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Hauptverfasser: Mule, Emanuele, Fiorini, Stefano, Purificato, Antonio, Siciliano, Federico, Coniglio, Stefano, Silvestri, Fabrizio
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2510.04727
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author Mule, Emanuele
Fiorini, Stefano
Purificato, Antonio
Siciliano, Federico
Coniglio, Stefano
Silvestri, Fabrizio
author_facet Mule, Emanuele
Fiorini, Stefano
Purificato, Antonio
Siciliano, Federico
Coniglio, Stefano
Silvestri, Fabrizio
contents Hypergraphs provide a natural way to represent higher-order interactions among multiple entities. While undirected hypergraphs have been extensively studied, the case of directed hypergraphs, which can model oriented group interactions, remains largely under-explored despite its relevance for many applications. Recent approaches in this direction often exhibit an implicit bias toward homophily, which limits their effectiveness in heterophilic settings. Rooted in the algebraic topology notion of Cellular Sheaves, Sheaf Neural Networks (SNNs) were introduced as an effective solution to circumvent such a drawback. While a generalization to hypergraphs is known, it is only suitable for undirected hypergraphs, failing to tackle the directed case. In this work, we introduce Directional Sheaf Hypergraph Networks (DSHN), a framework integrating sheaf theory with a principled treatment of asymmetric relations within a hypergraph. From it, we construct the Directed Sheaf Hypergraph Laplacian, a complex-valued operator by which we unify and generalize many existing Laplacian matrices proposed in the graph- and hypergraph-learning literature. Across 7 real-world datasets and against 13 baselines, DSHN achieves relative accuracy gains from 2% up to 20%, showing how a principled treatment of directionality in hypergraphs, combined with the expressive power of sheaves, can substantially improve performance.
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id arxiv_https___arxiv_org_abs_2510_04727
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Directional Sheaf Hypergraph Networks: Unifying Learning on Directed and Undirected Hypergraphs
Mule, Emanuele
Fiorini, Stefano
Purificato, Antonio
Siciliano, Federico
Coniglio, Stefano
Silvestri, Fabrizio
Machine Learning
Hypergraphs provide a natural way to represent higher-order interactions among multiple entities. While undirected hypergraphs have been extensively studied, the case of directed hypergraphs, which can model oriented group interactions, remains largely under-explored despite its relevance for many applications. Recent approaches in this direction often exhibit an implicit bias toward homophily, which limits their effectiveness in heterophilic settings. Rooted in the algebraic topology notion of Cellular Sheaves, Sheaf Neural Networks (SNNs) were introduced as an effective solution to circumvent such a drawback. While a generalization to hypergraphs is known, it is only suitable for undirected hypergraphs, failing to tackle the directed case. In this work, we introduce Directional Sheaf Hypergraph Networks (DSHN), a framework integrating sheaf theory with a principled treatment of asymmetric relations within a hypergraph. From it, we construct the Directed Sheaf Hypergraph Laplacian, a complex-valued operator by which we unify and generalize many existing Laplacian matrices proposed in the graph- and hypergraph-learning literature. Across 7 real-world datasets and against 13 baselines, DSHN achieves relative accuracy gains from 2% up to 20%, showing how a principled treatment of directionality in hypergraphs, combined with the expressive power of sheaves, can substantially improve performance.
title Directional Sheaf Hypergraph Networks: Unifying Learning on Directed and Undirected Hypergraphs
topic Machine Learning
url https://arxiv.org/abs/2510.04727