Transmit antenna selection strategies for spectrally efficient spatial modulation techniques

Summary Fifth‐generation (5G) networks are expected to offer unprecedented amounts of spectral and energy efficiency. Spatial modulation (SM) techniques have the capability to achieve an appealing trade‐off between these conflicting design parameters. Fully generalized SM (FGSM) and fully quadrature...

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Bibliographic Details
Published in:International journal of communication systems 2022-05, Vol.35 (7), p.n/a
Main Authors: Gudla, Vishnu Vardhan, Kumaravelu, Vinoth Babu, S, Asha, Murugadass, Arthi
Format: Article
Language:English
Subjects:
Antennas
Bit error rate
Channel capacity
Codes
Complexity
Design parameters
Energy efficiency
Euclidean geometry
fully generalized spatial modulation (FGSM)
fully quadrature spatial modulation (FQSM)
Modulation
multiple input and multiple output (MIMO)
next‐generation networks
Quadratures
spatial modulation (SM)
Spectra
transmit antenna selection schemes
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Summary:Summary Fifth‐generation (5G) networks are expected to offer unprecedented amounts of spectral and energy efficiency. Spatial modulation (SM) techniques have the capability to achieve an appealing trade‐off between these conflicting design parameters. Fully generalized SM (FGSM) and fully quadrature SM (FQSM) are the recent high‐rate SM variants, where the spectral efficiency is linearly proportional to the number of transmit antennas. The transmit antenna selection schemes can efficiently improve the average bit error rate (ABER) performance of SM techniques. The main objective of this work is to investigate the employment of transmit antenna selection schemes to FGSM and FQSM. Initially, Euclidean distance optimized antenna selection (EDAS) scheme is employed to FGSM and FQSM. It offers superior performance than conventional FGSM/FQSM without transmit antenna selection at the cost of higher computational complexity. In order to reduce the complexity cost, four suboptimal schemes based on channel capacity, correlation and combination of them are proposed and employed to FGSM and FQSM. The suboptimal transmit antenna selection based on capacity and correlation (TAS‐A‐C) offers a minimum gain of ∼6 dB over conventional FGSM/FQSM with significantly lower complexity. In addition, the performance of all schemes is investigated for increased number of available transmit antennas. As the proposed schemes address the spectral and energy efficiency trade‐off effectively, while corroborating better ABER performance, they have the potential to become a competing candidate for next‐generation networks. The main objective of this work is to investigate the employment of transmit antenna selection schemes to FGSM/FQSM. Five antenna selection strategies are proposed that are based on Euclidean distance, channel capacity, and correlation. TAS‐A‐C scheme offers a gain of ∼6 dB over FGSM/FQSM with lower complexity. The proposed schemes can be a competing candidate for next‐generation networks.
ISSN:1074-5351
1099-1131
DOI:10.1002/dac.5099