多网融合无人机网络辅助的低空盲区接入系统- “空天地一体化智能网联”专刊

doi:10.7527/S1000-6893.2026.32901

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多网融合无人机网络辅助的低空盲区接入系统- “空天地一体化智能网联”专刊

梁一博¹,朱小军²,董超²

1. 南京航空航天大学计算机科学与技术学院
2. 南京航空航天大学

收稿日期:2025-10-13 修回日期:2026-01-06 出版日期:2026-01-09 发布日期:2026-01-09
通讯作者: 朱小军
基金资助:
国家自然科学基金

Multi-network integrated UAV network assisted low-altitude access system for blind zone

Yi-Bo LIANG¹,Xiaojun Zhu², ²

1. College of Computer Science and Technology, Nanjing University of Aeronautics and Astronautics
2.

Received:2025-10-13 Revised:2026-01-06 Online:2026-01-09 Published:2026-01-09
Contact: Xiaojun Zhu
Supported by:
National Natural Science Foundation of China

摘要/Abstract

摘要： 灾害现场、海上平台、江面上空等区域存在蜂窝信号盲区，低空飞行器工作时面临无法接入系统、难以与后端控制中心通信的问题。现有方法通过在地面上部署专用蜂窝基站，或在无人机上加装卫星通信模块，实现网络接入，成本较高。设计并实现了多网融合无人机网络辅助的接入系统，该系统由网关无人机、中继无人机、提供接入服务的无人机组成，无人机之间通过自组网连接，将数据从提供接入服务的无人机，通过中继无人机多跳转发至网关无人机。系统使用商用的低成本嵌入式设备与自组网模块，实现了自动网络配置、无缝漫游、会话保持等功能。在原型系统实验中，无人机节点能在3秒内完成自组织部署，在0.65秒内实现漫游切换，实现了上行吞吐量11.15 Mbps，下行吞吐量15.98 Mbps，在低空动态变化的网络拓扑场景中，系统能够在1.5秒内完成路由收敛，低于OLSR路由协议的4.15秒，有效通信距离延伸至近1 km，单节点综合能耗不超过100W。系统在覆盖范围、连接稳定性和业务连续性方面表现良好，以低成本为低空通信盲区提供可靠的网络接入服务。

关键词: 低空智联网, 低空空域, 多网融合, 网络接入, 无人机网络

Abstract: In areas such as disaster sites, offshore platforms, and above river surfaces, there are signal blind spots for cellular networks. When low-altitude aircraft operate, they may not be able to connect to the system and communicate with the control center. Existing methods achieve network coverage by deploying dedicated cellular base stations on the ground or installing satellite communication modules on the aircraft, but these methods are expensive. A multi-network fusion unmanned aerial vehicle (UAV) network-assisted access system has been designed and implemented. This system consists of gateway UAVs, relay UAVs, and UAVs providing access services. The UAVs are connected through ad hoc networks, and data is relayed from the UAV providing access services to the gateway UAV via the relay UAVs and multi-hop transmission. The system uses commercial low-cost embedded devices and ad hoc network modules to achieve functions such as automatic network configuration, seamless roaming, and session persistence. In prototype system experiments, UAV nodes can complete self-organization deployment within 3 seconds and achieve roaming switching within 0.65 seconds, with an uplink throughput of 11.15 Mbps and a downlink throughput of 15.98 Mbps. Under dynamically changing low-altitude topologies, the system completes routing convergence within 1.5 seconds, significantly outperforming the OLSR routing protocol about 4.15 seconds. The effective communication distance is extended to nearly 1 km, and the per-node total power consumption remains below 100 W, which is considerably lower than existing UAV-based communication solutions. The system performs well in terms of coverage, connection stability, and business continuity, providing reliable network access services for low-altitude communication blind areas at a low cost.

Key words: low-altitude intelligent network, low-altitude airspace, multi-network integration, network access, UAV networks

中图分类号:

V243.1

梁一博朱小军董超. 多网融合无人机网络辅助的低空盲区接入系统- “空天地一体化智能网联”专刊[J]. 航空学报, doi: 10.7527/S1000-6893.2026.32901.

Yi-Bo LIANG Xiaojun Zhu. Multi-network integrated UAV network assisted low-altitude access system for blind zone[J]. Acta Aeronautica et Astronautica Sinica, doi: 10.7527/S1000-6893.2026.32901.

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主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

多网融合无人机网络辅助的低空盲区接入系统- “空天地一体化智能网联”专刊

Multi-network integrated UAV network assisted low-altitude access system for blind zone

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