An automated storage and retrieval system includes a storage grid for storage of storage containers and a delivery system for transport of said storage containers between a delivery port of the storage grid and an access point of the delivery system. The access point is adapted for handling of items held in the storage containers by a robotic operator or human operator. The delivery system includes a delivery rail system including at least a first set of parallel rails arranged in a horizontal plane (P1) and extending in a first direction (X), and at least a second set of parallel rails arranged in the horizontal plane (P1) and extending in a second direction (Y) which is orthogonal to the first direction (X), the first and second sets of rails together defining a delivery grid of delivery grid cells, the access point, and a remotely operated delivery vehicle comprising a motorized vehicle body and a container carrier provided above the motorized vehicle body for carrying a storage container of the storage containers. The delivery vehicle is moveable on the delivery grid of the delivery rail system. The delivery grid provides one or more delivery grid cells for the remotely operated delivery vehicle at the access point as well as a plurality of delivery grid cells adjacent the one or more delivery grid cells of the access point, such that there is more than one path to and/or from the access point for the remotely operated delivery vehicle via the plurality of delivery grid cells. The remotely operated delivery vehicle is arranged to transport the storage container from the delivery port of the storage grid across the delivery grid to the access point and return the storage container to the delivery port for storage within the storage grid. The access point is provided in a container accessing station, said station being arranged for separating the robotic or human operator from the delivery rail system and the remotely operated delivery vehicle. The container accessing station comprises a cabinet comprising walls and a top cover supported thereon, wherein the items held in the storage container carried by a remotely operated delivery vehicle at the access point is reachable through an opening in the top cover.

The present disclosure relates to the technical field of intelligent home, and provides a cleaning robot escape method, a cleaning robot escape device, a computer-readable storage medium, and an electronic apparatus. The cleaning robot escape method includes: detecting, when the cleaning robot encounters an obstacle while cleaning along an edge of a first surface medium region and turns around, a second surface medium region in response to a surface medium change signal from the surface medium sensor, and determining whether a path allowing the cleaning robot to bypass the second surface medium region exists; controlling, if the path exists, the cleaning robot to travel along the path to avoid the second surface medium region; and ignoring, if the path does not exist, the surface medium change signal from the surface medium sensor, and controlling the cleaning robot to turn around and return along an original path.

An autonomous floor cleaner includes multiple occupiable space sensors for position and/or proximity sensing. Data from the occupiable space sensors can be used determine areas of occupiable space in proximity to the autonomous floor cleaner. Methods for exiting a trapped condition, obstacle avoidance, and path planning are disclosed.

An autonomous floor cleaner includes multiple occupiable space sensors for position and/or proximity sensing. Data from the occupiable space sensors can be used determine areas of occupiable space in proximity to the autonomous floor cleaner. Methods for exiting a trapped condition, obstacle avoidance, and path planning are disclosed.

A cleaning method for an automatic cleaning device, a cleaning apparatus for the automatic cleaning device, a computer-readable storage medium, and an electronic device are provided. The cleaning method includes: after the automatic cleaning device enters a dual-region cleaning mode, determining whether a second surface medium region exists according to a stored map in the automatic cleaning device; in response to that the second surface medium region exists, cleaning the second surface medium region; after cleaning of the second surface medium region is completed, marking the second surface medium region as a cleaned region, determining whether a next second surface medium region exists, and cleaning the next second surface medium region in response to that the next second surface medium region exists, until cleaning of all second surface medium regions is completed; and controlling the automatic cleaning device to clean the first surface medium region.

An escaping method of a cleaning robot includes: when the cleaning robot encounters an obstacle and turns around while performing cleaning along an edge of a first surface medium area, in response to a surface medium change signal from the surface medium sensor indicates that a second surface medium area is detected, searching an established room map to determine whether the second surface medium area exists in the room map; if the second surface medium area exists, determining whether a route bypassing the second surface medium area exists based on the room map and a boundary of the second surface medium area in the room map; if the route exists, controlling the cleaning robot to travel along the route to bypass the second surface medium area; and if the route does not exist, controlling the cleaning robot to return along a cleaned route to bypass the second surface medium area.

An escaping method of a cleaning robot includes: when the cleaning robot encounters an obstacle and turns around while performing cleaning along an edge of a first surface medium area, in response to a surface medium change signal from the surface medium sensor indicates that a second surface medium area is detected, searching an established room map to determine whether the second surface medium area exists in the room map; if the second surface medium area exists, determining whether a route bypassing the second surface medium area exists based on the room map and a boundary of the second surface medium area in the room map; if the route exists, controlling the cleaning robot to travel along the route to bypass the second surface medium area; and if the route does not exist, controlling the cleaning robot to return along a cleaned route to bypass the second surface medium area.

An automatic cleaning device control method, an automatic cleaning device control apparatus, a computer-readable storage medium and an electronic device are provided. The method includes: acquiring first data based on current state data of a walking wheel of the automatic cleaning device and second data based on current state data of a machine body of the automatic cleaning device when the automatic cleaning device performs cleaning; determining, based on the first data and the second data, whether the automatic cleaning device is trapped or not and controlling the automatic cleaning device to enter an accelerated-escape mode in response to that the automatic cleaning device is trapped.

This application provides an obstacle avoidance method and apparatus, an electronic device, and a storage medium. The obstacle avoidance method is applicable to a robot. The robot is configured to move along a track in a rack area, and the method includes: detecting whether a suspected obstacle exists in a traveling direction, where the suspected obstacle protrudes beyond an edge of a rack; determining a relative position relationship between the suspected obstacle and a target position that the robot is required to reach along a current traveling direction when the suspected obstacle exists in the traveling direction; determining that the suspected obstacle is an obstacle when the suspected obstacle is located between a current position of the robot and the target position; and replanning a traveling route to avoid the obstacle.

A travel route creation system which creates a travel route for a personal mobility vehicle, the system including a controller configured to create the travel route in which an entering angle to a bump or a slope is set within an angle range of 45? and more based on map data indicating the bump or the slope which the personal mobility vehicle can travel over, when creating the travel route for the personal mobility vehicle to pass the bump or the slope.