Abstract
The skyrocketing growth in the number of Internet of Things (IoT) devices has posed a huge traffic demand for fifth-generation (5G) wireless networks and beyond. In-band full-duplex (IBFD), which is theoretically expected to double the spectral efficiency of a half-duplex wireless channel and connect more devices, has been considered as a promising technology in order to accelerate the development of IoT. In order to exploit the full potential of IBFD, the key challenge is how to handle network interference (including self-interference, co-channel interference, and multiuser interference) more effectively. In this paper, we propose a simple yet efficient user grouping method, where a base station (BS) serves strong downlink users and weak uplink users and vice versa in different frequency bands, mitigating severe network interference. First, we aim to maximize a minimum rate among all of the users subject to bandwidth and power constraints, which is formulated as a nonconvex optimization problem. By leveraging the inner approximation framework, we develop a very efficient iterative algorithm for solving this problem, which guarantees at least a local optimal solution. The proposed iterative algorithm solves a simple convex program at each iteration, which can be further cast to a conic quadratic program. We then formulate the optimization problem of sum throughput maximization, which can be solved by the proposed algorithm after some slight modifications. Extensive numerical results are provided to show not only the benefit of using full-duplex radio at BS, but also the advantage of the proposed user grouping method.
Highlights
By 2023, it is estimated that the number of Internet of Things (IoT) devices will be 29.3 billions with a connection density of one-million devices per km2 [1]
Aiming at max-min throughput fairness, we propose a new user grouping method to divide all users into two groups, which are served in different frequency bands
In order to reduce the complexity that is caused by the downlink beamforming, which has been widely done by the previous works, we develop a ZF beamforming that requires solving the problem of scalar variables, instead of vectors
Summary
By 2023, it is estimated that the number of Internet of Things (IoT) devices will be 29.3 billions with a connection density of one-million devices per km2 [1]. The global mobile data traffic is projected to reach 49 exabytes per month in 2021, in which the IoT related data are the main driving force. These numbers are tremendous and will further increase over the coming years. In order to meet the aforementioned demands and accelerate the roll-out of the IoT, the industry and academic communities are currently investigating promising physical layer technologies for fifth-generation (5G) wireless networks and beyond, including multiple access techniques and in-band full-duplex (IBFD) communications [4,5,6,7,8].
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