Abstract: A road driving and flight vehicle is able to automatically convert between two configurations to facilitate operations as an automobile and as an aircraft. In the flight configuration the craft includes two jet engines at a rear body part, two wings with ailerons produced by open/flap upwardly doors where the upper end is hinged to a body and bottom end raised up to place wings horizontally, and a vertical stabilizer with rudder and two horizontal stabilizers with elevators. In the road driving configuration vehicle includes conventional automobile power plant in the front part of the body, four wheels of which two front wheels are steerable, two doors, and a vertical and two horizontal stabilizers are stored at a rear part of the body.

Abstract: A platform including two winged aircraft are tethered during flight by a single tether near their respective centers of gravity. The tether is windable about a reel, so that a distance between the aircraft can be changed during flight. The aircraft contain avionics configured to enable autonomous flight using natural wind gradients. One aircraft imposes aerodynamic forces on the other, through the tether, while flying at an altitude where wind speed is significantly different than wind speed at an altitude of the other aircraft. The two aircraft cruise back and forth within a maximum distance from a station on the ground. Cruise conditions are established using an iterative computer algorithm which utilizes flight measurements. The aircraft communicate information between each other, and the ground, and contain a payload which performs a useful function at high altitudes.

Abstract: A flying object capable of being launched in air is detachably mounted on a wing body of a launching apparatus. The launching apparatus is towed by an aircraft through a cable so as to be run and taken off. After raising the launching apparatus to a launching height of the flying object by the aircraft, the flying object is released from the wing body in air and then the flying object is ignited and launched in air in a launching system. The system for launching in air can be developed without newly developing a platform as a mother ship so that a research cost can be remarkably reduced. In the case that a small artificial satellite is installed in a flying object, it is possible to develop an artificial satellite smoothly and quickly applicable to security matters and disaster observation.

Abstract: Methods and systems are provided which may allow a first vehicle to recover a second air vehicle while both are moving. The first vehicle and the second air vehicle may be traveling at different velocities. An attachment member of the second air vehicle may attach to a recovery member of the first vehicle while the first vehicle and the second air vehicle are traveling at different velocities. The recovery member attached to the second air vehicle may move relative to and along an exterior surface of the first vehicle in a direction substantially parallel to a direction of travel of the first vehicle.

Abstract: A system and method for docking various types of aircraft is disclosed. An aerodynamic lifting structure docking mechanism for docking two or more aircraft is provided comprising an aerodynamic lifting structure. The aerodynamic lifting structure includes a first and second airflow adjustment mechanism. The aerodynamic lifting structure further includes a first hard docking mechanism, and a second hard docking mechanism, and still further includes a soft docking mechanism. The first and second airflow adjustment mechanisms are configured to substantially remove any aerodynamic lifting structure vortices around each of the aerodynamic lifting structure tip areas. The soft docking mechanism is configured to soft dock a first aerodynamic lifting structure with a second aerodynamic lifting structure. The first hard docking mechanism is configured to hard dock with the second hard docking mechanism, thereby temporarily attaching the first aerodynamic lifting structure with the second aerodynamic lifting structure.

Abstract: A method for controlling an unmanned platform from a manned station is provided. The method includes transmitting a master arm control message from the manned station to the unmanned platform via a first control path, transmitting a first critical control message from the manned station to the unmanned platform via a second control path that is independent of the first control path, and transmitting a second critical control message from the manned station to the unmanned platform via a third control path that is different than the first control path and the second control path.

Abstract: The invention relates to an autonomous stratospheric aircraft which is lighter than air, and to a method for providing radio and optical communication, television broadcasting and monitoring with the aid of communication equipment arranged on the aircraft. The present invention can be used for producing lighter-than-air aircraft as well as global and regional communication and television broadcasting and multi-aspect monitoring systems and networks.

Abstract: A transforming unmanned aerial-to-ground vehicle assembly comprising: an aerodynamic flying assembly comprising an unmanned aerial vehicle integrated with an unmanned ground vehicle, a power unit shared by the unmanned aerial vehicle and the unmanned ground vehicle, vehicle controls shared by the unmanned aerial vehicle and the unmanned ground vehicle, a disengagement mechanism to separate the unmanned ground vehicle from the unmanned aerial vehicle, one or more manipulator arms located on either the unmanned aerial vehicle or the unmanned ground vehicle, and landing gear.

