Real-time remote manipulation and monitoring architecture of an industry robot

Remote control and monitoring are very necessary in decentralized manufacturing environments. This is evidenced by todaypsilas distributed shop floors where agility and responsiveness are required to maintain high productivity and flexibility. However, there exists a lack of an effective system architecture that integrates remote condition monitoring and control of automated equipment; that give much consideration about the Internet data transfer time delay. This paper presented an Internet-based and sensor-driven architecture, which can guarantee the non-distortion-transfer of control information and reduce the action time difference between local simulated virtual robot and remote real robot, couple the remote monitoring and control together. For demonstrate and validate the architectural design, a 3 DOF industry robot remote operation and monitoring system has been developed. Experimental results are encouraging and demonstrate a promising application in advanced intelligent manufacturing environment.

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