English

Sparse Gr\"obner Bases: the Unmixed Case

Symbolic Computation 2014-06-26 v3

Abstract

Toric (or sparse) elimination theory is a framework developped during the last decades to exploit monomial structures in systems of Laurent polynomials. Roughly speaking, this amounts to computing in a \emph{semigroup algebra}, \emph{i.e.} an algebra generated by a subset of Laurent monomials. In order to solve symbolically sparse systems, we introduce \emph{sparse Gr\"obner bases}, an analog of classical Gr\"obner bases for semigroup algebras, and we propose sparse variants of the F5F_5 and FGLM algorithms to compute them. Our prototype "proof-of-concept" implementation shows large speed-ups (more than 100 for some examples) compared to optimized (classical) Gr\"obner bases software. Moreover, in the case where the generating subset of monomials corresponds to the points with integer coordinates in a normal lattice polytope PRn\mathcal P\subset\mathbb R^n and under regularity assumptions, we prove complexity bounds which depend on the combinatorial properties of P\mathcal P. These bounds yield new estimates on the complexity of solving 00-dim systems where all polynomials share the same Newton polytope (\emph{unmixed case}). For instance, we generalize the bound min(n1,n2)+1\min(n_1,n_2)+1 on the maximal degree in a Gr\"obner basis of a 00-dim. bilinear system with blocks of variables of sizes (n1,n2)(n_1,n_2) to the multilinear case: nimax(ni)+1\sum n_i - \max(n_i)+1. We also propose a variant of Fr\"oberg's conjecture which allows us to estimate the complexity of solving overdetermined sparse systems.

Keywords

Cite

@article{arxiv.1402.7205,
  title  = {Sparse Gr\"obner Bases: the Unmixed Case},
  author = {Jean-Charles Faugere and Pierre-Jean Spaenlehauer and Jules Svartz},
  journal= {arXiv preprint arXiv:1402.7205},
  year   = {2014}
}

Comments

20 pages, Corollary 6.1 has been corrected, ISSAC 2014, Kobe : Japan (2014)

R2 v1 2026-06-22T03:17:45.275Z