Hierarchical Human-robot Cooperative Control Based on GPR and Deep Reinforcement Learning
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摘要: 提出了一种基于高斯过程回归与深度强化学习的分层人机协作控制方法, 并以人机协作控制球杆系统为例检验该方法的高效性. 主要贡献是: 1)在模型未知的情况下, 采用深度强化学习算法设计了一种有效的非线性次优控制策略, 并将其作为顶层期望控制策略以引导分层人机协作控制过程, 解决了传统控制方法无法直接应用于模型未知人机协作场景的问题; 2)针对分层人机协作过程中人未知和随机控制策略带来的不利影响, 采用高斯过程回归拟合人体控制策略以建立机器人对人控制行为的认知模型, 在减弱该不利影响的同时提升机器人在协作过程中的主动性, 从而进一步提升协作效率; 3)利用所得认知模型和期望控制策略设计机器人末端速度的控制律, 并通过实验对比验证了所提方法的有效性.Abstract: In this paper, a hierarchical human-robot collaboration control problem is investigated by Gaussian process regression and deep reinforcement learning approaches, and a ball and beam system controlled jointly by human and robot is used to verify the proposed method. The main contributions are as follows: 1) To deal with the problem that the classical control method can not be directly used in the human-robot collaboration scenario without a known model, a deep reinforcement learning algorithm is adopted to design an effective nonlinear suboptimal policy without the system model, and this suboptimal policy is considered as the expected control policy to guide the Human-robot collaboration process; 2) To weaken the negative influences caused by the unknown and random human-control strategies, the Gaussian process regression method is used to fit the human-control strategies and build the cognitive model of robot for human control behaviors, which can improve the efficiency of collaboration by enhancing the initiative of the robot through the Human-robot collaboration process; 3) A controller for the end-effector velocity is designed based on the cognitive model and the expected control policy, and the effectiveness of the proposed method is verified by experimental comparison.
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图 7 志愿者控制过程中产生数据的滤波结果图
Fig. 7 Filtering results of the data generated by volunteers' control process
图 8 志愿者控制过程中产生的部分轨迹图
Fig. 8 Some trajectories generated by the volunteers' control process
图 9 人体控制策略预测模型拟合结果图
Fig. 9 The fitting results of human-control policy prediction model
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