Abstract: A method of restoring navigational performance for a navigational system, the method comprising receiving by a first navigational system and a second navigational system a collection of data points to establish a real-time navigational route for the aircraft, comparing navigational performance values and/or drift ranges and establishing a new navigational route based on the collection of data points.

Abstract: An apparatus and method for establishing air data. An aircraft progresses while a processing module receives speed data from at least one sensor. The processing module can determine an actual airspeed of the aircraft based on the speed data. The processing model can also receive sensed real-time airspeed data for comparison to the actual airspeed. The comparison can automatically initiate a countermeasure.

Abstract: A method of adjusting an operator workload during a travel segment including tracking over a time period, using at least one sensor, one of inputs by an operator indicative of an operator workload or image sensor data or a biometric parameter indicative of an operator stress level during the travel segment. Determining, using a controller that is operatively connected to the at least one sensor, a level of one of the operator workload or operator stress level. The method also includes adjusting, using a controller that is operatively connected to the control computer, the operator workload when the level of one of the operator workload or operator stress level exceeds a predetermined threshold.

Abstract: A method of controlling an aircraft includes tracking, using at least one sensor, one of an input by a pilot or a biometric parameter of a first pilot during flight of the aircraft. The method also includes determining a lack of attention by the pilot or a depth of sleep of the pilot based on the biometric parameter.

Abstract: A method for identifying ghost aircraft and a system for displaying information in an aircraft including a flight display onboard the aircraft and configured to display a visual expression of at least some air traffic information and an interrogation module configured to determine information about an other aircraft based on the identification address to define interrogated data, determine real-time information about the other aircraft, compare the real-time information and the interrogated data and update the flight display based on the comparison.

Abstract: A method and apparatus for recording flight information of aircraft, such as position, mass, or type, in order to record the position of a wake turbulence of the aircraft. Weather information can be recorded as affecting the wake turbulence. Such information can be provided into a model or algorithm to determine a path of a wake turbulence. An aircraft on a flight path to encounter the wake turbulence can determine a vortex magnitude of the wake turbulence and determine if an advisory alert needs to be provided if the vortex magnitude satisfies a predetermined threshold.

Abstract: A tool verification system and a method of verifying an unqualified component includes receiving communications between a tool and an unverified component, comparing the communications with a previously-qualified set of communications, and determining whether the unqualified component can be qualified based on the comparison.

Abstract: Route planning and movement of an aircraft on the ground based on a navigation model trained to improve aircraft operational efficiency is provided herein. A system comprises a memory that stores executable components and a processor, operatively coupled to the memory, that executes the executable components that comprise an assessment component, a sensor component, and a route planning component. The assessment component accesses runway data, taxiway data, and gate configuration data associated with an airport. The sensor component collects, from a plurality of sensors, sensor data related to performance data of an aircraft and respective conditions of the runway, the taxiway, and the gate configuration data. The route planning component employs a navigation model that is trained to analyze the sensor data, the runway data, the taxiway data, and the gate configuration data, and generate a taxiing protocol to navigate the aircraft to improve aircraft operational efficiency.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate measuring weight and balance and optimizing center of gravity are provided. In one embodiment, a system 100 utilizes a processor 106 that executes computer implemented components stored in a memory 104. A compression component 108 calculates compression of landing gear struts based on height above ground of an aircraft. A gravity component 110 determines center of gravity based on differential compression of the landing gear struts. An optimization component 112 automatically optimizes the center of gravity to a rear limit of a center of gravity margin.

Abstract: One example aspect of the present disclosure relates to a method. The method can include determining, by one or more autonomous distress tracking (ADT) devices installed in a designated fire zone, a state of the vehicle. When the state of the vehicle is the normal state, the method can include transmitting first data via a first transmitter at a first interval, wherein the first transmitter is configured to transmit messages over a frequency band used for normal communications. When the state of the vehicle is the possible distress state, the method can include transmitting second data via the first transmitter at a second interval. When the state of the vehicle is the distress state, the method can include transmitting third data continuously via a second transmitter, wherein the second transmitter is configured to transmit messages over a frequency band reserved for emergency communications.

Abstract: A system and method for operating a wildlife intercept system, including receiving an indication of a presence of an intrusion in a predetermined area, determining a location of the intrusion in the predetermined area, and directing the intrusion away from the predetermined area by at least a subset of vehicles.

