RU2009137373A - ASSESSING A CHANNEL USING FREQUENCY SMOOTHING - Google Patents

Abstract

 1. A method of supplying a frequency-smoothed tuning communication signal, comprising the steps of! form a frequency-smoothed unbiased training signal in the quadrature modulation transmitter, wherein the frequency-smoothed unbiased training signal includes! many pieces of pilot signals; ! moreover, each product of the pilot signals includes complex plane information represented by a reference frequency subcarrier multiplied by complex plane information represented by a mirror frequency subcarrier; and! wherein the sum of the plurality of pilot signal products is zero; and! provide a frequency-smoothed unbiased training signal within a single symbol period. ! 2. The method of claim 1, wherein the step of generating a frequency-smoothed unbiased training signal includes generating a frequency-smoothed unbiased training signal including a plurality of adjacent frequency reference subcarriers and a plurality of adjacent mirror frequency subcarriers. ! 3. The method of claim 2, wherein the step of generating a frequency-smoothed unbiased training signal includes generating a frequency-smoothed unbiased training signal including a group of adjacent reference frequency frequency subcarriers without intermediate subcarriers and a plurality of adjacent mirror frequency subcarriers without intermediate subcarriers. ! 4. The method according to claim 1, wherein the step of generating a frequency-smoothed unbiased training signal includes a step of generating a frequency-smoothed unbiased training signal c�

Claims (64)

1. A method of supplying a frequency-smoothed training signal, comprising the steps of: forming a frequency-smoothed unbiased training signal in the quadrature modulation transmitter, wherein the frequency-smoothed unbiased training signal includes many pieces of pilot signals; moreover, each product of the pilot signals includes complex plane information represented by a reference frequency subcarrier multiplied by complex plane information represented by a mirror frequency subcarrier; and wherein the sum of the plurality of pilot signal products is zero; and provide a frequency-smoothed unbiased training signal within a single symbol period. 2. The method of claim 1, wherein the step of generating a frequency-smoothed unbiased training signal includes generating a frequency-smoothed unbiased training signal including a plurality of adjacent reference frequency reference subcarriers and a plurality of adjacent mirror frequency subcarriers. 3. The method of claim 2, wherein the step of generating a frequency-smoothed unbiased training signal includes generating a frequency-smoothed unbiased training signal including a group of adjacent reference frequency frequency subcarriers without intermediate subcarriers and a plurality of adjacent mirror frequency subcarriers without intermediate subcarriers. 4. The method according to claim 1, wherein the step of generating a frequency-smoothed unbiased training signal includes a step of generating a frequency-smoothed unbiased training signal as follows: Σ p _i p _im = 0, i = from 1 to n; where p is the reference frequency subcarrier, where p _m is the mirror frequency subcarrier and where n is equal to the number of pilot signal products. 5. The method according to claim 4, in which the step of generating a frequency-smoothed unbiased training signal includes the step of generating a plurality of weighted products of the pilot signals as follows: Σ w _i p _i p _im = 0, i = from 1 to n; where w is the weight coefficient. 6. The method according to claim 1, wherein the step of generating a frequency-smoothed unbiased training signal includes generating a frequency-smoothed unbiased training signal, comprising using a number of pilot signal products selected from the group consisting of 2 and more than 2. 7. The method according to claim 1, in which the step of generating a frequency-smoothed unbiased training signal includes a step of generating a frequency-smoothed unbiased training signal in the following form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency + f representing the first value of the complex plane, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane + 180 °. 8. The method according to claim 1, wherein the step of generating a frequency-smoothed unbiased training signal includes a step of generating a frequency-smoothed unbiased training signal as follows: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency + f representing the first value of the complex plane + 90º, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane -90 °. 9. The method according to claim 7, in which the step of generating a frequency-smoothed unbiased training signal includes a step of generating P products of pilot signals; moreover, the method further comprises the steps at which form (N-P) communication data symbols and transmit N subcarriers in one symbol period, including a frequency-smoothed unbiased training signal and quadrature modulated communication data. 10. The method of claim 7, wherein the step of generating a frequency-smoothed unbiased training signal includes generating a frequency-smoothed unbiased training signal using a group of reference frequency subcarriers and corresponding mirror frequency subcarriers; moreover, the issuance of a frequency-smoothed unbiased training signal within a single symbol period includes the issuance of a frequency-smoothed training signal in a first symbol period; moreover, the method further comprises the steps at which generating quadrature modulated communication data on a group of reference frequency subcarriers and corresponding mirror frequency subcarriers and provide quadrature modulated communication data in a second symbol period following the first symbol period. 