Hybrid metapopulation agent-based epidemiological models for efficient insight on the individual scale: a contribution to green computing
Emerging infectious diseases and climate change are two of the major challenges in 21st century. Although over the past decades, highly-resolved mathematical models have contributed in understanding dynamics of infectious diseases and are of great aid when it comes to finding suitable intervention m...
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| creator | Bicker, Julia Schmieding, René Meyer-Hermann, Michael Kühn, Martin J |
| description | Emerging infectious diseases and climate change are two of the major
challenges in 21st century. Although over the past decades, highly-resolved
mathematical models have contributed in understanding dynamics of infectious
diseases and are of great aid when it comes to finding suitable intervention
measures, they may need substantial computational effort and produce
significant CO2 emissions. Two popular modeling approaches for mitigating
infectious disease dynamics are agent-based and population-based models.
Agent-based models (ABMs) offer a microscopic view and are thus able to capture
heterogeneous human contact behavior and mobility patterns. However, insights
on individual-level dynamics come with high computational effort that scales
with the number of agents. On the other hand, population-based models using
e.g. ordinary differential equations (ODEs) are computationally efficient even
for large populations due to their complexity being independent of the
population size. Yet, population-based models are restricted in their
granularity as they assume a (to some extent) homogeneous and well-mixed
population. To manage the trade-off between computational complexity and level
of detail, we propose spatial- and temporal-hybrid models that use ABMs only in
an area or time frame of interest. To account for relevant influences to
disease dynamics, e.g., from outside, due to commuting activities, we use
population-based models, only adding moderate computational costs. Our
hybridization approach demonstrates significant reduction in computational
effort by up to 98% -- without losing the required depth in information in the
focus frame. Concluding, hybrid epidemiological models can provide insights on
the individual scale where necessary, using aggregated models where possible,
thereby making a contribution to green computing. |
| doi_str_mv | 10.48550/arxiv.2406.04386 |
| format | Article |
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challenges in 21st century. Although over the past decades, highly-resolved
mathematical models have contributed in understanding dynamics of infectious
diseases and are of great aid when it comes to finding suitable intervention
measures, they may need substantial computational effort and produce
significant CO2 emissions. Two popular modeling approaches for mitigating
infectious disease dynamics are agent-based and population-based models.
Agent-based models (ABMs) offer a microscopic view and are thus able to capture
heterogeneous human contact behavior and mobility patterns. However, insights
on individual-level dynamics come with high computational effort that scales
with the number of agents. On the other hand, population-based models using
e.g. ordinary differential equations (ODEs) are computationally efficient even
for large populations due to their complexity being independent of the
population size. Yet, population-based models are restricted in their
granularity as they assume a (to some extent) homogeneous and well-mixed
population. To manage the trade-off between computational complexity and level
of detail, we propose spatial- and temporal-hybrid models that use ABMs only in
an area or time frame of interest. To account for relevant influences to
disease dynamics, e.g., from outside, due to commuting activities, we use
population-based models, only adding moderate computational costs. Our
hybridization approach demonstrates significant reduction in computational
effort by up to 98% -- without losing the required depth in information in the
focus frame. Concluding, hybrid epidemiological models can provide insights on
the individual scale where necessary, using aggregated models where possible,
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challenges in 21st century. Although over the past decades, highly-resolved
mathematical models have contributed in understanding dynamics of infectious
diseases and are of great aid when it comes to finding suitable intervention
measures, they may need substantial computational effort and produce
significant CO2 emissions. Two popular modeling approaches for mitigating
infectious disease dynamics are agent-based and population-based models.
