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Autori principali: Fiorini, Stefano, Bovolenta, Giulia M., Coniglio, Stefano, Ciavotta, Michele, Morerio, Pietro, Parrinello, Michele, Del Bue, Alessio
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.06969
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author Fiorini, Stefano
Bovolenta, Giulia M.
Coniglio, Stefano
Ciavotta, Michele
Morerio, Pietro
Parrinello, Michele
Del Bue, Alessio
author_facet Fiorini, Stefano
Bovolenta, Giulia M.
Coniglio, Stefano
Ciavotta, Michele
Morerio, Pietro
Parrinello, Michele
Del Bue, Alessio
contents Graphs and hypergraphs provide powerful abstractions for modeling interactions among a set of entities of interest and have been attracting a growing interest in the literature thanks to many successful applications in several fields. In particular, they are rapidly expanding in domains such as chemistry and biology, especially in the areas of drug discovery and molecule generation. One of the areas witnessing the fasted growth is the chemical reactions field, where chemical reactions can be naturally encoded as directed hyperedges of a hypergraph. In this paper, we address the chemical reaction classification problem by introducing the notation of a Directed Line Graph (DGL) associated with a given directed hypergraph. On top of it, we build the Directed Line Graph Network (DLGNet), the first spectral-based Graph Neural Network (GNN) expressly designed to operate on a hypergraph via its DLG transformation. The foundation of DLGNet is a novel Hermitian matrix, the Directed Line Graph Laplacian, which compactly encodes the directionality of the interactions taking place within the directed hyperedges of the hypergraph thanks to the DLG representation. The Directed Line Graph Laplacian enjoys many desirable properties, including admitting an eigenvalue decomposition and being positive semidefinite, which make it well-suited for its adoption within a spectral-based GNN. Through extensive experiments on chemical reaction datasets, we show that DGLNet significantly outperforms the existing approaches, achieving on a collection of real-world datasets an average relative-percentage-difference improvement of 33.01%, with a maximum improvement of 37.71%.
format Preprint
id arxiv_https___arxiv_org_abs_2410_06969
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle DLGNet: Hyperedge Classification through Directed Line Graphs for Chemical Reactions
Fiorini, Stefano
Bovolenta, Giulia M.
Coniglio, Stefano
Ciavotta, Michele
Morerio, Pietro
Parrinello, Michele
Del Bue, Alessio
Machine Learning
Artificial Intelligence
Graphs and hypergraphs provide powerful abstractions for modeling interactions among a set of entities of interest and have been attracting a growing interest in the literature thanks to many successful applications in several fields. In particular, they are rapidly expanding in domains such as chemistry and biology, especially in the areas of drug discovery and molecule generation. One of the areas witnessing the fasted growth is the chemical reactions field, where chemical reactions can be naturally encoded as directed hyperedges of a hypergraph. In this paper, we address the chemical reaction classification problem by introducing the notation of a Directed Line Graph (DGL) associated with a given directed hypergraph. On top of it, we build the Directed Line Graph Network (DLGNet), the first spectral-based Graph Neural Network (GNN) expressly designed to operate on a hypergraph via its DLG transformation. The foundation of DLGNet is a novel Hermitian matrix, the Directed Line Graph Laplacian, which compactly encodes the directionality of the interactions taking place within the directed hyperedges of the hypergraph thanks to the DLG representation. The Directed Line Graph Laplacian enjoys many desirable properties, including admitting an eigenvalue decomposition and being positive semidefinite, which make it well-suited for its adoption within a spectral-based GNN. Through extensive experiments on chemical reaction datasets, we show that DGLNet significantly outperforms the existing approaches, achieving on a collection of real-world datasets an average relative-percentage-difference improvement of 33.01%, with a maximum improvement of 37.71%.
title DLGNet: Hyperedge Classification through Directed Line Graphs for Chemical Reactions
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2410.06969