Matrix-F5 algorithms over finite-precision complete discrete valuation fields

Abstract

Let (f\1,…, f\s) ∈ Q\p [X\1,…, X\n]s be a sequence of homogeneous polynomials with p-adic coefficients. Such system may happen, for example, in arithmetic geometry. Yet, since Q\p is not an effective field, classical algorithm does not apply.We provide a definition for an approximate Gr\"obner basis with respect to a monomial order w. We design a strategy to compute such a basis, when precision is enough and under the assumption that the input sequence is regular and the ideals f\1,…,f\i are weakly-w-ideals. The conjecture of Moreno-Socias states that for the grevlex ordering, such sequences are generic.Two variants of that strategy are available, depending on whether one lean more on precision or time-complexity. For the analysis of these algorithms, we study the loss of precision of the Gauss row-echelon algorithm, and apply it to an adapted Matrix-F5 algorithm. Numerical examples are provided.Moreover, the fact that under such hypotheses, Gr\"obner bases can be computed stably has many applications. Firstly, the mapping sending (f\1,…,f\s) to the reduced Gr\"obner basis of the ideal they span is differentiable, and its differential can be given explicitly. Secondly, these hypotheses allows to perform lifting on the Grobner bases, from Z/pk Z to Z/pk+k' Z or Z. Finally, asking for the same hypotheses on the highest-degree homogeneous components of the entry polynomials allows to extend our strategy to the affine case.