Patent Description:
The present disclosure relates generally to the presentation of a timescale on flight display systems on an aircraft. More particularly, embodiments of the present disclosure provide methods and systems for displaying time rings with time and range markers on an avionic display that visually communicate associated real-time time separations between the ownship and at least other traffic for maintenance of a required minimum separation time between aircraft during an approach to a destination.

For pilots engaged especially in supersonic flight, as well as in subsonic flights, awareness of a time scale during in-flight operations can be deemed on par with critical information of the aircraft's current distance scale. The need to know is based on the concept that when an aircraft is flying at a high airspeed the change in distance occurs at a high rate allowing, in many instances, little time or insufficient time for decision making in advance by the pilot in-flight for the required route and/or trajectory changes.

It is therefore desirable for the pilot to be able to visually monitor changes to the route and trajectory on an avionic display based on a time change or time frame rather than solely by the distance covered by the aircraft in-flight.

<CIT> discloses a flight display system, comprising a time/bearing map including a plurality of concentric "range" rings corresponding to selected times in the future.

The present disclosure provides a technical solution in the form of a set of time rings displayed on an avionic display that visually communicates a current flight separation time to the pilot of the ownship to a selected point of interest or another aircraft ahead while in-flight.

Other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.

In an embodiment, a method for displaying multiple time rings on an avionic display is provided according to claim <NUM>.

In at least one exemplary embodiment, the method includes displaying the distance marker and time marker for the range and the separation flight time of a transitioning to a subsonic flight phase about the ownship's position and airspeed, and to at least one time ring.

In at least one exemplary embodiment, the method includes displaying the distance marker and time marker in a visual combination wherein the distance marker is displayed above and the time marker is displayed below at least one time ring or vice versa displayed about at least one time ring.

In at least one exemplary embodiment, the method includes displaying the pair of visually spaced apart time rings, that include the first and second time rings in a flight path of an ownship, to represent visually at least a flight time separation between the ownship and another aircraft located ahead of the ownship in the flight path.

In at least one exemplary embodiment, the method includes displaying the flight time separation between the ownship and another aircraft located ahead of the ownship in the flight path to enable situational time awareness of the pilot by visual viewing of the flight time separation by a spacing of the time rings and by a time marker value on the avionic display thereby enabling enhanced control of an ownship flight operation to maintain a time-based separation.

In at least one exemplary embodiment, the method includes the time-based separation includes a two-minute time separation on an approach flight phase.

In at least one exemplary embodiment, the method includes displaying by the time marker, a calculated time separation based on a range separation of the ownship to a selected point of interest on a terrain map depicted on the avionic display.

In at least one exemplary embodiment, the method includes selecting a set of multiple points of interest on the terrain map to correspond to a set of multiple time rings on the avionic display for depicting visual time based separations on the avionic display.

In another exemplary embodiment, a system for presenting multiple time rings on an avionic display of an aircraft is provided according to claim <NUM>.

In at least one exemplary embodiment, the system includes the controller circuit configured by programming instructions to display the distance marker and time marker for the range and the separation flight time of a commencing of a supersonic flight phase in relation to the ownship's position and airspeed, and to at least one time ring.

In at least one exemplary embodiment, the system includes the controller circuit configured by programming instructions to display the distance marker and time marker for the range and the separation flight time of a transitioning to a subsonic flight phase in relation to the ownship's position and airspeed, and to at least one time ring.

In at least one exemplary embodiment, the system includes the controller circuit configured by programming instructions to display the distance marker and time marker in a visual combination wherein the distance marker is displayed above and the time marker is displayed below at least one time ring or vice versa displayed about at least one time ring.

In at least one exemplary embodiment, the system includes the controller circuit configured by programming instructions to display the pair of visually spaced apart time rings, that include the first and second time rings in a flight path of an ownship, to represent visually at least a flight time separation between an ownship and another aircraft located ahead of the ownship in the flight path.

In at least one exemplary embodiment, the system includes the controller circuit configured by programming instructions to display the flight time separation between the ownship and another aircraft located ahead of the ownship in the flight path to enable situational time awareness of the pilot by visual viewing of the flight time separation by a spacing of the time rings and by a time marker value on the avionic display thereby enabling enhanced control of an ownship flight operation to maintain a time-based separation.

