Application and Evaluation of Surrogate Models for Radiation Source Search

Jared A Cook,John Mattingly,Razvan Stefanescu,Ralph C Smith,Jason M Hite

doi:10.3390/a12120269

Jared A Cook, John Mattingly + Show 3 more

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https://doi.org/10.3390/a12120269

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Journal: Algorithms	Publication Date: Dec 12, 2019
Citations: 6	License type: CC BY 4.0

Affiliation: North Carolina State University

Abstract

Surrogate models are increasingly required for applications in which first-principles simulation models are prohibitively expensive to employ for uncertainty analysis, design, or control. They can also be used to approximate models whose discontinuous derivatives preclude the use of gradient-based optimization or data assimilation algorithms. We consider the problem of inferring the 2D location and intensity of a radiation source in an urban environment using a ray-tracing model based on Boltzmann transport theory. Whereas the code implementing this model is relatively efficient, extension to 3D Monte Carlo transport simulations precludes subsequent Bayesian inference to infer source locations, which typically requires thousands to millions of simulations. Additionally, the resulting likelihood exhibits discontinuous derivatives due to the presence of buildings. To address these issues, we discuss the construction of surrogate models for optimization, Bayesian inference, and uncertainty propagation. Specifically, we consider surrogate models based on Legendre polynomials, multivariate adaptive regression splines, radial basis functions, Gaussian processes, and neural networks. We detail strategies for computing training points and discuss the merits and deficits of each method.

Highlights

Significant attention has been focused on accurate and efficient determination of the location of radioactive materials
We extend the analysis presented in Ref. [2] by exploring the choice of surrogate modeling technique and training point selection in this paper
This is one reason the surrogate modeling techniques we explore are feasible for use with high-fidelity codes

Summary

Introduction

Significant attention has been focused on accurate and efficient determination of the location of radioactive materials. One avenue of current research has focused on fusing detector data to determine the source location while attempting to decrease the number of detectors, increase the accuracy of the location estimate, and increase the efficiency of the algorithm [1,2,3]. This problem requires modeling the paths of the gamma particles emitted by the source by employing the Boltzmann transport equation to determine the origination location.

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