IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
US-0803680
(2010-07-02)
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등록번호 |
US-8362943
(2013-01-29)
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발명자
/ 주소 |
- Jacobs, Mark H.
- Alon, Yair
- Geiger, Joseph H.
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출원인 / 주소 |
- Northrop Grumman Guidance and Electronics Company, Inc.
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인용정보 |
피인용 횟수 :
2 인용 특허 :
7 |
초록
▼
A method for registering a radar system. The method includes obtaining first values for a location of a target relative to the radar system using radar system initiated signals, obtaining geo-referenced location data for and from the target, obtaining second values for the location of the target rel
A method for registering a radar system. The method includes obtaining first values for a location of a target relative to the radar system using radar system initiated signals, obtaining geo-referenced location data for and from the target, obtaining second values for the location of the target relative to the radar system using the geo-referenced location data, computing location registration bias errors for the radar system using the first and second values, and registering the radar system using the computed location registration bias errors.
대표청구항
▼
1. A method for registering a radar system, comprising: obtaining first values for a location of a target relative to the radar system using radar system initiated signals;obtaining geo-referenced location data for and from the target;obtaining second values for the location of the target relative t
1. A method for registering a radar system, comprising: obtaining first values for a location of a target relative to the radar system using radar system initiated signals;obtaining geo-referenced location data for and from the target;obtaining second values for the location of the target relative to the radar system using the geo-referenced location data;computing location registration bias errors for the radar system using the first and second values; andregistering the radar system using the computed location registration bias errors. 2. The method as recited in claim 1, wherein the geo-referenced location data for the target comprises latitude, longitude and altitude of the target. 3. The method as recited in claim 1, wherein the first values comprise values for a measured range and a measured azimuth from the radar system to the target located on a set of orthogonal coordinates,wherein the second values comprise values for a computed range and a computed azimuth from the radar system to the target located on the orthogonal coordinates, andwherein the location registration bias errors for the radar system comprise a range registration bias error and an azimuth registration bias error. 4. The method as recited in claim 3, wherein the radar system initiated signals comprise a directed radar signal transmitted from the radar system and a transponder response signal transmitted by the target,wherein the directed radar signal comprises instructions to the target to which it is directed to respond with the transponder response signal when the target receives the directed radar signal, andwherein the transponder response signal comprises the geo-referenced location data for the target. 5. The method as recited in claim 4, wherein the radar system initiated signals further comprise a non-directed radar signal,wherein the non-directed radar signal includes instructions to the target(s) that receive the signal to respond with the transponder response signal, andwherein the non-directed radar signal is not addressed specifically to the target. 6. The method as recited in claim 5, further comprising: selecting the directed radar signal and its associated transponder response signal as the source for the radar measured range and azimuth orselecting the non-directed radar signal and its associated transponder response signal as the source for the radar measured range and azimuth. 7. The method as recited in claim 6, further comprising: extracting the geo-referenced location data for the target from the transponder response signal transmitted by a transponder in response to the directed radar signal,transforming the geo-referenced location data for the target to radar referenced coordinates;computing a computed range and a computed azimuth using the transformed geo-referenced location data for the target;computing a range registration bias error using the computed range and the measured range; andcomputing an azimuth registration bias error using the computed azimuth and the measured azimuth. 8. The method as recited in claim 7, further comprising: computing an average range registration bias error using the computed range registration bias error and other previously computed range registration bias errors; andcomputing an average azimuth registration bias error using the computed azimuth registration bias error and other previously computed azimuth registration bias errors. 9. The method as recited in claim 8, further comprising: registering the radar system using the average range registration bias error and the average azimuth registration bias error. 10. The method as recited in claim 8, further comprising: computing a figure of merit for the range registration bias error and the azimuth registration bias error; andif the computed figure of merit does not meet preselected criteria, repeating the above method steps. 11. The method as recited in claim 3, wherein the radar system initiated signals comprise a non-directed radar signal transmitted from the radar system and a transponder response signal transmitted by the target,wherein the non-directed radar signal comprises instructions to the target to respond with the transponder response signal when the target receives the non-directed radar signal,wherein a transponder asynchronous signal comprises the geo-referenced location data for the target, andwherein the non-directed radar signal is not addressed specifically to the target. 12. The method as recited in claim 11, further comprising: selecting the non-directed radar signal and its associated transponder response signal are selected as the source for the radar measured range and azimuth;extracting the geo-referenced location data for the target from the transponder asynchronous signal transmitted by a transponder asynchronously;correlating the asynchronous transponder signal with the closest in time transponder response signal;transforming the geo-referenced location data for the target to radar referenced coordinates;computing a computed range and a computed azimuth using the transformed geo-referenced location data for the target;computing a range registration bias error using the computed range and the measured range; andcomputing an azimuth registration bias error using the computed azimuth and the measured azimuth. 13. The method as recited in claim 12, further comprising: computing an average range registration bias error using the computed range registration bias error and other previously computed range registration bias errors; andcomputing an average azimuth registration bias error using the computed azimuth registration bias error and other previously computed azimuth registration bias errors. 14. The method as recited in claim 13, further comprising: registering the radar system using the average range registration bias error and the average azimuth registration bias error. 