Implementations of the disclosed subject matter provide a method of moving, using a drive system, a mobile robot within an area. Detecting, using at least one sensor of the mobile robot, at least one of air within the area, a surface within the area, and/or an object within the area. The area may be mapped in three dimensions based on the detecting of at least one of the air, the surface, and the object as the mobile robot moves within the area. Ultraviolet (UV) light may be emitted from a light source of the mobile robot to disinfect at least a portion of the area. A representation of the emission of the UV light may be plotted onto the mapped area to generate an exposure plot, where the representation is of the UV light emitted on at least one of the air, the surface, and the object in the area.

A robot includes an operation control unit that selects a motion of the robot, a drive mechanism that executes a motion selected by the operation control unit, an eye control unit that causes an eye image to be displayed on a monitor installed in the robot, and a recognizing unit that detects a user. The eye control unit causes a pupil region included in the eye image to change in accordance with a relative position of the user and the robot. A configuration may be such that the eye control unit causes the pupil region to change when detecting a sight line direction of the user, or when the user is in a predetermined range.

A robot includes an operation control unit that selects a motion of the robot, a drive mechanism that executes a motion selected by the operation control unit, an eye control unit that causes an eye image to be displayed on a monitor installed in the robot, and a recognizing unit that detects a user. The eye control unit causes a pupil region included in the eye image to change in accordance with a relative position of the user and the robot. A configuration may be such that the eye control unit causes the pupil region to change when detecting a sight line direction of the user, or when the user is in a predetermined range.

A method for 3D printing of a robot element, more particularly a finger for use in robotics. At least one sensor is concomitantly printed by means of multi-material printing during the printing of the robot element. A gripping element produced by a method of this kind includes a number of printed layers of robot element material and a concomitantly printed sensor.

A method for 3D printing of a robot element, more particularly a finger for use in robotics. At least one sensor is concomitantly printed by means of multi-material printing during the printing of the robot element. A gripping element produced by a method of this kind includes a number of printed layers of robot element material and a concomitantly printed sensor.

The robot system includes a robot having a robot body and a robot controller configured to control operation of the robot body, and an unmanned aerial vehicle capable of autonomous flight. The unmanned aerial vehicle acquires at least one of image pick-up data of a work of the robot body and positional information of a work object of the robot body, and transmits at least one of the image pick-up data and the positional information to the robot controller. The robot controller receives at least one of the image pick-up data and the positional information of the work object, and controls the operation of the robot body by using at least one of the image pick-up data and the positional information of the work object.

The robot system includes a robot having a robot body and a robot controller configured to control operation of the robot body, and an unmanned aerial vehicle capable of autonomous flight. The unmanned aerial vehicle acquires at least one of image pick-up data of a work of the robot body and positional information of a work object of the robot body, and transmits at least one of the image pick-up data and the positional information to the robot controller. The robot controller receives at least one of the image pick-up data and the positional information of the work object, and controls the operation of the robot body by using at least one of the image pick-up data and the positional information of the work object.

A robot is equipped with a processor. The processor detects external appearance or audio of a living being, and by controlling the robot, causes the robot to execute an operation in accordance with liking data indicating preferences of the robot regarding external appearance or audio and the detected external appearance or audio of the living being.

A robot is equipped with a processor. The processor detects external appearance or audio of a living being, and by controlling the robot, causes the robot to execute an operation in accordance with liking data indicating preferences of the robot regarding external appearance or audio and the detected external appearance or audio of the living being.

Implementations of the disclosed subject matter provide a method of moving a mobile robot within an area. The movement of the mobile robot and the emission of ultraviolet (UV) light may be stopped when a human and/or animal is determined to be within the area. Using at least one sensor, the method may be determine whether there is at least one of human identification, animal identification, motion, heat, and/or sound within the area for a predetermined period of time. When there is no human identification, animal identification, motion, heat, and/or sound within the predetermined period of time, UV light may be emitted and the drive system may be controlled to move the mobile robot within the area. When there is at least one of human identification, motion, heat, and/or sound within the predetermined period of time, a light source may be controlled to prohibit the emission of UV light.