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leveraging LSST

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Title: leveraging LSST


1

leveraging LSST
Tony Tyson Director, LSST Project University of
California, Davis
2
DSS digitized photographic plates
7.5 arcminutes
3
Sloan Digital Sky Survey
4
LSST -- almost
2800 galaxies ilt25 mag
200 for one DESpec FOV
5
LSST Observing Cadence
  • Pairs of 15 second exposures (to 24.5 mag) per
    visit to a given position in the sky.
  • Visit this position again within the hour with
    another pair of exposures.
  • Number of 9.6 sq.deg FOV visits per night 900
  • Deep-Drilling 1 hour per night on a selected
    field. Continuous 15 sec exposures

Detection of transients announced within 60
seconds. Expect 1 million per night
6
Number of visits per field in Deep Wide Survey
7
Two planned LSST surveys
MAIN SURVEY Deep Wide Survey 20,000 square
degrees to a uniform depth of
u 26.7 g 27.4 r 27.7 i 26.9
z 26.1 y 24.9 DEEP DRILLING 10 of time
30 selected fields. 300 square degrees
Continuous 15 sec
exposures. 1hour/night
8
LSST Wide-Fast-Deep survey
  • 4 billion galaxies with photometric redshifts
  • 20 trillion photometric measurements of 20
    billion objects
  • 70PB database
  • Immediate transient alerts

9
LSST Science Book v2.0 written by LSST
Collaboration
  • 245 authors
  • 598 pages
  • Living document
  • (on lsst.org)

http//www.lsst.org/lsst/scibook
10
LSST Science Charts New Territory
Probing Dark Matter And Dark Energy
Mapping the Milky Way
opens the time window!
Finding Near Earth Asteroids
11
Three classes of useful LSST spectroscopy
  1. Calibration samples for quantities that can be
    derived from photometric data photometric
    redshifts for galaxies, photometric metallicity
    for stars
  2. Supplemental data that cannot be obtained from
    LSST data radial velocity, emission and
    absorption line strengths
  3. Identification spectra for transient, weird and
    unusual objects (SNe, GRB followup, high-z
    quasars, brown dwarfs)

These differ by the needed sample size, sample
depth, required spectral resolution, and the
time delay relative to imaging data.
12
The vast majority of LSST science uses LSST
multi-band time domain photometry data alone
  • Some exceptions
  • 1. Photo-z needs spec for rlt24 mag over 10
    sq.deg -gt 10meter
  • 2. TRANSIENTS
  • Rare bright needs 2-4meter
  • Faint (22-24mag) needs 10-30meter
  • 3. Strong lensing magnified source
    spectroscopy
  • 4. SNe zlt1.2 needs 10meter
  • 5. Stellar mostly hi-res

13
190 sq deg
DESpec on Blanco
to 24.5
14
Alert Rate
  • In ten minutes time the LSST transient pipeline
    is likely to issue 10,000 alerts at 5s.
  • While most of these will be moving objects,
    perhaps several thousand will be flaring objects
    or bursts. Possibly new kinds of objects!
  • Clearly any feasible spectroscopic followup at 23
    mag will lag behind 1 hour per hour. What is
    needed then is highly trusted event
    classification. FAST

15
DESpec coverage of LSST surveys
  • ¼ of main 20,000 sq.deg to 22.5 mag at S/N5
  • 0.7 of gold sample of ilt25 mag
    galaxies
  • useful for correlation calibration of
    photo-z
  • deep spectroscopy of deep drilling fields
  • 20 fields, 20 hours each, 50 nights
  • 24 mag _at_ S/N10 per 10Å bin
  • transient host spectra
  • co-observing spectroscopy of deep drilling
    fields
  • 1 hour / night
  • 22 mag _at_ S/N5 per 1Å bin
  • transient spectra

16
DATA PRODUCTS
CLASSIFICATION
17
Science at the Limit
  • Much of the breakthrough science using surveys
    (imaging or spectroscopy) occurs at the limits of
    the surveys
  • Noise, Sample incompleteness
  • Subtle systematic errors

Statistical studies must be corrected for these
errors
18
large spectroscopic samples are useful
  • Example even an incomplete spectroscopic
    sample can help photo-z in two ways
  • angular cross correlation with faint photometric
    sample will calibrate photo-z statistically
    (Newman)
  • large spectroscopic samples can improve
    knowledge of evolution of galaxy SEDs.

19
There are currently 20 telescopes larger than 3m
with spectrographs that can reach the LSST survey
area. Even in the ELT era, wide field
multi-object spectroscopy on 4-10m class
telescopes will be useful Statistics matters.
Calibration of the 70PB LSST database, and
massively parallel follow-up of a million
transients will be complementary to selected
faint object spectroscopy
20
LSST science deliverables do not require followup
spectroscopy
But we can and should pursue a range of followup
programs, from co-observing highly parallel
spectroscopy, to individual object followup.
21
QA
22
Assuring accurate classification
  • Characterize the known clustering)
  • Assign the new (classification)
  • Discover the unknown (outlier detection)

Tom Vestrand
  • Benefits of very large data sets
  • best statistical analysis of typical events
  • automated search for rare events

23
The dimension reduction problem
  • Finding correlations and fundamental planes of
    parameters
  • The Curse of High Dimensionality !
  • Are there combinations (linear or non-linear
    functions) of observational parameters that
    correlate strongly with one another?
  • Are there basis sets that represent the full set
    of properties?
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