IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0516158
(2000-02-29)
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발명자
/ 주소 |
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출원인 / 주소 |
- Telefonaktiebolaget LM Ericsson (publ)
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
18 인용 특허 :
15 |
초록
▼
An apparatus and method are described in which a corrected signal-to-interference ratio (SIR) is determined in a cellular telephone receiver. First the estimated signal strength at the receiver is measured, then the estimated interference level is measured. The signal strength and the interference v
An apparatus and method are described in which a corrected signal-to-interference ratio (SIR) is determined in a cellular telephone receiver. First the estimated signal strength at the receiver is measured, then the estimated interference level is measured. The signal strength and the interference values are separately corrected in accordance with an algorithm. Thereafter, a corrected SIR value is obtained by dividing the corrected signal strength and the corrected interference values.
대표청구항
▼
1. A method comprising:receiving a signal transmitted over a communications channel; measuring an estimate of an energy value and an interference value of the received signal; correcting the energy value of the received signal for non-linearity; correcting the interference value of the received sign
1. A method comprising:receiving a signal transmitted over a communications channel; measuring an estimate of an energy value and an interference value of the received signal; correcting the energy value of the received signal for non-linearity; correcting the interference value of the received signal for non-linearity; and determining a corrected signal-to-interference ratio (SIR) value using the corrected energy value and the corrected interference value. 2. The method in claim 1, wherein:the interference value is corrected in accordance with the following equation: Icorr=Io?Ki·Eb, where Icorr is the corrected interference value, Eb is the measured estimate energy value, Io is the measured estimate interference value, and Ki is a constant. 3. The method in claim 2, wherein Ki is a constant depending on a spreading code associated with the transmitted signal.4. The method in claim 3, wherein Ki is selected by simulation to minimize error between the corrected interference value and a corresponding actual interference value.5. The method in claim 2, wherein:the energy value is corrected in accordance with the following equation: Ecorr=Eb?Ks·Icorr, where Ks is a constant. 6. The method in claim 5, wherein Ks is a constant depending on a spreading code associated with the transmitted signal.7. The method in claim 6, wherein Ks is selected by simulation to minimize error between the corrected energy value and a corresponding actual energy value.8. The method in claim 1, wherein:the interference value is corrected in accordance with the following equation: Icorr=Io?Ki·Eb, and the energy value is corrected in accordance with the following equation: Ecorr=Eb?Ks·Icorr, where Eb is the measured estimate energy value, Io is the measured estimate interference value, Ki is a constant, Ks is a constant, where Ki and Ks depend on a spreading code associated with the transmitted signal and are selected by simulation to minimize error between the corresponding corrected interference and energy values and corresponding ones of the actual interference and energy values. 9. The method in claim 8, wherein the method is used in a spread spectrum radio communications system and the constants Ki and Ks are determined as a function a spreading factor used to spread information to be transmitted over an available frequency spectrum.10. For use in a communications system, including plural mobile stations andat least one base station, a radio station comprising: a signal detector for estimating received signal strength associated with a communication between one of the mobile stations and the base station, and an interference detector for estimating an interference value associated with the communication, wherein the radio station is configured to independently compensate the estimated signal strength and the estimated interference value, and thereafter, determine a corrected signal-to-interference ratio (SIR) estimate based on the compensated signal strength and interference value estimates, the radio station is configured to compensate the estimated interference value in accordance with the following equation: Icorr=Io?Ki·Eb, where Icorr is the compensated interference value, Eb is the estimated received signal strength, Io is the estimated interference value, and Ki is a constant. 11. The radio station in claim 10, wherein the estimated received signal strength and estimated interference value establish an estimated SIR, and the base station is configured to determine the corrected SIR estimate to minimize a difference between the estimated SIR and an actual SIR corresponding to the estimated SIR.12. The radio station of claim 11 in a spread spectrum radio communications system.13. The radio station of claim 11, wherein the radio station is a base station.14. The radio station of claim 11, wherein the radio station is a mobile station.15. The radio station in claim 10, wherein the radio station is configured to generate a power control command based on the corrected SIR estimate and transmit that power control command.16. The radio station in claim 10, wherein Ki is a constant depending on a spreading code associated with the transmitted signal.17. The radio station in claim 16, wherein Ki is selected by simulation to minimize error between the corrected interference value and a corresponding actual interference value.18. The radio station in claim 10, wherein: the radio station is configured to compensate the estimated received signal strength in accordance with the following equation: Ecorr=Eb?Ks·Icorr where Ecorr is the corrected received signal strength, and Ks is a constant. 