English

The Proper Basis for Polynomial Ideals

Commutative Algebra 2025-01-06 v3 Symbolic Computation Algebraic Geometry

Abstract

We define a new type of ideal basis called the proper basis that improves both Gr\"obner basis and Buchberger's algorithm. Let x1x_1 be the least variable of a monomial ordering in a polynomial ring K[x1,,xn]K[x_1,\dotsc,x_n] over a field KK. The Gr\"obner basis of a zero-dimensional polynomial ideal contains a univariate polynomial in x1x_1. The proper basis is defined and computed in the variables x~:=(x2,,xn)\tilde{\bm{x}}:=(x_2,\dotsc,x_n) with x1x_1 serving as a parameter in the algebra K[x1][x~]K[x_1][\tilde{\bm{x}}]. Its algorithm is more efficient than not only Buchberger's algorithm whose elimination of x~\tilde{\bm{x}} unnecessarily involves the least variable x1x_1 but also M\"oller's algorithm due to its polynomial division mechanism. This is corroborated by a series of benchmark testings herein. The proper basis is in a modular form and neater than Gr\"obner basis and hence reduces its coefficient swell problem. It is expected that all the state of the art algorithms improving Buchberger's algorithm over the last decades can be further improved if we apply them to the proper basis.

Keywords

Cite

@article{arxiv.2101.03482,
  title  = {The Proper Basis for Polynomial Ideals},
  author = {Sheng-Ming Ma},
  journal= {arXiv preprint arXiv:2101.03482},
  year   = {2025}
}

Comments

15 pages. The length of the previous version is shortened to 15 pages in its current form

R2 v1 2026-06-23T21:57:29.950Z