学习用于磁共振图像超分辨率的双因子表示法

Weifeng Wei, Heng Chen, Pengxiang Su
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摘要

磁共振成像(MRI)需要在分辨率、信噪比和扫描时间之间进行权衡,因此高分辨率(HR)采集具有挑战性。然而,大多数现有方法在从低分辨率图像准确学习连续容积表示方面面临挑战,或者需要高分辨率图像进行监督。为了解决这些难题,我们提出了一种基于双因子表示的 MR 图像超分辨率新方法。具体来说,我们将强度信号因子化为可学习的基础因子和系数因子的线性组合,从而从低分辨率磁共振图像中获得高效的连续容积表示。此外,我们还引入了基于坐标的编码,以捕捉稀疏体素之间的结构关系,从而促进未观察区域的顺利完成。在 BraTS 2019 和 MSSEG 2016 数据集上进行的实验表明,我们的方法达到了最先进的性能,提供了卓越的视觉保真度和鲁棒性,尤其是在大采样规模的磁共振图像超分辨率中。
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Learning Two-factor Representation for Magnetic Resonance Image Super-resolution
Magnetic Resonance Imaging (MRI) requires a trade-off between resolution, signal-to-noise ratio, and scan time, making high-resolution (HR) acquisition challenging. Therefore, super-resolution for MR image is a feasible solution. However, most existing methods face challenges in accurately learning a continuous volumetric representation from low-resolution image or require HR image for supervision. To solve these challenges, we propose a novel method for MR image super-resolution based on two-factor representation. Specifically, we factorize intensity signals into a linear combination of learnable basis and coefficient factors, enabling efficient continuous volumetric representation from low-resolution MR image. Besides, we introduce a coordinate-based encoding to capture structural relationships between sparse voxels, facilitating smooth completion in unobserved regions. Experiments on BraTS 2019 and MSSEG 2016 datasets demonstrate that our method achieves state-of-the-art performance, providing superior visual fidelity and robustness, particularly in large up-sampling scale MR image super-resolution.
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