Phase Transitions in Planted k-Factor Recovery

Abstract

This paper studies the problem of inferring a k-factor, specifically a spanning k-regular graph, planted within an Erdos-Renyi random graph G(n,λ/n). We show that as the average degree λ surpasses the critical threshold of 1/k, the inference problem undergoes a transition from almost exact recovery to partial recovery. Moreover, as λ tends to infinity, the accuracy of recovery diminishes to zero. In addition, we characterize the recovery accuracy of a linear-time iterative pruning algorithm and show that it achieves almost exact recovery when λ< 1/k. A key component of our analysis is a two-step cycle construction: we first build trees through local neighborhood exploration and then connect them by sprinkling using reserved edges. Interestingly, for proving impossibility of almost exact recovery, we construct Θ(n) many small trees of size Θ(1), whereas for establishing the algorithmic lower bound, a single large tree of size Θ(n n) suffices.