Abstract
This paper studies the optimal joint beamforming and power control strategy for device-to-device (D2D) communication underlaying multiuser multiple-input multiple-output cellular networks. We consider multiple antennas at the base station (BS) and a single antenna at each cellular user (CU), D2D transmitter (DT), and D2D receiver (DR). We aim to minimize the total transmission power of the system by jointly designing the transmit beamforming at the BS and the transmit powers for both BS and DTs, while satisfying the signal-to-interference-plus-noise ratio based quality-of-service constraints for both CUs and DRs. Due to the nonconvex nature of the problem, we apply the semidefinite relaxation technique to find the optimal solution, which always satisfies the rank-one constraint. We also investigate three suboptimal fixed beamforming schemes: zero-forcing (ZF), regularized ZF, and hybrid maximum ratio transmission-ZF, where the focus is to minimize the total transmission power while reducing complexity. When perfect channel information is not available, we propose a robust transmit power minimization strategy with ZF beamforming that only requires limited feedback based channel direction information at the BS. Finally, computer simulation results are presented to demonstrate the effectiveness of the proposed schemes.
Highlights
I N a device-to-device (D2D) wireless communication, two neighbouring or nearby users are allowed to communicate directly with limited or no participation of the cellular base station (BS) [1]
This paper investigated the D2D underlaying MU multiple-input multiple-output (MIMO) cellular system and proposed the joint beamforming and transmit power strategies
We studied both the optimal solution using semidefinite relaxation (SDR) and fixed beamforming schemes with the aim to reduce the total transmit power consumption
Summary
I N a device-to-device (D2D) wireless communication, two neighbouring or nearby users are allowed to communicate directly with limited or no participation of the cellular base station (BS) [1]. D2D has been shown to improve resource utilization, spectral efficiency, energy efficiency [3] and cellular coverage [4] of wireless networks. Due to these attractive features, it has been envisioned as a key technology for the fifth generation (5G) communication systems. Overlay refers to the approach where cellular users (CUs) and D2D receivers (DRs) use orthogonal spectrum resources, whereas underlay refers to the framework where both CUs and DRs utilize the same time/frequency resources. This study focuses on the inband D2D underlaying cellular systems, and below we present some relevant studies that have been carried
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