VSA Browser

Glossary of VSA attributes

This Glossary alphabetically lists all attributes used in the VSAv20240304 database(s) held in the VSA. If you would like to have more information about the schema tables please use the VSAv20240304 Schema Browser (other Browser versions).

A B C D E F G H I J K L M
N O P Q R S T U V W X Y Z

F

Name Schema Table Database Description Type Length Unit Default Value Unified Content Descriptor

F1 glimpse_hrc_inter, glimpse_mca_inter GLIMPSE Flux in IRAC band 1 real 4 mJy -999.9

f1 hipparcos_new_reduction GAIADR1 Percentage rejected data int 4 arith.ratio;stat.value

F1_err glimpse_hrc_inter, glimpse_mca_inter GLIMPSE 1sigma flux error (IRAC band 1) real 4 mJy -999.9

F1_rms glimpse_hrc_inter, glimpse_mca_inter GLIMPSE RMS dev. of detection from F1 real 4 mJy -999.9

F2 glimpse_hrc_inter, glimpse_mca_inter GLIMPSE Flux in IRAC band 2 real 4 mJy -999.9

f2 hipparcos_new_reduction GAIADR1 Goodness of fit float 8 stat.fit.goodness

F24umMag spitzer_smcSource SPITZER The SPITZER F24μm band magnitude. real 4 mag

F2_err glimpse_hrc_inter, glimpse_mca_inter GLIMPSE 1sigma flux error (IRAC band 2) real 4 mJy -999.9

F2_rms glimpse_hrc_inter, glimpse_mca_inter GLIMPSE RMS dev. of detection from F2 real 4 mJy -999.9

F3 glimpse_hrc_inter, glimpse_mca_inter GLIMPSE Flux in IRAC band 3 real 4 mJy -999.9

F3_6 glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 3.6um IRAC (Band 1) flux real 4 mJy -999.9

F3_6_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 3.6um IRAC (Band 1) 1 sigma error real 4 mJy -999.9

F3_6_rms glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE RMS deviation of the individual detections from the final flux for 3.6um IRAC (Band 1) real 4 mJy -999.9

F3_6umMag spitzer_smcSource SPITZER The SPITZER F3.6μm band magnitude. real 4 mag

F3_err glimpse_hrc_inter, glimpse_mca_inter GLIMPSE 1sigma flux error (IRAC band 3) real 4 mJy -999.9

F3_rms glimpse_hrc_inter, glimpse_mca_inter GLIMPSE RMS dev. of detection from F3 real 4 mJy -999.9

F4 glimpse_hrc_inter, glimpse_mca_inter GLIMPSE Flux in IRAC band 4 real 4 mJy -999.9

F4_5 glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 4.5um IRAC (Band 2) flux real 4 mJy -999.9

F4_5_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 4.5um IRAC (Band 2) 1 sigma error real 4 mJy -999.9

F4_5_rms glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE RMS deviation of the individual detections from the final flux for 4.5um IRAC (Band 2) real 4 mJy -999.9

F4_5umMag spitzer_smcSource SPITZER The SPITZER F4.5μm band magnitude. real 4 mag

F4_err glimpse_hrc_inter, glimpse_mca_inter GLIMPSE 1sigma flux error (IRAC band 4) real 4 mJy -999.9

F4_rms glimpse_hrc_inter, glimpse_mca_inter GLIMPSE RMS dev. of detection from F4 real 4 mJy -999.9

F5_8 glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 5.8um IRAC (Band 3) flux real 4 mJy -999.9

F5_8_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 5.8um IRAC (Band 3) 1 sigma error real 4 mJy -999.9

F5_8_rms glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE RMS deviation of the individual detections from the final flux for 5.8um IRAC (Band 3) real 4 mJy -999.9

F5_8umMag spitzer_smcSource SPITZER The SPITZER F5.8μm band magnitude. real 4 mag

F70umMag spitzer_smcSource SPITZER The SPITZER F70μm band magnitude. real 4 mag

F8_0 glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 8.0um IRAC (Band 4) flux real 4 mJy -999.9

F8_0_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 8.0um IRAC (Band 4) 1 sigma error real 4 mJy -999.9

F8_0_rms glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE RMS deviation of the individual detections from the final flux for 8.0um IRAC (Band 4) real 4 mJy -999.9

F8_0umMag spitzer_smcSource SPITZER The SPITZER F8.0μm band magnitude. real 4 mag

f_resFlux nvssSource NVSS [PS* ] Residual Code varchar 2 meta.code

faPcorrelation2 vvvVivaCatalogue VVVDR5 False alarm probability for Kfi variability index {catalogue TType keyword: FAPcorrelation2} float 8 -9.999995e8

fCor_100 iras_psc IRAS Flux correction factor applied (times 1000, 100 micron) smallint 2 instr.param

fCor_12 iras_psc IRAS Flux correction factor applied (times 1000, 12 micron) smallint 2 instr.param

fCor_25 iras_psc IRAS Flux correction factor applied (times 1000, 25 micron) smallint 2 instr.param

fCor_60 iras_psc IRAS Flux correction factor applied (times 1000, 60 micron) smallint 2 instr.param

Fe ravedr5Source RAVE [Fe/H] abundance of Fe real 4 dex phys.abund.Z

Fe_N ravedr5Source RAVE Number of used spectral lines in calc. of [Fe/H] smallint 2 meta.number

fg_flg twomass_xsc TWOMASS flux-growth convergence flag. varchar 6 meta.code

FH glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 2MASS All-Sky PSC H Band flux real 4 mJy -999.9

FH_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 2MASS All-Sky PSC H Band 1 sigma error real 4 mJy -999.9

FiberNumber ravedr5Source RAVE Instrument fiber number (2df) [1..150] tinyint 1 meta.id;instr.part

FIBRE_R spectra SIXDF fibre number (row on CCD) smallint 2

FIBRE_V spectra SIXDF fibre number (row on CCD) smallint 2

field nvssSource NVSS Name of the original survey image field from which the component was derived. varchar 8 obs.field

field1 iras_asc IRAS object field #1 (magnitude/other) smallint 2 obs.field

field2 iras_asc IRAS object field #2 (magnitude/other) smallint 2 obs.field

field3 iras_asc IRAS object field #3 (size/other) smallint 2 obs.field

fieldID ExternalProductCatalogue SHARKSv20210222 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue SHARKSv20210421 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue ULTRAVISTADR4 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VHSDR3 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSDR4 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSDR5 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSDR6 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSv20150108 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSv20160114 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSv20160507 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSv20170630 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VHSv20180419 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VHSv20201209 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VIDEODR4 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VIDEODR5 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VIKINGDR4 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VIKINGv20150421 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VIKINGv20151230 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VIKINGv20160406 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VIKINGv20161202 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VIKINGv20170715 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCDEEPv20230713 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VMCDR4 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCDR5 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VMCv20140428 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20140903 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20150309 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20151218 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20160311 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20160822 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20170109 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20170411 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20171101 ID of field varchar 8 NONE meta.id

fieldID ExternalProductCatalogue VMCv20180702 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VMCv20181120 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VMCv20191212 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VMCv20210708 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VMCv20230816 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VMCv20240226 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VVVDR5 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue VVVXDR1 ID of field varchar 16 NONE meta.id

fieldID ExternalProductCatalogue, vmcCepheidVariables, vmcPsfCatalogue VMCDR3 ID of field varchar 8 NONE meta.id

fieldID ProgrammeFrame SHARKSv20210222 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame SHARKSv20210421 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame ULTRAVISTADR4 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VHSDR6 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VHSv20180419 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VHSv20201209 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCDEEPv20230713 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCDR5 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCv20171101 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCv20180702 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCv20181120 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCv20191212 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCv20210708 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCv20230816 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VMCv20240226 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VSAQC UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VVVDR5 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID ProgrammeFrame VVVXDR1 UID of position on sky, set just after ProgrammeBuilder runs int 4 -99999999 meta.bib

fieldID RegionFieldLinks SHARKSv20210222 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks SHARKSv20210421 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks ULTRAVISTADR4 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VHSv20201209 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VMCDEEPv20230713 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VMCDR5 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VMCv20191212 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VMCv20210708 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VMCv20230816 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VMCv20240226 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VVVDR5 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RegionFieldLinks VVVXDR1 Identifier assigned to each pointing in RequiredMosaic int 4 ??

