1 / 19

LBTI/NOMIC data analysis

LBTI/NOMIC data analysis. B. Mennesson , D . Defrère, P. Hinz , B . Hoffmann, O . Absil , B . Danchi, R. Millan-Gabet , and A. Skemer. Instrument Status Review Tucson AZ Sep 4 2013. Group activities. Detector and background characterization Noise mitigation strategies

maleah
Télécharger la présentation

LBTI/NOMIC data analysis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. LBTI/NOMIC data analysis B. Mennesson, D. Defrère, P. Hinz, B. Hoffmann, O. Absil, B. Danchi, R. Millan-Gabet, and A. Skemer Instrument Status Review Tucson AZ Sep 4 2013

  2. Group activities • Detector and background characterization • Noise mitigation strategies • Optimization of chopping/nodding frequency • Definition of data acquisition sequence • Computation of key instrument performance indicators • Adaptation of statistical reduction technique

  3. Group activities • Detector and background characterization • Noise mitigation strategies • Optimization of chopping/nodding frequency • Definition of data acquisition sequence • Computation of key instrument performance indicators • Adaptation of statistical reduction technique ✓

  4. Group activities • Detector and background characterization • Noise mitigation strategies • Optimization of chopping/nodding frequency • Definition of data acquisition sequence • Computation of key instrument performance indicators • Adaptation of statistical reduction technique ✓ ✓

  5. Group activities • Detector and background characterization • Noise mitigation strategies • Optimization of chopping/nodding frequency • Definition of data acquisition sequence • Computation of key instrument performance indicators • Adaptation of statistical reduction technique ✓ ✓ ✓

  6. Group activities • Detector and background characterization • Noise mitigation strategies • Optimization of chopping/nodding frequency • Definition of data acquisition sequence • Computation of key instrument performance indicators • Adaptation of statistical reduction technique ✓ ✓ ✓ ✓

  7. Group activities • Detector and background characterization • Noise mitigation strategies • Optimization of chopping/nodding frequency • Definition of data acquisition sequence • Computation of key instrument performance indicators • Adaptation of statistical reduction technique ✓ ✓ ✓ ✓ ✓

  8. Group activities • Detector and background characterization • Noise mitigation strategies • Optimization of chopping/nodding frequency • Definition of data acquisition sequence • Computation of key instrument performance indicators • Adaptation of statistical reduction technique ✓ ✓ ✓ ✓ ✓ ✗

  9. Detector and background • Complex spatiotemporal fluctuations • Flux-dependent detector behavior • Temporal and spatial noise correlation • Must be corrected for accurate null measurements Detector Background

  10. Noise mitigation strategies • Investigated various strategies: Concentric Vertical offset Horizontal offset OBVIOUS DRIFT Time series of residual background (DARK frames, June 27th 2013 – 55ms)

  11. Detector frame DARKS Noise mitigation strategies Photometric aperture Background regions (optimized for r=0.64l/D) Corrected Raw DIT=21ms

  12. Detector frame BACKGROUND Noise mitigation strategies Photometric aperture Background regions (optimized for r=0.64l/D) chopping/nodding Corrected Raw DIT=55ms

  13. Noise mitigation strategies • 40-min of sky data nodding every ~1min30 (June 27th 2013) • Offset reduced to ~8 ADU/PSF (+ Gaussian noise) DIT=55ms DIT=55ms WITHOUT NODDING SUBTRACTION WITH NODDING SUBTRACTION

  14. Noise mitigation strategies • 40-min of sky data nodding every ~1min30 (June 27th 2013) • Offset reduced to ~8 ADU/PSF (+ Gaussian noise) DIT=55ms DIT=55ms WITHOUT NODDING SUBTRACTION WITH NODDING SUBTRACTION

  15. Noise mitigation strategies Vega on June 27th (40 min of integration) DIT=55ms = bias = noise • Measured Vega’s flux ~ 2.2*105ADU/PSF in 55ms (optimum aperture) • Background noise is ~0.2% in 55ms (i.e., 0.07 Jy) • Background bias is ~0.004% (i.e., 0.001 Jy)

  16. Background b Leo ~ 10 sec Altair ~ 1 sec Vega ~ 0.6 sec Minimum integration time necessary to achieve 3-zodi sensitivity (assuming 1 zodi = 5.10-5). Comparing shot noise on constant background (ideal non realistic case) with current measured background uncertainty (after spatio/temporal correction of fluctuations)

  17. Chopping/nodding frequency • Nodding frequency: • Remove quasi-static offsets between photometric aperture and background regions • Can be slow (a few minutes or more) • Chopping frequency: • Relaxed thanks to simultaneous background subtraction technique • Will be constrained by photometric calibration (more data needed) • Likely to be slow • Still needed in conjunction of nodding for accurate background removal

  18. Data acquisition sequence 4 1 2 3 REF R+L L R NOD 0 REF R R+L L INTERFEROMETRIC FRAME - Chop positions: (1,1) - Nod positions: (0,0) PHOTOMETRIC FRAME - Chop positions: (1,2) - Nod positions: (0,0) INTERFEROMETRIC FRAME - Chop positions: (2,2) - Nod positions: (0,0) PHOTOMETRIC FRAME - Chop positions: (2,1) - Nod positions: (0,0) 8 5 6 7 REF R+L L R NOD 1 REF R R+L L INTERFEROMETRIC FRAME - Chop positions: (1,1) - Nod positions: (1,1) PHOTOMETRIC FRAME - Chop positions: (1,2) - Nod positions: (1,1) INTERFEROMETRIC FRAME - Chop positions: (2,2) - Nod positions: (1,1) PHOTOMETRIC FRAME - Chop positions: (2,1) - Nod positions: (1,1)

  19. Ongoing and future analysis • Statistical reduction technique. Adaptation from NIR Palomar Fiber • Nuller not straightforward: • 1D to 2D data • Higher background at 10microns • No single-mode fibers used -> higher phase orders than piston • Computation of chopping frequency (photometric calibration) • Determination of OPD reset frequency • - How long does the NIR OPD target remain valid in the MIR ? • - Transverse atm dispersion • - Other chromatic effects?

More Related