On Non-Orthogonal Multiple Access with Finite-Alphabet Inputs in Z-Channels

TL;DR

This paper designs a practical NOMA scheme for Z-channels with finite-alphabet QAM inputs, optimizing transmit scaling factors to improve error performance using a novel Farey sequence approach.

Contribution

It introduces a closed-form solution for joint scaling optimization in finite-alphabet NOMA Z-channels, addressing a complex mixed-integer problem with a new analytical method.

Findings

Proposed scheme outperforms existing orthogonal and non-orthogonal methods.

Closed-form solutions simplify the optimization process.

Simulation results validate the effectiveness of the design.

Abstract

This paper focuses on the design of non-orthogonal multiple access (NOMA) in a classical two-transmitter two-receiver Z-channel, wherein one transmitter sends information to its intended receiver from the direct link while the other transmitter sends information to both receivers from the direct and cross links. Unlike most existing designs using (continuous) Gaussian input distribution, we consider the practical finite-alphabet (i.e., discrete) inputs by assuming that the widely-used quadrature amplitude modulation (QAM) constellations are adopted by both transmitters. To balance the error performance of two receivers, we apply the max-min fairness design criterion in this paper. More specifically, we propose to jointly optimize the scaling factors at both transmitters, which control the minimum Euclidean distance of transmitting constellations, to maximize the smaller minimum Euclidean distance of two resulting constellations at the receivers, subject to an individual average power constraint at each transmitter. The formulated problem is a mixed continuous-discrete optimization problem and is thus intractable in general. By resorting to the Farey sequence, we manage to attain the closed-form expression for the optimal solution to the formulated problem. This is achieved by dividing the overall feasible region of the original optimization problem into a finite number of sub-intervals and deriving the optimal solution in each sub-interval. Through carefully observing the structure of the optimal solutions in all sub-intervals, we obtain compact and closed-form expressions for the optimal solutions to the original problem in three possible scenarios defined by the relative strength of the cross link. Simulation studies are provided to validate our analysis and demonstrate the merits of the proposed design over existing orthogonal or non-orthogonal schemes.