Cost-Effective Delay-Constrained Optical Fronthaul Design for 5G and Beyond

Pub Date : 2022-01-01 DOI:10.36244/icj.2022.2.2

A. Fayad, T. Cinkler

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引用次数: 4

Abstract

With the rapid growth of the telecom sector heading towards 5G and 6G and the emergence of high-bandwidth and time-sensitive applications, mobile network operators (MNOs) are driven to plan their networks to meet these new requirements in a cost-effective manner. The cloud radio access network (CRAN) has been presented as a promising architecture that can decrease capital expenditures (Capex) and operating expenditures (Opex) and improve network performance. The fronthaul (FH) is a part of the network that links the remote radio head (RRH) to the baseband unit (BBU); these links need high-capacity and low latency connections necessitating costeffective implementation. On the other hand, the transport delay and FH deployment costs increase if the BBU is not placed in an appropriate location. In this paper, we propose an integer linear program (ILP) that simultaneously optimizes BBU and FH deployment resulting in minimal capital expenditures (Capex). Simulations are run to compare the performance of star and tree topologies with the varying line of sight probabilities (LoS) and delay thresholds. We consider fiber-optic (FO) and free-space optics (FSO) technologies as FH for the CRAN. Finally, we provide an analysis of Opex and the total costs of ownership (TCO), i.e., a technoeconomic analysis.

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5G及以后的高性价比延迟约束光前传设计

随着电信行业向5G和6G的快速发展，以及高带宽和时间敏感应用的出现，移动网络运营商(mno)被推动以经济高效的方式规划其网络，以满足这些新需求。云无线接入网(CRAN)已经被认为是一种很有前途的架构，可以降低资本支出(Capex)和运营支出(Opex)，并提高网络性能。前传(FH)是将远程无线电头(RRH)连接到基带单元(BBU)的网络的一部分;这些链接需要高容量和低延迟的连接，因此需要具有成本效益的实现。另一方面，如果BBU放置位置不合适，则会增加传输延迟和跳频部署成本。在本文中，我们提出了一个整数线性计划(ILP)，同时优化BBU和FH部署，从而实现最小的资本支出(Capex)。仿真比较了不同视距概率(LoS)和延迟阈值下星形和树形拓扑的性能。我们考虑了光纤(FO)和自由空间光学(FSO)技术作为CRAN的跳频。最后，我们提供了运营成本和总拥有成本(TCO)的分析，即技术经济分析。

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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