Special plates
Back to spectra
Overview table of special programs
The Programname is stored in the
platex table in the CAS. We have begun to add SQL
example queries showing how to use the extra and special spectra.
We will soon provide SQL example queries for accessing the special
spectra in the CAS. The links in the Program column
point to the tables below describing individual target flags and
targeting criteria.
Programname |
Plates |
Program |
Comments |
seguetest83, seguetest96 |
1662-1664,1857 |
SEGUE test |
Imaging not available except for 1664 |
seguetest84 |
1665-1666 |
Perseus-Pisces F stars and galaxies |
Imaging not available |
fstar72 |
1468,1471,1472 |
F stars, quasars in M31 |
Imaging not available |
fstar51 |
1149,1150,1152-1155 |
F stars |
Double-length exposures |
fstar29 |
797 |
F stars |
Imaging not available |
lowz45, lowz52, lowz62, lowz74, lowz97 |
1021-1024, 1026-1037, 1156, 1157, 1243, 1538, 1539, 1561-1566, 1859 |
Low-z galaxies, Deep LRG, BCGs |
Double-length exposures |
merged73 |
1473-1476,1485-1499,1504-1506,1508-1511,1514-1518,1521-1523,1529 |
Complete Main, u-band galaxies, Spectra of Everything, Variability, High
Proper motion stars, Fainter
LRG |
Standard merged program |
merged48 |
1062-1096, 1101, 1103-1107, 1114-1117 |
Complete Main, u-band galaxies, Double-lobed
radio sources, faint quasars, Spectra of Everything |
Standard merged program |
rockosi50 |
1133-1135,1137,1143 |
MS Turnoff stars |
|
munn49 |
1118-1132 |
Thick and thin disk |
|
photoz21, photoz29, photoz79 |
669-672, 807-810, 1629, 1632, 1633, 1635 |
photo-z |
|
loveday29 |
811 |
low-z galaxies |
|
annis29 |
802-806 |
low-z galaxies |
|
south22 |
673-714 |
Main Extension: Galaxies, Quasars |
Extensions of standard algorithms |
Schlegel/Locus |
323-324 |
Stellar locus |
|
Descriptions of individual programs and primtarget categories
Note The descriptions on this page pertain to
targeting cateogries, i.e., the way in which objects where
selected from the photometry catalog. Before using these spectra, you
need to check both the spectral classification (specClass
in the CAS, spec_cln in the spSpec*.fits primary header)
and the redshift status (as for all
SDSS spectra).
Galactic kinematic programs
F stars
F stars are numerous in the Galaxy, have sharp spectral features
allowing accurate radial velocities to be measured, are approximate
standard candles if the stars are on the main sequence, and are of
high enough luminosity that they can be seen to great distances. This
program aims to use F star radial velocities to understand the
kinematics of the outer parts of the Milky Way. Most of these plates
were in the Southern Galactic Cap Equatorial Stripe, but there are
also three plates in the vicinity of M31, and another two plates
centered roughly on the Perseus cluster. The M31 (e.g., Zucker
et al. 2004a and Zucker
et al. 2004b) and Perseus imaging data are not included
in DR4, but will be included in a future data release.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
seguetest84, fstar72, fstar51, fstar29 |
F stars |
0x80002000 |
6050 |
Stellar objects with -0.3 < (g-r) < 0.3 and
19.0 < g < 20.5 |
Main sequence turnoff
This program was designed to study the kinematics and metallicities
of high-latitude thick disk and halo stars. One of the plates
overlaps with the area of the Thick/Thin disk program described below
and uses the extra color cut i-z>0.2 to avoid overlap
with that program. The DR4 spectra from this program are a random
subset of all the objects identified by the selection algorithm.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
rockosi50 |
Main-sequence turnoff |
0x80002000 |
2947 |
(l,b) near (64°,-45°): r < 19.15,
g-r < 0.8
(l,b) near (114°,-62°): r < 19.15,
g-r < 0.8, i-z > 0.2 |
Thick/thin disk stars
A third program was focused on the kinematics on the thin and thick
disks, targeting a complete sample of 8880 bright, red stars in three
adjacent spectroscopic tiles centered at high Galactic latitude. It
provides an in situ sample of thin and thick disk stars with radial
velocities, proper motions, and spectroscopic metallicity
determinations, densely sampling a single line of sight out to 2 kpc
above the Galactic plane.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
munn49 |
Thick/thin disk |
0x80040000 |
8859 |
i < 18.26, i-z > 0.2
near (l = 123°, b = -63°) |
SEGUE test plates
SEGUE ("Sloan Extension for Galactic Understanding and
Exploration") is part of a follow-on project to the SDSS,
emphasizing spectra of stars to study stellar populations and Galactic
structure. The targets on the SEGUE test plates in DR4 are Galactic
stars of a variety of colors and magnitudes, meant to sample the range
of available spectral types and to test the reproducibility of radial
velocity measurements at faint magnitudes. SEGUE aims to probe the
structure of the Milky Way by sampling Horizontal Branch, F turnoff, G
dwarf and K dwarf and giant stars, representing a variety of distances
in the disk and halo. These plates are being used to refine target
selection for the SEGUE program itself.
