Demonstration of 5G non-terrestrial network regenerative L1 processing
Demonstration of 5G non-terrestrial network regenerative L1 processing
The regenerative architecture for 5G Non- Terrestrial Networks (NTNs) offers several advantages over the transparent architecture, including reduced latency, improved quality of service, lower feeder link bandwidth, support for inter-satellite links and the provision of edge compute services. However, it has the challenge of requiring computationally intensive 5G base stations to be placed into the Low-Earth Orbit (LEO) satellites, rather than into ground stations as is done in the transparent architecture. Based on AccelerComm's portfolio of flexible O-RAN L1 solutions, this paper describes a demonstration of a low-power radiation-tolerant 5G base station L1 implementation which addresses this challenge, making it suitable for LEO satellite deployment.
Maunder, Rob
76099323-7d58-4732-a98f-22a662ccba6c
Kim, Lam Wui
6da224e6-6a43-49d3-a495-db69e3977253
Harvey, David
ff6ca8bc-abcb-48f6-bed1-b80acdc3104a
28 October 2024
Maunder, Rob
76099323-7d58-4732-a98f-22a662ccba6c
Kim, Lam Wui
6da224e6-6a43-49d3-a495-db69e3977253
Harvey, David
ff6ca8bc-abcb-48f6-bed1-b80acdc3104a
Maunder, Rob, Kim, Lam Wui and Harvey, David
(2024)
Demonstration of 5G non-terrestrial network regenerative L1 processing.
IEEE Military Communications Conference, , Wasshington, United States.
28 Oct - 01 Nov 2024.
2 pp
.
Record type:
Conference or Workshop Item
(Paper)
Abstract
The regenerative architecture for 5G Non- Terrestrial Networks (NTNs) offers several advantages over the transparent architecture, including reduced latency, improved quality of service, lower feeder link bandwidth, support for inter-satellite links and the provision of edge compute services. However, it has the challenge of requiring computationally intensive 5G base stations to be placed into the Low-Earth Orbit (LEO) satellites, rather than into ground stations as is done in the transparent architecture. Based on AccelerComm's portfolio of flexible O-RAN L1 solutions, this paper describes a demonstration of a low-power radiation-tolerant 5G base station L1 implementation which addresses this challenge, making it suitable for LEO satellite deployment.
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Milcom paper
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Published date: 28 October 2024
Venue - Dates:
IEEE Military Communications Conference, , Wasshington, United States, 2024-10-28 - 2024-11-01
Identifiers
Local EPrints ID: 494722
URI: http://eprints.soton.ac.uk/id/eprint/494722
PURE UUID: 6ef78dd5-8cc3-43c4-b47f-35480718cc1f
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Date deposited: 14 Oct 2024 16:56
Last modified: 02 Nov 2024 05:01
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Contributors
Author:
Rob Maunder
Author:
Lam Wui Kim
Author:
David Harvey
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