去噪监督

IF 20.8 1区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE IEEE Transactions on Pattern Analysis and Machine Intelligence Pub Date : 2023-07-28 DOI:10.1109/TPAMI.2023.3299789
Sean I Young, Adrian V Dalca, Enzo Ferrante, Polina Golland, Christopher A Metzler, Bruce Fischl, Juan Eugenio Iglesias
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引用次数: 0

摘要

基于学习的图像重建模型,如基于 U-Net 的模型,需要大量的标记图像集才能保证良好的泛化效果。然而,在某些成像领域,由于获取成本的原因,具有像素或体素级标签精度的标签数据非常稀缺。在医学成像等领域,这一问题更加严重,因为这些领域没有单一的地面实况标签,导致标签的重复变异性很大。因此,通过从有标签和无标签的示例中学习(称为半监督学习)来训练重建网络,使其具有更好的泛化能力,是一个具有实际意义和理论意义的问题。然而,用于图像重建的传统半监督学习方法往往需要针对特定的成像问题手工制作一个可微分的正则化器,这可能会非常耗时。在这项工作中,我们提出了 "去噪监督"(SUD),这是一种利用自身去噪输出作为标签对重建模型进行监督的框架。SUD 在时空去噪框架下统一了随机平均和空间去噪技术,并在半监督的优化框架中交替使用去噪和模型权重更新步骤。作为应用实例,我们将 SUD 应用于生物医学成像中的两个问题--大脑解剖重建(三维)和皮层解析(二维)--证明了与纯监督和集合基线相比,SUD 在重建方面的显著改进。我们的代码见 https://github.com/seannz/sud。
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Supervision by Denoising.

Learning-based image reconstruction models, such as those based on the U-Net, require a large set of labeled images if good generalization is to be guaranteed. In some imaging domains, however, labeled data with pixel- or voxel-level label accuracy are scarce due to the cost of acquiring them. This problem is exacerbated further in domains like medical imaging, where there is no single ground truth label, resulting in large amounts of repeat variability in the labels. Therefore, training reconstruction networks to generalize better by learning from both labeled and unlabeled examples (called semi-supervised learning) is problem of practical and theoretical interest. However, traditional semi-supervised learning methods for image reconstruction often necessitate handcrafting a differentiable regularizer specific to some given imaging problem, which can be extremely time-consuming. In this work, we propose "supervision by denoising" (SUD), a framework to supervise reconstruction models using their own denoised output as labels. SUD unifies stochastic averaging and spatial denoising techniques under a spatio-temporal denoising framework and alternates denoising and model weight update steps in an optimization framework for semi-supervision. As example applications, we apply SUD to two problems from biomedical imaging-anatomical brain reconstruction (3D) and cortical parcellation (2D)-to demonstrate a significant improvement in reconstruction over supervised-only and ensembling baselines. Our code available at https://github.com/seannz/sud.

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来源期刊
CiteScore
28.40
自引率
3.00%
发文量
885
审稿时长
8.5 months
期刊介绍: The IEEE Transactions on Pattern Analysis and Machine Intelligence publishes articles on all traditional areas of computer vision and image understanding, all traditional areas of pattern analysis and recognition, and selected areas of machine intelligence, with a particular emphasis on machine learning for pattern analysis. Areas such as techniques for visual search, document and handwriting analysis, medical image analysis, video and image sequence analysis, content-based retrieval of image and video, face and gesture recognition and relevant specialized hardware and/or software architectures are also covered.
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