Graphical symbology for depicting traffic position, navigation uncertainty, and data quality on aircraft displays
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-019/00
출원번호
US-0456695
(2003-06-06)
발명자
/ 주소
Zellers, Steven M.
Breiholz, Arlen E.
Koczo, Stefan
출원인 / 주소
Rockwell Collins
인용정보
피인용 횟수 :
13인용 특허 :
1
초록▼
A method of communicating an uncertainty of a location of an object near an aircraft is disclosed. According to the method, a plurality of signals are received from positioning sources. Each of the positioning sources provide information regarding the location of the object. A positional uncertainty
A method of communicating an uncertainty of a location of an object near an aircraft is disclosed. According to the method, a plurality of signals are received from positioning sources. Each of the positioning sources provide information regarding the location of the object. A positional uncertainty of the object is obtained for each of the plurality of signals. Each positional uncertainty is related to an accuracy of the signal to which the respective positional uncertainty relates. The obtained positional uncertainties are combined to derive a combined positional uncertainty of the object having first and second mutually orthogonal directional components. The combined positional uncertainty is expressed as a geometric shape. On a display associated with the aircraft upon which the aircraft and the object are graphically represented, the geometric shape is superimposed on the graphical representation of the object, to thereby apprise a viewer of the positional uncertainty of the object.
대표청구항▼
1. A method of communicating an uncertainty of a location of an object near an aircraft, comprising:receiving a plurality of signals from positioning sources, each of the positioning sources providing information regarding the location of the object; obtaining a positional uncertainty of the object
1. A method of communicating an uncertainty of a location of an object near an aircraft, comprising:receiving a plurality of signals from positioning sources, each of the positioning sources providing information regarding the location of the object; obtaining a positional uncertainty of the object for each of the plurality of signals, wherein each positional uncertainty is related to an accuracy of the signal to which the respective positional uncertainty relates; combining the obtained positional uncertainties to derive a combined positional uncertainty of the object, wherein the combined positional uncertainty has a first directional component and a second directional component orthogonal to the first directional component; expressing the combined positional uncertainty as a geometric shape; determining if the object is within an anticipated path of the aircraft; and on a display associated with the aircraft upon which the aircraft and the object are graphically represented, graphically superimposing the geometric shape on the graphical representation of the object only when the object is within the anticipated path of the aircraft, to thereby apprise a viewer of the positional uncertainty of the object. 2. The method of claim 1, wherein the combined positional uncertainty is expressed as one of a circle and an ellipse.3. The method of claim 1, wherein the combined positional uncertainty has a third directional component that is orthogonal to the first directional component and the second directional component.4. The method of claim 1, further comprising:displaying a plurality of predefined travel paths; and graphically superimposing the geometric shape on the graphical representation of the object if the combined positional uncertainty of the object is great enough to locate the object on more than one of the plurality of predefined travel paths. 5. The method of claim 1, further comprising:determining if the object is within a predetermined distance from the aircraft; and graphically superimposing the geometric shape of the graphical representation of the object if the object is within the predetermined distance from the aircraft. 6. A method of communicating an uncertainty of a location of a nearby aircraft, comprising:receiving a plurality of signals from positioning sources, each of the positioning sources providing information regarding the location of the aircraft; obtaining a positional uncertainty of the aircraft for each of the plurality of signals, wherein each positional uncertainty is related to an accuracy of the signal to which the respective positional uncertainty relates; combining the obtained positional uncertainties to derive a combined positional uncertainty of the aircraft; expressing the combined positional uncertainty as a geometric shape; determining if the aircraft is within an anticipated path of the own ship; displaying a plurality of predefined travel paths; and on a display associated with the aircraft upon which the aircraft is graphically represented, graphically and semi-transparently superimposing the geometric shape on the graphical representation of the aircraft if the aircraft is within the anticipated path of the own ship, and graphically superimposing the geometric shape on that graphical representation of the aircraft if the combined positional uncertainty of the aircraft is great enough to locate the aircraft on more than one of the plurality of travel paths, to thereby apprise the positional uncertainty of the aircraft to a viewer of the display. 7. The method of claim 6, wherein the combined positional uncertainty is expressed as a geometric shape having a first directional component and a second directional component orthogonal to the first directional component.8. The method of claim 7, wherein the combined positional uncertainty is expressed as a semi-transparent ellipse.9. The method of claim 6, wherein the display is located in an own ship, and further comprising:determining if the aircraft is within a predetermined distance from the own ship; and graphically superimposing the geometric shape of the graphical representation of the aircraft if the aircraft is within the predetermined distance from the own ship. 10. The method of claim 6, wherein the positioning sources from which the plurality of signals are received include one or more of a Traffic Collision and Avoidance System (TCAS) transponder, a Traffic Information Services?Broadcast (TIS-B) receiver, and an Automatic Dependent Surveillance?Broadcast (ADS-B) receiver.11. A method of communicating an uncertainty of a location of an object near an aircraft, comprising:receiving a plurality of signals from positioning sources, each of the positioning sources providing information regarding the location of the object; obtaining a positional uncertainty of the object for each of the plurality of signals, wherein each positional uncertainty is related to an accuracy of the signal to which the respective positional uncertainty relates; combining the obtained positional uncertainties to derive a combined positional uncertainty of the object, wherein the combined positional uncertainty has a first directional component and a second directional component orthogonal to the first directional component; expressing the combined positional uncertainty as a geometric shape; displaying a plurality of predefined travel paths; and on a display associated with the aircraft upon which the aircraft and the object are graphically represented, graphically superimposing the geometric shape on the graphical representation of the object if the combined positional uncertainty of the object is great enough to locate the object on more than one of the plurality of predefined travel paths, to thereby apprise a viewer of the positional uncertainty of the object. 12. The method of claim 11, wherein the combined positional uncertainty is expressed as one of a circle and an ellipse.13. The method of claim 11, wherein the combined positional uncertainty has a third directional component that is orthogonal to the first directional component and the second directional component.14. The method of claim 11, further comprising:determining if the object is within an anticipated path of the aircraft; and graphically superimposing the geometric shape on the graphical representation of the object when the object is within the anticipated path of the aircraft. 15. The method of claim 11, further comprising:determining if the object is within a predetermined distance from the aircraft; and graphically superimposing the geometric shape of the graphical representation of the object is within the predetermined distance from the aircraft.
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