A physics-based emulator for the simulation of geophysical mass flows

Published

Journal Article

© 2015 Society for Industrial and Applied Mathematics Publications. All rights reserved. Rare natural hazards such as large volcanic eruptions can cause loss of life and damage to property. With sufficient information, those charged with public safety may issue warnings of impending hazards to mitigate the hazard impact. Recent developments in modeling and simulating large geophysical mass flows can provide useful information in assessing hazard risk. In particular, computer simulations of a model system of PDEs, which determines flow depth and runout, are expensive to run. On the other hand, analysis based on only a few simulations is not sufficiently accurate for hazard analysis. Computational costs can be reduced by constructing a statistical emulator-an approximate response surface for selected output variables derived from several full simulator runs. Whenever the result from a simulation is required in an analysis, the emulator can be queried quickly. A key feature of the emulator is that an estimate of the prediction uncertainty is defined together with the regression estimate. A popular emulator is the Gaussian Separable Process emulator, or GaSP, which is constructed as the mean of a Bayesian posterior distribution over outputs. In this work, we propose an alternative procedure for constructing emulators, one that uses knowledge about the model physics. We model the mass flow as an Ornstein-Uhlenbeck (OU) process for sliding blocks over the topography. We demonstrate how the OU results can be used to predict simulator results. By calibrating certain input parameters, a fit to the OU process is made, together with an error approximation, by classical statistical techniques, to provide an emulator of the runout computed by the computer simulator.

Full Text

Duke Authors

Cited Authors

  • Mahmood, A; Wolpert, RL; Pitman, EB

Published Date

  • January 1, 2015

Published In

Volume / Issue

  • 3 / 1

Start / End Page

  • 562 - 585

Electronic International Standard Serial Number (EISSN)

  • 2166-2525

Digital Object Identifier (DOI)

  • 10.1137/130909445

Citation Source

  • Scopus