Attenuation compensation techniques for ultra-reliable high throughput satellite integrated network

Jinwara Surattanagul; K'ufre Mfon Ekerete; Sharmini Enoch; Jonathan Rodriguez; Ifiok Otung

doi:10.1049/icp.2023.1378

Attenuation compensation techniques for ultra-reliable high throughput satellite integrated network

Jinwara Surattanagul, K'ufre Mfon Ekerete, Sharmini Enoch, Jonathan Rodriguez, Ifiok Otung

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

To support future development in satellite communication systems in the Ka-band and above, this paper studies the beacon attenuation measurements recorded at Chilbolton in Southern England to evaluate the performance of Time Diversity (TD) and Site Diversity (SD) techniques. TD performance is computed by comparing the measured rain attenuation time series with a delayed version of itself. Five (5) time delays were employed, namely 1, 5, 10, 30 and 60 seconds. SD performance is obtained by using the single-site rain attenuation data at Chilbolton and the ITU-R P.618-13 recommendation [1], with inter-site distances 1, 5, 10, and 20 km, and baseline angle fixed at 90°. Analytical results of the selection combining (SC)-based TD and SD performance are validated by MATLAB simulations. Results show that the TD and SD are significant techniques for handling the effect of rain attenuation. However, to be effective, TD requires long time delays, whereas SD requires large inter-site separation distances and additional terrestrial infrastructure. Significant improvement in TD performance is obtained by using maximal ratio combining (MRC), rather than selection, to produce the carrier signal input to the demodulator at the receiver end. This improvement is demonstrated in the simulation results presented in the paper.

Original language	English
Title of host publication	IET Conference Proceedings
Publisher	Institution of Engineering and Technology
Pages	145-150
Number of pages	6
Volume	2022
Edition	29
ISBN (Electronic)	9781839538841
DOIs	https://doi.org/10.1049/icp.2023.1378
Publication status	E-pub ahead of print - 14 Jun 2023
Event	39th International Communications Satellite Systems Conference, ICSSC 2022 - Stresa, Italy Duration: 18 Oct 2022 → 21 Oct 2022

Conference

Conference	39th International Communications Satellite Systems Conference, ICSSC 2022
Country/Territory	Italy
City	Stresa
Period	18/10/22 → 21/10/22

Keywords

Attenuation Compensation Techniques
High Throughout Satellites
Maximal Ratio Combining (MRC)
Time Diversity

Access to Document

10.1049/icp.2023.1378

Cite this

@inproceedings{49b254098cae471aa01fd5f8e92b1bad,

title = "Attenuation compensation techniques for ultra-reliable high throughput satellite integrated network",

abstract = "To support future development in satellite communication systems in the Ka-band and above, this paper studies the beacon attenuation measurements recorded at Chilbolton in Southern England to evaluate the performance of Time Diversity (TD) and Site Diversity (SD) techniques. TD performance is computed by comparing the measured rain attenuation time series with a delayed version of itself. Five (5) time delays were employed, namely 1, 5, 10, 30 and 60 seconds. SD performance is obtained by using the single-site rain attenuation data at Chilbolton and the ITU-R P.618-13 recommendation [1], with inter-site distances 1, 5, 10, and 20 km, and baseline angle fixed at 90°. Analytical results of the selection combining (SC)-based TD and SD performance are validated by MATLAB simulations. Results show that the TD and SD are significant techniques for handling the effect of rain attenuation. However, to be effective, TD requires long time delays, whereas SD requires large inter-site separation distances and additional terrestrial infrastructure. Significant improvement in TD performance is obtained by using maximal ratio combining (MRC), rather than selection, to produce the carrier signal input to the demodulator at the receiver end. This improvement is demonstrated in the simulation results presented in the paper.",

keywords = "Attenuation Compensation Techniques, High Throughout Satellites, Maximal Ratio Combining (MRC), Time Diversity",

author = "Jinwara Surattanagul and Ekerete, {K'ufre Mfon} and Sharmini Enoch and Jonathan Rodriguez and Ifiok Otung",

note = "Funding Information: The authors would like to thank the Office of the Civil Service Commission, the Thai government and Office of Educational Affairs, and the Royal Thai Embassy in London for the funding and support to undertake this project. Publisher Copyright: {\textcopyright} 2022 Proceedings of the Design Society. All rights reserved.; 39th International Communications Satellite Systems Conference, ICSSC 2022 ; Conference date: 18-10-2022 Through 21-10-2022",

