Abstract
Complex networks appear naturally in many real-world situations. A power law is generally a good fit for their degree distribution. The popular Barabasi-Albert model (BA) combines growth and preferential attachment to model the emergence of the power law. One builds a network by adding new nodes that preferentially link to high-degree nodes in the network. One can also exploit random walks. In this case, the network growth is determined by choosing parent vertices by sequential random walks. The BA model’s main drawback is that the sample networks’ clustering coefficient is low, while typical real-world networks exhibit a high clustering coefficient. Indeed, nodes tend to form highly connected groups in real-world networks, particularly social networks. In this paper, we introduce a Biased Random Walk model with two parameters allowing us to tune the degree distribution exponent and the clustering coefficient of the sample networks. This efficient algorithm relies on local information to generate more realistic networks reproducing known real-world network properties.
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Vashishtha, R., Singh, A., Cherifi, H. (2023). A Biased Random Walk Scale-Free Network Growth Model with Tunable Clustering. In: Cherifi, H., Mantegna, R.N., Rocha, L.M., Cherifi, C., Micciche, S. (eds) Complex Networks and Their Applications XI. COMPLEX NETWORKS 2016 2022. Studies in Computational Intelligence, vol 1078. Springer, Cham. https://doi.org/10.1007/978-3-031-21131-7_10
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