The present specification relates to a mobile robot and a control method therefore, in which the mobile robot generates virtual floor surface information about a travelling environment by accumulating, for a certain time, the results of sensing via a camera sensor to improve the accuracy of obstacle detection using the camera sensor, detects whether or not there is an obstacle in the travelling environment, on the basis of the floor surface information, and controls travel according to the result of the detection.

A cleaning device having an electrical interface for interacting with an electrical counter-interface and a base station to charge the cleaning device. The cleaning device being configured to move autonomously in a processing environment, to carry out cleaning tasks, and to move into a service position with a base station. The cleaning device determines a range of service functions offered by a base station. When the cleaning device is in the service position, at least one measured value of a voltage or measured value of a voltage curve at the electrical interface provides a means of identification. This identification is used to determine the range of service functions at the base station or to identify a communication interface for use in determining the range of service functions by a data processing device. A cleaning system, a procedure, and a computer program product associated with the cleaning device is provided.

The present disclosure relates to an XR device and a method for controlling the same, and more particularly, is applicable to a 5G communication technology field, a robot technology field, an autonomous technology field and an artificial intelligence (AI) technology field. The method for controlling an XR device comprises executing an augmented reality (AR) assistant application in the XR device by a user, displaying a real space, which includes a first real object, on a screen of the XR device, detecting a state of the first real object, displaying at least one virtual object for identifying the state of the first real object on the real space of the screen by overlapping the at least one virtual object on the real space, and controlling the state of the first real object by using one or more second real objects of the real space.

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.

A UV based surface disinfection system that consists of the UV light source, a robot arm, and an omni directional mobile base. The mobile robot can be programmed autonomously and be able to bring the UV light source to the centimeters away from surfaces to achieve effective and efficient surface disinfection. The mobile robot can navigate autonomously in a complicated environment to perform disinfection operation in a large area.

A robotic cleaner may include a body having a top surface, a navigation sensor extending from the top surface of the body, a protective cover defining a sensor cavity, the navigation sensor being at least partially received within the sensor cavity, and a cover liquid diverter extending from an upper portion of the protective cover, the cover liquid diverter being flared in a direction of the body.

An autonomous coverage robot includes a cleaning assembly having forward roller and rearward rollers counter-rotating with respect to each other. The rollers are arranged to substantially maintain a cross sectional area between the two rollers yet permitting collapsing therebetween as large debris is passed. Each roller includes a resilient elastomer outer tube and a partially air-occupied inner resilient core configured to bias the outer tube to rebound. The core includes a hub and resilient spokes extending between the inner surface of the outer tube and the hub. The spokes suspend the outer tube to float about the hub and transfer torque from the hub to the outer tube while allowing the outer tube to momentarily deform or move offset from the hub during impact with debris larger than the cross sectional area between the two rollers.

Systems and methods disclosed herein include a robotic arm positioned outside of the vehicle. The robotic arm may include an end effector configured as a cleaning implement for cleaning a surface in the interior of the vehicle. The system may include a first camera configured to determine a position of the vehicle with respect to a reference point. The system may include a second camera configured to scan the interior of the vehicle. The second system may include a first controller configured to create and/or modify a tool path to execute a cleaning operation, based on the scan, and to send instructions to the robotic arm to execute the cleaning operation in accordance with the created and/or modified tool path.

A machine for producing sanitary articles includes a plurality of processing stations including automated apparatus for forming sanitary articles which advance along a machine direction. The machine includes a multi-axis industrial robot arranged to automatically clean and/or inspect the automated apparatus of the processing stations. The machine has a positive impact on sustainability.

Provided are a self-movement robot, a map invoking method and a combined robot. The self-movement robot includes a robot body and a control center disposed on the body, the robot body comprising a distance sensor, the distance sensor collects two-dimensional map information of a working surface on which the self-movement robot is located, and collects spatial height information above the working surface on which the self-movement robot is located; and while obtaining the two-dimensional map information of the working surface, the control center overlays the spatial height information to the two-dimensional map information and obtains three-dimensional map information of a working region.