English

A Geometric Perspective on Polynomially Solvable Convex Maximization

Optimization and Control 2026-05-01 v1

Abstract

Convex maximization encompasses a broad class of optimization problems and is generally NP-hard, even for low-rank objectives. This paper investigates structural conditions under which convex maximization becomes polynomially solvable. From a geometric perspective, we introduce comonotonicity, a structural property of the feasible region crucial for problem tractability, and establish mathematical characterizations of this property. Under comonotonicity and mild additional assumptions, we develop a unified enumerative framework showing that fixed-rank convex maximization is polynomially solvable. This viewpoint recovers several known tractability results that previously required separate analyses, such as fixed-rank convex matroid maximization and sparse principal component analysis (SPCA). Furthermore, for the more structured class of standard comonotone feasible regions, we refine the analysis via a lifting technique to achieve a square-root improvement in the complexity bound. Finally, applications to SPCA and its variants illustrate the broad applicability and effectiveness of the proposed framework.

Keywords

Cite

@article{arxiv.2604.27427,
  title  = {A Geometric Perspective on Polynomially Solvable Convex Maximization},
  author = {Shaoning Han and Liangju Li and Yongchun Li},
  journal= {arXiv preprint arXiv:2604.27427},
  year   = {2026}
}
R2 v1 2026-07-01T12:42:53.931Z