fieldID RequiredMergeLogMultiEpoch SHARKSv20210222 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch SHARKSv20210421 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch ULTRAVISTADR4 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VHSDR5 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VHSDR6 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VHSv20160114 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VHSv20160507 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VHSv20170630 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VHSv20180419 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VHSv20201209 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VIKINGv20151230 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VIKINGv20160406 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VIKINGv20161202 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VIKINGv20170715 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCDEEPv20230713 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCDR4 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCDR5 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20151218 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20160311 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20160822 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20170109 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20170411 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20171101 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20180702 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20181120 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20191212 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20210708 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20230816 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VMCv20240226 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VVVDR5 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMergeLogMultiEpoch VVVXDR1 UID of position on sky. References Required{productType}.fieldID int 4 -99999999 ??

fieldID RequiredMosaic SHARKSv20210421 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic ULTRAVISTADR4 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSDR1 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSDR2 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSDR3 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSDR4 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSDR5 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSDR6 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20120926 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20130417 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20150108 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20160114 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20160507 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20170630 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20180419 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VHSv20201209 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIDEODR2 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIDEODR3 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIDEODR4 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIDEODR5 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIDEOv20111208 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGDR2 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGDR3 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGDR4 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20110714 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20111019 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20130417 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20150421 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20151230 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20160406 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20161202 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VIKINGv20170715 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCDEEPv20230713 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCDR1 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCDR3 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCDR4 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCDR5 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20110816 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20110909 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20120126 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20121128 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20130304 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20130805 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20140428 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20140903 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20150309 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20151218 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20160311 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20160822 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20170109 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20170411 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20171101 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20180702 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20181120 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20191212 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20210708 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20230816 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VMCv20240226 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VVVDR1 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VVVDR2 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VVVDR5 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VVVXDR1 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VVVv20100531 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic VVVv20110718 UID of position on sky. int 4 -99999999 ??

fieldID RequiredMosaic, RequiredStack, RequiredTile SHARKSv20210222 UID of position on sky. int 4 -99999999 ??

fieldID StdFieldInfo VIDEOv20100513 The fieldID is a UID identifying each of the 43 standard fields that are observed as part of the calibration observations int 4 obs.field

fieldID StdFieldInfo VIKINGv20110714 The fieldID is a UID identifying each of the 43 standard fields that are observed as part of the calibration observations int 4 obs.field

fieldID StdFieldInfo VVVv20100531 The fieldID is a UID identifying each of the 43 standard fields that are observed as part of the calibration observations int 4 obs.field

fieldID rosat_bsc, rosat_fsc ROSAT identification number of SASS field varchar 8 obs.field

fieldID ultravistaMapLcVarFrameSetInfo ULTRAVISTADR4 fieldID, assigned in grouping procedure bigint 8 meta.id;obs.field

fieldID ultravistaMapLcVariability ULTRAVISTADR4 field ID assigned by ProgrammeBuilder module when grouping. bigint 8 meta.id;obs.field

fieldID vmcRRlyraeVariables VMCDR4 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20160822 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20170109 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20170411 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20171101 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20180702 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20181120 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20191212 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20210708 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20230816 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldID vmcRRlyraeVariables VMCv20240226 ID of field {catalogue TType keyword: FIELDID} varchar 8 NONE meta.id

fieldid smashdr2_source SMASH Field ID int 4

FieldName ravedr5Source RAVE Center of Observed Field (RA/Dec) varchar 8 meta.id;meta.file

fieldName PreviousCalibParams SHARKSv20210222 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams SHARKSv20210421 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams VHSv20201209 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams VMCDEEPv20230713 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams VMCv20210708 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams VMCv20230816 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams VMCv20240226 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams VVVDR5 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName PreviousCalibParams VVVXDR1 Pointing within the table (if all updated in the same way, use ALL) varchar 16

fieldName StdFieldInfo VIDEOv20100513 reference name of field varchar 16 NONE ????

fieldName StdFieldInfo VIKINGv20110714 reference name of field varchar 16 NONE ????

fieldName StdFieldInfo VVVv20100531 reference name of field varchar 16 NONE ????

fieldName first08Jul16Source, firstSource, firstSource12Feb16 FIRST Name of the coadded image containing the source (encodes the position of the field center). varchar 12 obs.image

fieldName vmcPointings VMCDR4 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCDR5 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20160311 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20160822 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20170109 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20170411 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20171101 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20180702 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20181120 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20191212 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20210708 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20230816 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPointings VMCv20240226 Pointing name, region_tile e.g. LMC_8_8 varchar 16 NONE meta.id,meta.main

fieldName vmcPsfDetections VMCv20181120 ID of field varchar 8 NONE meta.id

fieldName vmcPsfDetections, vmcPsfSource VMCv20180702 ID of field varchar 8 NONE meta.id

fieldName vvvPointings VVVDR5 Pointing name, region_tile e.g. B318 varchar 16 NONE meta.id,meta.main

fieldName vvvProperMotionCatalogue, vvvVivaCatalogue VVVDR5 UID of the pointing that this object comes from varchar 16 meta.id

fieldName vvvPsfDaophotJKsMergeLog, vvvPsfDophotZYJHKsMergeLog VVVDR5 the name of the pointing e.g. B418 varchar 16 meta.id,meta.main

fileName ExternalProductCatalogue SHARKSv20210222 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue SHARKSv20210421 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue ULTRAVISTADR4 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSDR3 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSDR4 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSDR5 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSDR6 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSv20150108 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSv20160114 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSv20160507 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSv20170630 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSv20180419 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VHSv20201209 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIDEODR4 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIDEODR5 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIKINGDR4 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIKINGv20150421 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIKINGv20151230 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIKINGv20160406 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIKINGv20161202 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VIKINGv20170715 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCDEEPv20230713 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCDR3 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCDR4 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCDR5 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20140428 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20140903 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20150309 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20151218 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20160311 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20160822 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20170109 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20170411 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20171101 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20180702 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20181120 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20191212 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20210708 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20230816 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VMCv20240226 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VVVDR5 Filename of file sent from survey team varchar 128

fileName ExternalProductCatalogue VVVXDR1 Filename of file sent from survey team varchar 128

fileName Multiframe SHARKSv20210222 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe SHARKSv20210421 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe ULTRAVISTADR4 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSDR1 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSDR2 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSDR3 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSDR4 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSDR5 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSDR6 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20120926 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20130417 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20140409 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20150108 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20160114 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20160507 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20170630 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20180419 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VHSv20201209 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIDEODR2 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIDEODR3 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIDEODR4 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIDEODR5 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIDEOv20100513 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIDEOv20111208 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGDR2 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGDR3 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGDR4 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20110714 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20111019 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20130417 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20140402 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20150421 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20151230 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20160406 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20161202 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VIKINGv20170715 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCDEEPv20230713 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCDR1 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCDR2 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCDR3 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCDR4 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCDR5 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20110816 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20110909 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20120126 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20121128 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20130304 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20130805 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20140428 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20140903 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20150309 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20151218 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20160311 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20160822 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20170109 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20170411 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20171101 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20180702 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20181120 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20191212 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20210708 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20230816 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VMCv20240226 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VVVDR1 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VVVDR2 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VVVDR5 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VVVXDR1 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VVVv20100531 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName Multiframe VVVv20110718 the filename for the multiframe, eg. server:/path/filename.fit varchar 256 'NONE' meta.id;meta.file

fileName sharksMultiframe, ultravistaMultiframe, vhsMultiframe, videoMultiframe, vikingMultiframe, vmcMultiframe, vvvMultiframe VSAQC the filename for the multiframe, eg. server:/path/filename.fit varchar 256 meta.id;meta.file

fileNameRoot ExternalProduct SHARKSv20210222 File name root of the products varchar 32

fileNameRoot ExternalProduct SHARKSv20210421 File name root of the products varchar 32

fileNameRoot ExternalProduct ULTRAVISTADR4 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSDR3 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSDR4 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSDR5 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSDR6 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSv20150108 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSv20160114 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSv20160507 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSv20170630 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSv20180419 File name root of the products varchar 32

fileNameRoot ExternalProduct VHSv20201209 File name root of the products varchar 32

