RU2007103333A - METHOD AND DEVICE FOR SUPPRESSING INTERFERENCE FROM A PILOT SIGNAL IN A WIRELESS COMMUNICATION SYSTEM - Google Patents

Claims (56)

1. The receiving unit is configured to receive a radio signal containing at least the first and second copies of the signal, with each copy of the signal containing data and a pilot signal containing processor configured with the option determining a first channel estimate for the first copy of the signal; using the first channel estimate and the extended pilot associated with the first copy of the signal to estimate the first pilot signal of the first copy of the signal; determining a second channel estimate for the second copy of the signal; and using a second channel estimate and an extended pilot associated with the second copy of the signal to estimate the second pilot signal of the second copy of the signal; and a buffer configured to accumulate the estimated first and second pilot signals, wherein the processor is configured to subtract the accumulated estimated first and second pilot signals from the received signal to evaluate the received signal with the suppressed pilot signal, the processor configured to use the estimated received signal with the suppressed a pilot signal for demodulating the data of the first copy of the signal. 2. The receiving unit according to claim 1, in which the radio signal comprises a code division multiple access (CDMA) signal. 3. The receiving unit according to claim 1, configured to receive the first and second copies of signals from the first and second remote terminals, respectively. 4. The receiving unit according to claim 1, in which the first and second copies of the signals are components of multipath signal propagation from one remote terminal. 5. The receiving unit according to claim 1, wherein the buffer is further configured to accumulate (a) an estimated first pilot signal corresponding to a first estimated time offset of the first copy of the signal, and (b) an estimated second pilot signal corresponding to a second estimated time offset of the second copy signal. 6. The receiving unit according to claim 1, further comprising a sample buffer configured to store a radio signal with a sampling frequency that is a multiple of the frequency of the radio signal chips. 7. The receiving unit according to claim 6, in which the sampling frequency of the sample buffer is equal to the sampling frequency of the buffer accumulating the estimated pilot signals. 8. The receiving unit according to claim 1, in which each extended pilot signal contains a pilot signal, expandable by a pseudo-random noise (PN) sequence. 9. The receiving unit according to claim 1, in which the first channel estimate, the advanced pilot signal associated with the first copy of the signal, and the first estimated pilot signal correspond to the segment of the received signal, the segment containing data samples for the time period of the received signal. 10. The receiving unit according to claim 1, in which the processor is further configured to determining a first noise estimate of the first copy of the signal; obtaining a suppression coefficient α based on a first channel estimate and a first noise estimate; multiplying the first channel estimate by the suppression coefficient to obtain a weighted channel estimate; and using a weighted channel estimate and an extended pilot associated with the first copy of the signal to estimate the first pilot signal of the first copy of the signal. 11. The receiving unit of claim 10, in which the suppression coefficient α is obtained from

where h is the first channel estimate, N _t is the first noise estimate, and N is the number of samples used to estimate h and N _{t of the} first copy of the signal. 12. The receiving unit of claim 10, in which the suppression ratio is ranked from 0 to 1.0. 13. The receiving unit of claim 10, in which the suppression ratio is ranked from 0 to a value greater than 1.0. 14. The receiving unit of claim 10, further comprising a lookup table with a set of channel estimates and noise estimates corresponding to the suppression coefficient. 15. The receiving unit according to claim 1, in which the processor is further configured to multiplying the first channel estimate by convolution of the transmitted pulse and the function of the receiving filter; and performing convolution (a) of the extended pilot signal associated with the first copy of the signal, and (b) the product of the first channel estimate and convolution of the transmitted pulse and the receive filter function of the first pilot signal of the first copy of the signal. 16. The receiving unit according to clause 15, in which the transmitted pulse is determined by the code division multiple access (CDMA) standard. 17. The receiving unit according to clause 15, in which the processor is configured to lower the sampling frequency of at least one of the following: (a) convolution of the transmitted pulse and the function of the receive filter and (b) convolution (i) of the extended pilot signal associated with the first signal mops, and (ii) the product of the first channel estimate and convolution of the transmitted pulse and the function of the receive filter to bring it into line with the buffer speed. 18. The receiving unit according to clause 15, in which the processor is configured to increase the sampling rate of at least one of the following: (a) convolution of a given transmit pulse and the function of the receive filter and (b) convolution (i) of the extended pilot signal associated with the first copy of the signal, and (ii) the product of the first channel estimate and convolution of the given transmit pulse and the function of the receive filter to bring it into line with the buffer speed. 