Abstract: A method whereby a relatively faster-moving vessel recovers a relatively-slower moving vehicle includes, in some embodiments, causing a first faster-moving vehicle to move along a first circular path, deploying a cable radially inward from the first circular path such that a free end of the cable circumscribes a second circular path having a radius smaller than that of the first circular path, attracting a second slower-moving vehicle to the free end of the cable, and coupling the second vehicle to the cable.

Abstract: A system and method for docking various types of aircraft is disclosed. An aerodynamic lifting structure docking mechanism for docking two or more aircraft is provided comprising an aerodynamic lifting structure. The aerodynamic lifting structure includes a first and second airflow adjustment mechanism. The aerodynamic lifting structure further includes a first hard docking mechanism, and a second hard docking mechanism, and still further includes a soft docking mechanism. The first and second airflow adjustment mechanisms are configured to substantially remove any aerodynamic lifting structure vortices around each of the aerodynamic lifting structure tip areas. The soft docking mechanism is configured to soft dock a first aerodynamic lifting structure with a second aerodynamic lifting structure. The first hard docking mechanism is configured to hard dock with the second hard docking mechanism, thereby temporarily attaching the first aerodynamic lifting structure with the second aerodynamic lifting structure.

Abstract: A system and method for docking various types of aircraft is disclosed. An aerodynamic lifting structure docking mechanism for docking two or more aircraft is provided comprising an aerodynamic lifting structure. The aerodynamic lifting structure includes a first and second airflow adjustment mechanism. The aerodynamic lifting structure further includes a first hard docking mechanism, and a second hard docking mechanism, and still further includes a soft docking mechanism. The first and second airflow adjustment mechanisms are configured to substantially remove any aerodynamic lifting structure vortices around each of the aerodynamic lifting structure tip areas. The soft docking mechanism is configured to soft dock a first aerodynamic lifting structure with a second aerodynamic lifting structure. The first hard docking mechanism is configured to hard dock with the second hard docking mechanism, thereby temporarily attaching the first aerodynamic lifting structure with the second aerodynamic lifting structure.

Abstract: A system and method for docking various types of aircraft is disclosed. An aerodynamic lifting structure docking mechanism for docking two or more aircraft is provided comprising an aerodynamic lifting structure. The aerodynamic lifting structure includes a first and second airflow adjustment mechanism. The aerodynamic lifting structure further includes a first hard docking mechanism, and a second hard docking mechanism, and still further includes a soft docking mechanism. The first and second airflow adjustment mechanisms are configured to substantially remove any aerodynamic lifting structure vortices around each of the aerodynamic lifting structure tip areas. The soft docking mechanism is configured to soft dock a first aerodynamic lifting structure with a second aerodynamic lifting structure. The first hard docking mechanism is configured to hard dock with the second hard docking mechanism, thereby temporarily attaching the first aerodynamic lifting structure with the second aerodynamic lifting structure.

Abstract: A roadable aircraft and an associated method are disclosed herein. The roadable aircraft includes a body extending along a longitudinal axis and operable to house a human occupant. The roadable aircraft also includes at least first and second wings each being selectively moveable relative to the body between a retracted position for stowing and an extended position for flight. Each of the first and second wings extend a wing cord along the longitudinal axis when in the extended position between a leading edge and a wing trailing-edge vectoring nozzle. The roadable aircraft also includes a system for directing first and second streams of air through the first and second wings, respectively, and out of the first and second wing trailing-edge vectoring nozzles such that thrust for the body is generated. In addition, embodiments of the invention can include a plurality of deployable, vectoring lift fans which are also capable of producing thrust.

