Uncertainty Quantification for Markov Processes via Variational Principles and Functional Inequalities
Probability
2020-06-11 v2
Abstract
Information-theory based variational principles have proven effective at providing scalable uncertainty quantification (i.e. robustness) bounds for quantities of interest in the presence of nonparametric model-form uncertainty. In this work, we combine such variational formulas with functional inequalities (Poincar{\'e}, -Sobolev, Liapunov functions) to derive explicit uncertainty quantification bounds for time-averaged observables, comparing a Markov process to a second (not necessarily Markov) process. These bounds are well-behaved in the infinite-time limit and apply to steady-states of both discrete and continuous-time Markov processes.
Cite
@article{arxiv.1812.05174,
title = {Uncertainty Quantification for Markov Processes via Variational Principles and Functional Inequalities},
author = {Jeremiah Birrell and Luc Rey-Bellet},
journal= {arXiv preprint arXiv:1812.05174},
year = {2020}
}
Comments
37 pages