Primal-dual interior-point Methods for Semidefinite Programming from an algebraic point of view, or: Using Noncommutativity for Optimization
Abstract
Since more than three decades, interior-point methods proved very useful for optimization, from linear over semidefinite to conic (and partly beyond non-convex) programming; despite the fact that already in the semidefinite case (even when strong duality holds) "hard" problems are known. We shade a light on a rather surprising restriction in the non-commutative world (of semidefinite programming), namely "commutative" paths and propose a new family of solvers that is able to use the full richness of "non-commutative" search directions: (primal) feasible-interior-point methods. Beside a detailed basic discussion, we illustrate some variants of "non-commutative" paths and provide a simple implementation for further (problem specific) investigations.
Cite
@article{arxiv.1812.10278,
title = {Primal-dual interior-point Methods for Semidefinite Programming from an algebraic point of view, or: Using Noncommutativity for Optimization},
author = {Konrad Schrempf},
journal= {arXiv preprint arXiv:1812.10278},
year = {2020}
}
Comments
49 pages, 10 figures, 3 tables, 5 Octave/Matlab files; slightly updated version