Upper bound and approximation of random access throughput over chase combining HARQ

A. Burkov; N. Matveev; A. Turlikov; A. Bulanov; O. Gahnina; S. Andreev

doi:10.1109/ICUMT.2017.8255206

Upper bound and approximation of random access throughput over chase combining HARQ

A. Burkov, N. Matveev, A. Turlikov, A. Bulanov, O. Gahnina, S. Andreev

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

Abstract

Massive MTC (mMTC) scenarios featuring a tremendous number of devices challenge the conventional multiple access protocols, which are mostly based on classic ALOHA algorithms known for their instability at higher loads. While numerous modifications of ALOHA adopt the unrealistic assumption on the fixed number of contending uses, we in this paper study a model where a random number of users activate within the slot. In particular, we explore a modification of ALOHA augmented with the Chase combining HARQ (HARQ-CC) and derive an approximation for and a simple upper bound on the system throughput. While the former perfectly matches the corresponding simulation results for the SNR of up to 10dB, the latter constitutes an increasingly tight limit as the SNR grows. Based on both analytical considerations, the resulting system throughput may be significantly improved with the optimal choice of the transmission probability and code spectral efficiency.

Original language	English
Title of host publication	2017 9th International Congress on Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT)
Publisher	IEEE
Pages	143-147
Number of pages	5
ISBN (Electronic)	978-1-5386-3435-6
DOIs	https://doi.org/10.1109/ICUMT.2017.8255206
Publication status	Published - 1 Nov 2017
Publication type	A4 Article in conference proceedings
Event	International Conference on Ultra Modern Telecommunications and Control Systems and Workshops - Duration: 1 Jan 1900 → …

Publication series

Name
ISSN (Print)	2157-023X

Conference

Conference	International Conference on Ultra Modern Telecommunications and Control Systems and Workshops
Period	1/01/00 → …

Keywords

Decoding
Interference
Nickel
Random variables
Signal to noise ratio
Throughput
Upper bound
ALOHA
Chase combining
Hybrid-ARQ
Random multiple access
system throughput
upper bound

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title = "Upper bound and approximation of random access throughput over chase combining HARQ",

abstract = "Massive MTC (mMTC) scenarios featuring a tremendous number of devices challenge the conventional multiple access protocols, which are mostly based on classic ALOHA algorithms known for their instability at higher loads. While numerous modifications of ALOHA adopt the unrealistic assumption on the fixed number of contending uses, we in this paper study a model where a random number of users activate within the slot. In particular, we explore a modification of ALOHA augmented with the Chase combining HARQ (HARQ-CC) and derive an approximation for and a simple upper bound on the system throughput. While the former perfectly matches the corresponding simulation results for the SNR of up to 10dB, the latter constitutes an increasingly tight limit as the SNR grows. Based on both analytical considerations, the resulting system throughput may be significantly improved with the optimal choice of the transmission probability and code spectral efficiency.",

keywords = "Decoding, Interference, Nickel, Random variables, Signal to noise ratio, Throughput, Upper bound, ALOHA, Chase combining, Hybrid-ARQ, Random multiple access, system throughput, upper bound",

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doi = "10.1109/ICUMT.2017.8255206",

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Burkov, A, Matveev, N, Turlikov, A, Bulanov, A, Gahnina, O & Andreev, S 2017, Upper bound and approximation of random access throughput over chase combining HARQ. in 2017 9th International Congress on Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT). IEEE, pp. 143-147, International Conference on Ultra Modern Telecommunications and Control Systems and Workshops, 1/01/00. https://doi.org/10.1109/ICUMT.2017.8255206

Upper bound and approximation of random access throughput over chase combining HARQ. / Burkov, A.; Matveev, N.; Turlikov, A. et al.
2017 9th International Congress on Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT). IEEE, 2017. p. 143-147.

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

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AU - Burkov, A.

AU - Matveev, N.

AU - Turlikov, A.

AU - Bulanov, A.

AU - Gahnina, O.

AU - Andreev, S.

N1 - INT=elt,"Gahnina, O." jufoid=72315

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N2 - Massive MTC (mMTC) scenarios featuring a tremendous number of devices challenge the conventional multiple access protocols, which are mostly based on classic ALOHA algorithms known for their instability at higher loads. While numerous modifications of ALOHA adopt the unrealistic assumption on the fixed number of contending uses, we in this paper study a model where a random number of users activate within the slot. In particular, we explore a modification of ALOHA augmented with the Chase combining HARQ (HARQ-CC) and derive an approximation for and a simple upper bound on the system throughput. While the former perfectly matches the corresponding simulation results for the SNR of up to 10dB, the latter constitutes an increasingly tight limit as the SNR grows. Based on both analytical considerations, the resulting system throughput may be significantly improved with the optimal choice of the transmission probability and code spectral efficiency.

AB - Massive MTC (mMTC) scenarios featuring a tremendous number of devices challenge the conventional multiple access protocols, which are mostly based on classic ALOHA algorithms known for their instability at higher loads. While numerous modifications of ALOHA adopt the unrealistic assumption on the fixed number of contending uses, we in this paper study a model where a random number of users activate within the slot. In particular, we explore a modification of ALOHA augmented with the Chase combining HARQ (HARQ-CC) and derive an approximation for and a simple upper bound on the system throughput. While the former perfectly matches the corresponding simulation results for the SNR of up to 10dB, the latter constitutes an increasingly tight limit as the SNR grows. Based on both analytical considerations, the resulting system throughput may be significantly improved with the optimal choice of the transmission probability and code spectral efficiency.

KW - Decoding

KW - Interference

KW - Nickel

KW - Random variables

KW - Signal to noise ratio

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KW - Upper bound

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KW - Hybrid-ARQ

KW - Random multiple access

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BT - 2017 9th International Congress on Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT)

PB - IEEE

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ER -

Upper bound and approximation of random access throughput over chase combining HARQ

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