This paper focuses on the application of reinforcement learning to the robust design of low-thrust interplanetary trajectories in presence of severe dynamical uncertainties modeled as Gaussian additive process noise. A closed-loop control policy is used to steer the spacecraft to a final target state despite the perturbations. The control policy is approximated by a deep neural network, trained by reinforcement learning to output the optimal control thrust given as input the current spacecraft state. The effectiveness of three different model-free reinforcement learning algorithms is assessed and compared on a three-dimensional low-thrust transfer between Earth and Mars elected as study case.
Comparative Analysis of Reinforcement Learning Algorithms for Robust Interplanetary Trajectory Design / Federici, Lorenzo; Zavoli, Alessandro; Furfaro, Roberto. - 1088:(2023), pp. 133-149. (Intervento presentato al convegno 2nd International Conference on Applied Intelligence and Informatics , AII 2022 tenutosi a Reggio Calabria, Italia) [10.1007/978-3-031-25755-1_9].
Comparative Analysis of Reinforcement Learning Algorithms for Robust Interplanetary Trajectory Design
Federici, Lorenzo;Zavoli, Alessandro;
2023
Abstract
This paper focuses on the application of reinforcement learning to the robust design of low-thrust interplanetary trajectories in presence of severe dynamical uncertainties modeled as Gaussian additive process noise. A closed-loop control policy is used to steer the spacecraft to a final target state despite the perturbations. The control policy is approximated by a deep neural network, trained by reinforcement learning to output the optimal control thrust given as input the current spacecraft state. The effectiveness of three different model-free reinforcement learning algorithms is assessed and compared on a three-dimensional low-thrust transfer between Earth and Mars elected as study case.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