11. A method for calculating a channel estimate using a frequency-smoothed unbiased training signal, the method comprising the steps of receiving a frequency-smoothed unbiased training sequence in a quadrature demodulation receiver, wherein the frequency-smoothed unbiased training sequence includes a plurality of a plurality of pilot signal products; moreover, each product of the pilot signals includes predetermined information (p) of the complex plane represented by the reference frequency subcarrier (f) times the predetermined information (p _m ) of the complex plane represented by the mirror frequency subcarrier (-f); and wherein the sum of the plurality of pilot signal products is zero; and processing a frequency-smoothed unbiased training signal, generating a plurality of processed symbols (y) representing complex plane information; multiply each processed symbol (y) by the conjugate value of the corresponding reference signal (p ^* ); and receive a frequency-smoothed channel estimate (h). 12. The method of claim 11, wherein the step of receiving a frequency-smoothed unbiased training signal includes receiving a frequency-smoothed unbiased training signal including a plurality of adjacent reference frequency reference subcarriers and a plurality of adjacent mirror frequency subcarriers. 13. The method of claim 12, wherein the step of receiving a frequency-smoothed unbiased training signal includes receiving a frequency-smoothed unbiased training signal including a group of adjacent reference frequency frequency subcarriers without intermediate subcarriers and a plurality of adjacent mirror frequency subcarriers without intermediate subcarriers. 14. The method according to claim 11, in which the step of receiving a frequency-smoothed unbiased training signal includes the step of receiving a frequency-smoothed unbiased training signal, presented as: Σ p _i p _im = 0, i = from 1 to n; where p is the reference frequency subcarrier, where p _m is the mirror frequency subcarrier and where n is equal to the number of pilot signal products. 15. The method of claim 14, wherein the step of receiving a frequency-smoothed unbiased training signal includes a step of receiving a plurality of weighted products of the pilot signals, represented as: Σ w _i p _i p _im = 0, i = from 1 to n; where w is the weight coefficient. 16. The method of claim 11, wherein the step of receiving a frequency-smoothed unbiased training signal includes receiving a frequency-smoothed unbiased training signal with a number of pilot signal products selected from the group consisting of 2 or more 2 pieces. 17. The method according to claim 11, in which the step of receiving a frequency-smoothed unbiased training signal includes the step of receiving a frequency-smoothed unbiased training signal, presented in the form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency f + representing the first value of the complex plane, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane +180 °. 18. The method according to claim 11, in which the step of receiving a frequency-smoothed unbiased training signal includes a step of receiving a frequency-smoothed unbiased training signal, presented as: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency f + representing the first value of the complex plane + 90 °, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane -90 °. 19. The method of claim 17, wherein the step of receiving a frequency-smoothed unbiased training signal includes: receiving P products of pilot signals in a symbol period; moreover, the method further comprises the step of receive (N-P) symbols of communication data in a symbol period. 20. The method of claim 17, wherein the step of receiving a frequency-smoothed unbiased training signal includes receiving a frequency-smoothed unbiased training signal with a group of reference frequency subcarriers and corresponding mirror frequency subcarriers; moreover, the method further comprises the step of receive quadrature modulated communication data on a group of reference frequency subcarriers and corresponding mirror frequency subcarriers after receiving a frequency-smoothed unbiased training signal. 21. A system for supplying a frequency-smoothed training signal, comprising a transmitter having an input for receiving training information and an output for supplying a quadrature modulated and frequency-smoothed unbiased training signal, the frequency-smoothed unbiased training signal includes many pieces of pilot signals; moreover, each product of the pilot signals includes complex plane information represented by a reference frequency subcarrier multiplied by complex plane information represented by a mirror frequency subcarrier; and wherein the sum of the plurality of pilot signal products is zero; and moreover, the transmitter provides a frequency-smoothed unbiased training signal within a single symbol period. 22. The system of claim 21, wherein the transmitter generates a frequency-smoothed unbiased training signal including a plurality of adjacent reference frequency frequency subcarriers and a plurality of adjacent mirror frequency subcarriers. 23. The system of claim 22, wherein the transmitter generates a frequency-smoothed unbiased training signal including a group of adjacent reference frequency frequency subcarriers without intermediate subcarriers and a plurality of adjacent mirror frequency frequency subcarriers without intermediate subcarriers. 24. The system of claim 21, wherein the transmitter generates a frequency-smoothed unbiased training signal as follows: Σ p _i p _im = 0, i = from 1 to n; where p is the reference frequency subcarrier, where p _m is the mirror frequency subcarrier and where n is equal to the number of pilot signal products. 