用于广域物联网网络主干的动态全双工蜂窝系统

IF 5.3 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Open Journal of Vehicular Technology Pub Date : 2024-08-26 DOI:10.1109/OJVT.2024.3450279
Keiichi Mizutani;Kazuki Nishikori;Kyoya Teramae;Hiroto Kuriki;Takeshi Matsumura;Hiroshi Harada
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引用次数: 0

摘要

本研究通过在基于时分双工(TDD)的传统蜂窝系统中分阶段引入带内全双工,提出了一种动态全双工蜂窝(DDC)系统。此外,我们还为密集城市多蜂窝环境中的 DDC 提出并评估了适当的用户设备(UE)调度和传输功率控制方案。所提出的 DDC 通过完全分布式资源分配充分抑制了小区间干扰,不需要在相邻小区之间交换信息。其中,传播损耗补偿因子、UE 发射功率限制和假定的上行信噪比加干扰功率比(SINR)调整因子被证明是至关重要的。通过适当设置这些系数,与传统 TDD 系统相比,拟议的 DDC 系统下行链路 (DL) 平均吞吐量提高了 13.2%,上行链路提高了 31.6%。此外,我们还观察到下行链路 5%用户吞吐量提高了 2.5%。通过提高有限频谱资源的利用效率,特别是在 6 GHz 以下频段,本研究的结果有望为实现大容量广域物联网网络骨干做出贡献。
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Dynamic Full-Duplex Cellular System for Wide Area IoT Network Backbone
This study proposes a dynamic full-duplex cellular (DDC) system by introducing an in-band full-duplex in a phased manner into a conventional time-division duplex (TDD)-based cellular system. Further, we propose and evaluate appropriate user equipment (UE) scheduling and transmission power control schemes for DDC in dense urban multi-cell environments. The proposed DDC sufficiently suppresses inter-cell interference through fully distributed resource allocation, which does not require information exchange among neighboring cells. In particular, the propagation loss compensation factor, UE transmission power limit, and assumed uplink signal-to-noise plus interference power ratio (SINR) adjustment factor prove to be essential. By appropriately setting these factors, the proposed DDC system improves the average throughput of the downlink (DL) by 13.2% and uplink by 31.6% compared with the conventional TDD system. Moreover, we observe a 2.5% improvement in the DL 5% user throughput. The results of this study are expected to contribute to the realization of a high-capacity wide-area IoT network backbone by improving the efficiency of utilization of limited spectral resources, especially in the sub-6 GHz band.
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CiteScore
9.60
自引率
0.00%
发文量
25
审稿时长
10 weeks
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