An extension of the angular synchronization problem to the heterogeneous setting

Abstract

Given an undirected measurement graph G = ([n], E), the classical angular synchronization problem consists of recovering unknown angles θ1,…,θn from a collection of noisy pairwise measurements of the form (θi - θj) 2π, for each \i,j\ ∈ E. This problem arises in a variety of applications, including computer vision, time synchronization of distributed networks, and ranking from preference relationships. In this paper, we consider a generalization to the setting where there exist k unknown groups of angles θl,1, …,θl,n, for l=1,…,k. For each \i,j\ ∈ E, we are given noisy pairwise measurements of the form θ,i - θ,j for an unknown ∈ \1,2,…,k\. This can be thought of as a natural extension of the angular synchronization problem to the heterogeneous setting of multiple groups of angles, where the measurement graph has an unknown edge-disjoint decomposition G = G1 G2 … Gk, where the Gi's denote the subgraphs of edges corresponding to each group. We propose a probabilistic generative model for this problem, along with a spectral algorithm for which we provide a detailed theoretical analysis in terms of robustness against both sampling sparsity and noise. The theoretical findings are complemented by a comprehensive set of numerical experiments, showcasing the efficacy of our algorithm under various parameter regimes. Finally, we consider an application of bi-synchronization to the graph realization problem, and provide along the way an iterative graph disentangling procedure that uncovers the subgraphs Gi, i=1,…,k which is of independent interest, as it is shown to improve the final recovery accuracy across all the experiments considered.