The SEGUE test plates use dereddened PSF magnitudes in their
selection. Most selection categories use a color and/or magnitude
weighting to get a more even sampling of the color/magnitude
distribution where the number counts rise steeply with color or
magnitude.
NOTE Among the SEGUE plates, plate 1664 is a
special radial-velocity standards plate which targets F, G and K stars
(mostly dwarfs). It includes very faint stars and has been observed
twice to explore the accuracy of radial velocity determinations at
faint magnitudes. Thus, the table below does not include counts for
objects from plate 1664 with its fainter magnitude limits.
In addition, not all plates from the SEGUE test chunks have been
observed, so that some targeting categories do not have any spectra
in DR4.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
seguetest83, seguetest96 |
White dwarfs |
0x80080000 |
35 |
g < 20.3, -1 < g-r < -0.2, -1
< u-g < 0.5
color weighting |
|
Cool White dwarfs |
0x80020000 |
0 |
15 < r < 20, -0.1 < g-r < 1.1,
g-r > 2.4*(r-i)+0.5, i-z < 0
color weighting |
|
A/BHB stars |
0x80002000 |
305 |
g < 20.5, 0.5 < u-g < 1.4, -0.8 <
g-r < 0.2, s-color < -0.065
color weighting |
|
F turnoff and sub-dwarfs |
0x80100000 |
0 |
-0.7 < p1(s) < -0.3, 0.4 < u-g < 1.7,
-0.3 < g-r < 3, g < 20.3
color and magnitude weighting |
|
G stars |
0x80040000 |
626 |
14.2 < r < 20.2, 0.50 < g-r
< 0.55
random weighting |
|
K Giants |
0x80004000 |
283 |
r < 20.2, 0.7 < u-g < 4.0 , 0.40 <
g-r < 1.2, 0.15 < r-i < 0.6,
l-color > 0.1, proper_motion < 15
arcsec/century (intended to be 1.5 arcsec/century)
color weighting |
|
Low metallicity |
0x80010000 |
276 |
r < 20.2, 0.3 < u-g < 3.0, -0.5 < g-r < 0.9, l-color > 0.15
color weighting |
|
K dwarfs |
0x80008000 |
178 |
14.5 < r < 19.5, g-r > 0.7,
r-i < 0.8
random weighting |
|
M dwarfs |
0x80200000 |
0 |
regular M dwarfs: r-i > 0.3, 14.5 <
r < 19.0 (N=12)
color weighting
Not sure if the r-i cut is correct (0.7-0.8?)
sub-dwarf cands: u-g > 1.8, g-r
> 0.8, 0.5 < r-i, 14.5 < r < 19
(N=15)
color weighting
high-velocity M dwarfs: r-i > 0.3, 14.5 < r < 19.3, velocity proxy
≅ 100 km/s (N=25)
velocity and color weighting |
|
AGB candidates |
0x80800000 |
0 |
14.5 < r < 19.5, 2.5 < u-g
< 3.5, 0.9 < g-r < 1.3, s-color <
-0.07
color weighting |
Other stellar/point-source target selection algorithms
Spectra of Everything
As part of an exploration of the full stellar locus, as well as a
search for unusual objects of all sorts, we carried out a survey of
all stellar objects ("Spectra of Everything"), which was
used as a filler for a series of so-called merged program plates,
which included a mixture of mostly extragalactic targets. In 2002
(chunk merged48 ), this included a random sampling of all
point sources with clean photometry (see the discussion of fatal and
non-fatal flags in Richards
et al. 2002) with reddening-corrected i-band PSF
magnitudes brighter than 19.1. Not surprisingly, the vast majority of
the targets were chosen from the densest core of the stellar locus in
color-color space.