Abstract: An airship system having a flexible envelope and at least one bladder positioned therein is described. The bladder(s) provide an impervious barrier between the gas within the bladder(s) and the air exterior to the bladder(s). The envelope includes longitudinal and hoops straps weaved together in a criss-cross manner. The envelope also includes rings positioned thereon that include truss members for receiving struts for removably coupling the airship to another airship. A tri-hull delta dirigible system is also described, comprising three airships coupled together using struts and arranged in an equilateral triangle formation. The tri-hull delta dirigible system has a similar lift capacity (volume) as a conventional large mono-hull dirigible, while minimizing the detrimental bending in the center of the conventional mono-hull dirigible.

Abstract: A vehicle includes a first sub-vehicle, and a second sub-vehicle which is repeatably moveable between coupled and uncoupled conditions with the first sub-vehicle. The first and second sub-vehicles each include a landing system and propulsion system. The first and second sub-vehicles are in the coupled condition during take-off. The first and second sub-vehicles are separately flyable in the uncoupled condition. Both vehicles are launched horizontally, by a ramp, or vertically, using atmospheric lift to achieve atmospheric flight, orbital, or sub-orbital launch.

Abstract: A cockpit and an aircraft including such cockpit. The cockpit includes a front section of an aircraft. Such cockpit includes a pressure bulkhead sealing the section and a pressurization system for pressurizing such section.

Abstract: An unmanned air module includes one or more rotors, engines, a transmission and avionics. Any of several different ground modules may be attached to the air module. The air module may fly with and without the ground module attached. The ground module may be a vehicle ground module and may be manned. The vehicle ground module may transport the attached air module across the ground. The air module may have two rotors, which may be ducted fans, and three different configurations: a tandem rotor configuration, a side-by-side configuration, and a tilted-rotor configuration.

Abstract: A system and method for docking various types of aircraft is disclosed. An aerodynamic lifting structure docking mechanism for docking two or more aircraft is provided comprising an aerodynamic lifting structure. The aerodynamic lifting structure includes a first and second airflow adjustment mechanism. The aerodynamic lifting structure further includes a first hard docking mechanism, and a second hard docking mechanism, and still further includes a soft docking mechanism. The first and second airflow adjustment mechanisms are configured to substantially remove any aerodynamic lifting structure vortices around each of the aerodynamic lifting structure tip areas. The soft docking mechanism is configured to soft dock a first aerodynamic lifting structure with a second aerodynamic lifting structure. The first hard docking mechanism is configured to hard dock with the second hard docking mechanism, thereby temporarily attaching the first aerodynamic lifting structure with the second aerodynamic lifting structure.

Abstract: A power generation apparatus and method comprises at least one gyroglider rotary wing flying at an altitude above the nap of the earth. A strong and flexible tether, connected to the gyroglider frame is pulled with a force generated by the rotary wing. The force is transmitted to a ground station that converts the comparatively linear motion of the tether being pulled upward with a lifting force. The linear motion is transferred to a rotary motion at the ground station to rotate an electrical generator. The tether is retrieved and re-coiled about a drum by controlling the gyroglider to fly down at a speed and lift force that permit recovery of the gyroglider at a substantially reduced amount of retrieval force compared to the lifting force during payout of the tether. Thus, the net difference in force results in a net gain of energy.

Abstract: An aero-assisted pre-stage (10) with a commensurably large wing area having a short-burn propulsion system providing sufficient thrust is used to launch a variety of single-stage and multiple-stage space vehicles (20), such as conventional ballistic rockets and prospective spaceplanes, from conventional runways. This method of launch eliminates the need for dedicated ground launch structures and/or dedicated long runways. The vehicle to be launched (20) is mated to this aero-assisted pre-stage (AP) (10), with their flight directions aligned, using a lock-and-release mechanism (30). The resulting stack takes off like a conventional airplane using the propulsion and aerodynamic lift of the AP. After the desired trajectory of the vehicle is achieved and propulsion system of the AP is shut down, the vehicle is separated from the AP, the propulsion system of the vehicle is ignited, and the vehicle continues its ascent. The AP returns back to the surface for reuse or disposal.

