PRECISION:用于光子计数计算机断层扫描的物理约束和噪声控制扩散模型。

Ruifeng Chen;Zhongliang Zhang;Guotao Quan;Yanfeng Du;Yang Chen;Yinsheng Li
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引用次数: 0

摘要

最近,光子计数探测器在计算机断层扫描(PCCT)中的应用引起了广泛关注。人们非常希望提高物质基础图像的质量和元素组成的定量准确性,尤其是在以较低辐射剂量水平获取 PCCT 数据时。在这项工作中,我们开发了一种物理约束和噪声控制的扩散模型(简称 PRECISION),以解决现有的直接物质基础图像重建方法中主要由不完善的噪声模型和/或对物质基础图像的手工正则化(如局部平滑和/或稀疏性)造成的物质基础图像质量下降和元素成分定量不准确的问题。与此形成鲜明对比的是,PRECISION 通过训练噪声控制的空间-光谱扩散模型,学习分布级正则化来描述理想物质基础图像的特征。每个受试者的最佳物质基础图像都是在给定 PCCT 物理模型和受试者测量数据的约束下,从学习到的分布中采样得到的。PRECISION 具有提高材料基础图像质量和 PCCT 元素组成定量准确性的潜力。
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PRECISION: A Physics-Constrained and Noise-Controlled Diffusion Model for Photon Counting Computed Tomography
Recently, the use of photon counting detectors in computed tomography (PCCT) has attracted extensive attention. It is highly desired to improve the quality of material basis image and the quantitative accuracy of elemental composition, particularly when PCCT data is acquired at lower radiation dose levels. In this work, we develop a p hysics-const r ained and nois e - c ontrolled d i ffu sion model, PRECISION in short, to address the degraded quality of material basis images and inaccurate quantification of elemental composition mainly caused by imperfect noise model and/or hand-crafted regularization of material basis images, such as local smoothness and/or sparsity, leveraged in the existing direct material basis image reconstruction approaches. In stark contrast, PRECISION learns distribution-level regularization to describe the feature of ideal material basis images via training a noise-controlled spatial-spectral diffusion model. The optimal material basis images of each individual subject are sampled from this learned distribution under the constraint of the physical model of a given PCCT and the measured data obtained from the subject. PRECISION exhibits the potential to improve the quality of material basis images and the quantitative accuracy of elemental composition for PCCT.
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