Method for signal transmission to multiple user equipments utilizing reciprocity of wireless channel

The invention claimed is: 1. A method for signal transmission, applied in a multi-user, multi-antenna system operating in a Time Division Duplex (TDD) mode and comprising a base station and a number, K, of User Equipments (UEs), the base station being configured with M antennas, each UE being configured with one receiving antenna or configured to combine signals from a plurality of receiving antennas to obtain one scalar channel output, each UE maintaining synchronization with the base station, one downlink transmission period being discretized into T timeslots, reciprocal uplink and downlink channels remaining unchanged during the T timeslots, an uplink channel from a UE k to the base station being denoted as h k , a downlink channel from the base station to the UE k being denoted as h k † , where † denotes conjugate transpose, the method comprising: S1: in the first timeslot, transmitting, by the UE k, a constant signal to the base station, such that a signal received by the base station is a simple addition of an uplink channel from the UE to the base station and a noise, i.e., y BS [1]=Σ k=1 K h k +z BS [1], where y BS [1] denotes a signal received by the base station in the first timeslot and z BS [1] denotes a noise at the base station; S2: in the second timeslot, multiplying, by the base station, the signal y BS [1] received in the first timeslot with a power adjustment factor a and feeding ay BS [1] back to all the UEs by means of broadcast, such that a signal received by a UE j in the second timeslot is y j [2]=h j † ay BS [1]+z j [2]≙g j +z j [2], where z j [2] is a noise at the UE j and g j =a(h j † Σ k=1 K h k +h j † z BS [1]), and the UE j estimates g j based on the signal y j [2] received in the second timeslot to obtain an estimated value ĝ j ; and S3: in the t-th timeslot, where t=3, . . . , T, precoding, by the base station, a signal x BS [t] to be broadcasted to the UEs in the t-th timeslot based on ay BS [1], and broadcasting ax BS [t]y BS [1] to all the UEs, such that a signal received by the UE j in the t-th timeslot is y j [t]=g j x BS [t]+z j [t], where z j [t] is a noise at the UE j, and the UE j demodulates x BS [t] based on ĝ j . 2. The method of claim 1 , wherein in the step S1, the constant signal is normalized to a transmission power of the UE. 3. The method of claim 1 , wherein in the step S1, the noise z BS [1] at the base station is an independent and identically distributed Gaussian noise, i.e., z BS [1]˜CN (0,σ BS 2 I M ), where σ BS 2 is a noise power at the base station, I M is an M-dimensional identity matrix, and CN (0,σ BS 2 I M ) denotes an M-dimensional cyclically symmetric complex Gaussian distribution having a mean value of 0 and a covariance matrix of σ BS 2 I M . 4. The method of claim 1 , wherein in the step S2, the power adjustment factor a satisfies a=1/√{square root over (MK)}. 5. The method of claim 1 , wherein in the step S2, the noise z j [2] at the UE j is a Gaussian noise, i.e., z j [2]˜CN (0,σ UE 2 ), where σ UE 2 is a noise power at the UE, and CN (0,σ UE 2 ) denotes a cyclically symmetric complex Gaussian distribution having a mean value of 0 and a covariance matrix of σ UE 2 . 6. The method of claim 1 , wherein in the step S2, ĝ j is estimated using a least square method, i.e., ĝ j =y j [2]. 7. A method for signal transmission, applied in a multi-user, multi-antenna system comprising a base station and a plurality of User Equipments (UEs), the UEs being divided into a number of groups, the UEs in different groups occupying different sub-carriers and the UEs in each group transmitting signals according to the method of claim 1 . 8. A method for signal transmission, applied in a multi-user, multi-antenna system operating in a Time Division Duplex (TDD) mode and comprising a base station and a number, K, of User Equipments (UEs), the base station being configured with M antennas, each UE being configured with one receiving antenna or configured to combine signals from a plurality of receiving antennas to obtain one scalar channel output, each UE maintaining synchronization with the base station, one downlink transmission period being discretized into T timeslots, reciprocal uplink and downlink channels remaining unchanged during the T timeslots, an uplink channel from a UE k to the base station being denoted as h k , a downlink channel from the base station to the UE k being denoted as h k † , the method comprising: S1: in the first timeslot, transmitting, by the UE k, a constant signal to the base station, such that a signal received by the base station is a simple addition of an uplink channel from the UE to the base station and a noise, i.e., y BS [1]=Σ k=1 K h k +z BS [1], where y BS [1] denotes a signal received by the base station in the first timeslot and z BS [1] denotes a noise at the base station; and S2: in the t-th timeslot, where t=2, . . . , T, applying, by the base station, a differential modulation to data to be broadcasted to the UEs in the t-th timeslot, so as to obtain a modulated signal x BS [t] first, then multiplying the signal y BS [1] received in the first timeslot with a power adjustment factor a, precoding x BS [t] based on ay BS [1], and broadcasting ax BS [t]y BS [1] to all the UEs, such that a signal received by a UE j in the t-th timeslot is y j [t]=h j † ay BS [1]x BS [t]≙g j x BS [t]+z j [t], where z j [t] is a noise at the UE j, g j =a(h j † Σ k=1 K h k +h j † z BS [1]), and the UE j applies incoherent differential demodulation to the signal broadcasted from the base station without performing any explicit channel estimation. 9. The method of claim 8 , wherein in the step S1, the constant signal is normalized to a transmission power of the UE. 10. The method of claim 8 , wherein in the step S1, the noise z BS [1] at the base station is an independent and identically distributed Gaussian noise, i.e., z BS [1]˜CN (0,σ BS 2 I M ), where σ BS 2 is a noise power at the base station, I M is an M-dimensional identity matrix, and CN (0,σ BS 2 I M ) denotes an M-dimensional cyclically symmetric complex Gaussian distribution having a mean value of 0 and a covariance matrix of σ BS 2 I M . 11. The method of claim 8 , wherein in the step S2, the power adjustment factor a satisfies a=1/√{square root over (MK)}. 12. The method of claim 8 , wherein in the step S2, the noise z j [2] at the UE j is a Gaussian noise, i.e., z j [2]˜CN (0,σ UE 2 ), where σ UE 2 is a noise power at the UE, and CN (0,σ UE 2 ) denotes a cyclically symmetric complex Gaussian distribution having a mean value of 0 and a covariance matrix of σ UE 2 . 13. A method for signal transmission, applied in a multi-user, multi-antenna system comprising a base station and a plurality of User Equipments (UEs), the UEs being divided into a number of groups, the UEs in different groups occupying different sub-carriers and the UEs in each group transmitting signals according to the method of claim 8 .