We consider two important time scales-the Markov and cryptic orders-that monitor how an observer synchronizes to a finitary stochastic process. We show how to compute these orders exactly and that they are most efficiently calculated from the ε-machine, a process's minimal unifilar model. Surprisingly, though the Markov order is a basic concept from stochastic process theory, it is not a probabilistic property of a process. Rather, it is a topological property and, moreover, it is not computable from any finite-state model other than the ε-machine. Via an exhaustive survey, we close by demonstrating that infinite Markov and infinite cryptic orders are a dominant feature in the space of finite-memory processes. We draw out the roles played i...
We investigate a stationary process's crypticity---a measure of the difference between its ...
Many natural and engineered dynamical systems, including all living objects, exhibit signatures of w...
The study of sequences of dependent random variables arose at the beginning of the twentieth century...
We consider two important time scales-the Markov and cryptic orders-that monitor how an observer syn...
We consider two important time scales---the Markov and cryptic orders---that monitor how an...
Abstract: Order-preserving couplings are elegant tools for obtaining robust estimates of the time-de...
An information-theoretic approach to numerically determine the Markov order of discrete stochastic p...
The world around us is awash with structure and pattern. We observe it in thecycles of the seasons, ...
Loosely speaking, the Shannon entropy rate is used to gauge a stochastic process’ intrinsic randomne...
Loosely speaking, the Shannon entropy rate is used to gauge a stochastic process' intrinsic randomne...
A stochastic process's statistical complexity stands out as a fundamental property: the min...
Let {Y sub t} be a stationary stochastic process with values in the finite set YY. We model {Y sub t...
A stochastic process' statistical complexity stands out as a fundamental property: the minimum infor...
The ε-machine is a stochastic process's optimal model-maximally predictive and minimal in size. It o...
We study the synchronization of two discrete Markov chains that share common states. Markov chains d...
We investigate a stationary process's crypticity---a measure of the difference between its ...
Many natural and engineered dynamical systems, including all living objects, exhibit signatures of w...
The study of sequences of dependent random variables arose at the beginning of the twentieth century...
We consider two important time scales-the Markov and cryptic orders-that monitor how an observer syn...
We consider two important time scales---the Markov and cryptic orders---that monitor how an...
Abstract: Order-preserving couplings are elegant tools for obtaining robust estimates of the time-de...
An information-theoretic approach to numerically determine the Markov order of discrete stochastic p...
The world around us is awash with structure and pattern. We observe it in thecycles of the seasons, ...
Loosely speaking, the Shannon entropy rate is used to gauge a stochastic process’ intrinsic randomne...
Loosely speaking, the Shannon entropy rate is used to gauge a stochastic process' intrinsic randomne...
A stochastic process's statistical complexity stands out as a fundamental property: the min...
Let {Y sub t} be a stationary stochastic process with values in the finite set YY. We model {Y sub t...
A stochastic process' statistical complexity stands out as a fundamental property: the minimum infor...
The ε-machine is a stochastic process's optimal model-maximally predictive and minimal in size. It o...
We study the synchronization of two discrete Markov chains that share common states. Markov chains d...
We investigate a stationary process's crypticity---a measure of the difference between its ...
Many natural and engineered dynamical systems, including all living objects, exhibit signatures of w...
The study of sequences of dependent random variables arose at the beginning of the twentieth century...