English

Elimination by Substitution

Commutative Algebra 2024-03-12 v1

Abstract

Let KK be a field and P=K[x1,,xn]P=K[x_1,\dots,x_n]. The technique of elimination by substitution is based on discovering a coherently Z=(z1,,zs)Z=(z_1,\dots,z_s)-separating tuple of polynomials (f1,,fs)(f_1,\dots,f_s) in an ideal II, i.e., on finding polynomials such that fi=zihif_i = z_i - h_i with hiK[XZ]h_i \in K[X \setminus Z]. Here we elaborate on this technique in the case when PP is non-negatively graded. The existence of a coherently ZZ-separating tuple is reduced to solving several P0P_0-module membership problems. Best separable re-embeddings, i.e., isomorphisms P/IK[XZ]/(IK[XZ])P/I \longrightarrow K[X \setminus Z] / (I \cap K[X \setminus Z]) with maximal #Z\#Z, are found degree-by-degree. They turn out to yield optimal re-embeddings in the positively graded case. Viewing P0P/IP_0 \longrightarrow P/I as a fibration over an affine space, we show that its fibers allow optimal ZZ-separating re-embeddings, and we provide a criterion for a fiber to be isomorphic to an affine space. In the last section we introduce a new technique based on the solution of a unimodular matrix problem which enables us to construct automorphisms of PP such that additional ZZ-separating re-embeddings are possible. One of the main outcomes is an algorithm which allows us to explicitly compute a homogeneous isomorphism between P/IP/I and a non-negatively graded polynomial ring if P/IP/I is regular.

Keywords

Cite

@article{arxiv.2403.06415,
  title  = {Elimination by Substitution},
  author = {Martin Kreuzer and Lorenzo Robbiano},
  journal= {arXiv preprint arXiv:2403.06415},
  year   = {2024}
}

Comments

26 pages

R2 v1 2026-06-28T15:15:18.052Z