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Main Authors: Labarthe, Aldric, Bouffanais, Roland, Randon-Furling, Julien
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.22806
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author Labarthe, Aldric
Bouffanais, Roland
Randon-Furling, Julien
author_facet Labarthe, Aldric
Bouffanais, Roland
Randon-Furling, Julien
contents The standard approach to representation learning on attributed graphs -- i.e., simultaneously reconstructing node attributes and graph structure -- is geometrically flawed, as it merges two potentially incompatible metric spaces. This forces a destructive alignment that erodes information about the graph's underlying generative process. To recover this lost signal, we introduce a custom variational autoencoder that separates manifold learning from structural alignment. By quantifying the metric distortion needed to map the attribute manifold onto the graph's Heat Kernel, we transform geometric conflict into an interpretable structural descriptor. Experiments show our method uncovers connectivity patterns and anomalies undetectable by conventional approaches, proving both their theoretical inadequacy and practical limitations.
format Preprint
id arxiv_https___arxiv_org_abs_2601_22806
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Aligning the Unseen in Attributed Graphs: Interplay between Graph Geometry and Node Attributes Manifold
Labarthe, Aldric
Bouffanais, Roland
Randon-Furling, Julien
Artificial Intelligence
Differential Geometry
The standard approach to representation learning on attributed graphs -- i.e., simultaneously reconstructing node attributes and graph structure -- is geometrically flawed, as it merges two potentially incompatible metric spaces. This forces a destructive alignment that erodes information about the graph's underlying generative process. To recover this lost signal, we introduce a custom variational autoencoder that separates manifold learning from structural alignment. By quantifying the metric distortion needed to map the attribute manifold onto the graph's Heat Kernel, we transform geometric conflict into an interpretable structural descriptor. Experiments show our method uncovers connectivity patterns and anomalies undetectable by conventional approaches, proving both their theoretical inadequacy and practical limitations.
title Aligning the Unseen in Attributed Graphs: Interplay between Graph Geometry and Node Attributes Manifold
topic Artificial Intelligence
Differential Geometry
url https://arxiv.org/abs/2601.22806