Bibcode
Widmann, F.; Pott, Jörg-Uwe; Velasco, S.
Bibliographical reference
Monthly Notices of the Royal Astronomical Society, Volume 475, Issue 1, p.1224-1237
Advertised on:
3
2018
Citations
3
Refereed citations
2
Description
For sensitive infrared interferometry, it is crucial to control the
differential piston evolution between the used telescopes. This is
classically done by the use of a fringe tracker. In this work, we
develop a new method to reconstruct the temporal piston variation from
the atmosphere, by using real-time data from adaptive optics (AO)
wavefront sensing: the Piston Reconstruction Experiment (P-REx). In
order to understand the principle performance of the system in a
realistic multilayer atmosphere, it is first extensively tested in
simulations. The gained insights are then used to apply P-REx to real
data, in order to demonstrate the benefit of using P-REx as an auxiliary
system in a real interferometer. All tests show positive results, which
encourages further research and eventually a real implementation.
Especially, the tests on on-sky data showed that the atmosphere is,
under decent observing conditions, sufficiently well structured and
stable, in order to apply P-REx. It was possible to conveniently
reconstruct the piston evolution in two-thirds of the data sets from
good observing conditions (r0 ˜ 30 cm). The main
conclusion is that applying the piston reconstruction in a real system
would reduce the piston variation from around 10 μm down to 1-2 μm
over time-scales of up to two seconds. This suggests an application for
mid-infrared interferometry, for example for MATISSE at the very large
telescope interferometer or the large binocular telescope
interferometer. P-REx therefore provides the possibility to improve
interferometric measurements without the need for more complex AO
systems than already in regular use at 8-m-class telescopes.