A method for instructing operation of a robotic floor-cleaning device based on the position of the robotic floor-cleaning device within a two-dimensional map of the workspace. A two-dimensional map of a workspace is generated using inputs from sensors positioned on a robotic floor-cleaning device to represent the multi-dimensional workspace of the robotic floor-cleaning device. The two-dimensional map is provided to a user on a user interface. A user may adjust the boundaries of the two-dimensional map through the user interface and select settings for map areas to control device operation in various areas of the workspace.

Systems and methods for hailing and using an autonomous storage vehicle. A user uses the storage vehicle to store goods purchased. The storage vehicle carries the goods and stays in a designated area nearby. The storage vehicle goes to the user only when the user calls it. The user meets with the storage vehicle in a meeting area of a parking lot to retrieve the goods.

A combine is a work vehicle that autonomously travels on the basis of a preset travel route, and is provided with an autonomous travel allowance switch, which is an autonomous travel allowance operation member that allows autonomous travel, and a control device that functions as an autonomous travel control part that controls autonomous travel based on the travel route. The autonomous travel control part executes autonomous travel based on the travel route while the autonomous travel allowance switch is being operated (pressed).

An information processing method, an information processing device, a computer-readable medium, and an imaging system capable of generating a flight route of a flight vehicle by simple operation are proposed.

An information processing method of the present disclosure includes: a display control step of causing a display unit to display a plurality of template objects schematically illustrating flight patterns; and a control signal generation step of generating a control signal for a flight vehicle on the basis of flight control information including information on a flight route corresponding to a plurality of selected template objects selected from among the plurality of template objects.

Systems, methods, and devices are provided herein for controlling one or more movable objects via a graphical user interface. A method for controlling a movable object may be provided. The method may comprise obtaining one or more parameters of a target object, and generating a motion path for the movable object based on the one or more parameters of the target object. The motion path may comprise a plurality of spatial points that are defined relative to the one or more parameters of the target object. The plurality of spatial points may be configured to be on one or more planes.

A customer service robot autonomously moves to support shopping of a customer in a commercial facility including a plurality of stores. The customer service robot includes an action plan generating unit (a route setting unit) configured to set a store to be visited and a moving route in the commercial facility based on a store visiting purpose acquired from the customer and an operation control unit (a movement control unit) configured to cause the customer service robot to autonomously move along the moving route.

A method for instructing operation of a robotic floor-cleaning device based on the position of the robotic floor-cleaning device within a two-dimensional map of the workspace. A two-dimensional map of a workspace is generated using inputs from sensors positioned on a robotic floor-cleaning device to represent the multi-dimensional workspace of the robotic floor-cleaning device. The two-dimensional map is provided to a user on a user interface. A user may adjust the boundaries of the two-dimensional map through the user interface and select settings for map areas to control device operation in various areas of the workspace.

A method for instructing operation of a robotic floor-cleaning device based on the position of the robotic floor-cleaning device within a two-dimensional map of the workspace. A two-dimensional map of a workspace is generated using inputs from sensors positioned on a robotic floor-cleaning device to represent the multi-dimensional workspace of the robotic floor-cleaning device. The two-dimensional map is provided to a user on a user interface. A user may adjust the boundaries of the two-dimensional map through the user interface and select settings for map areas to control device operation in various areas of the workspace.

A control system includes one or more processors configured to perform system control for controlling a system including a mobile robot configured to move autonomously and to be operated by a user based on a feature of a mobile body present around an operation interface configured to operate the mobile robot. The system control includes change control for changing operation limitation on the operation interface when the feature satisfies a predetermined condition.

A mobile terminal is operated by an operator to remotely support a moving body, and includes a communication device, a touch panel, and a processor. A motion of the moving body is controlled in accordance with an operation of the operator tilting the mobile terminal while touching the touch panel. The processor is configured to: determine, as a reference angle in a specific rotation direction of the mobile terminal, a tilt angle in the specific rotation direction at a time point of detection of a touch by the operator on the touch panel; generate a control signal for the motion based on the reference angle and the tilt angle in the specific rotation direction during a control validity period in which the touch is continued from the time point of the detection; and transmit the generated control signal to the moving body via the communication device.