Bounds and algorithms for graph trusses
DOI:
https://doi.org/10.7155/jgaa.00527Keywords:
Graph algorithms , Truss , Dense cores , Cohesive subnetworkAbstract
The $k$-truss, introduced by Cohen (2005), is a graph where every edge is incident to at least $k$ triangles. This is a relaxation of the clique. It has proved to be a useful tool in identifying cohesive subnetworks in a variety of real-world graphs. Despite its simplicity and its utility, the combinatorial and algorithmic aspects of trusses have not been thoroughly explored. We provide nearly-tight bounds on the edge counts of $k$-trusses. We also give two improved algorithms for finding trusses in large-scale graphs. First, we present a simplified and faster algorithm, based on approach discussed in Wang & Cheng (2012). Second, we present a theoretical algorithm based on fast matrix multiplication; this converts a triangle-generation algorithm of Björklund et al. (2014) into a dynamic data structure.Downloads
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Published
2020-03-01
How to Cite
Burkhardt, P., Faber, V., & Harris, D. (2020). Bounds and algorithms for graph trusses. Journal of Graph Algorithms and Applications, 24(3), 191–214. https://doi.org/10.7155/jgaa.00527
License
Copyright (c) 2020 Paul Burkhardt, Vance Faber, David Harris
This work is licensed under a Creative Commons Attribution 4.0 International License.
