避障
计算机科学
运动规划
强化学习
控制理论(社会学)
二次规划
控制(管理)
路径(计算)
控制器(灌溉)
数学优化
人工神经网络
方案(数学)
鲁棒控制
过程(计算)
观察员(物理)
运动控制
核(代数)
国家观察员
一般化
序列二次规划
最优控制
二次方程
人工智能
动态规划
控制系统
约束(计算机辅助设计)
先验与后验
增强学习
控制工程
上下界
国家(计算机科学)
车辆动力学
监督学习
模型预测控制
作者
Zhenyu Xu,Ke Wang,Chaoxu Mu,Tie Qiu
标识
DOI:10.1109/jiot.2025.3614857
摘要
This article presents a safety-critical control framework for navigation in complex environments with numerous obstacles. An online robust path planning scheme is developed by integrating reinforcement learning (RL) with control barrier functions (CBFs). First, a disturbance observer is designed to estimate the unknown disturbance along with a derived upper bound of the estimation error. Then, a nominal controller is designed using RL, where a critic neural network (NN) structure is established by using state-following (StaF) kernel function. Additionally, by employing a state extrapolation technique, the learning process leverages both real-time and simulated experience data. To ensure safety, obstacle avoidance is formulated as a forward invariance problem of safe sets defined by CBFs. Subsequently, the CBF-based safety-critical constraints are integrated into a quadratic programming (QP) framework to modify the nominal controller. Furthermore, these CBFs are incorporated into a composite CBF using smooth approximation, enabling efficient constraint consolidation. Then, an explicit safe control policy is proposed that guarantees collision-free path planning. Finally, the effectiveness of the proposed scheme is demonstrated through numerical simulations, and comparative results show the advantages over the existing methods in motion trajectory.
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