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Efficient Algorithms for Densest Subgraph Discovery on Large Directed Graphs

Chenhao Ma, Yixiang Fang, Reynold Cheng, Laks V. S. Lakshmanan, Wenjie Zhang, Xuemin Lin

202064 citationsDOI

Abstract

Given a directed graph G, the directed densest subgraph (DDS) problem refers to the finding of a subgraph from G, whose density is the highest among all the subgraphs of G. The DDS problem is fundamental to a wide range of applications, such as fraud detection, community mining, and graph compression. However, existing DDS solutions suffer from efficiency and scalability problems: on a three-thousand-edge graph, it takes three days for one of the best exact algorithms to complete. In this paper, we develop an efficient and scalable DDS solution. We introduce the notion of [x, y]-core, which is a dense subgraph for G, and show that the densest subgraph can be accurately located through the [x, y]-core with theoretical guarantees. Based on the [x, y]-core, we develop exact and approximation algorithms. We have performed an extensive evaluation of our approaches on eight real large datasets. The results show that our proposed solutions are up to six orders of magnitude faster than the state-of-the-art.

Topics & Concepts

ScalabilityComputer scienceInduced subgraph isomorphism problemAlgorithmEnhanced Data Rates for GSM EvolutionCore (optical fiber)Subgraph isomorphism problemGraphApproximation algorithmEfficient algorithmTheoretical computer scienceLine graphArtificial intelligenceDatabaseVoltage graphTelecommunicationsAdvanced Graph Neural NetworksGraph Theory and AlgorithmsComplex Network Analysis Techniques
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