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通过循环测量一致性实现不确定性引导的物理驱动深度学习重建

UNCERTAINTY-GUIDED PHYSICS-DRIVEN DEEP LEARNING RECONSTRUCTION VIA CYCLIC MEASUREMENT CONSISTENCY.

作者信息

Zhang Chi, Akçakaya Mehmet

机构信息

Electrical and Computer Engineering, University of Minnesota, Minneapolis, MN, USA.

Center for Magnetic Resonance Research, University of Minnesota, Minneapolis, MN, USA.

出版信息

Proc IEEE Int Conf Acoust Speech Signal Process. 2024 Apr;2024:13441-13445. doi: 10.1109/icassp48485.2024.10447594. Epub 2024 Mar 18.

DOI:10.1109/icassp48485.2024.10447594
PMID:39829965
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11736017/
Abstract

Physics-driven deep learning (PD-DL) techniques have recently emerged as a powerful means for improved computational imaging, including in MRI applications. These methods use the physics information by incorporating the known forward model for data fidelity, while performing regularization using neural networks. There has been substantial progress in the training of PD-DL reconstruction methods, ranging from simple supervised learning to more practical self-supervised learning and generative models that allow training without reference data. Similarly, efforts have been made to characterize the errors associated with PD-DL methods via uncertainty quantification, mostly focusing on generative models. In this work, we devise an uncertainty estimation process that primarily focuses on the data fidelity component of PD-DL by characterizing the cyclic consistency between different forward models. Subsequently, we use this uncertainty estimate to guide the training of the PD-DL method. Results show that the proposed uncertainty-guided PD-DL strategy improves reconstruction quality.

摘要

物理驱动的深度学习(PD-DL)技术最近已成为改进计算成像的有力手段,包括在磁共振成像(MRI)应用中。这些方法通过纳入已知的前向模型以确保数据保真度来利用物理信息,同时使用神经网络进行正则化。在PD-DL重建方法的训练方面已经取得了重大进展,从简单的监督学习到更实用的自监督学习以及无需参考数据即可进行训练的生成模型。同样,人们也努力通过不确定性量化来表征与PD-DL方法相关的误差,主要集中在生成模型上。在这项工作中,我们设计了一种不确定性估计过程,该过程主要通过表征不同前向模型之间的循环一致性来关注PD-DL的数据保真度部分。随后,我们使用这种不确定性估计来指导PD-DL方法的训练。结果表明,所提出的不确定性引导的PD-DL策略提高了重建质量。

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Memory-efficient model-based deep learning with convergence and robustness guarantees.具有收敛性和鲁棒性保证的基于模型的内存高效深度学习。
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4
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