Learning to Predict Graphs with Fused Gromov-Wasserstein Barycenters

Luc Brogat-Motte; Rémi Flamary; Céline Brouard; Juho Rousu; Florence D'Alché-Buc

Learning to Predict Graphs with Fused Gromov-Wasserstein Barycenters

Luc Brogat-Motte
, Rémi Flamary
, Céline Brouard
, Juho Rousu
, Florence D'Alché-Buc

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

Abstract

This paper introduces a novel and generic framework to solve the flagship task of supervised labeled graph prediction by leveraging Optimal Transport tools. We formulate the problem as regression with the Fused Gromov-Wasserstein (FGW) loss and propose a predictive model relying on a FGW barycenter whose weights depend on inputs. First we introduce a non-parametric estimator based on kernel ridge regression for which theoretical results such as consistency and excess risk bound are proved. Next we propose an interpretable parametric model where the barycenter weights are modeled with a neural network and the graphs on which the FGW barycenter is calculated are additionally learned. Numerical experiments show the strength of the method and its ability to interpolate in the labeled graph space on simulated data and on a difficult metabolic identification problem where it can reach very good performance with very little engineering.

Original language	English
Pages (from-to)	2321-2335
Number of pages	15
Journal	Proceedings of Machine Learning Research
Volume	162
Publication status	Published - 1 Jan 2022
Event	39th International Conference on Machine Learning, ICML 2022 - Baltimore, United States Duration: 17 Jul 2022 → 23 Jul 2022

Cite this

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title = "Learning to Predict Graphs with Fused Gromov-Wasserstein Barycenters",

abstract = "This paper introduces a novel and generic framework to solve the flagship task of supervised labeled graph prediction by leveraging Optimal Transport tools. We formulate the problem as regression with the Fused Gromov-Wasserstein (FGW) loss and propose a predictive model relying on a FGW barycenter whose weights depend on inputs. First we introduce a non-parametric estimator based on kernel ridge regression for which theoretical results such as consistency and excess risk bound are proved. Next we propose an interpretable parametric model where the barycenter weights are modeled with a neural network and the graphs on which the FGW barycenter is calculated are additionally learned. Numerical experiments show the strength of the method and its ability to interpolate in the labeled graph space on simulated data and on a difficult metabolic identification problem where it can reach very good performance with very little engineering.",

author = "Luc Brogat-Motte and R{\'e}mi Flamary and C{\'e}line Brouard and Juho Rousu and Florence D'Alch{\'e}-Buc",

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AU - Brogat-Motte, Luc

AU - Flamary, Rémi

AU - Brouard, Céline

AU - Rousu, Juho

AU - D'Alché-Buc, Florence

PY - 2022/1/1

Y1 - 2022/1/1

N2 - This paper introduces a novel and generic framework to solve the flagship task of supervised labeled graph prediction by leveraging Optimal Transport tools. We formulate the problem as regression with the Fused Gromov-Wasserstein (FGW) loss and propose a predictive model relying on a FGW barycenter whose weights depend on inputs. First we introduce a non-parametric estimator based on kernel ridge regression for which theoretical results such as consistency and excess risk bound are proved. Next we propose an interpretable parametric model where the barycenter weights are modeled with a neural network and the graphs on which the FGW barycenter is calculated are additionally learned. Numerical experiments show the strength of the method and its ability to interpolate in the labeled graph space on simulated data and on a difficult metabolic identification problem where it can reach very good performance with very little engineering.

AB - This paper introduces a novel and generic framework to solve the flagship task of supervised labeled graph prediction by leveraging Optimal Transport tools. We formulate the problem as regression with the Fused Gromov-Wasserstein (FGW) loss and propose a predictive model relying on a FGW barycenter whose weights depend on inputs. First we introduce a non-parametric estimator based on kernel ridge regression for which theoretical results such as consistency and excess risk bound are proved. Next we propose an interpretable parametric model where the barycenter weights are modeled with a neural network and the graphs on which the FGW barycenter is calculated are additionally learned. Numerical experiments show the strength of the method and its ability to interpolate in the labeled graph space on simulated data and on a difficult metabolic identification problem where it can reach very good performance with very little engineering.

UR - https://www.scopus.com/pages/publications/85143891773

M3 - Conference article

AN - SCOPUS:85143891773

SN - 2640-3498

VL - 162

SP - 2321

EP - 2335

JO - Proceedings of Machine Learning Research

JF - Proceedings of Machine Learning Research

T2 - 39th International Conference on Machine Learning, ICML 2022

Y2 - 17 July 2022 through 23 July 2022

ER -

Learning to Predict Graphs with Fused Gromov-Wasserstein Barycenters

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