In an attempt to put greater weight on the wings of the stellar
locus, we revised the selection algorithm slightly for chunk
merged73 . We defined a distance from the ridge of the
stellar locus, by asking for the median and standard deviation
u-g, g-r, and i-z of stars in narrow
bins of r-i. Having tabulated these, we calculated a crude
χ2-like quantity:
L = 1/3 Sum_{u-g,g-r,i-z} ((color-median color)/(standard deviation))2
75% of all stars had L < 1. We gave all stars with
L > 1 highest priority, and for L < 1, the
priority decreased smoothly with L.
These spectra were used for a determination of the completeness of
the quasar target selection algorithm (Vanden
Berk et al. 2005). The overwhelming majority of these objects are
confirmed to be stars; only 10 of the 19,543 of the Spectra of
Everything targets analyzed in that paper are quasars not previously
targeted as such.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged48 |
Spectra of everything |
0xA0000000 |
14779 |
Point sources at iPSF dered < 19.1 |
merged73 |
Spectra of everything |
0x80000001 |
3934 |
Point sources at iPSF dered < 19.1
L > 1 |
|
Spectra of everything |
0x80000002 |
5478 |
Point sources at iPSF dered < 19.1,
L < 1 |
High proper motion
A sample of high proper motion stars was defined using proper
motions determined using the methods of Munn
et al. (2004), where a consistent astrometric solution was found
matching USNO-B data (Monet
et al. 2003) with SDSS. There were two cuts:
- A simple cut of proper motion μ > 100 mas/y
- Cuts using reduced proper motion Hr
defined by:
Hr = r + 5 log10 μ + 5
The sample was defined by:
g-i < 2 Hr > 16
2 < g-i < 2.375 Hr > 8 + 4 (g-i)
2.375 < g-i Hr > 17.5
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged73 |
High proper motion |
0x80010000 |
966 |
Cuts on proper motion, or reduced proper motion together with
g-i color (described above) |
Stellar locus
For plates 323 and 324, stellar targets were chosen from SDSS
imaging data, randomly sampling the stellar locus in color space, in
order to explore the full range of stellar spectra. In particular,
grids of width 0.04 magnitude in the (u-g),(r-i)
and (r-i),(i-z) color planes were set down, and
where they existed, a single star was selected in each grid. The
process was iterated until about 600 targets on each plate had been
assigned.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
Schlegel/Locus |
Stellar locus |
0x2000 |
1188 |
Grid of objects in the u-g,r-i and r-i, i-z planes |
Galaxies at low redshifts
Main extension: galaxies
In Chunk 22, observed in Fall 2001, we used direct extensions of
the main survey target selection algorithms. In particular, the main
galaxy sample (Strauss
et al. 2002) was modified only slightly, by removing the cut on
objects with half-light Petrosian r band surface brightness
μ50,r below 24.5 mag/arcsec2. This adds
less than one object per square degree.
For LRGs, the sample was changed to probe about
0.3 mag fainter than for the main survey selection described by Eisenstein
et al (2001). In particular, the cuts that were used garner about
40 objects/deg2:
r < 19.5
r < 13.4 + c||/0.3
μ50,r < 25
|c⊥| < 0.4
for Cut I, and
r < 19.5
g-r > 1.65 - c⊥
μ50,r < 25
rPSF-rmodel > 0.3
for Cut II, with
c|| = 0.7(g-r) + 1.2(r-i-0.18)
c⊥ = (r-i) - (g-r)/8
Chunk |
Target category |
primtarget |
# of targets |
Selection |
south22 |
Main extension: galaxies |
Regular primtarget and sectarget flags, with bit 0x80000000 set |
8986 |
See text above |
Complete main galaxies
The main galaxy sample, as described by (Strauss
et al. 2002) is as complete as we can make it. However, the
subset for which we actually obtain a spectrum is only about 90%.
