Spatial coded modulation: Coding over antennas

In spatial modulation systems, the reliability of the active antenna detection is of vital importance since the modulated symbols tend to be correctly demodulated when the active antennas are accurately identified. In this paper, we propose a spatial coded modulation (SCM) scheme, which improves the...

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Bibliographic Details
Published inChina communications Vol. 21; no. 11; pp. 104 - 122
Main Authors Junshan, Luo, Fanggang, Wang, Shilian, Wang
Format Journal Article
LanguageEnglish
Published China Institute of Communications 01.11.2024
School of Electronic Science,National University of Defense Technology,Changsha 410073,China%State Key Laboratory of Rail Traffic Control and Safety,Beijing Jiaotong University,Beijing 100044,China
Subjects
antenna correlation
Antennas
channel capacity
Hamming distance
Hamming distances
Modulation
Receiving antennas
Reliability
spatial modulation
Symbols
Transmitting antennas
spatial modulation
Hamming distance
antenna correlation
channel capacity
reliability
Online AccessGet full text
ISSN1673-5447
DOI10.23919/JCC.ea.2021-0011.202401

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Summary:In spatial modulation systems, the reliability of the active antenna detection is of vital importance since the modulated symbols tend to be correctly demodulated when the active antennas are accurately identified. In this paper, we propose a spatial coded modulation (SCM) scheme, which improves the accuracy of the active antenna detection by coding over the transmit antennas. Specifically, the antenna activation pattern in the SCM corresponds to a codeword in a properly designed codebook with a larger minimum Hamming distance than the conventional spatial modulation. As the minimum Hamming distance increases, the reliability of the active antenna detection is directly enhanced, which yields a better system reliability. In addition to the reliability, the proposed SCM scheme also achieves a higher capacity with the identical antenna configuration compared to the conventional counterpart. The optimal maximum likelihood detector is first formulated. Then, a low-complexity suboptimal detector is proposed to reduce the computational complexity. Theoretical derivations of the channel capacity and the bit error rate are presented in various channel scenarios. Further derivation on performance bounding is also provided to reveal the insight of the benefit of increasing the minimum Hamming distance. Numerical results validate the analysis and demonstrate that the proposed SCM outperforms the conventional spatial modulation techniques in both channel capacity and system reliability.
ISSN:1673-5447
DOI:10.23919/JCC.ea.2021-0011.202401