19. The signal strength in claim 18, wherein Ks is a constant depending on a spreading code associated with the transmitted signal.20. The radio station in claim 19, wherein Ks is selected by simulation to minimize error between the corrected signal strength and a corresponding actual signal strength.21. The radio station in claim 10 in a spread spectrum radio communications system, wherein the constants Ki and Ks are determined as a function of a spreading factor used to spread information to be transmitted over an available frequency spectrum, and wherein Ks is a constant.22. For use in a communications system, including plural mobile stations andat least one base station, a radio station comprising: a signal detector for estimating received signal strength associated with a communication between one of the mobile stations and the base station, and an interference detector for estimating an interference value associated with the communication, wherein the radio station is configured to independently compensate the estimated signal strength and the estimated interference value, and thereafter, determine a corrected signal-to-interference ratio (SIR) estimate based on the compensated signal strength and interference value estimates, and wherein the radio station is configured to compensate the estimated received signal strength for a non-linearity and to compensate the estimated interference value for a non-linearity. 23. Apparatus comprising:a receiver for receiving a signal transmitted over a communications channel; a first detector for determining an estimate of an energy value of the received signal; a second detector for determining an interference value of the received signal; and circuitry configured to correct the energy value of the received signal for non-linearity, correct the interference value of the received signal for non-linearity, and determine a corrected signal-to-interference ratio (SIR) value using the corrected energy value and the corrected interference value. 24. The apparatus in claim 23, wherein:the interference value is corrected in accordance with the following equation: Icorr=Io?Ki·Eb, where Icorr is the corrected interference value, Eb is the measured estimate energy value, Io is the measured estimate interference value, and Ki is a constant. 25. The apparatus in claim 24, wherein Ki is a constant depending on a spreading code associated with the transmitted signal.26. The apparatus in claim 25, wherein Ki is selected by simulation to minimize error between the corrected interference value and a corresponding actual interference value.27. The apparatus in claim 24, wherein:the energy value is corrected in accordance with the following equation: Ecorr=Eb?Ks·Icorr, where Ks is a constant. 28. The apparatus in claim 27, wherein Ks is a constant depending on a spreading code associated with the transmitted signal.29. The apparatus in claim 28, wherein Ks is selected by simulation to minimize error between the corrected energy value and a corresponding actual energy value.30. The apparatus in claim 23, wherein the circuitry is configured to correct the interference value in accordance with the following equation: Icorr=Io?Ki·Eb and the energy value is corrected in accordance with the following equation:Ecorr=Eb?Ks·Icorr, where Eb is the measured estimate energy value, Io is the measured estimate interference value, Ki is a constant, Ks is a constant, where Ki and Ks depend on a spreading code associated with the transmitted signal and are selected by simulation to minimize error between the corresponding corrected interference and energy values and corresponding ones of the actual interference and energy values. 31. The apparatus in claim 30, wherein the apparatus is used in a spread spectrum radio communications system and the constants Ki and Ks are determined as a function a spreading factor used to spread information to be transmitted over an available frequency spectrum.32. Apparatus comprising:means for receiving a signal transmitted over a communications channel; means for determining an estimate of an energy value of the received signal; means for determining an interference value of the received signal; and means for correcting the energy value of the received signal for non-linearity; means for correcting the interference value of the received signal for non-linearity; and means for determining a corrected signal-to-interference ratio (SIR) value using the corrected energy value and the corrected interference value. 33. The apparatus in claim 32, wherein the means for correcting the interference value includes means for correcting the interference value in accordance with the following equation: Icorr=Io?Ki·Eb,where Icorr is the corrected interference value, Eb is the measured estimate energy value, Io is the measured estimate interference value, and Ki is a constant. 34. The apparatus in claim 33, wherein Ki is a constant depending on a spreading code associated with the transmitted signal.35. The apparatus in claim 34, wherein Ki is selected by simulation to minimize error between the corrected interference value and a corresponding actual interference value.36. The apparatus in claim 33, wherein the means for correcting the energy value includes means for correcting the energy value in accordance with the following equation: Ecorr=Eb?Ks·Icorr,where Ks is a constant. 37. The apparatus in claim 36, wherein Ks is a constant depending on a spreading code associated with the transmitted signal.38. The apparatus in claim 37, wherein Ks is selected by simulation to minimize error between the corrected energy value and a corresponding actual energy value.39. The apparatus in claim 32, wherein the means for correcting the interference value includes means for correcting the interference value in accordance with the following equation: Icorr=Io?Ki·Eb and the means for correcting the energy value includes means for correcting the energy value in accordance with the following equation: Ecorr=Eb?Ks·Icorr,where Eb is the measured estimate energy value, Io is the measured estimate interference value, Ki is a constant, Ks is a constant, where Ki and Ks depend on a spreading code associated with the transmitted signal and are selected by simulation to minimize error between the corresponding corrected interference and energy values and corresponding ones of the actual interference and energy values. 40. The apparatus in claim 39, wherein the apparatus is used in a spread spectrum radio communications system and the constants Ki and Ks are determined as a function a spreading factor used to spread information to be transmitted over an available frequency spectrum.
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