This incompleteness has several causes, including the fact that two
spectroscopic fibers cannot be placed closer than 55′′ on
a given plate, possible gaps between the plates, fibers that fall out
of their holes, and so on. This program aims to observe the remaining
10\% of galaxy targets in order to have a region of sky with truly
complete galaxy spectroscopic coverage. This is particularly
important for studies of galaxy pairs, which are by definition
strongly affected by the 55′′ rule. The target selection
algorithm is simple: all galaxies selected by the algorithm described
in (Strauss
et al. 2002) in the Southern Equatorial Stripe, minus those
galaxies that actually have a successfully measured redshift in
routine targeting.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged73 |
Complete MAIN galaxies |
Regular primtarget and sectarget flags |
2020 |
Additional fibers for MAIN survey galaxies |
merged48 |
Complete MAIN galaxies |
Regular primtarget and sectarget flags |
1605 |
Additional fibers for MAIN survey galaxies |
u-band galaxies
The main galaxy target selection is carried out in the r
band, and is flux-limited at r = 17.77. The bluest
galaxies have $u-r \approx 0.6$, thus a magnitude-limited in the $u$
band corresponds to $u \approx 18.4$.
In order to explore the u-band luminosity density of the
universe, and explore the recent history of star formation in the
universe, we carried out a u-band survey of galaxies in the
SDSS. Baldry
et al. (2005) describe the sample in detail and present the
resulting u-band luminosity function.
In the selection criteria below, we use a (dereddened)
"Pseudo-Petrosian" u-band magnitude
uselect = umodel - rmodel + rPetro.
Note that the objects targeted in this program do not include
objects with spectroscopic observations already in hand. Thus one
needs to combine objects from various programs to define a complete
sample. See the discussion in Baldry
et al. (2005) for determination of the completeness of the
resulting sample.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged73 |
u-band galaxies: priority |
0x80000040 |
765 |
uselect < 19.8
gPetro < 20.5
17.5 < rPetro < 20.5
μ50,r < 24.5
rPSF-rmodel > 0.2 |
|
u-band galaxies: extra |
0x800000c0 |
2128 |
uselect < 20.3 or
umodel < 19.8 or
uPetro < 19.5
gPetro < 19.5
17.3 < rPetro < 20.7
μ50,r < 24.7
rPSF-rmodel > 0.15 |
|
u-band galaxies: extra2 |
0x80000140 |
2108 |
uselect < 20.3
gPetro < 20.5
17.5 < rPetro < 20.5
μ50,r < 24.5
rPSF-rmodel > 0.2 |
merged48 |
u-band galaxies |
0x80000040 |
3426 |
uselect < 19.8
gPetro < 20.5
17.5 < rPetro < 20.5
μ50,r < 24.5
rPSF-rmodel > 0.2 |
Low-redshift galaxies
We have carried out a survey of low-redshift galaxies to 2
magnitudes fainter than the SDSS main sample limit in order to add
more low-luminosity galaxies to the sample. Our redshift selection
used photometric redshifts derived from second-order polynomial fits
to observed Petrosian r magnitudes and model colors, with
separate fits done in bins of model g-r color. For Chunks
45, 52, and 62, we used the SDSS EDR photometry and spectroscopy then
available to derive photometric redshifts, while for Chunks 74 and 97,
we were able to derive improved photometric redshifts using
catalog-coadded Stripe 82 SDSS photometry, combined with all available
SDSS redshift data on the Southern Equatorial Stripe as of 11 July
2003. This included much of the data taken for the express purpose of
calibrating the photometric redshift relation in the SDSS photometric
system.
Galaxies were then chosen for observations based on their
photometric redshift zp and Petrosian magnitude
rPetro. In particular, the aim was to target as
complete a sample as possible for 17.77 ≤ r < 19.0
and true redshift below 0.15, and sparse samples to higher redshifts,
as well as at fainter magnitudes 19.0 ≤ r < 19.5.
The specific target categories, in order of highest to lowest priority
for fiber assignment, are listed in the table below. As there are many
more such targets than available fibers, the available targets were
sampled sparsely. The sparse sampling fraction values were chosen to
get reasonable distributions of objects over the target categories and
to keep approximately similar target distributions from chunk to
chunk, which resulted in somewhat different sampling fractions for
each of the five chunks in which this algorithm was used.
