English

Decentralized Online Riemannian Optimization with Dynamic Environments

Optimization and Control 2024-10-08 v1 Differential Geometry

Abstract

This paper develops the first decentralized online Riemannian optimization algorithm on Hadamard manifolds. Our algorithm, the decentralized projected Riemannian gradient descent, iteratively performs local updates using projected Riemannian gradient descent and a consensus step via weighted Frechet mean. Theoretically, we establish linear variance reduction for the consensus step. Building on this, we prove a dynamic regret bound of order O(T(1+PT)/(1σ2(W))){\cal O}(\sqrt{T(1+P_T)}/\sqrt{(1-\sigma_2(W))}), where TT is the time horizon, PTP_T represents the path variation measuring nonstationarity, and σ2(W)\sigma_2(W) measures the network connectivity. The weighted Frechet mean in our algorithm incurs a minimization problem, which can be computationally expensive. To further alleviate this cost, we propose a simplified consensus step with a closed-form, replacing the weighted Frechet mean. We then establish linear variance reduction for this alternative and prove that the decentralized algorithm, even with this simple consensus step, achieves the same dynamic regret bound. Finally, we validate our approach with experiments on nonstationary decentralized Frechet mean computation over hyperbolic spaces and the space of symmetric positive definite matrices, demonstrating the effectiveness of our methods.

Keywords

Cite

@article{arxiv.2410.05128,
  title  = {Decentralized Online Riemannian Optimization with Dynamic Environments},
  author = {Hengchao Chen and Qiang Sun},
  journal= {arXiv preprint arXiv:2410.05128},
  year   = {2024}
}
R2 v1 2026-06-28T19:11:27.874Z