Search

Searching. Please wait…

Realistic assessment of transport protocols performance over LEO-based communications

Abstract: We study the performance exhibited by the transport protocols, Transport Control Protocol (TCP) and QUIC, over realistic satellite networks. We propose a novel methodology, which combines real implementation (exploiting virtualization techniques) and simulation, to carry out systematic and repetitive experiments. We modify the default operation of the ns-3 framework and we integrate the dynamism that characterizes satellite communication links, particularly Low Earth Orbit (LEO). We carry out a thorough assessment over different setups, changing the operating frequency band and packet buffer lengths. In addition, we ascertain the impact of using the multi-streaming feature that QUIC integrates. The results show that QUIC yields lower delays than TCP, although it might suffer from higher jitter in particular setups. In addition, the results evince that using multiple streams in QUIC does not yield a relevant gain for the default Round-Robin (RR) scheduler. We propose more appropriate scheduling strategies, which are able to yield better performances with unbalanced traffic. Even if the behavior of transport protocols over non-terrestrial-networks might not be always appropriate, the obtained results evince that QUIC can definitively bring benefits when compared to TCP. Furthermore, we have shown that optimal scheduling policies yields a fairer performance when using multiple flows, having unbalanced traffic loads.

 Authorship: Hervella C., Diez L., Fernández F., Marcano N.J.H., Jacobsen R.H., Agüero R.,

 Fuente: Computer Networks, 2023, 236, 110008

 Publisher: Elsevier

 Publication date: 01/11/2023

 No. of pages: 11

 Publication type: Article

 DOI: 10.1145/3551663.3558680

 ISSN: 1389-1286,1872-7069

 Spanish project: PID2021-125725OB-I00

 Publication Url: https://doi.org/10.1016/j.comnet.2023.110008

Authorship

CRISTINA AURORA HERVELLA BATURONE

FATIMA MARIA FERNANDEZ PEREZ

HERNÁNDEZ MARCANO, NÉSTOR J.

JACOBSEN, RUNE HYLSBERG