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Autores principales: Drygala, Claudia, Gottschalk, Hanno, Kruse, Thomas, Martin, Ségolène, Mütze, Annika
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2504.19779
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author Drygala, Claudia
Gottschalk, Hanno
Kruse, Thomas
Martin, Ségolène
Mütze, Annika
author_facet Drygala, Claudia
Gottschalk, Hanno
Kruse, Thomas
Martin, Ségolène
Mütze, Annika
contents Brenier proved that under certain conditions on a source and a target probability measure there exists a strictly convex function such that its gradient is a transport map from the source to the target distribution. This function is called the Brenier potential. Furthermore, detailed information on the Hölder regularity of the Brenier potential is available. In this work we develop the statistical learning theory of generative adversarial neural networks that learn the Brenier potential. As by the transformation of densities formula, the density of the generated measure depends on the second derivative of the Brenier potential, we develop the universal approximation theory of ReCU networks with cubic activation $\mathtt{ReCU}(x)=\max\{0,x\}^3$ that combines the favorable approximation properties of Hölder functions with a Lipschitz continuous density. In order to assure the convexity of such general networks, we introduce an adversarial training procedure for a potential function represented by the ReCU networks that combines the classical discriminator cross entropy loss with a penalty term that enforces (strict) convexity. We give a detailed decomposition of learning errors and show that for a suitable high penalty parameter all networks chosen in the adversarial min-max optimization problem are strictly convex. This is further exploited to prove the consistency of the learning procedure for (slowly) expanding network capacity. We also implement the described learning algorithm and apply it to a number of standard test cases from Gaussian mixture to image data as target distributions. As predicted in theory, we observe that the convexity loss becomes inactive during the training process and the potentials represented by the neural networks have learned convexity.
format Preprint
id arxiv_https___arxiv_org_abs_2504_19779
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning Brenier Potentials with Convex Generative Adversarial Neural Networks
Drygala, Claudia
Gottschalk, Hanno
Kruse, Thomas
Martin, Ségolène
Mütze, Annika
Machine Learning
Computer Vision and Pattern Recognition
Brenier proved that under certain conditions on a source and a target probability measure there exists a strictly convex function such that its gradient is a transport map from the source to the target distribution. This function is called the Brenier potential. Furthermore, detailed information on the Hölder regularity of the Brenier potential is available. In this work we develop the statistical learning theory of generative adversarial neural networks that learn the Brenier potential. As by the transformation of densities formula, the density of the generated measure depends on the second derivative of the Brenier potential, we develop the universal approximation theory of ReCU networks with cubic activation $\mathtt{ReCU}(x)=\max\{0,x\}^3$ that combines the favorable approximation properties of Hölder functions with a Lipschitz continuous density. In order to assure the convexity of such general networks, we introduce an adversarial training procedure for a potential function represented by the ReCU networks that combines the classical discriminator cross entropy loss with a penalty term that enforces (strict) convexity. We give a detailed decomposition of learning errors and show that for a suitable high penalty parameter all networks chosen in the adversarial min-max optimization problem are strictly convex. This is further exploited to prove the consistency of the learning procedure for (slowly) expanding network capacity. We also implement the described learning algorithm and apply it to a number of standard test cases from Gaussian mixture to image data as target distributions. As predicted in theory, we observe that the convexity loss becomes inactive during the training process and the potentials represented by the neural networks have learned convexity.
title Learning Brenier Potentials with Convex Generative Adversarial Neural Networks
topic Machine Learning
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2504.19779