\begin{document}$ p=0.004$\end{document}, \begin{document}$ p=0.006$\end{document}, \begin{document}$ p=0.008$\end{document} and \begin{document}$ p=0.01$\end{document}. The results show that the node hyper degree distribution of this hyper network model complies to the Poisson distribution \begin{document}$p(k)\approx \dfrac{{{\left\langle \lambda \right\rangle }^{k}}}{k!}{{e}^{-\left\langle \lambda \right\rangle }}$\end{document}, which conforms with the characteristics of random networks and is consistent with the theoretical derivation. Further, in order to more accurately and effectively describe the multiple heterogeneous relationship in real life, in this paper we construct three different kinds of double-layer hyper network models with node hyper degree distribution with bimodal peak characteristics. The three kinds respectively are ER-ER, BA-BA and BA-ER, where ER represents the ER random hyper network, and BA denotes the scale-free hyper network, and the layers are connected by a random manner. The analytical expressions of node hyper degree distribution of the three kinds of double-layer hyper network models are obtained by theoretical analysis, and the average node hyper degrees of the three double-layer hyper networks are closely related to the inter-layer hyper edge probability. As the inter-layer hyper edge probability increases, the average node hyper degree increases. The results of simulation experiments show that the node hyper degree distributions of three kinds of double-layer hyper network models proposed in this paper possess the characteristics of bimodal peaks. The ER random hyper network model and the double-layer hyper network model proposed in this paper provide the theories for further studying the hyper network entropy, hyper network dynamics, hyper network representation learning, hyper network link prediction, and traffic hyper network optimization of such hyper networks in the future, and also it has certain reference significance for studying the evolution of multilayer hyper networks."> - 必威体育下载

Search

Article

x

留言板

姓名
邮箱
手机号码
标题
留言内容
验证码

downloadPDF
Citation:

    Lu Wen, Zhao Hai-Xing, Meng Lei, Hu Feng
    PDF
    HTML
    Get Citation
    Metrics
    • Abstract views:6337
    • PDF Downloads:114
    • Cited By:0
    Publishing process
    • Received Date:04 July 2020
    • Accepted Date:31 August 2020
    • Available Online:22 December 2020
    • Published Online:05 January 2021

      返回文章
      返回
        Baidu
        map