msig	twomass_sixx2_psc	2MASS	J "default" mag uncertainty	real	4	mag
j_msig_10	twomass_xsc	2MASS	J 1-sigma uncertainty in 10 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_15	twomass_xsc	2MASS	J 1-sigma uncertainty in 15 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_20	twomass_xsc	2MASS	J 1-sigma uncertainty in 20 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_25	twomass_xsc	2MASS	J 1-sigma uncertainty in 25 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_2mass	allwise_sc	WISE	2MASS J-band corrected photometric uncertainty of the associated 2MASS PSC source. This column is "null" if there is no associated 2MASS PSC source or if the 2MASS PSC J-band uncertainty entry is "null".	float	8	mag
j_msig_2mass	wise_allskysc	WISE	2MASS J-band corrected photometric uncertainty of the associated 2MASS PSC source. This column is default if there is no associated 2MASS PSC source or if the 2MASS PSC J-band uncertainty entry is default.	real	4	mag	-0.9999995e9
j_msig_2mass	wise_prelimsc	WISE	2MASS J-band corrected photometric uncertainty of the associated 2MASS PSC source This column is default if there is no associated 2MASS PSC source or if the 2MASS PSC J-band uncertainty entry is default	real	4	mag	-0.9999995e9
j_msig_30	twomass_xsc	2MASS	J 1-sigma uncertainty in 30 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_40	twomass_xsc	2MASS	J 1-sigma uncertainty in 40 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_5	twomass_xsc	2MASS	J 1-sigma uncertainty in 5 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_50	twomass_xsc	2MASS	J 1-sigma uncertainty in 50 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_60	twomass_xsc	2MASS	J 1-sigma uncertainty in 60 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_7	twomass_sixx2_xsc	2MASS	J 1-sigma uncertainty in 7 arcsec circular ap. mag	real	4	mag
j_msig_7	twomass_xsc	2MASS	J 1-sigma uncertainty in 7 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_70	twomass_xsc	2MASS	J 1-sigma uncertainty in 70 arcsec circular ap. mag.	real	4	mag		ERROR
j_msig_c	twomass_xsc	2MASS	J 1-sigma uncertainty in Kron circular mag.	real	4	mag		ERROR
j_msig_e	twomass_xsc	2MASS	J 1-sigma uncertainty in Kron elliptical mag.	real	4	mag		ERROR
j_msig_ext	twomass_sixx2_xsc	2MASS	J 1-sigma uncertainty in mag from fit extrapolation	real	4	mag
j_msig_ext	twomass_xsc	2MASS	J 1-sigma uncertainty in mag from fit extrapolation.	real	4	mag		ERROR
j_msig_fc	twomass_xsc	2MASS	J 1-sigma uncertainty in fiducial Kron circ. mag.	real	4	mag		ERROR
j_msig_fe	twomass_xsc	2MASS	J 1-sigma uncertainty in fiducial Kron ell. mag.	real	4	mag		ERROR
j_msig_i20c	twomass_xsc	2MASS	J 1-sigma uncertainty in 20mag/sq." iso. circ. mag.	real	4	mag		ERROR
j_msig_i20e	twomass_xsc	2MASS	J 1-sigma uncertainty in 20mag/sq." iso. ell. mag.	real	4	mag		ERROR
j_msig_i21c	twomass_xsc	2MASS	J 1-sigma uncertainty in 21mag/sq." iso. circ. mag.	real	4	mag		ERROR
j_msig_i21e	twomass_xsc	2MASS	J 1-sigma uncertainty in 21mag/sq." iso. ell. mag.	real	4	mag		ERROR
j_msig_j21fc	twomass_xsc	2MASS	J 1-sigma uncertainty in 21mag/sq." iso.fid.circ.mag.	real	4	mag		ERROR
j_msig_j21fe	twomass_xsc	2MASS	J 1-sigma uncertainty in 21mag/sq." iso.fid.ell.mag.	real	4	mag		ERROR
j_msig_k20fc	twomass_xsc	2MASS	J 1-sigma uncertainty in 20mag/sq." iso.fid.circ. mag.	real	4	mag		ERROR
j_msig_k20fe	twomass_xsc	2MASS	J 1-sigma uncertainty in 20mag/sq." iso.fid.ell.mag.	real	4	mag		ERROR
j_msig_stdap	twomass_psc	2MASS	Uncertainty in the J-band standard aperture magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_msig_sys	twomass_xsc	2MASS	J 1-sigma uncertainty in system photometry mag.	real	4	mag		ERROR
j_msigcom	twomass_psc	2MASS	Combined, or total photometric uncertainty for the default J-band magnitude.	real	4	mag		SPECT_FLUX_VALUE
j_msigcom	twomass_sixx2_psc	2MASS	combined (total) J band photometric uncertainty	real	4	mag
j_msnr10	twomass_scn	2MASS	The estimated J-band magnitude at which SNR=10 is achieved for this scan.	real	4	mag		SPECT_FLUX_VALUE
j_msnr10	twomass_sixx2_scn	2MASS	J mag at which SNR=10 is achieved, from j_psp and j_zp_ap	real	4	mag
j_n_snr10	twomass_scn	2MASS	Number of point sources at J-band with SNR>10 (instrumental mag <=15.8)	int	4			NUMBER
j_n_snr10	twomass_sixx2_scn	2MASS	number of J point sources with SNR>10 (instrumental m<=15.8)	int	4
j_pchi	twomass_xsc	2MASS	J chi^2 of fit to rad. profile (LCSB: alpha scale len).	real	4			FIT_PARAM_VALUE
j_peak	twomass_xsc	2MASS	J peak pixel brightness.	real	4	mag		PHOT_SB_GENERAL
j_perc_darea	twomass_xsc	2MASS	J 5-sigma to 3-sigma percent area change.	smallint	2			FIT_PARAM
j_phi	twomass_xsc	2MASS	J angle to 3-sigma major axis (E of N).	smallint	2	degrees		POS_POS-ANG
j_psfchi	twomass_psc	2MASS	Reduced chi-squared goodness-of-fit value for the J-band profile-fit photometry made on the 1.3 s "Read_2" exposures.	real	4			FIT_PARAM_VALUE
j_psp	twomass_scn	2MASS	J-band photometric sensitivity paramater (PSP).	real	4			INST_SENSITIVITY
j_psp	twomass_sixx2_scn	2MASS	J photometric sensitivity param: j_shape_avg*(j_fbg_avg^.29)	real	4
j_pts_noise	twomass_scn	2MASS	Base-10 logarithm of the mode of the noise distribution for all point source detections in the scan, where the noise is estimated from the measured J-band photometric errors and is expressed in units of mJy.	real	4			INST_NOISE
j_pts_noise	twomass_sixx2_scn	2MASS	log10 of J band modal point src noise estimate	real	4	logmJy
j_r_c	twomass_xsc	2MASS	J Kron circular aperture radius.	real	4	arcsec		EXTENSION_RAD
j_r_e	twomass_xsc	2MASS	J Kron elliptical aperture semi-major axis.	real	4	arcsec		EXTENSION_RAD
j_r_eff	twomass_xsc	2MASS	J half-light (integrated half-flux point) radius.	real	4	arcsec		EXTENSION_RAD
j_r_i20c	twomass_xsc	2MASS	J 20mag/sq." isophotal circular aperture radius.	real	4	arcsec		EXTENSION_RAD
j_r_i20e	twomass_xsc	2MASS	J 20mag/sq." isophotal elliptical ap. semi-major axis.	real	4	arcsec		EXTENSION_RAD
j_r_i21c	twomass_xsc	2MASS	J 21mag/sq." isophotal circular aperture radius.	real	4	arcsec		EXTENSION_RAD
j_r_i21e	twomass_xsc	2MASS	J 21mag/sq." isophotal elliptical ap. semi-major axis.	real	4	arcsec		EXTENSION_RAD
j_resid_ann	twomass_xsc	2MASS	J residual annulus background median.	real	4	DN		CODE_MISC
j_sc_1mm	twomass_xsc	2MASS	J 1st moment (score) (LCSB: super blk 2,4,8 SNR).	real	4			CODE_MISC
j_sc_2mm	twomass_xsc	2MASS	J 2nd moment (score) (LCSB: SNRMAX - super SNR max).	real	4			CODE_MISC
j_sc_msh	twomass_xsc	2MASS	J median shape score.	real	4			CODE_MISC
j_sc_mxdn	twomass_xsc	2MASS	J mxdn (score) (LCSB: BSNR - block/smoothed SNR).	real	4			CODE_MISC
j_sc_r1	twomass_xsc	2MASS	J r1 (score).	real	4			CODE_MISC
j_sc_r23	twomass_xsc	2MASS	J r23 (score) (LCSB: TSNR - integrated SNR for r=15).	real	4			CODE_MISC
j_sc_sh	twomass_xsc	2MASS	J shape (score).	real	4			CODE_MISC
j_sc_vint	twomass_xsc	2MASS	J vint (score).	real	4			CODE_MISC
j_sc_wsh	twomass_xsc	2MASS	J wsh (score) (LCSB: PSNR - peak raw SNR).	real	4			CODE_MISC
j_seetrack	twomass_xsc	2MASS	J band seetracking score.	real	4			CODE_MISC
j_sh0	twomass_xsc	2MASS	J ridge shape (LCSB: BSNR limit).	real	4			FIT_PARAM
j_shape_avg	twomass_scn	2MASS	J-band average seeing shape for scan.	real	4			INST_SEEING
j_shape_avg	twomass_sixx2_scn	2MASS	J band average seeing shape for scan	real	4
j_shape_rms	twomass_scn	2MASS	RMS-error of J-band average seeing shape.	real	4			INST_SEEING
j_shape_rms	twomass_sixx2_scn	2MASS	rms of J band avg seeing shape for scan	real	4
j_sig_sh0	twomass_xsc	2MASS	J ridge shape sigma (LCSB: B2SNR limit).	real	4			FIT_PARAM
j_snr	twomass_psc	2MASS	J-band "scan" signal-to-noise ratio.	real	4	mag		INST_NOISE
j_snr	twomass_sixx2_psc	2MASS	J band "scan" signal-to-noise ratio	real	4
j_subst2	twomass_xsc	2MASS	J residual background #2 (score).	real	4			CODE_MISC
