A drone docking/landing system includes: a docking portion having a shape of any one of a polygonal pyramid, a truncated polygonal pyramid, a cone, and a truncated cone and being capable of docking a drone; and a landing portion mounted at a lower portion of the drone, having a lower portion that is open, into which the docking portion is inserted, and having an empty inner space, wherein the landing portion has a shape of any one of a polygonal pyramid, a truncated polygonal pyramid, a cone, and a truncated cone, wherein the shape corresponds to the shape of the docking portion so that the docking portion is inserted into the landing portion.

A drone docking/landing system includes: a docking portion having a shape of any one of a polygonal pyramid, a truncated polygonal pyramid, a cone, and a truncated cone and being capable of docking a drone; and a landing portion mounted at a lower portion of the drone, having a lower portion that is open, into which the docking portion is inserted, and having an empty inner space, wherein the landing portion has a shape of any one of a polygonal pyramid, a truncated polygonal pyramid, a cone, and a truncated cone, wherein the shape corresponds to the shape of the docking portion so that the docking portion is inserted into the landing portion.

A lighter-than-air airship has an exoskeleton constructed of spokes and hubs to create a set of connected hexagrams comprised of isosceles triangles wherein the spokes flex and vary in length to produce the slope of said airship's surface. In one embodiment, the exoskeleton connects to a nose cone that includes a cockpit cabin for controlling the airship's operation from a single location that can be physically separated from the exoskeleton in response to catastrophic events and for autonomous and/or remotely piloted operation. An improved means is also provided for landing and unloading cargo, and through use of unmanned aerial vehicles in another embodiment, the airship is configured for remote pickup, transport, delivery and return of payloads such as packages. In yet another embodiment, the airship provides a communications platform for beam form transmission and satellite signal relay, including in combination with the foregoing disclosed attributes.

To avoid the intervention of an operator on a direction control device with which an aircraft towing system is equipped, this system comprises a first towing sling comprising a front end connected to a towing vehicle, and a rear end connected to a first main landing gear, a second towing sling comprising a front end connected to the vehicle, and a rear end connected to a second main landing gear. The direction control device is connected to a front landing gear, and arranged between the first and second slings. The direction control device comprising a lateral direction control member having a first lateral end mounted on the first sling, and a second lateral end mounted on the second sling.

A transportation system and method serve passenger-conveying VTOL air vehicles (AVs) at a vertiport. The vertiport has a flight deck including at least one landing pad, a passenger terminal, and a dynamic partition arrangement that defines a capsule for receiving one of the AVs at a time. The dynamic partition arrangement assumes a first open state in which it is open to the flight deck and closed to the passenger terminal and a second open state in which it is closed to the flight deck and open to the passenger terminal. A robotic system includes a handling robot that automatically approaches and docks with the AV after landing, and conveys the AV between the landing pad and the capsule via an opening provided by the first open state of the dynamic partition.

A device (500) for controlling the ground clearance of an airship (200), the airship being provided with two lateral anchoring points (212), said device comprising: a frame (502), on which a weight (504) is fixed; two (rigid) arms (506), each arm having one end, called proximal end, that is articulated on the frame and one end, called distal end; means for moving the distal end of each arm between a position, called retention position, in which each distal end is in contact with a lateral anchoring end of the airship that is said to be connected to said distal end, and a position, called unlocked position, in which there is no contact between the airship and the docking station; and means for detachably fixing, in the retaining position, the respective distal end of each arm on the associated respective lateral anchoring point.

A ground station for aerial vehicles including a protective casing, at least one charging mechanism, and an extendable landing pad. The extended landing pad is operable to transition between a closed configuration having dimensions suitable to be contained within said protective casing, and an open configuration having dimensions suitable to land the aerial vehicle.

The present invention includes an apparatus for preventing aircraft rollover upon a water landing comprising: a deployable first and/or second boom affixed by a first end to the aircraft and capable of deployment substantially perpendicular to a longitudinal axis of the aircraft; and a first and/or second air bladder attached to a second end of the first and/or second boom, wherein the first and/or second air bladders are configured to inflate when an aircraft lands in the water, wherein deployment of the first and second boom and air bladder prevents aircraft rollover upon water landing; or a deployable keel affixed by a first end to the aircraft and capable of deployment substantially perpendicular to a longitudinal axis and opposite a rotor of the aircraft upon a water landing, wherein the keel is sized to prevent aircraft rollover upon deployment; or both.

A storage case, including, at least one door which is moveable between a first position in which the door is closed and a second position in which the door is opened; a platform, which can support an aerial vehicle; and a mechanical connection means which is connected between the platform and the at least one door, wherein the mechanical connection means is configured such that as the door is moved from its first position to its second position the platform is simultaneously elevated; and as the door is moved from its second position to its first position the platform is simultaneously lowered; and a controller configured to control the mechanical connection means. There is further provided a corresponding method of deploying an aerial vehicle; a corresponding method of storing an aerial vehicle; an assembly including the storage case and an aerial vehicle; and a vehicle including the storage case.

A vehicle includes, on its roof, a first autonomous driving sensor, a second autonomous driving sensor, and a takeoff and landing assist device. The first autonomous driving sensor is disposed adjacent to the front of the vehicle for sensing conditions ahead of the vehicle. The second autonomous driving sensor is disposed adjacent to the rear of the vehicle for sensing conditions behind the vehicle. The takeoff and landing assist device includes a takeoff and landing surface where a flying device takes off and lands. The takeoff and landing assist device is disposed between the first autonomous driving sensor and the second autonomous driving sensor.