Abstract: Disclosed is a flying object system performing ground traveling, which travels on the ground and flies in the air. The flying object system travels with three or more wheels connected to a main body, generates flying force through wings symmetrically installed at both sides of the main body, and is provided with plural propellers, operated by a control lever and installed on the wings and at least a part of the main body, each of the wings being divided into a plurality of compartments to be folded or be changed in shape by pressure of gas or air. Therefore, the flying object system travels on a road on the ground and takes off and flies in the air in traffic congestion, and flies in the air and lands and travels on a road on the ground if necessary, thus rapidly moving to a destination without the effects of traffic congestion.

Abstract: A vehicle suitable as both a road vehicle and an aircraft, which includes two units that can be coupled to one another; a first unit embodies a road vehicle with least single-file seating, and a second unit is embodied as a flight unit.

Abstract: A system including a heavier-than-air vehicle (HTA), a lighter-than-air vehicle (LTA), and a tether is disclosed. The tether is coupled between the HTA and the LTA such that the LTA supports the HTA. The system may be further configured to suit the needs of the particular application. For example, the system may be configured to be controllable from a remote location or capable of autonomous operations. The system may also be configured such that the HTA comprises a mission payload and communications equipment. In an exemplary embodiment of the invention, the LTA is configured to provide lift for the system and the HTA is configured to provide station-keeping propulsion, the advantage being reduced fuel consumption and increased mission endurance.

Abstract: Systems and/or methods for forming a multiple-articulated flying system (skybase) having a high aspect ratio wing platform, operable to loiter over an area of interest at a high altitude are provided. In certain exemplary embodiments, autonomous modular flyers join together in a wingtip-to-wingtip manner. Such modular flyers may derive their power from insolation. The autonomous flyers may include sensors which operate individually, or collectively after a skybase is formed. The skybase preferably may be aggregated, disaggregated, and/or re-aggregated as called for by the prevailing conditions. Thus, it may be possible to provide a “forever-on-station” aircraft.

Abstract: Miniature robotic vehicles suitable for a variety of tasks including covert surveillance, reconnaissance, and recreation are provided. Embodiments of the invention may include vehicles having a hybrid transportation system that incorporates a rotary-wing flight mode in conjunction with a wheeled ground transport mode. As a result, exemplary vehicles provide efficient ground-mode travel, with the added ability to fly over large obstacles and rough terrain.

Abstract: The invention relates to a flying device which can efficiently move in the air by aerodynamic forces and by direct force transmission on the ground, without the need for independent drive and thrust generation systems for the two modes of movement. The rotors (1) of the flying device are provided on the outside thereof with an annular rotating covering (4), connected directly to the rotor blade tips, which, when the flying device is on the ground and the rotor rotational axes (2) are correspondingly pitched about an axis (3), come into contact with the ground. The covering (4) hence permits a movement of the flying device on the ground by rolling, which is based on a direct force transfer to the ground. A further rotor pitching axis (5) permits the flying device to be controlled in the air and on the ground by means of the same actuator system.

Abstract: A method and apparatus for a composite helicopter comprising a rotary wing parent vehicle with various modular cabins detachable therefrom to facilitate various configuration aircraft platforms, dual operation and modular economy.

Abstract: A low-wing, low-span canard aircraft with a protected pusher-style propeller is designed to transition simply between use in the air and use on the ground, without any mechanical effort on the part of the pilot. The vehicle may include deformable aerodynamic bumpers, embedded road-safety vehicle lighting and license plates, a protected propeller, and an integrated RFID airport access system. The vehicle may be designed for potential certification by the Federal Aviation Administration as a Light Sport Aircraft.

Abstract: A vehicle (1) for riding on land and flying in air comprises: a cabin (2) with wheels (3, 4), the cabin (2) being designed for accommodating at least one person, a rotor (40) having a rotor axle (41), a rotor base (44) and rotor blades (45) mounted to the rotor base (44); a support bracket (30) carrying the rotor (40), the support bracket (30) having a bottom section (31) extending substantially parallel to the cabin roof, and having at least one leg section (32) extending substantially parallel to the cabin side, the leg section (32) having a free end connected to the cabin (2); wherein the rotor blades (45) are hingedly mounted to the rotor base (44); and wherein the bottom bracket (31) part with the rotor (40) is displaceable in the longitudinal direction of the vehicle (1).

