Enhancing industrial X-ray tomography by data-centric statistical methods

Jarkko Suuronen, Muhammad Emzir, Sari Lasanen, Simo Särkkä, Lassi Roininen*

*Corresponding author for this work

Research output: Contribution to journalArticleScientificpeer-review

5 Citations (Scopus)
101 Downloads (Pure)

Abstract

X-ray tomography has applications in various industrial fields such as sawmill industry, oil and gas industry, as well as chemical, biomedical, and geotechnical engineering. In this article, we study Bayesian methods for the X-ray tomography reconstruction. In Bayesian methods, the inverse problem of tomographic reconstruction is solved with the help of a statistical prior distribution which encodes the possible internal structures by assigning probabilities for smoothness and edge distribution of the object. We compare Gaussian random field priors, that favor smoothness, to non-Gaussian total variation (TV), Besov, and Cauchy priors which promote sharp edges and high-and low-contrast areas in the object. We also present computational schemes for solving the resulting high-dimensional Bayesian inverse problem with 100,000-1,000,000 unknowns. We study the applicability of a no-U-turn variant of Hamiltonian Monte Carlo (HMC) methods and of a more classical adaptive Metropolis-within-Gibbs (MwG) algorithm to enable full uncertainty quantification of the reconstructions. We use maximum a posteriori (MAP) estimates with limited-memory BFGS (Broyden-Fletcher-Goldfarb-Shanno) optimization algorithm. As the first industrial application, we consider sawmill industry X-ray log tomography. The logs have knots, rotten parts, and even possibly metallic pieces, making them good examples for non-Gaussian priors. Secondly, we study drill-core rock sample tomography, an example from oil and gas industry. In that case, we compare the priors without uncertainty quantification. We show that Cauchy priors produce smaller number of artefacts than other choices, especially with sparse high-noise measurements, and choosing HMC enables systematic uncertainty quantification, provided that the posterior is not pathologically multimodal or heavy-tailed.

Original languageEnglish
Article numbere10
Number of pages17
JournalData-Centric Engineering
Volume1
Issue number3
DOIs
Publication statusPublished - 16 Oct 2020
MoE publication typeA1 Journal article-refereed

Keywords

  • Bayesian statistical inverse problems
  • contrast-boosting inversion
  • Hamiltonian Monte Carlo
  • industrial X-ray tomography
  • non-Gaussian random fields

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    04/09/201931/12/2022

    Project: Academy of Finland: Other research funding

  • Probabilistic Deep Learning via Hierarchical Stochastic Partial Differential Equations

    Särkkä, S. (Principal investigator), Karvonen, T. (Project Member), Sarmavuori, J. (Project Member), Raitoharju, M. (Project Member), Bahrami Rad, A. (Project Member), Hostettler, R. (Project Member), Emzir, M. (Project Member), Gao, R. (Project Member), Purisha, Z. (Project Member) & Tronarp, F. (Project Member)

    01/01/201831/12/2019

    Project: Academy of Finland: Other research funding

  • Multispectral photon-counting for medical imaging and beam characterization

    Särkkä, S. (Principal investigator), Yamin, A. (Project Member), Gao, R. (Project Member), Purisha, Z. (Project Member), Tronarp, F. (Project Member), Emzir, M. (Project Member), Sarmavuori, J. (Project Member), Zhao, Z. (Project Member) & Hassan, S. S. (Project Member)

    01/01/201831/12/2021

    Project: Academy of Finland: Other research funding

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