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Autori principali: Catoni, Josefina, Martos, Domonkos, Csikor, Ferenc, Ferrante, Enzo, Milone, Diego H., Meszéna, Balázs, Orbán, Gergő, Echeveste, Rodrigo
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2404.15390
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author Catoni, Josefina
Martos, Domonkos
Csikor, Ferenc
Ferrante, Enzo
Milone, Diego H.
Meszéna, Balázs
Orbán, Gergő
Echeveste, Rodrigo
author_facet Catoni, Josefina
Martos, Domonkos
Csikor, Ferenc
Ferrante, Enzo
Milone, Diego H.
Meszéna, Balázs
Orbán, Gergő
Echeveste, Rodrigo
contents Optimal computations under uncertainty require an adequate probabilistic representation about beliefs. Deep generative models, and specifically Variational Autoencoders (VAEs), have the potential to meet this demand by building latent representations that learn to associate uncertainties with inferences while avoiding their characteristic intractable computations. Yet, we show that it is precisely uncertainty representation that suffers from inconsistencies under an array of relevant computer vision conditions: contrast-dependent computations, image corruption, out-of-distribution detection. Drawing inspiration from classical computer vision, we present a principled extension to the standard VAE by introducing a simple yet powerful inductive bias through a global scaling latent variable, which we call the Explaining-Away VAE (EA-VAE). By applying EA-VAEs to a spectrum of computer vision domains and a variety of datasets, spanning standard NIST datasets to rich medical and natural image sets, we show the EA-VAE restores normative requirements for uncertainty. Furthermore, we provide an analytical underpinning of the contribution of the introduced scaling latent to contrast-related and out-of-distribution related modulations of uncertainty, demonstrating that this mild inductive bias has stark benefits in a broad set of problems. Moreover, we find that EA-VAEs recruit divisive normalization, a motif widespread in biological neural networks, to remedy defective inference. Our results demonstrate that an easily implemented, still powerful update to the VAE architecture can remedy defective inference of uncertainty in probabilistic computations.
format Preprint
id arxiv_https___arxiv_org_abs_2404_15390
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Remedying uncertainty representations in visual inference through Explaining-Away Variational Autoencoders
Catoni, Josefina
Martos, Domonkos
Csikor, Ferenc
Ferrante, Enzo
Milone, Diego H.
Meszéna, Balázs
Orbán, Gergő
Echeveste, Rodrigo
Machine Learning
Artificial Intelligence
Optimal computations under uncertainty require an adequate probabilistic representation about beliefs. Deep generative models, and specifically Variational Autoencoders (VAEs), have the potential to meet this demand by building latent representations that learn to associate uncertainties with inferences while avoiding their characteristic intractable computations. Yet, we show that it is precisely uncertainty representation that suffers from inconsistencies under an array of relevant computer vision conditions: contrast-dependent computations, image corruption, out-of-distribution detection. Drawing inspiration from classical computer vision, we present a principled extension to the standard VAE by introducing a simple yet powerful inductive bias through a global scaling latent variable, which we call the Explaining-Away VAE (EA-VAE). By applying EA-VAEs to a spectrum of computer vision domains and a variety of datasets, spanning standard NIST datasets to rich medical and natural image sets, we show the EA-VAE restores normative requirements for uncertainty. Furthermore, we provide an analytical underpinning of the contribution of the introduced scaling latent to contrast-related and out-of-distribution related modulations of uncertainty, demonstrating that this mild inductive bias has stark benefits in a broad set of problems. Moreover, we find that EA-VAEs recruit divisive normalization, a motif widespread in biological neural networks, to remedy defective inference. Our results demonstrate that an easily implemented, still powerful update to the VAE architecture can remedy defective inference of uncertainty in probabilistic computations.
title Remedying uncertainty representations in visual inference through Explaining-Away Variational Autoencoders
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2404.15390