In at least one exemplary embodiment, the system provides the time-based separation that includes a two-minute time separation on an approach flight phase.

In at least one exemplary embodiment, the system provides the controller circuit configured by programming instructions to display by the time marker, a calculated time based on a range separation of the ownship to a selected point of interest on a terrain map.

In at least one exemplary embodiment, the system provides the controller circuit configured by programming instructions to display by the time marker, a calculated time separation based on a range separation of the ownship to a selected point of interest on a terrain map depicted on the avionic display.

In at least one exemplary embodiment, the system provides the controller circuit configured by programming instructions to select a set of multiple points of interest on the terrain map to correspond to a set of multiple time rings on the avionic display for depicting visual time based separations on the avionic display.

In yet another exemplary embodiment, a system for displaying a selected time ring to depict the separation of an ownship from an aircraft is provided. The system includes an avionic display; a navigation system configured to determine the location of the ownship and the aircraft; and a controller coupled to the avionic display and the navigation system and configured to display the desired flight path, display a position of the ownship in relation to the desired flight path, display a position of the aircraft in relation to the desired flight path, and display at least one set of time rings on the avionic display in relation to the desired flight path that indicates a desired separation of the aircraft from the ownship.

Furthermore, other desirable features and characteristics of the system and method will become apparent from the subsequent detailed description and the appended claims, taken in conjunction with the accompanying drawings and the preceding background.

At least one example of the present invention will hereinafter be described in conjunction with the following figures, wherein like numerals denote like elements, and wherein:.

The following Detailed Description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. The term "exemplary," as appearing throughout this document, is synonymous with the term "example" and is utilized repeatedly below to emphasize that the description appearing in the following section merely provides multiple non-limiting examples of the invention and should not be construed to restrict the scope of the invention, as set out in the Claims, in any respect. As further appearing herein, the term "pilot" encompasses all users of the below-described aircraft system.

As used herein, the term "present" refers broadly to any means or method for the distribution of information to a flight crew or other aircraft operator, whether visually, aurally, tactilely, or otherwise.

Hence, there exists a need to present a time scale context in primary and navigational display for pilots operating supersonic and subsonic aircraft. The addition of time rings in an avionic display can aid the pilot during the Visual Separation Approach (VSA), CDTI Assisted Visual Approach (CAVS), Flight Interval Management (FIM) operations. Besides spatial separation awareness, the time rings aid the pilot to acquire time separation and maintain separation between the ownship and selected traffic when instructed in traffic operations by the air traffic control.

The minimum time separation for an arriving aircraft with no radar is a time separation of <NUM> minutes for a medium aircraft behind a heavy aircraft and is <NUM> minutes for a light aircraft behind a heavy or medium aircraft (for the avoidance of turbulence caused by the heavy or medium aircraft in front). If in an approach phase, and the runway involved has a displaced threshold, the separation minimum time for aircraft on approach for runways with successive arriving departing or departing arriving traffic is <NUM> minutes.

It is therefore desirable for pilots to be relieved from having to perform the mental calculation to determine and maintain the required <NUM> or <NUM>-minute time separations by displaying visual time markers with time ring on an avionic display while in-flight thereby decreasing pilot workload (i.e., the pilot not having to perform mental calculations for time separation situation awareness) during a taxing time such as the approach and landing phases.

Air traffic control (ATC) procedures direct individual aircraft to separate from each other to maintain safety. Available flight control methods utilize aircraft current positions for separating aircraft. Using aircraft current positions to achieve required separations can impose a high workload for air traffic controllers in the terminal area. Also, using aircraft current positions to achieve required separations can result in many landing runways not being utilized to their capacity, especially in busiest airports as the separation time needs to be carefully monitored and maintained. Therefore, achieving required aircraft separations while also optimizing runway landing capacities at an airport is a technical problem.

