中文

Dimension and Relative Frequencies

计算复杂性 2007-05-23 v1

摘要

We show how to calculate the finite-state dimension (equivalently, the finite-state compressibility) of a saturated sets XX consisting of {\em all} infinite sequences SS over a finite alphabet Σm\Sigma_m satisfying some given condition PP on the asymptotic frequencies with which various symbols from Σm\Sigma_m appear in SS. When the condition PP completely specifies an empirical probability distribution π\pi over Σm\Sigma_m, i.e., a limiting frequency of occurrence for {\em every} symbol in Σm\Sigma_m, it has been known since 1949 that the Hausdorff dimension of XX is precisely \CH(π)\CH(\pi), the Shannon entropy of π\pi, and the finite-state dimension was proven to have this same value in 2001. The saturated sets were studied by Volkmann and Cajar decades ago. It got attention again only with the recent developments in multifractal analysis by Barreira, Saussol, Schmeling, and separately Olsen. However, the powerful methods they used -- ergodic theory and multifractal analysis -- do not yield a value for the finite-state (or even computable) dimension in an obvious manner. We give a pointwise characterization of finite-state dimensions of saturated sets. Simultaneously, we also show that their finite-state dimension and strong dimension coincide with their Hausdorff and packing dimension respectively, though the techniques we use are completely elementary. Our results automatically extend to less restrictive effective settings (e.g., constructive, computable, and polynomial-time dimensions).

引用

@article{arxiv.cs/0703085,
  title  = {Dimension and Relative Frequencies},
  author = {Xiaoyang Gu and Jack H. Lutz},
  journal= {arXiv preprint arXiv:cs/0703085},
  year   = {2007}
}