English

Strictly convergent analytic structures

Logic 2014-04-01 v2 Algebraic Geometry

Abstract

We give conclusive answers to some questions about definability in analytic languages that arose shortly after the work by Denef and van den Dries, [DD], on pp-adic subanalytic sets, and we continue the study of non-archimedean fields with analytic structure of [LR3], [CLR1] and [CL1]. We show that the language LKL_K consisting of the language of valued fields together with all strictly convergent power series over a complete, rank one valued field KK can be expanded, in a definitial way, to a larger language corresponding to an analytic structure (with separated power series) from [CL1], hence inheriting all properties from loc. cit., including geometric properties for the definable sets like certain forms of quantifier elimination. Our expansion comes from adding specific, existentially definable functions, which are solutions of certain henselian systems of equations. Moreover, we show that, even when KK is algebraically closed, one does not have quantifier elimination in LKL_K itself, and hence, passing to expansions is unavoidable in general. We pursue this study in the wider generality of extending non-separated power series rings to separated ones, and give new examples, in particular of the analytic structure over Z[[t]]\mathbb{Z}[[t]] that can be interpreted and understood now in all complete valued fields. In a separate direction, we show in rather large generality that Weierstrass preparation implies Weierstrass division.

Keywords

Cite

@article{arxiv.1312.5932,
  title  = {Strictly convergent analytic structures},
  author = {Raf Cluckers and Leonard Lipshitz},
  journal= {arXiv preprint arXiv:1312.5932},
  year   = {2014}
}

Comments

41 pages, some further results have been added

R2 v1 2026-06-22T02:32:31.967Z