Some solutions to this technical problem include utilizing aircraft trajectories, in addition to the aircraft's current position (spatially). Other solutions to this technical problem utilize aircraft trajectories, the aircraft current position (spatially), and add the aircraft current position (temporally); the solution that adds the temporal, or time, element, transitions the corresponding aircraft control procedures from three dimensions (3D) to four dimensions (4D). Aircraft following 4D trajectories will reduce air traffic controller workload, increase the capacity /throughput of runway surfaces, reduce time and distance flown, reduce fuel burn by increasing predictability of arrival times at 3D waypoints. A typical 4D flight plan clearance from an air traffic controller includes both a position clearance (lat/long/alt) and time clearance. Time clearance is provided as Required Time of Arrival (RTA) to a specified waypoint in the flight plan at a specified time. Therefore, the display of time markers with time rings selected about objects of interest can be beneficial in both 3D and 4D trajectories (especially in the approach trajectory phase) to maintain the required time separations when following an aircraft ahead in an approach.

In an exemplary embodiment, the use of current RTA usage is generally limited to a single RTA constraint in a cruise phase of flight. However, as next-generation procedures evolve, it is anticipated that RTAs will be become more common and proliferate through other phases of flight, including descent and taxi operations (although no altitude constraint, a waypoint with time). Descent profiles typically provide a higher workload to the pilot due to the frequency of both lateral track constraints and vertical constraints, therefore the display of time markers and time rings will decrease the pilot workload, and also enable more usage of RTAs in different phase as time separations can more easily be maintained and coordinated with RTAs.

Further, with RTAs as well as approach separation, the displaying of time rings along with the time markers and ranges between time rings can aid in visual time scale awareness and RTA usage. For example, the visual depiction of pairs or sets of time rings can aid the pilot to determine the amount of available time to act or distance to act when a transition from subsonic to supersonic segments (or vice-versa) begins, the time to reach a specific point of interest, the time to clear in-flight a particular obstacle and to determine a time spacing between a selected aircraft when instructed to follow by VSA/CAVS/FIM operations.

In an exemplary embodiment, the time difference visually depicted between an ownship with respect to the tagged and selected aircraft will assist a pilot in maintaining the time separation for a safe landing. The time rings will aid the pilot to determine the response time available to respond to any severe weather which is along with the flight plan. Similarly, with the use of time rings, the pilot will be able to correlate the sonic boom prediction for the next few minutes with respect to the terrain and map view.

For example, any changes to a supersonic flying corridor instructed by the air traffic controller (ATC) can result in the pilot needing to understand the time frame required to reach the new corridor. The pilot then can plan the required changes to flight parameters (e.g., speed) accordingly. In a current avionic display, almost all information is presented giving spatial and distance context. For example, the range rings in Synthetic Vision Display help pilot understand the radial distance from ownship to terrain or terrain-related information presented ahead. The navigational map, similarly, provide selected map range information for the pilot to acquire distance awareness for plan view terrain and other strategic flight plan information displayed on the navigation display.

Assuring the separation of individual aircraft to maintain safety, as required by regulating authorities and Air traffic control (ATC) procedures, is a technical problem that can even affect taxi operations (although a taxi operation has no altitude constraint, it can be considered a waypoint with time). In exemplary embodiments, the present disclosure describes solutions to this technical problem by utilizing the time rings for enhanced time situation awareness by viewing time separation in 4D aircraft trajectories.

Provided embodiments provide a technical solution in the form of a system that provides an intuitive visualization on an avionic display of the time-based separation distances between an ownship and other aircraft. With these features, the present disclosure provides an objectively improved human-machine interface (HMI) over available flight guidance systems.

<FIG> is a block diagram of a system <NUM> for presenting an RTA waypoint with associated time constraints (shortened herein to "system" <NUM>), as illustrated in accordance with an exemplary and non-limiting embodiment of the present disclosure. System <NUM> may be utilized onboard a mobile platform <NUM> to provide visual guidance, as described herein. In various embodiments, the mobile platform is an aircraft <NUM>, which carries or is equipped with the system <NUM>. As schematically depicted in <FIG>, system <NUM> includes the following components or subsystems, each of which may assume the form of a single device or multiple interconnected devices: a controller circuit <NUM> operationally coupled to at least one display device <NUM>; computer-readable storage media or memory <NUM>; an optional input interface <NUM>, and ownship data sources <NUM> including, for example, a flight management system (FMS) <NUM> and an array of flight system status and geospatial sensors <NUM>.

