Home /Research /HSRL: A Hierarchical Control System Based on Spiking Deep Reinforcement Learning for Robot Navigation
LEARNING

HSRL: A Hierarchical Control System Based on Spiking Deep Reinforcement Learning for Robot Navigation

Bo Yang, Shibo Zhou, Chaohui Lin, Rui Yan, De Ma, Gang Pan, Huajin Tang

Year
2025
Citations
3

Abstract

Reinforcement Learning (RL) has shown promise in robotic navigation tasks, yet applying it to real-world environments remains challenging due to dynamic complexities and the need for dynamically feasible actions. We propose a hierarchical control framework based on Spiking Deep Reinforcement Learning (SDRL) for robust robot navigation in real environments. Our approach utilizes a two-layer architecture: a high-level decision layer powered by a Spiking GRU network for handling partially observable environments, and a low-level executive layer employing Continuous Attractor Neural Networks (CANNs) to ensure precise and continuous actions. This hierarchical structure allows real-time decisionmaking that respects the physical constraints of the robot. Experimental results show that our method adapts effectively to new environments without fine-tuning and surpasses existing methods in performance. We also explore the implementation on the Darwin3 chip, paving the way for biologically inspired motion control in future robotic applications.

Keywords

Reinforcement learningComputer scienceArtificial intelligenceRobotRobot controlControl (management)Hierarchical control systemControl systemMobile robotRobot learning

Related papers

Browse all LEARNING papers