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Social Network Analysis and Mining
Erschienen in: Social Network Analysis and Mining 1/2014

01.12.2014 | Original Article

Coloring large complex networks

verfasst von: Ryan A. Rossi, Nesreen K. Ahmed

Erschienen in: Social Network Analysis and Mining | Ausgabe 1/2014

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Abstract

Given a large social or information network, how can we partition the vertices into sets (i.e., colors) such that no two vertices linked by an edge are in the same set while minimizing the number of sets used. Despite the obvious practical importance of graph coloring, existing works have not systematically investigated or designed methods for large complex networks. In this work, we develop a unified framework for coloring large complex networks that consists of two main coloring variants that effectively balances the tradeoff between accuracy and efficiency. Using this framework as a fundamental basis, we propose coloring methods designed for the scale and structure of complex networks. In particular, the methods leverage triangles, triangle-cores, and other egonet properties and their combinations. We systematically compare the proposed methods across a wide range of networks (e.g., social, web, biological networks) and find a significant improvement over previous approaches in nearly all cases. Additionally, the solutions obtained are nearly optimal and sometimes provably optimal for certain classes of graphs (e.g., collaboration networks). We also propose a parallel algorithm for the problem of coloring neighborhood subgraphs and make several key observations. Overall, the coloring methods are shown to be (1) accurate with solutions close to optimal, (2) fast and scalable for large networks, and (3) flexible for use in a variety of applications.
Vorheriger Artikel Exploration of methodologies to improve job recommender systems on social networks
Nächster Artikel In users we trust: towards social user interactions based Trust Assertions for the Social Semantic Web

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Fußnoten
1
In the spirit of reproducible research, the large 100+ collection of benchmark graphs used in this article are available for download at http://​www.​networkrepositor​y.​com.
 
2
The local vertex upper bound for \(u.\) denoted by \(B(u)\) is typically the maximum k-core number of the vertex \(u\) denoted by \({K}(u)\).
 
3
Also referred to as degeneracy (Erdős and Hajnal 1966), maximum k-core number (Batagelj and Zaversnik 2003), linkage (Matula and Beck 1983), among others.
 
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Metadaten
Titel
Coloring large complex networks
verfasst von
Ryan A. Rossi
Nesreen K. Ahmed
Publikationsdatum
01.12.2014
Verlag
Springer Vienna
Erschienen in
Social Network Analysis and Mining / Ausgabe 1/2014
Print ISSN: 1869-5450
Elektronische ISSN: 1869-5469
DOI
https://doi.org/10.1007/s13278-014-0228-y

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