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Human mobility in epidemic modeling

Human mobility in epidemic modeling
Human mobility in epidemic modeling
Human mobility forms the backbone of contact patterns through which infectious diseases propagate, fundamentally shaping the spatio-temporal dynamics of epidemics and pandemics. While traditional models are often based on the assumption that all individuals have the same probability of infecting every other individual in the population, a so-called random homogeneous mixing, they struggle to catch the complex and heterogeneous nature of real-world human interactions. Recent advancements in data-driven methodologies and computational capabilities have unlocked the potential of integrating high-resolution human mobility data into epidemic modeling, significantly improving the accuracy, timeliness, and applicability of epidemic risk assessment, contact tracing, and intervention strategies. This review provides a comprehensive synthesis of the current landscape in human mobility-informed epidemic modeling. We explore several data sources and representations of human mobility, and examine the behavioral and structural roles of mobility and contact in shaping disease transmission dynamics. Furthermore, the review spans a wide range of epidemic modeling approaches, ranging from classical compartmental models to network-based, agent-based, and machine learning models. It also discusses how mobility integration enhances risk management and response strategies during epidemics. By synthesizing these insights, the review can serve as a foundational resource for researchers and practitioners, bridging the gap between epidemiological theory and the dynamic complexities of human interaction while charting clear directions for future research.
Compartmental models, Complex networks, Contact networks, Epidemic dynamics, Human mobility, Non-pharmaceutical intervention
0370-1573
1-45
Lu, Xin
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Feng, Jiawei
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Lai, Shengjie
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Holme, Petter
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Liu, Shuo
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Du, Zhanwei
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Yuan, Xiaoqian
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Wang, Siqing
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Li, Yunxuan
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Zhang, Xiaoyu
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Bai, Yuan
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Duan, Xiaojun
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Mei, Wenjun
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Yu, Hongjie
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Tan, Suoyi
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Liljeros, Fredrik
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Lu, Xin
7f0f67c1-9c66-406e-8608-225d903e5c5d
Feng, Jiawei
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Lai, Shengjie
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Holme, Petter
bd500316-31c3-4c34-a243-25bc3b58f394
Liu, Shuo
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Du, Zhanwei
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Yuan, Xiaoqian
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Wang, Siqing
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Li, Yunxuan
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Zhang, Xiaoyu
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Bai, Yuan
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Duan, Xiaojun
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Mei, Wenjun
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Yu, Hongjie
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Tan, Suoyi
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Liljeros, Fredrik
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Lu, Xin, Feng, Jiawei, Lai, Shengjie, Holme, Petter, Liu, Shuo, Du, Zhanwei, Yuan, Xiaoqian, Wang, Siqing, Li, Yunxuan, Zhang, Xiaoyu, Bai, Yuan, Duan, Xiaojun, Mei, Wenjun, Yu, Hongjie, Tan, Suoyi and Liljeros, Fredrik (2026) Human mobility in epidemic modeling. Physics Reports, 1157, 1-45. (doi:10.1016/j.physrep.2025.10.010).

Record type: Review

Abstract

Human mobility forms the backbone of contact patterns through which infectious diseases propagate, fundamentally shaping the spatio-temporal dynamics of epidemics and pandemics. While traditional models are often based on the assumption that all individuals have the same probability of infecting every other individual in the population, a so-called random homogeneous mixing, they struggle to catch the complex and heterogeneous nature of real-world human interactions. Recent advancements in data-driven methodologies and computational capabilities have unlocked the potential of integrating high-resolution human mobility data into epidemic modeling, significantly improving the accuracy, timeliness, and applicability of epidemic risk assessment, contact tracing, and intervention strategies. This review provides a comprehensive synthesis of the current landscape in human mobility-informed epidemic modeling. We explore several data sources and representations of human mobility, and examine the behavioral and structural roles of mobility and contact in shaping disease transmission dynamics. Furthermore, the review spans a wide range of epidemic modeling approaches, ranging from classical compartmental models to network-based, agent-based, and machine learning models. It also discusses how mobility integration enhances risk management and response strategies during epidemics. By synthesizing these insights, the review can serve as a foundational resource for researchers and practitioners, bridging the gap between epidemiological theory and the dynamic complexities of human interaction while charting clear directions for future research.

Text
Physics Reports-Human Mobility and Epidemic Modeling-accepted version - Accepted Manuscript
Available under License Creative Commons Attribution Non-commercial No Derivatives.
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More information

Submitted date: 22 July 2025
Accepted/In Press date: 30 October 2025
e-pub ahead of print date: 7 November 2025
Published date: 12 February 2026
Additional Information: Publisher Copyright: © 2025 Elsevier B.V.
Keywords: Compartmental models, Complex networks, Contact networks, Epidemic dynamics, Human mobility, Non-pharmaceutical intervention

Identifiers

Local EPrints ID: 507050
URI: http://eprints.soton.ac.uk/id/eprint/507050
DOI: doi:10.1016/j.physrep.2025.10.010
ISSN: 0370-1573
PURE UUID: e122483a-0d17-4787-ab08-f0e240f43a99
ORCID for Shengjie Lai: ORCID iD orcid.org/0000-0001-9781-8148

Catalogue record

Date deposited: 25 Nov 2025 18:04
Last modified: 26 Nov 2025 02:55

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Contributors

Author: Xin Lu
Author: Jiawei Feng
Author: Shengjie Lai ORCID iD
Author: Petter Holme
Author: Shuo Liu
Author: Zhanwei Du
Author: Xiaoqian Yuan
Author: Siqing Wang
Author: Yunxuan Li
Author: Xiaoyu Zhang
Author: Yuan Bai
Author: Xiaojun Duan
Author: Wenjun Mei
Author: Hongjie Yu
Author: Suoyi Tan
Author: Fredrik Liljeros

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