Secrecy Capacity Scaling in Large Cooperative Wireless Networks

Abstract

We investigate large wireless networks subject to security constraints. In contrast to point-to-point, interference-limited communications considered in prior works, we propose active cooperative relaying based schemes. We consider a network with nl legitimate nodes, ne eavesdroppers, and path loss exponent α≥ 2. As long as ne2((ne))γ=o(nl), for some positive γ, we show one can obtain unbounded secure aggregate rate. This means zero-cost secure communication, given fixed total power constraint for the entire network. We achieve this result through (i) the source using Wyner randomized encoder and a serial (multi-stage) block Markov scheme, to cooperate with the relays and (ii) the relays acting as a virtual multi-antenna to apply beamforming against the eavesdroppers. Our simpler parallel (two-stage) relaying scheme can achieve the same unbounded secure aggregate rate when neα2+1((ne))γ+δ(α2+1)=o(nl) holds, for some positive γ,δ. Finally, we study the improvement (to the detriment of legitimate nodes) the eavesdroppers achieve in terms of the information leakage rate in a large cooperative network in case of collusion. We show that again the zero-cost secure communication is possible, if ne(2+2α)( ne)γ=o(nl) holds, for some positive γ; i.e., in case of collusion slightly fewer eavesdroppers can be tolerated compared to the non-colluding case.