In various embodiments, system <NUM> may be separate from or integrated within: the flight management system (FMS) and/or a flight control system (FCS). Although schematically illustrated in <FIG> as a single unit, the individual elements, and components of system <NUM> can be implemented in a distributed manner utilizing any practical number of physically distinct and operatively interconnected pieces of hardware or equipment. When system <NUM> is utilized as described herein, the various components of system <NUM> will typically all be located onboard Aircraft <NUM>.

The term "controller circuit" (and its simplification, "controller"), broadly encompasses those components utilized to carry out or otherwise support the processing functionalities of the system <NUM>. Accordingly, the controller circuit <NUM> can encompass or may be associated with a programmable logic array, application-specific integrated circuit or other similar firmware, as well as any number of individual processors, flight control computers, navigational equipment pieces, computer-readable memories (including or in addition to memory <NUM>), power supplies, storage devices, interface cards, and other standardized components. In various embodiments, the controller circuit <NUM> embodies one or more processors operationally coupled to data storage having stored therein at least one firmware or software program (generally, computer-readable instructions that embody an algorithm) for carrying out the various process tasks, calculations, and control/display functions described herein. During operation, the controller circuit <NUM> may be programmed with and execute at least one firmware or software program, for example, program <NUM>, that embodies an algorithm described herein for receiving and processing RTA waypoint information to thereby present a visualization of an RTA waypoint with associated time constraints on an avionic display for an aircraft <NUM>, and to accordingly perform the various process steps, tasks, calculations, and control/display functions described herein.

Controller circuit <NUM> may exchange data, including real-time wireless data, with one or more external sources <NUM> (for example, Air Traffic Control) to support the operation of system <NUM> in embodiments. In various embodiments, controller <NUM> may receive and process the required time of arrival (RTA) waypoint information for the aircraft <NUM>. In this case, bidirectional wireless data exchange may occur over a communications network, such as a public or private network implemented in accordance with Transmission Control Protocol/Internet Protocol architectures or other conventional protocol standards. Encryption and mutual authentication techniques may be applied, as appropriate, to ensure data security.

Memory <NUM> is a data storage that can encompass any number and type of storage media suitable for storing computer-readable code or instructions, such as the aforementioned software program <NUM>, as well as other data generally supporting the operation of the system <NUM>. Memory <NUM> may also store one or more threshold <NUM> values, for use by an algorithm embodied in software program <NUM>. Examples of threshold <NUM> values include margins of error for altitude deviations, airspeed deviations, and lateral deviations. One or more database(s) <NUM> are another form of storage media; they may be integrated with memory <NUM> or separate from it.

In various embodiments, aircraft-specific parameters and information for aircraft <NUM> may be stored in memory <NUM> or a database <NUM> and referenced by program <NUM>. Non-limiting examples of aircraft-specific information include an aircraft's weight and dimensions, performance capabilities, configuration options, and the like.

In various embodiments, two or three-dimensional map data may be stored in a database <NUM>, including airport features data, geographical (terrain), buildings, bridges, and other structures, street maps, and navigational databases including but not limited to waypoints and airways, which may be updated on a periodic or iterative basis to ensure data timeliness. This map data may be uploaded into the database <NUM> at an initialization step and then periodically updated, as directed by either a program <NUM> update or by an externally triggered update.

Flight parameter sensors and geospatial sensors <NUM> supply various types of data or measurements to controller circuit <NUM> during Aircraft flight. In various embodiments, the geospatial sensors <NUM> supply, without limitation, one or more: inertial reference system measurements providing a location, Flight Path Angle (FPA) measurements, airspeed data, groundspeed data (including groundspeed direction), vertical speed data, vertical acceleration data, altitude data, attitude data including pitch data and roll measurements, yaw data, heading information, sensed atmospheric conditions data (including wind speed and direction data), flight path data, flight track data, radar altitude data, and geometric altitude data.

