The CubeSat Laser Infrared CrosslinK Mission (CLICK)

Cahoy, Kerri; Grenfell, Peter; Crews, Angela; Long, Michael A.; Serra, Paul; Nguyễn, Anh Ngọc; Fitzgerald, Riley; Haughwout, Christian; Diez, Rodrigo; Aguilar, Alexa; Conklin, John; Payne, Cadence; Kusters, Joseph; Sackier, Chlöe V.; LaRocca, Mia; Yenchesky, Laura

doi:10.1117/12.2535953

Cited by 27 publications

(16 citation statements)

References 10 publications

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“…The ATP system in a laser terminal typically consists of a coarse pointing assembly (CPA) and a fine pointing assembly. The CPA provides coarse alignment of laser beams, and has a wide field of view and low precision while the fine pointing assembly has a narrow field of view and high precision, and aligns laser beams to achieve the desired pointing accuracy [17]. The CPA enables the ATP system to roughly point the laser beam in the desired direction without reorientation of the satellite.…”

Section: Discussionmentioning

confidence: 99%

“…Due to the low SWaP and cost requirements of small satellites like CubeSats, the ATP system design in CubeSat Lasercom Infrared CrosslinK (or CLICK) project [17] does not use a CPA and relies on satellite's attitude determination and control system for body pointing to achieve coarse pointing. Compared to CubeSats, the ATP system in SpaceX's Starlink satellites will have higher SWaP and cost.…”

Section: Discussionmentioning

confidence: 99%

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Laser Intersatellite Links in a Starlink Constellation: A Classification and Analysis

Chaudhry

Yanıkömeroğlu

2021

IEEE Veh. Technol. Mag.

106

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Laser inter-satellite links (LISLs) are envisioned between satellites in upcoming satellite constellations, such as Phase I of SpaceX's Starlink. Within a constellation, satellites can establish LISLs with other satellites in the same orbital plane or in different orbital planes. We present a classification of LISLs based on the location of satellites within a constellation and the duration of LISLs. Then, using satellite constellation for Phase I of Starlink, we study the effect of varying a satellite's LISL range on the number of different types of LISLs it can establish with other satellites. In addition to permanent LISLs, we observe a significant number of temporary LISLs between satellites in crossing orbital planes. Such LISLs can play a vital role in achieving low-latency paths within nextgeneration optical wireless satellite networks.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Laser Intersatellite Links in a Starlink Constellation: A Classification and Analysis

Chaudhry

Yanıkömeroğlu

2021

IEEE Veh. Technol. Mag.

106

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“…Many proposed solutions to the attitude control limitations of CubeSats have been in the form of second-stage correction (Beierle et al, 2018;Pong, 2018;Cahoy et al, 2019). ASTERIA (Arcsecond Space Telescope Enabling Research in Astrophysics) is the first sub-arcsecond imaging CubeSat (Pong, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…The science telescope on ASTERIA operates at 20 Hz, reading out 50-ms exposures for science and pointing control, limiting the detectable stellar magnitude to m V < 7 since dimmer stars do not flip the detector's first analog-to-digital bit (Knapp et al, 2020a) in an exposure. Similarly, the CLICK free-space laser communications CubeSats (Cahoy et al, 2019), due for launch in 2021, will use microelectromechanical systems (MEMS)-based steering mirrors to achieve fine pointing, while the DeMi mission launched in 2020 is designed to use a MEMS deformable mirror for fine wavefront steering (Morgan et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Practical Limits on Nanosatellite Telescope Pointing: The Impact of Disturbances and Photon Noise

Douglas¹,

Tracy

Manchester

2021

Front. Astron. Space Sci.

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Accurate and stable spacecraft pointing is a requirement of many astronomical observations. Pointing particularly challenges nanosatellites because of an unfavorable surface area–to-mass ratio and a proportionally large volume required for even the smallest attitude control systems. This work explores the limitations on astrophysical attitude knowledge and control in a regime unrestricted by actuator precision or actuator-induced disturbances such as jitter. The external disturbances on an archetypal 6U CubeSat are modeled, and the limiting sensing knowledge is calculated from the available stellar flux and grasp of a telescope within the available volume. These inputs are integrated using a model-predictive control scheme. For a simple test case at 1 Hz, with an 85-mm telescope and a single 11th magnitude star, the achievable body pointing is predicted to be 0.39 arcseconds. For a more general limit, integrating available star light, the achievable attitude sensing is approximately 1 milliarcsecond, which leads to a predicted body pointing accuracy of 20 milliarcseconds after application of the control model. These results show significant room for attitude sensing and control systems to improve before astrophysical and environmental limits are reached.

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“…Many proposed solutions to the attitude control limitations of CubeSats have been in the form of secondstage correction (Beierle et al, 2018;Pong, 2018;Cahoy et al, 2019). ASTERIA (Arcsecond Space Telescope Enabling Research in Astrophysics) is the first sub-arcsecond imaging CubeSat (Pong, 2018).…”

Section: Introductionmentioning

confidence: 99%

Practical limits on Nanosatellite Telescope Pointing: The Impact of Disturbances and Photon Noise

Douglas,

Tracy,

Manchester

2021

Preprint

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Accurate and stable spacecraft pointing is a requirement of many astronomical observations. Pointing particularly challenges nanosatellites because of an unfavorable surface area to mass ratio and proportionally large volume required for even the smallest attitude control systems. This work explores the limitations on astrophysical attitude knowledge and control in a regime unrestricted by actuator precision or actuator-induced disturbances such as jitter. The external disturbances on an archetypal 6U CubeSat are modeled and the limiting sensing knowledge is calculated from the available stellar flux and grasp of a telescope within the available volume. These inputs are integrated using a model-predictive control scheme. For a simple test case at 1 Hz, with an 85 mm telescope and a single 11th magnitude star, the achievable body pointing is predicted to be 0.39 arcseconds. For a more general limit, integrating available star light, the achievable attitude sensing is approximately 1 milliarcsecond, which leads to a predicted body pointing accuracy of 20 milliarcseconds after application of the control model. These results show significant room for attitude sensing and control systems to improve before astrophysical and environmental limits are reached.

show abstract

The CubeSat Laser Infrared CrosslinK Mission (CLICK)

Cited by 27 publications

References 10 publications

Laser Intersatellite Links in a Starlink Constellation: A Classification and Analysis

Laser Intersatellite Links in a Starlink Constellation: A Classification and Analysis

Practical Limits on Nanosatellite Telescope Pointing: The Impact of Disturbances and Photon Noise

Practical limits on Nanosatellite Telescope Pointing: The Impact of Disturbances and Photon Noise

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