An adaptive aerial vehicle includes a vehicle support, at least one frame assembly mounted relative to the support, at least one propulsion unit mounted to the frame assembly and operable to move the adaptive aerial vehicle, and an actuator configured to move the support relative to the frame assembly to redistribute the weight of the adaptive aerial vehicle.

Methods and apparatus of tracking moving targets from air vehicles are disclosed. An example method in response to an estimated speed and an estimated location of a moving target, determines a detectability zone surrounding the moving target; and causes an air vehicle to follow the moving target outside of the detectability zone.

Various embodiments include methods for operating a photovoltaic-powered drone having a photovoltaic surface on one side of at least one of wing or fuselage body of the drone. The method may include determining a flight attitude for the drone based on a first drone attitude for optimizing light energy harvesting by the photovoltaic surface and a second drone attitude for minimizing power expenditure by an onboard propulsion system of the drone to reach a designated destination. The method may include flying the drone in the determined flight attitude while converting light into electricity en route to the designated destination.

The universal vehicle system is designed with a lifting body which is composed of a plurality of interconnected modules which are configured to form an aerodynamically viable contour of the lifting body which including a front central module, a rear module, and thrust vectoring modules displaceably connected to the front central module and operatively coupled to respective propulsive mechanisms. The thrust vectoring modules are controlled for dynamical displacement relative to the lifting body (in tilting and/or translating fashion) to direct and actuate the propulsive mechanism(s) as needed for safe and stable operation in various modes of operation and transitioning therebetween in air, water and terrain environments.

A system includes: a lower sail module; an upper sail module; and a bridle assembly. The lower sail module defines a first edge and a second edge and includes: a first control surface extending between the first edge and the second edge; a set of payload instruments; and a motorized spool arranged proximal the second edge of the lower sail module. The upper sail module: is arranged above the lower sail module; defines a third edge and a fourth edge and includes; and includes a second control surface extending between the third edge and the fourth edge. The bridle assembly includes: a set of fixed sail cables coupling the upper sail module to the first control surface proximal the first edge; and a sail control cable wound about the motorized spool and coupling the upper sail module to the first control surface proximal the second edge.

A system includes: a lower sail module; an upper sail module; and a bridle assembly. The lower sail module defines a first edge and a second edge and includes: a first control surface extending between the first edge and the second edge; a set of payload instruments; and a motorized spool arranged proximal the second edge of the lower sail module. The upper sail module: is arranged above the lower sail module; defines a third edge and a fourth edge and includes; and includes a second control surface extending between the third edge and the fourth edge. The bridle assembly includes: a set of fixed sail cables coupling the upper sail module to the first control surface proximal the first edge; and a sail control cable wound about the motorized spool and coupling the upper sail module to the first control surface proximal the second edge.

A system and method for controlling a tail-sitter aircraft, includes determining a mode of operation for the aircraft; operating each of a large turbine engine and a small turbine engine to provide total aircraft power during hover or high-power mode of operation; and selectively providing aircraft power from the small turbine engine to a plurality of rotors during a long-range endurance cruise mode of operation.

Methods and apparatus of tracking moving targets from air vehicles are disclosed. An example method in response to an estimated speed and an estimated location of a moving target, determines a detectability zone surrounding the moving target; and causes an air vehicle to follow the moving target outside of the detectability zone.

A method, an unmanned mobile entity and a computer program are provided for evaluating a performance of a first sensor unit which is arranged to measure a physical property of its environment at a location. An unmanned mobile entity transports a reference sensor unit to the location and the reference sensor unit is arranged to measure the physical property at the location. The performance of the first sensor unit is evaluated based on a comparison of the measurements of the first and reference sensor units.

A method, an unmanned mobile entity and a computer program are provided for evaluating a performance of a first sensor unit which is arranged to measure a physical property of its environment at a location. An unmanned mobile entity transports a reference sensor unit to the location and the reference sensor unit is arranged to measure the physical property at the location. The performance of the first sensor unit is evaluated based on a comparison of the measurements of the first and reference sensor units.