25. The system of claim 24, wherein the transmitter generates a plurality of weighted products of the pilot signals as follows: Σ w _i p _i p _im = 0, i = from 1 to n; where w is the weight coefficient. 26. The system of claim 21, wherein the transmitter generates a frequency-smoothed unbiased training signal using a number of pilot signal products selected from the group consisting of 2 or more than 2 products. 27. The system according to item 21, in which the transmitter generates a frequency-smoothed unbiased training signal in the following form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency + f representing the first value of the complex plane, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane + 180 °. 28. The system according to item 21, in which the transmitter generates a frequency-smoothed unbiased training signal in the following form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency + f representing the first value of the complex plane + 90 °, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value complex plane -90 °. 29. The system of claim 27, wherein the transmitter receives communication data in addition to training information, generates an unbiased frequency-smoothed training signal with P pilot products, generates (NP) communication data symbols, and supplies N subcarriers in one symbol period, including frequency-smoothed unbiased training signal and quadrature modulated communication data. 30. The system of claim 27, wherein the transmitter provides a frequency-smoothed unbiased training signal in a first symbol period using a group of reference frequency subcarriers and corresponding mirror frequency subcarriers; and wherein the transmitter receives communication data, generates quadrature modulated communication data in a group of reference frequency subcarriers and corresponding mirror frequency subcarriers, and supplies quadrature modulated communication data in a second symbol period following the first symbol period. 31. A system for calculating a channel estimate using a frequency-smoothed unbiased training signal, comprising a receiver having an input for receiving a frequency-smoothed unbiased training sequence and an output for supplying training information, the frequency-smoothed unbiased training sequence including a plurality of a plurality of pilot signal products; moreover, each product of the pilot signals includes predetermined information (p) of the complex plane represented by the reference frequency subcarrier (f) times the predetermined information (p _m ) of the complex plane represented by the mirror frequency subcarrier (-f); and wherein the sum of the plurality of pilot signal products is zero; and a processor having an input for receiving tuning information, the processor generating a plurality of processed symbols (y) representing complex plane information, multiplying each processed symbol (y) by the conjugate value of the corresponding reference signal (p ^* ), and provides a frequency-smoothed estimate (h) output channel. 32. The system of claim 31, wherein the receiver receives a frequency-smoothed unbiased training signal including a plurality of adjacent reference frequency frequency subcarriers and a plurality of adjacent mirror frequency subcarriers. 33. The system of claim 32, wherein the receiver receives a frequency-smoothed unbiased training signal including a group of adjacent reference frequency frequency subcarriers without intermediate subcarriers and a plurality of adjacent mirror frequency frequency subcarriers without intermediate subcarriers. 34. The system according to p, in which the receiver receives a frequency-smoothed unbiased training signal, presented in the form: Σ p _i p _im = 0, i = from 1 to n; where p is the reference frequency subcarrier, where p _m is the mirror frequency subcarrier and where n is equal to the number of pilot signal products. 35. The system of claim 34, wherein the receiver receives a plurality of weighted products of the pilot signals, presented as: Σ w _i p _i p _im = 0, i = from 1 to n; where w is the weight coefficient. 36. The system of claim 31, wherein the receiver receives a frequency-smoothed unbiased training signal with a number of pilot signal products selected from the group consisting of 2 or more than 2 products. 37. The system according to p, in which the receiver receives a frequency-smoothed unbiased training signal, presented in the form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency f + representing the first value of the complex plane, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane +180 °. 38. The system according to p, in which the receiver receives a frequency-smoothed unbiased training signal, presented in the form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency f + representing the first value of the complex plane + 90 °, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane -90 °. 39. The system of claim 37, wherein the receiver receives an unbiased frequency-smoothed training signal with P products of pilot signals and (N-P) communication data symbols in the same symbol period and provides both training information and communication data. 40. The system of claim 37, wherein the receiver receives a frequency-smoothed unbiased training signal in a first symbol period with a group of reference frequency subcarriers and corresponding mirror frequency subcarriers; and wherein the receiver receives quadrature modulated communication data in a group of reference frequency subcarriers and corresponding mirror frequency subcarriers in a second symbol period following the first symbol period, and provides communication data. 41. A computer-readable storage medium having instructions stored thereon for a frequency-smoothed communication tuning signal, the instructions comprising the formation of a quadrature modulated frequency-smoothed tuning signal, including many pieces of pilot signals; moreover, each product of the pilot signals includes complex plane information represented by a reference frequency subcarrier multiplied by complex plane information represented by a mirror frequency subcarrier; and wherein the sum of the plurality of pilot signal products is zero; and provide a frequency-smoothed unbiased training signal within a single symbol period. 