T-GAE: A Timespan-aware Graph Attention-based Embedding Model for Temporal Knowledge Graph Completion

Temporal knowledge graphs (TKGs) often suffer from incompleteness, leading to an important research issue: Temporal Knowledge Graph Completion (TKGC). Knowledge Graph Embedding (KGE) methods have proven to be effective in solving this issue. However, most of them handle triples independently and do...

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Vydáno v:Information sciences Ročník 642; s. 119225
Hlavní autoři: Hou, Xiangning, Ma, Ruizhe, Yan, Li, Ma, Zongmin
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier Inc 01.09.2023
Témata:
Encoder-Decoder architecture
Graph Attention Network
Long Short-Term Memory Network
Temporal Knowledge Graph
Temporal Knowledge Graph Completion
Temporal Knowledge Graph
Encoder-Decoder architecture
Long Short-Term Memory Network
Graph Attention Network
Temporal Knowledge Graph Completion
ISSN:0020-0255, 1872-6291
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Shrnutí:Temporal knowledge graphs (TKGs) often suffer from incompleteness, leading to an important research issue: Temporal Knowledge Graph Completion (TKGC). Knowledge Graph Embedding (KGE) methods have proven to be effective in solving this issue. However, most of them handle triples independently and do not capture complex information embedded in the neighborhood topology of central entities. To this end, we propose a Timespan-awareGraphAttention-basedEmbedding Model named T-GAE to tackle the TKGC task. To the best of our knowledge, T-GAE is the first KGE model in which Graph-Attention-Networks (GATs) and Long Short-Term Memory (LSTM) Networks are simultaneously applied to the TKGC task. In essence, our model is an Encoder-Decoder architecture, where the encoder consists of an LSTM network and a GAT network. Firstly, we employ LSTM layers to learn new time-aware relational embeddings to incorporate time information. Then, we utilize these time-aware relational embedding and GATs considered as neighborhood aggregators to learn the entity and relational features of the central entity neighborhoods. Thus, T-GAE can capture the interaction features between multi-relational facts and the abundant temporal information in TKGs. As for the decoder, we choose the ConvKB model, which is essentially a scoring function. Our experiments demonstrate that T-GAE significantly outperforms most of the existing baseline methods for TKGC in terms of MRR and Hit@1/3/10.
ISSN:0020-0255
1872-6291
DOI:10.1016/j.ins.2023.119225