Abstract: An unmanned aircraft system includes a manned aircraft and an unmanned aircraft. The manned aircraft includes a manned aircraft main wing, a manned aircraft fuselage, a manned aircraft landing system, and a manned aircraft joining mechanism provided at a bottom portion of the manned aircraft fuselage. The unmanned aircraft includes an unmanned aircraft main wing, an unmanned aircraft fuselage, an unmanned aircraft landing system, and an unmanned aircraft joining mechanism provided at a roof portion of the unmanned aircraft fuselage. The manned aircraft joining mechanism and the unmanned aircraft joining mechanism are detachably joined. The unmanned aircraft system can take off or land in a state that the unmanned aircraft and the manned aircraft are joined.

Abstract: A convertible combined road, water, and aircraft vehicle has a road form, a water form, and an aircraft form. The vehicle includes a vehicle body having a passenger compartment and wheels supporting the vehicle body on the ground when in the road form. A wing assembly is attached to each side of the vehicle body. Each wing assembly includes a wing and at least one propelling device attached to the wing. The propelling devices may be jet engines, or ducted fans or in-wing propellers. A wing assembly rotating mechanism rotates the wing assembly 360 degrees when the vehicle is in the aircraft form so that thrust is provided in 360 degrees, allowing for vertical takeoff and landing and mid air hovering. A wing assembly positioning mechanism positions the wing assembly between an open-winged flying position and a folded or closed-winged non-flying position.

Abstract: A roadable aircraft may be registered and driven as a motorcycle on the roadways, does not require that any parts be “left behind” at the airport when configuring to roadable use and does not require removing portions of the aircraft and towing them behind. A foldable and collapsible wing comprises a number of wing ribs, which are hinged to a main forward spar. To fold for road usage, the wing ribs fold about a hinge fitting to collapse against the wing spar. To maintain tension on the wing skin (to prevent flutter) tensioning bladder(s) may be used to keep the fabric taut. Once retracted and folded, the wings align with tail booms to form a compact and aerodynamic package. The ductless fan may be provided with a center-mounted extraction fan ducted to inlets along the fuselage to draw low energy air in toward the fuselage and thus prevent boundary layer separation.

Abstract: A hybrid fixed wing aircraft converts into a roadworthy vehicle in a matter of seconds therefore operating efficiently in both air and ground transportation systems. The single piece wing is mounted on a skewed pivot that is on the lower portion of the fuselage and is operated by a pushbutton operating system. The aircraft includes telescopic twin boom tail design that when extended allows good pitch stability and damping. The aircraft's wing area may be increased with additional telescopic wing tip segments. This allows an increase in aspect ratio, hence improving efficiency at high loads. This feature will also creates a reduction in induced drag at cruise speed by simply retracting the tips in flight. The vehicle has a unique synchronized control system that switches from flight to ground mode without input from the operator, thereby providing a natural interface for the operator.

Abstract: System and method for a flyable and roadable vehicle. According to an embodiment, the present invention provides a vehicle capable of air and road travel. The vehicle is adaptable to a flying configuration and a road configuration. The vehicle includes a fuselage having a front end, a rear end, a top side, a bottom side. The vehicle also includes a wing component having a plurality of planes. The plurality of planes includes a first plane and a second plane. The vehicle additionally includes a connecting component for coupling the planes of the wing and the fuselage. The connecting component is able to accommodate a substantial relative rotation between the first plane and the fuselage. The vehicle further includes a plurality of wheels coupled to the bottom side of the fuselage.

Abstract: An aircraft structure is provide, an aircraft structure for an aircraft. Including front wings And rear wings of the Swan-Wings, vertical winglets and the first level floor body. The Fuselage has a cross-section of substantially flat fuselage shape being is wide enough to Provide lifting force. The front wings of the Swan-Wings are disposed horizontally in Front portion of the fuselage. The rear wings of the Swan-Wings are disposed Horizontally in rear portion of the fuselage. The vertical winglets are disposed at the top of the rear fuselage. The first level disposed fuel tank storages, a plurality of landing gear bays, cockpits with Control panels, various avionics and cabin doors. The top of the rear fuselage disposed jet power plants, the fuselage provide lifting force And the wings provides steering force and lifting force the whole structure of an aircraft Comprises carbon fiber honey comb composite molded structure which lighter weight And shear strong structure. The cockpit and cabins disposed.

