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.

The objective of the present invention is to allow a user to recognize, at a glance, the degree to which deterioration is occurring to a specific torque sensor from among torque sensors provided for an articulated arm of a robot. In the control device for a robot provided with sensors each of which detects an external force torque about a joint, the objective is achieved by providing a display device which displays, together with 3D graphics of a robot body, a warning icon in color at a mounted location of a deteriorated torque sensor, and changes the color according to the degree of deterioration.

The objective of the present invention is to allow a user to recognize, at a glance, the degree to which deterioration is occurring to a specific torque sensor from among torque sensors provided for an articulated arm of a robot. In the control device for a robot provided with sensors each of which detects an external force torque about a joint, the objective is achieved by providing a display device which displays, together with 3D graphics of a robot body, a warning icon in color at a mounted location of a deteriorated torque sensor, and changes the color according to the degree of deterioration.

Methods, apparatus, computing devices, computing entities, and/or the like associated with a robotic sortation system are provided. An example method may include receiving imaging data associated with a first item at a first sorting location of a material handling system, determining a sorting destination for the first item based at least in part on the imaging data, determining a plurality of first-tier robotic devices and a plurality of second-tier robotic devices based at least in part on the first sorting location and the sorting destination, and generating a first sortation scheme for the first item.

Methods, apparatus, computing devices, computing entities, and/or the like associated with a robotic sortation system are provided. An example method may include receiving imaging data associated with a first item at a first sorting location of a material handling system, determining a sorting destination for the first item based at least in part on the imaging data, determining a plurality of first-tier robotic devices and a plurality of second-tier robotic devices based at least in part on the first sorting location and the sorting destination, and generating a first sortation scheme for the first item.

A cleaning robot is provided. The cleaning robot includes a motion device configured to move the cleaning robot in an environment, and an exterior housing. The cleaning robot also includes a motion sensor configured to obtain parameters relating to a motion of the cleaning robot, and a storage device configured to store data including at least one of the one or more images or the one or more motion parameters. The cleaning robot also includes a camera configured to capture one or more images of the environment. The camera is disposed internal to a slant surface located at a front end of the exterior housing and is pivotable relative to the slant surface. The slant surface inclines upwardly with respect to a forward moving direction. The camera and the slant surface face substantially a same direction. A direction of the camera and the forward moving direction form an acute angle.

A cleaning robot is provided. The cleaning robot includes a motion device configured to move the cleaning robot in an environment, and an exterior housing. The cleaning robot also includes a motion sensor configured to obtain parameters relating to a motion of the cleaning robot, and a storage device configured to store data including at least one of the one or more images or the one or more motion parameters. The cleaning robot also includes a camera configured to capture one or more images of the environment. The camera is disposed internal to a slant surface located at a front end of the exterior housing and is pivotable relative to the slant surface. The slant surface inclines upwardly with respect to a forward moving direction. The camera and the slant surface face substantially a same direction. A direction of the camera and the forward moving direction form an acute angle.

A first robot may include: a communication circuit configured to transmit and receive a signal; a sensor configured to detect a surrounding environment; a driving device configured to implement movement of the first robot; and a processor configured to control the first robot. The processor may determine a second voice recognition range of a second robot on the basis of a confirmation signal transmitted from the second robot. When a user is positioned outside the determined second voice recognition range, the processor may control the driving device so that the first robot follows the user.

A task table for use in a robotic system comprising a robot mounted on a carriage configured to move the robot along a path is disclosed. The task table includes a substantially horizontal table surface, and one or more mounting arms to which the table surface is affixed at a first distal end and comprising, at a second distal end opposite the first distal end, one or more mounting structures, the one or more mounting arms having a length that allows the table surface to be mounted to the robot or the carriage at a distance from a base of the robot that enables the robot to reach a plurality of locations on the table surface each with a desired pose.

A task table for use in a robotic system comprising a robot mounted on a carriage configured to move the robot along a path is disclosed. The task table includes a substantially horizontal table surface, and one or more mounting arms to which the table surface is affixed at a first distal end and comprising, at a second distal end opposite the first distal end, one or more mounting structures, the one or more mounting arms having a length that allows the table surface to be mounted to the robot or the carriage at a distance from a base of the robot that enables the robot to reach a plurality of locations on the table surface each with a desired pose.