NOMA schemes with symbol level processing

T-Comm Pub Date : 1900-01-01 DOI:10.36724/2072-8735-2022-16-5-4-14

M. Bakulin, T. B. Ben Rejeb, V. Kreyndelin, D. Pankratov, A. Smirnov

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Abstract

Requirements for KPI in 6G networks are significantly higher than in 5G networks. Non-orthogonal multiple access (NOMA) technology has been proposed as a solution to meet the requirements of future communication networks. NOMA technology aims to improve the spectral efficiency of wireless communication systems and support the simultaneous operation of large number of subscribers (especially in mMTC scenarios) and provide flexible resource use. This article discusses the popular symbol-level processing NOMA schemes recently proposed as part of the 3GPP standardization, such as SCMA, PDMA, WSMA, MUSA, and other varieties of NOMA. The main advantages and principles of non-orthogonal access technology are illustrated using the NOMA system with division in power domain (PD-NOMA) for uplink and downlink. Characteristics of various symbol-level processing NOMA schemes, their advantages and disadvantages, as well as problems in the way of their implementation in future wireless networks are analyzed. In addition, this article discusses block diagrams of NOMA systems and mathematical models illustrating the formation of baseband signals in such systems. In conclusion, the noise immunity characteristics of the most popular NOMA schemes with symbol-level processing are given for various loading factors. From the analysis performed, it follows that no NOMA scheme has yet been proposed that is effective in various scenarios of future wireless communication systems and has an acceptable processing complexity in combination with flexible resource allocation for mass connection of subscriber devices.

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具有符号级处理的NOMA方案

6G网络对KPI的要求明显高于5G网络。非正交多址(NOMA)技术是满足未来通信网络需求的一种解决方案。NOMA技术旨在提高无线通信系统的频谱效率，支持大量用户同时运行(特别是在mMTC场景下)，并提供灵活的资源利用。本文讨论了最近作为3GPP标准化的一部分提出的流行的符号级处理NOMA方案，如SCMA、PDMA、WSMA、MUSA和其他类型的NOMA。以功率域划分的非正交接入系统(PD-NOMA)为例，阐述了非正交接入技术的主要优点和原理。分析了各种符号级处理NOMA方案的特点、优缺点以及在未来无线网络中实现方式存在的问题。此外，本文还讨论了NOMA系统的框图和说明该系统中基带信号形成的数学模型。最后，给出了最常用的带有符号级处理的NOMA方案在不同负载因素下的抗噪特性。从所进行的分析可以看出，目前还没有提出一种NOMA方案，能够在未来无线通信系统的各种场景中有效，并且结合用户设备大规模连接的灵活资源分配，具有可接受的处理复杂性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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T-Comm

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