Abstract: This apparatus is a new VTOL roadable aircraft having fore and aft sections joined by a seating midsection; with compact inlets built into its fuselage, also pairs of flight stabilizing surfaces and tail fins; the fuselage structure being a Lifting Body that provides aerodynamic lift during both forward flight and vertical descent; provided with intake chambers containing propelling surfaces rotating on longitudinal axis in opposite senses, and external pairs of swiveled nozzles producing thrust vectoring; these nozzles using conventional devices and having spins directed by original controls of corresponding identical movement directions; with standard automobile equipment integrated with the vehicle compact design and dimensions, making it compatible for road transport and enabling direct transitions to flight mode; and safe landing systems for emergencies are provided with half the technology being off the shelf devices as those in use by NASA and the US Airforce.

Abstract: A road driving and flight vehicle is able to automatically convert between two configurations to facilitate operations as an automobile and as an aircraft. In flight configuration the craft includes two jet engines at rear body part, two wings with ailerons produced by open/flap upwardly doors where the upper end is hinged to a body and bottom end raised up to place wings horizontally, and a vertical stabilizer with rudder and two horizontal stabilizers with elevators. In road driving configuration vehicle includes conventional automobile power plant in front part of the body, four wheels of which two front wheels are steerable, two doors, and a vertical and two horizontal stabilizers are stored at rear part of the body.

Abstract: A vehicle that can operate as either a motorcycle or an autogiro, said vehicle having a flight mode and a motorcycle mode, said vehicle comprising: a frame having a front part and a rear part; a center-line that passes from the front of said vehicle to the rear of said vehicle through the center of said vehicle such that said vehicle's weight is distributed nearly equally to either side of said center-line; a propeller mounted to a propeller barrel that is rotatably mounted to said frame such that the junction where said frame's front part meets said frame's rear part is located within said propeller barrel; an engine mounted to the rear part of said frame, wherein said engine powers said propeller in said flight mode; a cockpit fixedly mounted to the front part of said frame, said cockpit comprising means for controlling said vehicle; at least one aircraft lift means comprising: at least one rotor that is rotatably mounted to said frame when said vehicle is in said flight mode; a front wheel steerably and

Abstract: An apparatus for removing harmful gas components out of the earth's atmosphere is a free-flying autonomous lightweight aircraft with an onboard gas processing system including gas separation or extraction devices, and inlets and outlets connected to the devices. Solar cells and/or thermoelectric generators provided on the craft produce electrical energy to operate the individual devices. The system may include a cryogenic closed-loop circulation system that participates in liquefying the extracted gas components. The apparatus is preferably a lighter-than-air craft like a dirigible. A method of extracting harmful gas components from the atmosphere involves flying the apparatus at a prescribed altitude level and operating the gas processing system to remove the harmful gas component from the atmosphere, then returning the apparatus to earth to offload the liquefied stored harmful gas component.

Abstract: An aircraft comprising a fuselage, a vessel associated with the fuselage, a propulsion system associated with the fuselage, and a lift system. The vessel is capable of storing a pressurized gas compressed to a density that allows the aircraft to operate under water. The lift system is capable of providing the aircraft lift to fly in air.

Abstract: A transforming unmanned aerial-to-ground vehicle assembly comprising: an aerodynamic flying assembly comprising an unmanned aerial vehicle integrated with an unmanned ground vehicle, a power unit shared by the unmanned aerial vehicle and the unmanned ground vehicle, vehicle controls shared by the unmanned aerial vehicle and the unmanned ground vehicle, a disengagement mechanism to separate the unmanned ground vehicle from the unmanned aerial vehicle, one or more manipulator arms located on either the unmanned aerial vehicle or the unmanned ground vehicle, and landing gear.

