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Hauptverfasser: Tang, Bohan, Chen, Siheng, Dong, Xiaowen
Format: Preprint
Veröffentlicht: 2022
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Online-Zugang:https://arxiv.org/abs/2211.01717
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author Tang, Bohan
Chen, Siheng
Dong, Xiaowen
author_facet Tang, Bohan
Chen, Siheng
Dong, Xiaowen
contents Hypergraph structure learning, which aims to learn the hypergraph structures from the observed signals to capture the intrinsic high-order relationships among the entities, becomes crucial when a hypergraph topology is not readily available in the datasets. There are two challenges that lie at the heart of this problem: 1) how to handle the huge search space of potential hyperedges, and 2) how to define meaningful criteria to measure the relationship between the signals observed on nodes and the hypergraph structure. In this paper, for the first challenge, we adopt the assumption that the ideal hypergraph structure can be derived from a learnable graph structure that captures the pairwise relations within signals. Further, we propose a hypergraph structure learning framework HGSL with a novel dual smoothness prior that reveals a mapping between the observed node signals and the hypergraph structure, whereby each hyperedge corresponds to a subgraph with both node signal smoothness and edge signal smoothness in the learnable graph structure. Finally, we conduct extensive experiments to evaluate HGSL on both synthetic and real world datasets. Experiments show that HGSL can efficiently infer meaningful hypergraph topologies from observed signals.
format Preprint
id arxiv_https___arxiv_org_abs_2211_01717
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Learning Hypergraphs From Signals With Dual Smoothness Prior
Tang, Bohan
Chen, Siheng
Dong, Xiaowen
Machine Learning
Social and Information Networks
Signal Processing
Hypergraph structure learning, which aims to learn the hypergraph structures from the observed signals to capture the intrinsic high-order relationships among the entities, becomes crucial when a hypergraph topology is not readily available in the datasets. There are two challenges that lie at the heart of this problem: 1) how to handle the huge search space of potential hyperedges, and 2) how to define meaningful criteria to measure the relationship between the signals observed on nodes and the hypergraph structure. In this paper, for the first challenge, we adopt the assumption that the ideal hypergraph structure can be derived from a learnable graph structure that captures the pairwise relations within signals. Further, we propose a hypergraph structure learning framework HGSL with a novel dual smoothness prior that reveals a mapping between the observed node signals and the hypergraph structure, whereby each hyperedge corresponds to a subgraph with both node signal smoothness and edge signal smoothness in the learnable graph structure. Finally, we conduct extensive experiments to evaluate HGSL on both synthetic and real world datasets. Experiments show that HGSL can efficiently infer meaningful hypergraph topologies from observed signals.
title Learning Hypergraphs From Signals With Dual Smoothness Prior
topic Machine Learning
Social and Information Networks
Signal Processing
url https://arxiv.org/abs/2211.01717