IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0991625
(2004-11-17)
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등록번호 |
US-8254512
(2012-08-28)
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발명자
/ 주소 |
- Gaal, Peter
- Patrick, Christopher
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
2 인용 특허 :
11 |
초록
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A receiving method and apparatus for increasing coherent integration length while receiving a positioning signal from transmitters such as GPS satellites. In order to compensate for frequency drifts that may occur in the positioning signal, a hypothesis is made as to the frequency drift, which is in
A receiving method and apparatus for increasing coherent integration length while receiving a positioning signal from transmitters such as GPS satellites. In order to compensate for frequency drifts that may occur in the positioning signal, a hypothesis is made as to the frequency drift, which is inserted into the receiving algorithm. Advantageously, the length of coherent integration can be increased at the expense of reducing the length of incoherent integration while keeping the total integration length the same, the net effect of which is an increase in signal detection sensitivity. The frequency drift hypothesis has any appropriate waveform; for example, approximately linear or exponential. The hypothesized frequency drift can be inserted into the receiver algorithm in any suitable place; for example, the data block may be adjusted for the hypothesized frequency drift, alternatively the reference signal may be adjusted, or the frequency samples of either the data block or the reference signal may be adjusted.
대표청구항
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1. A method of using a long coherent integration period to receive a positioning signal transmitted from one of a plurality of transmitters at a predetermined carrier frequency, the positioning signal including a reference signal that uniquely identifies the transmitter that sent the positioning sig
1. A method of using a long coherent integration period to receive a positioning signal transmitted from one of a plurality of transmitters at a predetermined carrier frequency, the positioning signal including a reference signal that uniquely identifies the transmitter that sent the positioning signal, comprising: a) observing electromagnetic energy at about said carrier frequency, and providing data responsive to said observed electromagnetic energy;b) hypothesizing one of said transmitters, thereby hypothesizing one of said plurality of unique reference signals;c) hypothesizing a frequency drift, wherein the frequency drift changes according to a lapse in time;d) processing, using a processor, said data responsive to said hypothesized frequency drift;e) defining a data block of said data;f) searching for a match between said data block and said hypothesized unique reference signal; andg) if a matched signal is found, then determining phase delay and timing information, otherwise looping through said steps b through f until a matched signal is found or until a predetermined exit criteria has been met. 2. The method of claim 1 wherein said hypothesized frequency drift is approximately linear. 3. The method of claim 1 wherein said hypothesized frequency drift is approximately exponential. 4. The method of claim 1 wherein said step f comprises: processing said data block responsive to said hypothesized frequency drift to provide a drift-adjusted data signal; andsearching for a match between said drift-adjusted data block and said hypothesized unique reference signal over a plurality of phase shifts. 5. The method of claim 1 wherein said step f comprises: processing said hypothesized unique reference signal responsive to said hypothesized frequency drift to provide a drift-adjusted reference signal; andsearching for a match between said data block and said hypothesized unique reference signal over a plurality of phase shifts. 6. The method of claim 1, wherein said step f comprises: calculating frequency samples responsive to said data block;calculating frequency samples responsive to said reference signal; andsearching for a match between said data block frequency samples and said reference signal frequency samples. 7. The method of claim 6 wherein said step further comprises adjusting the vector basis of said data block frequency samples and said periodically repeating sequence responsive to said hypothesized frequency drift. 8. The method of claim 1 wherein said transmitters comprise a plurality of Global Positioning System (GPS) satellites that transmit GPS signals at a GPS frequency, each GPS satellite transmitting a unique reference signal. 9. The method of claim 1 wherein said data block has a size that corresponds to an integral number of repetitions of said reference signals. 10. The method of claim 1 wherein said data block has a size within a range of one hundred to five hundred repetitions of said reference signals. 11. The method of claim 1, wherein the hypothesized frequency drift corresponds to an estimation of non-constant frequency error over the long coherent integration period. 12. A method of using a long coherent integration period to receive a positioning signal transmitted from one of a plurality of transmitters at a predetermined carrier frequency, the positioning signal including a periodically-repeating sequence that uniquely identifies the transmitter that sent the positioning signal, comprising: a) observing electromagnetic energy at about said carrier frequency, and storing data indicative of said observed electromagnetic energy;b) defining a data block that may be subject to an unknown frequency drift, wherein the frequency drift changes according to a lapse in time;c) hypothesizing a frequency drift over said data block;d) processing, using a processor, said data responsive to said hypothesized frequency drift to provide a drift-adjusted signal;e) applying said drift-adjusted signal to a correlation system, and searching for a match between said drift-adjusted signal and at least one of said plurality of transmitters; andf) if a matched signal is found, then determining phase delay and timing information, otherwise looping through said steps c through e until a matched signal is found or until a predetermined exit criteria has been met. 13. The method of claim 11 wherein said hypothesized frequency drift is approximately linear. 14. The method of claim 11 wherein said hypothesized frequency drift is approximately exponential. 15. The method of claim 11 wherein said step e comprises: hypothesizing one of said plurality of transmitters and providing a reference code corresponding to said hypothesized transmitter;assuming a pilot reference (PR) shiftcorrelating said drift-adjusted signal and said reference code responsive to said PR shift, thereby providing a correlation data set; and searching said correlation data set to identify a signal match. 16. The method of claim 14 wherein said reference code comprises a time domain signal. 