On the Optimality of Network Topology Discovery in Single-Hop Bounded-Interference Networks

Abstract

We propose PRISM (Pseudorandom Residue-based Indexed Scheduling Method), a deterministic topology-discovery framework for single-hop wireless networks with bounded interference. Each receiver has at most \(L\) interfering transmitters among \(K\) transmitters and identifies them through singleton transmissions. PRISM assigns finite-field labels to transmitters and schedules transmissions via modular multiplication and a second prime modulus. It achieves full discovery in \(O(L(1+δ) K)\) rounds in expectation with failure probability \(K-δ\), and in \(O(L2 K)\) rounds deterministically. Simulations show \(≈ 0.9L K\) scaling, with \(q/L≈1.2\) minimizing mean completion time and \(q/L≈1.4--1.6\) improving tail performance.