j_zp_ap	twomass_scn	2MASS	Photometric zero-point for J-band aperture photometry.	real	4	mag		PHOT_ZP
j_zp_ap	twomass_sixx2_scn	2MASS	J band ap. calibration photometric zero-point for scan	real	4	mag
jAperJky3	lasYselJSourceRemeasurement	WSA	Default point source J aperture corrected (2.0 arcsec aperture diameter) calibrated flux If in doubt use this flux estimator	real	4	jansky	-0.9999995e9	phot.flux
jAperJky3Err	lasYselJSourceRemeasurement	WSA	Error in default point/extended source J (2.0 arcsec aperture diameter) calibrated flux	real	4	jansky	-0.9999995e9	stat.error
jAperJky4	lasYselJSourceRemeasurement	WSA	Point source J aperture corrected (2.8 arcsec aperture diameter) calibrated flux	real	4	jansky	-0.9999995e9	phot.flux
jAperJky4Err	lasYselJSourceRemeasurement	WSA	Error in point/extended source J (2.8 arcsec aperture diameter) calibrated flux	real	4	jansky	-0.9999995e9	stat.error
jAperJky6	lasYselJSourceRemeasurement	WSA	Point source J aperture corrected (5.7 arcsec aperture diameter) calibrated flux	real	4	jansky	-0.9999995e9	phot.flux
jAperJky6Err	lasYselJSourceRemeasurement	WSA	Error in point/extended source J (5.7 arcsec aperture diameter) calibrated flux	real	4	jansky	-0.9999995e9	stat.error
jAperJkyNoAperCorr3	lasYselJSourceRemeasurement	WSA	Default extended source J (2.0 arcsec aperture diameter, but no aperture correction applied) aperture calibrated flux If in doubt use this flux estimator	real	4	jansky	-0.9999995e9	phot.flux
jAperJkyNoAperCorr4	lasYselJSourceRemeasurement	WSA	Extended source J (2.8 arcsec aperture diameter, but no aperture correction applied) aperture calibrated flux	real	4	jansky	-0.9999995e9	phot.flux
jAperJkyNoAperCorr6	lasYselJSourceRemeasurement	WSA	Extended source J (5.7 arcsec aperture diameter, but no aperture correction applied) aperture calibrated flux	real	4	jansky	-0.9999995e9	phot.flux
jAperLup3	lasYselJSourceRemeasurement	WSA	Default point source J aperture corrected (2.0 arcsec aperture diameter) luptitude If in doubt use this flux estimator	real	4	lup	-0.9999995e9	phot.lup
jAperLup3Err	lasYselJSourceRemeasurement	WSA	Error in default point/extended source J (2.0 arcsec aperture diameter) luptitude	real	4	lup	-0.9999995e9	stat.error
jAperLup4	lasYselJSourceRemeasurement	WSA	Point source J aperture corrected (2.8 arcsec aperture diameter) luptitude	real	4	lup	-0.9999995e9	phot.lup
jAperLup4Err	lasYselJSourceRemeasurement	WSA	Error in point/extended source J (2.8 arcsec aperture diameter) luptitude	real	4	lup	-0.9999995e9	stat.error
jAperLup6	lasYselJSourceRemeasurement	WSA	Point source J aperture corrected (5.7 arcsec aperture diameter) luptitude	real	4	lup	-0.9999995e9	phot.lup
jAperLup6Err	lasYselJSourceRemeasurement	WSA	Error in point/extended source J (5.7 arcsec aperture diameter) luptitude	real	4	lup	-0.9999995e9	stat.error
jAperLupNoAperCorr3	lasYselJSourceRemeasurement	WSA	Default extended source J (2.0 arcsec aperture diameter, but no aperture correction applied) aperture luptitude If in doubt use this flux estimator	real	4	lup	-0.9999995e9	phot.lup
jAperLupNoAperCorr4	lasYselJSourceRemeasurement	WSA	Extended source J (2.8 arcsec aperture diameter, but no aperture correction applied) aperture luptitude	real	4	lup	-0.9999995e9	phot.lup
jAperLupNoAperCorr6	lasYselJSourceRemeasurement	WSA	Extended source J (5.7 arcsec aperture diameter, but no aperture correction applied) aperture luptitude	real	4	lup	-0.9999995e9	phot.lup
jAperMag1	calSynopticSource	WSACalib	Extended source J aperture corrected mag (1.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag1	gpsJHKsource, gpsPointSource, reliableGpsPointSource	WSA	Default point source J aperture corrected mag (1.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag1	gpsSource	WSA	Default point source J aperture corrected mag (1.0 arcsec aperture diameter) If in doubt use this flux estimator	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag1Err	calSynopticSource	WSACalib	Error in extended source J mag (1.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag1Err	gpsJHKsource, gpsPointSource, gpsSource, reliableGpsPointSource	WSA	Error in point source J mag (1.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag2	calSynopticSource	WSACalib	Extended source J aperture corrected mag (1.4 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag2Err	calSynopticSource	WSACalib	Error in extended source J mag (1.4 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag3	calSource	WSACalib	Default point/extended source J aperture corrected mag (2.0 arcsec aperture diameter) If in doubt use this flux estimator	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag3	calSynopticSource	WSACalib	Default point/extended source J aperture corrected mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag3	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Default point source J aperture corrected mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag3	dxsSource, gcsSource, gpsSource, lasSource	WSA	Default point source J aperture corrected mag (2.0 arcsec aperture diameter) If in doubt use this flux estimator	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag3	lasYselJSourceRemeasurement	WSA	Default point source J aperture corrected (2.0 arcsec aperture diameter) If in doubt use this flux estimator	real	4	mag	-0.9999995e9	phot.mag
jAperMag3	reliableUdsSource	WSA	Default point/extended source J mag, no aperture correction applied	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag3	udsSource	WSA	Default point/extended source J mag, no aperture correction applied If in doubt use this flux estimator	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag3	uhsSource, uhsSourceAll	WSAUHS	Default point source J aperture corrected mag (2.0 arcsec aperture diameter) If in doubt use this flux estimator	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag3Err	calSource, calSynopticSource	WSACalib	Error in default point/extended source J mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag3Err	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Error in default point source J mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag3Err	lasYselJSourceRemeasurement	WSA	Error in default point/extended source J (2.0 arcsec aperture diameter) magnitude	real	4	mag	-0.9999995e9	stat.error
jAperMag3Err	reliableUdsSource, udsSource	WSA	Error in default point/extended source J mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag3Err	uhsSource, uhsSourceAll	WSAUHS	Error in default point source J mag (2.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag4	calSource, calSynopticSource	WSACalib	Extended source J aperture corrected mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag4	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Point source J aperture corrected mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag4	lasYselJSourceRemeasurement	WSA	Point source J aperture corrected (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	phot.mag
jAperMag4	reliableUdsSource, udsSource	WSA	Extended source J mag, no aperture correction applied	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag4	uhsSource, uhsSourceAll	WSAUHS	Point source J aperture corrected mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag4Err	calSource, calSynopticSource	WSACalib	Error in extended source J mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag4Err	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Error in point source J mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag4Err	lasYselJSourceRemeasurement	WSA	Error in point/extended source J (2.8 arcsec aperture diameter) magnitude	real	4	mag	-0.9999995e9	stat.error
