The present application relates to a control method of an aerial vehicle. The aerial vehicle may comprise a propulsion structure for providing flight power and a spraying apparatus for spraying a material. The control method may comprise determining current target information of the aerial vehicle during a process of the aerial vehicle performing a spraying task, wherein the current target information indicates wind field strength of a downward pressure wind field generated by the propulsion structure; determining, based on the current target information, a desired relative flight altitude of the aerial vehicle corresponding to the current target information relative to the material being sprayed below the aerial vehicle; and controlling the aerial vehicle to fly toward the desired relative flight altitude.

A mobile outdoor power equipment machine for performing a controlled task within a work area includes a drive system for providing movement of the machine, a working apparatus for performing the task, and a scanning system for scanning an area surrounding the machine. The scanning system is configured to provide detection of physical elements in the environment to aid in navigation of the machine. In an embodiment, the scanning system and a control system are configured to scan the area, determine the presence of a physical element in the area, determine that the physical element is located within the work area, determine the proximity of the physical element to the machine, and direct a behavior of the machine.

This application relates to a method and an apparatus for controlling an intelligent lawn mower, an intelligent lawn mower, a computer device, and a storage medium. In the method, output torque of a mowing motor during working of the intelligent lawn mower is detected, a wheel rotation speed of the intelligent lawn mower is reduced in response to the output torque reaches a first set threshold, and the intelligent lawn mower is controlled to operate based on the reduced wheel rotation speed.

A management system includes a storage and a processor. While an agricultural machine including an GNSS receiver is traveling, the storage stores GNSS data output from the GNSS receiver and sensing data output from a sensor sensing a surrounding environment of the agricultural machine in association with each other. The processor is configured or programmed to generate and output visualized data, which represents the surrounding environment of the agricultural machine, based on the GNSS data and the sensing data, when reception interference of a satellite signal occurs.

A combine harvester comprises a control device. The control device functions as a travel route creation unit, a discharge route creation unit, and an autonomous driving control unit. The travel route creation unit creates a travel route R for an unharvested area of a field. The discharge route creation unit creates a discharge route D that extends from an end position E, of the travel route R, at which automatic harvesting of the unharvested area is completed, to a discharge position which is preset for the field. The autonomous driving control unit controls the automatic harvesting travel according to the travel route R or the automatic discharge travel according to the discharge route D.

A server device includes an area setting unit that sets a first area in which a first lawnmower executes first lawn-mowing work in a work area and a second area in which a second lawnmower second lawn-mowing work in the work area, a zone dividing unit that divides the work area into plural virtual zones, a time range setting unit that sets a first time range in which the first lawnmower executes the first lawn-mowing work in each of the virtual zones included in the plural virtual zones and a second time range in which the second lawnmower executes the second lawn-mowing work in each of the virtual zones included in the plural virtual zones, and a notification unit that notifies the first time range and the second time range to a smartphone. Consequently, a user can check a possibilty of contact between the first and second lawnmowers.

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).

In a combine harvester, a travel control portion performs control to enable traveling on a plurality of outermost periphery straight-ahead routes extending along a plurality of sides constituting a farm field outline, respectively. A route creation portion sets, based on machine body information of the combine harvester, a turning necessary area which is necessary for a turn from one outermost periphery straight-ahead route to a next outermost periphery straight-ahead route, and also creates, from a predetermined start point set on the one outermost periphery straight-ahead route toward an unworked land adjacent to an already-worked land which is formed by traveling based on the one outermost periphery straight-ahead route, a predetermined number of inclined routes, which are inclined at a predetermined angle relative to the one outermost periphery straight-ahead route, in the turning necessary area. The travel control portion performs control to enable autonomous straight-ahead traveling along the inclined route.

A method for determining a motion path on a surface in an environment, along which motion path a mobile appliance, in particular a robot, preferably a domestic robot or a robot vacuum cleaner, is intended to move. The method includes obtaining environment information and determining a region of the surface intended to be covered by the motion of the mobile appliance; determining, while taking into account the environment information, whether within the region there is at least one uneven area in the surface that can be negotiated by the mobile appliance; and determining the motion path while taking into account the at least one uneven area, if there is one. A mobile appliance is also described.

Provided is an autonomous lawn mowing system having improved safety. An autonomous lawn mowing system 1 is provided with: a position-information acquisition unit 14 that acquires position information concerning the position of an autonomous lawn mower 2 that is capable of travelling by itself; a moisture-information acquisition unit 15 that acquires moisture information concerning the moisture content of turf; a wet-ground identification unit 31 that identifies a wet region on the basis of the position information and the moisture information; and a control module 34 that controls the autonomous lawn mower 2 on the basis of the result identified by the wet-ground identification unit 31.