English

Using Semicontinuity for Standard Bases Computations

Commutative Algebra 2025-12-19 v1 Algebraic Geometry

Abstract

We present new results and an algorithm for standard basis computations of a 0-dimensional ideal I in a power series ring or in the localization of a polynomial ring in finitely many variables over a field K. The algorithm provides a significant speed up if K is the quotient field of a Noetherian integral domain A, when coefficient swell occurs. The most important special cases are perhaps when A is the ring of integers resp. when A is a polynomial ring over some field in finitely many parameters. Given I as an ideal in the polynomial ring over A, we compute first a standard basis modulo a prime number p, resp. by specializing the parameter to a constant. We then use the "highest corner" of the specialized ideal to cut off high order terms from the polynomials during the standard basis computation over K to get the speed up. An important fact is that we can choose p as an arbitrary prime resp. as an arbitrary constant, not just a "lucky" resp. "random" one. Correctness of the algorithm will be deduced from a general semicontinuity theorem due to the first two authors. The computer algebra system Singular provides already the functionality to realize the algorithm and we present several examples illustrating its power.

Keywords

Cite

@article{arxiv.2108.09735,
  title  = {Using Semicontinuity for Standard Bases Computations},
  author = {Gert-Martin Greuel and Gerhard Pfister and Hans Schönemann},
  journal= {arXiv preprint arXiv:2108.09735},
  year   = {2025}
}

Comments

13 pages

R2 v1 2026-06-24T05:19:18.361Z