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Main Authors: Thennakoon, Pandula, De Silva, Mario, Viduranga, M. Mahesha, Liyanage, Sashini, Godaliyadda, Roshan, Ekanayake, Mervyn Parakrama, Herath, Vijitha, Rathnayake, Anuruddhika, Thilakarathne, Ganga, Ekanayake, Janaka, Dharmarathne, Samath
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.06212
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author Thennakoon, Pandula
De Silva, Mario
Viduranga, M. Mahesha
Liyanage, Sashini
Godaliyadda, Roshan
Ekanayake, Mervyn Parakrama
Herath, Vijitha
Rathnayake, Anuruddhika
Thilakarathne, Ganga
Ekanayake, Janaka
Dharmarathne, Samath
author_facet Thennakoon, Pandula
De Silva, Mario
Viduranga, M. Mahesha
Liyanage, Sashini
Godaliyadda, Roshan
Ekanayake, Mervyn Parakrama
Herath, Vijitha
Rathnayake, Anuruddhika
Thilakarathne, Ganga
Ekanayake, Janaka
Dharmarathne, Samath
contents Computational disease modeling plays a crucial role in understanding and controlling the transmission of infectious diseases. While agent-based models (ABMs) provide detailed insights into individual dynamics, accurately replicating human motion remains challenging due to its complex, multi-factorial nature. Most existing frameworks fail to model realistic human motion, leading to oversimplified and less realistic behavior modeling. Furthermore, many current models rely on synthetic assumptions and fail to account for realistic environmental structures, transportation systems, and behavioral heterogeneity across occupation groups. To address these limitations, we introduce AVSim, an agent-based simulation framework designed to model airborne and vector-borne disease dynamics under realistic conditions. A distinguishing feature of AVSim is its ability to accurately model the dual nature of human mobility (both the destinations individuals visit and the duration of their stay) by utilizing GPS traces from real-world participants, characterized by occupation. This enables a significantly more granular and realistic representation of human movement compared to existing approaches. Furthermore, spectral clustering combined with graph-theoretic analysis is used to uncover latent behavioral patterns within occupations, enabling fine-grained modeling of agent behavior. We validate the synthetic human mobility patterns against ground-truth GPS data and demonstrate AVSim's capabilities via simulations of COVID-19 and dengue. The results highlight AVSim's capacity to trace infection pathways, identify high-risk zones, and evaluate interventions such as vaccination, quarantine, and vector control with occupational and geographic specificity.
format Preprint
id arxiv_https___arxiv_org_abs_2502_06212
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle AVSim -- Realistic Simulation Framework for Airborne and Vector-Borne Disease Dynamics
Thennakoon, Pandula
De Silva, Mario
Viduranga, M. Mahesha
Liyanage, Sashini
Godaliyadda, Roshan
Ekanayake, Mervyn Parakrama
Herath, Vijitha
Rathnayake, Anuruddhika
Thilakarathne, Ganga
Ekanayake, Janaka
Dharmarathne, Samath
Systems and Control
Computational disease modeling plays a crucial role in understanding and controlling the transmission of infectious diseases. While agent-based models (ABMs) provide detailed insights into individual dynamics, accurately replicating human motion remains challenging due to its complex, multi-factorial nature. Most existing frameworks fail to model realistic human motion, leading to oversimplified and less realistic behavior modeling. Furthermore, many current models rely on synthetic assumptions and fail to account for realistic environmental structures, transportation systems, and behavioral heterogeneity across occupation groups. To address these limitations, we introduce AVSim, an agent-based simulation framework designed to model airborne and vector-borne disease dynamics under realistic conditions. A distinguishing feature of AVSim is its ability to accurately model the dual nature of human mobility (both the destinations individuals visit and the duration of their stay) by utilizing GPS traces from real-world participants, characterized by occupation. This enables a significantly more granular and realistic representation of human movement compared to existing approaches. Furthermore, spectral clustering combined with graph-theoretic analysis is used to uncover latent behavioral patterns within occupations, enabling fine-grained modeling of agent behavior. We validate the synthetic human mobility patterns against ground-truth GPS data and demonstrate AVSim's capabilities via simulations of COVID-19 and dengue. The results highlight AVSim's capacity to trace infection pathways, identify high-risk zones, and evaluate interventions such as vaccination, quarantine, and vector control with occupational and geographic specificity.
title AVSim -- Realistic Simulation Framework for Airborne and Vector-Borne Disease Dynamics
topic Systems and Control
url https://arxiv.org/abs/2502.06212