On Rate-Splitting by a Secondary Link in Multiple Access Primary Network

TL;DR

This paper analyzes how a secondary link employing rate-splitting can coexist with a primary multiple access network, providing achievable rate regions and conditions for decoding primary signals without degrading primary rates.

Contribution

It introduces a novel achievable rate region for secondary links with rate-splitting in primary networks, including conditions for decoding primary signals without rate loss.

Findings

Rate-splitting improves secondary rates under certain conditions.

A necessary and sufficient condition for decoding primary signals is derived.

Probability of decoding primary signals increases with primary SNR.

Abstract

An achievable rate region is obtained for a primary multiple access network coexisting with a secondary link of one transmitter and a corresponding receiver. The rate region depicts the sum primary rate versus the secondary rate and is established assuming that the secondary link performs rate-splitting. The achievable rate region is the union of two types of achievable rate regions. The first type is a rate region established assuming that the secondary receiver cannot decode any primary signal, whereas the second is established assuming that the secondary receiver can decode the signal of one primary receiver. The achievable rate region is determined first assuming discrete memoryless channel (DMC) then the results are applied to a Gaussian channel. In the Gaussian channel, the performance of rate-splitting is characterized for the two types of rate regions. Moreover, a necessary and sufficient condition to determine which primary signal that the secondary receiver can decode without degrading the range of primary achievable sum rates is provided. When this condition is satisfied by a certain primary user, the secondary receiver can decode its signal and achieve larger rates without reducing the primary achievable sum rates from the case in which it does not decode any primary signal. It is also shown that, the probability of having at least one primary user satisfying this condition grows with the primary signal to noise ratio.