Divergent Predictive States:
The Statistical Complexity Dimension of Stationary, Ergodic Hidden Markov Processes

Alexandra M. Jurgens and James P. Crutchfield

Complexity Sciences Center
Physics Department
University of California at Davis
Davis, CA 95616

ABSTRACT: Even simply-defined, finite-state generators produce stochastic processes that require tracking an uncountable infinity of probabilistic features for optimal prediction. For processes generated by hidden Markov chains the consequences are dramatic. Their predictive models are generically infinite-state. And, until recently, one could determine neither their intrinsic randomness nor struc- tural complexity. The prequel, though, introduced methods to accurately calculate the Shannon entropy rate (randomness) and to constructively determine their minimal (though, infinite) set of predictive features. Leveraging this, we address the complementary challenge of determining how structured hidden Markov processes are by calculating their statistical complexity dimension—the information dimension of the minimal set of predictive features. This tracks the divergence rate of the minimal memory resources required to optimally predict a broad class of truly complex processes.


Alexandra M. Jurgens and James P. Crutchfield, “Divergent Predictive States: The Statistical Complexity Dimension of Stationary, Ergodic Hidden Markov Processes”, (2021).
doi:.
[pdf].
arxiv.org:2102.10487 [cond-mat.stat-mech].