TY - GEN
T1 - Photonic technologies for a pupil remapping interferometer
AU - Tuthill, Peter
AU - Jovanovic, Nemanja
AU - Lacour, Sylvestre
AU - Lehmann, Andrew
AU - Ams, Martin
AU - Marshall, Graham
AU - Lawrenc, Jon
AU - Withford, Michael
AU - Robertson, Gordon
AU - Ireland, Michael
AU - Pope, Benjamin
AU - Stewart, Paul
PY - 2010
Y1 - 2010
N2 - Interest in pupil-remapping interferometry, in which a single telescope pupil is fragmented and recombined using fiber optic technologies, has been growing among a number of groups. As a logical extrapolation from several highly successful aperture masking programs underway worldwide, pupil remapping offers the advantage of spatial filtering (with single-mode fibers) and in principle can avoid the penalty of low throughput inherent to an aperture mask. However in practice, pupil remapping presents a number of difficult technological challenges including injection into the fibers, pathlength matching of the device, and stability and reproducibility of the results. Here we present new approaches based on recently-available photonic technologies in which coherent threedimensional waveguide structures can be sculpted into bulk substrate. These advances allow us to miniaturize the photonic processing into a single, robust, thermally stable element; ideal for demanding observatory or spacecraft environments. Ultimately, a wide range of optical functionality could be routinely fabricated into such structures, including beam combiners and dispersive or wavelength selective elements, bringing us closer to the vision of an interferometer on a chip.
AB - Interest in pupil-remapping interferometry, in which a single telescope pupil is fragmented and recombined using fiber optic technologies, has been growing among a number of groups. As a logical extrapolation from several highly successful aperture masking programs underway worldwide, pupil remapping offers the advantage of spatial filtering (with single-mode fibers) and in principle can avoid the penalty of low throughput inherent to an aperture mask. However in practice, pupil remapping presents a number of difficult technological challenges including injection into the fibers, pathlength matching of the device, and stability and reproducibility of the results. Here we present new approaches based on recently-available photonic technologies in which coherent threedimensional waveguide structures can be sculpted into bulk substrate. These advances allow us to miniaturize the photonic processing into a single, robust, thermally stable element; ideal for demanding observatory or spacecraft environments. Ultimately, a wide range of optical functionality could be routinely fabricated into such structures, including beam combiners and dispersive or wavelength selective elements, bringing us closer to the vision of an interferometer on a chip.
KW - Astrophotonics
KW - Direct write technique
KW - Optical interferometry
KW - Ultrafast material processing
UR - http://www.scopus.com/inward/record.url?scp=79953066793&partnerID=8YFLogxK
U2 - 10.1117/12.856770
DO - 10.1117/12.856770
M3 - Conference contribution
SN - 9780819482242
T3 - Proceedings of SPIE - The International Society for Optical Engineering
BT - Optical and Infrared Interferometry II
T2 - Optical and Infrared Interferometry II
Y2 - 27 June 2010 through 2 July 2010
ER -