移动机器人
运动规划
计算机科学
动态决策
机器人
路径(计算)
实时计算
控制工程
模拟
分布式计算
人机交互
人工智能
工程类
计算机网络
作者
Xingshuo Hai,Ziming Zhu,Yuan Liu,Andy W. H. Khong,Changyun Wen
标识
DOI:10.1109/tie.2025.3561859
摘要
We propose a hierarchical dual-layer decision-making framework to address challenges associated with autonomous mobile robot (AMR) path planning in complex and dynamic campus environments. The upper-layer global planning is formulated as a multiobjective optimization model, where a multiobjective sheep flock migrate optimization algorithm (MOSFMO) is proposed to generate Pareto front solutions by optimizing path length and path safety jointly. In the lower layer, the autonomy of the AMR is enhanced through deep reinforcement learning (DRL) training with a composite reward scheme designed to enable resilient real-time decisions for avoiding unexpected pedestrians while achieving global objectives. Effective coordination is achieved through the availability of multiple candidate paths and a time-oriented deadlock detection mechanism, enabling uninterrupted task execution despite encountered blockage challenges. The proposed methods are validated through numerical simulations and real-world experiments, achieving on-time arrival rates of up to 99% in dynamic environments.
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