42. A computer-readable storage medium having instructions stored therein for calculating a channel estimate using a frequency-smoothed unbiased communication tuning signal, the instructions comprising receiving a frequency-smoothed unbiased training sequence in a quadrature demodulation receiver, wherein the frequency-smoothed unbiased training sequence includes a plurality of a plurality of pilot signal products; moreover, each product of the pilot signals includes predetermined information (p) of the complex plane represented by the reference frequency subcarrier (f) times the predetermined information (p _m ) of the complex plane represented by the mirror frequency subcarrier (-f); and wherein the sum of the plurality of pilot signal products is zero; and processing a frequency-smoothed unbiased training signal, forming a plurality of processed symbols (y) representing complex plane information; multiply each processed symbol (y) by the conjugate value of the corresponding reference signal (p ^* ); receive a frequency-smoothed channel estimate (h). 43. A device for supplying a frequency-smoothed training signal, the device comprising signal generating means having an input for receiving training information and an output for supplying a quadrature modulated and frequency-smoothed unbiased training signal, wherein the frequency-smoothed unbiased training signal includes many pieces of pilot signals; wherein each product of pilot signals includes complex plane information represented by a reference frequency subcarrier multiplied by complex plane information represented by a mirror frequency subcarrier; and wherein the sum of the plurality of pilot signal products is zero; and moreover, the signal generating means supplies a frequency-smoothed unbiased training signal within a single symbol period. 44. The device according to item 43, in which the signal generating means generates a frequency-smoothed unbiased training signal, including a plurality of adjacent reference frequency reference subcarriers and a plurality of adjacent mirror frequency subcarriers. 45. The device according to item 44, in which the signal generating means generates a frequency-smoothed unbiased training signal including a group of adjacent reference frequency frequency subcarriers without intermediate subcarriers and a plurality of adjacent mirror frequency frequency subcarriers without intermediate subcarriers. 46. The device according to item 43, in which the signal generating means generates a frequency-smoothed unbiased training signal as follows: Σ p _i p _im = 0, i = from 1 to n; where p is the reference frequency subcarrier, where p _m is the mirror frequency subcarrier and where n is equal to the number of pilot signal products. 47. The device according to item 46, in which the means of generating signals generates many weighted products of the pilot signals as follows: Σ w _i p _i p _im = 0, i = from 1 to n; where w is the weight coefficient. 48. The device according to item 43, in which the signal generating means generates a frequency-smoothed unbiased training signal using a number of pilot signal products selected from the group consisting of 2 or more than 2 works. 49. The device according to item 43, in which the means of generating signals generates a frequency-smoothed unbiased training signal in the following form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency + f representing the first value of the complex plane, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane + 180 °. 50. The device according to item 43, in which the means of generating signals generates a frequency-smoothed unbiased training signal in the following form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency + f representing the first value of the complex plane + 90 °, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value complex plane -90 °. 51. The device according to § 49, in which the signal conditioning means receives communication data in addition to the training information, generates an unbiased frequency-smoothed training signal with P products of pilot signals, generates (NP) communication data symbols and supplies N subcarriers in one period symbol, including frequency-smoothed unbiased training signal and quadrature modulated communication data. 52. The apparatus of claim 49, wherein the signal generating means provides a frequency-smoothed unbiased training signal in a first symbol period using a group of reference frequency subcarriers and corresponding mirror frequency subcarriers; and moreover, the signal generating means receives communication data, generates quadrature modulated communication data in a group of reference frequency subcarriers and corresponding mirror frequency subcarriers, and supplies quadrature modulated communication data in a second symbol period following the first symbol period. 