多无人机基站在应急场景下的空中组网覆盖解决方案

随着无人机技术的不断发展,其在各个领域的应用日益广泛,特别是在应急通信领域,无人机搭载通信装备能够快速、灵活地建立通信网络,完成空对地的信号覆盖,为抗灾救援提供可靠的通信支持。当灾害发生时,陆面通信基础设施可能受到损坏,特别是在“断路、断电、断网”的三断场景中,传统的应急通信基站车,不能第一时间赶赴灾害现场,为受灾区域提供通信救援保障。而无人机可以搭载4G/5G基站、非视距Mesh等装备,通过中星16、中星26、亚太6D等高通量卫星建立传输通道,快速开展空中通信组网,为救援区域提供广覆盖、高容量的通信服务,确保救援人员、指挥中心和受灾群众之间的信息畅通,提高救援效率和指挥决策的准确性。

仿雁群阵列量子空中通信组网构建策略

量子卫星通信是量子通信领域的研究热点和前沿,具有覆盖面广、通信效率高和安全性强的特点.量子通信组网的构建策略是量子通信的重要组成部分,然而,有关量子空中通信组网构建策略的研究,迄今尚未展开.本文采用仿生学原理,根据雁群空中飞行阵列的特点,提出了一种仿雁群Λ型量子空中通信组网拓扑结构,该结构可分为单头节点Λ型和多头节点Λ型.基于Greenberger-Horne-Zeilinger (GHZ)态的可认证QSDC网间通信系统和GHZ-EPR (Einstein-Podolsky-Rosen)量子卫星组网隐形传态通信系统,对该Λ型量子空中通信组网结构的误码率、能耗、吞吐率等参数进行了研究.理论分析和仿真结果表明,仿雁群单头节点Λ型组网结构,在噪声平均功率谱密度为2 dB/m的环境中,当网中头节点与子节点的通信距离小于400 m时,误码率小于0.094;若头节点与子节点的通信距离由400 m增大到1000 m时,误码率增长较快,达到0.585;当单侧子节点数由2增加到7时,吞吐率由110.6 kb/s下降到46.45 kb/s.以总节点数21为例,单头节点Λ型组网结构可节省32.6%的能量,吞吐率下降到23.9 kb/s.相比之下,总节点数为21的多头节点Λ型组网结构,可节省29.3%的能量,吞吐率达到163.4 kb/s.由此可见,采用仿雁群阵列结构的量子空中组网,具有很好的网络可扩展性、优良的信息安全性和灵活的网络结构.

Relay movement control for maintaining connectivity in aeronautical ad hoc networks

As a new sort of mobile ad hoc network(MANET), aeronautical ad hoc network(AANET) has fleet-moving airborne nodes(ANs) and suffers from frequent network partitioning due to the rapid-changing topology. In this work, the additional relay nodes(RNs) is employed to repair the network and maintain connectivity in AANET. As ANs move, RNs need to move as well in order to re-establish the topology as quickly as possible. The network model and problem definition are firstly given, and then an online approach for RNs' movement control is presented to make ANs achieve certain connectivity requirement during run time. By defining the minimum cost feasible moving matrix(MCFM), a fast algorithm is proposed for RNs' movement control problem. Simulations demonstrate that the proposed algorithm outperforms other control approaches in the highly-dynamic environment and is of great potential to be applied in AANET.