English

Computing conjugating sets and automorphism groups of rational functions

Number Theory 2012-07-05 v2 Dynamical Systems

Abstract

Let phi and psi be endomorphisms of the projective line of degree at least 2, defined over a noetherian commutative ring R with unity. From a dynamical perspective, a significant question is to determine whether phi and psi are conjugate (or to answer the related question of whether a given map phi has a nontrivial automorphism). We show that the space of automorphisms of P^1 conjugating phi to psi is a finite subscheme of PGL(2) (respectively that the automorphism group of phi is a finite group scheme). We construct efficient algorithms for computing the set of conjugating maps (resp. the group of automorphisms) when R is a field. Each of our algorithms takes advantage of different dynamical structures, so context (e.g., field of definition and degree of the map) determines the preferred algorithm. We have implemented them in Sage when R is a finite field or the field of rational numbers, and we give running times for computing automorphism groups for hundreds of random endomorphisms of P^1. These examples demonstrate the superiority of these new algorithms over a naive approach using Groebner bases.

Keywords

Cite

@article{arxiv.1202.5557,
  title  = {Computing conjugating sets and automorphism groups of rational functions},
  author = {Xander Faber and Michelle Manes and Bianca Viray},
  journal= {arXiv preprint arXiv:1202.5557},
  year   = {2012}
}

Comments

23 pages; title changed; algorithm sections rearranged to place more emphasis on the problem of detecting conjugacy between two rational functions; Sage implementation improved to run faster over large finite fields of small characteristic

R2 v1 2026-06-21T20:24:47.818Z