Fault-tolerant Model Predictive Control for Spacecraft
By: Raphael Stöckner , Pedro Roque , Maria Charitidou and more
Potential Business Impact:
Keeps broken satellites from crashing into others.
Given the cost and critical functions of satellite constellations, ensuring mission longevity and safe decommissioning is essential for space sustainability. This article presents a Model Predictive Control for spacecraft trajectory and setpoint stabilization under multiple actuation failures. The proposed solution allows us to efficiently control the faulty spacecraft enabling safe navigation towards servicing or collision-free trajectories. The proposed scheme ensures closed-loop asymptotic stability and is shown to be recursively feasible. We demonstrate its efficacy through open-source numerical results and realistic experiments using the ATMOS platform.
Similar Papers
Time-Optimal Model Predictive Control for Linear Systems with Multiplicative Uncertainties
Systems and Control
Guides robots to move perfectly, even when unsure.
MPC for momentum counter-balanced and zero-impulse contact with a free-spinning satellite
Systems and Control
Helps robots grab spinning satellites safely.
A Tilting-Rotor Enhanced Quadcopter Fault-Tolerant Control Based on Non-Linear Model Predictive Control
Systems and Control
Drone keeps flying even if a part breaks.