fileNameRoot ExternalProduct VIDEODR4 File name root of the products varchar 32

fileNameRoot ExternalProduct VIDEODR5 File name root of the products varchar 32

fileNameRoot ExternalProduct VIDEOv20111208 File name root of the products varchar 32

fileNameRoot ExternalProduct VIKINGDR4 File name root of the products varchar 32

fileNameRoot ExternalProduct VIKINGv20150421 File name root of the products varchar 32

fileNameRoot ExternalProduct VIKINGv20151230 File name root of the products varchar 32

fileNameRoot ExternalProduct VIKINGv20160406 File name root of the products varchar 32

fileNameRoot ExternalProduct VIKINGv20161202 File name root of the products varchar 32

fileNameRoot ExternalProduct VIKINGv20170715 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCDEEPv20230713 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCDR3 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCDR4 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCDR5 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20140428 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20140903 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20150309 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20151218 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20160311 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20160822 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20170109 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20170411 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20171101 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20180702 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20181120 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20191212 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20210708 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20230816 File name root of the products varchar 32

fileNameRoot ExternalProduct VMCv20240226 File name root of the products varchar 32

fileNameRoot ExternalProduct VVVDR5 File name root of the products varchar 32

fileNameRoot ExternalProduct VVVXDR1 File name root of the products varchar 32

fileTimeStamp Multiframe SHARKSv20210222 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe SHARKSv20210421 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe ULTRAVISTADR4 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSDR1 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSDR2 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSDR3 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSDR4 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSDR5 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSDR6 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20120926 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20130417 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20140409 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20150108 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20160114 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20160507 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20170630 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20180419 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VHSv20201209 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIDEODR2 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIDEODR3 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIDEODR4 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIDEODR5 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIDEOv20100513 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIDEOv20111208 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGDR2 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGDR3 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGDR4 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20110714 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20111019 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20130417 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20140402 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20150421 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20151230 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20160406 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20161202 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VIKINGv20170715 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCDEEPv20230713 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCDR1 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCDR2 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCDR3 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCDR4 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCDR5 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20110816 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20110909 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20120126 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20121128 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20130304 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20130805 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20140428 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20140903 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20150309 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20151218 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20160311 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20160822 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20170109 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20170411 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20171101 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20180702 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20181120 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20191212 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20210708 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20230816 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VMCv20240226 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VVVDR1 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VVVDR2 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VVVDR5 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VVVXDR1 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VVVv20100531 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp Multiframe VVVv20110718 Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 -99999999 ??

fileTimeStamp sharksMultiframe, ultravistaMultiframe, vhsMultiframe, videoMultiframe, vikingMultiframe, vmcMultiframe, vvvMultiframe VSAQC Time stamp digits (from the original CASU directory name and file time stamp) for enforcing uniqueness bigint 8 ??

filter smashdr2_source SMASH Filter, u, g, r, i, or z varchar 1

filter1 RequiredDiffImage SHARKSv20210222 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage SHARKSv20210421 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage ULTRAVISTADR4 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSDR1 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSDR2 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSDR3 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSDR4 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSDR5 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSDR6 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20120926 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20130417 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20150108 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20160114 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20160507 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20170630 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20180419 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VHSv20201209 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIDEODR2 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIDEODR3 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIDEODR4 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIDEODR5 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIDEOv20100513 UID of WFCAM narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIDEOv20111208 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGDR2 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGDR3 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGDR4 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20110714 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20111019 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20130417 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20150421 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20151230 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20160406 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20161202 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VIKINGv20170715 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCDEEPv20230713 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCDR1 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCDR3 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCDR4 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCDR5 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20110816 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20110909 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20120126 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20121128 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20130304 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20130805 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20140428 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20140903 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20150309 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20151218 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20160311 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20160822 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20170109 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20170411 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20171101 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20180702 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20181120 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20191212 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20210708 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20230816 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VMCv20240226 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VVVDR1 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VVVDR2 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VVVDR5 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VVVXDR1 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VVVv20100531 UID of WFCAM narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1 RequiredDiffImage VVVv20110718 UID of narrow band (primary) filter tinyint 1 meta.code;instr.filter

filter1_bfilmax machoLMCSource, machoSMCSource MACHO Filter 1, blue: max value of optimum filter for LC real 4

filter1_bfiltime machoLMCSource, machoSMCSource MACHO Filter 1, blue: LC time at which maximum occurred real 4

filter1_bNhi machoLMCSource, machoSMCSource MACHO Filter 1, blue: number points sigmathreshold high within duration of filter at peak (bfiltime) smallint 2

filter1_rfilmax machoLMCSource, machoSMCSource MACHO Filter 1, red: max value of optimum filter for LC real 4

filter1_rfiltime machoLMCSource, machoSMCSource MACHO Filter 1, red: LC time at which maximum occurred real 4

filter1_rNhi machoLMCSource, machoSMCSource MACHO Filter 1, red: number points sigmathreshold high within duration of filter at peak (rfiltime) smallint 2

filter2 RequiredDiffImage SHARKSv20210222 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage SHARKSv20210421 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage ULTRAVISTADR4 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSDR1 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSDR2 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSDR3 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSDR4 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSDR5 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSDR6 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20120926 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20130417 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20150108 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20160114 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20160507 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20170630 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20180419 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VHSv20201209 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIDEODR2 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIDEODR3 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIDEODR4 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIDEODR5 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIDEOv20100513 UID of WFCAM broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIDEOv20111208 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGDR2 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGDR3 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGDR4 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20110714 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20111019 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20130417 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20150421 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20151230 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20160406 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20161202 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VIKINGv20170715 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCDEEPv20230713 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCDR1 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCDR3 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCDR4 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCDR5 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20110816 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20110909 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20120126 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20121128 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20130304 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20130805 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20140428 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20140903 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20150309 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20151218 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20160311 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20160822 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20170109 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20170411 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20171101 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20180702 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20181120 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20191212 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20210708 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20230816 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VMCv20240226 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VVVDR1 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VVVDR2 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VVVDR5 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VVVXDR1 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VVVv20100531 UID of WFCAM broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2 RequiredDiffImage VVVv20110718 UID of broad band (reference) filter to be subtracted tinyint 1 meta.code;instr.filter

filter2_bfilmax machoLMCSource, machoSMCSource MACHO Filter 2, blue: max value of optimum filter for LC real 4

filter2_bfiltime machoLMCSource, machoSMCSource MACHO Filter 2, blue: LC time at which maximum occurred real 4

filter2_bNhi machoLMCSource, machoSMCSource MACHO Filter 2, blue: number points sigmathreshold high within duration of filter at peak (bfiltime) smallint 2

filter2_rfilmax machoLMCSource, machoSMCSource MACHO Filter 2, red: max value of optimum filter for LC real 4

filter2_rfiltime machoLMCSource, machoSMCSource MACHO Filter 2, red: LC time at which maximum occurred real 4

filter2_rNhi machoLMCSource, machoSMCSource MACHO Filter 2, red: number points sigmathreshold high within duration of filter at peak (rfiltime) smallint 2

filter3_bfilmax machoLMCSource, machoSMCSource MACHO Filter 3, blue: max value of optimum filter for LC real 4

filter3_bfiltime machoLMCSource, machoSMCSource MACHO Filter 3, blue: LC time at which maximum occurred real 4

filter3_bNhi machoLMCSource, machoSMCSource MACHO Filter 3, blue: number points sigmathreshold high within duration of filter at peak (bfiltime) smallint 2

filter3_rfilmax machoLMCSource, machoSMCSource MACHO Filter 3, red: max value of optimum filter for LC real 4

filter3_rfiltime machoLMCSource, machoSMCSource MACHO Filter 3, red: LC time at which maximum occurred real 4

filter3_rNhi machoLMCSource, machoSMCSource MACHO Filter 3, red: number points sigmathreshold high within duration of filter at peak (rfiltime) smallint 2

filteredImageName MapFrameStatus SHARKSv20210222 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus SHARKSv20210421 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus ULTRAVISTADR4 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VHSv20201209 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VMCDEEPv20230713 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VMCDR5 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VMCv20191212 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VMCv20210708 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VMCv20230816 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VMCv20240226 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VVVDR5 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filteredImageName MapFrameStatus VVVXDR1 the filename of the associated filtered image name, eg. server:/path/filename_st_tl_two.fit varchar 256 NONE

