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Auteurs principaux: Stoisa, Matteo, Azza, Federica Paganelli, Romanelli, Luca, Varile, Mattia
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2410.12703
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author Stoisa, Matteo
Azza, Federica Paganelli
Romanelli, Luca
Varile, Mattia
author_facet Stoisa, Matteo
Azza, Federica Paganelli
Romanelli, Luca
Varile, Mattia
contents Autonomous Rendezvous and Docking (RVD) have been extensively studied in recent years, addressing the stringent requirements of spacecraft dynamics variations and the limitations of GNC systems. This paper presents an innovative approach employing Artificial Neural Networks (ANN) trained through Reinforcement Learning (RL) for autonomous spacecraft guidance and control during the final phase of the rendezvous maneuver. The proposed strategy is easily implementable onboard and offers fast adaptability and robustness to disturbances by learning control policies from experience rather than relying on predefined models. Extensive Monte Carlo simulations within a relevant environment are conducted in 6DoF settings to validate our approach, along with hardware tests that demonstrate deployment feasibility. Our findings highlight the efficacy of RL in assuring the adaptability and efficiency of spacecraft RVD, offering insights into future mission expectations.
format Preprint
id arxiv_https___arxiv_org_abs_2410_12703
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Neural-based Control for CubeSat Docking Maneuvers
Stoisa, Matteo
Azza, Federica Paganelli
Romanelli, Luca
Varile, Mattia
Machine Learning
Autonomous Rendezvous and Docking (RVD) have been extensively studied in recent years, addressing the stringent requirements of spacecraft dynamics variations and the limitations of GNC systems. This paper presents an innovative approach employing Artificial Neural Networks (ANN) trained through Reinforcement Learning (RL) for autonomous spacecraft guidance and control during the final phase of the rendezvous maneuver. The proposed strategy is easily implementable onboard and offers fast adaptability and robustness to disturbances by learning control policies from experience rather than relying on predefined models. Extensive Monte Carlo simulations within a relevant environment are conducted in 6DoF settings to validate our approach, along with hardware tests that demonstrate deployment feasibility. Our findings highlight the efficacy of RL in assuring the adaptability and efficiency of spacecraft RVD, offering insights into future mission expectations.
title Neural-based Control for CubeSat Docking Maneuvers
topic Machine Learning
url https://arxiv.org/abs/2410.12703