Data Assimilation for Robust UQ Within Agent-Based Simulation on HPC Systems

Adam Spannaus; Sifat Afroj Moon; John Gounley; Heidi A. Hanson

doi:10.1145/3732775.3733582

Data Assimilation for Robust UQ Within Agent-Based Simulation on HPC Systems

Adam Spannaus, Sifat Afroj Moon, John Gounley, Heidi A. Hanson

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Agent-based simulation provides a powerful tool for in silico system modeling. However, these simulations do not provide built-in methods for uncertainty quantification (UQ). Within these types of models a typical approach to UQ is to run multiple realizations of the model then compute aggregate statistics. This approach is limited due to the compute time required for a solution. When faced with an emerging biothreat, public health decisions need to be made quickly and solutions for integrating near real-time data with analytic tools are needed. We propose an integrated Bayesian UQ framework for agent-based models based on sequential Monte Carlo sampling. Given streaming or static data about the evolution of an emerging pathogen this Bayesian framework provides a distribution over the parameters governing the spread of a disease through a population. These estimates of the spread of a disease may be provided to public health agencies seeking to abate the spread. By coupling agent-based simulations with Bayesian modeling in a data assimilation, our proposed framework provides a powerful tool for modeling dynamical systems in silico. We propose a method which reduces model error and provides a range of realistic possible outcomes. Moreover, our method addresses two primary limitations of ABMs: the lack of UQ and an inability to assimilate data. Our proposed framework combines the flexibility of an agent-based model with UQ provided by the Bayesian paradigm in a workflow which scales well to HPC systems. We provide algorithmic details and results on a simulated outbreak with both static and streaming data.

Original language	English
Title of host publication	PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings
Publisher	Association for Computing Machinery, Inc
ISBN (Electronic)	9798400718861
DOIs	https://doi.org/10.1145/3732775.3733582
State	Published - Jun 20 2025
Event	2025 Platform for Advanced Scientific Computing Conference, PASC 2025 - Brugg-Windisch, Switzerland Duration: Jun 16 2025 → Jun 18 2025

Publication series

Name	PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings

Conference

Conference	2025 Platform for Advanced Scientific Computing Conference, PASC 2025
Country/Territory	Switzerland
City	Brugg-Windisch
Period	06/16/25 → 06/18/25

Funding

This manuscript has been authored by UT-Battelle, LLC, under contract DE-AC05-00OR22725 with the US Department of Energy (DOE). The US government retains and the publisher, by accepting the article for publication, acknowledges that the US government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for US government purposes. DOE will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan (http://energy.gov/downloads/doe-public-access-plan). This material is based upon work supported by the U.S. Department of Energy, Office of Science, Office of Advanced Scientific Computing under Award Number DE-SC-ERKJ422.

Keywords

Agent-Based Simulation
Data Assimilation
Individual-Based Network Epidemic Modeling
Mathematics
Statistics

Access to Document

10.1145/3732775.3733582

Cite this

Spannaus, A., Moon, S. A., Gounley, J., & Hanson, H. A. (2025). Data Assimilation for Robust UQ Within Agent-Based Simulation on HPC Systems. In PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings (PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings). Association for Computing Machinery, Inc. https://doi.org/10.1145/3732775.3733582

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abstract = "Agent-based simulation provides a powerful tool for in silico system modeling. However, these simulations do not provide built-in methods for uncertainty quantification (UQ). Within these types of models a typical approach to UQ is to run multiple realizations of the model then compute aggregate statistics. This approach is limited due to the compute time required for a solution. When faced with an emerging biothreat, public health decisions need to be made quickly and solutions for integrating near real-time data with analytic tools are needed. We propose an integrated Bayesian UQ framework for agent-based models based on sequential Monte Carlo sampling. Given streaming or static data about the evolution of an emerging pathogen this Bayesian framework provides a distribution over the parameters governing the spread of a disease through a population. These estimates of the spread of a disease may be provided to public health agencies seeking to abate the spread. By coupling agent-based simulations with Bayesian modeling in a data assimilation, our proposed framework provides a powerful tool for modeling dynamical systems in silico. We propose a method which reduces model error and provides a range of realistic possible outcomes. Moreover, our method addresses two primary limitations of ABMs: the lack of UQ and an inability to assimilate data. Our proposed framework combines the flexibility of an agent-based model with UQ provided by the Bayesian paradigm in a workflow which scales well to HPC systems. We provide algorithmic details and results on a simulated outbreak with both static and streaming data.",

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author = "Adam Spannaus and Moon, \{Sifat Afroj\} and John Gounley and Hanson, \{Heidi A.\}",

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doi = "10.1145/3732775.3733582",

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Spannaus, A , Moon, SA , Gounley, J & Hanson, HA 2025, Data Assimilation for Robust UQ Within Agent-Based Simulation on HPC Systems. in PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings. PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings, Association for Computing Machinery, Inc, 2025 Platform for Advanced Scientific Computing Conference, PASC 2025, Brugg-Windisch, Switzerland, 06/16/25. https://doi.org/10.1145/3732775.3733582

Data Assimilation for Robust UQ Within Agent-Based Simulation on HPC Systems. / Spannaus, Adam ; Moon, Sifat Afroj ; Gounley, John et al.
PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings. Association for Computing Machinery, Inc, 2025. (PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AB - Agent-based simulation provides a powerful tool for in silico system modeling. However, these simulations do not provide built-in methods for uncertainty quantification (UQ). Within these types of models a typical approach to UQ is to run multiple realizations of the model then compute aggregate statistics. This approach is limited due to the compute time required for a solution. When faced with an emerging biothreat, public health decisions need to be made quickly and solutions for integrating near real-time data with analytic tools are needed. We propose an integrated Bayesian UQ framework for agent-based models based on sequential Monte Carlo sampling. Given streaming or static data about the evolution of an emerging pathogen this Bayesian framework provides a distribution over the parameters governing the spread of a disease through a population. These estimates of the spread of a disease may be provided to public health agencies seeking to abate the spread. By coupling agent-based simulations with Bayesian modeling in a data assimilation, our proposed framework provides a powerful tool for modeling dynamical systems in silico. We propose a method which reduces model error and provides a range of realistic possible outcomes. Moreover, our method addresses two primary limitations of ABMs: the lack of UQ and an inability to assimilate data. Our proposed framework combines the flexibility of an agent-based model with UQ provided by the Bayesian paradigm in a workflow which scales well to HPC systems. We provide algorithmic details and results on a simulated outbreak with both static and streaming data.

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KW - Mathematics

KW - Statistics

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M3 - Conference contribution

AN - SCOPUS:105010495716

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BT - PASC 2025 - Platform for Advanced Scientific Computing Conference, Proceedings

PB - Association for Computing Machinery, Inc

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ER -

Data Assimilation for Robust UQ Within Agent-Based Simulation on HPC Systems

Abstract

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