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2021-10-01Zeitschriftenartikel
Dose–response functions and surrogate models for exploring social contagion in the Copenhagen Networks Study
dc.contributor.authorDonges, Jonathan F.
dc.contributor.authorLochner, Jakob H.
dc.contributor.authorKitzmann, Niklas H.
dc.contributor.authorHeitzig, Jobst
dc.contributor.authorLehmann, Sune
dc.contributor.authorWiedermann, Marc
dc.contributor.authorVollmer, Jürgen
dc.date.accessioned2024-08-13T09:27:16Z
dc.date.available2024-08-13T09:27:16Z
dc.date.issued2021-10-01none
dc.identifier.other0.1140/epjs/s11734-021-00279-7
dc.identifier.urihttp://edoc.rki.de/176904/11898
dc.description.abstractSpreading dynamics and complex contagion processes on networks are important mechanisms underlying the emergence of critical transitions, tipping points and other non-linear phenomena in complex human and natural systems. Increasing amounts of temporal network data are now becoming available to study such spreading processes of behaviours, opinions, ideas, diseases and innovations to test hypotheses regarding their specific properties. To this end, we here present a methodology based on dose–response functions and hypothesis testing using surrogate data models that randomise most aspects of the empirical data while conserving certain structures relevant to contagion, group or homophily dynamics. We demonstrate this methodology for synthetic temporal network data of spreading processes generated by the adaptive voter model. Furthermore, we apply it to empirical temporal network data from the Copenhagen Networks Study. This data set provides a physically-close-contact network between several hundreds of university students participating in the study over the course of 3 months. We study the potential spreading dynamics of the health-related behaviour “regularly going to the fitness studio” on this network. Based on a hierarchy of surrogate data models, we find that our method neither provides significant evidence for an influence of a dose–response-type network spreading process in this data set, nor significant evidence for homophily. The empirical dynamics in exercise behaviour are likely better described by individual features such as the disposition towards the behaviour, and the persistence to maintain it, as well as external influences affecting the whole group, and the non-trivial network structure. The proposed methodology is generic and promising also for applications to other temporal network data sets and traits of interest.eng
dc.language.isoengnone
dc.publisherRobert Koch-Institut
dc.rights(CC BY 3.0 DE) Namensnennung 3.0 Deutschlandger
dc.rights.urihttp://creativecommons.org/licenses/by/3.0/de/
dc.subject.ddc610 Medizin und Gesundheitnone
dc.titleDose–response functions and surrogate models for exploring social contagion in the Copenhagen Networks Studynone
dc.typearticle
dc.identifier.urnurn:nbn:de:0257-176904/11898-3
dc.type.versionpublishedVersionnone
local.edoc.container-titleThe European Physical Journal Special Topicsnone
local.edoc.container-issn1951-6401none
local.edoc.pages24none
local.edoc.type-nameZeitschriftenartikel
local.edoc.container-typeperiodical
local.edoc.container-type-nameZeitschrift
local.edoc.container-urlhttps://link.springer.com/journal/11734none
local.edoc.container-publisher-nameSpringer Naturenone
local.edoc.container-volume230none
local.edoc.container-reportyear2021none
local.edoc.container-firstpage3311none
local.edoc.container-lastpage3334none
dc.description.versionPeer Reviewednone

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