English

Almost Newton, sometimes Latt\`es

Number Theory 2011-05-10 v1

Abstract

Self-maps everywhere defined on the projective space N\P^N over a number field or a function field are the basic objects of study in the arithmetic of dynamical systems. One reason is a theorem of Fakkruddin \cite{Fakhruddin} (with complements in \cite{Bhatnagar}) that asserts that a "polarized" self-map of a projective variety is essentially the restriction of a self-map of the projective space given by the polarization. In this paper we study the natural self-maps defined the following way: FF is a homogeneous polynomial of degree dd in (N+1)(N+1) variables XiX_i defining a smooth hypersurface. Suppose the characteristic of the field does not divide dd and define the map of partial derivatives ϕF=(FX0,...,FXN)\phi_F = (F_{X_0},...,F_{X_N}). The map ϕF\phi_F is defined everywhere due to the following formula of Euler: XiFXi=dF\sum X_i F_{X_i} = d F, which implies that a point where all the partial derivatives vanish is a non-smooth point of the hypersuface F=0. One can also compose such a map with an element of \PGLN+1\PGL_{N+1}. In the particular case addressed in this article, N=1, the smoothness condition means that FF has only simple zeroes. In this manner, fixed points and their multipliers are easy to describe and, moreover, with a few modifications we recover classical dynamical systems like the Newton method for finding roots of polynomials or the Latt\`es map corresponding to the multiplication by 2 on an elliptic curve.

Keywords

Cite

@article{arxiv.1105.1696,
  title  = {Almost Newton, sometimes Latt\`es},
  author = {Benjamin Hutz and Lucien Szpiro},
  journal= {arXiv preprint arXiv:1105.1696},
  year   = {2011}
}

Comments

11 pages

R2 v1 2026-06-21T18:04:36.344Z