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Main Authors: Sklaviadis, Sophia, Moellenhoff, Thomas, Martins, Andre, Figueiredo, Mario
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.10295
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author Sklaviadis, Sophia
Moellenhoff, Thomas
Martins, Andre
Figueiredo, Mario
author_facet Sklaviadis, Sophia
Moellenhoff, Thomas
Martins, Andre
Figueiredo, Mario
contents From a variational perspective, many statistical learning criteria involve seeking a distribution that balances empirical risk and regularization. In this paper, we broaden this perspective by introducing a new general class of variational methods based on Fenchel-Young (FY) losses, treated as divergences that generalize (and encompass) the familiar Kullback-Leibler divergence at the core of classical variational learning. Our proposed formulation -- FY variational learning -- includes as key ingredients new notions of FY free energy, FY evidence, FY evidence lower bound, and FY posterior. We derive alternating minimization and gradient backpropagation algorithms to compute (or lower bound) the FY evidence, which enables learning a wider class of models than previous variational formulations. This leads to generalized FY variants of classical algorithms, such as an FY expectation-maximization (FYEM) algorithm, and latent-variable models, such as an FY variational autoencoder (FYVAE). Our new methods are shown to be empirically competitive, often outperforming their classical counterparts, and most importantly, to have qualitatively novel features. For example, FYEM has an adaptively sparse E-step, while the FYVAE can support models with sparse observations and sparse posteriors.
format Preprint
id arxiv_https___arxiv_org_abs_2502_10295
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Fenchel-Young Variational Learning
Sklaviadis, Sophia
Moellenhoff, Thomas
Martins, Andre
Figueiredo, Mario
Machine Learning
From a variational perspective, many statistical learning criteria involve seeking a distribution that balances empirical risk and regularization. In this paper, we broaden this perspective by introducing a new general class of variational methods based on Fenchel-Young (FY) losses, treated as divergences that generalize (and encompass) the familiar Kullback-Leibler divergence at the core of classical variational learning. Our proposed formulation -- FY variational learning -- includes as key ingredients new notions of FY free energy, FY evidence, FY evidence lower bound, and FY posterior. We derive alternating minimization and gradient backpropagation algorithms to compute (or lower bound) the FY evidence, which enables learning a wider class of models than previous variational formulations. This leads to generalized FY variants of classical algorithms, such as an FY expectation-maximization (FYEM) algorithm, and latent-variable models, such as an FY variational autoencoder (FYVAE). Our new methods are shown to be empirically competitive, often outperforming their classical counterparts, and most importantly, to have qualitatively novel features. For example, FYEM has an adaptively sparse E-step, while the FYVAE can support models with sparse observations and sparse posteriors.
title Fenchel-Young Variational Learning
topic Machine Learning
url https://arxiv.org/abs/2502.10295