TY - JOUR
T1 - Holistic spectroscopy
T2 - Complete reconstruction of a wide-field, multiobject spectroscopic image using a photonic comb
AU - Kos, Janez
AU - Bland-Hawthorn, Joss
AU - Betters, Christopher H.
AU - Leon-Saval, Sergio
AU - Asplund, Martin
AU - Buder, Sven
AU - Casey, Andrew R.
AU - D'Orazi, Valentina
AU - Silva, Gayandhi de
AU - Freeman, Ken
AU - Lewis, Geraint
AU - Lin, Jane
AU - Martell, Sarah L.
AU - Schlesinger, Katharine
AU - Sharma, Sanjib
AU - Simpson, Jeffrey D.
AU - Zucker, Daniel
AU - Zwitter, Tomaž
AU - Hayden, Michael
AU - Horner, Jonathan
AU - Nataf, David M.
AU - Ting, Yuan Sen
N1 - Publisher Copyright:
© 2018 The Author(s).
PY - 2018
Y1 - 2018
N2 - The primary goal of Galactic archaeology is to learn about the origin of the Milky Way from the detailed chemistry and kinematics of millions of stars. Wide-field multifibre spectrographs are increasingly used to obtain spectral information for huge samples of stars. Some surveys (e.g. GALAH) are attempting tomeasure up to 30 separate elements per star. Stellar abundance spectroscopy is a subtle art that requires a very high degree of spectral uniformity across each of the fibres. However, wide-field spectrographs are notoriously non-uniform due to the fast output optics necessary to image many fibre outputs on to the detector. We show that precise spectroscopy is possible with such instruments across all fibres by employing a photonic comb - a device that produces uniformly spaced spots of light on the CCD to precisely map complex aberrations. Aberrations are parametrized by a set of orthogonal moments with ~100 independent parameters. We then reproduce the observed image by convolving high-resolution spectral templates with measured aberrations as opposed to extracting the spectra from the observed image. Such a forward modelling approach also trivializes some spectroscopic reduction problems like fibre cross-talk, and reliably extracts spectra with a resolution ~2.3 times above the nominal resolution of the instrument. Our rigorous treatment of optical aberrations also encourages a less conservative spectrograph design in the future.
AB - The primary goal of Galactic archaeology is to learn about the origin of the Milky Way from the detailed chemistry and kinematics of millions of stars. Wide-field multifibre spectrographs are increasingly used to obtain spectral information for huge samples of stars. Some surveys (e.g. GALAH) are attempting tomeasure up to 30 separate elements per star. Stellar abundance spectroscopy is a subtle art that requires a very high degree of spectral uniformity across each of the fibres. However, wide-field spectrographs are notoriously non-uniform due to the fast output optics necessary to image many fibre outputs on to the detector. We show that precise spectroscopy is possible with such instruments across all fibres by employing a photonic comb - a device that produces uniformly spaced spots of light on the CCD to precisely map complex aberrations. Aberrations are parametrized by a set of orthogonal moments with ~100 independent parameters. We then reproduce the observed image by convolving high-resolution spectral templates with measured aberrations as opposed to extracting the spectra from the observed image. Such a forward modelling approach also trivializes some spectroscopic reduction problems like fibre cross-talk, and reliably extracts spectra with a resolution ~2.3 times above the nominal resolution of the instrument. Our rigorous treatment of optical aberrations also encourages a less conservative spectrograph design in the future.
KW - Instrumentation: spectrographs
KW - Methods: data analysis
KW - Stars: abundances
KW - Techniques: image processing
KW - Techniques: spectroscopic
UR - http://www.scopus.com/inward/record.url?scp=85055166896&partnerID=8YFLogxK
U2 - 10.1093/MNRAS/STY2175
DO - 10.1093/MNRAS/STY2175
M3 - Article
SN - 0035-8711
VL - 480
SP - 5475
EP - 5494
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 4
ER -