Poster + Paper
11 September 2024 From SuperBIT to GigaBIT: informing next-generation balloon-borne telescope design with fine guidance system flight data
Philippe Voyer, Steven J. Benton, Christopher J. Damaren, Spencer W. Everett, Aurelien A. Fraisse, Ajay S. Gill, John W. Hartley, David Harvey, Michael Henderson, Bradley Holder, Eric M. Huff, Mathilde Jauzac, William C. Jones, David Lagattuta, Jason S.-Y. Leung, Lun Li, Thuy Vy T. Luu, Richard Massey, Jacqueline E. McCleary, Johanna M. Nagy, C. Barth Netterfield, Emaad Paracha, Susan F. Redmond, Jason D. Rhodes, Andrew Robertson, L. Javier Romualdez, Jürgen Schmoll, Mohamed M. Shaaban, Ellen L. Sirks, Georgios N. Vassilakis, André Z. Vitorelli
Author Affiliations +
Conference Poster
Abstract
The Super-pressure Balloon-borne Imaging Telescope (SuperBIT) is a near-diffraction-limited 0.5m telescope that launched via NASA’s super-pressure balloon technology on April 16, 2023. SuperBIT achieved precise pointing control through the use of three nested frames in conjunction with an optical Fine Guidance System (FGS), resulting in an average image stability of 0.055” over 300-second exposures. The SuperBIT FGS includes a tip-tilt fast-steering mirror that corrects for jitter on a pair of focal plane star cameras. In this paper, we leverage the empirical data from SuperBIT’s successful 39-day stratospheric mission to inform the FGS design for the next-generation balloon-borne telescope. The Gigapixel Balloon-borne Imaging Telescope (GigaBIT) is designed to be a 1.35m wide-field, high resolution imaging telescope, with specifications to extend the scale and capabilities beyond those of its predecessor SuperBIT. A description and analysis of the SuperBIT FGS will be presented along with methodologies for extrapolating this data to enhance GigaBIT’s FGS design and fine pointing control algorithm. We employ a systems engineering approach to outline and formalize the design constraints and specifications for GigaBIT’s FGS. GigaBIT, building on the SuperBIT legacy, is set to enhance high-resolution astronomical imaging, marking a significant advancement in the field of balloon-borne telescopes.
(2024) Published by SPIE. Downloading of the abstract is permitted for personal use only.
Philippe Voyer, Steven J. Benton, Christopher J. Damaren, Spencer W. Everett, Aurelien A. Fraisse, Ajay S. Gill, John W. Hartley, David Harvey, Michael Henderson, Bradley Holder, Eric M. Huff, Mathilde Jauzac, William C. Jones, David Lagattuta, Jason S.-Y. Leung, Lun Li, Thuy Vy T. Luu, Richard Massey, Jacqueline E. McCleary, Johanna M. Nagy, C. Barth Netterfield, Emaad Paracha, Susan F. Redmond, Jason D. Rhodes, Andrew Robertson, L. Javier Romualdez, Jürgen Schmoll, Mohamed M. Shaaban, Ellen L. Sirks, Georgios N. Vassilakis, and André Z. Vitorelli "From SuperBIT to GigaBIT: informing next-generation balloon-borne telescope design with fine guidance system flight data", Proc. SPIE 13094, Ground-based and Airborne Telescopes X, 130944Z (11 September 2024); https://doi.org/10.1117/12.3017869
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KEYWORDS
Telescopes

Gyroscopes

Design

Control systems

Stars

Cameras

Data modeling

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