Improved Bayesian Infrasonic Source Localization for regional infrasound

Philip S. Blom, Omar Marcillo, Stephen J. Arrowsmith

Research output: Contribution to journalArticlepeer-review

35 Scopus citations

Abstract

The mathematical framework used in the Bayesian Infrasonic Source Localization (BISL) methodology is examined and simplified providing a generalized method of estimating the source location and time for an infrasonic event. The likelihood function describing an infrasonic detection used in BISL has been redefined to include the von Mises distribution developed in directional statistics and propagation-based, physically derived celerity-range and azimuth deviation models. Frameworks for constructing propagation-based celerity-range and azimuth deviation statistics are presented to demonstrate how stochastic propagation modelling methods can be used to improve the precision and accuracy of the posterior probability density function describing the source localization. Infrasonic signals recorded at a number of arrays in the western United States produced by rocket motor detonations at the Utah Test and Training Range are used to demonstrate the application of the new mathematical framework and to quantify the improvement obtained by using the stochastic propagation modelling methods. Using propagation-based priors, the spatial and temporal confidence bounds of the source decreased by more than 40 per cent in all cases and by as much as 80 per cent in one case. Further, the accuracy of the estimates remained high, keeping the ground truth within the 99 per cent confidence bounds for all cases.

Original languageEnglish
Pages (from-to)1682-1693
Number of pages12
JournalGeophysical Journal International
Volume203
Issue number3
DOIs
StatePublished - Dec 1 2015
Externally publishedYes

Keywords

  • Acoustic-gravity waves
  • Probability distributions
  • Seismic monitoring and testban treaty verification
  • Wave propagation

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