Litcius/Paper detail

GloDyNE: Global Topology Preserving Dynamic Network Embedding

Chengbin Hou, Han Zhang, Shan He, Ke Tang

2020IEEE Transactions on Knowledge and Data Engineering45 citationsDOIOpen Access PDF

Abstract

Learning low-dimensional topological representation of a network in dynamic environments is attracting much attention due to the time-evolving nature of many real-world networks. The main and common objective of Dynamic Network Embedding (DNE) is to efficiently update node embeddings while preserving network topology at each time step. The idea of most existing DNE methods is to capture the topological changes at or around the most affected nodes (instead of all nodes) and accordingly update node embeddings. Unfortunately, this kind of approximation, although can improve efficiency, cannot effectively preserve the global topology of a dynamic network at each time step, due to not considering the inactive sub-networks that receive accumulated topological changes propagated via the high-order proximity. To tackle this challenge, we propose a novel node selecting strategy to diversely select the representative nodes over a network, which is coordinated with a new incremental learning paradigm of Skip-Gram based embedding approach. The extensive experiments show GloDyNE, with a small fraction of nodes being selected, can already achieve the superior or comparable performance w.r.t. the state-of-the-art DNE methods in three typical downstream tasks. Particularly, GloDyNE significantly outperforms other methods in the graph reconstruction task, which demonstrates its ability of global topology preservation.

Topics & Concepts

Computer scienceEmbeddingNetwork topologyTopology (electrical circuits)Distributed computingTheoretical computer scienceComputer networkArtificial intelligenceMathematicsCombinatoricsAdvanced Graph Neural NetworksComplex Network Analysis TechniquesTopological and Geometric Data Analysis
GloDyNE: Global Topology Preserving Dynamic Network Embedding | Litcius