Short-Packet Communications with NOMA for IoT Applications

This work introduces, for the first time, non-orthogonal multiple access (NOMA) into short-packet communications. This introduction has great potential to achieve low latency, thus making it attractive for the emerging Internet of Things. Considering a finite blocklength, we determine the optimal transmission rates and power allocation in NOMA that maximize the effective throughput of the user with a higher channel gain while guaranteeing a certain effective throughput at the other user. With a finite blocklength, the perfect successive interference cancellation cannot be guaranteed, which leads to new challenges in optimizing NOMA that have been addressed in this work. We also analyze the performance of orthogonal multiple access (OMA) as a benchmark to fully demonstrate the benefit of NOMA. Our examination shows that NOMA significantly outperforms OMA in terms of achieving a higher effective throughput subject to the same latency or incurring a lower latency to achieve the same effective throughput target. Interestingly, we also find that with a finite blocklength the advantage of NOMA relative to OMA is more prominent when the effective throughput targets at the two users become more comparable. Our work indicates that NOMA is a promising enabler of short-packet communications, and achieving fairness among users.

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