Extremely Large Telescope

FMOS: The fiber multiple-object spectrograph VI: On board performances and results of the engineering observations

Proceedings of SPIE - The International Society for Optical Engineering 7014 (2008)

Authors:

F Iwamuro, T Maihara, M Akiyama, M Kimura, N Tamura, N Takato, K Ohta, S Eto, Y Moritani, GB Dalton, IJ Lewis, H Lee, IAJ Tosh, TR Froud, GJ Murray, C Blackburn, DG Bonfield, PR Gillingham, S Smedley, GA Smith, G Frost

Abstract:

FMOS: the Fiber Multiple-Object Spectrograph is the next common-use instrument of the Subaru Telescope, having a capability of 400 targets multiplicity in the near-infrared 0.9-1.8μm wavelength range with a field coverage of 30- diameter. FMOS consists of three units: 1) the prime focus unit including the corrector lenses, the Echidna fiber positioner, and the instrument-bay to adjust the instrument focus and shift the axis of the corrector lens system, 2) the fiber bundle unit equipping two fiber slits on one end and a fiber connector box with the back-illumination mechanism on the other end on the bundle, 3) the two infrared spectrographs (IRS1 and IRS2) to obtain 2×200 spectra simultaneously. After all the components were installed in the telescope at the end of 2007, the total performance was checked through various tests and engineering observations. We report the results of these tests and demonstrate the performance of FMOS.

Implementation of differential wavefront sampling in optical alignment of pupil-segmented telescope systems

Proceedings of SPIE - The International Society for Optical Engineering 7017 (2008)

Authors:

H Lee, GB Dalton, IAJ Tosh, SW Kim

Abstract:

We describe the implementation of differential wavefront sampling(DWS) in optical alignment of a pupilsegmented telescope system. As a wavefront-based optical alignment method, DWS can efficiently provide estimations of misalignments present in an optical system by deliberately perturbing optical elements in a systematic manner. This has been demonstrated in our previous numerical studies with realistic uncertainties in wavefront measurements, motion control, and optical surface deformations, suggesting that the method has potential in optical alignment and phasing of pupil-segmented systems such as the future Extremely Large Telescopes (ELTs). The basic idea and procedures of DWS are first described. We then present and discuss preliminary simulations using the currently proposed European Extremely Large Telescope (E-ELT) as an example system.

Integration, commissioning and performance of the UK FMOS spectrograph

Proceedings of SPIE - The International Society for Optical Engineering 7014 (2008)

Authors:

GB Dalton, IJ Lewis, IAJ Tosh, C Blackburn, DG Bonfield, Charles, B Brooks, AR Holmes, H Lee, TR Froud, M Akiyama, N Tamura, N Takato

Abstract:

The UK FMOS spectrograph forms part of Subaru's FMOS multi-object infrared spectroscopy facility. The spectrograph was shipped to Hilo in component form in August of 2007. We describe the integration sequence for the spectrograph, the results of cooldown tests using a new chiller unit fitted to the spectrograph at the telescope, and alignment tests of the spectrograph, gratings and OH-suppression masks. We present the first-light observations for the spectrograph from May 2008.

Management of optical interfaces in the VLT KMOS instrument

Proceedings of SPIE - The International Society for Optical Engineering 7017 (2008)

Authors:

P Rees, R Content, M Dubbeldam, I Lewis, S Rolt, S Todd, I Tosh

Abstract:

The heart of the KMOS instrument is a complex optical system with over 300 separate optical paths. The optical design is spread between 4 sub-systems which have been designed at three different institutions. In order that the end to end performance of the final design can be monitored and controlled it is necessary to specify the performance and interface requirements of each sub-system clearly. This paper describes the parameters that were necessary to control so that the sub-system designs could be carried out independently while maintaining visibility and control of the end to end performance. The method of apportioning the budgets between the sub-systems and the modeling performed to verify compliance is also described.

System design and analysis of the exo-planet imaging camera and spectrograph (EPICS) for the European ELT

Proceedings of SPIE - The International Society for Optical Engineering 7014 (2008)

Authors:

C Vérinaud, V Korkiakoskia, N Yaitskova, P Martinez, EK Markus, Jean-Luc Beuzit, Lyu Abe, Pierr, Baudozd, Anthony Boccalettid, Kjetil Dohlene, GG Raffaele, Dino Mesaf, Florian Kerberb, Hans Martin Schmidg, Lars Venema, Graeme Slater, Matthias Tecza, AT Niranjan

Abstract:

One of the main science objectives of the European ELT is the direct imaging of extrasolar planets. The large aperture of the telescope has the potential to significantly enlarge the discovery space towards older gas giant exo-planets seen in reflected light. In this paper, we give an overview of the EPICS system design strategy during the phase A study. In order to tackle the critical limitations to high contrast, extensive end-to-end simulations will be developed since the start to test different scenarios and guide the overall design. Keywords: Extremely Large Telescope, high contrast imaging, extrasolar planets, instrumentation, adaptive optics.