A system and methods for generating one or more flight management strips presentable to a viewer on a display unit are disclosed. The flight management strip generating system may include a flight management system (FMS) and an event generator (EG). The EG may be configured to receive flight management data and generate event data representative of a flight management strip(s). In some embodiments, each flight management strip may be informative of FMS event(s) and comprised of a first row, a plurality of second rows, and one or more third rows. In some embodiments, a first flight management strip or at least one second management strip is informative of one FMS event and comprised of a plurality of rows. First rows may be reserved for a display of time(s), second rows for the display of FMS event(s), and third rows for the display of an FMS mode.

An unmanned aircraft structure evaluation system includes a computer system with an input unit, a display unit, one or more processors, and one or more non-transitory computer readable medium. Image display and analysis software causes the one or more processors to generate unmanned aircraft information. The unmanned aircraft information includes flight path information configured to direct an unmanned aircraft to fly a flight path around the structure.

A method for allowing missions of unmanned aerial vehicles (UAV), in particular in non-segregated air space, includes the steps of: prearranging a flight plan by an operator of an unmanned aerial vehicle; verifying, by a management and control body, that the flight plan is compatible with other flight plans of other aerial vehicles, and, if necessary, modifying the flight plan so as to prevent any collisions with the other aerial vehicles, wherein the following steps are carried out: encrypting the flight plan, by the management and control body, with a private key of the management and control body, so as to obtain an encrypted flight plan; encoding the encrypted flight plan with a public key of the unmanned aerial vehicle for which the flight plan is intended, so as to obtain an encrypted and encoded flight plan.

A method for operating a distributed flight management system. The method includes operating a control station instance of the distributed flight management system. The method includes receiving flight management system data from a remotely accessed vehicle. The method includes receiving time-space-position information of the remotely accessed vehicle from the remotely accessed vehicle. The method includes updating the control station instance of the distributed flight management system based at least on the received flight management system data and the time-space-position information of the remotely accessed vehicle. The method includes outputting updated flight management system data for transmission to the remotely accessed vehicle to synchronize a remotely accessed vehicle instance of the distributed flight management system with the control station instance of the distributed flight management system.

An unmanned aerial vehicle with lift and propulsion system and a flight control system and method. The flight control system has a flight control unit, a navigation system, a communication system and an actuator system. The flight control unit can calculate, based on data from the navigation system and/or data of a ground control station, control commands which can be fed to the actuator system for actuating the lift and propulsion system. The ground control station is configured to control and/or monitor the aerial vehicle. The aerial vehicle has a monitoring unit to monitor the communication system to determine whether all the communication links are interrupted. The monitoring unit can cause the flight control unit to land the aerial vehicle safely at a suitable landing site based on stored data relating to current flight conditions and nearby landing sites.

A system and method of generating optimised aircraft flight trajectories on Flight Management Systems with limited computational power that takes into account developing operational conditions, air traffic constraints and aircraft performance in a timely manner on the flight management system that can allow tactical flight plan changes to be incorporated without unduly introducing operational or financial penalties to the operator. An example method involves parameterisation of optimal trajectories as functions of operational parameters thereby allowing computational systems to use such computed functions in the air to determine the optimal trajectory or flight profile required for the specific operating conditions quickly and accurately.

A method for en-route flight path optimization is disclosed. A plurality of alternate flight paths between an origin and a destination of the aircraft in flight is determined based on real-time weather data air traffic conflict data, and air space constraint data. Further, flight time savings and fuel savings for each of the plurality of alternate flight paths with respect to an actual path is computed. Furthermore, an optimal flight path from the plurality of alternate flight paths is determined based on the computed flight time savings, fuel savings, and a priority for the flight time savings and the fuel savings.

A method for managing a premature descent envelope during descent of an aircraft is provided. The method receives glideslope deviation data by an instrument landing system (ILS) onboard the aircraft; compares, by the ILS, the glideslope deviation data to an acceptable band of glideslope deviation values; and when the glideslope deviation data is within the acceptable band, expands, by a terrain awareness and warning system (TAWS), the premature descent envelope to produce an increased premature descent envelope for the aircraft.

The DYNAMIC TURBULENCE ENGINE CONTROLLER APPARATUSES, METHODS AND SYSTEMS (DTEC) transform weather, terrain, and flight parameter data via DTEC components into turbulence avoidance optimized flight plans. In one implementation, the DTEC comprises a processor and a memory disposed in communication with the processor and storing processor-issuable instructions to receive anticipated flight plan parameter data, obtain terrain data based on the flight plan parameter data, obtain atmospheric data based on the flight plan parameter data, and determine a plurality of four-dimensional grid points based on the flight plan parameter data. The DTEC may then determine a non-dimensional mountain wave amplitude and mountain top wave drag, an upper level non-dimensional gravity wave amplitude, and a buoyant turbulent kinetic energy. The DTEC determines a boundary layer eddy dissipation rate, storm velocity, and eddy dissipation rate from updrafts, maximum updraft speed at grid point equilibrium level and storm divergence while the updraft speed is above the equilibrium level and identify storm top. The DTEC determines storm overshoot and storm drag, Doppler speed, eddy dissipation rate above the storm top, and determine eddy dissipation rate from downdrafts. The DTEC then determines the turbulent kinetic energy for each grid point and identifies an at least one flight plan based on the flight plan parameter data and the determined turbulent kinetic energy.

The trajectory coming from a planned trajectory, managed by a system, and from at least one trajectory section sent by a third party system to the system, the method at least comprises: a preliminary step in which a knowledge base is produced comprising the calculation parameters and their field of use for the moving object, several envelopes of parameters being defined within the field of use corresponding to different operational constraints of the moving object; a first step in which the system initializes the planned trajectory according to the parameters of the preliminary step, the calculation parameters of the planned trajectory being contained in one of the envelopes; a second step in which the system receives a trajectory section sent by the third party system in order to be inserted in the planned trajectory by replacing a part of the trajectory; a third step in which the received and accepted section is simplified by segmentation in such a way that its calculation parameters are contained in the at least one of the envelopes; the system carrying out calculations on the basis of the simplified trajectory.