基于多智能体强化学习的冗余机器人控制

2020 IEEE 16th International Conference on Automation Science and Engineering (CASE) Pub Date : 2020-08-01 DOI:10.1109/CASE48305.2020.9216774

Adolfo Perrusquía, Wen Yu, Xiaoou Li

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引用次数: 7

摘要

机器人在任务空间1中的控制需要运动学逆解和雅可比矩阵。由于冗余机器人的自由度太大，因此不能使用它们。智能学习方法，如神经网络(NN)和强化学习(RL)可以学习它们。然而，神经网络需要大数据，强化学习作为冗余机器人不适合多链路机器人。在本文中，我们提出了一种完全合作的多智能体强化学习(MARL)来解决上述问题。将机器人的每个关节视为一个agent。虽然学习空间的维数很大，但完全合作MARL采用了运动学习，避免了大学习空间中的函数逼近器。实验结果表明，与基于雅可比矩阵的方法和神经网络等经典方法相比，我们的MARL具有更好的性能。任务空间(或笛卡尔空间)是由机器人末端执行器的位置和方向来定义的。关节空间由机器人各关节的角位移来定义。

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Redundant Robot Control Using Multi Agent Reinforcement Learning

Robot control in task-space1 needs the inverse kinematics and Jacobian matrix. They are not available for redundant robots, because there are so many degrees-of-freedom (DOF). Intelligent learning methods, such as neural networks (NN) and reinforcement learning (RL) can learn them. However, NN needs big data and RL is not suitable for multilink robots as the redundant robots. In this paper, we propose a full cooperative multi-agent reinforcement learning (MARL) to solve the above problems. Each joint of the robot is regarded as one agent. Although the dimension of the learning space is very large, the full cooperative MARL uses the kinematic learning and avoids the function approximators in large learning space. The experimental results show that our MARL is much more better compared with the classic methods such as, Jacobian-based methods and neural networks.1Task-space (or Cartesian space) is defined by the position and orientation of the end effector of a robot. Joint-space is defined by angular displacements of each joint of a robot.

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2020 IEEE 16th International Conference on Automation Science and Engineering (CASE)

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