Abstract: Route planning and movement of an aircraft on the ground based on a navigation model trained to improve aircraft operational efficiency is provided herein. A system comprises a memory that stores executable components and a processor, operatively coupled to the memory, that executes the executable components that comprise an assessment component, a sensor component, and a route planning component. The assessment component accesses runway data, taxiway data, and gate configuration data associated with an airport. The sensor component collects, from a plurality of sensors, sensor data related to performance data of an aircraft and respective conditions of the runway, the taxiway, and the gate configuration data. The route planning component employs a navigation model that is trained to analyze the sensor data, the runway data, the taxiway data, and the gate configuration data, and generate a taxiing protocol to navigate the aircraft to improve aircraft operational efficiency.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate landing on emergency or unprepared landing strip in low visibility condition are provided. In one embodiment, a system 100 utilizes a processor 106 that executes computer implemented components stored in a memory 104. A selection component 108 selects candidate spaces from a navigation database or machine vision data for landing an aircraft. A guidance component 110 guides landing the aircraft on a landing strip from among the candidate spaces in low visibility condition.

Abstract: Systems and techniques to facilitate airborne mesh network information exchange are presented. In an example, an air traffic communication system 102 can include a mesh network component 104 and a traffic management component 106. The mesh network component generates a mesh network of communication datalinks 606 associated with one or more aircrafts 402 based on broadcast data that includes a set of broadcasts associated with an aircraft surveillance system 404 for the one or more aircrafts. The traffic management component augments air traffic data and weather data provided by an air traffic management system with sensor data received via the mesh network.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate generating aircraft performance volume based on collision avoidance are provided. In one embodiment, a system utilizes a processor that executes computer implemented components stored in a memory. A graph component uses flight management data to plot course of flight for a determined period of time. A deviation component calculates a volume of space of aircraft performance that is capable of deviating from the course of flight based on current aircraft configuration and capability. A search component searches for intersections between the volume of space of the aircraft with broadcasted volume of space of other aircrafts to identify potential collisions.

Abstract: A method and apparatus for reducing bending moment on a wing of an aircraft can include at least one sensor provided on the aircraft configured to monitor a shape or position of the wing. The sensor can provide a change in the position or shape of the wing to a controller. The controller can operate one or more spoilers in response to the change in shape or position of the wings to reduce loading on the wings to reduce the bending moment.

Abstract: Systems, computer-implemented methods and/or computer program products that facilitate automating fault isolation of flight control surfaces and damage detection of aircraft are provided. In one embodiment, a system 100 utilizes a processor 102 that executes computer implemented components stored in memory 104. One or more sensors 106 monitor wing and flight control surface from one or more vantage points to obtain full coverage of the wing. A machine vision component 108 assesses condition of the wing and the flight control surface based on results of the one or more sensors 106. A spectrographic component 110 detects leaks by monitoring airflow for traces of fuel or hydraulic fluid.

Abstract: Systems and methods for authenticating data transmissions are provided, such as e.g., analog radio streams received at a vehicle. In one aspect, the vehicle includes features that allow for detection and decryption of an encrypted source identifier embedded or introduced into a data transmission transmitted to the vehicle. The source identifier may be used to determine whether the source is authorized to transmit data transmissions to the vehicle and the data transmission may be authenticated accordingly. In another aspect, the vehicle includes features that determine the location of the transmitting device used to transmit the data transmission to the vehicle. The location is then used to determine whether the data transmission should be authenticated.

Abstract: Systems and methods for control of vehicles are provided. A computer-implemented method in example embodiments may include receiving, at a computing system comprising one or more processors positioned in a vehicle, voice data from one or more audio sensors positioned in the vehicle. The system can determine whether configuration of a reference voiceprint for a speech processing system of the vehicle is authorized based at least in part on performance data associated with the vehicle. In response to determining that configuration of the reference voiceprint is authorized, a first reference voiceprint based on the reference voice data can be stored and the speech processing system configured to authenticate input voice data for a first set of voice commands based on the reference voiceprint.

Abstract: A network switch includes a first port configured for communication with a first electric device and a second port configured for communication with a second electric device in a deterministic network. The network switch includes one or more processors configured to receive at the first port a communication packet associated with the first electric device and the second electric device, determine if the communication packet satisfies a plurality of protocol constraints, and in response to the communication packet satisfying the plurality of protocol constraints, input one or more message characteristics from the communication packet into a model associated with a first industrial process. The model is configured to output a process behavioral classification based on the one or more message characteristics. The one or more processors receive a process behavioral classification for the communication packet, and selectively generate a control action for the ICS based on the process behavioral classification.