低轨卫星通导一体化信号设计及处理

刘炳宏; 赵亚飞; 彭木根; 赵祥天; 封慧琪

doi:10.11959/j.issn.2096-8930.2023029

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低轨卫星通导一体化信号设计及处理

专题：面向6G的星地融合移动通信 | 更新时间：2024-06-03

- 低轨卫星通导一体化信号设计及处理
- Design and Processing of Communication and Navigation Integrated Signal Based on LEO Satellite
- 天地一体化信息网络 2023年4卷第3期页码：40-47
- 作者机构：
- 作者简介：
  
  [ "刘炳宏（1995- ），女，博士，北京邮电大学博士后，主要研究方向为低轨卫星通导一体化、无人机通信、无线资源分配" ]
  [ "赵亚飞（1987- ），男，博士，北京邮电大学网络与交换技术国家重点实验室副研究员，主要研究方向为低轨卫星通导一体化" ]
  [ "彭木根（1978- ），男，博士，北京邮电大学网络与交换技术国家重点实验室教授，主要研究方向为空间信息通信、通感算一体化、无线接入网络等" ]
  [ "赵祥天（1992- ），男，博士，北京邮电大学网络与交换技术国家重点实验室博士后，主要研究方向为空间非合作目标协同感知、低轨卫星通导一体化等" ]
  [ "封慧琪（2001- ），男，北京邮电大学信息与通信工程学院本科生" ]
- 基金信息：
  
  北京市科技计划项目;Beijing Municipal Science and Technology Project(Z221100007722012)
- DOI：10.11959/j.issn.2096-8930.2023029
  中图分类号： TP393
- 网络出版日期：2023-09，
  
  纸质出版日期：2023-09-20
- 稿件说明：
移动端阅览
刘炳宏, 赵亚飞, 彭木根, 等. 低轨卫星通导一体化信号设计及处理[J]. 天地一体化信息网络, 2023,4(3):40-47.

Binghong LIU, Yafei ZHAO, Mugen PENG, et al. Design and Processing of Communication and Navigation Integrated Signal Based on LEO Satellite[J]. Space-integrated-ground information networks, 2023, 4(3): 40-47.
刘炳宏, 赵亚飞, 彭木根, 等. 低轨卫星通导一体化信号设计及处理[J]. 天地一体化信息网络, 2023,4(3):40-47. DOI： 10.11959/j.issn.2096-8930.2023029.

Binghong LIU, Yafei ZHAO, Mugen PENG, et al. Design and Processing of Communication and Navigation Integrated Signal Based on LEO Satellite[J]. Space-integrated-ground information networks, 2023, 4(3): 40-47. DOI： 10.11959/j.issn.2096-8930.2023029.

摘要

通导一体化是现代卫星通信与导航领域的重要发展方向。低轨巨型通信星座的迅速发展提供了丰富的载荷、链路和终端资源，以及强大的通信覆盖及信息传输能力，同时利用低轨星座几何构型变化快、落地功率强等特点，可实现对现有导航系统的补充、备份和增强，从而提供覆盖更广、精度更高且更为稳健的通信与导航服务。低轨卫星通导一体化系统中，发送信号设计及接收信号处理是实现高效通信与高精度导航的关键环节。为此，首先梳理低轨卫星通导融合的演进过程；其次，围绕发送信号设计和接收信号处理，重点阐述帧结构和接收机设计的相关方案；最后，探讨未来所面临的挑战及潜在解决方案。

Abstract

The integration of communication and navigation is an important direction in modern satellite communication and navigation fields.The advancement of low earth orbit (LEO) mega-constellations provides the abundant load

link and terminal resources

as well as the powerful communication coverage and information transmission capabilities.Moreover

together with the fast-changing geometric configuration and strong power

the LEO satellites can complement

backup

and enhance the existing navigation systems to provide communication and navigation services with broader coverage

higher precision and reliability.In the LEO satellite-enabled communication and navigation-integrated system

the design of the transmitted signals and the processing of the received signals are crucial for achieving efficient communication and high-precision navigation.To this end

the evolution process of the communication and navigation fusion was first outlined.Then

it focused on the design of transmitting signals and the processing of receiving signals

the relevant schemes included the layout of the frame structure and the receiver were emphasized

respectively.Finally

the challenges and potential solutions that lie ahead in the future were explored.

关键词

Keywords

references

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