With continued reference to <FIG>, display device <NUM> can include any number and type of image generating devices on which one or more avionic displays <NUM> may be produced. When system <NUM> is utilized for a manned Aircraft, display device <NUM> may be affixed to the static structure of the Aircraft cockpit as, for example, a Head Down Display (HDD) or Head-Up Display (HUD) unit. In various embodiments, the display device <NUM> may assume the form of a movable display device (e.g., a pilot-worn display device) or a portable display device, such as an Electronic Flight Bag (EFB), a laptop, or a tablet computer carried into the Aircraft cockpit by a pilot.

At least one avionic display <NUM> is generated on display device <NUM> during operation of the system <NUM>; the term "avionic display" is synonymous with the term "aircraft-related display" and "cockpit display" and encompasses displays generated in textual, graphical, cartographical and other formats. System <NUM> can simultaneously generate various types of lateral and vertical avionic displays <NUM> on which map views and symbology, text annunciations, and other graphics about flight planning are presented for a pilot to view. The display device <NUM> is configured to continuously render at least a lateral display showing the aircraft <NUM> at its current location and trajectory within the map data. The avionic display <NUM> generated and controlled by the system <NUM> can include graphical user interface (GUI) objects and alphanumerical input displays of the type commonly presented on the screens of MCDUs, as well as Control Display Units (CDUs) generally. Specifically, embodiments of avionic displays <NUM> include one or more two dimensional (2D) avionic displays, such as a horizontal (i.e., lateral) navigation display or vertical navigation display (i.e., vertical situation display VSD); and/or, one or more three dimensional (3D) avionic displays, such as a Primary Flight Display (PFD) or an exocentric 3D avionic display.

In various embodiments, a human-machine interface is implemented as an integration of a pilot input interface <NUM> and a display device <NUM>. In various embodiments, the human-machine interface is embodied as a touch screen display device <NUM>. In various embodiments, the human-machine interface includes a touch screen display device <NUM> and at least one additional pilot input interface <NUM> (such as a keyboard, cursor control device, voice input device, or the like), generally operationally coupled to the display device <NUM>. Via various display and graphics systems processes, the controller circuit <NUM> may command and control a touch screen display device <NUM> to generate a variety of graphical user interface (GUI) objects or elements described herein, including, for example, buttons, sliders, and the like, which are used to prompt a user to interact with the human-machine interface to provide user input; and for the controller circuit <NUM> to activate respective system functions and provide user feedback, responsive to received user input at the GUI element.

In various embodiments, system <NUM> may also include a dedicated communications circuit <NUM> configured to provide a real-time bidirectional wired and/or wireless data exchange for the controller <NUM> to communicate with the external sources <NUM> (including, each of traffic, air traffic control (ATC), satellite weather sources, ground stations, and the like). In various embodiments, the communications circuit <NUM> may include a public or private network implemented in accordance with Transmission Control Protocol/Internet Protocol architectures and/or other conventional protocol standards. Encryption and mutual authentication techniques may be applied, as appropriate, to ensure data security. In some embodiments, the communications circuit <NUM> is integrated within the controller circuit <NUM>, and in other embodiments, the communications circuit <NUM> is external to the controller circuit <NUM>. When the external source <NUM> is "traffic," the communications circuit <NUM> may incorporate software and/or hardware for communication protocols as needed for traffic collision avoidance (TCAS), automatic dependent surveillance-broadcast (ADSB), and enhanced vision systems (EVS).

In certain embodiments of system <NUM>, the controller circuit <NUM> and the other components of system <NUM> may be integrated within or cooperate with any number and type of systems commonly deployed onboard an aircraft including, for example, the FMS <NUM>. System <NUM> includes a source of an assigned flight plan includes a plurality of waypoints. In various embodiments, the FMS <NUM> is the source of the assigned flight plan and waypoints.

The disclosed algorithm is embodied in a hardware program or software program (e.g. program <NUM> in controller circuit <NUM>) and configured to operate when aircraft <NUM> is in any phase of flight. The algorithm presents RTA waypoint time constraint information to the pilot and crew via at least the avionic display <NUM>.