jAperMag4Err	reliableUdsSource, udsSource	WSA	Error in extended source J mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag4Err	uhsSource, uhsSourceAll	WSAUHS	Error in point source J mag (2.8 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag5	calSynopticSource	WSACalib	Extended source J aperture corrected mag (4.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag5Err	calSynopticSource	WSACalib	Error in extended source J mag (4.0 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag6	calSource	WSACalib	Extended source J aperture corrected mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag6	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableLasPointSource	WSA	Point source J aperture corrected mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag6	lasYselJSourceRemeasurement	WSA	Point source J aperture corrected (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	phot.mag
jAperMag6	reliableUdsSource, udsSource	WSA	Extended source J mag, no aperture correction applied	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag6	uhsSource, uhsSourceAll	WSAUHS	Point source J aperture corrected mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	PHOT_MAG
jAperMag6Err	calSource	WSACalib	Error in extended source J mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag6Err	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableLasPointSource	WSA	Error in point source J mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag6Err	lasYselJSourceRemeasurement	WSA	Error in point/extended source J (5.7 arcsec aperture diameter) magnitude	real	4	mag	-0.9999995e9	stat.error
jAperMag6Err	reliableUdsSource, udsSource	WSA	Error in extended source J mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMag6Err	uhsSource, uhsSourceAll	WSAUHS	Error in point source J mag (5.7 arcsec aperture diameter)	real	4	mag	-0.9999995e9	ERROR
jAperMagNoAperCorr3	lasYselJSourceRemeasurement	WSA	Default extended source J (2.0 arcsec aperture diameter, but no aperture correction applied) aperture magnitude If in doubt use this flux estimator	real	4	mag	-0.9999995e9	phot.mag
jAperMagNoAperCorr4	lasYselJSourceRemeasurement	WSA	Extended source J (2.8 arcsec aperture diameter, but no aperture correction applied) aperture magnitude	real	4	mag	-0.9999995e9	phot.mag
jAperMagNoAperCorr6	lasYselJSourceRemeasurement	WSA	Extended source J (5.7 arcsec aperture diameter, but no aperture correction applied) aperture magnitude	real	4	mag	-0.9999995e9	phot.mag
jaStratAst	calVarFrameSetInfo	WSACalib	Strateva parameter, a, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jaStratAst	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Strateva parameter, a, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jaStratAst	uhsVarFrameSetInfo	WSAUHS	Strateva parameter, a, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jaStratPht	calVarFrameSetInfo	WSACalib	Strateva parameter, a, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jaStratPht	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Strateva parameter, a, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jaStratPht	uhsVarFrameSetInfo	WSAUHS	Strateva parameter, a, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jAverageConf	lasYselJSourceRemeasurement	WSA	average confidence in 2 arcsec diameter default aperture (aper3) J	real	4		-0.9999995e9	stat.likelihood;em.IR.NIR
jbestAper	calVariability	WSACalib	Best aperture (1-6) for photometric statistics in the J band	int	4		-9999
			Aperture magnitude (1-6) which gives the lowest RMS for the object. All apertures have the appropriate aperture correction. This can give better values in crowded regions than aperMag3 (see Irwin et al. 2007, MNRAS, 375, 1449)
jbestAper	dxsVariability, lasVariability, udsVariability	WSA	Best aperture (1-6) for photometric statistics in the J band	int	4		-9999
			Aperture magnitude (1-6) which gives the lowest RMS for the object. All apertures have the appropriate aperture correction. This can give better values in crowded regions than aperMag3 (see Irwin et al. 2007, MNRAS, 375, 1449)
jbestAper	uhsVariability	WSAUHS	Best aperture (1-6) for photometric statistics in the J band	int	4		-9999
			Aperture magnitude (1-6) which gives the lowest RMS for the object. All apertures have the appropriate aperture correction. This can give better values in crowded regions than aperMag3 (see Irwin et al. 2007, MNRAS, 375, 1449)
jbStratAst	calVarFrameSetInfo	WSACalib	Strateva parameter, b, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jbStratAst	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Strateva parameter, b, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jbStratAst	uhsVarFrameSetInfo	WSAUHS	Strateva parameter, b, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jbStratPht	calVarFrameSetInfo	WSACalib	Strateva parameter, b, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jbStratPht	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Strateva parameter, b, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jbStratPht	uhsVarFrameSetInfo	WSAUHS	Strateva parameter, b, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jchiSqAst	calVarFrameSetInfo	WSACalib	Goodness of fit of Strateva function to astrometric data in J band	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jchiSqAst	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Goodness of fit of Strateva function to astrometric data in J band	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jchiSqAst	uhsVarFrameSetInfo	WSAUHS	Goodness of fit of Strateva function to astrometric data in J band	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jchiSqpd	calVariability	WSACalib	Chi square (per degree of freedom) fit to data (mean and expected rms)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jchiSqpd	dxsVariability, lasVariability, udsVariability	WSA	Chi square (per degree of freedom) fit to data (mean and expected rms)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jchiSqpd	uhsVariability	WSAUHS	Chi square (per degree of freedom) fit to data (mean and expected rms)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jchiSqPht	calVarFrameSetInfo	WSACalib	Goodness of fit of Strateva function to photometric data in J band	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jchiSqPht	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Goodness of fit of Strateva function to photometric data in J band	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jchiSqPht	uhsVarFrameSetInfo	WSAUHS	Goodness of fit of Strateva function to photometric data in J band	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jClass	calSource, calSynopticSource	WSACalib	discrete image classification flag in J	smallint	2		-9999	CLASS_MISC
jClass	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	discrete image classification flag in J	smallint	2		-9999	CLASS_MISC
jClass	lasYselJSourceRemeasurement	WSA	discrete image classification flag in J	smallint	2		-9999	src.class
jClass	uhsSource, uhsSourceAll	WSAUHS	discrete image classification flag in J	smallint	2		-9999	CLASS_MISC
jClassStat	calSource, calSynopticSource	WSACalib	N(0,1) stellarness-of-profile statistic in J	real	4		-0.9999995e9	STAT_PROP
jClassStat	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	N(0,1) stellarness-of-profile statistic in J	real	4		-0.9999995e9	STAT_PROP
jClassStat	lasYselJSourceRemeasurement	WSA	N(0,1) stellarness-of-profile statistic in J	real	4		-0.9999995e9	stat
jClassStat	reliableUdsSource, udsSource	WSA	S-Extractor classification statistic in J	real	4		-0.9999995e9	STAT_PROP
jClassStat	uhsSource, uhsSourceAll	WSAUHS	N(0,1) stellarness-of-profile statistic in J	real	4		-0.9999995e9	STAT_PROP
jCorr	twompzPhotoz	TWOMPZ	J 20mag/sq." isophotal fiducial ell. ap. magnitude with Galactic dust correction {image primary HDU keyword: Jcorr}	real	4	mag	-0.9999995e9	phot.mag;em.IR.J
jCorrErr	twompzPhotoz	TWOMPZ	J 1-sigma uncertainty in 20mag/sq." aperture {image primary HDU keyword: j_msig_k20fe}	real	4	mag	-0.9999995e9
