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Shortest Path in LEO Satellite Constellation Networks: An Explicit Analytic Approach

Quan Chen, Lei Yang, Yong Zhao, Yi Wang, Haibo Zhou, Xiaoqian Chen

2024IEEE Journal on Selected Areas in Communications105 citationsDOIOpen Access PDF

Abstract

The Shortest Distance Path (SDP) problem is a critical routing issue in communication networks, particularly in satellite networks. Typically, SDP is solved by graph-based iterative algorithms, while an explicit or analytic approach is challenging. However, considering the orbit dynamics and topology regularity, this paper proposes, for the first time, an explicit analytic phase-based algorithm STEPCLIMB to directly solve the SDP in low-Earth orbit (LEO) satellite networks. Based on the relationship between satellite phase and inter-satellite link distance, the SDP is modeled with the satellite phase, and SDP problem is converted into a total phase offset problem through theoretical derivations. Then STEPCLIMB is derived in two cases, respectively. Monte-Carlo simulations verify STEPCLIMB’s accuracy, which has zero error in the mono-valley case and has less than 0.1% error in the bi-valley case. The algorithm performs better in larger-scale constellations and can save over 99.4% computational cost compared to Dijkstra algorithm. Further, the SDP pattern and features in Starlink constellation are analyzed. The model proves that most inter-plane hops in the SDP occur successively, and the simulations further indicate that these hops prefer satellites in the higher latitude regions.

Topics & Concepts

Computer scienceConstellationSatellite constellationComputer networkSatelliteTelecommunicationsPath (computing)Shortest path problemTheoretical computer scienceGraphAerospace engineeringEngineeringPhysicsAstronomySatellite Communication SystemsOpportunistic and Delay-Tolerant NetworksIoT Networks and Protocols
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