Alex Glyn-Davies, Arnaud Vadeboncoeur, O. Deniz Akyildiz, Ieva Kazlauskaite, Mark Girolami
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引用次数: 0
Abstract
Variational inference (VI) is a computationally efficient and scalable
methodology for approximate Bayesian inference. It strikes a balance between
accuracy of uncertainty quantification and practical tractability. It excels at
generative modelling and inversion tasks due to its built-in Bayesian
regularisation and flexibility, essential qualities for physics related
problems. Deriving the central learning objective for VI must often be tailored
to new learning tasks where the nature of the problems dictates the conditional
dependence between variables of interest, such as arising in physics problems.
In this paper, we provide an accessible and thorough technical introduction to
VI for forward and inverse problems, guiding the reader through standard
derivations of the VI framework and how it can best be realized through deep
learning. We then review and unify recent literature exemplifying the creative
flexibility allowed by VI. This paper is designed for a general scientific
audience looking to solve physics-based problems with an emphasis on
uncertainty quantification.
变量推理(Variational inference,VI)是一种计算效率高、可扩展的近似贝叶斯推理方法。它在不确定性量化的准确性和实用性之间取得了平衡。由于其内置的贝叶斯规则化和灵活性,它在生成建模和反演任务中表现出色,这些都是物理相关问题的基本特征。在本文中,我们针对正演和反演问题对 VI 进行了深入浅出的技术介绍,引导读者了解 VI 框架的标准衍生,以及如何通过深度学习最好地实现 VI。然后,我们回顾并统一了最近的文献,这些文献体现了 VI 所允许的创造性灵活性。本文面向希望解决物理问题的普通科学读者,重点关注不确定性量化。
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