Flight deck display systems and methods for generating cockpit displays including dynamic taxi turnoff icons are provided. In one embodiment, the flight deck display system includes a display device, a memory storing an airport map database, and a controller operably coupled to the display device and to the memory. The controller is configured to recall information from the airport map database pertaining to a runway cleared for usage by the aircraft. The controller further identifies a taxi exit along the runway based, at least in part, on the information recalled from the airport map database. The controller then generates a dynamic taxi turnoff icon on the display device including symbology representative of the runway and the location of the taxi exit along the runway.

A computing system for landing and storing vertical take-off and landing (VTOL) aircraft can be configured to receive aircraft data, passenger data, or environment data associated with a VTOL aircraft and determine a landing pad location within a landing facility based on the aircraft data, passenger data, and/or environment data. The landing facility can include a lower level and an upper level. The lower level can include a lower landing area and a lower storage area. The upper level can include an upper landing area. At least a portion of the upper level can be arranged over the lower storage area. The landing pad location can include a location within the lower landing area or the upper landing area of the landing facility. The computing system can communicate the landing pad location to an operator or a navigation system of the VTOL aircraft.

Systems and methods of the present invention are provided to generate a plurality of flight trajectories that do not conflict with other aircraft in a local area. Interventions by an air traffic control system help prevent collisions between aircraft, but these interventions can also cause an aircraft to substantially deviate from the pilot's intended flight trajectory, which burns fuels, wastes time, etc. Systems and methods of the present invention can assign a standard avoidance interval to other aircraft in the area such that a pilot's aircraft does not receive an intervention by an air traffic control system. Systems and methods of the present invention also generate a plurality of conflict-free flight trajectories such that a pilot or an automated system may select the most desirable flight trajectory for fuel efficiency, speed, and other operational considerations, etc.

The invention consists of an actuated box and navigation aid for automatic delivery by unmanned vehicles (UAV) or drones. It also incorporates delivery information via the web linking orders, enclosure status, package specific drone homing signals, delivery confirmations and more.

This system incorporates a novel and effective means for providing a standardized and predicable area for safe landing during delivery by functionalized drones. It also secures the package from theft, vandalism, animals and the weather and provides features necessary for air-traffic management.

A device for determining navigation parameters of an aircraft during a landing phase includes a video system including at least one digital video camera arranged on the aircraft, the digital video camera being configured to generate on the aircraft current video data relating to at least one characteristic point on the Earth, whose coordinates are known, and a data processing unit including an extended Kalman filter and configured to determine the navigation parameters on the basis of current navigation data of the aircraft, arising from a satellite navigation system, current inertial data of the aircraft, as well as said video data.

A system for piloting an aircraft during an autonomous approach for the purpose of landing. The piloting system has a flight guidance computer that directly computes, with the aid of a position indication and of information characterizing a virtual approach axis, linear deviations. Another computer computes aircraft piloting instructions using the linear deviations.

An estimation unit including an element for computing an actual distance, representing the distance covered by the aircraft over at least one speed interval delimited between two speeds of the aircraft, the interval corresponding to rollout on a segment of the runway, for which the braking performance of the aircraft is limited by the friction of the runway, an element for computing a plurality of so-called reference distances corresponding to various runway states, an element for comparing the actual distance with the reference distances, and an element for selecting, on the basis of these comparisons, one of the reference distances, the runway state which corresponds to the reference distance thus selected representing the runway state determined by the device.

A flight management system that manages flight of an unmanned aircraft flying according to a flight plan. The flight management system including at least one unmanned aircraft that holds shared information in which transmission information including identification information, position information, and time information about the unmanned aircraft and flight plan information including a flight plan are associated with each other and that flies according to the flight plan while transmitting the transmission information at a predetermined timing, and a flight management device that shares the shared information with the unmanned aircraft to be managed and that acquires the transmission information transmitted from the unmanned aircraft flying according to the flight plan to update the shared information.

A flight management system that manages flight of an unmanned aircraft flying according to a flight plan. The flight management system including at least one unmanned aircraft that holds shared information in which transmission information including identification information, position information, and time information about the unmanned aircraft and flight plan information including a flight plan are associated with each other and that flies according to the flight plan while transmitting the transmission information at a predetermined timing, and a flight management device that shares the shared information with the unmanned aircraft to be managed and that acquires the transmission information transmitted from the unmanned aircraft flying according to the flight plan to update the shared information.

A signal transmitting device is provided for communicating with an aircraft in the vicinity of a landing area. The signal transmitting device is configured to receive a signal from the aircraft and further configured to transmit a return signal to the aircraft automatically upon receipt of the signal. The return signal comprises information regarding the landing area.