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A Surrogate Modelling Approach Based on Nonlinear Dimension Reduction for Uncertainty Quantification in Groundwater

C Gadd1, W Xing1, M Mousavi Nezhad1

  • 1School of Engineering, University of Warwick, Coventry, CV47AL UK.

Transport in Porous Media
|March 16, 2019
PubMed
Summary

This study introduces a new surrogate modeling method for groundwater flow, accurately predicting outputs from uncertain inputs. The approach enhances uncertainty quantification for complex hydrological models.

Keywords:
Groundwater flow modelsKarhunen–Loève expansionManifold learningSurrogate modelUncertainty quantification

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Area of Science:

  • Environmental science
  • Geosciences
  • Computational modeling

Background:

  • Groundwater flow models often involve complex, uncertain input fields like hydraulic conductivity.
  • Accurate prediction of output fields (e.g., pressure head) is crucial for hydrological assessments.
  • Existing methods may struggle with high-dimensional stochastic inputs and uncertainty quantification.

Purpose of the Study:

  • To develop an efficient surrogate modeling approach for groundwater flow with stochastic inputs.
  • To enable accurate prediction of output fields for unseen input scenarios.
  • To establish a framework for forward uncertainty quantification in these models.

Main Methods:

  • Utilized Karhunen-Loève expansion for log-normally distributed input fields.
  • Applied manifold learning (local tangent space alignment) for Gaussian process Bayesian inference.
  • Employed Hamiltonian Monte Carlo and Monte Carlo methods for sampling and analysis.

Main Results:

  • Developed a surrogate model capable of capturing output fields from stochastic inputs.
  • Successfully performed Gaussian process Bayesian inference in an abstract feature space.
  • Demonstrated the approach's accuracy on 2-D Darcy flow and 3-D Richards equation models.

Conclusions:

  • The proposed surrogate modeling approach accurately predicts groundwater flow outputs under uncertainty.
  • The framework provides a robust method for forward uncertainty quantification in hydrological modeling.
  • This technique offers a computationally efficient way to handle complex stochastic problems in geosciences.