In various embodiments, the provided controller circuit <NUM>, and therefore its program <NUM> may incorporate the programming instructions necessary for: (a) receiving and processing aircraft status data and RTA waypoint information, determining a time constraint for an RTA waypoint, commanding the display device <NUM> to render the navigation display and the VSD on the avionic display <NUM>, and rendering the RTA waypoint using a visual encoding scheme; and (b) maintaining the human-machine interface (HMI), including any associated graphical user interface (GUI) presented on the display device <NUM>.

In operation, the display device <NUM> is also configured to process the current flight status data for the host aircraft. In this regard, the sources of flight status data generate, measure, and/or provide different types of data related to the operational status of the host aircraft, the environment in which the host aircraft is operating, flight parameters, and the like. In practice, the sources of flight status data may be realized using line replaceable units (LRUs), transducers, accelerometers, instruments, sensors, and other well-known devices. The data provided by the sources of flight status data may include, without limitation: airspeed data; groundspeed data; altitude data; attitude data, including pitch data and roll data; yaw data; geographic position data, such as GPS data; time/date information; heading information; weather information; flight path data; track data; radar altitude data; geometric altitude data; wind speed data; wind direction data; etc..

Turning now to <FIG>, the operation of various embodiments is described. <FIG> provides simplified illustrations to introduce features of a presentation of multiple time rings in a cockpit display <NUM> associated time markers, and distance.

During operation, the controller circuit <NUM>, which is programmed by programming instructions to receive and process aircraft status data including location and airspeed, commands the display device <NUM> to render a time ring <NUM> for the aircraft <NUM> at its current location and current trajectory in a lateral display and a vertical display and another time ring or multiple time rings ahead in the avionic display <NUM>. The avionic display <NUM> includes a horizontal or navigation display (INAV) with depictions of multiple time rings, time markers, and distance markers in a flight path.

The avionic display <NUM> displays a time ring <NUM> with a distance marker <NUM>, and a time marker <NUM>. The distance marker <NUM> displays the numerical value "<NUM>" which is the distance in nautical miles to the next (or above) time ring <NUM>. The time marker <NUM> displays the numerical value "<NUM>" which is the time at the current airspeed of the aircraft <NUM> to traverse the distance or separation <NUM> to the next time ring <NUM> (i.e., the separation time between a set of time rings). In an exemplary embodiment, the time marker <NUM> displays a numerical value of the separation time between each of the time rings in a pair of time rings.

In an exemplary embodiment, the pilot may select a first and second-time ring. For example, the pilot may select the first time ring (i.e., the time ring <NUM>) and then select the second time ring <NUM> at a location ahead of an aircraft's current position ahead in the flight path. In this way, the time marker <NUM> would serve as a visual indicator and value of the separation time between another aircraft or obstacle located at or near the second time ring <NUM>. Further, the separation time value displayed by the time marker <NUM> would aid pilot in maintaining a required separation time and distance between the aircraft or obstacle ahead.

In another exemplary embodiment, the time scale of the time ring represents a numerical value of "<NUM>" <NUM> in <FIG>. The "<NUM> minute" time period can represent a beginning or start of a supersonic segment or can represent the transition from a supersonic inflight segment of aircraft <NUM> to a subsonic in-flight segment based on a flight plan. In this instance, the time marker <NUM> and the numerical value of "<NUM>" (i. e, <NUM> minutes) can also be used by pilot as an indicator when the aircraft can cruise to a supersonic airspeed (i.e., reach an airspeed of about or greater than Mach I) and can cause the pilot to consider or make a situation-aware conjecture about the time of a sonic boom effect on the ground occurring that is caused by the transition to the supersonic airspeed.

In another exemplary embodiment, the time rings (i.e., <NUM>, <NUM>) can also assist the pilot during Visual Separation Approach (VSA), CDTI Assisted Visual Approach (CAVS), Flight Interval Management (FIM) operations. Besides spatial separation awareness, the time rings help the pilot to acquire time separation between an ownship and selected traffic ahead in a flight path or an approach. This can allow the pilot to maintain the minimum time separation for arriving aircraft with no radar which is required generally to be separated <NUM> minutes for a medium aircraft behind a heavy aircraft and <NUM> minutes for a light aircraft behind a heavy or medium aircraft. If the runway involved has a displaced threshold, the separation minimum for runways with successive arriving departing or departing arriving traffic is required to be about <NUM> minutes. The time markers and distance markers displayed with the time rings provided added visual awareness for the pilot to maintain these <NUM> and <NUM>-minute time separations.

