English

Completeness for the Complexity Class $\forall \exists \mathbb{R}$ and Area-Universality

Computational Geometry 2021-11-15 v3 Computational Complexity Discrete Mathematics

Abstract

Exhibiting a deep connection between purely geometric problems and real algebra, the complexity class R\exists \mathbb{R} plays a crucial role in the study of geometric problems. Sometimes R\exists \mathbb{R} is referred to as the 'real analog' of NP. While NP is a class of computational problems that deals with existentially quantified boolean variables, R\exists \mathbb{R} deals with existentially quantified real variables. In analogy to Π2p\Pi_2^p and Σ2p\Sigma_2^p in the famous polynomial hierarchy, we study the complexity classes R\forall \exists \mathbb{R} and R\exists \forall \mathbb{R} with real variables. Our main interest is the area-universality problem, where we are given a plane graph GG, and ask if for each assignment of areas to the inner faces of GG, there exists a straight-line drawing of GG realizing the assigned areas. We conjecture that area-universality is R\forall \exists \mathbb{R}-complete and support this conjecture by proving R\exists \mathbb{R}- and R\forall \exists \mathbb{R}-completeness of two variants of area-universality. To this end, we introduce tools to prove R\forall \exists \mathbb{R}-hardness and membership. Finally, we present geometric problems as candidates for R\forall \exists \mathbb{R}-complete problems. These problems have connections to the concepts of imprecision, robustness, and extendability.

Keywords

Cite

@article{arxiv.1712.05142,
  title  = {Completeness for the Complexity Class $\forall \exists \mathbb{R}$ and Area-Universality},
  author = {Michael G. Dobbins and Linda Kleist and Tillmann Miltzow and Paweł Rzążewski},
  journal= {arXiv preprint arXiv:1712.05142},
  year   = {2021}
}

Comments

36 pages, 17 figures

R2 v1 2026-06-22T23:17:49.800Z