15. The method as recited in claim 13, further comprising: computing a figure of merit for the range registration bias error and the azimuth registration bias error; andif the computed figure of merit does not meet preselected criteria, repeating the above method steps. 16. A registration system for registering a radar system, comprising: the radar system, wherein the radar system is capable of measuring first values for a location of a target relative to the radar system using radar system initiated signals,wherein the radar system is capable of receiving geo-referenced location data for and from the target,wherein the radar system is capable of computing second values for the location of the target relative to the radar system using the geo-referenced location data,wherein the radar system is capable of computing location registration bias errors for the radar system using the first and second values, andwherein the registration system is capable of registering the radar system using the computed location registration bias errors. 17. The registration system as recited in claim 16, wherein the geo-referenced location data for the target comprises latitude, longitude and altitude of the target. 18. The registration system as recited in claim 16, wherein the first values comprise values for a measured range and a measured azimuth from the radar system to the target located on a set of orthogonal coordinates,wherein the second values comprise values for a computed range and a computed azimuth from the radar system to the target located on the orthogonal coordinates, andwherein the location registration bias errors for the radar system comprise a range registration bias error and an azimuth registration bias error. 19. The registration system as recited in claim 18, wherein the radar system initiated signals comprise a directed radar signal transmitted from the radar system and a transponder response signal transmitted by the target,wherein the directed radar signal comprises instructions to the target to which it is directed to respond with the transponder response signal when the target receives the directed radar signal, andwherein the transponder response signal comprises the geo-referenced location data for the target. 20. The registration system as recited in claim 19, wherein the radar system initiated signals further comprise a non-directed radar signal,wherein the non-directed radar signal includes instructions to the target(s) that receive the signal to respond with the transponder response signal andwherein the non-directed radar signal is not addressed specifically to the target. 21. The registration system as recited in claim 20, wherein the directed radar signal and its associated transponder response signal are selected as the source for the radar measured range and azimuth or the non-directed radar signal and its associated transponder response signal are selected as the source for the radar measured range and azimuth,wherein the radar system is capable of extracting the geo-referenced location data for the target from the transponder response signal transmitted by a transponder in response to the directed radar signal,wherein the radar system is capable of transforming the geo-referenced location data for the target to radar referenced coordinates,wherein the radar system is capable of computing a computed range and a computed azimuth using the transformed geo-referenced location data for the target,wherein the radar system is capable of computing a range registration bias error using the computed range and the measured range andwherein the radar system is capable of computing an azimuth registration bias error using the computed azimuth and the measured azimuth. 22. The registration system as recited in claim 18, wherein the radar system initiated signals comprise a non-directed radar signal transmitted from the radar system and a transponder response signal transmitted by the target,wherein the non-directed radar signal comprises instructions to the target to respond with the transponder response signal when the target receives the non-directed radar signal,wherein a transponder asynchronous signal comprises the geo-referenced location data for the target, andwherein the non-directed radar signal is not addressed specifically to the target. 23. The registration system as recited in claim 22, wherein the non-directed radar signal and its associated transponder response signal are selected as the source for the radar measured range and azimuth,wherein the radar system is capable of correlating the asynchronous transponder signal with the closest in time transponder response signal,wherein the radar system is capable of extracting the geo-referenced location data for the target from the transponder asynchronous signal transmitted by a transponder asynchronously,wherein the radar system is capable of transforming the geo-referenced location data for the target to radar referenced coordinates,wherein the radar system is capable of computing a computed range and a computed azimuth using the transformed geo-referenced location data for the target,wherein the radar system is capable of computing a range registration bias error using the computed range and the measured range, andwherein the radar system is capable of computing an azimuth registration bias error using the computed azimuth and the measured azimuth. 24. A radar registration system comprising: a radar operable to output radar data including a plurality of radar-based position reports associated with one or more targets moving within a range of the radar;a geo-referenced position source operable to output a plurality of geo-referenced position reports associated with the one or more targets; anda processor operable to compute position bias parameters associated with the radar by analyzing the radar-based position reports using the geo-referenced position reports as a reference. 25. The system of claim 24 wherein the position bias parameters comprise a range bias and an azimuth bias that are orthogonal to one another. 26. The system of claim 24 wherein the processor is included within an air traffic control system. 27. The system of claim 24 wherein said processor is further operable to perform quality monitoring during computation of the position and time bias parameters to provide an estimate of the quality of the position bias parameters. 28. A method of registering a radar, said method comprising: collecting a plurality of radar data samples from the radar, the radar data samples comprising radar-based position reports associated with one or more targets moving within range of the radar;collecting a plurality of geo-referenced data samples from a geo-referenced position source, the geo-referenced data samples comprising geo-referenced position reports associated with the one or more targets; andcomputing position bias parameters associated with the radar by analyzing the radar-based position reports using the geo-referenced position reports as a reference. 29. The method of claim 28 wherein in said step of computing position bias parameters, the position bias parameters comprise a range bias and an azimuth bias that are orthogonal to one another. 30. The method of claim 28 wherein said step of computing position bias parameters, computation of the position and time bias parameters occurs on a processor within an air traffic control system. 31. The method of claim 28 further comprising the step of: performing a quality monitoring during computation of the position bias parameters to provide an estimate of the quality of the position bias parameters.
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