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doi = "10.1049/icp.2023.1378",

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Surattanagul, J, Ekerete, KM, Enoch, S, Rodriguez, J & Otung, I 2023, Attenuation compensation techniques for ultra-reliable high throughput satellite integrated network. in IET Conference Proceedings. 29 edn, vol. 2022, Institution of Engineering and Technology, pp. 145-150, 39th International Communications Satellite Systems Conference, ICSSC 2022, Stresa, Italy, 18/10/22. https://doi.org/10.1049/icp.2023.1378

Attenuation compensation techniques for ultra-reliable high throughput satellite integrated network. / Surattanagul, Jinwara; Ekerete, K'ufre Mfon; Enoch, Sharmini et al.
IET Conference Proceedings. Vol. 2022 29. ed. Institution of Engineering and Technology, 2023. p. 145-150.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Attenuation compensation techniques for ultra-reliable high throughput satellite integrated network

AU - Surattanagul, Jinwara

AU - Ekerete, K'ufre Mfon

AU - Enoch, Sharmini

AU - Rodriguez, Jonathan

AU - Otung, Ifiok

N1 - Funding Information: The authors would like to thank the Office of the Civil Service Commission, the Thai government and Office of Educational Affairs, and the Royal Thai Embassy in London for the funding and support to undertake this project. Publisher Copyright: © 2022 Proceedings of the Design Society. All rights reserved.

PY - 2023/6/14

Y1 - 2023/6/14

N2 - To support future development in satellite communication systems in the Ka-band and above, this paper studies the beacon attenuation measurements recorded at Chilbolton in Southern England to evaluate the performance of Time Diversity (TD) and Site Diversity (SD) techniques. TD performance is computed by comparing the measured rain attenuation time series with a delayed version of itself. Five (5) time delays were employed, namely 1, 5, 10, 30 and 60 seconds. SD performance is obtained by using the single-site rain attenuation data at Chilbolton and the ITU-R P.618-13 recommendation [1], with inter-site distances 1, 5, 10, and 20 km, and baseline angle fixed at 90°. Analytical results of the selection combining (SC)-based TD and SD performance are validated by MATLAB simulations. Results show that the TD and SD are significant techniques for handling the effect of rain attenuation. However, to be effective, TD requires long time delays, whereas SD requires large inter-site separation distances and additional terrestrial infrastructure. Significant improvement in TD performance is obtained by using maximal ratio combining (MRC), rather than selection, to produce the carrier signal input to the demodulator at the receiver end. This improvement is demonstrated in the simulation results presented in the paper.

AB - To support future development in satellite communication systems in the Ka-band and above, this paper studies the beacon attenuation measurements recorded at Chilbolton in Southern England to evaluate the performance of Time Diversity (TD) and Site Diversity (SD) techniques. TD performance is computed by comparing the measured rain attenuation time series with a delayed version of itself. Five (5) time delays were employed, namely 1, 5, 10, 30 and 60 seconds. SD performance is obtained by using the single-site rain attenuation data at Chilbolton and the ITU-R P.618-13 recommendation [1], with inter-site distances 1, 5, 10, and 20 km, and baseline angle fixed at 90°. Analytical results of the selection combining (SC)-based TD and SD performance are validated by MATLAB simulations. Results show that the TD and SD are significant techniques for handling the effect of rain attenuation. However, to be effective, TD requires long time delays, whereas SD requires large inter-site separation distances and additional terrestrial infrastructure. Significant improvement in TD performance is obtained by using maximal ratio combining (MRC), rather than selection, to produce the carrier signal input to the demodulator at the receiver end. This improvement is demonstrated in the simulation results presented in the paper.

KW - Attenuation Compensation Techniques

KW - High Throughout Satellites

KW - Maximal Ratio Combining (MRC)

KW - Time Diversity

U2 - 10.1049/icp.2023.1378

DO - 10.1049/icp.2023.1378

M3 - Conference contribution

AN - SCOPUS:85165735723

VL - 2022

SP - 145

EP - 150

BT - IET Conference Proceedings

PB - Institution of Engineering and Technology

T2 - 39th International Communications Satellite Systems Conference, ICSSC 2022

Y2 - 18 October 2022 through 21 October 2022

ER -

Attenuation compensation techniques for ultra-reliable high throughput satellite integrated network

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Conference

Keywords

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