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面向 6G 的多维扩展通感一体化研究综述

徐金雷 赵俊湦 卢华兵 蒋旭 赵楠

徐金雷, 赵俊湦, 卢华兵, 蒋旭, 赵楠. 面向 6G 的多维扩展通感一体化研究综述[J]. 电子与信息学报, 2024, 46(5): 1672-1683. doi: 10.11999/JEIT231045
引用本文: 徐金雷, 赵俊湦, 卢华兵, 蒋旭, 赵楠. 面向 6G 的多维扩展通感一体化研究综述[J]. 电子与信息学报, 2024, 46(5): 1672-1683. doi: 10.11999/JEIT231045
XU Jinlei, ZHAO Junsheng, LU Huabing, JIANG Xu, ZHAO Nan. An Overview on Multi-dimensional Expanded Integrated Sensing and Communication for 6G[J]. Journal of Electronics & Information Technology, 2024, 46(5): 1672-1683. doi: 10.11999/JEIT231045
Citation: XU Jinlei, ZHAO Junsheng, LU Huabing, JIANG Xu, ZHAO Nan. An Overview on Multi-dimensional Expanded Integrated Sensing and Communication for 6G[J]. Journal of Electronics & Information Technology, 2024, 46(5): 1672-1683. doi: 10.11999/JEIT231045

面向 6G 的多维扩展通感一体化研究综述

doi: 10.11999/JEIT231045
基金项目: 国家重点研发计划 (2020YFB1807002),国家自然科学基金(62371087, 62101091), 辽宁省应用基础研究计划 (2023TH2/101300197)
详细信息
    作者简介:

    徐金雷:男,博士生,研究方向为通感一体化、无人机通信、智能反射面

    赵俊湦:男,高级工程师/副教授,研究方向为通信产业趋势、通感一体化、无人机通信

    卢华兵:男,博士,研究方向为通感一体化、无人机通信、物理层安全

    蒋旭:男,副教授,研究方向为通感一体化、无人机通信、隐蔽通信

    赵楠:男,教授,博士生导师,研究方向为通感一体化、无人机通信、 绿色通信

    通讯作者:

    赵楠 zhaonan@dlut.edu.cn

  • 中图分类号: TN915.0

An Overview on Multi-dimensional Expanded Integrated Sensing and Communication for 6G

Funds: The National Key R&D Program of China (2020YFB1807002), The National Natural Science Foundation of China (62371087, 62101091), The Application and Fundamental Research Planning Project in Liaoning Province (2023TH2/101300197)
  • 摘要: 面对第6代移动通信(6G)网络立体覆盖的互联感知需求和无线设备广泛接入造成的频谱稀缺问题,基于无人机(UAV)的机动性和智能反射面(IRS)重构无线传播环境特性的多维扩展通感一体化可实现立体网络空间中通信和感知功能的相互协同,有效提升频谱效率和硬件资源的利用率,满足6G万物智联的无线网络愿景。该文针对6G多维扩展通感一体化网络架构展开综述。首先,概述了 6G网络愿景和通感一体化的理论基础,并讨论基于UAV和IRS多维扩展通感一体化的应用场景、发展趋势和性能指标。然后,探讨了超大规模多输入多输出天线、太赫兹、无线携能通信、人工智能、隐蔽通信和有源反射面等6G关键前沿技术在基于无人机和智能反射面多维扩展通感一体化网络中的潜在应用。最后,展望了未来6G多维扩展通感一体化的发展方向及关键技术挑战。
  • 图  1  面向6G的新场景演进

    图  2  多小区协作的通感一体化网络

    图  3  无人机通感一体化网络

    图  4  基于IRS-UAV多维扩展的通感一体化

    表  1  基于UAV和IRS多维扩展的通感一体化网络应用场景

    场景/应用分类 同步成像与环境重构 高精度定位与跟踪 增强人类感官 动作和表情识别
    智慧工厂 区域检测和环境感知 设备定位和安装 自动化测量和控制 产品质量检测
    垂直行业 智慧农业 作物生理监测和生产 自动化收取和存储 种植环境检测 作物质量监管
    智慧交通 3D道路成像 无人驾驶与辅助驾驶 雨雾天气路况监测 安全驾驶
    环境监测 无人机集群管理 水利水文监测 污染与空气质量检测 残障保障服务
    公共服务 公共安全 灾害应急管理和疏散 交通运输安全 无接触安全检测 突发事件预测
    城市管理 城市环境监督 城市文明监察 建筑安全风险检测 全时段监控
    灾难救援 灾情评估与灾后重建 人员定位与物资投送 灾区环境检测 人员搜救
    极端场景 战场支援 实时情报获取 精确打击支持 敌对目标监视和侦测 敌情侦测与分析
    应用 太空探测 地球和大气监测 太空垃圾探测 星际空间探测 航天员健康检测
    海洋勘探 海洋资源勘探 海上巡逻与航行安全 海洋气象和气候监测 海洋生态监测
    下载: 导出CSV

    表  2  现有ISAC和波形设计简要总结

    参考文献 ISAC波形设计 技术原理 优点 缺点
    文献[26, 27] 以感知为基础的设计 将通信信号调制或引入感知系统中,在不影响
    感知功能情况下实现通信功能
    与感知系统高度兼容 低数据速率
    文献[28, 29] 以通信为基础的设计 利用通信波形、协议和架构进行感知,
    通过目标回波提取感知信息
    与通信系统高度兼容 感知性能差
    文献 [3032] 通感一体联合优
    化设计
    兼顾通信和感知的需求和性能指标 高性能感知和通信 设计复杂度高
    下载: 导出CSV

    表  3  基于UAV和IRS的多维扩展通感一体化网络性能指标

    性能分类 性能指标 具体要求
    通信性能 带宽和速率
    稳定性
    传输数据的速度和容量,较大的带宽能够支持高分辨率图像、视频等大数据传输
    保障UAV在高速运动和复杂环境中通信连接的可靠性,防止干扰和信号丢失
    感知性能 感知范围
    感知精度
    感知功能的有效覆盖区域,UAV和IRS可提供更广泛的环境信息
    感知系统识别目标和获取环境信息的准确度和可靠性,影响系统的决策能力
    多源数据
    融合性能
    数据融合精度
    传输时延
    不同传感器数据融合后的信息准确性,能够提供更全面、准确的环境认知
    确保感知数据的快速获取和信息交互效率,提高系统的实时决策能力
    数据质量
    和准确性
    鲁棒性
    隐私和安全性
    在干扰和突发情况下,UAV的移动性和IRS环境重构能力保障系统功能的弹性设计
    提供安全的数据传输和存储机制,保障敏感信息的安全传输
    网络协
    同性能
    自适应性
    能耗和计算资源
    基于IRS-UAV的无线网络需实现空地网络的相互协同,适应环境和任务需求的变化
    保持低能耗,确保感知和数据处理和计算不过度消耗电力,提高UAV的续航能力
    下载: 导出CSV
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出版历程
  • 收稿日期:  2023-09-25
  • 修回日期:  2024-04-16
  • 网络出版日期:  2024-05-04
  • 刊出日期:  2024-05-30

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