Link-Level Performance Analysis of DVB Standards in Ultra-Dense LEO Satellite-Terrestrial Networks

Ultra-dense low earth orbit (LEO) satellite terrestrial networks (ULSNs) are considered as a crucial component of future six generation (6G) networks, offering ubiquitous and massive services for various applications. However, for the development of advanced physical layer technologies for ULSNs, a...

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Bibliographic Details
Published in:IEEE Vehicular Technology Conference pp. 01 - 05
Main Authors: Zhang, Xin, Wang, Yilei, Qin, Xiaohan, Zhang, Zitian, Zhou, Haibo, Shen, Xuemin
Format: Conference Proceeding
Language:English
Published: IEEE 24.06.2024
Subjects:
Attenuation
DVB protocol
link-level simulation
Low earth orbit satellites
Microwave communication
modulation and coding scheme
Performance analysis
Physical layer
Rain
Space-air-ground integrated networks
Ultra-dense LEO satellite-terrestrial networks
ISSN:2577-2465
Online Access:Get full text
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Summary:Ultra-dense low earth orbit (LEO) satellite terrestrial networks (ULSNs) are considered as a crucial component of future six generation (6G) networks, offering ubiquitous and massive services for various applications. However, for the development of advanced physical layer technologies for ULSNs, a comprehensive link-level simulation tool that integrates up-to-date satellite communication protocols becomes paramount and is urgently needed. In this paper, we develop a versatile simulator for the link-level performance analysis of ULSNs under the prevalent digital video broadcasting (DVB) standards. We first establish a complete satellite-terrestrial microwave channel model, taking practical factors such as rain attenuation, cloud attenuation, and Doppler frequency shift into consideration. Subsequently, the whole physical layer modules tailored for satellite-terrestrial microwave communication are implemented, including diverse physical layer modulation and coding schemes (MCSs). Furthermore, we realize adaptive coding and modulation (ACM) for adaptive channel performance simulation. Finally, comparative performance analysis using the established channel model is conducted to demonstrate the effectiveness of different MCSs of DVB standards. The complete link-level performance analysis based on our self-developed simulator can advance the field of satellite-terrestrial microwave communication and provide valuable insights for further exploration of ULSNs.
ISSN:2577-2465
DOI:10.1109/VTC2024-Spring62846.2024.10683179