Abstract: Systems and/or methods for forming a multiple-articulated flying system (skybase) having a high aspect ratio wing platform, operable to loiter over an area of interest at a high altitude are provided. In certain exemplary embodiments, autonomous modular flyers join together in a wingtip-to-wingtip manner. Such modular flyers may derive their power from insolation. The autonomous flyers may include sensors which operate individually, or collectively after a skybase is formed. The skybase preferably may be aggregated, disaggregated, and/or re-aggregated as called for by the prevailing conditions. Thus, it may be possible to provide a “forever-on-station” aircraft.

Abstract: The invention is an unmanned flying helicopter aircraft platform (“aircraft platform”) that can be powered by either interchangeable electric motors or by fuel powered internal combustion engines. The aircraft platform is surrounded by a lightweight exoskeleton cage that protects the rotor blades from coming into contact with external objects. The aircraft platform uses a weight located on the bottom side of the aircraft platform that can be remotely moved to adjust the center of gravity in order to navigate in any direction. The aircraft platform has a place on its bottom side where attachments can be added or removed which allows the aircraft platform to be used for multiple different purposes. The aircraft platform can be flown and operated either remotely using a hand held control unit or it can be flown and operated by an onboard pilot located in the human carrying attachment.

Abstract: A ducted fan air vehicle and method of operation is disclosed for obtaining aerodynamic lift and efficiency in forward flight operation without significantly impacting hover stability. One or more retractable wings are included on the ducted fan air vehicle and are deployed during forward flight to provide aerodynamic lift. The wing or wings are retracted when the vehicle hovers to reduce the impact the wings have on stability in a wind. Each wing may conform to the curvature or profile of the vehicle when retracted, and may be constructed in one or more wing sections. The wing or wings may be deployed and retracted automatically or at the command of an operator. Each wing and related components may be integrated into the vehicle or may be detachable.

Abstract: To fly kite requires wind and skill. Balloon kite can fly high with no wind. To fly balloon kite requires no skill. You do not have to be an expert to fly balloon kite. In a year only windy season is suitable for flying kite. With balloon kite every day is a flying kite day and every child can fly it. Children can enjoy flying balloon kite all year round.

Abstract: The invention discloses a new method for controlling lifting force of an aerovane fan and a helicar utilizing this method. The method directly controls airflow rate enter a duct (Collar, culvert pipe, in which has the aerovanes fans), using an airflow valve that can be opening or closed by a rotating operation, so to control lifting force. The airflow valve has double layer perforated the hemisphere hulls or hemi-ellipsoid hulls in shape. A simple and practical helicar is designed on the basis of this method.

Abstract: A space vehicle and its launcher are capable of low-cost launch, safe maneuvering, plus powered go-around for landing.

Abstract: A reconfigurable aircraft and associated methods. In one embodiment the reconfigurable aircraft comprises a plurality of payload retainers. The payload retainers are configured to receive and retain payloads, including fuel, armaments and sensors. The aircraft is configured to cooperate in flight with an airborne supply vehicle to receive the payloads from the supply vehicle.

Abstract: A system including a heavier-than-air vehicle (HTA), a lighter-than-air vehicle (LTA), and a tether is disclosed. The tether is coupled between the HTA and the LTA such that the LTA supports the HTA. The system may be further configured to suit the needs of the particular application. For example, the system may be configured to be controllable from a remote location or capable of autonomous operations. The system may also be configured such that the HTA comprises a mission payload and communications equipment. In an exemplary embodiment of the invention, the LTA is configured to provide lift for the system and the HTA is configured to provide station-keeping propulsion, the advantage being reduced fuel consumption and increased mission endurance.

Abstract: The present invention provides a system for reconnaissance using autonomous unmanned airborne vehicles (UAV). The system comprises a mothership, which is generally a fixed wing fuel tank capable of providing a suitable surface for flight (lift) and one or more elements for attachment of individual UAVs. The system further comprises one or more UAVs that are detachably connected to the mothership, and which are independently controllable for reconnaissance and tracking. The system and its individual parts are reusable and independently controllable, permitting low cost reconnaissance over wide areas of geography.