Mining Dense Subgraphs with Similar Edges

Publication date

2021-02-25

Authors

Rozenshtein, Polina
Preti, Giulia
Gionis, Aristides
Velegrakis, YannisORCID 0000-0001-6332-0296ISNI 0000000125737584

Editors

Hutter, Frank
Kersting, Kristian
Lijffijt, Jefrey
Valera, Isabel

Advisors

Supervisors

Document Type

Part of book
Open Access logo

License

taverne

Abstract

When searching for interesting structures in graphs, it is often important to take into account not only the graph connectivity, but also the metadata available, such as node and edge labels, or temporal information. In this paper we are interested in settings where such metadata is used to define a similarity between edges. We consider the problem of finding subgraphs that are dense and whose edges are similar to each other with respect to a given similarity function. Depending on the application, this function can be, for example, the Jaccard similarity between the edge label sets, or the temporal correlation of the edge occurrences in a temporal graph. We formulate a Lagrangian relaxation-based optimization problem to search for dense subgraphs with high pairwise edge similarity. We design a novel algorithm to solve the problem through parametric min-cut [15, 17], and provide an efficient search scheme to iterate through the values of the Lagrangian multipliers. Our study is complemented by an evaluation on real-world datasets, which demonstrates the usefulness and efficiency of the proposed approach.

Keywords

Taverne, Theoretical Computer Science, General Computer Science

Citation

Rozenshtein, P, Preti, G, Gionis, A & Velegrakis, Y 2021, Mining Dense Subgraphs with Similar Edges. in F Hutter, K Kersting, J Lijffijt & I Valera (eds), Machine Learning and Knowledge Discovery in Databases : European Conference, ECML PKDD 2020, Ghent, Belgium, September 14–18, 2020, Proceedings, Part III. 1 edn, Lecture Notes in Computer Science , vol. 12459 , Springer, Cham, pp. 20-36, European Conference on Machine Learning and Knowledge Discovery in Databases, ECML PKDD 2020, Virtual, Online, 14/09/20. https://doi.org/10.1007/978-3-030-67664-3_2, conference