Sparse sampling fractions
magnitudes |
redshift |
Chunk 45 |
Chunk 52 |
Chunk 62 |
Chunk 74 |
Chunk 97 |
17.77 ≤ r < 19.0 | 0.00 ≤ zp < 0.15 | 1.0 | 0.85 | 0.7 | 1.0 | 1.0 |
17.77 ≤ r < 19.0 | 0.15 ≤ zp < 0.20 | 0.15 | 0.1275 | 0.105 | 0.15 | 0.3 |
17.77 ≤ r < 19.0 | 0.20 ≤ zp < 0.25 | 0.15 | 0.1275 | 0.105 | 0.15 | 0.3 |
19.0 ≤ r < 19.5 | 0.00 ≤ zp < 0.15 | 0.25 | 0.2 | 0.15 | 0.25 | 0.3 |
19.0 ≤ r < 19.5 | 0.15 ≤ zp < 0.20 | 0.25 | 0.16 | 0.1 | 0.25 | 0.3 |
19.0 ≤ r < 19.5 | 0.20 ≤ zp < 0.25 | 0.25 | 0.18 | 0.15 | 0.25 | 0.3 |
17.77 ≤ r < 19.0 | 0.25 ≤ zp | 0.015 | 0.015 | 0.015 | 0.17 | 0.3 |
17.77 ≤ r < 19.0 | zp < 0.0 | 0.65 | 0.65 | 0.65 | 0 | 0 |
19.0 ≤ r < 19.5 | 0.25 ≤ zp | 0.005 | 0.005 | 0.005 | 0.15 | 0.3 |
19.0 ≤ r < 19.5 | zp < 0.00 | 1.0 | 1.0 | 1.0 | 0 | 0 |
A caveat to note is that Chunk 45 used the
star/galaxy separation criteria of the SDSS photometric pipeline to
select galaxies, and this resulted in noticeable contamination of
stars in several of the Chunk 45 plates located at lower galactic
latitudes. The other chunks used the star/galaxy cut employed by the
SDSS main sample target selection algorithm
(rPSF - rmodel ≥ 0.3 or
0.24, depending on the version of the photometric pipeline), which is
more conservative for selecting galaxies.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
lowz45, lowz52, lowz62, lowz74, lowz97 |
low-z |
0x80000040 |
14210 |
Photometric redshift, sparse sampling as given in table above |
loveday29 |
low-z |
0x80000040 |
570 |
EDR photometric redshift from Csabai
et al. (2003) > 0.003,
rPetro < 20,
estimated Mr > -18 |
annis29 |
low-z |
0x80000040 |
2849 |
iPetro ≤ 20,
iPetro + (r-i)model ≥
17.75,
zp ≤ 0.17-0.19, chosen plate-by-plate
to give enough targets to match the available number of fibers |
Galaxy target selection for calibration of photometric
redshifts
The SDSS five-band photometry goes substantially fainter than does the
spectroscopy, suggesting the opportunity to derive photometric
redshifts for vastly more objects than have spectroscopy (see, for
example, Csabai
etal 2003). Calibrating the photometric redshift relation
requires a training sample exploring the same range of apparent
magnitudes and colors as the objects for which photometric redshifts
will eventually be derived. The SDSS LRG sample (Eisenstein
et al. 2001) obtains spectra for red faint (r <
19.5) galaxies; photometric redshifts of this relatively uniform
population (e.g., Eisenstein
et al. 2003) are fairly robust (e.g., Padmanabhan
et al. 2005). However, we do not have a corresponding sample of
faint blue galaxies for the calibration of photometric redshifts.
Therefore, a series of spectroscopic plates was designed to obtain
redshifts for the blue end of the galaxy color distribution at the
faint end.
