Abstract
Full-duplex (FD) is a promising technology for increasing the spectral efficiency of next-generation wireless communication systems. A major technical challenge in enabling FD in a real network is to remove the self-interference (SI) caused by simultaneous transmission and reception at the transceiver, and the SI cancellation performance depends significantly on the estimation accuracy of the SI channel. In this study, we proposed a novel partial SI channel training method for minimizing the residual SI power for FD massive multiple-input multiple-output (MIMO) systems. Based on an SI channel training framework under a limited training overhead, using the proposed scheme, the BS estimates only a part of the SI channel vectors, while skipping the channel training for the other remaining SI channel vectors by using their last estimates. With this partial training framework, the proposed scheme finds the optimal partial SI channel training strategy for pilot allocation to minimize the expected residual SI power, considering the time-varying Rician fading channel model for the SI channel. Therefore, the proposed scheme can improve the sum-rate performance compared with other simple partial training schemes for FD massive MIMO systems under a limited training overhead. Numerical results confirm the effectiveness of the proposed scheme for FD massive MIMO systems compared with the full training scheme, as well as other partial training schemes.
Highlights
Fifth-generation (5G) wireless communication systems, called new radio (NR), have been successfully commercialized at a global level [1,2]
The base station (BS) antenna and pilot resource allocations were arbitrarily applied for every transmission block during random training, whereas the BS antenna was sequentially selected in a round-robin manner according to the selection of the last transmission block during the round-robin training
The zero-forcing (ZF) beamformer was employed for DL transmission, whereas the ZF receiver was employed for UL reception
Summary
Fifth-generation (5G) wireless communication systems, called new radio (NR), have been successfully commercialized at a global level [1,2]. In this study, we propose an efficient SI channel estimation framework based on a partial training strategy for FD massive MIMO systems. The pilot signals for SI channel training are allocated to a number of massive BS antennas to satisfy the limited training overhead constraint, and only a part of the SI channel vectors among the entire SI channel matrix corresponding to the allocated BS antennas is estimated for each transmission block. To find an optimal training strategy under the proposed SI channel training framework, we formulated an optimization problem to minimize the expected residual SI power after the SIC operation To this end, we analyzed and derived a closed-form expression of the expected residual SI power in terms of pilot allocation. CN (0, 1) represents a complex Gaussian random variable with zero mean and unit variance
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