Space-time shift keying aided OTFS modulation for orthogonal multiple access
Space-time shift keying aided OTFS modulation for orthogonal multiple access
Space-time shift keying-aided orthogonal time frequency space modulation-based multiple access (STSK-OTFSMA) is proposed for reliable uplink transmission in high- Doppler scenarios. As a beneficial feature of our STSK-OTFSMAsystem, extra information bits are mapped onto the indices of the active dispersion matrices, which allows the system to enjoy the joint benefits of both STSK and OTFS signalling. Due to the fact that both the time-, space- and DD-domaindegrees of freedom are jointly exploited, our STSK-OTFS-MA achieves increased diversity and coding gains. To mitigate the potentially excessive detection complexity, the sparse structure of the equivalent transmitted symbol vector is exploited, resulting in a pair of low-complexity near-maximum likelihood (ML) multiuser detection algorithms. Explicitly, we conceive a progressive residual check-based greedy detector (PRCGD) and an iterative reduced-space check-based detector (IRCD). Then, we derive both the unconditional single-user pairwise error probability (SU-UPEP) and a tight bit error ratio (BER) union-bound for our single-user STSK-OTFS-MA system employing the ML detector. Furthermore, the discrete-input continuous-output memoryless channel (DCMC) capacity of the proposed system is derived. The optimal dispersion matrices (DMs) are designed based on the maximum attainable diversity and coding gain metrics. Finally, itis demonstrated that our STSK-OTFS-MA system achieves both a lower BER and a higher DCMC capacity than its conventional spatial modulation (SM) and its orthogonal frequency-division multiplexing (OFDM) counterparts. As a benefit, the proposed system strikes a compelling BER vs. system complexity as well as BER vs. detection complexity trade-offs.
Complexity theory, Detectors, Encoding, Interference, OFDM, Space-time shift keying (STSK), Symbols, Time-frequency analysis, low-complexity detection, maximum-likelihood detection, multiple access, orthogonal time frequency space (OTFS), performance analysis
7393-7408
Sui, Zeping
5bad7b4a-c408-40e1-9992-7bfd9b6d7cf0
Zhang, Hongming
f9be6479-a4af-4a51-a257-80f77f7fc91e
Sun, Sumei
dc8a2bd8-c57e-4ece-a45b-c48a7c7d1ed5
Yang, Lie-Liang
ae425648-d9a3-4b7d-8abd-b3cfea375bc7
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
1 December 2023
Sui, Zeping
5bad7b4a-c408-40e1-9992-7bfd9b6d7cf0
Zhang, Hongming
f9be6479-a4af-4a51-a257-80f77f7fc91e
Sun, Sumei
dc8a2bd8-c57e-4ece-a45b-c48a7c7d1ed5
Yang, Lie-Liang
ae425648-d9a3-4b7d-8abd-b3cfea375bc7
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Sui, Zeping, Zhang, Hongming, Sun, Sumei, Yang, Lie-Liang and Hanzo, Lajos
(2023)
Space-time shift keying aided OTFS modulation for orthogonal multiple access.
IEEE Transactions on Communications, 71 (12), .
(doi:10.1109/TCOMM.2023.3314861).
Abstract
Space-time shift keying-aided orthogonal time frequency space modulation-based multiple access (STSK-OTFSMA) is proposed for reliable uplink transmission in high- Doppler scenarios. As a beneficial feature of our STSK-OTFSMAsystem, extra information bits are mapped onto the indices of the active dispersion matrices, which allows the system to enjoy the joint benefits of both STSK and OTFS signalling. Due to the fact that both the time-, space- and DD-domaindegrees of freedom are jointly exploited, our STSK-OTFS-MA achieves increased diversity and coding gains. To mitigate the potentially excessive detection complexity, the sparse structure of the equivalent transmitted symbol vector is exploited, resulting in a pair of low-complexity near-maximum likelihood (ML) multiuser detection algorithms. Explicitly, we conceive a progressive residual check-based greedy detector (PRCGD) and an iterative reduced-space check-based detector (IRCD). Then, we derive both the unconditional single-user pairwise error probability (SU-UPEP) and a tight bit error ratio (BER) union-bound for our single-user STSK-OTFS-MA system employing the ML detector. Furthermore, the discrete-input continuous-output memoryless channel (DCMC) capacity of the proposed system is derived. The optimal dispersion matrices (DMs) are designed based on the maximum attainable diversity and coding gain metrics. Finally, itis demonstrated that our STSK-OTFS-MA system achieves both a lower BER and a higher DCMC capacity than its conventional spatial modulation (SM) and its orthogonal frequency-division multiplexing (OFDM) counterparts. As a benefit, the proposed system strikes a compelling BER vs. system complexity as well as BER vs. detection complexity trade-offs.
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More information
Accepted/In Press date: 6 September 2023
e-pub ahead of print date: 13 September 2023
Published date: 1 December 2023
Additional Information:
Publisher Copyright:
© 1972-2012 IEEE.
Keywords:
Complexity theory, Detectors, Encoding, Interference, OFDM, Space-time shift keying (STSK), Symbols, Time-frequency analysis, low-complexity detection, maximum-likelihood detection, multiple access, orthogonal time frequency space (OTFS), performance analysis
Identifiers
Local EPrints ID: 481981
URI: http://eprints.soton.ac.uk/id/eprint/481981
ISSN: 0090-6778
PURE UUID: cd163ae0-7300-4124-825a-c67516feca15
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Date deposited: 14 Sep 2023 16:46
Last modified: 18 Mar 2024 05:15
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Contributors
Author:
Zeping Sui
Author:
Hongming Zhang
Author:
Sumei Sun
Author:
Lie-Liang Yang
Author:
Lajos Hanzo
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