0.40 + 0.6(u-g) < g-r < 1.7 - 0.1(u-g)
-0.5 < u-g < 3.0
0 < g-r < 1.8
-0.5 < r-i < 1.5
-1 < i-z < 1.5
18.0 < u < 24.0
18.0 < g < 21.5
17.8 < r < 19.5
16.5 < i < 20.5
16.0 < z < 20.0
σu < 0.6
σg,r,i,z < 0.25
For objects that satisfied the above cuts, the quantity
exp[c((g-r) - (0.40 +0.6(u-g)))] was
calculated; if it was larger than a random number chosen between zero
and one, the object was targeted for spectroscopy. The coefficient
c=0.1411 was chosen to obtain an appropriate density of
targets. Note that plates 672 and 809 have the same center, and some
of the same objects were inadvertently observed twice.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
photoz21, photoz29, photoz79 |
photo-z |
0x80000040 |
4526 |
See text above |
Perseus-Pisces galaxies
Imaging scans were taken centered roughly on the Perseus cluster at
z ≅ 0.018, and were used to target galaxies. The
double exposure plates 1665, 1666 targeted, and obtained redshifts
for, approximately 400 galaxies as faint as
rfiber = 18.8 in a region centered on the
cluster at (α,δ) = (49.96°r;, 41.53°r;). The
majority of the galaxies are associated with the cluster, although
there are 50 objects in a background overdensity at
z≅0.05 (Brunzendorf
& Meusinger 1999). These plates also included approximately
300 foreground F-stars.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
seguetest84 |
Perseus-Pisces galaxies |
0x80000040 |
787 |
MAIN galaxy target selection |
Higher-redshift galaxies
Deep LRG exposures
The SDSS LRG sample (Eisenstein
et al. 2001) targets high-redshift (0.2 < z <
0.55), luminous galaxies by their colors and magnitudes. As part of
Southern targeting, we have explored this algorithm in several ways.
The first, the Deep LRG sample, uses double-length spectroscopic
exposures to get higher S/N spectra of LRGs with z >
0.25 which satisfied the Cut I criteria from Eisenstein et al. 2001.
These serve two purposes: first, to obtain measurements of velocity
dispersion for galaxies where the current, single-pass spectroscopy is
only "good enough for a redshift". Second, given the
discontinuity in targeting algorithm at z ≅ 0.4 (the
distinction between Cut I and Cut II; see Eisenstein
et al. 2001) higher S/N spectra allow the exploration of possible
spectroscopic differences at this transition, implying differences in
stellar populations. XXX This sounds a bit rough.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
lowz45, lowz52, lowz62, lowz74, lowz97 |
Deep LRG, Cut I |
0x80000020 |
1230 |
LRG Cut I |
|
Deep LRG, Cut I |
0x80000020 |
205 |
LRG Cut II |
Faint LRGs
The LRG Cut II sample aims for a flux-limited sample of LRG with
redshifts roughly between 0.40 and 0.55. We also experimented with an
extension of this cut, going substantially fainter.
17.5 < ideV < 20
iPetro < 19.1
0.5 < g-r < 3.0
0.0 < r-i < 2.0
c|| = 0.7(g-r) + 1.2(r-i-0.18)
> 1.6
c⊥ = (r-i) - (g-r)/8
> 0.5
Here, deV refers to deVaucouleurs model magnitude,
Petro to Petrosian magnitude, and all colors are based
on model magnitudes (see Which magnitudes
should I use?)
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged73 |
Faint LRG |
0x840000a0 |
2301 |
See text above |
Brightest Cluster Galaxies (BCGs)
A separate program explicitly targeted the brightest galaxies in
clusters. While LRGs are often the brightest galaxies in their
clusters, they need not be. The so-called MaxBCG method described by
Bahcall
et al. (2003) searches for galaxies with the apparent magnitudes
and colors of LRGs, together with a red sequence of fainter
ellipticals in the vicinity (cf., Gladders
& Yee 2000). The BCG program targeted BCG candidates found
with this method, with estimated redshifts in the range 0.4 <
z < 0.7. The MaxBCG algorithm was run on photometry
derived from co-adding the detections (at the catalog level) of
multiple scans of the Southern Equatorial Stripe.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
lowz74, lowz97 |
BCGs |
0x80000100 |
439 |
See text above |
Quasar and variability target selection
Main extension: quasars
In Chunk 22, the quasar target selection algorithm (Richards
et al. 2002) was extended as follows. For objects selected from
the ugri color cube, the magnitude limit was changed from
i = 19.1 to 19.9, while for the griz color cube
(where high-redshift quasars are selected), we changed the limit from
i = 20.2 to 20.4.
