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Auteurs principaux: Kautz, Maggie Y., Kelly, Douglas, Choi, Heejoo, Kim, Young Sik, Coronado, Fernando, Ard, Cameron C., Ingraham, Patrick, Kim, Daewook, Douglas, Ewan S.
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2508.21245
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author Kautz, Maggie Y.
Kelly, Douglas
Choi, Heejoo
Kim, Young Sik
Coronado, Fernando
Ard, Cameron C.
Ingraham, Patrick
Kim, Daewook
Douglas, Ewan S.
author_facet Kautz, Maggie Y.
Kelly, Douglas
Choi, Heejoo
Kim, Young Sik
Coronado, Fernando
Ard, Cameron C.
Ingraham, Patrick
Kim, Daewook
Douglas, Ewan S.
contents Recent advances in CMOS technology have potential to significantly increase the performance, at low-cost, of an astronomical space telescope. Arrays of sensors in space missions are typically contiguous and act as a monolithic detector. A non-contiguous array, with gaps between individual commercial CMOS detectors, offers potential cost and schedule benefits but poses a unique challenge for stray/scattered light mitigation due to complexities in the optomechanics. For example, if the array of detectors is being fed a large field of view, then each detector will have a different angle of incidence. Any individual bandpass filters need to be held perpendicular to the incoming beam so as not to create variances of central wavelength transmission from detector to detector. It naturally follows that the optical design can force filter ghosts to fall between detectors. When dealing with well-focused, high-intensity beams, first and second order stray light path analyses must be conducted to determine scattered light from glints off of individual optics/opto-mechanics or detector specific vane structures. More mechanical structures are necessary for imaging with non-contiguous arrays, all of which have potential to increase scattered light. This proceeding will document various stray light mitigation strategies for a non-contiguous array of sensors in a space telescope.
format Preprint
id arxiv_https___arxiv_org_abs_2508_21245
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Stray and Scattered Light Considerations in a Non-contiguous Array of Commercial CMOS Sensors in a Space Mission
Kautz, Maggie Y.
Kelly, Douglas
Choi, Heejoo
Kim, Young Sik
Coronado, Fernando
Ard, Cameron C.
Ingraham, Patrick
Kim, Daewook
Douglas, Ewan S.
Instrumentation and Methods for Astrophysics
Recent advances in CMOS technology have potential to significantly increase the performance, at low-cost, of an astronomical space telescope. Arrays of sensors in space missions are typically contiguous and act as a monolithic detector. A non-contiguous array, with gaps between individual commercial CMOS detectors, offers potential cost and schedule benefits but poses a unique challenge for stray/scattered light mitigation due to complexities in the optomechanics. For example, if the array of detectors is being fed a large field of view, then each detector will have a different angle of incidence. Any individual bandpass filters need to be held perpendicular to the incoming beam so as not to create variances of central wavelength transmission from detector to detector. It naturally follows that the optical design can force filter ghosts to fall between detectors. When dealing with well-focused, high-intensity beams, first and second order stray light path analyses must be conducted to determine scattered light from glints off of individual optics/opto-mechanics or detector specific vane structures. More mechanical structures are necessary for imaging with non-contiguous arrays, all of which have potential to increase scattered light. This proceeding will document various stray light mitigation strategies for a non-contiguous array of sensors in a space telescope.
title Stray and Scattered Light Considerations in a Non-contiguous Array of Commercial CMOS Sensors in a Space Mission
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2508.21245