Publication result detail

Verification of Communication Parameters for NTN Communication

DVOŘÁK, R.; PALUŘÍK, P.; LE, D.; ŠTŮSEK, M.; MAŠEK, P.; MOLTCHANOV, D.; HOŠEK, J.

Original Title

Verification of Communication Parameters for NTN Communication

English Title

Verification of Communication Parameters for NTN Communication

Type

Paper in proceedings (conference paper)

Original Abstract

Non-terrestrial networks (NTNs) are envisioned to extend 5 G coverage globally, with Narrowband IoT (NB-IoT) identified as a key technology for massive machine-type communication in remote or underserved areas. Accurate modeling of the satellite channel is crucial to assess reliability and system performance. This paper presents a comparative study of two widely used NTN propagation models: the ETSI Rician fading model and the ITU-R P. 681 land mobile-satellite model. Using MATLAB simulations of the NB-IoT NPDSCH link in a LEO 1200 km scenario, we evaluate block error rate (BLER) performance across elevation angles from 0° to 90° with varying numbers of repetitions. Results demonstrate that the ETSI Rician model, while simple and analytically tractable, produces overly optimistic BLER predictions at low elevations. In contrast, the ITU-R P. 681 model proved to be more versatile and capable of capturing diverse propagation environments. These findings highlight the importance of model selection for NTN design, particularly in low-elevation and urban scenarios.

English abstract

Non-terrestrial networks (NTNs) are envisioned to extend 5 G coverage globally, with Narrowband IoT (NB-IoT) identified as a key technology for massive machine-type communication in remote or underserved areas. Accurate modeling of the satellite channel is crucial to assess reliability and system performance. This paper presents a comparative study of two widely used NTN propagation models: the ETSI Rician fading model and the ITU-R P. 681 land mobile-satellite model. Using MATLAB simulations of the NB-IoT NPDSCH link in a LEO 1200 km scenario, we evaluate block error rate (BLER) performance across elevation angles from 0° to 90° with varying numbers of repetitions. Results demonstrate that the ETSI Rician model, while simple and analytically tractable, produces overly optimistic BLER predictions at low elevations. In contrast, the ITU-R P. 681 model proved to be more versatile and capable of capturing diverse propagation environments. These findings highlight the importance of model selection for NTN design, particularly in low-elevation and urban scenarios.

Keywords

NB-IoT; Non-terrestrial networks; Propagation models; Elevation angle; BLER

Key words in English

NB-IoT; Non-terrestrial networks; Propagation models; Elevation angle; BLER

Authors

DVOŘÁK, R.; PALUŘÍK, P.; LE, D.; ŠTŮSEK, M.; MAŠEK, P.; MOLTCHANOV, D.; HOŠEK, J.

RIV year

2026

Released

03.12.2025

Publisher

IEEE Computer Society

Location

Florence

ISBN

979-8-3315-7675-2

Book

International Conference on Ultra Modern Telecommunications and Workshops

Periodical

International Congress on Ultra Modern Telecommunications and Workshops

State

United States of America

Pages from

87

Pages to

93

Pages count

7

BibTex

@inproceedings{BUT200550,
  author="Radim {Dvořák} and Pavel {Paluřík} and Dinh Thao {Le} and Martin {Štůsek} and Pavel {Mašek} and Dmitri {Moltchanov} and  {} and Jiří {Hošek} and  {}",
  title="Verification of Communication Parameters for NTN Communication",
  booktitle="International Conference on Ultra Modern Telecommunications and Workshops",
  year="2025",
  journal="International Congress on Ultra Modern Telecommunications and Workshops",
  pages="87--93",
  publisher="IEEE Computer Society",
  address="Florence",
  doi="10.1109/ICUMT67815.2025.11268807",
  isbn="979-8-3315-7675-2"
}