DDEQs: Distributional Deep Equilibrium Models through Wasserstein Gradient Flows

Jonathan Geuter; Clément Bonet; Anna Korba; David Alvarez-Melis

DDEQs: Distributional Deep Equilibrium Models through Wasserstein Gradient Flows

Jonathan Geuter
, Clément Bonet
, Anna Korba
, David Alvarez-Melis

Harvard University
ENSAE

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

Résumé

Deep Equilibrium Models (DEQs) are a class of implicit neural networks that solve for a fixed point of a neural network in their forward pass. Traditionally, DEQs take sequences as inputs, but have since been applied to a variety of data. In this work, we present Distributional Deep Equilibrium Models (DDEQs), extending DEQs to discrete measure inputs, such as sets or point clouds. We provide a theoretically grounded framework for DDEQs. Leveraging Wasserstein gradient flows, we show how the forward pass of the DEQ can be adapted to find fixed points of discrete measures under permutation-invariance, and derive adequate network architectures for DDEQs. In experiments, we show that they can compete with state-of-the-art models in tasks such as point cloud classification and point cloud completion, while being significantly more parameter-efficient.

langue originale	Anglais
Pages (de - à)	3988-3996
Nombre de pages	9
journal	Proceedings of Machine Learning Research
Volume	258
état	Publié - 1 janv. 2025
Modification externe	Oui
Evénement	28th International Conference on Artificial Intelligence and Statistics, AISTATS 2025 - Mai Khao, Thadlande Durée: 3 mai 2025 → 5 mai 2025

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title = "DDEQs: Distributional Deep Equilibrium Models through Wasserstein Gradient Flows",

abstract = "Deep Equilibrium Models (DEQs) are a class of implicit neural networks that solve for a fixed point of a neural network in their forward pass. Traditionally, DEQs take sequences as inputs, but have since been applied to a variety of data. In this work, we present Distributional Deep Equilibrium Models (DDEQs), extending DEQs to discrete measure inputs, such as sets or point clouds. We provide a theoretically grounded framework for DDEQs. Leveraging Wasserstein gradient flows, we show how the forward pass of the DEQ can be adapted to find fixed points of discrete measures under permutation-invariance, and derive adequate network architectures for DDEQs. In experiments, we show that they can compete with state-of-the-art models in tasks such as point cloud classification and point cloud completion, while being significantly more parameter-efficient.",

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T2 - 28th International Conference on Artificial Intelligence and Statistics, AISTATS 2025

AU - Geuter, Jonathan

AU - Bonet, Clément

AU - Korba, Anna

AU - Alvarez-Melis, David

PY - 2025/1/1

Y1 - 2025/1/1

N2 - Deep Equilibrium Models (DEQs) are a class of implicit neural networks that solve for a fixed point of a neural network in their forward pass. Traditionally, DEQs take sequences as inputs, but have since been applied to a variety of data. In this work, we present Distributional Deep Equilibrium Models (DDEQs), extending DEQs to discrete measure inputs, such as sets or point clouds. We provide a theoretically grounded framework for DDEQs. Leveraging Wasserstein gradient flows, we show how the forward pass of the DEQ can be adapted to find fixed points of discrete measures under permutation-invariance, and derive adequate network architectures for DDEQs. In experiments, we show that they can compete with state-of-the-art models in tasks such as point cloud classification and point cloud completion, while being significantly more parameter-efficient.

AB - Deep Equilibrium Models (DEQs) are a class of implicit neural networks that solve for a fixed point of a neural network in their forward pass. Traditionally, DEQs take sequences as inputs, but have since been applied to a variety of data. In this work, we present Distributional Deep Equilibrium Models (DDEQs), extending DEQs to discrete measure inputs, such as sets or point clouds. We provide a theoretically grounded framework for DDEQs. Leveraging Wasserstein gradient flows, we show how the forward pass of the DEQ can be adapted to find fixed points of discrete measures under permutation-invariance, and derive adequate network architectures for DDEQs. In experiments, we show that they can compete with state-of-the-art models in tasks such as point cloud classification and point cloud completion, while being significantly more parameter-efficient.

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M3 - Conference article

AN - SCOPUS:105014328036

SN - 2640-3498

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SP - 3988

EP - 3996

JO - Proceedings of Machine Learning Research

JF - Proceedings of Machine Learning Research

Y2 - 3 May 2025 through 5 May 2025

ER -

DDEQs: Distributional Deep Equilibrium Models through Wasserstein Gradient Flows

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