19. The receiving unit according to clause 15, in which the processor is configured to decimation of the convolution of samples of a given transmitted pulse and the function of the receiving filter corresponding to the phase associated with the estimated time shift of the first copy of the signal; multiplying the first channel estimate by thinned convolutional samples of a given transmitted pulse and the receiving filter function; and performing convolution of the extended pilot signal associated with the first copy of the signal, and the product of the first channel estimation and decimated samples to evaluate the first pilot signal of the first copy of the signal. 20. The receiving unit according to clause 15, further comprising a multiphase filter with a finite impulse response (FIR), configured to decimation of convolution samples of a given transmitted pulse and a receiving filter function corresponding to the phase associated with the estimated time shift of the first copy of the signal; multiplying the first channel estimate by thinned convolutional samples of a given transmitted pulse and the receiving filter function; and performing convolution of the extended pilot signal associated with the first copy of the signal, and the product of the first channel estimation and decimated samples to evaluate the first pilot signal of the first copy of the signal. 21. The receiver unit of claim 15, further comprising a filtering table of predetermined filtering coefficients that correspond to a plurality of different phases, the processor being configured to select a phase and corresponding filtering coefficients based on the estimated time offset of the first copy of the signal. 22. The receiving unit according to claim 1, in which the processor is further configured to filter the estimated received signal with the suppressed pilot signal by convolution of a given transmit pulse and the function of the receive filter. 23. The receiving unit according to claim 1, in which the processor is configured to determine the first channel estimate and use the first channel estimate and the extended pilot signal associated with the first copy of the signal to estimate the first pilot signal of the first copy of the signal essentially in parallel with the determination of the second channel estimating and using the second channel estimate and the extended pilot associated with the second copy of the signal to estimate the second pilot signal of the second copy of the signal. 24. The receiving unit according to claim 1, wherein the processor is configured to evaluate pilot signals for multiple copies of the signals by time division multiplexing. 25. A transmission system comprising a base station configured to receive a radio signal containing at least first and second copies of the signals, each copy of the signal containing data and a pilot signal, while the base station contains processor configured with the option determining a first channel estimate for the first copy of the signal; using the first channel estimate and the extended pilot associated with the first copy of the signal to estimate the first pilot signal of the first copy of the signal; determining a second channel estimate for the second copy of the signal; and using a second channel estimate and an extended pilot associated with the second copy of the signal to estimate the second pilot signal of the second copy of the signal; and a memory configured to accumulate the estimated first and second pilot signals, wherein the processor is configured to subtract the accumulated estimated first and second pilot signals from the received signal to evaluate the received signal with the suppressed pilot signal, wherein the processor is configured to use the estimated received signal with the suppressed a pilot signal for demodulating the data of the first copy of the signal. 26. The transmission system of claim 25, wherein the processor is further configured to multiplying the first channel estimate by convolution of a given transmitted pulse and the function of the receiving filter; and performing convolution (a) of the extended pilot signal associated with the first copy of the signal, and (b) the product of the first channel estimate and the convolution of the given transmit pulse and the receive filter function to evaluate the first pilot signal of the first copy of the signal. 27. The transmission system of claim 25, wherein the base station comprises a plurality of antennas and a plurality of buffers in memory, each buffer configured to accumulate estimated pilot signals copies of signals received by one antenna. 28. The transmission system of claim 25, wherein the base station comprises a plurality of antennas, the memory having a single buffer configured to accumulate estimated pilot signals copies of signals received by the multiple antennas. 29. The transmission system according A.25, in which the base station contains X antennas and Y buffers in memory, and X is greater than Y, while at least one buffer is configured to accumulate the estimated pilot signal copies of the signals received by two or more antennas. 