English

Decentralization and Acceleration Enables Large-Scale Bundle Adjustment

Computer Vision and Pattern Recognition 2023-08-10 v3 Robotics Optimization and Control

Abstract

Scaling to arbitrarily large bundle adjustment problems requires data and compute to be distributed across multiple devices. Centralized methods in prior works are only able to solve small or medium size problems due to overhead in computation and communication. In this paper, we present a fully decentralized method that alleviates computation and communication bottlenecks to solve arbitrarily large bundle adjustment problems. We achieve this by reformulating the reprojection error and deriving a novel surrogate function that decouples optimization variables from different devices. This function makes it possible to use majorization minimization techniques and reduces bundle adjustment to independent optimization subproblems that can be solved in parallel. We further apply Nesterov's acceleration and adaptive restart to improve convergence while maintaining its theoretical guarantees. Despite limited peer-to-peer communication, our method has provable convergence to first-order critical points under mild conditions. On extensive benchmarks with public datasets, our method converges much faster than decentralized baselines with similar memory usage and communication load. Compared to centralized baselines using a single device, our method, while being decentralized, yields more accurate solutions with significant speedups of up to 953.7x over Ceres and 174.6x over DeepLM. Code: https://joeaortiz.github.io/daba.

Keywords

Cite

@article{arxiv.2305.07026,
  title  = {Decentralization and Acceleration Enables Large-Scale Bundle Adjustment},
  author = {Taosha Fan and Joseph Ortiz and Ming Hsiao and Maurizio Monge and Jing Dong and Todd Murphey and Mustafa Mukadam},
  journal= {arXiv preprint arXiv:2305.07026},
  year   = {2023}
}

Comments

Robotics: Science and Systems (RSS), 2023

R2 v1 2026-06-28T10:32:20.527Z