English

NestE: Modeling Nested Relational Structures for Knowledge Graph Reasoning

Artificial Intelligence 2023-12-15 v1

Abstract

Reasoning with knowledge graphs (KGs) has primarily focused on triple-shaped facts. Recent advancements have been explored to enhance the semantics of these facts by incorporating more potent representations, such as hyper-relational facts. However, these approaches are limited to \emph{atomic facts}, which describe a single piece of information. This paper extends beyond \emph{atomic facts} and delves into \emph{nested facts}, represented by quoted triples where subjects and objects are triples themselves (e.g., ((\emph{BarackObama}, \emph{holds\_position}, \emph{President}), \emph{succeed\_by}, (\emph{DonaldTrump}, \emph{holds\_position}, \emph{President}))). These nested facts enable the expression of complex semantics like \emph{situations} over time and \emph{logical patterns} over entities and relations. In response, we introduce NestE, a novel KG embedding approach that captures the semantics of both atomic and nested factual knowledge. NestE represents each atomic fact as a 1×31\times3 matrix, and each nested relation is modeled as a 3×33\times3 matrix that rotates the 1×31\times3 atomic fact matrix through matrix multiplication. Each element of the matrix is represented as a complex number in the generalized 4D hypercomplex space, including (spherical) quaternions, hyperbolic quaternions, and split-quaternions. Through thorough analysis, we demonstrate the embedding's efficacy in capturing diverse logical patterns over nested facts, surpassing the confines of first-order logic-like expressions. Our experimental results showcase NestE's significant performance gains over current baselines in triple prediction and conditional link prediction. The code and pre-trained models are open available at https://github.com/xiongbo010/NestE.

Keywords

Cite

@article{arxiv.2312.09219,
  title  = {NestE: Modeling Nested Relational Structures for Knowledge Graph Reasoning},
  author = {Bo Xiong and Mojtaba Nayyeri and Linhao Luo and Zihao Wang and Shirui Pan and Steffen Staab},
  journal= {arXiv preprint arXiv:2312.09219},
  year   = {2023}
}

Comments

The 38th Annual AAAI Conference on Artificial Intelligence (AAAI'24)

R2 v1 2026-06-28T13:51:26.205Z