A method of controlling an aircraft in the event of pilot incapacity includes detecting, using at least one sensor, the occurrence of an event relating to a pilot's capacity to control the aircraft, determining whether the event justifies a controlled takeover of the aircraft from the pilot, asserting a controlled takeover of the aircraft from the pilot if it has been determined that a controlled takeover is justified, and executing a controlled landing of the aircraft without assistance of the pilot.

A system for augmented pilot operations is provided to perform checks and balances between navigable systems and a plurality of controlling parties of a Fly-By-Wire vehicle. A ground based control system having at least one of manual controls and an autonomous piloting system, an electronic communication system including at least one of an onboard communication system, a ground based communication system, and a programmable interface for inter party communication. An on board flight control system including at least one of a primary power unit, manual flight controls, and a programmable flight management system may be provided. An onboard auxiliary navigation system including at least one of an auxiliary power control unit, a ground operated control/navigation unit, a physical barrier may prevent manual override from within the plane or cockpit, and an assignment device. A disagreement detection system may be configured to detect unauthorized use of the Fly-By-Wire vehicle.

A method of controlling an aircraft in the event of pilot incapacity includes detecting, using at least one sensor, the occurrence of an event relating to a pilot's capacity to control the aircraft, determining whether the event justifies a controlled takeover of the aircraft from the pilot, asserting a controlled takeover of the aircraft from the pilot if it has been determined that a controlled takeover is justified, and executing a controlled landing of the aircraft without assistance of the pilot.

Communication method for an aircraft (1) comprising the steps of: installing a security system (100 or IDDS) in a non-pressurized zone (2) of the aircraft (1), said security system (100) comprising a GPS localization device (101) with satellite link and an autonomous battery (102);detecting in the GPS localization device (101) at least one position (A) of the aircraft;sending the position (A) to a control station (200) interconnected with the satellite link; said steps of detecting and sending the position (A) being performed if an anomaly is detected.

A system for augmented pilot operations is provided to perform checks and balances between navigable systems and a plurality of controlling parties of a Fly-By-Wire vehicle. A ground based control system having at least one of manual controls and an autonomous piloting system, an electronic communication system including at least one of an onboard communication system, a ground based communication system, and a programmable interface for inter party communication. An on board flight control system including at least one of a primary power unit, manual flight controls, and a programmable flight management system may be provided. An onboard auxiliary navigation system including at least one of an auxiliary power control unit, a ground operated control/navigation unit, a physical barrier may prevent manual override from within the plane or cockpit, and an assignment device. A disagreement detection system may be configured to detect unauthorized use of the Fly-By-Wire vehicle.

A system includes a first terminal configured to transmit control data to a controlled terminal via a first communication link for controlling operation of the controlled terminal, and a second terminal configured to transmit control data to the controlled terminal via a second communication link for controlling operation of the controlled terminal. The second terminal is further configured to, in response to the first communication link being under interference, receive the control data from the first terminal via a third communication link and transmit the control data received from the first terminal to the controlled terminal via the second communication link.

An apparatus comprising a system with an array of sensors, sound and light emitting and receiving devices having at least one object control from a monitored object comprised of an operator, a patient, an animal, or machine, control of at least one performance parameter of the system; at least one iris/retina biometric sensor; at least one physiological iris/pupil sensor; at least one infinite random light emitter; said at least one iris/pupil biometric sensor; said at least one physiological pupil sensor and said one infinite random light emitter operatively connected and synchronized communication with each other utilizing at least one central processing unit; said at least one biometric sensor and said at least one physiological sensor delivering a parallel array of sensory readings to said central processing unit; said central processing unit capable of detecting a normal or an abnormal sensory reading; said at least one central processing unit capable of effecting said at least one performance parameter in response to said sensory reading; and said central processing unit recording said sensory reading on a storage medium to be used for identifying and detection of said alive status and health condition of the monitored object in real time.

A computer-implemented method for protecting a vehicle from a directed energy attack is provided. The method includes receiving, at the vehicle, a beam of directed energy, determining a threat level of the beam of directed energy, and causing the vehicle to automatically execute at least one evasive maneuver when the threat level of the beam of directed energy is greater than a predetermined threshold.

Embodiments herein describe a perch for screening drones before permitting access to a restricted geographic region. The perch may include various scanners for evaluating the payload of the drone, its hardware, and flight control software. In one embodiment, the screening perch includes a conveyor belt that moves the drone through various scanners or stages in the perch. In one embodiment, the perch ensures the drone is properly configured to enter the restricted geographic region. The region may include multiple requirements or criteria that must be satisfied before a drone is permitted to enter. For example, the drone may need a signed flight plan, cargo that is less than a certain percentage of its weight, or an approved flight controller before being permitted into the restricted region. In this manner, the perch serves as a controlled entrance point for drones attempting to enter the restricted region.

In some embodiments, a control manager is disposed between the rotor system and the flight control inceptor. The control manager is configured to receive control commands wirelessly from a ground control station, translate the control commands into one or more axes associated with the flight control inceptor, and transmit the translated control commands to the rotor system in place of the instructions received from the pilot via the flight control inceptor.