30. A receiving unit comprising means for receiving a radio signal comprising at least a first and a second copy of the signal, each copy of the signal containing data and a pilot signal; means for determining a first channel estimate for the first copy of the signal; means for obtaining a product of a first channel estimate and convolution of a given transmitted pulse and a receiving filter function; means for using the product of the first channel estimate and convolution to estimate the first pilot signal of the first copy of the signal; means for determining a second channel estimate of the second copy of the signal; means for obtaining the product of the second channel estimate and convolution of a given transmitted pulse and the function of the receiving filter; means for using the product of the second channel estimate and convolution to estimate the second pilot signal of the second copy of the signal; means for accumulating the estimated first and second pilot signals; and means for subtracting the accumulated estimated first and second pilot signals from the received signal to obtain the estimated received signal with the suppressed pilot signal. 31. The method consists in the fact that receive a radio signal containing at least the first and second copies of the signal, with each copy of the signal containing data and a pilot signal; determining a first channel estimate for the first copy of the signal; get the product of the first channel estimate and convolution of a given transmitted pulse and the function of the receiving filter; using the product of the first channel estimate and convolution to estimate the first pilot signal of the first copy of the signal; determining a second channel estimate for the second copy of the signal; get the product of the second channel estimate and convolution of a given transmitted pulse and the function of the receiving filter; using the product of the second channel estimate and convolution to estimate the second pilot signal of the second copy of the signal; accumulate estimated first and second pilot signals; and subtracting the accumulated estimated first and second pilot signals from the received signal to obtain the estimated received signal with the suppressed pilot. 32. The method according to p, in which when receiving a radio signal receive the first and second copies of signals from the first and second terminals. 33. The method according to p, in which each copy of the signal has an estimated time offset due to the transmitting path of the copy signal. 34. The method of claim 31, wherein the radio signal comprises a code division multiple access (CDMA) signal. 35. The method according to p, in which the radio signal is transmitted from the terminal to the base station. 36. The method according to p, in which the radio signal is transmitted from the base station to the terminal. 37. The method according to p, in which additionally buffer the received radio signal with a sampling frequency that is a multiple of the frequency of the chips. 38. The method according to p, in which when determining the first channel estimate for the first copy of the signal compressing the samples of the received signal using the spreading sequence associated with the first copy of the signal to obtain compressed samples; deforming the channels of the compressed samples using a pilot channelization code to obtain pilot symbols; and filter the pilot signal to obtain a first channel estimate. 39. The method according to p, in which when determining the first channel estimate for the first copy of the signals using the first segment of the data samples from the received signal, the first estimated pilot signal corresponds to the first segment of the data samples. 40. The method according to § 39, in which the first segment contains data samples for the time period of the received signal. 41. The method according to p, in which additionally determining a noise estimate of the first copy of the signal; obtaining a suppression coefficient based on the channel estimate and the noise estimate of the first copy of the signal; and multiplying the first channel estimate by the suppression coefficient to obtain a weighted channel estimate; using a weighted channel estimate and an extended pilot associated with the first copy of the signal to estimate the first pilot signal of the first copy of the signal. 42. The method according to paragraph 41, in which when obtaining the coefficient of suppression α use

where h is the first channel estimate, N _t is the noise estimate, and N is the number of samples used to estimate h and N _t for the first copy of the signal. 43. The method according to p, in which additionally thin out the convolution samples of a given transmitted pulse and the receiving filter function corresponding to the phase associated with the estimated time shift of the first copy of the signal; multiplying the first channel estimate by thinned convolutional samples of a given transmitted pulse and the receiving filter function; and performing the convolution of the extended pilot signal and the product of the first channel estimation and thinned samples to estimate the first pilot signal of the first copy of the signal. 44. The method according to p, in which additionally selecting a phase based on the estimated time offset of the first copy of the signal; using the selected phase to find the specified filtering coefficients, while the specified filtering coefficients correspond to the convolution of a previously transmitted pulse and the function of the receiving filter; and multiply the first channel estimate by the found filter coefficients. 