English

Solving Stochastic Inverse Problems using Sigma-Algebras on Contour Maps

Numerical Analysis 2014-07-16 v1

Abstract

We compute approximate solutions to inverse problems for determining parameters in differential equation models with stochastic data on output quantities. The formulation of the problem and modeling framework define a solution as a probability measure on the parameter domain for a given σ\sigma-algebra. In the case where the number of output quantities is less than the number of parameters, the inverse of the map from parameters to data defines a type of generalized contour map. The approximate contour maps define a geometric structure on events in the σ\sigma-algebra for the parameter domain. We develop and analyze an inherently non-intrusive method of sampling the parameter domain and events in the given σ\sigma-algebra to approximate the probability measure. We use results from stochastic geometry for point processes to prove convergence of a random sample based approximation method. We define a numerical σ\sigma-algebra on which we compute probabilities and derive computable estimates for the error in the probability measure. We present numerical results to illustrate the various sources of error for a model of fluid flow past a cylinder.

Keywords

Cite

@article{arxiv.1407.3851,
  title  = {Solving Stochastic Inverse Problems using Sigma-Algebras on Contour Maps},
  author = {Troy Butler and Don Estep and Simon Tavener and Timothy Wildey and Clint Dawson and Lindley Graham},
  journal= {arXiv preprint arXiv:1407.3851},
  year   = {2014}
}

Comments

26 pages, 24 figures

R2 v1 2026-06-22T05:04:05.053Z