jcStratAst	calVarFrameSetInfo	WSACalib	Strateva parameter, c, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jcStratAst	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Strateva parameter, c, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jcStratAst	uhsVarFrameSetInfo	WSAUHS	Strateva parameter, c, in fit to astrometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jcStratPht	calVarFrameSetInfo	WSACalib	Strateva parameter, c, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jcStratPht	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Strateva parameter, c, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jcStratPht	uhsVarFrameSetInfo	WSAUHS	Strateva parameter, c, in fit to photometric rms vs magnitude in J band, see Sesar et al. 2007.	real	4		-0.9999995e9
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jdate	twomass_psc	2MASS	The Julian Date of the source measurement accurate to +-30 seconds.	float	8	Julian days		TIME_DATE
jdate	twomass_scn	2MASS	Julian Date at beginning of scan.	float	8	Julian days		TIME_DATE
jdate	twomass_sixx2_psc	2MASS	julian date of source measurement to +/- 30 sec	float	8	jdate
jdate	twomass_sixx2_scn	2MASS	Julian date beginning UT of scan data	float	8	jdate
jdate	twomass_xsc	2MASS	Julian date of the source measurement accurate to +-3 minutes.	float	8	Julian days		TIME_DATE
jDeblend	calSource	WSACalib	placeholder flag indicating parent/child relation in J	int	4		-99999999	CODE_MISC
			This CASU pipeline processing source extraction flag is a placeholder only, and is always set to zero in all passbands in the merged source lists. If you need to know when a particular image detection is a component of a deblend or not, test bit 4 of attribute ppErrBits (see corresponding glossary entry) which is set by WFAU's post-processing software based on testing the areal profiles aprof2-8 (these are set by CASU to -1 for deblended components, or positive values for non-deblended detections). We encode this in an information bit of ppErrBits for convenience when querying the merged source tables.
jDeblend	calSynopticSource	WSACalib	placeholder flag indicating parent/child relation in J	int	4		-99999999	CODE_MISC
jDeblend	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	placeholder flag indicating parent/child relation in J	int	4		-99999999	CODE_MISC
jDeblend	dxsSource, gcsSource, gpsSource, lasSource	WSA	placeholder flag indicating parent/child relation in J	int	4		-99999999	CODE_MISC
			This CASU pipeline processing source extraction flag is a placeholder only, and is always set to zero in all passbands in the merged source lists. If you need to know when a particular image detection is a component of a deblend or not, test bit 4 of attribute ppErrBits (see corresponding glossary entry) which is set by WFAU's post-processing software based on testing the areal profiles aprof2-8 (these are set by CASU to -1 for deblended components, or positive values for non-deblended detections). We encode this in an information bit of ppErrBits for convenience when querying the merged source tables.
jDeblend	uhsSource, uhsSourceAll	WSAUHS	placeholder flag indicating parent/child relation in J	int	4		-99999999	CODE_MISC
			This CASU pipeline processing source extraction flag is a placeholder only, and is always set to zero in all passbands in the merged source lists. If you need to know when a particular image detection is a component of a deblend or not, test bit 4 of attribute ppErrBits (see corresponding glossary entry) which is set by WFAU's post-processing software based on testing the areal profiles aprof2-8 (these are set by CASU to -1 for deblended components, or positive values for non-deblended detections). We encode this in an information bit of ppErrBits for convenience when querying the merged source tables.
jEll	calSource, calSynopticSource	WSACalib	1-b/a, where a/b=semi-major/minor axes in J	real	4		-0.9999995e9	PHYS_ELLIPTICITY
jEll	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	1-b/a, where a/b=semi-major/minor axes in J	real	4		-0.9999995e9	PHYS_ELLIPTICITY
jEll	lasYselJSourceRemeasurement	WSA	1-b/a, where a/b=semi-major/minor axes in J	real	4		-0.9999995e9	src.ellipticty
jEll	uhsSource, uhsSourceAll	WSAUHS	1-b/a, where a/b=semi-major/minor axes in J	real	4		-0.9999995e9	PHYS_ELLIPTICITY
jeNum	calMergeLog, calSynopticMergeLog	WSACalib	the extension number of this J frame	tinyint	1			NUMBER
jeNum	dxsJKmergeLog, gpsJHKmergeLog	WSA	the extension number of this frame	tinyint	1			NUMBER
jeNum	dxsMergeLog, gcsMergeLog, gcsZYJHKmergeLog, gpsMergeLog, lasMergeLog, lasYJHKmergeLog, udsMergeLog	WSA	the extension number of this J frame	tinyint	1			NUMBER
jeNum	lasYselJRemeasMergeLog	WSA	the extension number of this J frame	tinyint	1			meta.number;em.IR.J
jeNum	uhsMergeLog	WSAUHS	the extension number of this J frame	tinyint	1			NUMBER
jErrBits	calSource, calSynopticSource	WSACalib	processing warning/error bitwise flags in J	int	4		-99999999	CODE_MISC
			Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
jErrBits	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource	WSA	processing warning/error bitwise flags in J	int	4		-99999999	CODE_MISC
jErrBits	dxsSource, gcsSource, gpsSource, lasSource	WSA	processing warning/error bitwise flags in J	int	4		-99999999	CODE_MISC
			Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
jErrBits	lasYselJSourceRemeasurement	WSA	processing warning/error bitwise flags in J	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.
jErrBits	udsSource	WSA	processing warning/error bitwise flags in J	int	4		-99999999	CODE_MISC
			This uses the FLAGS attribute in SE. The individual bit flags that this can be decomposed into are as follows: Bit Flag Meaning 1 The object has neighbours, bright enough and close enough to significantly bias the MAG_AUTO photometry or bad pixels (more than 10% of photometry affected). 2 The object was originally blended with another 4 At least one pixel is saturated (or very close to) 8 The object is truncated (too close to an image boundary) 16 Object's aperture data are incomplete or corrupted 32 Object's isophotal data are imcomplete or corrupted. This is an old flag inherited from SE v1.0, and is kept for compatability reasons. It doesn't have any consequence for the extracted parameters. 64 Memory overflow occurred during deblending 128 Memory overflow occurred during extraction
jErrBits	uhsSource, uhsSourceAll	WSAUHS	processing warning/error bitwise flags in J	int	4		-99999999	CODE_MISC
			Apparently not actually an error bit flag, but a count of the number of zero confidence pixels in the default (2 arcsec diameter) aperture.
jEta	calSource, calSynopticSource	WSACalib	Offset of J detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
jEta	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource	WSA	Offset of J detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
jEta	dxsSource, gcsSource, gpsSource, lasSource, udsSource	WSA	Offset of J detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
jEta	uhsSource, uhsSourceAll	WSAUHS	Offset of J detection from master position (+north/-south)	real	4	arcsec	-0.9999995e9	POS_EQ_DEC_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
jexpML	calVarFrameSetInfo	WSACalib	Expected magnitude limit of frameSet in this in J band.	real	4		-0.9999995e9
			The expected magnitude limit of an intermediate stack, based on the total exposure time. expML=Filter.oneSecML+1.25*log10(totalExpTime). Since different intermediate stacks can have different exposure times, the totalExpTime is the minimum, as long as the number of stacks with this minimum make up 10% of the total. This is a more conservative treatment than just taking the mean or median total exposure time.