45. The method according to p, in which when using the product of the first channel estimation and convolution to estimate the first pilot signal of the first copy of the signal, the convolution (a) of the product of the channel estimation and convolution and (b) the extended pilot signal associated with the first copy of the signal is performed. 46. The method according to item 45, in which the first channel estimate, the advanced pilot signal associated with the first copy of the signal, and the first estimated pilot signal correspond to the first segment of the received signal, the first segment containing data samples for the time period of the received signal. 47. The method of claim 45, wherein the enhanced pilot associated with the first copy of the signal has a phase corresponding to the arrival time of the first copy of the signal. 48. The method according to p, in which additionally use the estimated received signal with the suppressed pilot signal to demodulate the data of the first copy of the signal. 49. The method according to p, in which when using the estimated received signal with the suppressed pilot signal to demodulate data of the first copy of the signal compressing the samples of the estimated received signal with the suppressed pilot signal using the spreading sequence for the first copy of the signal to obtain compressed samples; carry out the deformation of the channel of compressed samples using the code for forming the data channel to obtain data symbols; and demodulating data symbols with a first channel estimate for the first copy of the signal to obtain demodulated data for the first copy of the signal. 50. The method according to p, in which determining the first channel estimate, obtaining the product of the first channel estimate and convolution, and using the product to estimate the first pilot signal of the first copy of the signal essentially occurs in parallel with determining the second channel estimate, obtaining the product of the second channel estimate and convolution and using the product to estimate the second pilot signal of the second copy of the signal. 51. The method of claim 31, wherein said determining the first channel estimate, obtaining the product of the first channel estimate and convolution, and using the product to estimate the first pilot signal of the first copy of the signal occurs by the time division multiplexing method, determining the second channel estimate, obtaining the product second channel estimation and convolution and using the product to estimate the second pilot signal of the second copy of the signal. 52. The method according to p. 31, in which the accumulated estimated first and second pilot signals accumulate (a) the estimated first pilot signal corresponding to the first estimated time offset of the first copy of the signal, and (b) the estimated second pilot signal corresponding to the second estimated time offset second copy of the signal. 53. The method according to p, in which the accumulation of the estimated first and second pilot signals occurs with a given sampling frequency of the received signal. 54. The method according to item 53, in which the sampling frequency is a multiple of the frequency of the chips. 55. The method consists in the fact that receive a radio signal containing at least the first and second copies of the signal, with each copy of the signal containing data and a pilot signal; determining a first channel estimate for the first copy of the signal; using the first channel estimate to estimate the first pilot signal of the first copy of the signal; determining a second channel estimate for the second copy of the signal; using a second channel estimate to estimate the second pilot signal of the second copy of the signal; accumulate the estimated first and second pilot signals; filtering the accumulated estimated first and second pilot signals with the convolution of a given transmitted pulse and the receiving filter function; and the filtered accumulated estimated first and second pilot signals are subtracted from the received signal to obtain the estimated received signal with the suppressed pilot. 56. The method consists in the fact that receive a radio signal containing at least a first and a second copy of the signal, with each copy of the signal containing data and a pilot signal; processing (a) a convolution of a given transmit pulse and a receive filter function; and (b) an expanded pilot signal associated with the first copy of the signal to generate reconstructed samples of the pilot signal of the first copy of the signal; determining a first channel estimate for the first copy of the signal; multiplying the reconstructed pilot samples with a first channel estimate to obtain a first pilot signal estimate of the first signal copy; processing (a) a convolution of a given transmit pulse and a receiving filter function; and (b) an expanded pilot signal associated with the second copy of the signal to generate reconstructed samples of the pilot signal of the second copy of the signal; determining a second channel estimate for the second copy of the signal; multiplying the reconstructed pilot samples of the second signal copy by a second channel estimate to obtain a second pilot signal estimate of the second signal copy; accumulate the first and second estimates of the pilot signal; and subtracting the accumulated first and second estimates of the pilot signal from the received signal to obtain the estimated received signal with the suppressed pilot signal.