Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Patel, Lekha, Ulmer, Craig, Verzi, Stephen J., Krofcheck, Daniel J., Manickam, Indu, Naugle, Asmeret, Ray, Jaideep
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2511.16816
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866909915918893056
author Patel, Lekha
Ulmer, Craig
Verzi, Stephen J.
Krofcheck, Daniel J.
Manickam, Indu
Naugle, Asmeret
Ray, Jaideep
author_facet Patel, Lekha
Ulmer, Craig
Verzi, Stephen J.
Krofcheck, Daniel J.
Manickam, Indu
Naugle, Asmeret
Ray, Jaideep
contents The estimation of explosive yield from heterogeneous observational data presents fundamental challenges in inverse problems, particularly when combining traditional physical measurements with modern artificial intelligence-interpreted modalities. We present a novel Bayesian fractional posterior framework that fuses seismic waves, crater dimensions, synthetic aperture radar imagery, and vision-language model interpreted ground-level images to estimate the yield of the 2020 Beirut explosion. Unlike conventional approaches that may treat data sources equally, our method learns trust weights for each modality through a Dirichlet prior, automatically calibrating the relative information content of disparate observations. Applied to the Beirut explosion, the framework yields an estimate of 0.34--0.48 kt TNT equivalent, representing 12 to 17 percent detonation efficiency relative to the 2.75 kt theoretical maximum from the blast's stored ammonium nitrate. The fractional posterior approach demonstrates superior uncertainty quantification compared to single-modality estimates while providing robustness against systematic biases. This work establishes a principled framework for integrating qualitative assessments with quantitative physical measurements, with applications to explosion monitoring, disaster response, and forensic analysis.
format Preprint
id arxiv_https___arxiv_org_abs_2511_16816
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Trust-Aware Multimodal Data Fusion for Yield Estimation: A Case Study of the 2020 Beirut Explosion
Patel, Lekha
Ulmer, Craig
Verzi, Stephen J.
Krofcheck, Daniel J.
Manickam, Indu
Naugle, Asmeret
Ray, Jaideep
Applications
Computation
The estimation of explosive yield from heterogeneous observational data presents fundamental challenges in inverse problems, particularly when combining traditional physical measurements with modern artificial intelligence-interpreted modalities. We present a novel Bayesian fractional posterior framework that fuses seismic waves, crater dimensions, synthetic aperture radar imagery, and vision-language model interpreted ground-level images to estimate the yield of the 2020 Beirut explosion. Unlike conventional approaches that may treat data sources equally, our method learns trust weights for each modality through a Dirichlet prior, automatically calibrating the relative information content of disparate observations. Applied to the Beirut explosion, the framework yields an estimate of 0.34--0.48 kt TNT equivalent, representing 12 to 17 percent detonation efficiency relative to the 2.75 kt theoretical maximum from the blast's stored ammonium nitrate. The fractional posterior approach demonstrates superior uncertainty quantification compared to single-modality estimates while providing robustness against systematic biases. This work establishes a principled framework for integrating qualitative assessments with quantitative physical measurements, with applications to explosion monitoring, disaster response, and forensic analysis.
title Trust-Aware Multimodal Data Fusion for Yield Estimation: A Case Study of the 2020 Beirut Explosion
topic Applications
Computation
url https://arxiv.org/abs/2511.16816