Mathematics > Algebraic Geometry
[Submitted on 17 Dec 2018 (v1), last revised 17 Jul 2019 (this version, v2)]
Title:Shifted varieties and discrete neighborhoods around varieties
View PDFAbstract:In the area of symbolic-numerical computation within computer algebra, an interesting question is how "close" a random input is to the "critical" ones, like the singular matrices in linear algebra or the polynomials with multiple roots for Newton's root-finding method. Bounds, sometimes very precise, are known for the volumes over R or C of such neighborhoods of the varieties of "critical" inputs.
This paper deals with the discrete version of this question: over a finite field, how many points lie in a certain type of neighborhood around a given variety? A trivial upper bound on this number is (size of the variety) x (size of a neighborhood of a point). It turns out that this bound is usually asymptotically tight, including for the singular matrices, polynomials with multiple roots, and pairs of non-coprime polynomials.
The interesting question then is: for which varieties does this bound not hold? We show that these are precisely those that admit a shift, that is, where one absolutely irreducible component is a shift (translation by a fixed nonzero point) of another such component. Furthermore, the shift-invariant absolutely irreducible varieties are characterized as being cylinders over some base variety.
Computationally, determining whether a given variety is shift-invariant turns out to be intractable, namely NP-hard even in simple cases.
Submission history
From: Guillermo Matera [view email][v1] Mon, 17 Dec 2018 19:36:15 UTC (24 KB)
[v2] Wed, 17 Jul 2019 22:01:14 UTC (27 KB)
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