Disclosed herein is a method and apparatus for deploying a self-moving device, an electronic device, and a non-transitory storage medium. The method includes acquiring position information of a target object in each region; determining an activity trajectory of the target object in each region according to the position information; determining a deployment position of the self-moving device in each region according to the activity trajectory; and controlling the self-moving device to move to the deployment position.

A method is provided of real-time controlling a remote device to perform a task, the method comprising steps of: for controlling the remote device to perform a task, obtaining graphical data, such as image frames forming a video, of surroundings of the remote device, such as an area of farmland or beach, sending the graphical data to a remote operation device, obtaining user input data from an operator, which user input data is indicative of a location of interest in the graphical data, generating a control signal for controlling the remote device to perform a task based on the user input data, and using the control signal for controlling the remote device to perform the task at the location of interest. The user input data is further used as training data for training a machine learning algorithm, which algorithm is arranged for generating at least part of a control signal for controlling the remote device; and/or providing a suggested location of interest to the operator.

A robot for waste disposal, the robot being configured to be secured to a garbage container. The robot includes a propulsion system, a control unit, a navigation system, and at least one power source. The control unit is configured to: store a scheduler event in the memory, the scheduler event including information pertaining to a day of the week and a time of the day; store a navigation instruction in the memory, the navigation instruction including at least a first route that begins at a first location and ends at a trash pickup location; and activate the propulsion system based on information provided by the navigation system to propel the garbage container along the first route of the navigation instruction such that the garbage container is propelled from the first location to the trash pickup location when the scheduler event occurs.

A work management system includes: a working robot configured to perform work while autonomously traveling on a field; a management facility configured to manage the field and balls; and a management device configured to know a management situation of the balls. A work schedule of the working robot is adjusted depending on a ball management situation known by the management device.

The present invention relates to a system for smart agriculture biochar production, yield prediction, and measurement. The system utilizes real time remote sensing of the local environment, weather and related conditions, and data analysis on spatial and spectral imagery data captured from satellite sensors, aerial sensors, and agricultural drones. The system performs a field mapping of a target field having a biomass and obtaining spectral imagery data of the biomass. A mobile pyrolysis system is deployed about the target field and follows a path derived from the spectral imagery data.

Disclosed is a marine and freshwater debris collection system using drones and a method for collecting debris using the same. More specifically, the invention allows for the faster and more efficient collection of debris in marine and freshwater environments through the use of drones. In particular, the drones approach a target point, launch a net, and a net hoisting and retrieval hook is used to hoist the trapped debris onto the vessel. This entire process is automated or semi-automated, thereby maximizing the efficiency of the debris collection operation.

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.