In another exemplary embodiment, time rings (<NUM>, <NUM>) can aid for enhanced time situation awareness of the pilot by enabling viewing of time separation in 4D aircraft trajectories. In this case, with the 4D aircraft trajectories which are defined as the aircraft current position (spatially), and the aircraft current position (temporally) and used in the context of ATC clearance communications provided to the pilot wherein a typical 4D flight plan clearance includes both a position clearance (lat/long/alt) and the added time clearance. The time clearance may be provided or communicated to the pilot as Required Time of Arrival (RTA) to a specified waypoint in the flight plan at a specified time. Therefore visual representation of the time separation to specific RTA to the specified RTA waypoint can be displayed by the pilot selection of one or more time rings positioned on an avionic display that correlates to the specified RTA waypoint. The time marker about the time ring would visually indicate to the pilot the time separation in real-time to the specified RTA waypoint and enhance the pilot time situation awareness and overall situation awareness with both the time marker and distance marker displaying current time and distance information to the specified RTA waypoint during the ownship flight phase.

<FIG> illustrates an avionic display with the time rings to aid the pilot in reaching a point of interest by selecting a point of interest in a flight path and configuring multiple time rings to the point of interest in accordance with an exemplary embodiment.

In <FIG>, an avionic display <NUM> includes a horizontal or navigation display (INAV). Aircraft <NUM> is shown on a trajectory (or flight path <NUM>) on the navigation display. In case of VSA approaches, a pilot will be asked to follow a leading aircraft and the proposal is to represent the time difference of the ownship with respect to the leading aircraft on a display. The displayed time marker <NUM> with the time ring <NUM> and time ring <NUM> can aid the pilot to maintain a separation of <NUM> mins (at time marker <NUM>)with respect to the leading aircraft (i.e., at time rings <NUM> to <NUM>). In the scenario depicted in <FIG>, multiple time rings <NUM> to <NUM> can be selected and configured to be displayed at a specific time, e.g. <NUM> mins from the ownship.

In an exemplary embodiment depicted in <FIG>, the pilot can locate a point of interest <NUM> that is ahead of the aircraft <NUM> on its current trajectory or flight path <NUM> and selects a set of multiple range rings <NUM> to <NUM> to that point of interest <NUM>. The pilot by a calculation performed by a controller and displaying of the time marker <NUM> with the numerical value of "<NUM>" minutes can determine the time to reach the point of interest <NUM>.

In another exemplary embodiment, for VSA approaches, the pilot may be requested by ATC to follow a leading aircraft and the multiple time rings can aid the pilot visually in this instructed task by providing visual representations of multiple time differences of the ownship to the aircraft ahead on an avionic display. This will increase the pilot situation time awareness as well as spatial awareness and increase the ability of the pilot to control the airship to maintain the separation time of <NUM> mins to aircraft ahead in the flight path. For this scenario, because of the <NUM> minutes instructed separation time, a set of multiple time rings can be selected and configured on the avionic display at specified <NUM> minute time periods (e.g. commencing with a <NUM> from the ownship).

In an exemplary embodiment, the depiction of the time ring with a time marker and distance marker on an avionic display will aid the pilot in <NUM>th dimension information and time situational awareness with RTA by time separations as well as other distance cues during in-flight phases of the ownship.

In an exemplary embodiment, in conjunction with the depictions of the time rings and time/distance marker in <FIG>, the (i.e., the visualization) of the time-based separations using a selection of time rings provides an objective improvement in the HMI, enabling the pilot to visually assess the ownship position with respect to assumed spatial and temporal points of interest targets.

In <FIG>, a flow diagram is provided illustrating a method <NUM> for displaying a time ring with time and distance markers, in accordance with the present disclosure.

