Any2Graph: Deep End-To-End Supervised Graph Prediction With An Optimal Transport Loss

Paul Krzakala; Junjie Yang; Rémi Flamary; Florence d'Alché-Buc; Charlotte Laclau; Matthieu Labeau

Any2Graph: Deep End-To-End Supervised Graph Prediction With An Optimal Transport Loss

Telecom Paris

Résultats de recherche: Contribution à un journal › Article de conférence › Revue par des pairs

Résumé

We propose Any2Graph, a generic framework for end-to-end Supervised Graph Prediction (SGP) i.e. a deep learning model that predicts an entire graph for any kind of input. The framework is built on a novel Optimal Transport loss, the Partially-Masked Fused Gromov-Wasserstein, that exhibits all necessary properties (permutation invariance, differentiability) and is designed to handle any-sized graphs. Numerical experiments showcase the versatility of the approach that outperforms existing competitors on a novel challenging synthetic dataset and a variety of real-world tasks such as map construction from satellite image (Sat2Graph) or molecule prediction from fingerprint (Fingerprint2Graph).

langue originale	Anglais
journal	Advances in Neural Information Processing Systems
Volume	37
état	Publié - 1 janv. 2024
Evénement	38th Conference on Neural Information Processing Systems, NeurIPS 2024 - Vancouver, Canada Durée: 9 déc. 2024 → 15 déc. 2024

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title = "Any2Graph: Deep End-To-End Supervised Graph Prediction With An Optimal Transport Loss",

abstract = "We propose Any2Graph, a generic framework for end-to-end Supervised Graph Prediction (SGP) i.e. a deep learning model that predicts an entire graph for any kind of input. The framework is built on a novel Optimal Transport loss, the Partially-Masked Fused Gromov-Wasserstein, that exhibits all necessary properties (permutation invariance, differentiability) and is designed to handle any-sized graphs. Numerical experiments showcase the versatility of the approach that outperforms existing competitors on a novel challenging synthetic dataset and a variety of real-world tasks such as map construction from satellite image (Sat2Graph) or molecule prediction from fingerprint (Fingerprint2Graph).",

author = "Paul Krzakala and Junjie Yang and R{\'e}mi Flamary and Florence d'Alch{\'e}-Buc and Charlotte Laclau and Matthieu Labeau",

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T2 - 38th Conference on Neural Information Processing Systems, NeurIPS 2024

AU - Krzakala, Paul

AU - Yang, Junjie

AU - Flamary, Rémi

AU - d'Alché-Buc, Florence

AU - Laclau, Charlotte

AU - Labeau, Matthieu

PY - 2024/1/1

Y1 - 2024/1/1

N2 - We propose Any2Graph, a generic framework for end-to-end Supervised Graph Prediction (SGP) i.e. a deep learning model that predicts an entire graph for any kind of input. The framework is built on a novel Optimal Transport loss, the Partially-Masked Fused Gromov-Wasserstein, that exhibits all necessary properties (permutation invariance, differentiability) and is designed to handle any-sized graphs. Numerical experiments showcase the versatility of the approach that outperforms existing competitors on a novel challenging synthetic dataset and a variety of real-world tasks such as map construction from satellite image (Sat2Graph) or molecule prediction from fingerprint (Fingerprint2Graph).

AB - We propose Any2Graph, a generic framework for end-to-end Supervised Graph Prediction (SGP) i.e. a deep learning model that predicts an entire graph for any kind of input. The framework is built on a novel Optimal Transport loss, the Partially-Masked Fused Gromov-Wasserstein, that exhibits all necessary properties (permutation invariance, differentiability) and is designed to handle any-sized graphs. Numerical experiments showcase the versatility of the approach that outperforms existing competitors on a novel challenging synthetic dataset and a variety of real-world tasks such as map construction from satellite image (Sat2Graph) or molecule prediction from fingerprint (Fingerprint2Graph).

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M3 - Conference article

AN - SCOPUS:105000499598

SN - 1049-5258

VL - 37

JO - Advances in Neural Information Processing Systems

JF - Advances in Neural Information Processing Systems

Y2 - 9 December 2024 through 15 December 2024

ER -

Any2Graph: Deep End-To-End Supervised Graph Prediction With An Optimal Transport Loss

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