Abstract
Measuring and optimizing the influence of nodes in big-data online social networks are important for many practical applications, such as the viral marketing and the adoption of new products. As the viral spreading on a social network is a global process, it is commonly believed that measuring the influence of nodes inevitably requires the knowledge of the entire network. Using percolation theory, we show that the spreading process displays a nucleation behavior: Once a piece of information spreads from the seeds to more than a small characteristic number of nodes, it reaches a point of no return and will quickly reach the percolation cluster, regardless of the entire network structure; otherwise the spreading will be contained locally. Thus, we find that, without the knowledge of the entire network, any node’s global influence can be accurately measured using this characteristic number, which is independent of the network size. This motivates an efficient algorithm with constant time complexity on the long-standing problem of best seed spreaders selection, with performance remarkably close to the true optimum.
| Original language | English |
|---|---|
| Pages (from-to) | 7468-7472 |
| Number of pages | 5 |
| Journal | Proceedings of the National Academy of Sciences of the United States of America |
| Volume | 115 |
| Issue number | 29 |
| DOIs | |
| State | Published - 17 Jul 2018 |
Bibliographical note
Funding Information:ACKNOWLEDGMENTS. Y.H., S.J., and L.F. are supported by The National Nature Science Foundation of China Grants 61773412, U1711265, 71731002; Guangzhou Science and Technology Project Grant 201804010473; and Three Big Constructions Supercomputing Application Cultivation Projects sponsored by National Supercomputer Center in Guangzhou. Y.J. is supported by Chinese Academy of Sciences Hundred-Talent Program. S.H. acknowledges the Israel Science Foundation, the Israel Ministry of Science and Technology (MOST) with the Italy Ministry of Foreign Affairs, MOST with the Japan Science and Technology Agency, the Bar-Ilan University Center for Research in Applied Cryptography and Cyber Security, and Defense Threat Reduction Agency Grants HDTRA-1-10-1-0014 for financial support. The Boston University Center for Polymer Studies is supported by National Science Foundation Grants PHY-1505000, CMMI-1125290, and CHE-1213217, and by Defense Threat Reduction Agency Grant HDTRA1-14-1-0017.
Funding Information:
Y.H., S.J., and L.F. are supported by The National Nature Science Foundation of China Grants 61773412, U1711265, 71731002; Guangzhou Science and Technology Project Grant 201804010473; and Three Big Constructions Supercomputing Application Cultivation Projects sponsored by National Supercomputer Center in Guangzhou. Y.J. is supported by Chinese Academy of Sciences Hundred-Talent Program. S.H. acknowledges the Israel Science Foundation, the Israel Ministry of Science and Technology (MOST) with the Italy Ministry of Foreign Affairs, MOST with the Japan Science and Technology Agency, the Bar-Ilan University Center for Research in Applied Cryptography and Cyber Security, and Defense Threat Reduction Agency Grants HDTRA-1-10-1-0014 for financial support. The Boston University Center for Polymer Studies is supported by National Science Foundation Grants PHY-1505000, CMMI-1125290, and CHE-1213217, and by Defense Threat Reduction Agency Grant HDTRA1-14-1-0017.
Publisher Copyright:
© 2018 National Academy of Sciences. All Rights Reserved.
Keywords
- Complex network
- Influence
- Percolation
- Social media
- Viral marketing