Distributed Reed–Solomon coded cooperative space–time labeling diversity network

This paper proposes a distributed Reed-Solomon coded cooperative labeling diversity (DRSCC-LD) scheme over the Rayleigh frequency-flat fast fading channel to further improve the BER performance. The non-binary Reed-Solomon (RS) code with more consecutive roots is applied at the relay to provide addi...

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Bibliographic Details
Published in:Radioengineering Vol. 31; no. 4; pp. 496 - 509
Main Authors: Chen, C., Yang, F. F., Zhao, C. L., Xu, H. J.
Format: Journal Article
Language:English
Published: Spolecnost pro radioelektronicke inzenyrstvi 01.12.2022
Subjects:
detection algorithm
distributed coded cooperation
joint decoding algorithm
labeling diversity (ld)
reed-solomon (rs) code
ISSN:1210-2512
Online Access:Get full text
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Summary:This paper proposes a distributed Reed-Solomon coded cooperative labeling diversity (DRSCC-LD) scheme over the Rayleigh frequency-flat fast fading channel to further improve the BER performance. The non-binary Reed-Solomon (RS) code with more consecutive roots is applied at the relay to provide additional redundancy. As a novel diversity technique, labeling diversity (LD) with three different mappers is employed in the proposed DRSCC-LD scheme utilizing 16-QAM and 64-QAM, respectively, which may achieve diversity gain and greatly decrease the error floor (EF). Besides, a reduced-complexity detection algorithm based on a variable signal subset (RC-VSS) is proposed to lower the complexity of detection at both relay and destination. The proposed critical SNR-assisted (CSA) joint decoding algorithm then collaborates with the joint detection based on the RC-VSS algorithm to improve the overall BER performance. Theoretical analysis and Monte Carlo simulated results reveal that the proposed DRSCC-LD scheme clearly outperforms its corresponding non-cooperative RS coded scheme by a gain of more than 7 dB and the existing schemes by a margin of more than 3.5 dB under the identical conditions, respectively.
ISSN:1210-2512
DOI:10.13164/re.2022.0496