A preliminary design for the GMT-Consortium Large Earth Finder (G-CLEF)
2014; SPIE; Volume: 9147; Linguagem: Inglês
10.1117/12.2056741
ISSN1996-756X
AutoresAndrew Szentgyorgyi, Stuart Barnes, Jacob L. Bean, Bruce C. Bigelow, Antonin H. Bouchez, Moo‐Young Chun, Jeffrey D. Crane, Harland W. Epps, I. N. Evans, Janet D. Evans, Anna Frebel, Gábor Fűrész, Alex Glenday, Dani Guzmán, Tyson Hare, Bi-Ho Jang, Jeong-Gyun Jang, Ueejong Jeong, Andrés Jordán, Kang-Min Kim, Ji-Hun Kim, Chih‐Hao Li, Mercedes López‐Morales, K. G. McCracken, B. A. McLeod, Mark Mueller, Jakyung Nah, Timothy Norton, Heeyoung Oh, Jae Sok Oh, Mark Ordway, Byeong-Gon Park, Chan Park, Sung‐Joon Park, David F. Phillips, David A. Plummer, William Podgorski, F. Rodler, Andreas Seifahrt, Kyung-Mo Tak, Alan Uomoto, Marcos A. van Dam, Ronald L. Walsworth, Young Sam Yu, In-Soo Yuk,
Tópico(s)Stellar, planetary, and galactic studies
ResumoThe GMT-Consortium Large Earth Finder (G-CLEF) is an optical-band echelle spectrograph that has been selected as the first light instrument for the Giant Magellan Telescope (GMT). G-CLEF is a general-purpose, high dispersion spectrograph that is fiber fed and capable of extremely precise radial velocity measurements. The G-CLEF Concept Design (CoD) was selected in Spring 2013. Since then, G-CLEF has undergone science requirements and instrument requirements reviews and will be the subject of a preliminary design review (PDR) in March 2015. Since CoD review (CoDR), the overall G-CLEF design has evolved significantly as we have optimized the constituent designs of the major subsystems, i.e. the fiber system, the telescope interface, the calibration system and the spectrograph itself. These modifications have been made to enhance G-CLEF's capability to address frontier science problems, as well as to respond to the evolution of the GMT itself and developments in the technical landscape. G-CLEF has been designed by applying rigorous systems engineering methodology to flow Level 1 Scientific Objectives to Level 2 Observational Requirements and thence to Level 3 and Level 4. The rigorous systems approach applied to G-CLEF establishes a well defined science requirements framework for the engineering design. By adopting this formalism, we may flexibly update and analyze the capability of G-CLEF to respond to new scientific discoveries as we move toward first light. G-CLEF will exploit numerous technological advances and features of the GMT itself to deliver an efficient, high performance instrument, e.g. exploiting the adaptive optics secondary system to increase both throughput and radial velocity measurement precision.
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