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Bibliographic Details
Main Authors: Haq, Ihtisham Ul, Richard, Serge
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.29907
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author Haq, Ihtisham Ul
Richard, Serge
author_facet Haq, Ihtisham Ul
Richard, Serge
contents Parameter inference and state estimation in stochastic and partially observed biological systems remain major problems in mathematical biology. In this work, we introduce a two-dimensional lattice graph model for the spread of infectious diseases. Estimating states and parameters in graph-based stochastic epidemic systems is particularly challenging because of randomness and incomplete observations. To address these issues, we propose a particle filter based data assimilation framework for the sequential estimation of both model states and unknown parameters. Two methodologies are developed: one based on the number of infected agents and another based on partial spatial location's information of infected agents on a two-dimensional lattice. The performance of the two methods are firstly analyzed and validated using synthetic data, and the first method is then applied to influenza data collected from different prefectures in Japan between July 2024 and December 2025. One-week-ahead forecasting simulations are also performed using current weekly data. The findings highlight the effectiveness of the proposed PF framework for real-time epidemic monitoring, forecasting, and adaptive public health decision-making.
format Preprint
id arxiv_https___arxiv_org_abs_2605_29907
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Stochastic network epidemic model and particle filter: General framework and application to influenza in Japan
Haq, Ihtisham Ul
Richard, Serge
Quantitative Methods
Parameter inference and state estimation in stochastic and partially observed biological systems remain major problems in mathematical biology. In this work, we introduce a two-dimensional lattice graph model for the spread of infectious diseases. Estimating states and parameters in graph-based stochastic epidemic systems is particularly challenging because of randomness and incomplete observations. To address these issues, we propose a particle filter based data assimilation framework for the sequential estimation of both model states and unknown parameters. Two methodologies are developed: one based on the number of infected agents and another based on partial spatial location's information of infected agents on a two-dimensional lattice. The performance of the two methods are firstly analyzed and validated using synthetic data, and the first method is then applied to influenza data collected from different prefectures in Japan between July 2024 and December 2025. One-week-ahead forecasting simulations are also performed using current weekly data. The findings highlight the effectiveness of the proposed PF framework for real-time epidemic monitoring, forecasting, and adaptive public health decision-making.
title Stochastic network epidemic model and particle filter: General framework and application to influenza in Japan
topic Quantitative Methods
url https://arxiv.org/abs/2605.29907