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

Research output: Contribution to journal › Conference article › peer-review

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).

Original language	English
Journal	Advances in Neural Information Processing Systems
Volume	37
Publication status	Published - 1 Jan 2024
Event	38th Conference on Neural Information Processing Systems, NeurIPS 2024 - Vancouver, Canada Duration: 9 Dec 2024 → 15 Dec 2024

Cite this

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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).

UR - https://www.scopus.com/pages/publications/105000499598

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

Abstract

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