[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.9708/jksci.2019.24.07.061

The Classification of random graph models using graph centralities

Cho, Tae-Soo (Dept. of Computer Engineering, Kyung Hee University)
Han, Chi-Geun (Dept. of Computer Engineering, Kyung Hee University)
Lee, Sang-Hoon (Dept. of Computer Engineering, Kyung Hee University)

Publication Information

Journal of the Korea Society of Computer and Information / v.24, no.7, 2019 , pp. 61-69 More about this Journal

Abstract

In this paper, a classification method of random graph models is proposed and it is based on centralities of the random graphs. Similarity between two random graphs is measured for the classification of random graph models. The similarity between two random graph models $G^{R_1}$ and $G^{R_2}$ is defined by the distance of $G^{R_1}$ and $G^{R_2}$ , where $G^{R_2}$ is a set of random graph $G^{R_2}=\{G_1^{R_2},...,G_p^{R_2}\}$ that have the same number of nodes and edges as random graph $G^{R_1}$ . The distance( $G^{R_1},G^{R_2}$ ) is obtained by comparing centralities of $G^{R_1}$ and $G^{R_2}$ . Through the computational experiments, we show that it is possible to compare random graph models regardless of the number of vertices or edges of the random graphs. Also, it is possible to identify and classify the properties of the random graph models by measuring and comparing similarities between random graph models.

Keywords

graph; centrality; random graph; similarity measure; random graph model classification;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	West, Douglas Brent. Introduction to graph theory. Vol. 2. Upper Saddle River: Prentice hall, 2001.
2	Bollobas, Bela. "Random graphs." Modern graph theory. Springer, New York, NY, 1998. 215-252.
3	Sanfeliu, Alberto, and King-Sun Fu. "A distance measure between attributed relational graphs for pattern recognition." IEEE transactions on systems, man, and cybernetics 3 (1983): 353-362. DOI
4	Akoglu, Leman, Hanghang Tong, and Danai Koutra. "Graph based anomaly detection and description: a survey." Data mining and knowledge discovery 29.3 (2015): 626-688. DOI
5	Pignolet, Yvonne Anne, et al. "The many faces of graph dynamics." Journal of Statistical Mechanics: Theory and Experiment 2017.6 (2017): 063401. DOI
6	Tae-Soo Cho, Chi-Geun Han, and Sang-Hoon Lee. "Measurement of graphs similarity using graph centralities." JKCSI 23.12 (2018): 57-64.
7	Freeman, Linton C. "A set of measures of centrality based on betweenness." Sociometry (1977): 35-41.
8	Okamoto, Kazuya, Wei Chen, and Xiang-Yang Li. "Ranking of closeness centrality for large-scale social networks." International Workshop on Frontiers in Algorithmics. Springer, Berlin, Heidelberg, 2008.
9	Freeman, Linton C. "Centrality in social networks conceptual clarification." Social networks 1.3 (1978): 215-239. DOI
10	Bonacich, Phillip. "Some unique properties of eigenvector centrality." Social networks 29.4 (2007): 555-564. DOI
11	Gilbert, Edgar N. "Random graphs." The Annals of Mathematical Statistics 30.4 (1959): 1141-1144. DOI
12	Barabasi, Albert-Laszlo, and Reka Albert. "Emergence of scaling in random networks." science 286.5439 (1999): 509-512. DOI
13	ERDdS, P., and A. R&WI. "On random graphs I." Publ. Math. Debrecen 6 (1959): 290-297.
14	Watts, Duncan J., and Steven H. Strogatz. "Collective dynamics of 'small-world'networks." nature 393.6684 (1998): 440. DOI
15	Bianconi, Ginestra, and A-L. Barabasi. "Competition and multiscaling in evolving networks." EPL (Europhysics Letters) 54.4 (2001): 436. DOI
16	Penrose, Mathew D. "On k-connectivity for a geometric random graph." Random Structures & Algorithms 15.2 (1999): 145-164 DOI