Two models of sparse and clustered dynamic networks

Abstract

We present two models of sparse dynamic networks that display transitivity - the tendency for vertices sharing a common neighbour to be neighbours of one another. Our first network is a continuous time Markov chain G=\Gt=(V,Et), t 0\ whose states are graphs with the common vertex set V=\1,…, n\. The transitions are defined as follows. Given t, the vertex pairs \i,j\⊂ V are assigned independent exponential waiting times Aij. At time t+ij Aij the pair \i0,j0\ with Ai0j0=ij Aij toggles its adjacency status. To mimic clustering patterns of sparse real networks we set intensities aij of exponential times Aij to be negatively correlated with the degrees of the common neighbours of vertices i and j in Gt. Another dynamic network is based on a latent Markov chain H=\Ht=(V W, Et), t 0\ whose states are bipartite graphs with the bipartition V W, where W=\1,…,m\ is an auxiliary set of attributes/affiliations. Our second network G'=\G't =(E't,V), t 0\ is the affiliation network defined by H: vertices i1,i2∈ V are adjacent in G't whenever i1 and i2 have a common neighbour in Ht. We analyze geometric properties of both dynamic networks at stationarity and show that networks possess high clustering. They admit tunable degree distribution and clustering coefficients.

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