Archive/Intelligent Path Planning Method for Lunar Rovers
Intelligent Path Planning Method for Lunar Rovers
He Tian, Hanguang Zhao, Xinchao Xu et al.
July 17, 2026
en

Abstract

To address the safety, efficiency, and adaptability challenges of autonomous path planning for lunar rovers in complex and unknown terrain, this study proposes a path planning method that integrates deep reinforcement learning with Hybrid A*. Multi-level obstacle maps are generated from lunar digital elevation models and local terrain reconstruction, and an environment model integrating terrain features and rover states is constructed. A Deep Deterministic Policy Gradient framework is introduced, including a state encoder, a policy network, and dual Q-networks, to dynamically adapt the search parameters of Hybrid A* and optimize the path-cost function online. Simulation experiments are conducted under simple, moderate, and complex scenarios. The results show that the proposed method achieves a 100% path planning success rate in the evaluated baseline scenarios, with comprehensive accuracy scores of 0.931, 0.907, and 0.886, respectively. It outperforms conventional A*, RRT, and Hybrid A* algorithms in path length, smoothness, and safety. The method can support safe and efficient autonomous exploration by lunar rovers under the tested dynamic-illumination and multi-obstacle conditions and provides technical support for future deep-space exploration missions such as Chang’e and Tianwen.

IPC Classification

G06H04

Keywords

intelligentpathplanninglunarroversappliedsciencesaddresssafetyefficiencyadaptabilitychallengesautonomouscomplexunknownterrainproposesintegratesdeepreinforcementlearninghybridmulti-levelobstacle
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