A robot for performing an expression by a non-verbal reaction, includes a body including a lower part provided so as to be capable of panning and tilting with respect to a support point coupled to a placement surface; a pair of arms provided to side parts of the body so as to be capable of moving up and down; and a head provided to an upper part of the body so as to be capable of panning and tilting, wherein the non-verbal reaction includes a combination of the tilting and the panning of the body with respect to the support point and movement of the pair of arms or the head or any combination thereof.

A moving robot includes: a connection unit configured to detachably mount one of a plurality of task modules and electrically connectable to the one of a plurality of task modules when the one of a plurality of task modules is mounted; a frame unit supporting the connection unit and configured to be movable; a drive unit configured to move the frame unit; and a control unit to which a plurality of different driving modes corresponding to at least some of the plurality of task modules is input in advance and which controls the drive unit so that the moving robot is autonomously driven based on the plurality of driving modes.

In one aspect the invention relates to a sorting system (SortS) for sorting processed parts (P) from a workpiece (W), which has been processed by a laser processing machine (L), in particular a laser sheet processing machine, comprising:—A working table (WT) for supporting the workpiece (W) with the processed parts (P), which have been processed by the processing machine (L),—A fleet of interacting legged mobile robots (MR) for sorting the processed parts (P) in a collaborative manner to a target destination.

A substrate handling system including an infeed system for feeding stacked substrates and including a processing machine for processing stacked substrates, and in particular a printing press for printing stacked substrates. A robot cell is provided between the infeed system and the processing machine. The robot cell comprises one or two gripper systems, each for handling a plurality of substrates. The robot cell is configured in such a way, that selectively differently stacked substrates, which are feedable by the infeed system, can be handled.

A robot control system includes a robot that screw-fastens a sub-component placed in a main-component to the main-component, a robot control unit that controls the robot, and a display as an output unit through which the robot control unit outputs a message to an operator. The robot control unit determines whether or not the robot can screw-fasten the sub-component to the main-component by itself. Then, when the robot control unit determines that the robot cannot screw-fasten the sub-component to the main-component by itself, the robot control unit outputs a cooperation message to an operator through the display.

A box handling system is disclosed for use in an object processing system. The box handling system includes a box tray including a recessed area for receiving a box, and the recessed area includes a plurality of floor and edge portions for receiving the box that contains objects to be processed.

A robotic device includes an end effector device, a first sensor, and a controller. The end effector device includes two fingers for gripping a workpiece. The first sensor detects a pressure distribution on a gripping position on the workpiece by the two fingers. The controller performs, based on a temporal variation in the pressure distribution when the workpiece is lifted, posture control including rotation of the end effector device.

One embodiment of a method for controlling a robot includes receiving sensor data associated with an environment that includes an object; applying a machine learning model to a portion of the sensor data associated with the object and one or more trajectories of motion of the robot to determine one or more path lengths of the one or more trajectories; generating a new trajectory of motion of the robot based on the one or more trajectories and the one or more path lengths; and causing the robot to perform one or more movements based on the new trajectory.

The present disclosure discloses a method and apparatus for motion planning of a robot, a method and apparatus for path planning of a robot, and a method and apparatus for grasping of a robot. The method includes: when the robot operates on an object to be operated, performing, in combination with a space model of a real scene where the object is located, collision detection on the object and a collision subject in the space model; and determining a motion planning scheme for the robot corresponding to a result of the collision detection based on collision sensitivity of the object and collision sensitivity of the collision subject, the motion planning scheme being formed by the robot operating on the object.

A robotic assembly for servicing equipment, the robotic assembly including an area configured to receive components associated with a workscope of the equipment; an environmental capture device configured to capture information associated with an environment in which the robotic assembly is disposed; and one or more computing devices configured to: locate the equipment in the environment; autonomously navigate the robotic assembly through the environment to the equipment; and autonomously adjust a position of the robotic assembly in response to the workscope.