jexpML	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Expected magnitude limit of frameSet in this in J band.	real	4		-0.9999995e9
			The expected magnitude limit of an intermediate stack, based on the total exposure time. expML=Filter.oneSecML+1.25*log10(totalExpTime). Since different intermediate stacks can have different exposure times, the totalExpTime is the minimum, as long as the number of stacks with this minimum make up 10% of the total. This is a more conservative treatment than just taking the mean or median total exposure time.
jexpML	uhsVarFrameSetInfo	WSAUHS	Expected magnitude limit of frameSet in this in J band.	real	4		-0.9999995e9
			The expected magnitude limit of an intermediate stack, based on the total exposure time. expML=Filter.oneSecML+1.25*log10(totalExpTime). Since different intermediate stacks can have different exposure times, the totalExpTime is the minimum, as long as the number of stacks with this minimum make up 10% of the total. This is a more conservative treatment than just taking the mean or median total exposure time.
jExpRms	calVariability	WSACalib	Rms calculated from polynomial fit to modal RMS as a function of magnitude in J band	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jExpRms	dxsVariability, lasVariability, udsVariability	WSA	Rms calculated from polynomial fit to modal RMS as a function of magnitude in J band	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jExpRms	uhsVariability	WSAUHS	Rms calculated from polynomial fit to modal RMS as a function of magnitude in J band	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jGausig	calSource, calSynopticSource	WSACalib	RMS of axes of ellipse fit in J	real	4	pixels	-0.9999995e9	MORPH_PARAM
jGausig	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	RMS of axes of ellipse fit in J	real	4	pixels	-0.9999995e9	MORPH_PARAM
jGausig	lasYselJSourceRemeasurement	WSA	RMS of axes of ellipse fit in J	real	4	pixels	-0.9999995e9	src.morph.param
jGausig	uhsSource, uhsSourceAll	WSAUHS	RMS of axes of ellipse fit in J	real	4	pixels	-0.9999995e9	MORPH_PARAM
jHallMag	calSource	WSACalib	Total point source J mag	real	4	mag	-0.9999995e9	PHOT_MAG
jHallMag	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Total point source J mag	real	4	mag	-0.9999995e9	PHOT_MAG
jHallMag	reliableUdsSource, udsSource	WSA	Not available in SE output	real	4	mag	-0.9999995e9	PHOT_MAG
jHallMag	uhsSource, uhsSourceAll	WSAUHS	Total point source J mag	real	4	mag	-0.9999995e9	PHOT_MAG
jHallMagErr	calSource	WSACalib	Error in total point source J mag	real	4	mag	-0.9999995e9	ERROR
jHallMagErr	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Error in total point source J mag	real	4	mag	-0.9999995e9	ERROR
jHallMagErr	reliableUdsSource, udsSource	WSA	Not available in SE output	real	4	mag	-0.9999995e9	ERROR
jHallMagErr	uhsSource, uhsSourceAll	WSAUHS	Error in total point source J mag	real	4	mag	-0.9999995e9	ERROR
jhiWS	calVariability	WSACalib	Welch-Stetson statistic between J and H. This assumes colour does not vary much and helps remove variation due to a few poor detections	real	4		-0.9999995e9
			The Welch-Stetson statistic is a measure of the correlation of the variability between two bands. We use the calculation in Welch D.L. and Stetson P.B. 1993, AJ, 105, 5, which is also used in Sesar et al. 2007, AJ, 134, 2236. We use the aperMag3 magnitude when comparing between bands.
jIntRms	calVariability	WSACalib	Intrinsic rms in J-band	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jIntRms	dxsVariability, lasVariability, udsVariability	WSA	Intrinsic rms in J-band	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jIntRms	uhsVariability	WSAUHS	Intrinsic rms in J-band	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jisDefAst	calVarFrameSetInfo	WSACalib	Use a default model for the astrometric noise in J band.	tinyint	1		0
jisDefAst	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Use a default model for the astrometric noise in J band.	tinyint	1		0
jisDefAst	uhsVarFrameSetInfo	WSAUHS	Use a default model for the astrometric noise in J band.	tinyint	1		0
jisDefPht	calVarFrameSetInfo	WSACalib	Use a default model for the photometric noise in J band.	tinyint	1		0
jisDefPht	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Use a default model for the photometric noise in J band.	tinyint	1		0
jisDefPht	uhsVarFrameSetInfo	WSAUHS	Use a default model for the photometric noise in J band.	tinyint	1		0
jIsMeas	lasYselJSourceRemeasurement	WSA	Is pass band J measured? 0 no, 1 yes	tinyint	1		0	meta.code
jitterID	Multiframe	WSA	Serial number in this telescope jitter pattern {image primary HDU keyword: JITTER_I}	smallint	2		-9999	meta.id
jitterID	Multiframe	WSACalib	Serial number in this telescope jitter pattern {image primary HDU keyword: JITTER_I}	smallint	2		-9999	meta.id
jitterID	Multiframe	WSATransit	Serial number in this telescope jitter pattern {image primary HDU keyword: JITTER_I}	smallint	2		-9999	meta.id
jitterID	Multiframe	WSAUHS	Serial number in this telescope jitter pattern {image primary HDU keyword: JITTER_I}	smallint	2		-9999	meta.id
jitterX	Multiframe	WSA	X (RA) offset in tel jitter pattern {image primary HDU keyword: JITTER_X}	real	4	arcsec	-0.9999995e9	pos.eq.ra;arith.diff
jitterX	Multiframe	WSACalib	X (RA) offset in tel jitter pattern {image primary HDU keyword: JITTER_X}	real	4	arcsec	-0.9999995e9	pos.eq.ra;arith.diff
jitterX	Multiframe	WSATransit	X (RA) offset in tel jitter pattern {image primary HDU keyword: JITTER_X}	real	4	arcsec	-0.9999995e9	pos.eq.ra;arith.diff
jitterX	Multiframe	WSAUHS	X (RA) offset in tel jitter pattern {image primary HDU keyword: JITTER_X}	real	4	arcsec	-0.9999995e9	pos.eq.ra;arith.diff
jitterY	Multiframe	WSA	Y (Dec) offset in tel jitter pattern {image primary HDU keyword: JITTER_Y}	real	4	arcsec	-0.9999995e9	pos.eq.dec;arith.diff
jitterY	Multiframe	WSACalib	Y (Dec) offset in tel jitter pattern {image primary HDU keyword: JITTER_Y}	real	4	arcsec	-0.9999995e9	pos.eq.dec;arith.diff
jitterY	Multiframe	WSATransit	Y (Dec) offset in tel jitter pattern {image primary HDU keyword: JITTER_Y}	real	4	arcsec	-0.9999995e9	pos.eq.dec;arith.diff
jitterY	Multiframe	WSAUHS	Y (Dec) offset in tel jitter pattern {image primary HDU keyword: JITTER_Y}	real	4	arcsec	-0.9999995e9	pos.eq.dec;arith.diff
jMag	ukirtFSstars	WSA	J band total magnitude on the MKO(UFTI) system	real	4	mag		phot.mag
jMag	ukirtFSstars	WSACalib	J band total magnitude on the MKO(UFTI) system	real	4	mag		phot.mag
jMag	ukirtFSstars	WSAUHS	J band total magnitude on the MKO(UFTI) system	real	4	mag		phot.mag
jMagErr	ukirtFSstars	WSA	J band magnitude error	real	4	mag		stat.error
jMagErr	ukirtFSstars	WSACalib	J band magnitude error	real	4	mag		stat.error
jMagErr	ukirtFSstars	WSAUHS	J band magnitude error	real	4	mag		stat.error
jMagMAD	calVariability	WSACalib	Median Absolute Deviation of J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMagMAD	dxsVariability, lasVariability, udsVariability	WSA	Median Absolute Deviation of J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMagMAD	uhsVariability	WSAUHS	Median Absolute Deviation of J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMagRms	calVariability	WSACalib	rms of J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMagRms	dxsVariability, lasVariability, udsVariability	WSA	rms of J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMagRms	uhsVariability	WSAUHS	rms of J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmaxCadence	calVariability	WSACalib	maximum gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jmaxCadence	dxsVariability, lasVariability, udsVariability	WSA	maximum gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jmaxCadence	uhsVariability	WSAUHS	maximum gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jMaxMag	calVariability	WSACalib	Maximum magnitude in J band, of good detections	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMaxMag	dxsVariability, lasVariability, udsVariability	WSA	Maximum magnitude in J band, of good detections	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMaxMag	uhsVariability	WSAUHS	Maximum magnitude in J band, of good detections	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmeanMag	calVariability	WSACalib	Mean J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmeanMag	dxsVariability, lasVariability, udsVariability	WSA	Mean J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmeanMag	uhsVariability	WSAUHS	Mean J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmedCadence	calVariability	WSACalib	median gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jmedCadence	dxsVariability, lasVariability, udsVariability	WSA	median gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jmedCadence	uhsVariability	WSAUHS	median gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jmedianMag	calVariability	WSACalib	Median J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmedianMag	dxsVariability, lasVariability, udsVariability	WSA	Median J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmedianMag	uhsVariability	WSAUHS	Median J magnitude	real	4	mag	-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmfID	calMergeLog, calSynopticMergeLog	WSACalib	the UID of the relevant J multiframe	bigint	8			ID_FRAME