filterID CombinedFilters SHARKSv20210222 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters SHARKSv20210421 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters ULTRAVISTADR4 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VHSv20201209 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VMCDEEPv20230713 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VMCDR5 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VMCv20191212 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VMCv20210708 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VMCv20230816 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VMCv20240226 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VVVDR5 UID of combined filter tinyint 1 meta.code

filterID CombinedFilters VVVXDR1 UID of combined filter tinyint 1 meta.code

filterID Detection PS1DR2 Filter identifier. Details in the Filter table. tinyint 1

filterID Filter SHARKSv20210421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter ULTRAVISTADR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSDR6 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20120926 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20150108 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20160114 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20160507 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20170630 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20180419 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VHSv20201209 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIDEODR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIDEODR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIDEODR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIDEODR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIDEOv20100513 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIDEOv20111208 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20110714 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20111019 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20150421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20151230 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20160406 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20161202 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VIKINGv20170715 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCDEEPv20230713 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20110816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20110909 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20120126 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20121128 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20130304 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20130805 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20140428 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20140903 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20150309 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20151218 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20160311 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20160822 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20170109 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20170411 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20171101 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20180702 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20181120 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20191212 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20210708 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20230816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VMCv20240226 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VSAQC UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VVVDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VVVDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VVVDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VVVXDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VVVv20100531 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter VVVv20110718 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID Filter, MapFilterLupt, RequiredFilters, RequiredMosaic, RequiredStack, RequiredTile SHARKSv20210222 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID FilterExtinctionCoefficients EXTINCT UID of filter smallint 2 meta.id;meta.main

filterID FilterSections SHARKSv20210421 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections ULTRAVISTADR4 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSDR3 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSDR4 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSDR5 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSDR6 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSv20150108 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSv20160114 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSv20160507 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSv20170630 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSv20180419 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VHSv20201209 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIDEODR4 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIDEODR5 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIKINGDR4 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIKINGv20150421 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIKINGv20151230 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIKINGv20160406 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIKINGv20161202 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VIKINGv20170715 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCDEEPv20230713 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCDR3 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCDR4 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCDR5 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20140428 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20140903 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20150309 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20151218 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20160311 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20160822 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20170109 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20170411 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20171101 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20180702 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20181120 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20191212 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20210708 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20230816 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VMCv20240226 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VSAQC UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VVVDR5 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections VVVXDR1 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID FilterSections, RequiredMergeLogMultiEpoch SHARKSv20210222 UID of combined filter (assigned in OSA: 1=u,2=g,3=r,4=i,5=z,6=blank) tinyint 1 meta.code;instr.filter

filterID Multiframe SHARKSv20210222 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe SHARKSv20210421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe ULTRAVISTADR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSDR6 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20120926 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20140409 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20150108 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20160114 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20160507 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20170630 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20180419 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VHSv20201209 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIDEODR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIDEODR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIDEODR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIDEODR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIDEOv20100513 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIDEOv20111208 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20110714 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20111019 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20140402 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20150421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20151230 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20160406 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20161202 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VIKINGv20170715 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCDEEPv20230713 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20110816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20110909 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20120126 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20121128 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20130304 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20130805 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20140428 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20140903 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20150309 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20151218 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20160311 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20160822 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20170109 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20170411 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20171101 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20180702 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20181120 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20191212 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20210708 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20230816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VMCv20240226 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VVVDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VVVDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VVVDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VVVXDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VVVv20100531 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID Multiframe VVVv20110718 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector SHARKSv20210222 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector SHARKSv20210421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector ULTRAVISTADR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSDR6 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20120926 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20140409 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20150108 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20160114 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20160507 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20170630 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20180419 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VHSv20201209 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIDEODR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIDEODR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIDEODR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIDEODR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIDEOv20100513 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIDEOv20111208 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20110714 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20111019 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20140402 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20150421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20151230 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20160406 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20161202 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VIKINGv20170715 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCDEEPv20230713 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20110816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20110909 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20120126 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20121128 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20130304 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20130805 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20140428 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20140903 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20150309 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20151218 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20160311 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20160822 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20170109 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20170411 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20171101 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20180702 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20181120 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20191212 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20210708 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20230816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VMCv20240226 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VVVDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VVVDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VVVDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VVVXDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VVVv20100531 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID MultiframeDetector VVVv20110718 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} tinyint 1 0 meta.code;instr.filter

filterID RequiredListDrivenProduct VHSv20120926 filterID of the data that the list is driven from. If 0, then take the source list. tinyint 1 0

filterID RequiredListDrivenProduct VIDEODR3 filterID of the data that the list is driven from. If 0, then take the source list. tinyint 1 0

filterID RequiredListDrivenProduct VIKINGDR3 filterID of the data that the list is driven from. If 0, then take the source list. tinyint 1 0

filterID RequiredListDrivenProduct VMCv20121128 filterID of the data that the list is driven from. If 0, then take the source list. tinyint 1 0

filterID RequiredListDrivenProduct VMCv20130304 filterID of the data that the list is driven from. If 0, then take the source list. tinyint 1 0

filterID RequiredListDrivenProduct VVVDR1 filterID of the data that the list is driven from. If 0, then take the source list. tinyint 1 0

filterID sharksDetection SHARKSv20210222 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID sharksDetection SHARKSv20210421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID sharksMultiframe, sharksMultiframeDetector, ultravistaMultiframe, ultravistaMultiframeDetector, vhsMultiframe, vhsMultiframeDetector, videoMultiframe, videoMultiframeDetector, vikingMultiframe, vikingMultiframeDetector, vmcMultiframe, vmcMultiframeDetector, vvvMultiframe, vvvMultiframeDetector VSAQC UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks) tinyint 1 meta.code;instr.filter

filterID ultravistaDetection ULTRAVISTADR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID ultravistaMapRemeasAver ULTRAVISTADR4 UID of combined filter (assigned in VSA) tinyint 1 meta.code;instr.filter

filterID ultravistaMapRemeasurement ULTRAVISTADR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSDR6 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20120926 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20140409 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20150108 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20160114 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20160507 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20170630 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20180419 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsDetection VHSv20201209 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vhsListRemeasurement VHSDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID videoDetection VIDEODR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID videoDetection VIDEODR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID videoDetection VIDEODR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID videoDetection VIDEODR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID videoDetection VIDEOv20100513 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID videoDetection VIDEOv20111208 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID videoListRemeasurement VIDEOv20100513 UID of combined filter (assigned in WSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20110714 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20111019 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20130417 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20140402 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20150421 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20151230 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20160406 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20161202 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingDetection VIKINGv20170715 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingListRemeasurement VIKINGv20110714 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingListRemeasurement VIKINGv20111019 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingMapRemeasAver VIKINGZYSELJv20170124 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vikingMapRemeasAver, vikingMapRemeasurement VIKINGZYSELJv20160909 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCDR3 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCDR4 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20110816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20110909 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20120126 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20121128 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20130304 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20130805 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20140428 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20140903 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20150309 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20151218 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20160311 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20160822 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20170109 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20170411 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20171101 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20180702 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20181120 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20191212 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20210708 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20230816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcDetection VMCv20240226 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcListRemeasurement VMCv20110816 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcListRemeasurement VMCv20110909 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vmcdeepDetection VMCDEEPv20230713 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vvvDetection VVVDR1 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vvvDetection VVVDR2 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vvvDetection VVVv20100531 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vvvDetection, vvvDetectionPawPrints, vvvDetectionTiles VVVDR5 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=Ks,8=blank) tinyint 1 meta.code;instr.filter

filterID vvvListRemeasurement VVVv20100531 UID of combined filter (assigned in WSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterID vvvListRemeasurement VVVv20110718 UID of combined filter (assigned in VSA: 1=Z,2=Y,3=J,4=H,5=K,6=H2,7=Br,8=blank) tinyint 1 meta.code;instr.filter

filterIDList CombinedFilters SHARKSv20210222 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters SHARKSv20210421 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters ULTRAVISTADR4 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VHSv20201209 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VMCDEEPv20230713 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VMCDR5 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VMCv20191212 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VMCv20210708 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VMCv20230816 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VMCv20240226 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VVVDR5 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterIDList CombinedFilters VVVXDR1 List of filters as comma separated string. Optional put archive in front if filters from multiple archives: eg. WSA-1,2,3;SDSS-2,3,4 varchar 64

