An adjustable foil having a suction surface and a pressure surface. The foil comprises an adjustable internal frame comprising a base, a plurality of articulately connected sections forming the suction surface of the foil, arranged consecutively from the leading edge of the foil to the trailing edge of the foil, and a plurality of frame struts, each articulately connected to the base and to a section of the plurality of sections. The foil is movable from a collapsed configuration to an expanded configuration by rotating the frame struts with respect to the base.

An adjustable foil having a suction surface and a pressure surface. The foil comprises an adjustable internal frame comprising a base, a plurality of articulately connected sections forming the suction surface of the foil, arranged consecutively from the leading edge of the foil to the trailing edge of the foil, and a plurality of frame struts, each articulately connected to the base and to a section of the plurality of sections. The foil is movable from a collapsed configuration to an expanded configuration by rotating the frame struts with respect to the base.

A vertical take-off and landing (VTOL) aircraft, that may be incorporated into a personal automobile, comprises a rectangular wing including an upper wing section having a right upper wing side and a left upper wing side, a lower wing section having a right lower wing side and left lower wing side, a right vertical wing section coupled to the right upper wing side and to the right lower wing side, and a left vertical wing section coupled to the left upper wing side and to the left lower wing side, the upper wing section having an upper wing cross section with a first asymmetrical airfoil shape configured to cause lift when in forward flight, the lower wing section having a lower wing cross section with a second asymmetrical airfoil shape for causing lift when in forward flight, each of the right vertical wing section and the left vertical wing section having a vertical wing cross section with a symmetrical shape to cause lateral stability when in forward flight; two elevons on at least one of the upper wing section and the lower wing section; at least one rudder on each of the right vertical wing section and the left vertical wing section; a support frame coupled to the rectangular wing; and a propulsion system coupled to the support frame.

A vertical take-off and landing (VTOL) aircraft, that may be incorporated into a personal automobile, comprises a rectangular wing including an upper wing section having a right upper wing side and a left upper wing side, a lower wing section having a right lower wing side and left lower wing side, a right vertical wing section coupled to the right upper wing side and to the right lower wing side, and a left vertical wing section coupled to the left upper wing side and to the left lower wing side, the upper wing section having an upper wing cross section with a first asymmetrical airfoil shape configured to cause lift when in forward flight, the lower wing section having a lower wing cross section with a second asymmetrical airfoil shape for causing lift when in forward flight, each of the right vertical wing section and the left vertical wing section having a vertical wing cross section with a symmetrical shape to cause lateral stability when in forward flight; two elevons on at least one of the upper wing section and the lower wing section; at least one rudder on each of the right vertical wing section and the left vertical wing section; a support frame coupled to the rectangular wing; and a propulsion system coupled to the support frame.

A vertical take-off and landing (VTOL) aircraft has a first drivable configuration in which the pilot seat is positioned between the wings and facing the direction of forward travel. The VTOL may be driven in the first configuration as a normal automobile. In the first configuration the wings are aligned with the direction of forward travel and their surfaces are vertically oriented. In the first configuration, the VTOL may also attain altitude and be maneuvered using thrust from propulsion sources. In a second configuration, the pilot seat is rotated 90 degrees from the direction of forward travel to a direction of forward flight. Forward flight is achieved using thrust to rotate the wings from the vertical orientation to a lift-providing orientation. In concert with the rotation of the wings, the pi lot seat is counter-rotated to maintain the seat facing the direction of forward flight.

A vertical take-off and landing (VTOL) aircraft has a first drivable configuration in which the pilot seat is positioned between the wings and facing the direction of forward travel. The VTOL may be driven in the first configuration as a normal automobile. In the first configuration the wings are aligned with the direction of forward travel and their surfaces are vertically oriented. In the first configuration, the VTOL may also attain altitude and be maneuvered using thrust from propulsion sources. In a second configuration, the pilot seat is rotated 90 degrees from the direction of forward travel to a direction of forward flight. Forward flight is achieved using thrust to rotate the wings from the vertical orientation to a lift-providing orientation. In concert with the rotation of the wings, the pi lot seat is counter-rotated to maintain the seat facing the direction of forward flight.

Morphable active corrugate structure and aeronautical wings are provided herein including one or more skins or envelopes, and a sheet having independently actuable hinge domains attached to the one or more skins or envelopes and independently actuable facet domains, each of the hinge domains and facet domains configured with through-thickness differential expansion coefficients, wherein differential strains in at least one of the hinge domains or the facet domains cause the sheet to expand or contract along a flexible axis of the sheet, wherein the sheet is attached to the upper and lower skins at respective upper and lower of the hinge domains.

Morphable active corrugate structure and aeronautical wings are provided herein including one or more skins or envelopes, and a sheet having independently actuable hinge domains attached to the one or more skins or envelopes and independently actuable facet domains, each of the hinge domains and facet domains configured with through-thickness differential expansion coefficients, wherein differential strains in at least one of the hinge domains or the facet domains cause the sheet to expand or contract along a flexible axis of the sheet, wherein the sheet is attached to the upper and lower skins at respective upper and lower of the hinge domains.

Wing-in-ground effect (WIG) vehicles are disclosed herein. Hovercraft takeoff and landing modes are disclosed herein. Uses of WIG vehicles, including for maritime monitoring, are disclosed herein.

Wing-in-ground effect (WIG) vehicles are disclosed herein. Hovercraft takeoff and landing modes are disclosed herein. Uses of WIG vehicles, including for maritime monitoring, are disclosed herein.