Detecting communities in time-evolving proximity networks

The pattern of interactions between individuals in a population contains implicitly within them a remarkable amount of information. This information, if extracted, could be of significant importance in several realms such as containing the spread of disease, understanding information flow in social...

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Hauptverfasser:	Pandit, S., Yang Yang, Kawadia, V., Sreenivasan, S., Chawla, N. V.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Clustering algorithms Communities community detection Concurrent computing contact graph Data mining Electronic mail Humans Image edge detection social network temporal data
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creator	Pandit, S. Yang Yang Kawadia, V. Sreenivasan, S. Chawla, N. V.
description	The pattern of interactions between individuals in a population contains implicitly within them a remarkable amount of information. This information, if extracted, could be of significant importance in several realms such as containing the spread of disease, understanding information flow in social systems and predicting likely future interactions. A popular method of discovering structure in networks is through community detection which attempts to capture the extent to which that network is different from a random network. However, communities are not very well defined for time-varying networks. In this paper, we introduce the notion of spatio-temporal communities that attempts to capture the structure in spatial connections as well as temporal changes in a network. We illustrate the notion via several examples and list the challenges in effectively discovering spatio-temporal communities. For example, such communities are lost if the temporal interactions are aggregated in a single weighted network since the concurrency information is lost. We present an approach that first extracts concurrency information via node-clustering on each snapshot. Each node is then assigned a vector of community memberships over time, which is then used to group nodes into overlapping communities via recently introduced link clustering techniques. However we measure similarity (of nodes and edges) based on concurrence, i.e. when they existed, if they existed together. We call our approach the co-community algorithm. We validate our approach using several real-world data sets spanning multiple contexts.
doi_str_mv	10.1109/NSW.2011.6004643
format	Conference Proceeding
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V.</au><format>book</format><genre>proceeding</genre><ristype>CONF</ristype><atitle>Detecting communities in time-evolving proximity networks</atitle><btitle>2011 IEEE Network Science Workshop</btitle><stitle>NSW</stitle><date>2011-06</date><risdate>2011</risdate><spage>173</spage><epage>179</epage><pages>173-179</pages><isbn>9781457710490</isbn><isbn>1457710498</isbn><eisbn>1457710501</eisbn><eisbn>9781457710513</eisbn><eisbn>145771051X</eisbn><eisbn>9781457710506</eisbn><abstract>The pattern of interactions between individuals in a population contains implicitly within them a remarkable amount of information. This information, if extracted, could be of significant importance in several realms such as containing the spread of disease, understanding information flow in social systems and predicting likely future interactions. 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subjects	Clustering algorithms Communities community detection Concurrent computing contact graph Data mining Electronic mail Humans Image edge detection social network temporal data
title	Detecting communities in time-evolving proximity networks
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