RU2003131399A - SPACE-TEMPORARY CODE WITH NON-ZERO COMPLEX WEIGHING FOR TRANSMISSION OF ANTENNA MULTIPLE - Google Patents

Claims (20)

1. A method of transmitting a signal from multiple antennas, comprising the steps of receiving a symbol stream at a transmitter, converting an input symbol stream to generate a conversion result containing an orthogonal space-time block code NxN ', and generating N first signals, performing non-zero complex weighting , during the time of at least one of the N first signals of the conversion result to generate at least one second signal, each of which changes in phase at least one second signal with respect to one of the N first signals from which it was generated, wherein said non-zero complex weighting includes a phase shift of at least one of the N first signals in accordance with at least a first predetermined sequence of phase jump wherein the weights of the phase jump for the mentioned phase jump sequence are obtained from the phase shift keying diagram (QPS) having 8 states and I the phase jump sequence in degrees is (0, 135, 270, 45, 180, 315, 90, 225), and each of the N first signals of the conversion result from the first at least one antenna is transmitted essentially simultaneously at least one second signal from the second at least one antenna, said N first signals and said at least one second signal together contain M signals, where M is greater than N. 2. An apparatus for transmitting a signal from a plurality of antennas, comprising the steps of including an input symbol stream, a processor for converting an input symbol stream to generate a conversion result, the conversion result comprising an orthogonal space-time block code N × N ′, and generating N the first signals, at least one non-zero complex weighting device for at least one of the N first signals of the conversion result to generate at least one second signal, wherein each of the at least one second weighted signal is phase shifted relative to one of the N first signals from which it was generated, and wherein said non-zero complex weighting includes a phase shift of at least one of the N first signals in accordance with at least a first predetermined phase hopping sequence, wherein the phase hopping weights for said hopping sequence the phases are obtained from a phase shift keying diagram (QPSK) having 8 states, and the predetermined sequence of phase jump in degrees is (0, 135, 270, 45, 180, 315, 90, 225), and a transmitter for transmitting substantially simultaneously each of the N first signals of the conversion result from the first at least one antenna and each of the at least one second signal from the second at least one antenna, said N first signals and said at least one second signal together contain M signals, where M is greater , I eat N. 3. The method according to claim 1, characterized in that at least one second signal that is phase shifted relative to one of the N signals from which it was generated at the stage of non-zero complex weighing, is two second signals, including the first one of at least one second signal and at least a second one of at least one second signal, wherein at least a first predetermined phase hopping sequence includes a first predetermined hopping sequence phase changes in degrees (0, 135, 270, 45, 180, 315, 90, 225) and at least a second predetermined sequence of phase jump, and the second predetermined sequence of phase jump in degrees is (180, 315, 90, 225, 0, 135, 270, 45). 4. The method according to claim 3, characterized in that the first one of the at least one second signal is phase shifted using a first predetermined sequence of phase hopping, and the second one of the at least one second signal is phase shifted using a second predetermined phase jump sequences. 5. The method according to claim 4, characterized in that the phase shift jumps of the first predetermined phase jump sequence and the second predetermined phase jump sequence, by which the first and second of the second signals are respectively phase shifted at the non-zero complex weighting step, are repeated sequentially with consecutive selected intervals. 6. The method according to claim 5, characterized in that the successive selected intervals, with which the phase jumps of the first and second predetermined phase jump sequences sequentially repeating, phase shifting the first and second of the second signals, consist of periodic intervals. 7. The method according to claim 4, characterized in that the jumps in phase shifts of the first predetermined sequence of abrupt phase change and the second predetermined sequence of abrupt phase change, in accordance with which the first and second of the second signals are respectively phase shifted at the stage of non-zero complex weighing, follow at random intervals. 8. The method according to claim 1, characterized in that jumps in phase shifts of a given sequence of phase-hopping, in accordance with which at least one of the second signals is phase-shifted at the stage of non-zero complex weighing, is followed at successive intervals. 9. The method according to claim 5, characterized in that the successive selected intervals with which the phase jumps of the predetermined sequence of the phase jump, phase shifting at least one of the second signals are successively repeated contain periodic intervals. 10. The method according to claim 1, characterized in that jumps in phase shifts of a given sequence of abrupt phase change, in accordance with which at least one of the second signals is phase-shifted at the stage of non-zero complex weighing, is followed at random intervals. 11. The device according to claim 2, characterized in that at least one second signal that is phase-shifted relative to one of the N signals from which it was generated by the at least one weighing device, contains the first of the second signals and at least at least the second of the second signals, and at least the first predetermined phase jump sequence includes a first predetermined phase jump sequence in degrees (0, 135, 270, 45, 180, 315, 90, 225) and at least a second second the given sequence of phase jump, and the second predetermined sequence of phase jump in degrees is (180, 315, 90, 225, 0, 135, 270, 45). 12. The device according to claim 11, characterized in that the first of the second signals is phase shifted using a first predetermined phase jump sequence, and the second of the second signals is phase shifted using a second predetermined phase jump sequence. 13. The device according to p. 12, characterized in that the jumps of the phase shift of the first predetermined sequence of abrupt phase changes and the second specified phase jump sequences by which the first and second of the second signals are respectively phase shifted by the at least one weighing device, are successively repeated at successive selected intervals. 14. The device according to p. 12, characterized in that the successive selected intervals with which the jumps in phase shifts of the first and second predetermined phase jump sequences sequentially repeating, phase shifting the first and second of the second signals, consist of periodic intervals. 15. The device according to p. 12, characterized in that the jumps of phase shifts of the first predetermined sequence of abrupt phase change and the second predetermined sequence of abrupt phase change, in accordance with which the first and second of the second signals are respectively phase shifted by at least one weighing device follow at random intervals. 16. The device according to claim 11, characterized in that said at least one weighing device comprises a first weighing device for non-zero complex weighing of the first of the first of N first signals generated by the processor, and a second weighing device for non-zero complex weighing of the second of the first of N first signals generated by the processor. 17. The device according to clause 16, wherein the first weighing device phase outsets the first of the first signal through the first predetermined phase jump sequence, and the second weighing device phase outs the second of the first signal through the second predetermined phase jump sequence. 18. The device according to claim 2, characterized in that jumps in phase shifts of a given sequence of abrupt phase change, in accordance with which at least one second signal is phase shifted by means of at least one weighing device at sequentially selected intervals. 19. The device according to p. 18, characterized in that the consecutive selected intervals, which sequentially repeat the phase jumps of a given sequence of abrupt phase changes, phase shifting at least one second signal, contain periodic intervals. 20. The device according to claim 2, characterized in that jumps in phase shifts of a given sequence of phase-hopping, in accordance with which at least one second of the second signal is phase shifted by at least one weighing device, are followed at random intervals.