jmfID	dxsJKmergeLog, gpsJHKmergeLog	WSA	the UID of the relevant multiframe	bigint	8			ID_FRAME
jmfID	dxsMergeLog, gcsMergeLog, gcsZYJHKmergeLog, gpsMergeLog, lasMergeLog, lasYJHKmergeLog, udsMergeLog	WSA	the UID of the relevant J multiframe	bigint	8			ID_FRAME
jmfID	lasYselJRemeasMergeLog	WSA	the UID of the relevant J multiframe	bigint	8			meta.id;obs.field;em.IR.J
jmfID	uhsMergeLog	WSAUHS	the UID of the relevant J multiframe	bigint	8			ID_FRAME
jmhExt	calSource	WSACalib	Extended source colour J-H (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.
jmhExt	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource	WSA	Extended source colour J-H (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
jmhExt	dxsSource, gcsSource, gpsSource, lasSource, udsSource	WSA	Extended source colour J-H (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.
jmhExt	lasYselJSourceRemeasurement	WSA	Extended source colour J-H (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.
jmhExtErr	calSource	WSACalib	Error on extended source colour J-H	real	4	mag	-0.9999995e9	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.
jmhExtErr	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource	WSA	Error on extended source colour J-H	real	4	mag	-0.9999995e9	ERROR
jmhExtErr	dxsSource, gcsSource, gpsSource, lasSource, udsSource	WSA	Error on extended source colour J-H	real	4	mag	-0.9999995e9	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.
jmhExtErr	lasYselJSourceRemeasurement	WSA	Error on extended source colour J-H	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.
jmhExtJky	lasYselJSourceRemeasurement	WSA	Extended source colour calibrated flux H/J (using aperJkyNoAperCorr3)	real	4	jansky	-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.
jmhExtJkyErr	lasYselJSourceRemeasurement	WSA	Error on extended source colour calibrated flux H/J	real	4	jansky	-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.
jmhExtLup	lasYselJSourceRemeasurement	WSA	Extended source colour luptitudeJ-H (using aperLupNoAperCorr3)	real	4	lup	-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.
jmhExtLupErr	lasYselJSourceRemeasurement	WSA	Error on extended source colour luptitude J-H	real	4	lup	-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.
jmhPnt	calSource, calSynopticSource	WSACalib	Point source colour J-H (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.
jmhPnt	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource	WSA	Point source colour J-H (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
jmhPnt	dxsSource, gcsSource, gpsSource, lasSource, udsSource	WSA	Point source colour J-H (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.
jmhPnt	lasYselJSourceRemeasurement	WSA	Point source colour J-H (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.
jmhPntErr	calSource, calSynopticSource	WSACalib	Error on point source colour J-H	real	4	mag	-0.9999995e9	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.
jmhPntErr	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource	WSA	Error on point source colour J-H	real	4	mag	-0.9999995e9	ERROR
jmhPntErr	dxsSource, gcsSource, gpsSource, lasSource, udsSource	WSA	Error on point source colour J-H	real	4	mag	-0.9999995e9	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.
jmhPntErr	lasYselJSourceRemeasurement	WSA	Error on point source colour J-H	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.
jmhPntJky	lasYselJSourceRemeasurement	WSA	Point source colour calibrated flux H/J (using aperJky3)	real	4	jansky	-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.
jmhPntJkyErr	lasYselJSourceRemeasurement	WSA	Error on point source colour calibrated flux H/J	real	4	jansky	-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.
jmhPntLup	lasYselJSourceRemeasurement	WSA	Point source colour luptitude J-H (using aperLup3)	real	4	lup	-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.
jmhPntLupErr	lasYselJSourceRemeasurement	WSA	Error on point source colour luptitude J-H	real	4	lup	-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.
jminCadence	calVariability	WSACalib	minimum gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jminCadence	dxsVariability, lasVariability, udsVariability	WSA	minimum gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jminCadence	uhsVariability	WSAUHS	minimum gap between observations	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jMinMag	calVariability	WSACalib	Minimum magnitude in J band, of good detections	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMinMag	dxsVariability, lasVariability, udsVariability	WSA	Minimum magnitude in J band, of good detections	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jMinMag	uhsVariability	WSAUHS	Minimum magnitude in J band, of good detections	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jmkExt	dxsJKsource, reliableDxsSource	WSA	Extended source colour J-K (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
jmkExt	dxsSource	WSA	Extended source colour J-K (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.
jmkExt	uhsSource	WSAUHS	Extended source colour J-K (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.
jmkExtErr	dxsJKsource, reliableDxsSource	WSA	Error on extended source colour J-K	real	4	mag	-0.9999995e9	ERROR
jmkExtErr	dxsSource	WSA	Error on extended source colour J-K	real	4	mag	-0.9999995e9	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.
jmkExtErr	uhsSource	WSAUHS	Error on extended source colour J-K	real	4	mag	-0.9999995e9	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.
jmkPnt	dxsJKsource, reliableDxsSource	WSA	Point source colour J-K (using aperMag3)	real	4	mag	-0.9999995e9	PHOT_COLOR
jmkPnt	dxsSource	WSA	Point source colour J-K (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.
jmkPnt	uhsSource	WSAUHS	Point source colour J-K (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.
jmkPntErr	dxsJKsource, reliableDxsSource	WSA	Error on point source colour J-K	real	4	mag	-0.9999995e9	ERROR
jmkPntErr	dxsSource	WSA	Error on point source colour J-K	real	4	mag	-0.9999995e9	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.
jmkPntErr	uhsSource	WSAUHS	Error on point source colour J-K	real	4	mag	-0.9999995e9	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.
jndof	calVariability	WSACalib	Number of degrees of freedom for chisquare	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jndof	dxsVariability, lasVariability, udsVariability	WSA	Number of degrees of freedom for chisquare	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jndof	uhsVariability	WSAUHS	Number of degrees of freedom for chisquare	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jnDofAst	calVarFrameSetInfo	WSACalib	Number of degrees of freedom of astrometric fit in J band.	smallint	2		-9999
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jnDofAst	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Number of degrees of freedom of astrometric fit in J band.	smallint	2		-9999
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jnDofAst	uhsVarFrameSetInfo	WSAUHS	Number of degrees of freedom of astrometric fit in J band.	smallint	2		-9999
			The best fit solution to the expected RMS position around the mean for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated.