53. A device for calculating channel estimates using a frequency-smoothed unbiased training signal, the device comprising reception means having an input for receiving a frequency-smoothed unbiased training sequence and an output for supplying training information, the frequency-smoothed unbiased training sequence including a plurality of a plurality of pilot signal products; moreover, each product of the pilot signals includes predetermined information (p) of the complex plane represented by the reference frequency subcarrier (f) times the predetermined information (p _m ) of the complex plane represented by the mirror frequency subcarrier (-f); and wherein the sum of the plurality of pilot signal products is zero; and processing means having an input for receiving training information, the processing means generating a plurality of processed symbols (y) representing complex plane information, multiplying each processed symbol (y) by the conjugate value of the corresponding reference signal (p ^* ), and provides a frequency-smoothed estimate ( h) output channel. 54. The device according to item 53, in which the receiving means receives a frequency-smoothed unbiased training signal including a plurality of adjacent reference reference frequency subcarriers and a plurality of adjacent mirror frequency subcarriers. 55. The device according to item 54, in which the receiving means receives a frequency-smoothed unbiased training signal, including a group of adjacent reference frequency frequency subcarriers without intermediate subcarriers and a plurality of adjacent mirror frequency frequency subcarriers without intermediate subcarriers. 56. The device according to item 53, in which the receiving means receives a frequency-smoothed unbiased training signal, presented in the form: Σ p _i p _im = 0, i = from 1 to n; where p is the reference frequency subcarrier, where p _m is the mirror frequency subcarrier and where n is equal to the number of pilot signal products. 57. The device according to p, in which the receiving means receives a lot of weighted products of the pilot signals, presented in the form: Σ w _i p _i p _im = 0, i = from 1 to n; where w is the weight coefficient. 58. The device according to item 53, in which the receiving means receives a frequency-smoothed unbiased training signal with a number of pilot signal products selected from the group consisting of 2 or more than 2 products. 59. The device according to item 53, in which the receiving means receives a frequency-smoothed unbiased training signal, presented in the form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency f + representing the first value of the complex plane, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane + 180º . 60. The device according to item 53, in which the receiving means receives a frequency-smoothed unbiased training signal, presented in the form: the first product of the pilot signals with a reference subcarrier at a frequency + f representing information as the first value of the complex plane and a mirror subcarrier at a frequency-f representing the first value of the complex plane; and the second product of the pilot signals with a reference subcarrier at a frequency (f + 1), an adjacent frequency f + representing the first value of the complex plane + 90 °, and a mirror subcarrier at a frequency of (f + 1), an adjacent frequency -f representing the first value of the complex plane -90 °. 61. The device according to § 59, in which the receiving means receives an unbiased frequency-smoothed training signal with P products of pilot signals and (N-P) communication data symbols in the same symbol period and provides both training information and communication data. 62. The device according to § 59, in which the receiving means receives a frequency-smoothed unbiased training signal in a first symbol period with a group of reference frequency subcarriers and corresponding mirror frequency subcarriers; and wherein the receiving means receives quadrature modulated communication data in a group of reference frequency subcarriers and corresponding mirror frequency subcarriers in a second symbol period following the first symbol period, and provides communication data. 63. A processing device for generating a frequency-smoothed unbiased training signal, the processing device comprising a signal generator module having an input for receiving training information and an output for supplying a quadrature modulated and frequency-smoothed unbiased training signal, wherein the frequency-smoothed unbiased training signal includes many pieces of pilot signals; wherein each product of pilot signals includes complex plane information represented by a reference frequency subcarrier multiplied by complex plane information represented by a mirror frequency subcarrier; and wherein the sum of the plurality of pilot signal products is zero; and moreover, the signal generator module provides a frequency-smoothed unbiased training signal within a single symbol period. 64. A processing device for calculating a channel estimate using a frequency-smoothed unbiased training signal, the processing device comprising a receiver module having an input for receiving a frequency-smoothed unbiased training sequence and an output for supplying training information, the frequency-smoothed unbiased training sequence including a plurality of a plurality of pilot signal products; moreover, each product of the pilot signals includes predetermined information (p) of the complex plane represented by the reference frequency subcarrier (f) times the predetermined information (p _m ) of the complex plane represented by the mirror frequency subcarrier (-f); and wherein the sum of the plurality of pilot signal products is zero; and a calculation module having an input for receiving tuning information, the calculation module generating a plurality of processed symbols (y) representing complex plane information, multiplying each processed symbol (y) by the conjugate value of the corresponding reference signal (p ^* ), and provides a frequency-smoothed estimate ( h) output channel.