filterList RequiredListDrivenProduct VHSv20130417 the list of filters used in initial selection? (standard programmeFilters) if NONE varchar 64 NONE

filterList RequiredListDrivenProduct VIKINGv20130417 the list of filters used in initial selection? (standard programmeFilters) if NONE varchar 64 NONE

filterList RequiredListDrivenProduct VMCv20130805 the list of filters used in initial selection? (standard programmeFilters) if NONE varchar 64 NONE

filterN machoLMCSource, machoSMCSource MACHO number of filters applied; always 3 smallint 2

filterName Multiframe SHARKSv20210222 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe SHARKSv20210421 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe ULTRAVISTADR4 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSDR1 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSDR2 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSDR3 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSDR4 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSDR5 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSDR6 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20120926 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20130417 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20140409 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20150108 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20160114 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20160507 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20170630 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20180419 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VHSv20201209 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIDEODR2 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIDEODR3 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIDEODR4 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIDEODR5 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIDEOv20100513 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIDEOv20111208 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGDR2 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGDR3 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGDR4 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20110714 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20111019 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20130417 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20140402 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20150421 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20151230 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20160406 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20161202 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VIKINGv20170715 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCDEEPv20230713 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCDR1 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCDR2 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCDR3 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCDR4 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCDR5 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20110816 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20110909 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20120126 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20121128 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20130304 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20130805 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20140428 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20140903 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20150309 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20151218 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20160311 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20160822 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20170109 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20170411 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20171101 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20180702 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20181120 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20191212 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20210708 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20230816 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VMCv20240226 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VVVDR1 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VVVDR2 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VVVDR5 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VVVXDR1 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VVVv20100531 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName Multiframe VVVv20110718 VISTA combined filter name {image primary HDU keyword: HIERARCH ESO INS FILT1 NAME} varchar 16 'NONE' ??

filterName sharksMultiframe, ultravistaMultiframe, vhsMultiframe, videoMultiframe, vikingMultiframe, vmcMultiframe, vvvMultiframe VSAQC VISTA combined filter name varchar 16 ??

filterType Filter SHARKSv20210222 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter SHARKSv20210421 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter ULTRAVISTADR4 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSDR4 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSDR5 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSDR6 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSv20150108 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSv20160114 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSv20160507 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSv20170630 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSv20180419 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VHSv20201209 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VIDEODR4 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VIDEODR5 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VIKINGv20150421 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VIKINGv20151230 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VIKINGv20160406 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VIKINGv20161202 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VIKINGv20170715 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCDEEPv20230713 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCDR4 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCDR5 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20140903 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20150309 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20151218 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20160311 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20160822 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20170109 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20170411 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20171101 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20180702 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20181120 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20191212 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20210708 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20230816 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VMCv20240226 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VSAQC The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VVVDR5 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

filterType Filter VVVXDR1 The type of filter BROAD, NARROW, BROADLIST varchar 16 NONE

finalProductTable RequiredMatchedApertureProduct SHARKSv20210222 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct SHARKSv20210421 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct ULTRAVISTADR4 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VHSv20201209 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VMCDEEPv20230713 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VMCDR5 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VMCv20191212 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VMCv20210708 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VMCv20230816 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VMCv20240226 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VVVDR5 the name of the final product table for this product varchar 64 meta.id;meta.dataset

finalProductTable RequiredMatchedApertureProduct VVVXDR1 the name of the final product table for this product varchar 64 meta.id;meta.dataset

fInt first08Jul16Source, firstSource, firstSource12Feb16 FIRST integrated flux densities real 4 mJy phot.flux.density;em.radio.750-1500MHz

Fit_Flag_Binney ravedr5Source RAVE See final paragraph 3 (Binney et al. 2014) int 4 meta.code.qual

Fitmag_I denisDR3Source DENIS Magnitude in I band from PSF fit float 8 mag

Fitmag_J denisDR3Source DENIS Magnitude in J band from PSF fit float 8 mag

Fitmag_K denisDR3Source DENIS Magnitude in K band from PSF fit float 8 mag

FitQuality_Binney ravedr5Source RAVE Given by symbol F in eq 15 of Binney et al. (2014) real 4 meta.code.qual

FJ glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 2MASS All-Sky PSC J Band flux real 4 mJy -999.9

FJ_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 2MASS All-Sky PSC J Band 1 sigma error real 4 mJy -999.9

FKs glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 2MASS All-Sky PSC Ks Band flux real 4 mJy -999.9

FKs_err glimpse1_hrc, glimpse1_mca, glimpse2_hrc, glimpse2_mca GLIMPSE 2MASS All-Sky PSC Ks Band 1 sigma error real 4 mJy -999.9

flag sharksSourceXDetectionBestMatch SHARKSv20210222 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag sharksSourceXDetectionBestMatch SHARKSv20210421 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag smashdr2_deep, smashdr2_object SMASH OR-combined Source Extractor FLAG value from coadd image smallint 2

flag smashdr2_source SMASH Source Extractor FLAG value from coadd image smallint 2

flag ultravistaSourceXDetectionBestMatch ULTRAVISTADR4 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag videoSourceXDetectionBestMatch VIDEODR2 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag videoSourceXDetectionBestMatch VIDEODR3 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag videoSourceXDetectionBestMatch VIDEODR4 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag videoSourceXDetectionBestMatch VIDEODR5 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag videoSourceXDetectionBestMatch VIDEOv20100513 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag videoSourceXDetectionBestMatch VIDEOv20111208 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGDR2 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGDR3 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGDR4 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20110714 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20111019 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20130417 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20140402 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20150421 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20151230 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20160406 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20161202 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vikingSourceXDetectionBestMatch VIKINGv20170715 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCDR1 Flag for potential matching problems int 4 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCDR2 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCDR3 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCDR4 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCDR5 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20110816 Flag for potential matching problems int 4 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20110909 Flag for potential matching problems int 4 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20120126 Flag for potential matching problems int 4 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20121128 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20130304 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20130805 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20140428 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20140903 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20150309 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20151218 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20160311 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20160822 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20170109 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20170411 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20171101 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20180702 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20181120 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20191212 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20210708 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20230816 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcSourceXSynopticSourceBestMatch VMCv20240226 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vmcdeepSourceXSynopticSourceBestMatch VMCDEEPv20230713 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vvvSourceXDetectionBestMatch VVVDR1 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vvvSourceXDetectionBestMatch VVVDR2 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vvvSourceXDetectionBestMatch VVVDR5 Flag for potential matching problems tinyint 1 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vvvSourceXDetectionBestMatch VVVv20100531 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vvvSourceXDetectionBestMatch VVVv20110718 Flag for potential matching problems tinyint 1 0

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag vvvSourceXSynopticSourceBestMatch VVVDR1 Flag for potential matching problems int 4 0 meta.code.qual

flag=1 if the same intermediate stack detection is linked to two different unique sources. This can happen in images where the seeing was poorer than average or if a source has moved over time and overlaps with another source. flag=2 no intermediate stack detection, but the expected location is in 1 dither offset of the edge of the stack.

flag160 sage_lmcMips160Source SPITZER How many times a source was observed by different AORs in a single epoch int 4

flag24 sage_lmcMips24Source SPITZER How many times a source was observed by different AORs in a single epoch int 4

flag70 sage_lmcMips70Source SPITZER How many times a source was observed by different AORs in a single epoch int 4

Flag_I denisDR3Source DENIS Image and source flag in I band This flag is the concatenation of image and source flags, in hexadecimal format. For the image flag, the first two digits contain: Bit 0 - clouds during observation; Bit 1 - electronic Read-Out problem; Bit 2 - internal temperature problem; Bit 3 - very bright star; Bit 4 - bright star; Bit 5 - stray light; Bit 6 - unknown problem. For the source flag, the last two digits contain: Bit 0 - source might be a dust on mirror; Bit 1 - source is a ghost detection of a bright star; Bit 2 - source is saturated; Bit 3 - source is multiple detect. varchar 5

Flag_J denisDR3Source DENIS Image and source flag in J band This flag is the concatenation of image and source flags, in hexadecimal format. For the image flag, the first two digits contain: Bit 0 - clouds during observation; Bit 1 - electronic Read-Out problem; Bit 2 - internal temperature problem; Bit 3 - very bright star; Bit 4 - bright star; Bit 5 - stray light; Bit 6 - unknown problem. For the source flag, the last two digits contain: Bit 0 - source might be a dust on mirror; Bit 1 - source is a ghost detection of a bright star; Bit 2 - source is saturated; Bit 3 - source is multiple detect. varchar 5

