English

Generic Birkhoff Spectra

Dynamical Systems 2019-10-31 v2

Abstract

Suppose that Ω={0,1}N\Omega = \{0, 1\}^ {\mathbb {N}} and σ {\sigma} is the one-sided shift. The Birkhoff spectrum Sf(α)=dimH{ωΩ:limN1Nn=1Nf(σnω)=α}, \displaystyle S_{f}( {\alpha})=\dim_{H}\Big \{ {\omega}\in {\Omega}:\lim_{N \to \infty} \frac{1}{N} \sum_{n=1}^N f(\sigma^n \omega) = \alpha \Big \}, where dimH\dim_{H} is the Hausdorff dimension. It is well-known that the support of Sf(α)S_{f}( {\alpha}) is a bounded and closed interval Lf=[αf,min,αf,max]L_f = [\alpha_{f, \min}^*, \alpha_{f, \max}^*] and Sf(α)S_{f}( {\alpha}) on LfL_{f} is concave and upper semicontinuous. We are interested in possible shapes/properties of the spectrum, especially for generic/typical fC(Ω)f\in C( {\Omega}) in the sense of Baire category. For a dense set in C(Ω)C( {\Omega}) the spectrum is not continuous on R {\mathbb {R}}, though for the generic fC(Ω)f\in C( {\Omega}) the spectrum is continuous on R {\mathbb {R}}, but has infinite one-sided derivatives at the endpoints of LfL_{f}. We give an example of a function which has continuous SfS_{f} on R {\mathbb {R}}, but with finite one-sided derivatives at the endpoints of LfL_{f}. The spectrum of this function can be as close as possible to a "minimal spectrum". We use that if two functions ff and gg are close in C(Ω)C( {\Omega}) then SfS_{f} and SgS_{g} are close on LfL_{f} apart from neighborhoods of the endpoints.

Keywords

Cite

@article{arxiv.1905.06001,
  title  = {Generic Birkhoff Spectra},
  author = {Zoltán Buczolich and Balázs Maga and Ryo Moore},
  journal= {arXiv preprint arXiv:1905.06001},
  year   = {2019}
}

Comments

Revised version after the referee's report

R2 v1 2026-06-23T09:07:00.734Z