Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Schwarz, Tassilo, Dieball, Cai, Kogler, Constantin, Lambiotte, Renaud, Doucet, Arnaud, Godec, Aljaž, Deligiannidis, George
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2510.08535
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866913170255249408
author Schwarz, Tassilo
Dieball, Cai
Kogler, Constantin
Lambiotte, Renaud
Doucet, Arnaud
Godec, Aljaž
Deligiannidis, George
author_facet Schwarz, Tassilo
Dieball, Cai
Kogler, Constantin
Lambiotte, Renaud
Doucet, Arnaud
Godec, Aljaž
Deligiannidis, George
contents Diffusion models are central to generative modeling and have been adapted to graphs by diffusing adjacency matrix representations. The challenge of having up to $n!$ such representations for graphs with $n$ nodes is only partially mitigated by using permutation-equivariant learning architectures. Despite their computational efficiency, existing graph diffusion models struggle to distinguish certain graph families and their spectra, unless graph data are augmented with ad hoc features. This shortcoming stems from enforcing the inductive bias within the learning architecture. In this work, we leverage random matrix theory to analytically extract the spectral properties of the diffusion process, allowing us to push most of the inductive bias from the architecture into the dynamics. Building on this, we introduce the Dyson Diffusion Model, which employs Dyson's Brownian motion to capture the spectral dynamics of an Ornstein-Uhlenbeck process on the adjacency matrix. Furthermore, conditioned on the spectral dynamics, we formulate a Lie group diffusion, appropriately modeling the remaining degrees of freedom. Strikingly, the resulting learning problem becomes permutation invariant at the Lie algebra level. We demonstrate that the Dyson Diffusion Model learns graph spectra accurately and outperforms existing graph diffusion models.
format Preprint
id arxiv_https___arxiv_org_abs_2510_08535
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Permutation-Invariant Spectral Learning via Dyson Diffusion
Schwarz, Tassilo
Dieball, Cai
Kogler, Constantin
Lambiotte, Renaud
Doucet, Arnaud
Godec, Aljaž
Deligiannidis, George
Machine Learning
Probability
Diffusion models are central to generative modeling and have been adapted to graphs by diffusing adjacency matrix representations. The challenge of having up to $n!$ such representations for graphs with $n$ nodes is only partially mitigated by using permutation-equivariant learning architectures. Despite their computational efficiency, existing graph diffusion models struggle to distinguish certain graph families and their spectra, unless graph data are augmented with ad hoc features. This shortcoming stems from enforcing the inductive bias within the learning architecture. In this work, we leverage random matrix theory to analytically extract the spectral properties of the diffusion process, allowing us to push most of the inductive bias from the architecture into the dynamics. Building on this, we introduce the Dyson Diffusion Model, which employs Dyson's Brownian motion to capture the spectral dynamics of an Ornstein-Uhlenbeck process on the adjacency matrix. Furthermore, conditioned on the spectral dynamics, we formulate a Lie group diffusion, appropriately modeling the remaining degrees of freedom. Strikingly, the resulting learning problem becomes permutation invariant at the Lie algebra level. We demonstrate that the Dyson Diffusion Model learns graph spectra accurately and outperforms existing graph diffusion models.
title Permutation-Invariant Spectral Learning via Dyson Diffusion
topic Machine Learning
Probability
url https://arxiv.org/abs/2510.08535