Flag_K denisDR3Source DENIS Image and source flag in K band This flag is the concatenation of image and source flags, in hexadecimal format. For the image flag, the first two digits contain: Bit 0 - clouds during observation; Bit 1 - electronic Read-Out problem; Bit 2 - internal temperature problem; Bit 3 - very bright star; Bit 4 - bright star; Bit 5 - stray light; Bit 6 - unknown problem. For the source flag, the last two digits contain: Bit 0 - source might be a dust on mirror; Bit 1 - source is a ghost detection of a bright star; Bit 2 - source is saturated; Bit 3 - source is multiple detect. varchar 5

Flag_mult denisDR3Source DENIS Multiplicity flag; if set to 1, this flag indicates that the source was detected in two consecutive images, and that the 2 measurements have been combined. tinyint 1

flagDataType vvvVivaCatalogue VVVDR5 Flag about data type, i.e correlated data (CCD) or non-correlated data (NCD) {catalogue TType keyword: FlagDataType} varchar 4 NONE

FLAGEQ akari_lmc_psa_v1, akari_lmc_psc_v1 AKARI Eqband flag that indicates the band at which the coordinates are determined (0:N3, 1:S7, 2:S11, 3:L15, 4:L24) char 1

flagFbias6 vvvVivaCatalogue VVVDR5 Counts of periods within $10^{-6}$ periods, calculated per tile (for more details see Sect. \ref{sec_mainperiod}) related with FreqLSG {catalogue TType keyword: FlagFbias6} int 4 -9999

flagFbias7 vvvVivaCatalogue VVVDR5 Counts of periods within $10^{-7}$ periods, calculated per tile (for more details see Sect. \ref{sec_mainperiod}) related with FreqLSG {catalogue TType keyword: FlagFbias7} int 4 -9999

flagNfreq vvvVivaCatalogue VVVDR5 Number of frequencies in agreement with FreqLSG or its harmonic or subharmonic. It assumes values from 1 to 5 {catalogue TType keyword: FlagNfreq} smallint 2 -9999

FLAGS mgcDetection MGC Extraction flags int 4

flags masterDR2 SKYMAPPER Bitwise OR of Source Extractor flags across all observations smallint 2 meta.code

flags_psf masterDR2 SKYMAPPER Bitmask indicating whether photometry is likely biased by neighbours at >1%; bits 0-5 correspond to filters z-u int 4 meta.code

FLAGSL15 akari_lmc_psa_v1, akari_lmc_psc_v1 AKARI Star designation
The flag consist of seven characters: exposure, photometry, saturation, mux bleed, column pulldown, artifact, and multiple flags. char 7 9999999

FLAGSL24 akari_lmc_psa_v1, akari_lmc_psc_v1 AKARI Star designation
The flag consist of seven characters: exposure, photometry, saturation, mux bleed, column pulldown, artifact, and multiple flags. char 7 9999999

FLAGSN3 akari_lmc_psa_v1, akari_lmc_psc_v1 AKARI Star designation
The flag consist of seven characters: exposure, photometry, saturation, mux bleed, column pulldown, artifact, and multiple flags. char 7 9999999

FLAGSS11 akari_lmc_psa_v1, akari_lmc_psc_v1 AKARI Star designation
The flag consist of seven characters: exposure, photometry, saturation, mux bleed, column pulldown, artifact, and multiple flags. char 7 9999999

FLAGSS7 akari_lmc_psa_v1, akari_lmc_psc_v1 AKARI Star designation
The flag consist of seven characters: exposure, photometry, saturation, mux bleed, column pulldown, artifact, and multiple flags. char 7 9999999

flame_flags gaia_source GAIADR2 Flags from Apsis-FLAME analysis bigint 8 meta.code

flatID Multiframe SHARKSv20210222 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe SHARKSv20210421 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe ULTRAVISTADR4 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSDR1 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSDR2 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSDR3 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSDR4 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSDR5 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSDR6 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20120926 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20130417 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20140409 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20150108 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20160114 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20160507 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20170630 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20180419 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VHSv20201209 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIDEODR2 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIDEODR3 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIDEODR4 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIDEODR5 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIDEOv20100513 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIDEOv20111208 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGDR2 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGDR3 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGDR4 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20110714 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20111019 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20130417 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20140402 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20150421 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20151230 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20160406 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20161202 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VIKINGv20170715 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCDEEPv20230713 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCDR1 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCDR2 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCDR3 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCDR4 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCDR5 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20110816 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20110909 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20120126 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20121128 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20130304 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20130805 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20140428 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20140903 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20150309 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20151218 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20160311 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20160822 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20170109 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20170411 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20171101 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20180702 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20181120 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20191212 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20210708 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20230816 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VMCv20240226 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VVVDR1 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VVVDR2 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VVVDR5 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VVVXDR1 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VVVv20100531 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID Multiframe VVVv20110718 UID of library calibration flatfield frame {image extension keyword: FLATCOR} bigint 8 -99999999 obs.field

flatID sharksMultiframe, ultravistaMultiframe, vhsMultiframe, videoMultiframe, vikingMultiframe, vmcMultiframe, vvvMultiframe VSAQC UID of library calibration flatfield frame bigint 8 -99999999 obs.field

flux160 sage_lmcMips160Source SPITZER 160um flux float 8 mJy

flux24 sage_lmcMips24Source SPITZER 24um flux float 8 mJy

flux3_6 sage_lmcIracSource SPITZER 3.6um flux real 4 mJy

flux3_6 sage_smcIRACv1_5Source SPITZER 3.6um IRAC (Band 1) flux real 4 mJy

flux4_5 sage_lmcIracSource SPITZER 4.5um flux real 4 mJy

flux4_5 sage_smcIRACv1_5Source SPITZER 4.5um IRAC (Band 1) flux real 4 mJy

flux5_8 sage_lmcIracSource SPITZER 5.8um flux real 4 mJy

flux5_8 sage_smcIRACv1_5Source SPITZER 5.8um IRAC (Band 1) flux real 4 mJy

flux70 sage_lmcMips70Source SPITZER 70um flux float 8 mJy

flux8_0 sage_lmcIracSource SPITZER 8.0um flux real 4 mJy

flux8_0 sage_smcIRACv1_5Source SPITZER 8.0um IRAC (Band 1) flux real 4 mJy

flux_100 iras_psc IRAS Averaged non-color corrected 100 micron flux density real 4 Jansky (1.0E-26 W/m**2/Hz) phot.flux.density;em.IR.60-100um

flux_12 iras_psc IRAS Averaged non-color corrected 12 micron flux density real 4 Jansky (1.0E-26 W/m**2/Hz) phot.flux.density;em.IR.8-15um

flux_25 iras_psc IRAS Averaged non-color corrected 25 micron flux density real 4 Jansky (1.0E-26 W/m**2/Hz) phot.flux.density;em.IR.15-30um

flux_60 iras_psc IRAS Averaged non-color corrected 60 micron flux density real 4 Jansky (1.0E-26 W/m**2/Hz) phot.flux.density;em.IR.30-60um

fluxH sage_lmcIracSource SPITZER H band flux real 4 mJy

fluxH sage_smcIRACv1_5Source SPITZER 2MASS All-Sky PSC H band flux real 4 mJy

fluxJ sage_lmcIracSource SPITZER J band flux real 4 mJy

fluxJ sage_smcIRACv1_5Source SPITZER 2MASS All-Sky PSC J band flux real 4 mJy

fluxK sage_lmcIracSource SPITZER K band flux real 4 mJy

fluxK sage_smcIRACv1_5Source SPITZER 2MASS All-Sky PSC K band flux real 4 mJy

FMAG grs_ngpSource, grs_ranSource, grs_sgpSource TWODFGRS Unmatched raw APM 2" profile integrated mag real 4

fMaj first08Jul16Source, firstSource, firstSource12Feb16 FIRST major axes derived from the elliptical Gaussian model for the source before deconvolution. real 4 arcsec phys.angSize.smajAxis

