Proposal for a self-calibrating and instrument-independent MOS DRS - PowerPoint PPT Presentation

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Proposal for a self-calibrating and instrument-independent MOS DRS

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Title: Proposal for a self-calibrating and instrument-independent MOS DRS


1
Proposal for a self-calibrating and
instrument-independent MOS DRS
  • Carlo Izzo

2
MOS arc lamp exposure FORS2-MXU, GRIS_150I27
3
Using first-guess models to find reference lines
4
Earthquake!
5
High Expectations
  • Traditional data reduction techniques are
    based on first-guess distortion models.
  • The instrument is stable, together with its
    components (grisms, masks, filter wheels, etc.)
  • The code can be kept simple, because the
    reference patterns in the calibration exposures
    (flats, arcs) are safely identified
  • The procedures will be general, because different
    distortion models can be stored in appropriate
    configuration files

6
The hard reality
  • The instrument is not stable, changing in the
    short and long time scales, requiring continuous
    maintenance work on the configuration files
  • The code cannot be kept simple, because the
    reference patterns are not safely identified
    (e.g., due to unexpected contaminations, or to
    instrument instabilities)
  • The procedures cannot be kept general, because
    the ad hoc solutions adding robustness to the DRS
    are typically instrument-dependent

7
VIMOS
8
Interactive systems
9
First-guess vs pattern-recognition
10
Distortion models parameters
11
DFO reports a problem
12
and the problem is solved
13
but whats the use of it?
  • Using first-guess model
  • The pipeline may stop with a generic calibration
    failed
  • The pipeline may find a wrong solution
  • The QC1 parameters may show nothing strange
  • Using pattern-recognition
  • The pipeline always completes successfully
  • The pipeline always finds the right solution
  • The QC1 parameters report exactly what happened

14
Do we need a physical model of the distortions?
  • YES! A physical model of the optical distortions
    is necessary for comparing the expected
    distortions with the observed ones (instrument
    health monitoring)
  • BUT We should not use the model of the expected
    distortions as a first-guess (even if we may use
    it for fitting the data)
  • ALSO A physical model of the instrument
    distortions is necessary for a meaningful
    instrument health monitoring

15
Fix the models, or fix the instrument?
  • In principle, the instrument should be fixed.
  • In practice, it is often necessary to fix the
    models because
  • To fix the instrument is not always immediate
    (see for instance the light contaminations in
    FORS, or the flexures in VIMOS), and in the
    meantime we must keep reducing the data
  • Sometimes the real optical distortions are
    accepted, even if they are far from the
    instrument original design
  • Using a pattern-recognition approach we would
    not need to fix models anymore!

16
Looking for patterns
  • The pattern wavelengths
  • 5400.562
  • 5460.742
  • 5764.419
  • 5769.598
  • 5790.656
  • 5852.488
  • 5875.620
  • 5881.900
  • 5944.830
  • The data pixel positions
  • 1220.64
  • 1253.23
  • 1299.44
  • 1304.07
  • 1339.30
  • 1400.33
  • 1450.28
  • 1457.32
  • 1471.00
  • 1496.21
  • 1520.66
  • 1522.44
  • 1549.01

17
Looking for peaks
  • ________________________________________

18
Looking for peaks
  • Any local maximum identifies a peak
  • A peak positions is determined by parabolic
    interpolation of the three nearby pixel values

19
Looking for peaks
20
A simple case FORS2-LSS GRIS_1200R
  • _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
    _ _

21
Identifying arc lamp lines
22
Wavelength calibration
  • Mean accuracy 0.05 pixel

23
Resampled spectrum
  • Mean accuracy 0.05 pixel

24
Another case VIMOS GRIS_HRred
25
Wavelength calibration
Mean accuracy 0.07 pixel
26
Another case FORS1-MOS GRIS_300V
27
Wavelength calibration
Mean accuracy 0.09 pixel
28
Another case FORS2-MXU GRIS_150I
29
Wavelength calibration
  • Mean accuracy 0.05 pixel

30
Identifying the slits
  • Select the reference wavelength in this
    example, l 7000.00

31
Rectified image
32
Accuracy
33
Accuracy
  • The accuracy of the extraction mask depends on
    many factors
  • Number of fitted points,
  • Accuracy of peaks positions,
  • Appropriate choice of fitting models,
  • Position along the spectral interval,
  • but, above all,
  • Correct identification of the detected peaks.
  • Inaccuracy comes from misidentification!

34
This system is flexible
  • Any MOS arc lamp exposure can be wavelength
    calibrated (instrument-independency)
  • This method can also be directly applied to the
    scientific exposures (if the sky is visible and
    there are enough sky lines)
  • This method may even be applied to intermediate
    products from any kind of spectroscopic data (not
    just MOS, but also IFU, echelle, etc.).

35
GIRAFFE Medusa1_H525.8nm
Mean accuracy 0.10 pixel
36
Other issues
  • After the extraction mask is completely
    defined, the usual reduction steps can be
    applied
  • Object detection,
  • Determination of the sky spectrum,
  • Optimal extraction,
  • Combining different spectra,
  • Error propagation

37
THE END
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