Disclosed is a docking station for use with an unmanned aerial vehicle (UAV). The docking station has a retractable guide apparatus having a retracted state in which the retractable guide apparatus is retracted within the docking station and an expanded state in which the retractable guide is expanded outward from the docking station for physically guiding the UAV into the docking station. Given that the guide apparatus is retractable, the retractable guide apparatus is provided with some protection from environmental factors such as exposure to ice, snow and high winds. This can help to increase durability and reliability, such that the UAV can reliably land in the docking station without any personnel being present. Deployment is also possible without any personnel being present. Therefore, it is possible to avoid or mitigate the costs associated with personnel.

A housing for a ground vehicle-mountable aerial vehicle is provided. The housing includes a base portion defining a cavity and an opening leading into the cavity. The cavity is structured to receive an unmanned aerial vehicle therein. The cavity is configured so as to open upwardly when the housing is mounted on the vehicle. The housing also includes a drafting wall structured to extend from the base portion at a location forward of at least a portion of the cavity when the housing is mounted on the ground vehicle.

The present disclosure describes various systems, devices, and methods configured to retrieve a fixed-wing aircraft from free flight using a flexible capture member and a monopole assembly.

An urban air mobility power supply system includes an urban air mobility (UAM) device and a power supply drone docked with the UAM device using electromagnetic force to supply external power, and a power supply method, in which the UAM device 200 and the power supply drone are accurately aligned with each other using electromagnets provided in the UAM device and the power supply drone to supply power, and the UAM device and the power supply drone can be easily separated from each other using electromagnetic force.

A projectile landing apparatus for retrieving a projectile includes a plurality of grippers disposed to be spaced apart. The plurality of grippers may include a support, a guide having one side connected to one end of the support, and a shock absorber having one end connected to the other end of the support and having the other end connected to the guide. The plurality of grippers may guide a projectile, buffer a load, and safely retrieve the projectile.

Methods and apparatus to recover unmanned aerial vehicles with kites are disclosed. A disclosed example apparatus includes a tether line to be supported by a kite at a distal end thereof, and a release to deploy and expand a parafoil from at least one of the tether line or the kite in response to the aircraft contacting the tether line.

Methods, apparatus, systems and articles of manufacture are disclosed. A disclosed example apparatus to recover an aircraft includes a mast extending from a base, a boom extending from the mast at a first end of the boom to a second end of the boom opposite the first end, a tether line extending between the mast to the base and guided by the boom, a portion of the tether line extending between the second end of the boom and the base, and a mount to operatively coupled the a kite to the tether line, the kite to support the tether line as the aircraft contacts the portion for recovery thereof.

Aerial launch and/or recovery for unmanned aircraft, and associated systems and methods are described. A representative system includes a first, carrier aircraft having an airframe, a propulsion system carried by the airframe and positioned to support the carrier aircraft in hover, and a capture line carried by the carrier aircraft and deployable to hang from the carrier aircraft. The capture line is sized to releasably engage with a capture device of a second, carried aircraft. The system further includes a retrieval device positioned to support the carried aircraft for detachment from the capture line.

Aerial launch and/or recovery for unmanned aircraft, and associated systems and methods are described. A representative system includes a first, carrier aircraft having an airframe, a propulsion system carried by the airframe and positioned to support the carrier aircraft in hover, and a capture line carried by the carrier aircraft and deployable to hang from the carrier aircraft. The capture line is sized to releasably engage with a capture device of a second, carried aircraft. The system further includes a retrieval device positioned to support the carried aircraft for detachment from the capture line.

A positioning mechanism includes a base including a landing area and a guide member movably arranged at the landing area and configured to guide a moving object. The landing area includes a positioning portion. The guide member is configured to be in a non-operating state or an operating state relative to the base. A form of the guide member in the non-operating state is different from the form of the guide member in the operating state.