English

Optimal measures and Markov transition kernels

Optimization and Control 2021-11-23 v7 Computational Complexity Information Theory Mathematical Physics Functional Analysis math.IT math.MP Machine Learning

Abstract

We study optimal solutions to an abstract optimization problem for measures, which is a generalization of classical variational problems in information theory and statistical physics. In the classical problems, information and relative entropy are defined using the Kullback-Leibler divergence, and for this reason optimal measures belong to a one-parameter exponential family. Measures within such a family have the property of mutual absolute continuity. Here we show that this property characterizes other families of optimal positive measures if a functional representing information has a strictly convex dual. Mutual absolute continuity of optimal probability measures allows us to strictly separate deterministic and non-deterministic Markov transition kernels, which play an important role in theories of decisions, estimation, control, communication and computation. We show that deterministic transitions are strictly sub-optimal, unless information resource with a strictly convex dual is unconstrained. For illustration, we construct an example where, unlike non-deterministic, any deterministic kernel either has negatively infinite expected utility (unbounded expected error) or communicates infinite information.

Keywords

Cite

@article{arxiv.1012.0366,
  title  = {Optimal measures and Markov transition kernels},
  author = {Roman V. Belavkin},
  journal= {arXiv preprint arXiv:1012.0366},
  year   = {2021}
}

Comments

Replaced with a final and accepted draft; Journal of Global Optimization, Springer, Jan 1, 2012

R2 v1 2026-06-21T16:52:16.760Z