基于多agent的制造系统自动化系统设计

Samyeul Noh, Junhee Park
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引用次数: 4

摘要

提出了一种基于多智能体制造系统的自动化系统设计,通过对多个机器人的系统控制,自动完成给定的复杂任务。为此,本系统设计了环境感知、任务规划和运动规划三个模块配置。环境感知模块利用视觉传感器识别放置在工作空间上的所有物体,并提取它们的唯一ID、大小和姿势。任务规划模块将给定的任务划分为多个原语技能等级,并将每个原语技能与相应的对象信息系统地分配给关联的机器人机械手,使机器人机械手之间不发生碰撞。运动规划模块通过求解机械臂的逆运动学和打开或关闭两个手指来确定机械臂和机械手的运动。提出的系统已经在真实机器人环境中通过一个复杂的任务“钉在洞里”进行了测试和验证,该任务至少需要两个机器人操纵器。
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System Design for Automation in Multi-Agent-Based Manufacturing Systems
This paper proposes a system design for automation in multi-agent-based manufacturing systems to conduct a given complex task automatically by controlling multiple robotic manipulators in a systematic manner. To this end, the proposed system is designed with three-module configurations: environmental perception, task planning, and motion planning. The environmental perception module utilizes a vision sensor to recognize all objects placed on the workspace and extract their unique ID, size, and pose. The task planning module divides a given task into primitive skill levels and distributes each primitive skill to the associated robotic manipulator with the relevant object information in a systematic manner for robotic manipulators not to collide with each other. The motion planning module determines the motion of a robotic arm and a robotic hand by solving inverse kinematics for the robotic arm and by opening or closing two fingers. The proposed system has been tested and verified in real robot environments through a complex task "peg in hole" that requires at least two robotic manipulators.
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