An aerial vehicle and methods of use. The aerial vehicle including a central rotor assembly configured to provide vertical thrust. A fuselage having a longitudinal axis mounted to the central rotor assembly. A plurality of rotors smaller than said central rotor mounted to said fuselage by a frame, includes a propeller, an electrical motor, an electronic speed controller, a flight controller (means for controlling the rotation speed of the central rotor and the smaller rotors). A propulsion system for powering said central rotor, said smaller rotors and said flight controller. Together with control and monitoring systems, the aerial vehicle system enables a new agricultural ecosystem for providing small farmer access to global markets.

A flying machine includes: a flying machine body that includes a rotor blade; a protective member that forms a frame shape inside which the rotor blade is disposed, that is rotatably fixed to both end portions of the flying machine body, and that is pipe shaped; and a connecting wire that passes through an inner portion of the protective member to connect the flying machine body and an external device together.

A robust amphibious air vehicle incorporates a fuselage with buoyant stabilizers and wings extending from the fuselage. At least one lift fan is mounted in the fuselage. Movable propulsion units carried by the wings are rotatable through a range of angles adapted for vertical and horizontal flight operations.

A vehicle can be configured to include a body having a body bottom conjoined with a body sidewall and a body top forming a body cavity. The body top includes a body top opening and the body sidewall includes a body sidewall opening. The vehicle can include a payload housing having a payload bottom conjoined with a payload housing sidewall and a payload housing top forming a payload housing cavity, wherein the payload housing cavity is configured to hold at least one operating module for the vehicle. The vehicle can include at least one arm. The vehicle can include at least one interlocking arrangement of the body top opening or body side wall configured to removably secure the payload housing and the at least one arm to the body. Each of the body, the payload housing, and the at least one arm can be structured with additive manufactured material.

A vehicle for aerial-aquatic locomotion is provided. The vehicle may include a propeller, an electric motor operably coupled to the propeller and configured to rotate the propeller, a maneuvering assembly configured to change an attitude and altitude of the vehicle, and a controller operably coupled to the electric motor and the maneuvering assembly. The controller may be configured to receive a command for the vehicle to exit a first medium and enter a second medium, compute or retrieve a hybrid trajectory, and control the electric motor and the maneuvering assembly to maneuver the vehicle in accordance with the hybrid trajectory.

A personal transportation device comprises a frame, a wheel pivotably connected to a frame and switchable between a driving configuration and a flying configuration, a motor to rotate the wheel; and an automatic cruise module. The automatic cruise module is configured to control the wheel and guide the personal transportation device to fly from a first location to a second location according to a designated route as an unmanned aircraft.

An Unmanned Aerial Vehicle (UAV) has a fuselage, a rotor system, and a wing configured for selective positioning during flight of the UAV to a deployed position, a stowed position, and to positions between the deployed position and the stowed position. The UAV has a flexible wing skin at least partially carried by a leading arm and the leading arm is rotatable relative to the fuselage.

A multi-modal vehicle includes a frame, a rotor pivotally mounted to the frame, the rotor including a first position and a second position circumferentially spaced from the first position, and a motor coupled to the rotor and configured to rotate the rotor, wherein, when the rotor is disposed in the first position, the rotor is configured to generate lift when actuated by the motor, wherein, when the rotor is disposed in the second position, the rotor is configured to engage a surface to transport the vehicle when actuated by the motor.

Transformable unmanned vehicles and related methods are disclosed. An example vehicle includes a body having, a first cap, a second cap spaced from the first cap, and a plurality of segments radially spaced relative to a longitudinal axis of the body. The segments are movable relative to the first cap and the second cap. The vehicle includes a payload supported by the first cap. An actuation system moves the segments relative to the first cap and the second cap to transform the body between a first configuration and a second configuration different than the first configuration.

A robust amphibious air vehicle incorporates a fuselage with buoyant stabilizers and wings extending from the fuselage. At least one lift fan is mounted in the fuselage. Movable propulsion units carried by the wings are rotatable through a range of angles adapted for vertical and horizontal flight operations.