jnDofPht	calVarFrameSetInfo	WSACalib	Number of degrees of freedom of photometric fit in J band.	smallint	2		-9999
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jnDofPht	dxsVarFrameSetInfo, lasVarFrameSetInfo, udsVarFrameSetInfo	WSA	Number of degrees of freedom of photometric fit in J band.	smallint	2		-9999
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jnDofPht	uhsVarFrameSetInfo	WSAUHS	Number of degrees of freedom of photometric fit in J band.	smallint	2		-9999
			The best fit solution to the expected RMS brightness (in magnitudes) for all objects in the frameset. Objects were binned in ranges of magnitude and the median RMS (after clipping out variable objects using the median-absolute deviation) was calculated. The Strateva function $\zeta(m)>=a+b\,10^{0.4m}+c\,10^{0.8m}$ was fit, where $\zeta(m)$ is the expected RMS as a function of magnitude. The chi-squared and number of degrees of freedom are also calculated. This technique was used in Sesar et al. 2007, AJ, 134, 2236.
jnFlaggedObs	calVariability	WSACalib	Number of detections in J band flagged as potentially spurious by calDetection.ppErrBits	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnFlaggedObs	dxsVariability	WSA	Number of detections in J band flagged as potentially spurious by dxsDetection.ppErrBits	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnFlaggedObs	lasVariability	WSA	Number of detections in J band flagged as potentially spurious by lasDetection.ppErrBits	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnFlaggedObs	udsVariability	WSA	Number of detections in J band flagged as potentially spurious by udsDetection.ppErrBits	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnFlaggedObs	uhsVariability	WSAUHS	Number of detections in J band flagged as potentially spurious by uhsDetection.ppErrBits	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnGoodObs	calVariability	WSACalib	Number of good detections in J band	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnGoodObs	dxsVariability, lasVariability, udsVariability	WSA	Number of good detections in J band	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnGoodObs	uhsVariability	WSAUHS	Number of good detections in J band	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jNgt3sig	calVariability	WSACalib	Number of good detections in J-band that are more than 3 sigma deviations	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jNgt3sig	dxsVariability, lasVariability, udsVariability	WSA	Number of good detections in J-band that are more than 3 sigma deviations (jAperMagN < (jMeanMag-3*jMagRms)	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jNgt3sig	uhsVariability	WSAUHS	Number of good detections in J-band that are more than 3 sigma deviations (jAperMagN < (jMeanMag-3*jMagRms)	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jnMissingObs	calVariability	WSACalib	Number of J band frames that this object should have been detected on and was not	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnMissingObs	dxsVariability, lasVariability, udsVariability	WSA	Number of J band frames that this object should have been detected on and was not	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jnMissingObs	uhsVariability	WSAUHS	Number of J band frames that this object should have been detected on and was not	int	4		0
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
joinCriterion	RequiredNeighbours	WSA	the join criterion (search radius for matches)	real	4	degrees		??
joinCriterion	RequiredNeighbours	WSACalib	the join criterion (search radius for matches)	real	4	degrees		??
joinCriterion	RequiredNeighbours	WSATransit	the join criterion (search radius for matches)	real	4	degrees		??
joinCriterion	RequiredNeighbours	WSAUHS	the join criterion (search radius for matches)	real	4	degrees		??
jPA	calSource, calSynopticSource	WSACalib	ellipse fit celestial orientation in J	real	4	Degrees	-0.9999995e9	POS_POS-ANG
jPA	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	ellipse fit celestial orientation in J	real	4	Degrees	-0.9999995e9	POS_POS-ANG
jPA	lasYselJSourceRemeasurement	WSA	ellipse fit celestial orientation in J	real	4	Degrees	-0.9999995e9	pos.posAng
jPA	uhsSource, uhsSourceAll	WSAUHS	ellipse fit celestial orientation in J	real	4	Degrees	-0.9999995e9	POS_POS-ANG
jPetroMag	calSource	WSACalib	Extended source J mag (Petrosian)	real	4	mag	-0.9999995e9	PHOT_MAG
jPetroMag	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	Extended source J mag (Petrosian)	real	4	mag	-0.9999995e9	PHOT_MAG
jPetroMag	uhsSource, uhsSourceAll	WSAUHS	Extended source J mag (Petrosian)	real	4	mag	-0.9999995e9	PHOT_MAG
jPetroMagErr	calSource	WSACalib	Error in extended source J mag (Petrosian)	real	4	mag	-0.9999995e9	ERROR
jPetroMagErr	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	Error in extended source J mag (Petrosian)	real	4	mag	-0.9999995e9	ERROR
jPetroMagErr	uhsSource, uhsSourceAll	WSAUHS	Error in extended source J mag (Petrosian)	real	4	mag	-0.9999995e9	ERROR
jppErrBits	calSource, calSynopticSource	WSACalib	additional WFAU post-processing error bits in J	int	4		0	CODE_MISC
			Post-processing error quality bit flags assigned (NB: from UKIDSS DR2 release onwards) in the WSA 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: Byte Bit Detection quality issue Threshold or bit mask Applies to Decimal Hexadecimal 0 4 Deblended 16 0x00000010 All VDFS catalogues 0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues 1 15 Source in poor flat field region 32768 0x00008000 All but mosaics 2 16 Close to saturated 65536 0x00010000 All VDFS catalogues (though deeps excluded prior to DR8) 2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 GPS only 2 19 Possible crosstalk artefact/contamination 524288 0x00080000 All but GPS 2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All but mosaics 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 K band sources in the LAS 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.
jppErrBits	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	additional WFAU post-processing error bits in J	int	4		0	CODE_MISC
jppErrBits	dxsSource, gcsSource, gpsSource, lasSource	WSA	additional WFAU post-processing error bits in J	int	4		0	CODE_MISC
			Post-processing error quality bit flags assigned (NB: from UKIDSS DR2 release onwards) in the WSA 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: Byte Bit Detection quality issue Threshold or bit mask Applies to Decimal Hexadecimal 0 4 Deblended 16 0x00000010 All VDFS catalogues 0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues 1 15 Source in poor flat field region 32768 0x00008000 All but mosaics 2 16 Close to saturated 65536 0x00010000 All VDFS catalogues (though deeps excluded prior to DR8) 2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 GPS only 2 19 Possible crosstalk artefact/contamination 524288 0x00080000 All but GPS 2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All but mosaics 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 K band sources in the LAS 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.
jppErrBits	lasYselJSourceRemeasurement	WSA	additional WFAU post-processing error bits in J	int	4		0	meta.code
			Post-processing error quality bit flags assigned (NB: from UKIDSS DR2 release onwards) in the WSA 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: Byte Bit Detection quality issue Threshold or bit mask Applies to Decimal Hexadecimal 0 4 Deblended 16 0x00000010 All VDFS catalogues 0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues 1 15 Source in poor flat field region 32768 0x00008000 All but mosaics 2 16 Close to saturated 65536 0x00010000 All VDFS catalogues (though deeps excluded prior to DR8) 2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 GPS only 2 19 Possible crosstalk artefact/contamination 524288 0x00080000 All but GPS 2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All but mosaics 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 K band sources in the LAS 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.
jppErrBits	uhsSource, uhsSourceAll	WSAUHS	additional WFAU post-processing error bits in J	int	4		0	CODE_MISC
			Post-processing error quality bit flags assigned (NB: from UKIDSS DR2 release onwards) in the WSA 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: Byte Bit Detection quality issue Threshold or bit mask Applies to Decimal Hexadecimal 0 4 Deblended 16 0x00000010 All VDFS catalogues 0 6 Bad pixel(s) in default aperture 64 0x00000040 All VDFS catalogues 1 15 Source in poor flat field region 32768 0x00008000 All but mosaics 2 16 Close to saturated 65536 0x00010000 All VDFS catalogues (though deeps excluded prior to DR8) 2 17 Photometric calibration probably subject to systematic error 131072 0x00020000 GPS only 2 19 Possible crosstalk artefact/contamination 524288 0x00080000 All but GPS 2 22 Lies within a dither offset of the stacked frame boundary 4194304 0x00400000 All but mosaics 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 K band sources in the LAS 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.
