A hybrid airship-aerostat includes a hull, a motor, a fin, a controller, and a bridle system. The motor is coupled to the hull and is configured to rotate between a thrust configuration and a lift configuration. The motor is configured to generate a lift force, a thrust force, or a combination thereof. The fin is coupled to a tail of the hull and is configured to provide directional control of the hull. The controller is configured to operate the motor and the fin to pilot the hull. The bridle system is configured to removably couple to a first end of a tether.

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.

An air vehicle comprises a payload vessel, a propulsion system, and a buoyancy lifting unit anchored on said payload vessel. The buoyancy lifting unit comprises a plurality of balloons and a plurality of buoyancy gas reservoirs arranged in horizontal rows and vertical columns, a protractible rod, and a control system. Each of the balloons and buoyancy gas reservoirs is tethered to a lifting-joint on the protractible rod through a cable. The control system controls vertical move of the air vehicle to ascend through directing buoyancy gas flow from the buoyancy gas reservoirs into the balloons, and to descend through directing buoyancy gas flow from the balloons into the buoyancy gas reservoirs. The propulsion system controls horizontal move of the air vehicle to go forward and make turns.

An air vehicle comprises a payload vessel, a propulsion system, and a buoyancy lifting unit anchored on said payload vessel. The buoyancy lifting unit comprises a plurality of balloons and a plurality of buoyancy gas reservoirs arranged in horizontal rows and vertical columns, a protractible rod, and a control system. Each of the balloons and buoyancy gas reservoirs is tethered to a lifting-joint on the protractible rod through a cable. The control system controls vertical move of the air vehicle to ascend through directing buoyancy gas flow from the buoyancy gas reservoirs into the balloons, and to descend through directing buoyancy gas flow from the balloons into the buoyancy gas reservoirs. The propulsion system controls horizontal move of the air vehicle to go forward and make turns.

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.

An airborne platform vehicle comprising an aircraft with a platform affixed to the top side providing for a multipurpose airborne platform is disclosed. The airborne platform vehicle comprising a platform affixed to the top side of an aircraft or airship providing accessibility to the platform from either inside or outside the aircraft. The aircraft itself being able to float or fly by virtue of the lighter than air gas inside the body of the aircraft or with assisted lift from wings, being propelled by a ducted fan, propeller drive system, or otherwise and having a power source from which to power the drive system. The airborne platform vehicle being capable of movement and remaining upright through the use of ballast, propellers, ducted fans, vector thrusters, wings, fins, and/or rudders. The airborne platform vehicle itself being able to take-off and land as well as stay afloat for long durations in a stationary or non-stationary position.

An airborne platform vehicle comprising an aircraft with a platform affixed to the top side providing for a multipurpose airborne platform is disclosed. The airborne platform vehicle comprising a platform affixed to the top side of an aircraft or airship providing accessibility to the platform from either inside or outside the aircraft. The aircraft itself being able to float or fly by virtue of the lighter than air gas inside the body of the aircraft or with assisted lift from wings, being propelled by a ducted fan, propeller drive system, or otherwise and having a power source from which to power the drive system. The airborne platform vehicle being capable of movement and remaining upright through the use of ballast, propellers, ducted fans, vector thrusters, wings, fins, and/or rudders. The airborne platform vehicle itself being able to take-off and land as well as stay afloat for long durations in a stationary or non-stationary position.

An airborne computational facility uses an energy collection system to provide energy for operation. An airborne balloon is provided with a photovoltaic collector array, and uses energy generated by the photovoltaic collector array to power an on-board computational facility. Data for computation is received by a communication module and computational results are transmitted by the communication module.

An airborne computational facility uses an energy collection system to provide energy for operation. An airborne balloon is provided with a photovoltaic collector array, and uses energy generated by the photovoltaic collector array to power an on-board computational facility. Data for computation is received by a communication module and computational results are transmitted by the communication module.

A device for controlling thrust vectoring of a cyclorotor includes a control cam positionable relative to a drive shaft of a cyclorotor along each of a first axis and a second axis, where the drive shaft is rotatable about a third axis. The device may further include a frame having a plurality of sides, where the frame is disposed at least partly around the drive shaft of the cyclorotor, a first positioning assembly disposed on a first side of the frame, where the first positioning assembly is structurally configured to move the frame along the first axis, and a second positioning assembly disposed on a second side of the frame, where the second positioning assembly is engaged with the control cam and structurally configured to move the control cam relative to the frame along the second axis.