English

Finite-State Mutual Dimension

Information Theory 2021-09-30 v1 Computational Complexity math.IT

Abstract

In 2004, Dai, Lathrop, Lutz, and Mayordomo defined and investigated the finite-state dimension (a finite-state version of algorithmic dimension) of a sequence SΣS \in \Sigma^\infty and, in 2018, Case and Lutz defined and investigated the mutual (algorithmic) dimension between two sequences SΣS \in \Sigma^\infty and TΣT \in \Sigma^\infty. In this paper, we propose a definition for the lower and upper finite-state mutual dimensions mdimFS(S:T)mdim_{FS}(S:T) and MdimFS(S:T)Mdim_{FS}(S:T) between two sequences SΣS \in \Sigma^\infty and TΣT \in \Sigma^\infty over an alphabet Σ\Sigma. Intuitively, the finite-state dimension of a sequence SΣS \in \Sigma^\infty represents the density of finite-state information contained within SS, while the finite-state mutual dimension between two sequences SΣS \in \Sigma^\infty and TΣT \in \Sigma^\infty represents the density of finite-state information shared by SS and TT. Thus ``finite-state mutual dimension'' can be viewed as a ``finite-state'' version of mutual dimension and as a ``mutual'' version of finite-state dimension. The main results of this investigation are as follows. First, we show that finite-state mutual dimension, defined using information-lossless finite-state compressors, has all of the properties expected of a measure of mutual information. Next, we prove that finite-state mutual dimension may be characterized in terms of block mutual information rates. Finally, we provide necessary and sufficient conditions for two normal sequences to achieve mdimFS(S:T)=MdimFS(S:T)=0mdim_{FS}(S:T) = Mdim_{FS}(S:T) = 0.

Cite

@article{arxiv.2109.14574,
  title  = {Finite-State Mutual Dimension},
  author = {Adam Case and Jack H. Lutz},
  journal= {arXiv preprint arXiv:2109.14574},
  year   = {2021}
}

Comments

35 pages

R2 v1 2026-06-24T06:29:24.921Z