Linear Network Coding Capacity Region of The Smart Repeater with Broadcast Erasure Channels (1605.01331v1)
Abstract: This work considers the smart repeater network where a single source $s$ wants to send two independent packet streams to destinations ${d_1,d_2}$ with the help of relay $r$. The transmission from $s$ or $r$ is modeled by packet erasure channels: For each time slot, a packet transmitted by $s$ may be received, with some probabilities, by a random subset of ${d_1,d_2,r}$; and those transmitted by $r$ will be received by a random subset of ${d_1,d_2}$. Interference is avoided by allowing at most one of ${s,r}$ to transmit in each time slot. One example of this model is any cellular network that supports two cell-edge users when a relay in the middle uses the same downlink resources for throughput/safety enhancement. In this setting, we study the capacity region of $(R_1,R_2)$ when allowing linear network coding (LNC). The proposed LNC inner bound introduces more advanced packing-mixing operations other than the previously well-known butterfly-style XOR operation on overheard packets of two co-existing flows. A new LNC outer bound is derived by exploring the inherent algebraic structure of the LNC problem. Numerical results show that, with more than 85% of the experiments, the relative sum-rate gap between the proposed outer and inner bounds is smaller than 0.08% under the strong-relaying setting and 0.04% under arbitrary distributions, thus effectively bracketing the LNC capacity of the smart repeater problem.