fMin first08Jul16Source, firstSource, firstSource12Feb16 FIRST minor axes derived from the elliptical Gaussian model for the source before deconvolution. real 4 arcsec phys.angSize.sminAxis

focus twomass_scn TWOMASS Focus setting of telescope at beginning of scan. smallint 2 instr.tel.focalLength

focus twomass_sixx2_scn TWOMASS telescope focus setting smallint 2

FOCUS_R spectra SIXDF R frame spectrograph focus value real 4

FOCUS_V spectra SIXDF V frame spectrograph focus value real 4

FootPrint_Flag ravedr5Source RAVE 1 => in RAVE selection function footprint, 0 => outside footprint tinyint 1 meta.code.qual

forced smashdr2_source SMASH Boolean flag indicating if this is forced (ALLFRAME) photometry smallint 2

fPA first08Jul16Source, firstSource, firstSource12Feb16 FIRST position angle (east of north) derived from the elliptical Gaussian model for the source before deconvolution. real 4 degrees pos.posAng

fPeak first08Jul16Source, firstSource, firstSource12Feb16 FIRST peak flux densities real 4 mJy phot.flux.density;em.radio.750-1500MHz

fQual_100 iras_psc IRAS 100 micron flux density quality. smallint 2 meta.code.qual

fQual_12 iras_psc IRAS 12 micron flux density quality. smallint 2 meta.code.qual

fQual_25 iras_psc IRAS 25 micron flux density quality. smallint 2 meta.code.qual

fQual_60 iras_psc IRAS 60 micron flux density quality. smallint 2 meta.code.qual

frac_c ravedr5Source RAVE Fraction of spectrum used [Chemical pipeline] (Note 2) real 4 stat.value

frame_rotator_object_type gaia_source GAIADR2 The type of the source mainly used for frame rotation int 4 meta.code

frameCode videoDetection VIDEOv20100513 Code for frameType of science frame from which these data were extracted tinyint 1 0

Post-processing bit flag assigned to represent the frameType of the image that the detections were extracted from. Catalogues come from frames that are interleaved (leav) and stacked or simply stacked (stack). These may be filtered (filt) to remove variations in the background at certain scales. 6 VISTA pawprint stacks are typically tiled (tile) to make a 1.5 square degree tile. Pawprints or tiles may be stacked to produce deep stacks or tiles (deep) and multiple tiles may be mosaicked together to produce a mosaic (mosaic). Thus a science image may be one of several types and the catalogue data from these images may or may not be used in different curation use cases or by different users. The error bit flag allows users to select or reject different data.

Bit FrameType

Decimal Hexadecimal

-- NONE 0 0x00000000

0 leav 1 0x00000001

1 stack 2 0x00000010

2 filt 4 0x00000100

3 tile 8 0x00001000

4 deep 16 0x00010000

5 mosaic 32 0x00100000

Different frame types can be built up from these bit flags. E.g., a mosaicdeepstack would be 0x00110010 or 50 in decimal. A tile would always have bit 3 set to 1. 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 detections in the VHS from tile frames, but not deep tile frames, include a predicate ... AND frameCode & 0x00001000 = 1 AND frameCode & 0x00010000 = 0. See the SQL Cookbook and other online pages for further information. All other frameTypes, such as normal, sky, dark, conf have frameCode=0.

frameCode vvvDetection VVVv20100531 Code for frameType of science frame from which these data were extracted tinyint 1 0

Post-processing bit flag assigned to represent the frameType of the image that the detections were extracted from. Catalogues come from frames that are interleaved (leav) and stacked or simply stacked (stack). These may be filtered (filt) to remove variations in the background at certain scales. 6 VISTA pawprint stacks are typically tiled (tile) to make a 1.5 square degree tile. Pawprints or tiles may be stacked to produce deep stacks or tiles (deep) and multiple tiles may be mosaicked together to produce a mosaic (mosaic). Thus a science image may be one of several types and the catalogue data from these images may or may not be used in different curation use cases or by different users. The error bit flag allows users to select or reject different data.

Bit FrameType

Decimal Hexadecimal

-- NONE 0 0x00000000

0 leav 1 0x00000001

1 stack 2 0x00000010

2 filt 4 0x00000100

3 tile 8 0x00001000

4 deep 16 0x00010000

5 mosaic 32 0x00100000

Different frame types can be built up from these bit flags. E.g., a mosaicdeepstack would be 0x00110010 or 50 in decimal. A tile would always have bit 3 set to 1. 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 detections in the VHS from tile frames, but not deep tile frames, include a predicate ... AND frameCode & 0x00001000 = 1 AND frameCode & 0x00010000 = 0. See the SQL Cookbook and other online pages for further information. All other frameTypes, such as normal, sky, dark, conf have frameCode=0.

frameSetID sharksMergeLog SHARKSv20210421 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID sharksMergeLog, sharksVarFrameSetInfo, sharksVariability SHARKSv20210222 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID sharksSource SHARKSv20210222 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID sharksSource SHARKSv20210421 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID ultravistaMergeLog, ultravistaRemeasMergeLog, ultravistaVarFrameSetInfo, ultravistaVariability ULTRAVISTADR4 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID ultravistaSource ULTRAVISTADR4 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID ultravistaSourceRemeasurement ULTRAVISTADR4 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vhsMergeLog VHSDR1 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSDR2 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSDR3 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSDR4 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSDR5 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSDR6 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20120926 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20130417 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20140409 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20150108 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20160114 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20160507 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20170630 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20180419 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsMergeLog VHSv20201209 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSDR1 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSDR2 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSDR3 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSDR4 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSDR5 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSDR6 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20120926 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20130417 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20140409 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20150108 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20160114 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20160507 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20170630 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20180419 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSource VHSv20201209 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vhsSourceRemeasurement VHSDR1 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID videoMergeLog VIDEODR3 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoMergeLog VIDEODR4 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoMergeLog VIDEODR5 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoMergeLog VIDEOv20100513 frame set ID, unique over the whole WSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoMergeLog VIDEOv20111208 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoMergeLog, videoVarFrameSetInfo, videoVariability VIDEODR2 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoSource VIDEODR2 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoSource VIDEODR3 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoSource VIDEODR4 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoSource VIDEODR5 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoSource VIDEOv20100513 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoSource VIDEOv20111208 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID videoSourceRemeasurement VIDEOv20100513 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vikingMergeLog VIKINGDR3 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGDR4 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20110714 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20111019 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20130417 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20140402 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20150421 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20151230 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20160406 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20161202 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog VIKINGv20170715 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingMergeLog, vikingVarFrameSetInfo, vikingVariability VIKINGDR2 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGDR2 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGDR3 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGDR4 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20110714 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20111019 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20130417 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20140402 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20150421 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20151230 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20160406 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20161202 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSource VIKINGv20170715 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingSourceRemeasurement VIKINGv20110714 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vikingSourceRemeasurement VIKINGv20111019 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vikingZY_selJ_RemeasMergeLog VIKINGZYSELJv20160909 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingZY_selJ_RemeasMergeLog VIKINGZYSELJv20170124 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vikingZY_selJ_SourceRemeasurement VIKINGZYSELJv20160909 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vikingZY_selJ_SourceRemeasurement VIKINGZYSELJv20170124 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vmcMergeLog VMCDR2 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCDR3 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCDR4 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCDR5 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20110816 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20110909 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20120126 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20121128 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20130304 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20130805 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20140428 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20140903 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20150309 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20151218 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20160311 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20160822 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20170109 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20170411 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20171101 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20180702 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20181120 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20191212 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20210708 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20230816 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog VMCv20240226 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcMergeLog, vmcVarFrameSetInfo, vmcVariability VMCDR1 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcPsfDetections VMCv20181120 frame set ID, linked to vmcMergeLog, assigned by merging procedure bigint 8 meta.id

frameSetID vmcPsfDetections, vmcPsfSource VMCv20180702 frame set ID, linked to vmcMergeLog, assigned by merging procedure bigint 8 meta.id

frameSetID vmcSource VMCDR1 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCDR2 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCDR3 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCDR4 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCDR5 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20110816 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20110909 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20120126 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20121128 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20130304 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20130805 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20140428 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20140903 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20150309 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20151218 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20160311 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20160822 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20170109 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20170411 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20171101 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20180702 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20181120 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20191212 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20210708 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20230816 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSource VMCv20240226 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcSourceRemeasurement VMCv20110816 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vmcSourceRemeasurement VMCv20110909 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vmcdeepMergeLog, vmcdeepVarFrameSetInfo, vmcdeepVariability VMCDEEPv20230713 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vmcdeepSource VMCDEEPv20230713 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvMergeLog VVVDR2 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvMergeLog VVVv20100531 frame set ID, unique over the whole WSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvMergeLog VVVv20110718 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvMergeLog, vvvPsfDophotZYJHKsMergeLog VVVDR5 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvMergeLog, vvvVarFrameSetInfo, vvvVariability VVVDR1 frame set ID, unique over the whole VSA via programme ID prefix, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvPsfDaophotJKsMergeLog VVVDR5 frame set ID, assigned by merging procedure bigint 8 meta.id;obs.field

