English

Segre-Driven Radicality Testing

Algebraic Geometry 2021-10-06 v1 Computational Complexity Symbolic Computation Commutative Algebra

Abstract

We present a probabilistic algorithm to test if a homogeneous polynomial ideal II defining a scheme XX in Pn\mathbb{P}^n is radical using Segre classes and other geometric notions from intersection theory. Its worst case complexity depends on the geometry of XX. If the scheme XX has reduced isolated primary components and no embedded components supported the singular locus of Xred=V(I)X_{\rm red}=V(\sqrt{I}), then the worst case complexity is doubly exponential in nn; in all the other cases the complexity is singly exponential. The realm of the ideals for which our radical testing procedure requires only single exponential time includes examples which are often considered pathological, such as the ones drawn from the famous Mayr-Meyer set of ideals which exhibit doubly exponential complexity for the ideal membership problem.

Keywords

Cite

@article{arxiv.2110.01913,
  title  = {Segre-Driven Radicality Testing},
  author = {Martin Helmer and Elias Tsigaridas},
  journal= {arXiv preprint arXiv:2110.01913},
  year   = {2021}
}
R2 v1 2026-06-24T06:37:45.898Z