近地轨道卫星星座交通工程分段路由与有效恢复

IF 7.5 2区 计算机科学 Q1 TELECOMMUNICATIONS
Shengyu Zhang , Xiaoqian Li , Kwan Lawrence Yeung
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引用次数: 0

摘要

低地轨道卫星星座(LEO-SCs)提供全球、高速和低延迟的互联网接入服务,弥合了偏远地区的数字鸿沟。由于最初部署的卫星(即 Starlink)不支持卫星间连接,卫星之间的通信依靠地面站的无线电频率信号。由于卫星的快速移动,这种低地轨道卫星通信中心和地面站的混合拓扑结构是时变的,这给不间断的服务提供和网络管理带来了巨大挑战。在本文中,我们将重点解决这种地面站辅助 LEO-SC 拓扑中的两个显著问题,即流量工程和快速重路由,以保证数据包以均衡、不间断的方式转发。具体来说,我们采用段路由来支持 LEO-SC 中的任意路径路由。为了解决流量工程问题,我们提出了两种具有流量分割算法的源路由,即延迟有界流量分割(DBTS)和 DBTS+,其中 DBTS 平均分割流量,而 DBTS + 则偏向于更短的路径。仿真结果表明,DBTS + 可以降低约 30% 的最大卫星负载,但代价是延迟增加约 10%。为了保证故障的快速恢复,我们研究了两种快速重路由机制,即无环路备用(LFA)和 LFA+,其中 LFA 预计算一个备用下一跳作为备份,而 LFA + 则寻找一个 2 段备份路径。我们的研究表明,LFA + 可以将保护覆盖率提高约 15%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Segment routing for traffic engineering and effective recovery in low-earth orbit satellite constellations

Low-Earth Orbit Satellite Constellations (LEO-SCs) provide global, high-speed, and low latency Internet access services, which bridges the digital divide in the remote areas. As inter-satellite links are not supported in initial deployment (i.e. the Starlink), the communication between satellites is based on ground stations with radio frequency signals. Due to the rapid movement of satellites, this hybrid topology of LEO-SCs and ground stations is time-varying, which imposes a major challenge to uninterrupted service provisioning and network management. In this paper, we focus on solving two notable problems in such a ground station-assisted LEO-SC topology, i.e., traffic engineering and fast reroute, to guarantee that the packets are forwarded in a balanced and uninterrupted manner. Specifically, we employ segment routing to support the arbitrary path routing in LEO-SCs. To solve the traffic engineering problem, we proposed two source routings with traffic splitting algorithms, Delay-Bounded Traffic Splitting (DBTS) and DBTS+, where DBTS equally splits a flow and DBTS ​+ ​favors shorter paths. Simulation results show that DBTS ​+ ​can achieve about 30% lower maximum satellite load at the cost of about 10% more delay. To guarantee the fast recovery of failures, two fast reroute mechanisms, Loop-Free Alternate (LFA) and LFA+, are studied, where LFA pre-computes an alternate next-hop as a backup while LFA ​+ ​finds a 2-segment backup path. We show that LFA ​+ ​can increase the percentage of protection coverage by about 15%.

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来源期刊
Digital Communications and Networks
Digital Communications and Networks Computer Science-Hardware and Architecture
CiteScore
12.80
自引率
5.10%
发文量
915
审稿时长
30 weeks
期刊介绍: Digital Communications and Networks is a prestigious journal that emphasizes on communication systems and networks. We publish only top-notch original articles and authoritative reviews, which undergo rigorous peer-review. We are proud to announce that all our articles are fully Open Access and can be accessed on ScienceDirect. Our journal is recognized and indexed by eminent databases such as the Science Citation Index Expanded (SCIE) and Scopus. In addition to regular articles, we may also consider exceptional conference papers that have been significantly expanded. Furthermore, we periodically release special issues that focus on specific aspects of the field. In conclusion, Digital Communications and Networks is a leading journal that guarantees exceptional quality and accessibility for researchers and scholars in the field of communication systems and networks.
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