Learning of state-space models with highly informative observations: a tempered Sequential Monte Carlo solution
Andreas Svensson, Thomas B. Sch\"on, Fredrik Lindsten

TL;DR
This paper introduces a tempered Sequential Monte Carlo method to improve parameter learning in nonlinear state-space models with highly informative observations, addressing a key challenge in probabilistic filtering.
Contribution
The authors propose an adaptive algorithm that gradually reduces artificial measurement noise, enabling effective likelihood estimation in challenging high-information scenarios.
Findings
Successfully applied to Wiener-Hammerstein benchmark
Demonstrates improved likelihood estimation accuracy
Shows promise for complex nonlinear models
Abstract
Probabilistic (or Bayesian) modeling and learning offers interesting possibilities for systematic representation of uncertainty using probability theory. However, probabilistic learning often leads to computationally challenging problems. Some problems of this type that were previously intractable can now be solved on standard personal computers thanks to recent advances in Monte Carlo methods. In particular, for learning of unknown parameters in nonlinear state-space models, methods based on the particle filter (a Monte Carlo method) have proven very useful. A notoriously challenging problem, however, still occurs when the observations in the state-space model are highly informative, i.e. when there is very little or no measurement noise present, relative to the amount of process noise. The particle filter will then struggle in estimating one of the basic components for probabilistic…
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