1. Summary Let (ft, (B, u) be a probability measure space on which is defined a stochastic process {x,} with finite state space. In 1-3 we define a notion of fractional dimension, in terms of and {x}, for any set M c t. If t is the unit interval, if is Lebesgue measure, and if = x(o)s is, for each , the base s expansion of , the definition reduces to the classical one due to Hausdorff. In 4 and 5 we obtain, under the assumption that {x} is a Markov chain, the dimensions of certain sets defined in terms of the asymptotic relative frequencies of the various transitions i--. j. In 7 these theorems are specialized to the case in which {x.} is independent. In the classical case these results become extensions of theorems due to Eggleston [4, 5] and Volkmann [16, 17]. In 6 we use the preceding theorems to obrain a result on "generalized Lipschitz conditions" on certain measures, a result which reduces in the classical case to one of Kinney [11]. In 8 the dimensions obtained in the first part of the paper are shown to be related to entropy and certain allied concepts of information theory.
[1]
P. Whittle,et al.
Some Distribution and Moment Formulae for the Markov Chain
,
1955
.
[2]
B. McMillan.
The Basic Theorems of Information Theory
,
1953
.
[3]
Feller William,et al.
An Introduction To Probability Theory And Its Applications
,
1950
.
[4]
Barnes.
Discussion of the Paper
,
1961,
Public health papers and reports.
[5]
I. J. Good,et al.
Exact Markov Probabilities from Oriented Linear Graphs
,
1957
.
[6]
L. A. Goodman.
Exact Probabilities and Asymptotic Relationships for Some Statistics from $m$-th Order Markov Chains
,
1958
.
[7]
H. Eggleston.
The fractional dimension of a set defined by decimal properties
,
1949
.
[8]
H. Eggleston,et al.
Sets of Fractional Dimensions which Occur in Some Problems of Number Theory
,
1952
.
[9]
J. Kinney.
Singular functions associated with Markov chains
,
1958
.