An unmanned aerial vehicle comprising at least one rotor motor. The rotor motor is powered by a micro hybrid generation system. The micro hybrid generator system comprises a rechargeable battery configured to provide power to the at least one rotor motor, a small engine configured to generate mechanical power, a generator motor coupled to the small engine and configured to generate AC power using the mechanical power generated by the small engine, a bridge rectifier configured to convert the AC power generated by the generator motor to DC power and provide the DC power to either or both the rechargeable battery and the at least one rotor motor, and an electronic control unit configured to control a throttle of the small engine based, at least in part, on a power demand of at least one load, the at least one load including the at least one rotor motor.

An unmanned aerial vehicle comprising at least one rotor motor. The rotor motor is powered by a micro hybrid generation system. The micro hybrid generator system comprises a rechargeable battery configured to provide power to the at least one rotor motor, a small engine configured to generate mechanical power, a generator motor coupled to the small engine and configured to generate AC power using the mechanical power generated by the small engine, a bridge rectifier configured to convert the AC power generated by the generator motor to DC power and provide the DC power to either or both the rechargeable battery and the at least one rotor motor, and an electronic control unit configured to control a throttle of the small engine based, at least in part, on a power demand of at least one load, the at least one load including the at least one rotor motor.

An unmanned aerial vehicle (UAV) includes a body that supports one or more rotors, the one or more rotors each driven by a motor and configured to provide lift to the body. The UAV further includes a parts handler coupled to the body, the parts handler configured to grasp a payload, and rotate the payload with respect to an external structure to couple the payload to, or decouple the payload from, the external structure. The UAV includes a stabilizing mechanism extending from the body, the stabilizing mechanism configured to contact the external structure without transferring entire weight of the UAV to the external structure and prevent rotation of the body when the part-handler rotates the payload.

Disclosed are systems, apparatuses, and methods to determine, communicate, and/or respond to state information of at least one of a suspended load control apparatus, carrier, or load suspended by a cable from the carrier, wherein response to the state information may be to control at least one of the suspended load control apparatus, carrier, or load suspended by a cable from the carrier.

There is described an aircraft configured to be able to hover, comprising a fuselage; and a support element adapted to support a load, made of elastically deformable material and constrained to said fuselage; the support element being movable in an operating position in which it is arranged at least partially outside said fuselage and supports said load; the aircraft comprises a sock surrounding the support element arranged in said operating position; the sock is configured to contain the elastic return of the support element, in case the support element arranged in said operating position is sheared off.

There is disclosed a system for enhanced aerial delivery capability. In an embodiment, there is provided an electro-mechanical cargo alignment and capture system to allow Unmanned Aerial Systems to align and collect/capture external cargo payloads. In another embodiment, there is provided an electro-mechanical cargo alignment and capture system to allow Unmanned Aerial Systems to align and secure external cargo payloads to ground docking stations. Other embodiments are also disclosed.

There is disclosed a system for enhanced aerial delivery capability. In an embodiment, there is provided an electro-mechanical cargo alignment and capture system to allow Unmanned Aerial Systems to align and collect/capture external cargo payloads. In another embodiment, there is provided an electro-mechanical cargo alignment and capture system to allow Unmanned Aerial Systems to align and secure external cargo payloads to ground docking stations. Other embodiments are also disclosed.

A payload suspension system is described herein. A payload suspension system may comprise a suspended payload container within an internal cavity defined by the payload suspension system. The suspended payload container may be suspended by one or more tensile members. The one or more tensile members may be coupled with respective tension adjustment mechanisms configured to adjust a tension of the tensile members. The tension may be adjusted based on a transition to and from a low- or micro-gravity state, in order to provide an increased or decreased movement/rotational ability for the payload container. The low- or micro-gravity state may be produced due to an aircraft performing a parabolic maneuver.

A payload suspension system is described herein. A payload suspension system may comprise a suspended payload container within an internal cavity defined by the payload suspension system. The suspended payload container may be suspended by one or more tensile members. The one or more tensile members may be coupled with respective tension adjustment mechanisms configured to adjust a tension of the tensile members. The tension may be adjusted based on a transition to and from a low- or micro-gravity state, in order to provide an increased or decreased movement/rotational ability for the payload container. The low- or micro-gravity state may be produced due to an aircraft performing a parabolic maneuver.

A system for remote pilot control of an electric aircraft in autopilot mode including a remote computing device configured to receive a user input and generate a control datum as a function of the pilot input, a flight controller configured to receive the control datum from the remote computing device, and generate a command datum as a function of the control datum and an authority status, and the remote computing device configured to receive the command datum from the flight controller, and display the command datum.