This paper introduces a novel approach to impulsive control in spacecraft rendezvous operations. By isolating different dynamics and using Lyapunov functions, the authors demonstrate effective control strategies through simulations. The work addresses the increasing complexity of space missions and the need for precise maneuvers near target spacecraft. The study highlights the importance of autonomous guidance and control in various space activities like asteroid mining, collision avoidance, and debris removal. The research builds upon previous works that have focused on feedback laws for rendezvous problems using Model Predictive Control (MPC) strategies. However, this study diverges by utilizing a simpler simulation model while incorporating saturations into the analysis without requiring an optimization process in control law computation. The paper delves into the terminal rendezvous stage with a focus on designing efficient impulsive maneuvers using a hybrid systems framework. By separating out-of-plane and in-plane dynamics, specific feedback control laws are proposed based on Lyapunov functions tailored to each dynamic aspect. These functions are found by expressing dynamics in more natural coordinates that capture their physical behavior. Through simulations, the effectiveness of these control laws is demonstrated, showcasing their ability to address thruster saturation and minimum impulse bit requirements effectively.
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by Alexandre Se... ב- arxiv.org 03-07-2024
https://arxiv.org/pdf/2403.03633.pdfשאלות מעמיקות