An autopilot device for attaching to and exerting forces upon a control wheel of an aircraft includes an actuator fixed with a base, the actuator adapted to move a weight between a left-most position, a center position, and a right-most position. When the weight is in the center position, the base has a center-of-gravity vertically aligned with the rotational axis of the control wheel. When the weight is left or right of the center position, the weight causes a left or right rotational moment on the control wheel, respectively. A controller is connected with the actuator and a power source and is adapted to detect flight parameters including an aircraft orientation, an aircraft heading, and a desired flight path. The controller applies power from the power source to the actuator to move the actuator and weight, thereby causing the aircraft to intercept and track the desired flight path.

An autopilot device for attaching to and exerting forces upon a control wheel of an aircraft includes an actuator fixed with a base, the actuator adapted to move a weight between a left-most position, a center position, and a right-most position. When the weight is in the center position, the base has a center-of-gravity vertically aligned with the rotational axis of the control wheel. When the weight is left or right of the center position, the weight causes a left or right rotational moment on the control wheel, respectively. A controller is connected with the actuator and a power source and is adapted to detect flight parameters including an aircraft orientation, an aircraft heading, and a desired flight path. The controller applies power from the power source to the actuator to move the actuator and weight, thereby causing the aircraft to intercept and track the desired flight path.

Provided are a device for communicating with and controlling a small unmanned airplane, and a method therefor. In an information processing system to which the present invention is applied, a drone is provided with: a converter module that operates on a storage battery; an onboard communication means; an FDR module; a drive unit or the like, not illustrated; a leg section that contacts or approaches a landing port; and a charging terminal for supplying power for charging to the storage battery, the charging terminal being disposed in the proximal area. The landing port is the landing port where the drone lands, and has a projection for guiding the leg section onto a planar section.

Provided are a device for communicating with and controlling a small unmanned airplane, and a method therefor. In an information processing system to which the present invention is applied, a drone is provided with: a converter module that operates on a storage battery; an onboard communication means; an FDR module; a drive unit or the like, not illustrated; a leg section that contacts or approaches a landing port; and a charging terminal for supplying power for charging to the storage battery, the charging terminal being disposed in the proximal area. The landing port is the landing port where the drone lands, and has a projection for guiding the leg section onto a planar section.

The present invention relates to a device capable of controlling a flying bot and a control method therefor, the device comprising: a communication unit for performing wireless communication with the flying bot; a display unit for displaying image information related to the control of the flying bot; a user input unit for controlling a flying state of the flying bot and a function which can be performed by the flying bot; a detection unit for detecting at least one of a rotating direction, a moving direction and a tilt state of the flying bot; and a control unit for receiving, from the flying bot, information about a location and/or a surrounding situation of the flying bot through the communication unit and changing a flight control manner of the flying bot on the basis of the received result, wherein, according to the changed flight control manner of the flying bot, the control unit determines, on the basis of a location of a user, the moving direction and the rotating direction of the flying bot according to an input into the user input unit.

An aircraft control system and control method are disclosed. The system comprises a remote control apparatus with a first control rod and a flight controller associated with an aircraft. The first control rod is configured to move in a first movement direction to control a motion of the aircraft in a first motion direction when an external force is applied on the first control rod and after a withdrawal of the external force, the first control rod returns to a preset position. The remote control apparatus operates to generate one or more control signals corresponding to the withdrawal of the external force. The flight controller controls the aircraft to maintain a flight state based on said control signals and one or more state signals, which are generated based on a measurement of the flight state by a flight controller associated with the aircraft state measurement sensors carried by the aircraft.

An aircraft control system and control method are disclosed. The system comprises a remote control apparatus with a first control rod and a flight controller associated with an aircraft. The first control rod is configured to move in a first movement direction to control a motion of the aircraft in a first motion direction when an external force is applied on the first control rod and after a withdrawal of the external force, the first control rod returns to a preset position. The remote control apparatus operates to generate one or more control signals corresponding to the withdrawal of the external force. The flight controller controls the aircraft to maintain a flight state based on said control signals and one or more state signals, which are generated based on a measurement of the flight state by a flight controller associated with the aircraft state measurement sensors carried by the aircraft.

A drone with a high-voltage trap seeks, identifies, pursues and destroys flying insects within a patrolling area. During its passive attracting mode, the drone lands on a designated ground site and attracts insects with light, sound, and scents. Once insects are lured, the high voltage screens trap will immediately electrocute targeted insects. In its active offensive mode, the drone hovers closer to insect nests using its high-velocity propellers, producing strong downdraft jet streams to disturb the nest and force insects, such as mosquitoes and the like, to evacuate their nest. Once insects are airborne, the drone pursues fleeing insects from below or behind, making use of its propellers and vacuuming the fleeing insects. Slow flying insects that come in contact with the high-voltage electrified screens are immediately electrocuted. Insects that are vacuumed into the fast-spinning propellers blades are knocked down and killed. A rectified charging pad recharges the drone batteries.

An aerial vehicle including a frame, a housing at least partially enclosing the frame, and a flap assembly mounted to at least one of the frame and the housing. The flap assembly can include a flap and an actuator. The aerial vehicle further can include a communication device coupled to the flap. The actuator can be operable to move the flap relative to the housing to at least partially maintain an orientation of the communication device relative to a remote system.

An aerial vehicle including a frame, a housing at least partially enclosing the frame, and a flap assembly mounted to at least one of the frame and the housing. The flap assembly can include a flap and an actuator. The aerial vehicle further can include a communication device coupled to the flap. The actuator can be operable to move the flap relative to the housing to at least partially maintain an orientation of the communication device relative to a remote system.