English

Optimization and Sampling Under Continuous Symmetry: Examples and Lie Theory

Data Structures and Algorithms 2021-09-03 v1 Machine Learning Optimization and Control Representation Theory Computation

Abstract

In the last few years, the notion of symmetry has provided a powerful and essential lens to view several optimization or sampling problems that arise in areas such as theoretical computer science, statistics, machine learning, quantum inference, and privacy. Here, we present two examples of nonconvex problems in optimization and sampling where continuous symmetries play -- implicitly or explicitly -- a key role in the development of efficient algorithms. These examples rely on deep and hidden connections between nonconvex symmetric manifolds and convex polytopes, and are heavily generalizable. To formulate and understand these generalizations, we then present an introduction to Lie theory -- an indispensable mathematical toolkit for capturing and working with continuous symmetries. We first present the basics of Lie groups, Lie algebras, and the adjoint actions associated with them, and we also mention the classification theorem for Lie algebras. Subsequently, we present Kostant's convexity theorem and show how it allows us to reduce linear optimization problems over orbits of Lie groups to linear optimization problems over polytopes. Finally, we present the Harish-Chandra and the Harish-Chandra--Itzykson--Zuber (HCIZ) formulas, which convert partition functions (integrals) over Lie groups into sums over the corresponding (discrete) Weyl groups, enabling efficient sampling algorithms.

Keywords

Cite

@article{arxiv.2109.01080,
  title  = {Optimization and Sampling Under Continuous Symmetry: Examples and Lie Theory},
  author = {Jonathan Leake and Nisheeth K. Vishnoi},
  journal= {arXiv preprint arXiv:2109.01080},
  year   = {2021}
}

Comments

This article is to supplement the talks by the authors at the Bootcamp in the semester on Geometric Methods for Optimization and Sampling at the Simons Institute for the Theory of Computing

R2 v1 2026-06-24T05:38:14.475Z