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arxiv: 2203.12215 · v3 · pith:NWKFFD3Ynew · submitted 2022-03-23 · 📡 eess.IV · cs.CV· cs.LG· eess.SP· physics.med-ph

Physics-Driven Deep Learning for Computational Magnetic Resonance Imaging

classification 📡 eess.IV cs.CVcs.LGeess.SPphysics.med-ph
keywords physics-drivenlearningcomputationaldeepimagingmodelsapproacheschallenges
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Physics-driven deep learning methods have emerged as a powerful tool for computational magnetic resonance imaging (MRI) problems, pushing reconstruction performance to new limits. This article provides an overview of the recent developments in incorporating physics information into learning-based MRI reconstruction. We consider inverse problems with both linear and non-linear forward models for computational MRI, and review the classical approaches for solving these. We then focus on physics-driven deep learning approaches, covering physics-driven loss functions, plug-and-play methods, generative models, and unrolled networks. We highlight domain-specific challenges such as real- and complex-valued building blocks of neural networks, and translational applications in MRI with linear and non-linear forward models. Finally, we discuss common issues and open challenges, and draw connections to the importance of physics-driven learning when combined with other downstream tasks in the medical imaging pipeline.

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