English

Interior-point methods on manifolds: theory and applications

Optimization and Control 2024-06-26 v2 Data Structures and Algorithms Differential Geometry

Abstract

Interior-point methods offer a highly versatile framework for convex optimization that is effective in theory and practice. A key notion in their theory is that of a self-concordant barrier. We give a suitable generalization of self-concordance to Riemannian manifolds and show that it gives the same structural results and guarantees as in the Euclidean setting, in particular local quadratic convergence of Newton's method. We analyze a path-following method for optimizing compatible objectives over a convex domain for which one has a self-concordant barrier, and obtain the standard complexity guarantees as in the Euclidean setting. We provide general constructions of barriers, and show that on the space of positive-definite matrices and other symmetric spaces, the squared distance to a point is self-concordant. To demonstrate the versatility of our framework, we give algorithms with state-of-the-art complexity guarantees for the general class of scaling and non-commutative optimization problems, which have been of much recent interest, and we provide the first algorithms for efficiently finding high-precision solutions for computing minimal enclosing balls and geometric medians in nonpositive curvature.

Keywords

Cite

@article{arxiv.2303.04771,
  title  = {Interior-point methods on manifolds: theory and applications},
  author = {Hiroshi Hirai and Harold Nieuwboer and Michael Walter},
  journal= {arXiv preprint arXiv:2303.04771},
  year   = {2024}
}

Comments

85 pages. v2: Merged with independent work arXiv:2212.10981 by Hiroshi Hirai

R2 v1 2026-06-28T09:07:56.162Z