English

Non-autonomous Parabolic Bifurcation

Complex Variables 2019-05-06 v1 Dynamical Systems

Abstract

Let f(z)=z+z2+O(z3)f(z) = z+z^2+O(z^3) and fϵ(z)=f(z)+ϵ2f_\epsilon(z) = f(z) + \epsilon^2. A classical result in parabolic bifurcation in one complex variable is the following: if Nπϵ0N-\frac{\pi}{\epsilon}\to 0 we obtain (fϵ)NLf(f_\epsilon)^{N} \to \mathcal{L}_f, where Lf\mathcal{L}_f is the Lavaurs map of ff. In this paper we study a \textit{non-autonomous} parabolic bifurcation. We focus on the case of f0(z)=z1zf_0(z)=\frac{z}{1-z}. Given a sequence {ϵi}1iN\{\epsilon_i\}_{1\leq i\leq N}, we denote fn(z)=f0(z)+ϵn2f_n(z) = f_0(z) + \epsilon_n^2. We give sufficient and necessary conditions on the sequence {ϵi}\{\epsilon_i\} that imply that fNf1Idf_{N}\circ\ldots f_{1} \to \textrm{Id} (the Lavaurs map of f0f_0). We apply our results to prove parabolic bifurcation phenomenon in two dimensions for some class of maps.

Cite

@article{arxiv.1905.00937,
  title  = {Non-autonomous Parabolic Bifurcation},
  author = {Liz Vivas},
  journal= {arXiv preprint arXiv:1905.00937},
  year   = {2019}
}

Comments

12 pages, comments welcome

R2 v1 2026-06-23T08:55:38.926Z