飞对飞(F2F)通信:5G无线回程的下一个演进步骤

Anup Chaudhari, C. Murthy
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引用次数: 5

摘要

未来的5G蜂窝网络预计将支持数倍增长的数据流量和设备数量,并提供极低延迟和千兆速率的数据服务。为了满足这些需求,毫米波(mmWave)通信(30-300 GHz)被提议成为5G蜂窝网络的重要组成部分。由于大多数高数据速率需求来自室内用户设备(ue),传统的有线回程链路被证明是一个主要瓶颈。因此,在Femto基站(FBSs)中探索毫米波无线回程链路。为了获得毫米波回程链路的最大效益,有效利用资源(数据槽)是必要的。适当调度毫米波回程链路将有助于实现这一目标。在本文中,我们提出了一种新的FBS-to-FBS (F2F)通信方案,它不仅有助于卸载来自微基站(MiBS)的数据流量,而且可以作为其他fbs的中继链路,将回程流量路由到MiBS。考虑到FBS-to-MiBS (F2M)和F2F链路共存,我们还提出了一种毫米波无线回程链路并发调度的解决方案,以提高资源利用率。我们提出的解决方案包括两个部分:首先,根据定向天线的不同波瓣的朝向,通过找出干扰距离的上界来确定哪些回程链路可以同时调度;其次,根据各链路的服务质量(QoS)要求对传输功率进行调节,进一步控制干扰,增加并发传输数。通过仿真研究了该方案的优点,并与时分多址(TDMA)和随机调度方案进行了比较。
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Femto-to-Femto (F2F) communication: The next evolution step in 5G wireless backhauling
The future 5G cellular networks are expected to support several-fold increase in data traffic and number of devices, and provide a very low latency and gigabit-rate data services. millimeter Wave (mmWave) communication (30–300 GHz) is proposed to be an important part of the 5G cellular networks to fulfill these requirements. With most of the high data rate demands originating from indoor User Equipments (UEs), conventional wired backhaul links prove to be a major bottleneck. Hence, mmWave wireless backhaul links are explored at Femto Base Stations (FBSs). In order to derive maximum benefit of mmWave backhaul links, efficient resource (data slots) utilization is necessary. Proper scheduling of mmWave backhaul links will help to achieve the same. In this paper, we propose a novel FBS-to-FBS (F2F) communication scheme which not only helps in offloading the data traffic from the Micro Base Station (MiBS) but also can act as a relay link for the other FBSs for routing the backhaul traffic to the MiBS. We also propose a solution to concurrently schedule mmWave wireless backhaul links to increase the resource utilization considering the coexistence of both FBS-to-MiBS (F2M) and F2F links. Our proposed solution consists of two parts — first, it determines which backhaul links can be scheduled concurrently by finding the upper bound for the interfering distance based on the alignment of different lobes of the directional antennas. Second, the transmit power is throttled to match the Quality of Service (QoS) requirements of each link aiming to further control the interference and to increase the number of concurrent transmissions. The benefits of the proposed solution are studied and compared with the Time Division Multiple Access (TDMA) and random scheduling schemes using extensive simulations.
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Keynote speaker Keynote speaker Ad-Hoc, Mobile, and Wireless Networks: 19th International Conference on Ad-Hoc Networks and Wireless, ADHOC-NOW 2020, Bari, Italy, October 19–21, 2020, Proceedings Retraction Note to: Mobility Aided Context-Aware Forwarding Approach for Destination-Less OppNets Ad-Hoc, Mobile, and Wireless Networks: 18th International Conference on Ad-Hoc Networks and Wireless, ADHOC-NOW 2019, Luxembourg, Luxembourg, October 1–3, 2019, Proceedings
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