Scale-Free Network Topologies with Clustering Similar to Online Social Networks

Вaргa, Имре

doi:10.1007/978-3-319-20591-5_29

Cited by 10 publications

(7 citation statements)

References 12 publications

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“…It would be ideal to also compare the common BA model with the transitivities present in the hierarchical network; however, a number of problems exist for this at present. First, the traditional BA model does not produce the requisite levels of transitivity present in observed social networks (Ravasz & Barab asi, 2003;Varga, 2015). Second, while modified versions of the BA model exist to try and make this property an adjustable parameter (Jin et al, 2001;Varga, 2015), as well as novel procedures to produce scale-free networks with tunable transitivity (Chakrabarti, Heath, & Ramakrishnan, 2017;Herrera & Zufiria, 2011), no method yet exists that accounts for the distribution of connection density in a way that mimics social networks and/or allows for manipulation of that density measure beyond a narrow range.…”

Section: Network Architecture and Communicationmentioning

confidence: 99%

“…First, the traditional BA model does not produce the requisite levels of transitivity present in observed social networks (Ravasz & Barab asi, 2003;Varga, 2015). Second, while modified versions of the BA model exist to try and make this property an adjustable parameter (Jin et al, 2001;Varga, 2015), as well as novel procedures to produce scale-free networks with tunable transitivity (Chakrabarti, Heath, & Ramakrishnan, 2017;Herrera & Zufiria, 2011), no method yet exists that accounts for the distribution of connection density in a way that mimics social networks and/or allows for manipulation of that density measure beyond a narrow range. A key issue is that in large, scale-free human social networks, the local transitivity of an agent is inversely proportional to its number of connections, for example, to its degree (Soffer & Vazquez, 2005).…”

Section: Network Architecture and Communicationmentioning

confidence: 99%

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Social Network Limits Language Complexity

Lou-Magnuson

Onnis

2018

Cognitive Science

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Section: Network Architecture and Communicationmentioning

confidence: 99%

Section: Network Architecture and Communicationmentioning

confidence: 99%

Social Network Limits Language Complexity

Lou-Magnuson

Onnis

2018

Cognitive Science

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“…One particular class of discrete data for which the power law is often suitable is the degree distribution or related characteristics of networks. Examples include networks of links on the World-Wide Web (Barabási and Albert, 1999, Faloutsos et al, 1999, social networks (Lee, 2014, Lee and Oh, 2014, Varga, 2015, coauthorship/collaboration and citation networks (de Solla Price, 1976, Newman, 2001a,b, 2004, Thelwall and Wilson, 2014, Ji and Jin, 2016, Arroyo-Machado et al, 2020, retweet counts Bhamidi et al (2015), Mathews et al (2017). As an example, consider the citation network of a computer science conference, which corresponds to the top-right plots of Figures 1 and 2, and has been analysed by Lee et al (2019).…”

Section: Introductionmentioning

confidence: 99%

From the power law to extreme value mixture distributions

Lee¹,

Eastoe²

2020

Preprint

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The power law is useful in describing count phenomena such as network degrees and word frequencies. With a single parameter, it captures the main feature that the frequencies are linear on the log-log scale. Nevertheless, there have been criticisms of the power law, and various approaches have been proposed to resolve issues such as selecting the required threshold and quantifying the uncertainty around it, and to test hypotheses on whether the data could have come from the power law. As extreme value theory generalises the (continuous) power law, it is natural to consider the former as a solution to these problems around the latter. In this paper, we propose two extreme value mixture distributions, in one of which the power law is incorporated, without the need of pre-specifying the threshold. The proposed distributions are shown to fit the data well, quantify the threshold uncertainty in a natural way, and satisfactorily answer whether the power law is useful enough.

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“…First, the traditional BA model does not produce the requisite levels of transitivity present in observed social networks (Ravasz and Barabási, 2003;Varga, 2015). Second, while M a n u s c r i p t modified versions of the BA model exist to try and make this property an adjustable parameter (Jin et al, 2001;Varga, 2015), as well as novel procedures to produce scale-free networks with tunable transitivity (Chakrabarti et al, 2017;Herrera and Zufiria, 2011), no method yet exists that accounts for the distribution of connection density in a way that mimics social networks, and/or allows for manipulation of that density measure beyond a narrow range. A key issue is that in large, scale-free human social networks, the local transitivity of an agent is inversely proportional to its number of connections, i.e.…”

Section: Network Architecture and Communicationmentioning

confidence: 99%

Social Network Limits Language Complexity

Lou-Magnuson¹,

Onnis²

2017

Preprint

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Natural languages vary widely in the degree to which they make use of nested compositional structure in their grammars. It has long been noted by linguists that the languages historically spoken in small communities develop much deeper levels of compositional embedding than those spoken by larger groups. Recently this observation has been confirmed by a robust statistical analysis of the World Atlas of Language Structures. In order to examine this connection mechanistically, we propose an agent-based model that accounts for key cultural evolutionary features of language transfer and language change. We identify transitivity as a physical parameter of social networks critical for the evolution of compositional structure, and the hierarchical patterning of scale-free distributions as inhibitory.Natural languages vary widely in grammatical structure, especially in the degree to which they make use of nested composition. A graduated divide in this typological space is the extent to which words themselves make use of compositional patterning. That is, the degree on average to which words possess internal structural hierarchies (morphological composition), beyond their arrangement in the phrasal hierarchy of a sentence (syntactic composition). In some languages, such as Chinese, morphological structure is virtually nonexistent, whereas others, like Lushootseed (an indigenous, Salishan language of North America), have so much morphological structure that entire utterances can be a single, highly complex word. It is not yet understood how such typological patterns emerge historically, and why natural languages vary in this property over time.Computational modeling researchers have proposed both symbolic (Smith et al., 2003) and neural architectures (Batali, 1998) to demonstrate that compositional language structure develops where cultural evolutionary forces are at * Equally contributing authors.

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Scale-Free Network Topologies with Clustering Similar to Online Social Networks

Cited by 10 publications

References 12 publications

Social Network Limits Language Complexity

Social Network Limits Language Complexity

From the power law to extreme value mixture distributions

Social Network Limits Language Complexity

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