Enhancing piecewise‐defined surrogate response surfaces with adjoints on sets of unstructured samples to solve stochastic inverse problems

Summary Many approaches for solving stochastic inverse problems suffer from both stochastic and deterministic sources of error. The finite number of samples used to construct a solution is a common source of stochastic error. When computational models are expensive to evaluate, surrogate response su...

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Bibliographic Details
Published in:International journal for numerical methods in engineering 2019-09, Vol.119 (10), p.923-940
Main Authors: Mattis, Steven A., Butler, Troy
Format: Article
Language:English
Subjects:
a posteriori error estimate
Accuracy
adjoint problems
Adjoints
Engineering
Errors
Inverse problems
Mathematical models
Mathematics
Monte Carlo methods
Response surface methodology
Sampling
Sampling error
surrogate modeling
uncertainty quantification
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Summary:Summary Many approaches for solving stochastic inverse problems suffer from both stochastic and deterministic sources of error. The finite number of samples used to construct a solution is a common source of stochastic error. When computational models are expensive to evaluate, surrogate response surfaces are often employed to increase the number of samples available for approximating the solution. This leads to a reduction in finite sampling errors while the deterministic error in the evaluation of each sample is potentially increased. The pointwise accuracy of sampling the surrogate is primarily impacted by two sources of deterministic error: the local order of accuracy in the surrogate and the numerical error from the numerical solution of the model. In this work, we use adjoints to simultaneously give a posteriori error and derivative estimates in order to construct low‐order, piecewise‐defined surrogates on sets of unstructured samples. Several examples demonstrate the computational gains of this approach in obtaining accurate estimates of probabilities for events in the design space of model input parameters. This lays the groundwork for future studies on goal‐oriented adaptive refinement of such surrogates.
ISSN:0029-5981
1097-0207
DOI:10.1002/nme.6078