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Literature DB >> 20007780

Distinguishing influence-based contagion from homophily-driven diffusion in dynamic networks.

Sinan Aral¹, Lev Muchnik, Arun Sundararajan.

Abstract

Node characteristics and behaviors are often correlated with the structure of social networks over time. While evidence of this type of assortative mixing and temporal clustering of behaviors among linked nodes is used to support claims of peer influence and social contagion in networks, homophily may also explain such evidence. Here we develop a dynamic matched sample estimation framework to distinguish influence and homophily effects in dynamic networks, and we apply this framework to a global instant messaging network of 27.4 million users, using data on the day-by-day adoption of a mobile service application and users' longitudinal behavioral, demographic, and geographic data. We find that previous methods overestimate peer influence in product adoption decisions in this network by 300-700%, and that homophily explains >50% of the perceived behavioral contagion. These findings and methods are essential to both our understanding of the mechanisms that drive contagions in networks and our knowledge of how to propagate or combat them in domains as diverse as epidemiology, marketing, development economics, and public health.

Mesh：

Year: 2009 PMID： 20007780 PMCID： PMC2799846 DOI： 10.1073/pnas.0908800106

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

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Distinguishing influence-based contagion from homophily-driven diffusion in dynamic networks.

1. Assortative mixing in networks.

2. Modelling disease outbreaks in realistic urban social networks.

3. Team assembly mechanisms determine collaboration network structure and team performance.

4. Empirical analysis of an evolving social network.

5. Distribution of node characteristics in complex networks.

6. Structure and tie strengths in mobile communication networks.

7. Quantifying social group evolution.

8. The collective dynamics of smoking in a large social network.

9. The spread of obesity in a large social network over 32 years.

10. Social science. Computational social science.

1. Sumter County on the Move! Evaluation of a Walking Group Intervention to Promote Physical Activity Within Existing Social Networks.

2. Social selection and peer influence in an online social network.

3. Structural diversity in social contagion.

Review 4. Using Social Networks to Understand and Overcome Implementation Barriers in the Global HIV Response.

5. Understanding metropolitan patterns of daily encounters.

6. Identifying the roles of race-based choice and chance in high school friendship network formation.

7. A natural experiment of social network formation and dynamics.

8. Complex contagion process in spreading of online innovation.

9. Social science: Poked to vote.

10. Association between social network communities and health behavior: an observational sociocentric network study of latrine ownership in rural India.