Graphlets over Time: A New Lens for Temporal Network Analysis
Graphs are widely used for modeling various types of interactions, such as email
communications and online discussions. Many of such real-world graphs are temporal, and
specifically, they grow over time with new nodes and edges. Counting the instances of each
graphlet (ie, an induced subgraph isomorphism class) has been successful in characterizing
local structures of graphs, with many applications. While graphlets have been extended for
temporal graphs, the extensions are designed for examining temporally-local subgraphs …
communications and online discussions. Many of such real-world graphs are temporal, and
specifically, they grow over time with new nodes and edges. Counting the instances of each
graphlet (ie, an induced subgraph isomorphism class) has been successful in characterizing
local structures of graphs, with many applications. While graphlets have been extended for
temporal graphs, the extensions are designed for examining temporally-local subgraphs …
Graphs are widely used for modeling various types of interactions, such as email communications and online discussions. Many of such real-world graphs are temporal, and specifically, they grow over time with new nodes and edges. Counting the instances of each graphlet (i.e., an induced subgraph isomorphism class) has been successful in characterizing local structures of graphs, with many applications. While graphlets have been extended for temporal graphs, the extensions are designed for examining temporally-local subgraphs composed of edges with close arrival times, instead of long-term changes in local structures. In this paper, as a new lens for temporal graph analysis, we study the evolution of distributions of graphlet instances over time in real-world graphs at three different levels (graphs, nodes, and edges). At the graph level, we first discover that the evolution patterns are significantly different from those in random graphs. Then, we suggest a graphlet transition graph for measuring the similarity of the evolution patterns of graphs, and we find out a surprising similarity between the graphs from the same domain. At the node and edge levels, we demonstrate that the local structures around nodes and edges in their early stage provide a strong signal regarding their future importance. In particular, we significantly improve the predictability of the future importance of nodes and edges using the counts of the roles (a.k.a., orbits) that they take within graphlets.
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