TY - GEN
T1 - LFAST, the Large Fiber Array Spectroscopic Telescope
AU - Angel, Roger
AU - Bender, Chad
AU - Berkson, Joel
AU - Didato, Nick
AU - Ford, John
AU - Gray, Peter
AU - Jannuzi, Buell
AU - Ketelsen, Dean
AU - Kim, Daewook
AU - Chavez Lopez, Gilberto
AU - Monson, Andrew
AU - Oh, Chang Jin
AU - Patrou, Jason
AU - Rademacher, Matthew
AU - Schwab, Christian
AU - Sisco, Melanie
AU - Wortley, Rich
AU - Young, Andrew
N1 - Funding Information: This research was funded by the generosity of Eric and Wendy Schmidt, by recommendation of the Schmidt Futures program. Publisher Copyright: © 2022 SPIE.
PY - 2022
Y1 - 2022
N2 - The LFAST concept is to use thousands of small telescopes combined by fibers for high resolution (R=150,000) spectroscopy, in a way that will realize large cost savings and lead to an affordable aperture as large as 20,000 m2. Such large aperture is needed, for example, to make a comprehensive search for biosignatures in the atmospheres of transiting exoplanets. Each unit telescope of 0.76 m aperture (0.43 m2) will focus the image of a single star onto a small (17 μm core) fiber, subtending 1.32 arcsec. Our telescope design calls for a spherical mirror, with a 4-lens assembly at prime focus that corrects not only for spherical aberration, but also for atmospheric dispersion down to 30° elevation, from 390 nm-1700 nm, and for rapid image motion caused by seeing or wind jitter. A method for rapid production of such mirrors has been tested, in which a disc of borosilicate float glass is slumped over a high-precision polished mandrel to an accuracy that greatly reduces subsequent optical finishing time. A method for active thermal control of mirror figure using Peltier devices will be incorporated. The projected cost of each unit telescope, when mass produced by the thousand, would then be approximately $8,000. The telescopes will be mounted in the open in groups of 20 located 12 m apart. The mirrors will be arrayed on either side of a central, pedestal-mounted alt-az drive using commercial worm gear bearings. Protection against rain and dust will be provided by automated covers above and below the mirrors, and by pointing the mirrors down (-20° elevation). The first LFAST array, some 150 m in diameter, will comprise 132 mounts carrying a total of 2,640 mirrors and having 1,200 m2 in collecting area. The light from all the fibers is combined at the central spectrographs, with little increase in etendue, by a 5 x 528 array of adjacent hexagonal lenses. A telecentric lens is used to reimage the lens array at the entrance slits of two echelle spectrographs. Together, these two cover simultaneously the full 390 nm-1700 nm spectral range of the star being observed. The targeted cost for the installed LFAST telescope and fiber array is $60M.
AB - The LFAST concept is to use thousands of small telescopes combined by fibers for high resolution (R=150,000) spectroscopy, in a way that will realize large cost savings and lead to an affordable aperture as large as 20,000 m2. Such large aperture is needed, for example, to make a comprehensive search for biosignatures in the atmospheres of transiting exoplanets. Each unit telescope of 0.76 m aperture (0.43 m2) will focus the image of a single star onto a small (17 μm core) fiber, subtending 1.32 arcsec. Our telescope design calls for a spherical mirror, with a 4-lens assembly at prime focus that corrects not only for spherical aberration, but also for atmospheric dispersion down to 30° elevation, from 390 nm-1700 nm, and for rapid image motion caused by seeing or wind jitter. A method for rapid production of such mirrors has been tested, in which a disc of borosilicate float glass is slumped over a high-precision polished mandrel to an accuracy that greatly reduces subsequent optical finishing time. A method for active thermal control of mirror figure using Peltier devices will be incorporated. The projected cost of each unit telescope, when mass produced by the thousand, would then be approximately $8,000. The telescopes will be mounted in the open in groups of 20 located 12 m apart. The mirrors will be arrayed on either side of a central, pedestal-mounted alt-az drive using commercial worm gear bearings. Protection against rain and dust will be provided by automated covers above and below the mirrors, and by pointing the mirrors down (-20° elevation). The first LFAST array, some 150 m in diameter, will comprise 132 mounts carrying a total of 2,640 mirrors and having 1,200 m2 in collecting area. The light from all the fibers is combined at the central spectrographs, with little increase in etendue, by a 5 x 528 array of adjacent hexagonal lenses. A telecentric lens is used to reimage the lens array at the entrance slits of two echelle spectrographs. Together, these two cover simultaneously the full 390 nm-1700 nm spectral range of the star being observed. The targeted cost for the installed LFAST telescope and fiber array is $60M.
KW - LFAST
KW - etendue
KW - exoplanet transit spectroscopy
KW - fiber-feed
KW - high resolution spectroscopy
KW - telescope arrays
UR - http://www.scopus.com/inward/record.url?scp=85140095885&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85140095885&partnerID=8YFLogxK
U2 - 10.1117/12.2629655
DO - 10.1117/12.2629655
M3 - Conference contribution
T3 - Proceedings of SPIE - The International Society for Optical Engineering
BT - Ground-Based and Airborne Telescopes IX
A2 - Marshall, Heather K.
A2 - Spyromilio, Jason
A2 - Usuda, Tomonori
PB - SPIE
T2 - Ground-Based and Airborne Telescopes IX 2022
Y2 - 17 July 2022 through 22 July 2022
ER -