17. The method of claim 11 wherein said transmitters comprise a plurality of Global Positioning System (GPS) satellites that transmit GPS signals at a GPS frequency, each GPS satellite transmitting a unique periodically-repeating sequence. 18. The method of claim 11 wherein said data block has a size that corresponds to an integral number of repetitions of said periodically-repeating sequences. 19. The method of claim 11 wherein said data block has a size within a range of one hundred to five hundred repetitions of said periodically-repeating sequences. 20. The method of claim 11 further comprising utilizing said timing information to determine a position of said mobile station. 21. The method of claim 11 wherein said data block corresponds to a time period between ten milliseconds and 1 second. 22. A receiver that uses a long coherent integration period to receive a positioning signal transmitted from one of a plurality of transmitters at a predetermined carrier frequency, the positioning signal including a reference signal that uniquely identifies the transmitter that sent the positioning signal, comprising: means for observing electromagnetic energy at about said carrier frequency, including an antenna;means for storing data indicative of said observed electromagnetic energy over a predefined period of time;means for hypothesizing one of said transmitters, thereby hypothesizing one of said plurality of unique reference signals;means for hypothesizing a frequency drift, wherein the frequency drift changes according to a lapse in time;means, for defining a data block responsive to said data, and searching for a match between said data block and said hypothesized unique reference signal over a plurality of phase shifts, responsive to said hypothesized frequency drift;means for determining phase delay and timing information; andcontrol means for determining when a matched signal has been found. 23. The receiver of claim 21 wherein said hypothesized frequency drift is approximately linear. 24. The receiver of claim 21 wherein said hypothesized frequency drift is approximately exponential. 25. The receiver of claim 21 further comprising: means for processing said data block responsive to said hypothesized frequency drift to provide a drift-adjusted data signal; andmeans for searching for a match between said drift-adjusted data block and said hypothesized unique reference signal. 26. The receiver of claim 21 further comprising: means for processing said hypothesized unique reference signal responsive to said hypothesized frequency drift to provide a drift-adjusted reference signal; andmeans for searching for a match between said data block and said hypothesized reference signal. 27. The receiver of claim 21, further comprising: means for calculating frequency samples responsive to said data block;means for frequency samples responsive to said reference signal; andmeans for searching for a match between said Fourier-transformed data block and said Fourier-transformed reference signal. 28. The receiver of claim 26 further comprising means for adjusting the vector basis of said data block frequency samples and said periodically repeating sequence responsive to said hypothesized frequency drift. 29. The receiver of claim 21 wherein said transmitters comprise a plurality of Global Positioning System (GPS) satellites that transmit GPS signals at a GPS frequency, each GPS satellite transmitting a unique reference signal. 30. The receiver of claim 21 wherein said data block has a size that corresponds to an integral number of repetitions of said reference signals. 31. The receiver of claim 21 wherein said data block corresponds to a time period between ten milliseconds and 1 second. 32. A mobile station that uses a long coherent integration period to receive a positioning signal transmitted from one of a plurality of transmitters at a predetermined carrier frequency, the positioning signal including a reference signal that uniquely identifies the transmitter that sent the positioning signal, comprising: a position location system configured to observe electromagnetic energy at about said carrier frequency, including an antenna;a mobile device control system configured to store data indicative of said observed electromagnetic energy over a predefined period of time, to hypothesize one of said transmitters, thereby hypothesizing one of said plurality of unique reference signals, to hypothesize a frequency drift according to a lapse in time, to define a data block responsive to said data, to search for a match between said data block and said hypothesized unique reference signal over a plurality of phase shifts, responsive to said hypothesized frequency drift, to determine phase delay and timing information andto determine when a matched signal has been found. 33. A non-transitory computer-readable medium having computer-executable instructions for performing a method of using a long coherent integration period to receive a positioning signal transmitted from one of a plurality of transmitters at a predetermined carrier frequency, the positioning signal including a reference signal that uniquely identifies the transmitter that sent the positioning signal, comprising: observing electromagnetic energy at about said carrier frequency, and providing data responsive to said observed electromagnetic energy;hypothesizing one of said transmitters, thereby hypothesizing one of said plurality of unique reference signals;hypothesizing a frequency drift, wherein the frequency drift changes according to a lapse of time;processing said data responsive to said hypothesized frequency drift; defining a data block of said data;searching for a match between said data block and said hypothesized reference signal; andif a matched signal is found, then determining phase delay and timing information, otherwise looping through said steps b through f until a matched signal is found or until predetermined exit criteria has been met. 34. The non-transitory computer-readable medium of claim 33 wherein the computer- executable instructions provide for: processing said data block responsive to said hypothesized frequency drift to provide a drift-adjusted data signal; andsearching for a match between said drift-adjusted data block and said hypothesized reference signal over a plurality of phase shifts. 35. The non-transitory computer-readable medium of claim 33 wherein the computer- executable instructions provide for: processing said hypothesized reference signal responsive to said hypothesized frequency drift to provide a drift-adjusted reference signal; andsearching for a match between said data block and said hypothesized reference signal over a plurality of phase shifts. 36. The non-transitory computer-readable medium of claim 33 wherein the computer- executable instructions provide for: calculating frequency samples responsive to said data block;calculating frequency samples responsive to said reference signal;searching for a match between said data block frequency samples and said reference signal frequency samples; andadjusting the vector basis of said data block frequency samples and said periodically repeating sequence responsive to said hypothesized frequency drift.
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