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvPsfDaophotJKsSource, vvvPsfDophotZYJHKsSource VVVDR5 UID of the set of frames that this merged source comes from bigint 8 meta.id

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvSource VVVDR1 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvSource VVVDR2 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvSource VVVDR5 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvSource VVVv20100531 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvSource VVVv20110718 UID of the set of frames that this merged source comes from bigint 8 meta.bib

Each merged source in the merged source tables come from a set of individual passband frames (with different filters and/or different epochs of observation). In the WSA, a frame is generally the image provided by one detector (dither-stacked and interlaced as appropriate); hence a frame set comprises a set of individual detector frames in different passbands and/or at different observation epochs. Each frame set is uniquely identified by the attribute frameSetID, and this references a row in the corresponding merge log for the source table (for example, vhsSource.frameSetID references whsMergeLog.frameSetID. The merge log in turn references the full set of image descriptive data held in the tables MultiframeDetector and ultimately Multiframe (these two tables map directly onto the multi-extension FITS file hierarchy of extension FITS headers beneath a single primary HDU FITS header - primary HDU FITS keys will be found in Multiframe, while the corresponding extension FITS keys for each primary set will be found in table MultiframeDetector). In this way, you can trace the provenance of a merged source record right back to the individual image frames from which it is derived.

frameSetID vvvSourceRemeasurement VVVv20100531 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetID vvvSourceRemeasurement VVVv20110718 UID of the set of frames that this remeasured source comes from bigint 8 meta.bib

frameSetTolerance Programme SHARKSv20210222 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme SHARKSv20210421 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme ULTRAVISTADR4 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSDR1 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSDR2 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSDR3 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSDR4 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSDR5 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSDR6 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20120926 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20130417 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20150108 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20160114 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20160507 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20170630 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20180419 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VHSv20201209 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIDEODR2 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIDEODR3 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIDEODR4 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIDEODR5 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIDEOv20100513 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIDEOv20111208 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGDR2 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGDR3 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGDR4 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20110714 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20111019 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20130417 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20150421 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20151230 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20160406 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20161202 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VIKINGv20170715 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCDEEPv20230713 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCDR1 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCDR3 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCDR4 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCDR5 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20110816 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20110909 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20120126 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20121128 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20130304 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20130805 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20140428 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20140903 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20150309 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20151218 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20160311 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20160822 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20170109 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20170411 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20171101 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20180702 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20181120 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20191212 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20210708 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20230816 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VMCv20240226 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VSAQC The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VVVDR1 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VVVDR2 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VVVDR5 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VVVXDR1 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VVVv20100531 The match tolerance for different passband frames real 4 Degrees ??

frameSetTolerance Programme VVVv20110718 The match tolerance for different passband frames real 4 Degrees ??

frameType Multiframe SHARKSv20210222 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe SHARKSv20210421 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe ULTRAVISTADR4 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSDR1 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSDR2 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSDR3 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSDR4 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSDR5 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSDR6 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20120926 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20130417 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20140409 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20150108 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20160114 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20160507 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20170630 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20180419 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VHSv20201209 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIDEODR2 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIDEODR3 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIDEODR4 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIDEODR5 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIDEOv20100513 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIDEOv20111208 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGDR2 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGDR3 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGDR4 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20110714 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20111019 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20130417 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20140402 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20150421 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20151230 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20160406 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20161202 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VIKINGv20170715 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCDEEPv20230713 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCDR1 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCDR2 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCDR3 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCDR4 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCDR5 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20110816 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20110909 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20120126 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20121128 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20130304 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20130805 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20140428 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20140903 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20150309 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20151218 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20160311 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20160822 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20170109 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20170411 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20171101 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20180702 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20181120 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20191212 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20210708 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20230816 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VMCv20240226 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VVVDR1 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VVVDR2 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VVVDR5 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VVVXDR1 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VVVv20100531 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType Multiframe VVVv20110718 The type of multiframe (e.g. stack|tile|mosaic etc.)
A multiframe can have a combination of different types. varchar 64 normal meta.code.class

The frame types and their abbreviations are:

confidence = "conf" dark = "dark" deep = "deep" difference = "diff" filtered = "filt"
flat = "flat" interleaved = "leav" mosaic = "mosaic" sky = "sky" stack = "stack" default value = "normal"

frameType sharksMultiframe, ultravistaMultiframe, vhsMultiframe, videoMultiframe, vikingMultiframe, vmcMultiframe, vvvMultiframe VSAQC The type of multiframe (e.g. stack|tile|mosaic etc.) varchar 64 normal meta.code.class

freqLSG vvvVivaCatalogue VVVDR5 main variability frequency using Lomb-Scargle generalized method {catalogue TType keyword: FreqLSG} float 8 days^{-1} -9.999995e8

freqPDM vvvVivaCatalogue VVVDR5 Main variability frequency using Phase Dispersion Minimization method {catalogue TType keyword: FreqPDM} float 8 days^{-1} -9.999995e8

freqPKfi2 vvvVivaCatalogue VVVDR5 Main variability frequency using flux independent period method {catalogue TType keyword: FreqPKfi2} float 8 days^{-1} -9.999995e8

freqPLfi2 vvvVivaCatalogue VVVDR5 Main variability frequency using panchromatic period method {catalogue TType keyword: FreqPLfi2} float 8 days^{-1} -9.999995e8

freqSTR vvvVivaCatalogue VVVDR5 Main variability frequency using String Length Method method {catalogue TType keyword: FreqSTR} float 8 days^{-1} -9.999995e8

frinID Multiframe SHARKSv20210222 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe SHARKSv20210421 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe ULTRAVISTADR4 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSDR1 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSDR2 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSDR3 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSDR4 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSDR5 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSDR6 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20120926 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20130417 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20140409 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20150108 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20160114 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20160507 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20170630 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20180419 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VHSv20201209 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIDEODR2 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIDEODR3 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIDEODR4 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIDEODR5 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIDEOv20100513 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIDEOv20111208 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGDR2 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGDR3 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGDR4 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20110714 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20111019 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20130417 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20140402 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20150421 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20151230 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20160406 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20161202 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VIKINGv20170715 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCDEEPv20230713 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCDR1 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCDR2 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCDR3 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCDR4 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCDR5 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20110816 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20110909 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20120126 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20121128 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20130304 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20130805 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20140428 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20140903 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20150309 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20151218 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20160311 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20160822 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20170109 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20170411 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20171101 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20180702 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20181120 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20191212 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20210708 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20230816 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VMCv20240226 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VVVDR1 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VVVDR2 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VVVDR5 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VVVXDR1 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VVVv20100531 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID Multiframe VVVv20110718 UID of library calibration fringe frame bigint 8 -99999999 obs.field

frinID sharksMultiframe, ultravistaMultiframe, vhsMultiframe, videoMultiframe, vikingMultiframe, vmcMultiframe, vvvMultiframe VSAQC UID of library calibration fringe frame bigint 8 -99999999 obs.field

fromAllSky twompzPhotoz TWOMPZ Is the WISE designation from the wise_allskysc catalogue 0 NO/1 YES tinyint 1 0

fromAllSky wiseScosPhotoz, wiseScosPhotozRejects, wiseScosSvm WISExSCOSPZ Is the WISE designation from the wise_allskysc catalogue 0 NO/1 YES {image primary HDU keyword: fromAllSky} tinyint 1 0

FWHM_IMAGE mgcDetection MGC FWHM assuming a gaussian core real 4 pixel

WFAU, Institute for Astronomy,
Royal Observatory, Blackford Hill
Edinburgh, EH9 3HJ, UK

vsa-support@roe.ac.uk
04/03/2024