Distributed Certifiably Correct Pose-Graph Optimization

This article presents the first certifiably correct algorithm for distributed pose-graph optimization (PGO), the backbone of modern collaborative simultaneous localization and mapping (CSLAM) and camera network localization (CNL) systems. Our method is based upon a sparse semidefinite relaxation that we prove provides globally optimal PGO solutions under moderate measurement noise (matching the guarantees enjoyed by the state-of-the-art centralized methods), but is amenable to distributed optimization using the low-rank Riemannian Staircase framework. To implement the Riemannian Staircase in the distributed setting, we develop Riemannian block coordinate descent (RBCD), a novel method for (locally) minimizing a function over a product of Riemannian manifolds. We also propose the first distributed solution verification and saddle escape methods to certify the global optimality of critical points recovered via RBCD, and to descend from suboptimal critical points (if necessary). All components of our approach are inherently decentralized: they require only local communication, provide privacy protection, and are easily parallelizable. Extensive evaluations on synthetic and real-world datasets demonstrate that the proposed method correctly recovers globally optimal solutions under moderate noise, and outperforms alternative distributed techniques in terms of solution precision and convergence speed.

Automated summary

This article introduces the first certified correct algorithm for distributed pose-graph optimization, which achieves globally optimal solutions and proposes the distributed Riemannian gradient framework and Riemannian block coordinate descent method. Extensive evaluations show that the proposed method can correctly recover globally optimal solutions under moderate noise.