Abstract
In this paper, we study the achievable link-layer rate, namely, effective capacity (EC), under the per-user statistical delay quality-of-service (QoS) requirements, for a downlink non-orthogonal multiple access (NOMA) network with $M$ users. Specifically, the $M$ users are assumed to be divided into multiple NOMA pairs. Conventional orthogonal multiple access (OMA) then is applied for inter-NOMA-pairs multiple access. Focusing on the total link-layer rate for a downlink $M$ -user network, we prove that OMA outperforms NOMA when the transmit signal-to-noise ratio (SNR) is small. On the contrary, simulation results show that NOMA prevails over OMA at high values of SNR. Aware of the importance of a two-user NOMA network, we also theoretically investigate the impact of the transmit SNR and the delay QoS requirement on the individual EC performance and the total link-layer rate for a two-user network. Specifically, for delay-constrained and delay-unconstrained users, we prove that for the user with the stronger channel condition in a two-user network, NOMA prevails over OMA when the transmit SNR is large. On the other hand, for the user with the weaker channel condition in a two-user network, it is proved that NOMA outperforms OMA when the transmit SNR is small. Furthermore, for the user with the weaker channel condition, the individual EC in NOMA is limited to a maximum value, even if the transmit SNR goes to infinity. To confirm these insightful conclusions, the closed-form expressions for the individual EC in a two-user network, by applying NOMA or OMA, are derived for both users and then confirmed using Monte Carlo simulations.
Highlights
Due to the explosive growth of mobile data and the Internet of Things (IoT) applications which exponentially accelerate the demand for high data rates, 5G has been anticipated to offer much higher data rate, less end-to-end latency and a significant reduction in network energy usage [1]
By assuming that the M users are divided into multiple non-orthogonal multiple access (NOMA) pairs, simulation results show that NOMA offers higher total effective capacity (EC) than orthogonal multiple access (OMA) at high signal-to-noise ratio (SNR) values
We found that the advantage of NOMA over OMA becomes stable when the transmit SNR is extremely high
Summary
Due to the explosive growth of mobile data and the Internet of Things (IoT) applications which exponentially accelerate the demand for high data rates, 5G has been anticipated to offer much higher data rate, less end-to-end latency and a significant reduction in network energy usage [1]. We focus on a downlink NOMA network with M users, and theoretically prove the advantage of NOMA over OMA, in terms of either the individual EC or the total linklayer achievable rate. The impact of the transmit SNR and the delay QoS requirement on the individual linklayer rate and the total EC for the two-user network are investigated and analyzed. We start to analyze and investigate the individual EC and the total link-layer rate for a downlink NOMA network, which includes the closed-form expressions for the link-layer rates in a two-user network, in NOMA and OMA scenarios, and the theoretical analysis for a two-user network and a downlink NOMA network with multiple NOMA pairs.
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