A robot is provided. The robot includes a lower module includes a wheel and a motor provided inside the lower module, and an upper module disposed at an upper portion of the lower module and including a trash can assembly and a display unit. The upper module includes a body part coupled to the upper portion of the lower module and a head part rotatably coupled to an upper portion of the body part. The body part includes a front case forming a front outer appearance of the body part and including the trash can assembly provided inside the front case, and a rear case forming a rear outer appearance of the body part and including the display unit.

An apparatus for de-icing a pathway, the apparatus comprising a frame including a set of wheels, a salt dispenser, a servo attached to the salt dispenser, one or more motors, the motors attached to at least one of the set of wheels, and a microcontroller communicatively coupled to the servo and the one or more motors, wherein the microcontroller instructs the servo to operate the salt dispenser and activates the one or more motors to drive the at least one of the set of wheels.

A system for performing interactions within a physical environment including: a robot base that undergoes movement relative to the environment; a robot arm mounted to the robot base, the robot arm including an end effector mounted thereon; a first tracking system that measures a robot base position; a second tracking system that measures movement of the robot base; and, a control system that uses a robot base position to at least partially control the robot arm to move the end effector along an end effector path, wherein the control system: determines the robot base position at least in part using signals from the first tracking system; and, in the event of failure of the first tracking system: determines a robot base position using signals from the second tracking system; and, controls the robot arm to move the end effector along the end effector path at a reduced end effector speed.

The present disclosure relates to a system for installing a floor finishing material using an autonomous driving robot

According to the present disclosure, there is provided a system for installing a floor finishing material using autonomous driving including: a floor surface cleaning and adhesive application robot that cleans a floor surface and applies adhesive while moving with autonomous driving; a finishing material installation robot that installs the floor finishing material on an upper side of the adhesive surface; a finishing material loading robot that loads the floor finishing material loaded in an installation site, on a pallet; a finishing material transport robot that transports and delivers the loaded floor finishing material to the finishing material installation robot; and a 3D positioning device that sets a position thereof as an origin and recognizes positions of a plurality of active markers installed in a work site.

A multi-shelf storage apparatus for storage of articles, comprising a wheeled base; a frame disposed on the wheeled base; a plurality of vertically-spaced shelves on the frame for providing a storage area for articles, each shelf configured to move vertically. The apparatus includes a lift mechanism disposed on the frame, coupled to the shelves, and configured to cause collapse and extension of the shelves in a vertical direction. The apparatus has an actuator on the frame operable to drive the lift mechanism, and a power interface on the frame and electrically connected to the actuator. The apparatus has a mechanical connection for connecting to a towing device and a first power interface integral to the mechanical connection such that the actuator can receive electrical power from the towing device. Systems comprising one or more of the apparatuses and methods for loading/unloading articles utilizing the apparatuses are also disclosed.

A method for self-diagnosing a data acquisition system for acquiring calibrated images of an area by a controller includes requesting a signal, from a sensor associated with a mobile platform in the area, removing from the signal, background noise associated with the mobile platform, thereby focusing the measurement to a foreground signal, wherein the background noise is removed from the foreground signal via a subspace approximation using singular value, requesting a previous-in-time signal indicative of a previous-in-time measurement of the parameter, wherein previous-in-time background noise is removed from a previous-in-time foreground signal via subspace approximation using singular value decomposition and in response to a change detection indicating a difference between a spectrogram of the background noise and a previous-in-time spectrogram of the previous-in-time background noise exceeding a predetermined threshold at a predetermined frequency, outputting a status signal indicative of a change in operating characteristics of the mobile platform.

An apparatus for automating inventory procedures for items stored on shelves in a closed environment includes a mobile mechanical device having a movable appendage including a camera and additional sensory modalities. The camera and additional sensory modalities are used to position the movable appendage to take camera images of the items on the shelves from many different perspectives. Camera vision and the additional sensory modalities can be used to rotate, lower and raise movable appendage to position the appendage over and along the sides of the items on the shelf. The context of the mobile mechanical device is determined and edge AI computing retrieves AI context specific models based on the context. The AI context specific models may be downloaded from a cloud service. The edge AI computing uses the AI context specific models to identify and count the items on the shelf.

A robot for transporting cargo box, relating to the field of automatic logistics storage, includes a drive unit, a cargo box storing unit and a cargo box delivery unit, wherein the drive unit drives the cargo box storing unit and the cargo box delivery unit to move together; the cargo box storing unit includes one or more cargo box storing spaces; the cargo box delivery unit is configured to deliver the cargo box between the storing space and the shelf.

A method may be provided for controlling a mobile robot. This may include receiving user input including a predetermined service request by the mobile robot, receiving an article to be served, by the mobile robot, searching for a user, analyzing a gesture of the user, and extracting a serving position, by the mobile robot, analyzing an image of the serving position and extracting a distance and height of the serving position, moving the mobile robot to the serving position and lifting the served article to be served, to a height of the serving position, and putting down the article to be served at the serving position by horizontally moving the article to be served to the serving position.

The present invention relates to a system, comprising: a transport device 100 comprising a transport vehicle 110 which can be moved freely on a base area and a handling device 150 provided on the transport vehicle 110, a carrier for goods in transport 200 which can be received by the handling device 150 and includes at least one first alignment element 220, and a receiving apparatus 300 for receiving the carrier for goods in transport 200 which can be set up on the base area or arranged on a machine set up on the base area, wherein the handling device 150 is configured to hold the carrier for goods in transport 200 in such a way that, when the carrier for goods in transport 200 is inserted and/or exchanged on the receiving apparatus 300 by the handling device 150, the carrier for goods in transport 200 is kept movable relative to the handling device 150, and the receiving apparatus 300 includes at least one second alignment element 320 which, when the carrier for goods in transport 200 is inserted and/or exchanged, is configured to interact with the at least one first alignment element 220 of the carrier for goods in transport 200 for aligning the carrier for goods in transport 200 with the receiving apparatus 300.