Described herein are devices, systems and methods related to automated waste management. Aspects of the present disclosure include devices, systems, and methods comprising an autonomous waste bin. The autonomous waste bin may include a first and second driving wheels connected to a base of a hollow receptacle. The autonomous waste bin may include a first and second driving motor connected to the first and second driving wheels respectively, the first and second driving motor configured to provide a driving force to the first and second driving wheels. The autonomous waste bin may include at least one controller in communication with the first and second driving motors, the at least one controller configured to control the movement of the autonomous waste bin, via the first and second driving wheels.

A waste collection system includes a movable waste box to automatically travel by using a sensor group including cameras, a sonar, a millimeter wave radar, and a LiDAR, and a supervision apparatus to manage the movable waste box. The movable waste box autonomously moves by following path information indicating a path. The movable waste box includes a waste box to accept waste a person who is present partway on a path has. The supervision apparatus includes a path information generating unit to generate the path information and to transmit the path information to the movable waste box.

To provide a highly reliable, cost-effective traveling collector that can determine the positions of fallen objects, such as balls, on the ground using a simple method, or determine the correct positions of fallen objects, such as balls, on the ground only by improving software and without the need for significant changes to hardware. The traveling collector includes a count sensor as a sensor for detecting the position of each collected ball at a position detected by a satellite positioning system, for example. A controller determines a position, which is obtained by reflecting, based on the positional information on the ball collector at a time point when the ball was counted by touching the count sensor, the movement distance of the ball collector from the time each ball was picked up from the ground by a ball collection wheel till the ball was counted by touching the count sensor in a direction opposite to the traveling direction of the ball collector at that time, as the actual position where each ball was picked up.

Provided is a highly reliable, cost-effective scattered object collection system that can efficiently collect scattered objects by reducing unnecessary traveling of a traveling collector. The scattered object collection system includes a traveling collector that performs a collecting operation by picking up balls B while traveling in a work area W, sets a virtual work area Z (or a virtual priority work area Za) to an area in the work area W where balls are relatively densely present and in the vicinity of the storage space of balls, and allows the traveling collector to perform a collecting operation in the virtual work area Z (or the virtual priority work area Za) with higher priority than the other areas.

A method executed by a control device includes: acquiring odor information indicating an odor intensity of each of a plurality of garbage collection sites, the odor intensity being detected by an odor sensor; determining an order in which garbage is collected from each of the garbage collection sites based on the odor information; and causing a garbage collection device to sequentially collect the garbage from each of the garbage collection sites according to the order.

A control device provided in a vehicle allows reception of a load carried by a drone, determines a position of a user who has ordered the load, and causes a ceiling module to move to the determined position while the vehicle is traveling toward a destination.

A method and apparatus are disclosed for a clutter tidying robot utilizing floor segmentation for its mapping and navigation system, whereby a perception module and navigation module transform lidar and image data from lidar sensors and cameras of a robot sensing system using segmentation and pseudo-laserscan or point cloud transformations to generate global and local maps. The robot pose and maps are transmitted to a robot brain that directs an action module to produce robot action commands controlling the operation of a clutter tidying robot using the pose and map data. In this manner multi-stage planning and sophisticated obstacle avoidance techniques may be incorporated into autonomous robot operations.

The invention proposes a method for the automated discharge of loose transport material from a container, transported by means of a self-driving vehicle, into a collection container, where the unloading takes place in a spatially defined unloading cone within an unloading station. Furthermore, an unloading station for automated discharge according to the method is proposed.

Described herein are devices, systems and methods related to automated waste management. Aspects of the present disclosure include devices, systems, and methods comprising an autonomous waste bin. The autonomous waste bin may include a first and second driving wheels connected to a base of a hollow receptacle. The autonomous waste bin may include a first and second driving motor connected to the first and second driving wheels respectively, the first and second driving motor configured to provide a driving force to the first and second driving wheels. The autonomous waste bin may include at least one controller in communication with the first and second driving motors, the at least one controller configured to control the movement of the autonomous waste bin, via the first and second driving wheels.

A remote control system for operating vehicles includes a first vehicle, a second vehicle including one or more controllable elements, and one or more processing circuits. The one or more processing circuits are configured to acquire, from the first vehicle, input data corresponding to the second vehicle, generate, based on the input data, control signals for the one or more controllable elements of the second vehicle, and provide the control signals to the one or more controllable elements of the second vehicle to operate the one or more controllable elements according to the input data.