English

The embedding flows of $C^\infty$ hyperbolic diffeomorphisms

Classical Analysis and ODEs 2014-07-31 v1 Dynamical Systems

Abstract

In [{\it American J. Mathematics}, 124(2002), 107--127] we proved that for a germ of CC^\infty hyperbolic diffeomorphisms F(x)=Ax+f(x)F(x)=Ax+f(x) in (Rn,0)(\mathbb R^n,0), if AA has a real logarithm with its eigenvalues weakly nonresonant, then F(x)F(x) can be embedded in a CC^\infty autonomous differential system. Its proof was very complicated, which involved the existence of embedding periodic vector field of F(x)F(x) and the extension of the Floquet's theory to nonlinear CC^\infty periodic differential systems. In this paper we shall provide a simple and direct proof to this last result. Next we shall show that the weakly nonresonant condition in the last result on the real logarithm of AA is necessary for some CC^\infty diffeomorphisms F(x)=Ax+f(x)F(x)=Ax+f(x) to have CC^\infty embedding flows. Finally we shall prove that a germ of CC^\infty hyperbolic diffeomorphisms F(x)=Ax+f(x)F(x)=Ax+f(x) with f(x)=O(x2)f(x)=O(|x|^2) in (R2,0)(\mathbb R^2,0) has a CC^\infty embedding flow if and only if either AA has no negative eigenvalues or AA has two equal negative eigenvalues and it can be diagonalizable.

Cite

@article{arxiv.1407.7949,
  title  = {The embedding flows of $C^\infty$ hyperbolic diffeomorphisms},
  author = {Zhang Xiang},
  journal= {arXiv preprint arXiv:1407.7949},
  year   = {2014}
}

Comments

23. Journal of Differential Equations, 2011

R2 v1 2026-06-22T05:16:24.211Z