A robotic arm system comprising an artificial intelligence (AI) processor system, a transceiver electrically coupled to the AI processor system, and a robotic arm having an optical data communication network that communicates with the transceiver. The robotic arm further comprises a transmitter, a plurality of sensors electrically coupled to the transmitter, a receiver, and a plurality of motion actuators electrically coupled to the receiver. The optical data communication network comprises gigabit plastic optical fiber (GbPOF) having a graded-index core made of a transparent carbon-hydrogen bond-free perfluorinated polymer with dopant. In one embodiment, one GbPOF optically couples the transmitter to the transceiver and another GbPOF optically couples the transceiver to the receiver. The flexible high-data-rate GbPOF enables robotic arm control using artificial intelligence.

A multi-axis servo control system includes a plurality of motors and a plurality of drive control apparatuses. The drive control apparatuses are connected to each other through an external field bus. Each drive control apparatus includes a control unit and a plurality of drive units. The drive units are connected to the control unit in series by a plurality of local buses to form a series-connected communication loop of sequentially transmitting data. Each drive unit controls at least one of the motors. The control unit receives multi-axis position commands through the external field bus, and the drive units correspondingly receive multi-axis commands through the local buses so as to control the motors in a decentralization manner.

A robot control system according to the present invention includes a robot control device for controlling a robot, and a control CPU detachably provided on the robot control device, for generating an operation command to operate the robot. The robot control device includes a network controller for communicating with the outside of the robot control device, a servo controller for controlling the robot, and a connector for connecting the control CPU to the network controller.

A robotic arm system comprising an artificial intelligence (AI) processor system, a transceiver electrically coupled to the AI processor system, and a robotic arm having an optical data communication network that communicates with the transceiver. The robotic arm further comprises a transmitter, a plurality of sensors electrically coupled to the transmitter, a receiver, and a plurality of motion actuators electrically coupled to the receiver. The optical data communication network comprises gigabit plastic optical fiber (GbPOF) having a graded-index core made of a transparent carbon-hydrogen bond-free perfluorinated polymer with dopant. In one embodiment, one GbPOF optically couples the transmitter to the transceiver and another GbPOF optically couples the transceiver to the receiver. The flexible high-data-rate GbPOF enables robotic arm control using artificial intelligence.

A robot includes a first control device; and one or more second control devices to be controlled by the first control device. The second control device controls a control target controlled by the second control device at a predetermined cycle. The predetermined cycle is determined based on first information received by the second control device from the first control device at a first time point and second information received by the second control device from the first control device at a second time point.

A robot apparatus capable of performing a stable wireless communication is provided. The robot apparatus includes a robot arm including a link, a first control device disposed in the robot arm, a second control device, and a wireless communication unit configured to enable the first control device and the second control device to communicate with each other wirelessly. The wireless communication unit is disposed in the link.

A robot control system according to the present invention includes a robot control device for controlling a robot, and a control CPU detachably provided on the robot control device, for generating an operation command to operate the robot. The robot control device includes a network controller for communicating with the outside of the robot control device, a servo controller for controlling the robot, and a connector for connecting the control CPU to the network controller.

The present disclosure discloses a management method and system for wireless networking of units inside a robot. The system includes a control unit and a plurality of tributary units, wherein each tributary unit has a wireless transceiver module, and the units are in wireless communication with each other. With the management method and system for wireless networking of units inside a robot according to the present disclosure, by virtue of the short-range and low-power consumption wireless communication technology, networking is implemented for the units inside the robot to take the place of the communication manner using limited cables, electrical faults caused by wearing and bending of the cables for a long time are removed, safety and reliability of the robot are improved.

A robot includes a first control device; and one or more second control devices to be controlled by the first control device. The second control device controls a control target controlled by the second control device at a predetermined cycle. The predetermined cycle is determined based on first information received by the second control device from the first control device at a first time point and second information received by the second control device from the first control device at a second time point.

A multi-axis servo control system includes a plurality of motors and a plurality of drive control apparatuses. The drive control apparatuses are connected to each other through an external field bus. Each drive control apparatus includes a control unit and a plurality of drive units. The drive units are connected to the control unit in series by a plurality of local buses to form a series-connected communication loop of sequentially transmitting data. Each drive unit controls at least one of the motors. The control unit receives multi-axis position commands through the external field bus, and the drive units correspondingly receive multi-axis commands through the local buses so as to control the motors in a decentralization manner.