English

Integral representation for bracket-generating multi-flows

Dynamical Systems 2023-02-15 v2

Abstract

If f1,f2f_1,f_2 are smooth vector fields on an open subset of an Euclidean space and [f1,f2][f_1,f_2] is their Lie bracket, the asymptotic formula Ψ[f1,f2](t1,t2)(x)x=t1t2[f1,f2](x)+o(t1t2),\Psi_{[f_1,f_2]}(t_1,t_2)(x) - x =t_1t_2 [f_1,f_2](x) +o(t_1t_2), where we have set Ψ[f1,f2](t1,t2)(x):=exp(t2f2)exp(t1f1)exp(t2f2)exp(t1f1)(x) \Psi_{[f_1,f_2]}(t_1,t_2)(x) := \exp(-t_2f_2)\circ\exp(-t_1f_1)\circ\exp(t_2f_2)\circ\exp(t_1f_1)(x), is valid for all t1,t2t_1,t_2 small enough. In fact, the integral, exact formula \begin{equation}\label{abstractform} \Psi_{[f_1,f_2]}(t_1,t_2)(x) - x = \int_0^{t_1}\int_0^{t_2}[f_1,f_2]^{(s_2,s_1)} (\Psi(t_1,s_2)(x))ds_1\,ds_2 , \end{equation} where [f1,f2](s2,s1)(y):=D(exp(s1f1)exp(s2f2))1[f1,f2](exp(s1f1)exp(s2f2)(y)), [f_1,f_2]^{(s_2,s_1)}(y) := D\Big(\exp(s_1f_1)\circ \exp(s_2f_2{{)}}\Big)^{-1}\cdot [f_1,f_2](\exp(s_1f_1)\circ \exp(s_2f_2){(y)}), with y=Ψ(t1,s2)(x){{y = \Psi(t_1,s_2)(x)}} has also been proven. Of course the integral formula can be regarded as an improvement of the asymptotic formula. In this paper we show that an integral representation holds true for any iterated bracket made from elements of a family of vector fields f1,,fk{f_1,\dots,f_{{k}}}. In perspective, these integral representations might lie at the basis for extensions of asymptotic formulas involving nonsmooth vector fields.

Cite

@article{arxiv.1709.02677,
  title  = {Integral representation for bracket-generating multi-flows},
  author = {Ermal Feleqi and Franco Rampazzo},
  journal= {arXiv preprint arXiv:1709.02677},
  year   = {2023}
}

Comments

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R2 v1 2026-06-22T21:37:11.339Z