jprobVar	calVariability	WSACalib	Probability of variable from chi-square (and other data)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jprobVar	dxsVariability, lasVariability, udsVariability	WSA	Probability of variable from chi-square (and other data)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jprobVar	uhsVariability	WSAUHS	Probability of variable from chi-square (and other data)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jPsfMag	calSource	WSACalib	Point source profile-fitted J mag	real	4	mag	-0.9999995e9	PHOT_MAG
jPsfMag	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Point source profile-fitted J mag	real	4	mag	-0.9999995e9	PHOT_MAG
jPsfMag	reliableUdsSource, udsSource	WSA	Not available in SE output	real	4	mag	-0.9999995e9	PHOT_MAG
jPsfMag	uhsSource, uhsSourceAll	WSAUHS	Point source profile-fitted J mag	real	4	mag	-0.9999995e9	PHOT_MAG
jPsfMagErr	calSource	WSACalib	Error in point source profile-fitted J mag	real	4	mag	-0.9999995e9	ERROR
jPsfMagErr	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Error in point source profile-fitted J mag	real	4	mag	-0.9999995e9	ERROR
jPsfMagErr	reliableUdsSource, udsSource	WSA	Not available in SE output	real	4	mag	-0.9999995e9	ERROR
jPsfMagErr	uhsSource, uhsSourceAll	WSAUHS	Error in point source profile-fitted J mag	real	4	mag	-0.9999995e9	ERROR
jSeqNum	calSource, calSynopticSource	WSACalib	the running number of the J detection	int	4		-99999999	ID_NUMBER
jSeqNum	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource, udsSource	WSA	the running number of the J detection	int	4		-99999999	ID_NUMBER
jSeqNum	uhsSource, uhsSourceAll	WSAUHS	the running number of the J detection	int	4		-99999999	ID_NUMBER
jSerMag2D	calSource	WSACalib	Extended source J mag (profile-fitted)	real	4	mag	-0.9999995e9	PHOT_MAG
jSerMag2D	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Extended source J mag (profile-fitted)	real	4	mag	-0.9999995e9	PHOT_MAG
jSerMag2D	reliableUdsSource, udsSource	WSA	Not available in SE output	real	4	mag	-0.9999995e9	PHOT_MAG
jSerMag2D	uhsSource, uhsSourceAll	WSAUHS	Extended source J mag (profile-fitted)	real	4	mag	-0.9999995e9	PHOT_MAG
jSerMag2DErr	calSource	WSACalib	Error in extended source J mag (profile-fitted)	real	4	mag	-0.9999995e9	ERROR
jSerMag2DErr	dxsJKsource, dxsSource, gcsPointSource, gcsSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, gpsSource, lasExtendedSource, lasPointSource, lasSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource	WSA	Error in extended source J mag (profile-fitted)	real	4	mag	-0.9999995e9	ERROR
jSerMag2DErr	reliableUdsSource, udsSource	WSA	Not available in SE output	real	4	mag	-0.9999995e9	ERROR
jSerMag2DErr	uhsSource, uhsSourceAll	WSAUHS	Error in extended source J mag (profile-fitted)	real	4	mag	-0.9999995e9	ERROR
jskewness	calVariability	WSACalib	Skewness in J band (see Sesar et al. 2007)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jskewness	dxsVariability, lasVariability, udsVariability	WSA	Skewness in J band (see Sesar et al. 2007)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jskewness	uhsVariability	WSAUHS	Skewness in J band (see Sesar et al. 2007)	real	4		-0.9999995e9
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jtotalPeriod	calVariability	WSACalib	total period of observations (last obs-first obs)	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jtotalPeriod	dxsVariability, lasVariability, udsVariability	WSA	total period of observations (last obs-first obs)	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
jtotalPeriod	uhsVariability	WSAUHS	total period of observations (last obs-first obs)	real	4	days	-0.9999995e9
			The observations are classified as good, flagged or missing. Flagged observations are ones where the object has a ppErrBit flag. Missing observations are observations of the part of the sky that include the position of the object, but had no detection. All the statistics are calculated from good observations. The cadence parameters give the minimum, median and maximum time between observations, which is useful to know if the data could be used to find a particular type of variable.
julianDayNum	Multiframe	WSA	the Julian Day number of the UKIRT night	int	4	Julian days		time.epoch
julianDayNum	Multiframe	WSACalib	the Julian Day number of the UKIRT night	int	4	Julian days		time.epoch
julianDayNum	Multiframe	WSATransit	the Julian Day number of the UKIRT night	int	4	Julian days		time.epoch
julianDayNum	Multiframe	WSAUHS	the Julian Day number of the UKIRT night	int	4	Julian days		time.epoch
julianDayNum	MultiframeDetector	WSA	the Julian Day number of the UKIRT night {image primary HDU keyword: UTDATE}	int	4	Julian days		time.epoch
julianDayNum	MultiframeDetector	WSACalib	the Julian Day number of the UKIRT night {image primary HDU keyword: UTDATE}	int	4	Julian days		time.epoch
julianDayNum	MultiframeDetector	WSATransit	the Julian Day number of the UKIRT night {image primary HDU keyword: UTDATE}	int	4	Julian days		time.epoch
julianDayNum	MultiframeDetector	WSAUHS	the Julian Day number of the UKIRT night {image primary HDU keyword: UTDATE}	int	4	Julian days		time.epoch
jVarClass	calVariability	WSACalib	Classification of variability in this band	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jVarClass	dxsVariability, lasVariability, udsVariability	WSA	Classification of variability in this band	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jVarClass	uhsVariability	WSAUHS	Classification of variability in this band	smallint	2		-9999
			The photometry is calculated for good observations in the best aperture. The mean, rms, median, median absolute deviation, minMag and maxMag are quite standard. The skewness is calculated as in Sesar et al. 2007, AJ, 134, 2236. The number of good detections that are more than 3 standard deviations can indicate a distribution with many outliers. In each frameset, the mean and rms are used to derive a fit to the expected rms as a function of magnitude. The parameters for the fit are stored in VarFrameSetInfo and the value for the source is in expRms. This is subtracted from the rms in quadrature to get the intrinsic rms: the variability of the object beyond the noise in the system. The chi-squared is calculated, assuming a non-variable object which has the noise from the expected-rms and mean calculated as above. The probVar statistic assumes a chi-squared distribution with the correct number of degrees of freedom. The varClass statistic is 1, if the probVar>0.9 and intrinsicRMS/expectedRMS>3.
jXi	calSource, calSynopticSource	WSACalib	Offset of J detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
jXi	dxsJKsource, gcsPointSource, gcsZYJHKsource, gpsJHKsource, gpsPointSource, lasExtendedSource, lasPointSource, lasYJHKsource, reliableDxsSource, reliableGcsPointSource, reliableGpsPointSource, reliableLasPointSource, reliableUdsSource	WSA	Offset of J detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
jXi	dxsSource, gcsSource, gpsSource, lasSource, udsSource	WSA	Offset of J detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.
jXi	uhsSource, uhsSourceAll	WSAUHS	Offset of J detection from master position (+east/-west)	real	4	arcsec	-0.9999995e9	POS_EQ_RA_OFF
			When associating individual passband detections into merged sources, a generous (in terms of the positional uncertainties) pairing radius of 2.0 (UKIDSS LAS and GPS; UHS; also non-survey programmes) or 1.0 (UKIDSS GPS, DXS and UDS) arcseconds is used, the higher value enabling pairing of moving sources when epoch separations may be several years. 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 LAS, you might wish to insist that the offsets in the selected sample are all below 1 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.