Lightning UQ Box: Uncertainty Quantification for Neural Networks

Nils Lehmann; Nina Maria Gottschling; Jakob Gawlikowski; Adam J. Stewart; Stefan Depeweg; Eric Nalisnick

Lightning UQ Box: Uncertainty Quantification for Neural Networks

Nils Lehmann
, Nina Maria Gottschling
, Jakob Gawlikowski
, Adam J. Stewart
, Stefan Depeweg
, Eric Nalisnick

Quantum Communications and Networking

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Although neural networks have shown impressive results in a multitude of application domains, the “black box” nature of deep learning and lack of confidence estimates have led to scepticism, especially in domains like medicine and physics where such estimates are critical. Research on uncertainty quantification (UQ) has helped elucidate the reliability of these models, but existing implementations of these UQ methods are sparse and difficult to reuse. To this end, we introduce Lightning UQ Box, a PyTorch-based Python library for deep learning-based UQ methods powered by PyTorch Lightning. Lightning UQ Box supports classification, regression, semantic segmentation, and pixelwise regression applications, and UQ methods from a variety of theoretical motivations. With this library, we provide an entry point for practitioners new to UQ, as well as easy-to-use components and tools for scalable deep learning applications.

Original language	English
Journal	Journal of Machine Learning Research
Volume	26
State	Published - 2025

Keywords

Bayesian Deep Learning
Conformal Prediction
Deep Learning
PyTorch
Uncertainty Quantification

Cite this

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title = "Lightning UQ Box: Uncertainty Quantification for Neural Networks",

abstract = "Although neural networks have shown impressive results in a multitude of application domains, the “black box” nature of deep learning and lack of confidence estimates have led to scepticism, especially in domains like medicine and physics where such estimates are critical. Research on uncertainty quantification (UQ) has helped elucidate the reliability of these models, but existing implementations of these UQ methods are sparse and difficult to reuse. To this end, we introduce Lightning UQ Box, a PyTorch-based Python library for deep learning-based UQ methods powered by PyTorch Lightning. Lightning UQ Box supports classification, regression, semantic segmentation, and pixelwise regression applications, and UQ methods from a variety of theoretical motivations. With this library, we provide an entry point for practitioners new to UQ, as well as easy-to-use components and tools for scalable deep learning applications.",

keywords = "Bayesian Deep Learning, Conformal Prediction, Deep Learning, PyTorch, Uncertainty Quantification",

author = "Nils Lehmann and Gottschling, \{Nina Maria\} and Jakob Gawlikowski and Stewart, \{Adam J.\} and Stefan Depeweg and Eric Nalisnick",

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T2 - Uncertainty Quantification for Neural Networks

AU - Lehmann, Nils

AU - Gottschling, Nina Maria

AU - Gawlikowski, Jakob

AU - Stewart, Adam J.

AU - Depeweg, Stefan

AU - Nalisnick, Eric

PY - 2025

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AB - Although neural networks have shown impressive results in a multitude of application domains, the “black box” nature of deep learning and lack of confidence estimates have led to scepticism, especially in domains like medicine and physics where such estimates are critical. Research on uncertainty quantification (UQ) has helped elucidate the reliability of these models, but existing implementations of these UQ methods are sparse and difficult to reuse. To this end, we introduce Lightning UQ Box, a PyTorch-based Python library for deep learning-based UQ methods powered by PyTorch Lightning. Lightning UQ Box supports classification, regression, semantic segmentation, and pixelwise regression applications, and UQ methods from a variety of theoretical motivations. With this library, we provide an entry point for practitioners new to UQ, as well as easy-to-use components and tools for scalable deep learning applications.

KW - Bayesian Deep Learning

KW - Conformal Prediction

KW - Deep Learning

KW - PyTorch

KW - Uncertainty Quantification

UR - https://www.scopus.com/pages/publications/105018916957

M3 - Article

AN - SCOPUS:105018916957

SN - 1532-4435

VL - 26

JO - Journal of Machine Learning Research

JF - Journal of Machine Learning Research

ER -

Lightning UQ Box: Uncertainty Quantification for Neural Networks

Abstract

Keywords

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