A task execution method and apparatus for robots capable of freely constructing a network, and a storage medium are provided. The method includes: partitioning, by a server, an entire region of a warehouse to obtain local region(s) corresponding to the partitioned warehouse (S10); receiving capability feature information reported by each robot moving freely within a current warehouse range after the robot comes online (S20); determining, according to the capability feature information reported by the robot, a local center robot, and assigning corresponding to-be-executed task(s) to the local region obtained via the partitioning, such that robot(s) freely constructing a local network execute the to-be-executed task(s) (S30); and after the robot(s) have completed the to-be-executed task(s), receiving task completion information reported by a robot, and releasing the robot to be a free moving robot (S40).

In a robot control system, a storage unit stores a plurality of programs corresponding to tasks for a robot to perform. A reception unit receives selections made by a user, which designate a task for the robot to perform and attribute information related to a program causing the robot to perform the task among the plurality of programs. An acquisition unit acquires the program for performing the task among the plurality of programs from the storage unit based on the task and the attribute information. A robot control unit controls the robot in accordance with the acquired program.

An industrial robot including a manipulator and a robot control unit are disclosed, wherein the manipulator includes a plurality of joints that are moved under the control of the control unit, and the control unit includes a storage medium including program code for controlling the motions of the robot when executed by the control unit. The control unit is configured to automatically select which part of the program code to be executed next based on the position of the robot. A method for controlling the robot is also disclosed.

An industrial robot including a manipulator and a robot control unit are disclosed, wherein the manipulator includes a plurality of joints that are moved under the control of the control unit, and the control unit includes a storage medium including program code for controlling the motions of the robot when executed by the control unit. The control unit is configured to automatically select which part of the program code to be executed next based on the position of the robot. A method for controlling the robot is also disclosed.

An operation monitoring server includes a storage apparatus configured to store instructions, and a processor configured to operate based on the instructions. The processor is configured to acquire state information on at least one of a monitoring target device or a base location in which the monitoring target device is placed. The processor is configured to select, based on the acquired state information, one of a plurality of service request processing apparatus each having a function of processing a service request received from the monitoring target device.

A method for identifying a manipulator by means of a portable terminal device, wherein the portable terminal device comprises a 3D camera. The method operates to detect a three-dimensional image of at least one part of the manipulator to be identified by means of the 3D camera of the portable terminal device. An actual status of the manipulator is determined based on the three-dimensional image detected. The 3D camera is a plenoptic camera, and the detected three-dimensional image comprises a four-dimensional light field of at least one part of the manipulator to be identified.

An operation monitoring server includes a storage apparatus configured to store instructions, and a processor configured to operate based on the instructions. The processor is configured to acquire state information on at least one of a monitoring target device or a base location in which the monitoring target device is placed. The processor is configured to select, based on the acquired state information, one of a plurality of service request processing apparatus each having a function of processing a service request received from the monitoring target device.

A task execution method and apparatus for robots capable of freely constructing a network, and a storage medium are provided. The method includes: partitioning, by a server, an entire region of a warehouse to obtain local region(s) corresponding to the partitioned warehouse (S10); receiving capability feature information reported by each robot moving freely within a current warehouse range after the robot comes online (S20); determining, according to the capability feature information reported by the robot, a local center robot, and assigning corresponding to-be-executed task(s) to the local region obtained via the partitioning, such that robot(s) freely constructing a local network execute the to-be-executed task(s) (S30); and after the robot(s) have completed the to-be-executed task(s), receiving task completion information reported by a robot, and releasing the robot to be a free moving robot (S40).