On The Effective Capacity Performance Analysis Over Nakagami-m Distribution-Based Double-Shadowed Rician Fading Channel

IF 1.6 4区 地球科学 Q3 ASTRONOMY & ASTROPHYSICS
Radio Science Pub Date : 2024-04-10 DOI:10.1029/2023rs007868
Rajnish K. Ranjan, Atanu Chowdhury, Dibyendu Ghoshal
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引用次数: 0

Abstract

The practical applications within the domain of the fifth generation (5G) and the emerging beyond 5G network necessitate a high data transmission rate along with minimal achievable delay. With this objective in focus, the maximum capacity is extensively quantified through the utilization of the delay-constrained effective capacity (EC) technique, which stands in contrast to Shannon's ergodic capacity. The current study is engaged in the analysis of EC within a delay-limited wireless system operating in a double-shadowed Rician (DSR) fading channel. Within this channel, only the Nakagami-m distribution concept has been applied to both the dominant and secondary shadowing components of the proposed network model. A new exact closed-form expression for EC within the DSR fading channel has been derived using the Fox-H function. Furthermore, an analysis has been conducted for both high and low signal-to-noise ratios to provide further insights and explanations for the proposed model. It is worth noting that the results obtained from both simulation and analytical methods exhibit substantial similarity, revealing interdependence among various parameters present in the proposed model.
基于 Nakagami-m 分布的双影 Rician Fading 信道的有效容量性能分析
第五代(5G)和新兴的超越 5G 网络领域的实际应用需要高数据传输速率和最小的可实现延迟。基于这一目标,最大容量通过利用延迟受限有效容量(EC)技术得到了广泛量化,这与香农的遍历容量形成了鲜明对比。目前的研究主要是分析在双影 Rician(DSR)衰减信道中运行的延迟受限无线系统中的有效容量。在该信道中,只有 Nakagami-m 分布概念被应用于拟议网络模型的主要和次要阴影部分。利用 Fox-H 函数推导出了 DSR 衰减信道中 EC 的新精确闭式表达式。此外,还对高信噪比和低信噪比进行了分析,以进一步深入了解和解释所提出的模型。值得注意的是,模拟和分析方法得出的结果具有很大的相似性,揭示了拟议模型中各种参数之间的相互依存关系。
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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来源期刊
Radio Science
Radio Science 工程技术-地球化学与地球物理
CiteScore
3.30
自引率
12.50%
发文量
112
审稿时长
1 months
期刊介绍: Radio Science (RDS) publishes original scientific contributions on radio-frequency electromagnetic-propagation and its applications. Contributions covering measurement, modelling, prediction and forecasting techniques pertinent to fields and waves - including antennas, signals and systems, the terrestrial and space environment and radio propagation problems in radio astronomy - are welcome. Contributions may address propagation through, interaction with, and remote sensing of structures, geophysical media, plasmas, and materials, as well as the application of radio frequency electromagnetic techniques to remote sensing of the Earth and other bodies in the solar system.
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