At <NUM>, system <NUM> is determined to have been programmed with the algorithm and programmed to respond to the selection of time rings by the pilot in an avionic display, and the method determines and renders a current location and trajectory of the aircraft <NUM> in a navigation display with respect to multiple time rings display where each of the time rings contains numerical values for time and distance markers integrated in pair combinations of corresponding time and distance separations of pairs of time rings. At <NUM>, the pilot can select one or more time rings and position each ring using a touch screen display device <NUM> and/or at least one additional pilot input interface <NUM> touch screen or other selection tools connected with the avionic display. In an exemplary embodiment, the pilot can select and first time ring for display and select a second time ring for display.

At <NUM>, the system <NUM> displays a time ring and the time marker and the distance marker about the time ring. The time marker and distance marker are displayed as a pair about a time ring and indicate visually the time separation and distance between each time ring of a pair displayed. The numerical values for the distance and time of each marker are dynamic and change (by system <NUM>) in relation to the ownship's position and airspeed. At <NUM>, the distance marker and time marker for the distance (range) and the separation flight time of a commencing of a supersonic flight phase in relation to the ownship's current position and airspeed, and the time rings. At <NUM>, the distance marker and time marker are displayed for the distance and the separation flight time of a transition from a subsonic flight phase or airspeed to supersonic airspeed about the ownship's position and airspeed, and the time rings. At <NUM>, the distance and time marker displayed in a visual combination with the distance marker positioned above and the time marker positioned below the time ring or vice versa. At <NUM>, the pair of time rings based on the pilot's selection and positioning of the time rings on the avionic display can represent visually at least the flight time separation between an ownship and another aircraft located ahead of the ownship in the flight path. At <NUM>, the flight time separation between the ownship and another aircraft located ahead of the ownship in the flight path enhances situational time awareness of the pilot by visual viewing of the time separation shown by a current real-time spacing of the time rings and by a time marker value on the avionic display. At <NUM>, the time rings a position and is selected to present a <NUM>-minute time separation (or <NUM>-minute separations or other separations times required) between objects or aircraft and the ownship to aid the pilot in a required <NUM>-minute time separation on the approach phase. At <NUM>, the separation time of a pair of time rings is displayed for a pilot selection of a range separation of the ownship to a selected point of interest on a terrain map depicted on the avionic display or waypoint with time constraints. At <NUM>, multiple points of interest are selected by the pilot on the terrain map to correspond to a set of multiple time rings on the avionic display for depicting visual time-based separations on the avionic display in a flight path or trajectory.

As such, disclosed herein is a flight display system with time rings that presents time separations of the ownship to an aircraft ahead or RTA waypoints with time constraint information, using the visual encoding scheme, on an avionic display <NUM>. System <NUM> improves upon available algorithms and display techniques by presenting time separation by the spacing between time rings that can be visually viewed on an avionic display by the pilot combined with both time and distance markers of values of separation times and ranges between time rings that correspond to points selected on the avionic display. Additionally, system <NUM> can improve the safety of taxi operations (as mentioned, although a taxi operation has no altitude constraint, it can be considered a waypoint with time). Thus, system <NUM> provides an objectively improved human-machine interface (HMI).

While the present disclosure has provided exemplary embodiments directed to a flight display system, it will be appreciated that the embodiments presented herein can be extended to other applications where approach assistance may be desirable, and where approaches may be improved through the use of a display. For example, other suitable applications may include maritime applications, railroad applications, industrial/manufacturing plant applications, space travel applications, simulator applications, and others as will be appreciated by those having ordinary skill in the art.

Claim 1:
A method for displaying multiple time rings on an avionic display (<NUM>,<NUM>), the method comprising:
displaying a first time ring (<NUM>) in the avionic display;
displaying a second time ring (<NUM>) in the avionic display, wherein the first and second time rings comprise a pair of visually spaced apart time rings, wherein a visual spacing apart between the first and second time rings is indicative of a range and a separation flight time between the first and second time rings; and
displaying, about at least the first time ring in the avionic display, a distance marker (<NUM>) of a value for a range and a numerical value for a time marker (<NUM>) corresponding to a separation flight time between the first and second rings in relation to an ownship's position and airspeed, the method further comprising:
displaying the distance marker and the time marker for the range and the separation flight time, the range and the separation flight time corresponding to a commencing of a supersonic flight phase in relation to the ownship's position and airspeed.