A New Multiple Access Technique for 5G: Power Domain Sparse Code Multiple Access (PSMA)
TLDR
In this paper, the authors proposed a power domain sparse code multiple access (PSMA) for 5G networks, where the same codebook can be reused in the coverage area of each base station more than one time.Abstract:
In this paper, a new approach for multiple access in the fifth generation (5G) of cellular networks called power domain sparse code multiple access (PSMA) is proposed. In PSMA, we adopt both the power domain and the code domain to transmit multiple users’ signals over a subcarrier simultaneously. In such a model, the same sparse code multiple-access (SCMA) codebook can be used by multiple users, where, for these users, the power domain non-orthogonal multiple access (PD-NOMA) technique is used to send signals non-orthogonally. Although the signal of different SCMA codebooks can be detected orthogonally, the same codebook used by multiple users produces interference over these users. With PSMA, a codebook can be reused in the coverage area of each base station more than one time, which can improve the spectral efficiency. We investigate the signal model as well as the receiver and transmitter of the PSMA method. In the receiver side, we propose a message passing algorithm-based successive interference cancellation detector to detect the signal of each user. To evaluate the performance of PSMA, we consider a heterogeneous cellular network. In this case, our design objective is to maximize the system sum rate of the network subject to some system level and QoS constraints such as transmit power constraints. We formulate the proposed resource allocation problem as an optimization problem and solve it by successive convex approximation techniques. Moreover, we compare PSMA with SCMA and PD-NOMA from the performance and computational complexity perspective. Finally, the effectiveness of the proposed approach is investigated using numerical results. We show that by a reasonable increase in complexity, PSMA can improve the spectral efficiency about 50% compared with SCMA and PD-NOMA.read more
Citations
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Journal ArticleDOI
A Systematic Review on NOMA Variants for 5G and Beyond
Ishan Budhiraja,Neeraj Kumar,Sudhanshu Tyagi,Sudeep Tanwar,Zhu Han,Md. Jalil Piran,Doug Young Suh +6 more
TL;DR: In this paper, the authors present an in-depth survey of state-of-the-art non-orthogonal multiple access (NOMA) variants having power and code domains as the backbone for interference mitigation, resource allocations, and QoS management in the 5G environment.
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Joint Power-Domain and SCMA-Based NOMA System for Downlink in 5G and Beyond
TL;DR: A joint power and code-domain non-orthogonal multiple access technique for the fifth-generation (5G) wireless networks and beyond and a downlink system, where the users’ experience diverse channel conditions, is considered.
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Creating Collision-Free Communication in IoT with 6G Using Multiple Machine Access Learning Collision Avoidance Protocol
P. Mohamed Shakeel,S. Baskar,Hassan Fouad,Hassan Fouad,Gunasekaran Manogaran,Gunasekaran Manogaran,Vijayalakshmi Saravanan,Qin Xin +7 more
TL;DR: This protocol employs the Media Access Control protocol for the sync of high-speed wireless communication networks in the Terahertz (THz) band and performs multiple machine access and collision control for improving the resource utilization and latency-less services of the users.
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Performance Analysis of Cooperative Relaying Systems With Power-Domain Non-Orthogonal Multiple Access
TL;DR: This paper shows that the proposed cooperative NOMA relaying scheme with two-phase superposition coding can significantly outperform existing schemes in terms of achieving a higher ergodic sum rate, a lower outage probability, or higher throughput at the cost of a slightly increased complexity.
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On information-theoretic limits of code-domain NOMA for 5G
TL;DR: The comparative analysis shows that it is beneficial to adopt extreme low-dense code-domain NOMA in the large system limit, where the number of resource elements and number of users grow unboundedly while their ratio, called load, is kept constant.
References
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Proceedings ArticleDOI
Sparse code multiple access
Hosein Nikopour,Hadi Baligh +1 more
TL;DR: A new multiple access scheme so called sparse code multiple access (SCMA) is proposed which still enjoys the low complexity reception technique but with better performance compared to LDS, allowing us to take advantage of a near optimal ML receiver with practically feasible complexity.