使用能量分辨光栅干涉仪和一种新型秩约束提高X射线差分相衬成像的辐射剂量效率。
Improving radiation dose efficiency of X-ray differential phase contrast imaging using an energy-resolving grating interferometer and a novel rank constraint.
作者信息
Ge Yongshuai, Zhang Ran, Li Ke, Chen Guang-Hong
出版信息
Opt Express. 2016 Jun 13;24(12):12955-68. doi: 10.1364/OE.24.012955.
Abstract
In this paper, a novel method was developed to improve the radiation dose efficiency, viz., contrast to noise ratio normalized by dose (CNRD), of the grating-based X-ray differential phase contrast (DPC) imaging system that is integrated with an energy-resolving photon counting detector. The method exploits the low-dimensionality of the spatial-spectral DPC image matrix acquired from different energy windows. A low rank approximation of the spatial-spectral image matrix was developed to reduce image noise while retaining the DPC signal accuracy for every energy window. Numerical simulations and experimental phantom studies have been performed to validate the proposed method by showing noise reduction and CNRD improvement for each energy window.
摘要
在本文中,开发了一种新方法来提高基于光栅的X射线微分相衬(DPC)成像系统的辐射剂量效率,即剂量归一化对比度噪声比(CNRD),该成像系统集成了能量分辨光子计数探测器。该方法利用了从不同能量窗口获取的空间光谱DPC图像矩阵的低维特性。通过对空间光谱图像矩阵进行低秩近似,在保留每个能量窗口DPC信号精度的同时降低图像噪声。已进行数值模拟和实验体模研究,通过展示每个能量窗口的降噪效果和CNRD改善情况来验证所提出的方法。
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