An in-depth assessment of the physical layer performance in the proposed B5G framework

IF 4.4 3区 计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS Ad Hoc Networks Pub Date : 2024-07-26 DOI:10.1016/j.adhoc.2024.103609
Juan Diego Belesaca , Andres Vazquez-Rodas , Luis F. Urquiza-Aguiar , J. David Vega-Sánchez
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Abstract

The introduction of fifth-generation (5G) technology marks a significant milestone in next-generation networks, offering higher data rates and new services. Achieving optimal performance in 5G and beyond 5G (B5G) systems requires addressing key requirements like increased capacity, high efficiency, improved performance, low latency, support for many connections, and quality of service. It is well-known that suboptimal network configuration, hardware impairments, or malfunctioning components can degrade system performance. The physical layer of the radio access network, particularly channel estimation and synchronization, plays a crucial role. Hence, this paper offers an in-depth evaluation of the 5G Physical Downlink Shared Channel (PDSCH), along with its related channel models such as the Clustered Delay Line (CDL) and the Tapped Delay Line (TDL). This work assesses 5G network performance through practical and IA-based channel estimation and synchronization techniques, and anticipates numerologies for B5G networks. Extensive simulations leveraging the Matlab 5G New Radio (NR) toolbox assess standardized channel scenarios in both macro-urban and indoor environments, following configurations set by the 3rd Generation Partnership Project (3GPP). The numerical results offer valuable insights into achieving the maximum achievable throughput across various channel environments, including both line-of-sight (LoS) and non-line-of-sight (NLoS) conditions. The throughput comparisons are performed under assumptions of ideal, realistic, and convolutional neural networks (CNN)-based channel estimation with both perfect and realistic synchronization conditions. Importantly, the study pinpoints certain physical layer elements that have a pronounced impact on system performance, providing essential insights for devising effective strategies or refining CNN-based methods for forthcoming mobile B5G networks.

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深入评估拟议 B5G 框架中的物理层性能
第五代(5G)技术的推出标志着下一代网络的一个重要里程碑,它将提供更高的数据传输速率和新的服务。要在 5G 和超越 5G (B5G) 系统中实现最佳性能,就必须满足一些关键要求,如增加容量、提高效率、改善性能、降低延迟、支持多种连接以及提高服务质量。众所周知,网络配置不理想、硬件损坏或组件故障都会降低系统性能。无线接入网络的物理层,尤其是信道估计和同步,起着至关重要的作用。因此,本文对 5G 物理下行链路共享信道(PDSCH)及其相关信道模型(如集群延迟线(CDL)和分接延迟线(TDL))进行了深入评估。这项工作通过实用的基于 IA 的信道估计和同步技术来评估 5G 网络性能,并预测 B5G 网络的数字技术。利用 Matlab 5G 新无线电(NR)工具箱进行了大量仿真,按照第三代合作伙伴关系项目(3GPP)设定的配置,评估了宏观城市和室内环境中的标准化信道场景。数值结果为在各种信道环境(包括视距(LoS)和非视距(NLoS)条件)下实现最大可实现吞吐量提供了有价值的见解。吞吐量比较是在理想、现实和基于卷积神经网络(CNN)的信道估计以及完美和现实同步条件的假设下进行的。重要的是,该研究指出了对系统性能有明显影响的某些物理层元素,为即将推出的移动 B5G 网络设计有效策略或改进基于 CNN 的方法提供了重要启示。
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来源期刊
Ad Hoc Networks
Ad Hoc Networks 工程技术-电信学
CiteScore
10.20
自引率
4.20%
发文量
131
审稿时长
4.8 months
期刊介绍: The Ad Hoc Networks is an international and archival journal providing a publication vehicle for complete coverage of all topics of interest to those involved in ad hoc and sensor networking areas. The Ad Hoc Networks considers original, high quality and unpublished contributions addressing all aspects of ad hoc and sensor networks. Specific areas of interest include, but are not limited to: Mobile and Wireless Ad Hoc Networks Sensor Networks Wireless Local and Personal Area Networks Home Networks Ad Hoc Networks of Autonomous Intelligent Systems Novel Architectures for Ad Hoc and Sensor Networks Self-organizing Network Architectures and Protocols Transport Layer Protocols Routing protocols (unicast, multicast, geocast, etc.) Media Access Control Techniques Error Control Schemes Power-Aware, Low-Power and Energy-Efficient Designs Synchronization and Scheduling Issues Mobility Management Mobility-Tolerant Communication Protocols Location Tracking and Location-based Services Resource and Information Management Security and Fault-Tolerance Issues Hardware and Software Platforms, Systems, and Testbeds Experimental and Prototype Results Quality-of-Service Issues Cross-Layer Interactions Scalability Issues Performance Analysis and Simulation of Protocols.
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