Agent-based models (ABMs) offer a microscopic view and are thus able to capture
heterogeneous human contact behavior and mobility patterns. However, insights
on individual-level dynamics come with high computational effort that scales
with the number of agents. On the other hand, population-based models using
e.g. ordinary differential equations (ODEs) are computationally efficient even
for large populations due to their complexity being independent of the
population size. Yet, population-based models are restricted in their
granularity as they assume a (to some extent) homogeneous and well-mixed
population. To manage the trade-off between computational complexity and level
of detail, we propose spatial- and temporal-hybrid models that use ABMs only in
an area or time frame of interest. To account for relevant influences to
disease dynamics, e.g., from outside, due to commuting activities, we use
population-based models, only adding moderate computational costs. Our
hybridization approach demonstrates significant reduction in computational
effort by up to 98% -- without losing the required depth in information in the
focus frame. Concluding, hybrid epidemiological models can provide insights on
the individual scale where necessary, using aggregated models where possible,
thereby making a contribution to green computing.</description><subject>Quantitative Biology - Populations and Evolution</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNotkEFOwzAQRbNhgQoHYIUvkGA3tpOyQxVQpEpsuq_G9jgdKYkjx63oEbg1JrCa-V__z0ivKB4Er2SrFH-C-EWXai25rrisW31bfO-uJpJjAyaYwnTuIVEYGXQ4ptLAjI7hRA4HCn3oyELPhuCwn5kPkaH3ZClHGY0zdafEcjedMEtHF3LnHJ9zB58ZMBvGFMmclwcpsC4ijtkdpmyN3V1x46Gf8f5_rorD2-thuyv3n-8f25d9CbrRpRaNFsqgVVa3xliwG-6t5WtTb-pWKgEbL4XlTZsXXnMHVjZSKS9EFriuV8Xj39mFxXGKNEC8Hn-ZHBcm9Q9GCV_6</recordid><startdate>20240606</startdate><enddate>20240606</enddate><creator>Bicker, Julia</creator><creator>Schmieding, René</creator><creator>Meyer-Hermann, Michael</creator><creator>Kühn, Martin J</creator><scope>ALC</scope><scope>GOX</scope></search><sort><creationdate>20240606</creationdate><title>Hybrid metapopulation agent-based epidemiological models for efficient insight on the individual scale: a contribution to green computing</title><author>Bicker, Julia ; Schmieding, René ; Meyer-Hermann, Michael ; Kühn, Martin J</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a676-617615bec5c68bbcac90fcc02b3938451a9f41c078a9f030dac47455f1130de23</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2024</creationdate><topic>Quantitative Biology - Populations and Evolution</topic><toplevel>online_resources</toplevel><creatorcontrib>Bicker, Julia</creatorcontrib><creatorcontrib>Schmieding, René</creatorcontrib><creatorcontrib>Meyer-Hermann, Michael</creatorcontrib><creatorcontrib>Kühn, Martin J</creatorcontrib><collection>arXiv Quantitative Biology</collection><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Bicker, Julia</au><au>Schmieding, René</au><au>Meyer-Hermann, Michael</au><au>Kühn, Martin J</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Hybrid metapopulation agent-based epidemiological models for efficient insight on the individual scale: a contribution to green computing</atitle><date>2024-06-06</date><risdate>2024</risdate><abstract>Emerging infectious diseases and climate change are two of the major
challenges in 21st century. Although over the past decades, highly-resolved
mathematical models have contributed in understanding dynamics of infectious
diseases and are of great aid when it comes to finding suitable intervention
measures, they may need substantial computational effort and produce
significant CO2 emissions. Two popular modeling approaches for mitigating
infectious disease dynamics are agent-based and population-based models.
Agent-based models (ABMs) offer a microscopic view and are thus able to capture
heterogeneous human contact behavior and mobility patterns. However, insights
on individual-level dynamics come with high computational effort that scales
with the number of agents. On the other hand, population-based models using
e.g. ordinary differential equations (ODEs) are computationally efficient even
for large populations due to their complexity being independent of the
population size. Yet, population-based models are restricted in their
granularity as they assume a (to some extent) homogeneous and well-mixed
population. To manage the trade-off between computational complexity and level
of detail, we propose spatial- and temporal-hybrid models that use ABMs only in
an area or time frame of interest. To account for relevant influences to
disease dynamics, e.g., from outside, due to commuting activities, we use
population-based models, only adding moderate computational costs. Our
hybridization approach demonstrates significant reduction in computational
effort by up to 98% -- without losing the required depth in information in the
focus frame. Concluding, hybrid epidemiological models can provide insights on
the individual scale where necessary, using aggregated models where possible,
thereby making a contribution to green computing.</abstract><doi>10.48550/arxiv.2406.04386</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Quantitative Biology - Populations and Evolution |
| title | Hybrid metapopulation agent-based epidemiological models for efficient insight on the individual scale: a contribution to green computing |
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