NOMA Made Practical: Removing the Receive SIC Processing through Interference Exploitation

TL;DR

This paper introduces CoMA, a practical NOMA scheme that eliminates the need for SIC at the receiver by aligning superimposed signals constructively, improving efficiency and reducing complexity.

Contribution

A novel constructive multiple access (CoMA) scheme for NOMA that removes the need for SIC at the receiver, with optimized precoders for power and error rate minimization.

Findings

CoMA outperforms conventional NOMA in power efficiency.

CoMA reduces receiver complexity by eliminating SIC.

CoMA is effective for systems with few BS antennas.

Abstract

Non-orthogonal multiple access (NOMA) is a powerful transmission technique that enhances the spectral efficiency of communication links, and is being investigated for 5G standards and beyond. A major drawback of NOMA is the need to apply successive interference cancellation (SIC) at the receiver on a symbol-by-symbol basis, which limits its practicality. To circumvent this, in this paper a novel constructive multiple access (CoMA) scheme is proposed and investigated. CoMA aligns the superimposed signals to the different users constructively to the signal of interest. Since the superimposed signal aligns with the data signal, there is no need to remove it at the receiver using SIC. Accordingly, SIC component can be removed at the receiver side. In this regard and in order to provide a comprehensive investigation and comparison, different optimization problems for user paring NOMA multiple-input-single-output (MISO) systems are considered. Firstly, an optimal precoder to minimize the total transmission power for CoMA subject to a quality-of-service constraint is obtained, and compared to conventional NOMA. Then, a precoder that minimizes the CoMA symbol error rate (SER) subject to power constraint is investigated. Further, the computational complexity of CoMA is considered and compared with conventional NOMA scheme in terms of total number of complex operations. The results in this paper prove the superiority of the proposed CoMA scheme over the conventional NOMA technique, and demonstrate that CoMA is an attractive solution for user paring NOMA MISO systems with low number of BS antennas, while circumventing the receive SIC complexity.