Calibrated object lists
Up: Data Products Sections: Images - Object lists - Spectra - Tiling
About SDSS object lists
The calibrated object lists reports positions, fluxes, and shapes
of all objects detected at >5 sigma on the survey
images. Photometry is reported on the natural system of the APO 2.5m survey telescope (a
system which includes 1.3 airmasses at APO; see description of photometric flux calibration)
in asinh magnitudes.
Getting and using object lists
You need to look at the object
flags in the object lists to obtain meaningful
results.
Calibrated object lists are stored in two file types in the Data Archive Server:
The fpAtlas*.fits
files contain "postage-stamp"
images, the set of pixels determined to belong to each object.
See how to read an atlas
image.
The data access page contains various
query forms to search the object lists by coordinates, magnitude,
color etc., and to retrieve data from the archive. In particular, the
Catalog Archive Server
provides a fast search capability for object lists and spectroscopic
parameters as well as pointers to the files in the Data Archive Server. The Imaging
Query Server query form is dedicated to the search of the imaging
database.
Caveats
Isophotal radii in DR3 are given in pixels, not arcseconds
The isophotal radii of objects are supposed to be reported in
arcseconds, as they were in earlier data releases. Due to a
programming error, all isophotal radii are given in pixels in DR3. To
obtain the isophotal radii in arcseconds, scale by the pixel size of
0.396 arcseconds.
The bug is present in both the tsObj files in the DAS and the photoObj
and derived tables in the CAS. It will be fixed in the next
data release.
SDSS and AB magnitudes
The SDSS photometry is intended to be on the AB system. However,
this is known not to be exactly true. See Conversion from SDSS to
AB magnitudes in the Flux calibration section of the Algorithm
descriptions.
Sky brightness values are extinction-corrected
The various measures of sky brightness reported in the
tsField files are corrected for atmospheric extinction in
the same way as calibrated object magnitudes in tsObj
files. To do a correct conversion from
magnitudes to counts and vice versa, you need to treat object and
sky magnitudes in the same way.
Sky brightness values are given in maggies, not magnitudes
The various measures of sky brightness reported in the
tsField files are given in maggies/square arcsecond (as
in tsObj files), but the fits headers incorrectly give
magnitudes/square arcseconds as units. Only tsField
files in the TARGET version of runs 94, 125, 1033 and
1056 still have the numbers in magnitudes.
Object counts
The nobjects etc. entries in tsField
files (field table in the CAS database) are currently
meaningless.
A few runs processed with slightly older version of photo
As described in the DR2 paper, mis-estimates of the sky background
in the postage stamps of stars used for PSF determination occasionally
coupled with the PSF determination itself in early versions of the
photometric pipeline. We were able to suppress this behavior by
explicitly forcing the sky-subtracted images to zero at their edges.
This revised code was run on most of the imaging runs included in DR2
and DR3, but not quite all of them. In every case that was run with
the old code, a comparison of PSF and aperture photometry of stars
confirmed that there was no significant contribution to the PSF from
wrongly estimated sky, but the user should be aware that these runs have
not been reduced by the identical version of the pipeline. The run/reruns
in question are: 1239/40, 1336/40, 1339/40, 1356/40, 1359/40, 1659/40, 1889/40,
2075/40, 2076/40, 2248/40, 2305/40, 2328/40, 2335/40, 2662/40, 2738/40,
3538/40, 3704/40, 3723/40, 3894/40, 3905/40, 3909/40, 3910/40, 3919/40,
3927/30, 3325/41, and 3838/41. These will be reprocessed and replaced
in the archive for a future data release.
Red leak to the u filter and very red objects
The u filter has a natural red leak around 7100 Å
which is supposed to be blocked by an interference coating. However,
under the vacuum in the camera, the wavelength cutoff of the
interference coating has shifted redward (see the discussion in the
EDR paper), allowing some of this red leak through. The extent of
this contamination is different for each camera column. It is not
completely clear if the effect is deterministic; there is some
evidence that it is variable from one run to another with very similar
conditions in a given camera column. Roughly speaking, however, this
is a 0.02 magnitude effect in the u magnitudes for mid-K
stars (and galaxies of similar color), increasing to 0.06 magnitude
for M0 stars (r-i ~ 0.5), 0.2 magnitude at r-i ~
1.2, and 0.3 magnitude at r-i = 1.5. There is a large
dispersion in the red leak for the redder stars, caused by three
effects:
- The differences in the detailed red
leak response from column to column, beating with the complex red
spectra of these objects.
- The almost certain time variability of the red leak.
- The red-leak images on the u chips are out of focus and are
not centered at the same place as the u image because of
lateral color in the optics and differential refraction - this means
that the fraction of the red-leak flux recovered by the PSF fitting
depends on the amount of centroid displacement.
To make matters even more complicated, this is a detector
effect. This means that it is not the real i and
z which drive the excess, but the instrumental colors
(i.e., including the effects of atmospheric extinction), so the leak
is worse at high airmass, when the true ultraviolet flux is heavily
absorbed but the infrared flux is relatively unaffected. Given these
complications, we cannot recommend a specific correction to the
u-band magnitudes of red stars, and warn the user of these
data about over-interpreting results on colors involving the
u band for stars later than K.
u-band sky determination
There is a slight and only recently recognized downward bias in the
determination of the sky level in the photometry, at the level of
roughly 0.1 DN per pixel. This is apparent if one compares
large-aperture and PSF photometry of faint stars; the bias is of order
29 mag arcsec-2 in r. This, together with
scattered light problems in the u band, can cause of order
10% errors in the u band Petrosian fluxes of large
galaxies.
Astrometry bug fixed in DR2/DR3
Astrometry for each object is referred to the reference frame of
the r-band images. DR1 had a bug in the reported right ascension and
declination (and all other celestial coordinates, such as l and b) for
those rare sources that are not detected in the r band (for
example, cool brown dwarfs and z > 5.7 quasars). This bug has been
fixed in DR2/DR3 and the positions of z-band only detections
are now correct.
Deblending of bright galaxies significantly improved in DR2/DR3
The behavior of the deblender of overlapping images has been
further improved since the DR1; these changes are most important for
bright galaxies of large angular extent (> 1'). In the EDR, and to
a lesser extent in the DR1, bright galaxies were occasionally
"shredded" by the deblender, i.e., interpreted as two or
more objects and taken apart. With improvements in the code that
finds the center of large galaxies in the presence of superposed
stars, and the deblending of stars superposed on galaxies, this
shredding now rarely happens. Indeed, inspections of several hundred
NGC galaxies shows that the deblend is correct in 95% of the cases;
most of the exceptions are irregular galaxies of various sorts.
Last modified: Fri Oct 1 15:05:15 CDT 2004
|