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Algorithms: Astrometry

A detailed description of the astrometric calibration is given in Pier et al. (2003) (AJ, or astro-ph/0211375). Portions of that discussion are summarized here, and on the astrometry quality overview page.

The r photometric CCDs serve as the astrometric reference CCDs for the SDSS. That is, the positions for SDSS objects are based on the r centroids and calibrations. The r CCDs are calibrated by matching up bright stars detected by SDSS with existing astrometric reference catalogs. One of two reduction strategies is employed, depending on the coverage of the astrometric catalogs:

  1. Whenever possible, stars detected on the r CCDs are matched directly with stars in the United States Naval Observatory CCD Astrograph Catalog (UCAC, Zacharias et al. 2000), an (eventually) all-sky astrometric catalog with a precision of 70 mas at its catalog limit of r= 16, and systematic errors of less than 30 mas. There are approximately 2 - 3 magnituds of overlay between UCAC and unsaturated stars on the r CCDs. The astrometric CCDs are not used. For DR2/DR3, stripes 9-13, 76, 82, and 86 used UCAC.
  2. If a scan is not covered by the current version of UCAC, then it is reduced against Tycho-2 (Hog et al. 2000), an all-sky astrometric catalog with a median precision of 70 mas at its catalog limit of VT = 11.5, and systematic errors of less than 1 mas. All Tycho-2 stars are saturated on the r CCDs; however there are about 3.5 magnitudes of overlap between bright unsaturated stars on the astrometric CCDs and the faint end of Tycho-2 ( 8 < r < 11.5), and about 3 magnitudes of overlap between bright unsaturated stars on the r CCDs and faint stars on the astrometric CCDs (14 < r < 17). The overlap stars in common to the astrometric and r CCDs are used to map detections of Tycho-2 stars on the astrometric CCDs onto the r CCDs. For DR2/DR3, stripes 30-43 used Tycho-2.

The r CCDs are therefore calibrated directly against the primary astrometric reference catalog. FRAMES uses the astrometric calibrations to match up detections of the same object observed in the other four filters. The accuracy of the relative astrometry between filters can thus significantly impact FRAMES, in particular the deblending of overlapping objects, photometry based on the same aperture in different filters, and detection of moving objects. To minimize the errors in the relative astrometry between filters, the u, g, i, and z CCDs are calibrated against the r CCDs.

Each drift scan is processed separately. All six camera columns are processed in a single reduction. In brief, stars detected on the r CCDs if calibrating against UCAC, or stars detected on the astrometric CCDs transformed to r coordinates if calibrating against Tycho-2, are matched to catalog stars. Transformations from r pixel coordinates to catalog mean place (CMP) celestial coordinates are derived using a running-means least-squares fit to a focal plane model, using all six r CCDs together to solve for both the telescope tracking and the r CCDs' focal plane offsets, rotations, and scales, combined with smoothing spline fits to the intermediate residuals. These transformations, comprising the calibrations for the r CCDs, are then applied to the stars detected on the r CCDs, converting them to CMP coordinates and creating a catalog of secondary astrometric standards. Stars detected on the u, g, i, and z CCDs are then matched to this secondary catalog, and a similar fitting procedure (each CCD is fitted separately) is used to derive transformations from the pixel coordinates for the other photometric CCDs to CMP celestial coordinates, comprising the calibrations for the u, g, i, and z CCDs.

Notes: At the edges of pixels, the quantities objc_rowc and objc_colc take integer values.

Astrometric recalibration

Early SDSS imaging runs were astrometrically calibrated against Tycho-2 (Hogg et al. 2000), which yielded statistical errors per coordinate for bright stars (r < 20) of approximately 75 mas and systematic errors of 20 — 30 mas. Later runs were calibrated against preliminary versions of the USNO CCD Astrograph Catalog (UCAC, Zacharias et al. 2000), which yielded improved statistical errors per coordinate of approximately 45 mas, with systematic errors of 20 — 30 mas (Pier et al. 2003). Proper motions were not available for the preliminary versions of UCAC. Since the typical epoch difference between the SDSS and UCAC observations is a few years and the typical proper motion of UCAC stars is a few mas year-1, this introduces an additional roughly 10 mas of systematic error in the positions due to the uncorrected proper motions of the calibrating stars.

All of DR7 has been recalibrated astrometrically against the second data release of UCAC (UCAC2; Zacharias et al. 2004). While the systematic errors for UCAC2 are not yet well characterized, they are thought to be less than 20 mas (N. Zacharias, private communication). UCAC2 also includes proper motions for stars with δ < +41º. For stars at higher declination, proper motions from the SDSS+USNO-B catalog (Munn et al. 2004) have been merged with the UCAC2 positions. With these improvements, all DR7 astrometry has statistical errors per coordinate for bright stars of approximately 45 mas, with systematic errors of less than 20 mas. The mean differences per run between the old and new calibrations is a function of position on the sky, with typical absolute mean differences of 0 to 40 mas. The rms differences are of order 10 to 40 mas for runs previously reduced against UCAC, and 40 to 80 mas for runs previously reduced against Tycho-2, consistent with what we would expect given the errors in the reductions.

Note that the formal SDSS names of objects in the CAS are of the form SDSSJhhmmss.ss±mddmmss.s. Because of the subtle changes in the astrometry, these names will be slightly different for many objects between DR6 and DR7. The user should be aware of this in comparing objects between DR6 and DR7.

The CAS includes proper motions for objects derived by combining SDSS astrometry with USNO-B positions, recalibrated against SDSS (Munn et al. 2004). These are given in the ProperMotions table in the CAS. (This table was called USNOB in the DR3 and DR4 versions of the CAS.) An error was discovered in the proper motion code in Data Releases 3 through 6, which causes smoothly varying systematic errors, in the proper motion in right ascension only, of typically 1—2 mas year-1 (see Munn et al. 2007 for a full description of the problem and its effects). This error has been corrected in DR7, thus any use of proper motions should use the DR7 CAS.

Errors on RA, DEC available in photoObj tables in CAS from DR6 on

The photoObjAll and derived views (photoObj, star, photoPrimary etc.) in the CAS now contain the errors and covariances for the right ascension and declination as well as galactic coordinates for all objects (see the CAS Schema Browser entry for photoAuxAll). These errors are calculated by adding the centroiding errors in quadrature with the estimated astrometric calibration errors. The centroiding and calibration errors are calculated in great circle coordinates and are assumed to be uncorrelated in the great circle longitude and latitude directions; the covariance between the right ascension and declination errors is then introduced when transforming the uncorrelated errors in great circle coordinates to the celestial coordinate system.

In DR4 and DR5, these errors were available only in the photoAuxAll table (as were galactic coordinates). For backwards compatibility, there are still photoAuxAll and photoAux views, but new queries requiring these parameters do not need these auxiliary tables any more.


*Text and figures on this page come from an author-created, un-copyedited version of the SDSS Data Release 7 paper, an article submitted to Astrophysical Journal Supplements. IOP Publishing Ltd is not responsible for any errors or omissions in this version of the manuscript or any version derived from it. A preprint of the DR7 paper is available from the arXiv preprint server.


Last modified on $Date: 2009/03/25 16:49:12 $ (UT).