A tracked, amphibious vehicle, provides at least two, spaced, elongated pontoons disposed generally parallel to one another. A platform structure can be supported by and structurally connects the pontoons, the platform structure including a transom and a lowermost generally horizontally extending panel. A continuous, endless belt can encircle each pontoon engaging bogie wheels on the pontoon. A supplemental, marine drive assembly includes a hydraulic motor having a shaft with an axis, a propeller shaft having an axis, wherein the motor axis and propeller axis are aligned. A universal joint connects the hydraulic motor to the transom. A housing includes a sleeve that contains the propeller shaft.

A vertical takeoff and landing craft that utilizes lifting, propulsion and maneuvering (LPM) assemblies comprising a series of blade foils arranged along track elongated loop paths disposed at the sides of a fuselage. These LPM assemblies are provided with control mechanisms enabling lift, attitude changes, altitude changes and directional flight propulsion and control including those needed for hovering as well as vertical takeoff and landing. The LPM assemblies are configured to drive large volumes of air in a manner and scale favorably similar to conventional rotorcraft while in contrast, providing capability for faster flights by eliminating or minimizing speed limiting factors commonly associated with rotorcraft.

A vertical takeoff and landing craft that utilizes lifting, propulsion and maneuvering (LPM) assemblies comprising a series of blade foils arranged along track elongated loop paths disposed at the sides of a fuselage. These LPM assemblies are provided with control mechanisms enabling lift, attitude changes, altitude changes and directional flight propulsion and control including those needed for hovering as well as vertical takeoff and landing. The LPM assemblies are configured to drive large volumes of air in a manner and scale favorably similar to conventional rotorcraft while in contrast, providing capability for faster flights by eliminating or minimizing speed limiting factors commonly associated with rotorcraft.

An unmanned ocean vehicle apparatus having a hull, solar array, hydrofoil, and electric thruster is operable on a surface of a body of water to travel from one point to another with long range capabilities. The unmanned ocean vehicle can further be placed in a more compact configuration, incorporating a mechanism to alternate between operational mode and collapsed storage mode to facilitate physical storage or shipment of the vehicle. Methods are described for optimizing travel and determining favorable movements of the unmanned ocean vehicle by calculating current and predicted conditions at certain waypoints using a combination of a sensor, a computer, and a control system. The physical support of hydrofoils, a drag reducing system, capsize-prevention technique, and a three-dimensional arrangement of solar panels provides efficient power management, optimal route strategy, and sustainability of the vehicle's high speeds in wildly varying ocean conditions.

An unmanned ocean vehicle apparatus having a hull, solar array, hydrofoil, and electric thruster is operable on a surface of a body of water to travel from one point to another with long range capabilities. The unmanned ocean vehicle can further be placed in a more compact configuration, incorporating a mechanism to alternate between operational mode and collapsed storage mode to facilitate physical storage or shipment of the vehicle. Methods are described for optimizing travel and determining favorable movements of the unmanned ocean vehicle by calculating current and predicted conditions at certain waypoints using a combination of a sensor, a computer, and a control system. The physical support of hydrofoils, a drag reducing system, capsize-prevention technique, and a three-dimensional arrangement of solar panels provides efficient power management, optimal route strategy, and sustainability of the vehicle's high speeds in wildly varying ocean conditions.

A device for driving a primary shaft, the device including: a first system including an element for driving movement of a control member along a looped trajectory having two axial components; a second system including an element for pivoting the shaft about its longitudinal axis, actuated by the movement of the member along at least one component of the looped trajectory; a third system including an element for driving movement of the shaft, actuated by the movement of the control member along at least the other component of the looped trajectory, the control member projecting from the plane of the components and engaged with both the driving element for pivoting and for moving of the shaft, the movement of the control member along the looped trajectory generating a pivoting of the shaft in alternating directions and its movement in alternating directions.

A device for driving a primary shaft, the device including: a first system including an element for driving movement of a control member along a looped trajectory having two axial components; a second system including an element for pivoting the shaft about its longitudinal axis, actuated by the movement of the member along at least one component of the looped trajectory; a third system including an element for driving movement of the shaft, actuated by the movement of the control member along at least the other component of the looped trajectory, the control member projecting from the plane of the components and engaged with both the driving element for pivoting and for moving of the shaft, the movement of the control member along the looped trajectory generating a pivoting of the shaft in alternating directions and its movement in alternating directions.