Model-Based Design and Testbed for CubeSat Attitude Determination and Control System with Magnetic Actuation
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Published:2024-07-11
Issue:14
Volume:14
Page:6065
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ISSN:2076-3417
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Container-title:Applied Sciences
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language:en
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Short-container-title:Applied Sciences
Author:
Ticona Coaquira Franklin Josue1ORCID, Wang Xinsheng12, Vidaurre Torrez Karen Wendy3ORCID, Mamani Quiroga Misael Jhamel3ORCID, Silva Plata Miguel Angel3ORCID, Luna Verdueta Grace Abigail3, Murillo Quispe Sandro Estiven3, Auza Banegas Guillermo Javier3, Antezana Lopez Franz Pablo4ORCID, Rojas Arturo1
Affiliation:
1. School of Astronautics, Beihang University, Beijing 100191, China 2. UN Regional Centre for Space Science and Technology Education in Asia and the Pacific (China), Beijing 100191, China 3. Centro de Investigación, Desarrollo e Innovación en Ingeniería Mecatrónica, Universidad Católica Boliviana San Pablo, La Paz 0000, Bolivia 4. School of Instrumentation Science and Optoelectronic Engineering, Beihang University, Beijing 100191, China
Abstract
This study introduces a robust model-based framework designed for the verification and validation (V&V) of Attitude Determination and Control Systems (ADCSs) in nanosatellites, focusing on magnetic actuation while still being applicable to larger spacecraft platforms. By employing Model-in-the-Loop (MIL), Software-in-the-Loop (SIL), Processor-in-the-Loop (PIL), and Hardware-in-the-Loop (HIL) methodologies, this framework enables a thorough and systematic approach to testing and validation. The framework facilitates the assessment of long-term maneuvers, addressing challenges such as initial small-attitude errors and restricted 3D movements. Two specific maneuvers are evaluated: detumbling and nadir pointing, utilizing quaternions and a comprehensive suite of sensors, including six sun sensors, a three-axis magnetometer, a three-axis gyroscope, GPS, and three magnetorquers. The methodologies—MIL, SIL, PIL, and HIL—integrate the behaviors of digital sensors, analog signals, and astrodynamic perturbations. Based on an optimized SIL environment, Monte Carlo simulations were performed to optimize control gains for nadir pointing, achieving a mean pointing accuracy of 11.69° (MIL) and 18.22° (PIL), and an angular velocity norm of 0.0022 rad/s for detumbling. The HIL environment demonstrated a mean pointing accuracy of 9.96° and an angular velocity norm of 0.0024 rad/s. This comprehensive framework significantly advances the design and verification processes for nanosatellite ADCSs, enhancing the reliability and performance of nanosatellite missions.
Funder
CAST, “The Belt and Road” International Science and Technology Organization Cooperation Founding BIMT, Tongxin Program Founding
Reference53 articles.
1. A multiple-CubeSat constellation for integrated earth observation and marine/air traffic monitoring;Wu;Adv. Space Res.,2021 2. CubeSat microsatellite demonstrator with X-ray optical payload;Daniel;Proceedings of the EUV and X-ray Optics: Synergy between Laboratory and Space VIII,2023 3. Lepcha, P., Malmadayalage, T.D., Örger, N.C., Purio, M.A., Duran, F., Kishimoto, M., El-Megharbel, H.A., and Cho, M. (2022). Assessing the Capacity and Coverage of Satellite IoT for Developing Countries Using a CubeSat. Appl. Sci., 12. 4. Aswin, M., Pavithran, A., Mangrole, Y., and Ravi, B. (2022, January 25–26). Structural and Thermal Analysis of a CubeSat. Proceedings of the Conference of Innovative Product Design and Intelligent Manufacturing System, Rourkela, India. 5. Bloser, P., Murphy, D., Fiore, F., and Perkins, J. (2024). CubeSats for gamma-ray astronomy. Handbook of X-ray and Gamma-ray Astrophysics, Springer.
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