Abstract
We consider a multiple-input single-output simultaneous wireless information and power transfer (MISO-SWIPT) system, where a power-splitting protocol is employed at users near the base station (BS) to provide both energy harvesting (EH) and information decoding. For the considered system, it is of practical interest to adopt non-orthogonal multiple access (NOMA) to improve the network spectral efficiency, while still meeting the EH requirements. In addition, an alternating current computing (ACC) logic is incorporated into EH receivers to directly use the wirelessly harvested AC power, which in turn achieves higher energy efficiency than traditional direct current computing (DCC). We formulate a problem of maximizing the spectral efficiency subject to the constraints of quality-of-service for the individual user, EH requirements, and BS’s maximum transmit power, where the beamformers and PS ratios are jointly optimized. To achieve an efficient solution to this nonconvex problem, we propose an iterative algorithm based on the inner approximation (IA) framework, where the approximate convex problem solved in each iteration can be cast as a second-order-cone program with convergence guaranteed. To further simplify the problem design, we propose a zero-forcing beamforming-based NOMA approach to partially eliminate interference, which has the potential to significantly reduce the number of variables. The extensive numerical results are presented to demonstrate the effectiveness of the proposed algorithms, compared with the baseline schemes.
Highlights
The fifth generation (5G) wireless network has been recognized as the panacea of the current wireless networks to meet a dramatic growth of wireless devices, new applications and demand for wireless data traffic [1]
In this paper, we have proposed an efficient non-orthogonal multiple access (NOMA)-assisted multiple-input single-output (MISO)-simultaneous wireless information and power transfer (SWIPT) system under a practical nonlinear energy harvesting (EH) circuit, where the power splitting (PS) protocol is adopted at the near users to realize both wireless radio frequency (RF)-EH and information decoding
We have investigated the problem of sum rate (SR) maximization under QoS requirement for individual user, EH constraints at near users and power constraint at the base station (BS), by jointly optimizing the beamformers and PS ratios
Summary
The fifth generation (5G) wireless network has been recognized as the panacea of the current wireless networks to meet a dramatic growth of wireless devices, new applications and demand for wireless data traffic [1]. One of the most challenging tasks in the SR maximization problem is to guarantee the quality-ofservice (QoS) in terms of data rate to users with poor channel condition, who are usually placed at the cell edge. Unlike with the traditional OMA techniques such as timedivision multiple access, NOMA aims at serving multiple users on the same time-frequency resource and allocating different power levels to them.. In the scenario of two users [5], the user with poorer channel condition is generally allocated higher transmission power than the user with better channel condition to improve the edge data rate, while the latter is capable of canceling the interference from the former by successive interference cancellation (SIC) technique. When multiple users have similar channel conditions, dynamic user pairing and clustering with distinct channel gains are effective ways to exploit the potential of NOMA in providing the massive connectivity requirement of 5G networks [6]–[9]
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