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Autori principali: Honoré, Benjamin, Carballo-Castro, Alba, Qin, Yiming, Frossard, Pascal
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2602.18084
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author Honoré, Benjamin
Carballo-Castro, Alba
Qin, Yiming
Frossard, Pascal
author_facet Honoré, Benjamin
Carballo-Castro, Alba
Qin, Yiming
Frossard, Pascal
contents Equivariance is central to graph generative models, as it ensures the model respects the permutation symmetry of graphs. However, strict equivariance can increase computational cost due to added architectural constraints, and can slow down convergence because the model must be consistent across a large space of possible node permutations. We study this trade-off for graph generative models. Specifically, we start from an equivariant discrete flow-matching model, and relax its equivariance during training via a controllable symmetry modulation scheme based on sinusoidal positional encodings and node permutations. Experiments first show that symmetry-breaking can accelerate early training by providing an easier learning signal, but at the expense of encouraging shortcut solutions that can cause overfitting, where the model repeatedly generates graphs that are duplicates of the training set. On the contrary, properly modulating the symmetry signal can delay overfitting while accelerating convergence, allowing the model to reach stronger performance with $19\%$ of the baseline training epochs.
format Preprint
id arxiv_https___arxiv_org_abs_2602_18084
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Balancing Symmetry and Efficiency in Graph Flow Matching
Honoré, Benjamin
Carballo-Castro, Alba
Qin, Yiming
Frossard, Pascal
Machine Learning
Equivariance is central to graph generative models, as it ensures the model respects the permutation symmetry of graphs. However, strict equivariance can increase computational cost due to added architectural constraints, and can slow down convergence because the model must be consistent across a large space of possible node permutations. We study this trade-off for graph generative models. Specifically, we start from an equivariant discrete flow-matching model, and relax its equivariance during training via a controllable symmetry modulation scheme based on sinusoidal positional encodings and node permutations. Experiments first show that symmetry-breaking can accelerate early training by providing an easier learning signal, but at the expense of encouraging shortcut solutions that can cause overfitting, where the model repeatedly generates graphs that are duplicates of the training set. On the contrary, properly modulating the symmetry signal can delay overfitting while accelerating convergence, allowing the model to reach stronger performance with $19\%$ of the baseline training epochs.
title Balancing Symmetry and Efficiency in Graph Flow Matching
topic Machine Learning
url https://arxiv.org/abs/2602.18084