As Richards
et al. (2002) describe, there are regions outside the stellar
locus that are heavily contaminated by hot white dwarfs, M dwarf-white
dwarf pairs (Smolcic
et al. 2004), and other non-quasars. These regions are explicitly
excluded from quasar target selection in the main survey; however, in
the extension, they are allowed back in. Similarly, there is a region
of color space where z ≅ 2.7 quasars intersect the
stellar locus. In the main survey, objects falling in this region are
sparse-sampled to 10% (to reduce the number of stars); in the
extension, all objects falling in the mid-z box defined in Richards et
al. (2002) are targeted.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
south22 |
Main extension: quasars |
Regular primtarget and sectarget flags, with bit 0x80000000 set |
8030 |
See text above |
Faint quasars
The quasar target selection was further modified for the faint
quasar targets on the merged plates on Chunk 48. In particular, the
following are the changes over the standard quasar target selection
algorithm described in Richards
et al. 2002:
- The magnitude limit is set to i= 20.1, rather than
i = 19.1 for the ugri color cube;
- The magnitude limit for optical counterparts to FIRST sources is
set to i = 20.65, rather than i =
19.1;
- The standard quasar target selection algorithm requires that the
estimated PSF magnitude errors in u and g
both be less than 0.1 for UV excess sources
(u-g<0.6). This limit is now set to 0.2.
- For UV excess objects with 19.1 ≤ i < 20.1,
we add a requirement that g - r < 0.7 to minimize
stellar contamination.
- Objects in the "mid-z box" are excluded altogether.
- In addition to the usual "distance from the stellar locus"
algorithm used to target quasars, in the main sample there are
hard color cuts used to select high-redshift quasars in the
griz color cube. These color cuts are not used in
the Southern targeting.
- Finally, there were additional color cuts to reject unphysical
objects affected by bad CCD columns; we required g-r>-0.5,
r-i>-0.5, and i-z>-0.6.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged48 |
Faint quasars |
Regular primtarget flags, with bit 0x80000000 set |
6655 |
See text above |
M31 Quasars
Low-redshift quasars were targeted on the M31 imaging data (Chunk
72) using the standard quasar selection algorithm (Richards
et al. 2002), but excluding the high-redshift candidates selected
from the griz cube. The confirmed quasars can be used to
probe gas in the halo of M31. The plates used for this program also
included F star targets.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
fstar72 |
Quasars |
0x80000004 |
174 |
Regular ugri quasar target selection |
Double-lobed radio sources
Quasar target selection targets unresolved optical counterparts to
FIRST radio sources, while "serendipity" target selection
(see the
EDR paper, Stoughton et al. 2002; we also provide this html version of the EDR
paper) selects FIRST sources with extended optical counterparts.
This works fine for compact or core-dominated radio sources, but is
less effective for double-lobed radio sources, in which the optical
counterpart is associated with a point between the two. An algorithm
was developed to find these double-lobed sources, including allowing
for the more challenging case of bent double sources. In
particular, pairs of FIRST sources separated by 90′′ or
less without SDSS optical counterparts were identified. Given the
distance d between the centers of these two sources, a
rectangle is drawn centered at the midpoint between the sources, with
dimensions 0.57d, 1.33d, with the short axis
parallel to the line connecting the two sources. This box size was
chosen empirically to include the core of a sample of bent double
sources compiled by E. Blanton (see Blanton
et al. 2001). Optical counterparts with r < 19.8
that fell into the box were selected as bent double counterparts. A
subset of those objects, which fell into a 12 arcsec square centered
on the midpoint between the sources, were selected as straight double
counterparts.
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged48 |
Bent double-lobed radio sources |
0x80200000 |
97 |
See text |
|
Straight double-lobed radio sources |
0x80000010 |
13 |
See text |
Variability
As discussed above, the Southern Equatorial Stripe has been imaged
multiple times in the course of the SDSS, allowing photometric
variability to be studied. Variable sources were selected for
follow-up spectroscopy using pairs of observations of unique
unsaturated point sources with i < 21, and requiring
that the changes in the g and r bands exceed 0.1
mag, and are at least 3 sigma significant (using error estimates
computed by the photometric pipeline). The time difference between the
two observations varied from 56 days to 1212 days.
This target selection produced targets over the Southern Equatorial
stripe with a surface density of about 10 objects
deg-2. The majority of these targets have colors consistent
with z < 2 (UV excess) quasars and RR Lyrae stars,
classifications confirmed by the spectroscopy. Out of these, 978 have
been observed on DR4 special plates (as for other special plates,
objects which had already been observed on regular survey plates were
not reobserved).
Chunk |
Target category |
primtarget |
# of targets |
Selection |
merged73 |
Variability: high priority |
0x81000000 |
318 |
See text, and i < 19.5 |
|
Variability: low priority |
0x80800000 |
660 |
See text, and 19.5 ≤ i < 21 |
Last modified: Mon Jan 23 11:31:28 CST 2006
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