Alejandro de la Fuente, Giovanni Interdonato, Giuseppe Araniti
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引用次数: 0
Abstract
Massive multiple-input-multiple-output (MIMO) is unquestionably a key enabler
of the fifth-generation (5G) technology for mobile systems, enabling to meet
the high requirements of upcoming mobile broadband services. Physical-layer
multicasting refers to a technique for simultaneously serving multiple users,
demanding for the same service and sharing the same radio resources, with a
single transmission. Massive MIMO systems with multicast communications have
been so far studied under the ideal assumption of uncorrelated Rayleigh fading
channels. In this work, we consider a practical multicast massive MIMO system
over spatially correlated Rayleigh fading channels, investigating the impact of
the spatial channel correlation on the favorable propagation, hence on the
performance. We propose a subgrouping strategy for the multicast users based on
their channel correlation matrices' similarities. The proposed subgrouping
approach capitalizes on the spatial correlation to enhance the quality of the
channel estimation, and thereby the effectiveness of the precoding. Moreover,
we devise a max-min fairness (MMF) power allocation strategy that makes the
spectral efficiency (SE) among different multicast subgroups uniform. Lastly,
we propose a novel power allocation for uplink (UL) pilot transmission to
maximize the SE among the users within the same multicast subgroup. Simulation
results show a significant SE gain provided by our user subgrouping and power
allocation strategies. Importantly, we show how spatial channel correlation can
be exploited to enhance multicast massive MIMO communications.
大规模多输入多输出(MIMO)无疑是第五代(5G)移动系统技术的关键推动因素,能够满足即将到来的移动宽带服务的高要求。物理层多播指的是通过一次传输同时为多个用户提供服务的技术,这些用户需要相同的服务并共享相同的无线电资源。带组播通信的大规模多输入多输出系统迄今一直是在不相关的瑞利衰减信道的理想假设下进行研究的。在这项工作中,我们考虑了在空间相关的瑞利衰减信道上的实用多播大规模 MIMO 系统,研究了空间信道相关性对有利传播的影响,从而对性能的影响。我们提出了一种基于信道相关矩阵相似性的多播用户分组策略。建议的分组方法利用空间相关性来提高信道估计的质量,从而提高预编码的有效性。此外,我们还设计了一种最大最小公平(MMF)功率分配策略,使不同组播子组之间的光谱效率(SE)保持一致。最后,我们为上行链路(UL)先导传输提出了一种新的功率分配方案,以最大限度地提高同一组播子组内用户之间的光谱效率(SE)。仿真结果表明,我们的用户分组和功率分配策略带来了显著的 SE 增益。重要的是,我们展示了如何利用空间信道相关性来增强组播大规模 MIMO 通信。