Efficient Z2 synchronization on Zd under symmetry-preserving side information
Abstract
We consider Z2-synchronization on the Euclidean lattice. Every vertex of Zd is assigned an independent symmetric random sign θu, and for every edge (u,v) of the lattice, one observes the product θuθv flipped independently with probability p. The task is to reconstruct products θuθv for pairs of vertices u and v which are arbitrarily far apart. Abb\'e, Massouli\'e, Montanari, Sly and Srivastava (2018) showed that synchronization is possible if and only if p is below a critical threshold pc(d), and efficiently so for p small enough. We augment this synchronization setting with a model of side information preserving the sign symmetry of θ, and propose an efficient algorithm which synchronizes a randomly chosen pair of far away vertices on average, up to a differently defined critical threshold pc(d). We conjecture that pc(d)=pc(d) for all d 2. Our strategy is to renormalize the synchronization model in order to reduce the effective noise parameter, and then apply a variant of the multiscale algorithm of AMMSS. The success of the renormalization procedure is conditional on a plausible but unproved assumption about the regularity of the free energy of an Ising spin glass model on Zd.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.