Exoatmospheric Evasion Guidance Law with Total Energy Limit via Constrained Reinforcement Learning

Abstract

AbstractDue to the lack of aerodynamic forces, the available propulsion for exoatmospheric pursuit-evasion problem is strictly limited, which has not been thoroughly investigated. This paper focuses on the evasion guidance in an exoatmospheric environment with total energy limit. A Constrained Reinforcement Learning (CRL) method is proposed to solve the problem. Firstly, the acceleration commands of the evader are defined as cost and an Actor-Critic-Cost (AC2) network structure is established to predict the accumulated cost of a trajectory. The learning objective of the agent becomes to maximize cumulative rewards while satisfying the cost constraint. Secondly, a Maximum-Minimum Entropy Learning (M2EL) method is proposed to minimize the randomness of acceleration commands while preserving the agent’s exploration capability. Our approaches address two challenges in the application of reinforcement learning: constraint specification and precise control. The well-trained agent is capable of generating accurate commands while satisfying the specified constraints. The simulation results indicate that the CRL and M2EL methods can effectively control the agent’s energy consumption within the specified constraints. The robustness of the agent under information error is also validated.