Impact of CSIR, SIC, and Hardware Impairments on the Ergodic Rate of Downlink RSMA

TL;DR

This paper analyzes how practical impairments like CSIR, SIC, and hardware issues affect the ergodic rate of downlink RSMA, providing closed-form expressions and highlighting RSMA's robustness over NOMA.

Contribution

It derives analytical expressions for ergodic rate and fairness under impairments, demonstrating RSMA's superiority and robustness in realistic conditions.

Findings

Imperfect CSIR dominates at low transmit powers.

Hardware impairments become the main bottleneck at high transmit powers.

RSMA outperforms NOMA in ergodic rate, fairness, and sum-rate under impairments.

Abstract

This work investigates the ergodic rate performance analysis of rate-splitting multiple access (RSMA) in a downlink communication system under practical impairments. Closed-form expressions are derived for key performance metrics such as ergodic rate, energy efficiency, sum-rate, and Jains fairness index, capturing the joint effects of imperfect channel state information at the receiver (CSIR), imperfect successive interference cancellation (SIC), and hardware impairments. Numerical simulations validate the accuracy of the analytical expressions and reveal several insightful trends. At low transmit powers, imperfect CSIR is the dominant performance-limiting factor, followed by hardware impairments and imperfect SIC. However, as the transmit power increases, hardware impairments become the primary bottleneck, with the impact of imperfect CSIR gradually diminishing, and imperfect SIC becoming a more prominent bottleneck. Moreover, RSMA consistently outperforms non-orthogonal multiple access (NOMA) in terms of ergodic rate, fairness, and sum-rate, even under severe non-idealities. These findings underscore the importance of incorporating fairness as a core design objective alongside rate and energy efficiency, positioning RSMA as a robust and strong multiple access candidate for next-generation wireless networks.