Optimum Low-Complexity Decoder for Spatial Modulation

Al-Nahhal, Ibrahim; Başar, Ertuğrul; Dobre, Octavia A.; Ikki, Salama

doi:10.1109/jsac.2019.2929454

Cited by 23 publications

(14 citation statements)

References 34 publications

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“…In a single-user SM system, the input data stream is transmitted as a combination of spatial symbols and modulated symbols. At the receiver side, the decoder estimates both the spatial and modulated symbols by performing an exhaustive search or by using one of the low-complexity decoding algorithms, such as those in [13]- [15]. For instance, assume that an SM system is equipped with four transmit antennas (i.e., four spatial symbols) and two modulated symbols (i.e., binary phase shift keying).…”

Section: Related Work and Motivationmentioning

confidence: 99%

Low-Cost Uplink Sparse Code Multiple Access for Spatial Modulation

Al-Nahhal

Dobre

Başar

et al. 2019

IEEE Trans. Veh. Technol.

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Spatial modulation (SM)-sparse code multiple access (SCMA) systems provide high spectral efficiency (SE) at the expense of using a high number of transmit antennas. To overcome this drawback, this letter proposes a novel SM-SCMA system operating in uplink transmission, referred to as rotational generalized SM-SCMA (RGSM-SCMA). For the proposed system, the following are introduced: a) transmitter design and its formulation, b) maximum likelihood and maximum a posteriori probability decoders, and c) practical low-complexity message passing algorithm and its complexity analysis.Simulation results and complexity analysis show that the proposed RGSM-SCMA system delivers the same SE with significant savings in the number of transmit antennas, at the expense of close bit error rate and a negligible increase in the decoding complexity, when compared with SM-SCMA. Index TermsSparse code multiple access (SCMA), spatial modulation (SM), message passing algorithm (MPA).

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Section: Related Work and Motivationmentioning

confidence: 99%

Low-Cost Uplink Sparse Code Multiple Access for Spatial Modulation

Al-Nahhal

Dobre

Başar

et al. 2019

IEEE Trans. Veh. Technol.

Self Cite

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“…In recent works, some low complexity algorithms have been presented for MIMO, SM, and QSM signal detection [10,13,19]. In the works presented by [14,16], optimization algorithms and trigonometric functions were required in the receiver to detect the most likely antenna combinations.…”

Section: Low Complexity Detection Algorithmmentioning

confidence: 99%

“…However, these schemes demand many hardware implementation resources. Other detection techniques for MIMO-SM-QSM were reported in [15,19,20]. These detectors were based on tree search and spherical detection.…”

Section: Low Complexity Detection Algorithmmentioning

confidence: 99%

Fast Scalable Architecture of a Near-ML Detector for a MIMO-QSM Receiver

et al. 2019

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This paper presents a proposal for an architecture in FPGA for the implementation of a low complexity near maximum likelihood (Near-ML) detection algorithm for a multiple input-multiple output (MIMO) quadrature spatial modulation (QSM) transmission system. The proposed low complexity detection algorithm is based on a tree search and a spherical detection strategy. Our proposal was verified in the context of a MIMO receiver. The effects of the finite length arithmetic and limited precision were evaluated in terms of their impact on the receiver bit error rate (BER). We defined the minimum fixed point word size required not to impact performance adversely for n T transmit antennas and n R receive antennas. The results showed that the proposal performed very near to optimal with the advantage of a meaningful reduction in the complexity of the receiver. The performance analysis of the proposed detector of the MIMO receiver under these conditions showed a strong robustness on the numerical precision, which allowed having a receiver performance very close to that obtained with floating point arithmetic in terms of BER; therefore, we believe this architecture can be an attractive candidate for its implementation in current communications standards.

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“…Signals in Carvajal et al 26 are presented in the form of a matrix arrangement to implement a sphere decoder at the receiver. Al‐Nahhal and Dobre 27 have proposed a novel low complexity sphere decoder algorithm for quadrature spatial modulation (QSM) decoders for the decreased complexity of QSM‐ML. A smart searching algorithm depending upon perfect channel state information is proposed in 28 .…”

Section: Introductionmentioning

confidence: 99%

Novel K best sphere decoders with higher order modulation for internet of things

Mishra

Thakur

Singh

2022

Int J Communication

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Summary Future generation communication devices, particularly the Internet of Things (IoTs) demand for low bit error rate (BER) and higher spectral efficiencies. In this context, a low complexity detection algorithm plays a vital role in determining the performance of receivers. In this paper, we have evaluated the performance of low complexity sphere decoders using K best algorithm by modifying the conventional sphere decoders into new K and K1 sphere decoders. The proposed algorithm enables the sphere decoders to use smaller values of K for better performance. Numerical simulation is performed using MATLAB to support the validity of the proposed algorithm in terms of BER and spectral efficiency at higher order modulation techniques such as 1024 quadrature amplitude modulation (QAM) and offset quadrature amplitude modulation (OQAM). Further, we have also analyzed the computational complexity of the proposed algorithm.

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Optimum Low-Complexity Decoder for Spatial Modulation

Cited by 23 publications

References 34 publications

Low-Cost Uplink Sparse Code Multiple Access for Spatial Modulation

Low-Cost Uplink Sparse Code Multiple Access for Spatial Modulation

Fast Scalable Architecture of a Near-ML Detector for a MIMO-QSM Receiver

Novel K best sphere decoders with higher order modulation for internet of things

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