Enregistré dans:
Détails bibliographiques
Auteurs principaux: Liu, Z. N. D., Hansen, A. C.
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2401.07874
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866909073695309824
author Liu, Z. N. D.
Hansen, A. C.
author_facet Liu, Z. N. D.
Hansen, A. C.
contents In deep learning (DL) the instability phenomenon is widespread and well documented, most commonly using the classical measure of stability, the Lipschitz constant. While a small Lipchitz constant is traditionally viewed as guarantying stability, it does not capture the instability phenomenon in DL for classification well. The reason is that a classification function -- which is the target function to be approximated -- is necessarily discontinuous, thus having an 'infinite' Lipchitz constant. As a result, the classical approach will deem every classification function unstable, yet basic classification functions a la 'is there a cat in the image?' will typically be locally very 'flat' -- and thus locally stable -- except at the decision boundary. The lack of an appropriate measure of stability hinders a rigorous theory for stability in DL, and consequently, there are no proper approximation theoretic results that can guarantee the existence of stable networks for classification functions. In this paper we introduce a novel stability measure $\mathscr{S}(f)$, for any classification function $f$, appropriate to study the stability of discontinuous functions and their approximations. We further prove two approximation theorems: First, for any $ε> 0$ and any classification function $f$ on a \emph{compact set}, there is a neural network (NN) $ψ$, such that $ψ- f \neq 0$ only on a set of measure $< ε$, moreover, $\mathscr{S}(ψ) \geq \mathscr{S}(f) - ε$ (as accurate and stable as $f$ up to $ε$). Second, for any classification function $f$ and $ε> 0$, there exists a NN $ψ$ such that $ψ= f$ on the set of points that are at least $ε$ away from the decision boundary.
format Preprint
id arxiv_https___arxiv_org_abs_2401_07874
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Do stable neural networks exist for classification problems? -- A new view on stability in AI
Liu, Z. N. D.
Hansen, A. C.
Machine Learning
Functional Analysis
In deep learning (DL) the instability phenomenon is widespread and well documented, most commonly using the classical measure of stability, the Lipschitz constant. While a small Lipchitz constant is traditionally viewed as guarantying stability, it does not capture the instability phenomenon in DL for classification well. The reason is that a classification function -- which is the target function to be approximated -- is necessarily discontinuous, thus having an 'infinite' Lipchitz constant. As a result, the classical approach will deem every classification function unstable, yet basic classification functions a la 'is there a cat in the image?' will typically be locally very 'flat' -- and thus locally stable -- except at the decision boundary. The lack of an appropriate measure of stability hinders a rigorous theory for stability in DL, and consequently, there are no proper approximation theoretic results that can guarantee the existence of stable networks for classification functions. In this paper we introduce a novel stability measure $\mathscr{S}(f)$, for any classification function $f$, appropriate to study the stability of discontinuous functions and their approximations. We further prove two approximation theorems: First, for any $ε> 0$ and any classification function $f$ on a \emph{compact set}, there is a neural network (NN) $ψ$, such that $ψ- f \neq 0$ only on a set of measure $< ε$, moreover, $\mathscr{S}(ψ) \geq \mathscr{S}(f) - ε$ (as accurate and stable as $f$ up to $ε$). Second, for any classification function $f$ and $ε> 0$, there exists a NN $ψ$ such that $ψ= f$ on the set of points that are at least $ε$ away from the decision boundary.
title Do stable neural networks exist for classification problems? -- A new view on stability in AI
topic Machine Learning
Functional Analysis
url https://arxiv.org/abs/2401.07874