RU2005116236A - ASSESSMENT OF THE CHANNEL STATUS FOR OFDM COMMUNICATION SYSTEMS - Google Patents

Claims (27)

1. The method of estimating the frequency response of a wireless channel, which consists in receiving an initial estimate of the frequency response of the wireless channel for the first group of subbands; and get an improved estimate of the frequency response of the wireless channel for the second group of subbands based on the initial estimate of the frequency response, and an improved estimate of the frequency response is obtained based on the impulse response of the wireless channel, which is implicitly or explicitly obtained based on the initial estimate of the frequency response. 2. The method according to claim 1, wherein the second group includes subbands of the first group. 3. The method according to claim 2, in which the second group further includes at least one additional subband not from the first group. 4. The method according to claim 1, in which the initial estimate of the frequency response of the channel is obtained based on the transmission of the pilot signal received in the subbands of the first group. 5. The method according to claim 4, in which an initial estimate of the channel frequency response is obtained based on the ratios of the received pilot symbols from all transmitted pilot symbols. 6. The method of claim 1, wherein the impulse response estimate is obtained based on a mean square estimate. 7. The method according to claim 1, in which additionally form the first matrix of the discrete Fourier transform (DFT) for the subbands of the first group, and the impulse response estimate is implicitly or explicitly additionally obtained based on the first DFT matrix. 8. The method according to claim 7, in which an additional second DFT matrix is formed for the subbands of the second group, and an improved frequency response estimate is further obtained based on the second DFT matrix. 9. The method according to claim 1, in which the first group of subbands is a subsystem of all subbands used for data transmission. 10. The method according to claim 9, in which the subbands of the first group are evenly distributed over the used subbands. 11. The method according to claim 1, in which the transmit power for the subbands of the first group is scaled so that the total transmit power is maintained at the maximum allowed level. 12. The method according to claim 11, in which the transmit power for each subband of the first group is increased by the M / S ratio relative to the average power level obtained by uniformly distributing the maximum allowed transmit power across all M subbands, where M is the number of subbands used for data transmission , and S is the number of subbands of the first group. 13. The method according to claim 1, in which the first group includes all subbands used for data transmission. 14. The method according to claim 1, in which the second group includes all subbands used for data transmission. 15. The method according to claim 1, in which the first group includes S subbands and the impulse response estimate for the wireless channel includes L tags, and wherein S is greater than or equal to L. 16. The method according to clause 15, in which S is approximately 1.1 · L. 17. The method according to claim 1, in which the subbands of the first and second groups are orthogonal subbands of the orthogonal frequency division multiplexing system (OFDM). 18. A method for evaluating the frequency response of a wireless channel in a communication system with orthogonal frequency division multiplexing (OFDM), which consists in obtaining an initial estimate of the frequency response of the wireless channel for the first group of subbands based on the transmission of the pilot signal received in the subbands of the first group wherein the first group of subbands is a subsystem of all subbands used for data transmission; and get an improved estimate of the frequency response of the wireless channel for the used subbands based on the initial estimate of the frequency response, wherein an improved estimate of the frequency response is obtained based on the estimate of the impulse response of the wireless channel, which is explicitly or implicitly obtained from the initial estimate of the frequency response, and an improved estimate frequency response is additionally obtained based on the first discrete Fourier transform (DFT) matrix for the subbands of the first group and the second DFT matrix for used oddiapazonov. 19. A method for estimating the frequency response of a wireless channel for each of a set of terminals in a wireless communication system, which consists in obtaining an initial estimate of the frequency response of a wireless channel for each of the set of terminals, each of which, respectively, is associated with one of the set of non-overlapping groups of subbands, and in this case, an initial estimate of the frequency response for each terminal is obtained for the corresponding groups of subbands based on the transmission of the pilot signal received in the subbands correspondingly cabbage group; and get an improved estimate of the frequency response of the wireless channel for each of the set of terminals based on the initial estimate of the frequency response of the terminal, and the improved estimate of the frequency response for each terminal covers a certain number of subbands and it is obtained based on the estimate of the impulse response of the wireless channel for the terminal, which is clearly or implicitly obtained based on the initial estimate of the frequency response for the terminal. 20. The method according to claim 19, in which a set of non-overlapping groups of subbands is formed from a set of used subbands, and wherein the subbands in each of the sets of non-overlapping groups are evenly distributed over the set of used subbands. 21. An apparatus configured to estimate a frequency response of a wireless channel, comprising: means for obtaining an initial estimate of the frequency response of a wireless channel for a first group of subbands; and means for obtaining an improved estimate of the frequency response of the wireless channel for the second group of subbands based on the impulse response estimate, wherein an improved estimate of the frequency response is obtained based on an estimate of the impulse response of the wireless channel, which is explicitly or implicitly based on the initial estimate of the frequency response. 22. The device according to item 21, in which the second group includes subbands of the first group and at least one additional subband not from the first group. 23. The device according to item 21, in which the estimate of the impulse response is obtained based on the first matrix of discrete Fourier transform (DFT) for the subbands of the first group, and an improved estimate of the frequency response is obtained on the basis of the second DFT matrix for the subbands second group. 24. An access point for a wireless communication system comprising a demodulator configured to receive pilot transmission from one or more terminals, the set of non-overlapping groups of subbands being formed from the set of used subbands, and each terminal transmits a pilot signal in a separate a subband group that is selected from a set of non-overlapping subband groups and assigned to the terminal; and a controller configured to obtain an initial estimate of the frequency response of the uplink channel for each terminal, wherein the initial estimate of the frequency response for each terminal covers a group of subbands assigned to the terminal, and is obtained based on the transmission of the pilot signal received from the terminal, and obtaining an improved estimate of the frequency response of the uplink channel for each of the terminals, based on the initial estimate of the frequency response for the terminal, and an improved estimate of the frequency response for each terminal is obtained based on the estimation of the wireless channel impulse response for the terminal that is implicitly or explicitly obtained, based on the initial frequency response estimate for the terminal. 25. The access point according to paragraph 24, in which the subbands in each of the set of non-overlapping groups are evenly distributed over the set of used subbands. 26. A wireless communication system terminal, comprising a demodulator configured to receive pilot transmission in a first group of subbands; and a controller configured to obtain an initial estimate of the frequency response of the downlink channel for the first group of subbands based on the transmission of the pilot signal received in the subbands of the first group and to obtain an improved estimate of the frequency response of the downlink channel for the second group of subbands based on an initial estimate of the frequency response, wherein an improved estimate of the frequency response is obtained based on an estimate of the impulse response of the wireless channel, which is obtained explicitly or implicitly, using odya of initial frequency response estimate. 27. The terminal of claim 26, wherein the second group includes subbands of the first group and at least one additional subband not from the first group.