X-ray Products, Varian Medical Systems Inc., Liverpool, New York 13088, USA.
Med Phys. 2013 Aug;40(8):081913. doi: 10.1118/1.4813303.
Anode heel effect renders large-scale background nonuniformities in digital radiographs. Conventional offset/gain calibration is performed at mono source-to-image distance (SID), and disregards the SID-dependent characteristic of heel effect. It results in a residual nonuniform background in the corrected radiographs when the SID settings for calibration and correction differ. In this work, the authors develop a robust and efficient computational method for digital x-ray detector gain correction adapted to SID-variant heel effect, without resorting to physical filters, phantoms, complicated heel effect models, or multiple-SID calibration and interpolation.
The authors present the Duo-SID projection correction method. In our approach, conventional offset/gain calibrations are performed only twice, at the minimum and maximum SIDs of the system in typical clinical use. A fast iterative separation algorithm is devised to extract the detector gain and basis heel patterns from the min/max SID calibrations. The resultant detector gain is independent of SID, while the basis heel patterns are parameterized by the min- and max-SID. The heel pattern at any SID is obtained from the min-SID basis heel pattern via projection imaging principles. The system gain desired at a specific acquisition SID is then constructed using the projected heel pattern and detector gain map.
The method was evaluated for flat field and anatomical phantom image corrections. It demonstrated promising improvements over interpolation and conventional gain calibration/correction methods, lowering their correction errors by approximately 70% and 80%, respectively. The separation algorithm was able to extract the detector gain and heel patterns with less than 2% error, and the Duo-SID corrected images showed perceptually appealing uniform background across the detector.
The Duo-SID correction method has substantially improved on conventional offset/gain corrections for digital x-ray imaging in an SID-variant environment. The technique is relatively simple, and can be easily incorporated into multiple-point gain calibration/correction techniques. It offers a potentially valuable tool for preprocessing digital x-ray images to boost image quality of mammography, chest and cardiac radiography, as well as automated computer aided diagnostic radiology.
阳极足跟效应会导致数字射线照片中出现大规模的背景不均匀性。传统的偏移/增益校准是在单源-像距(SID)处进行的,并且忽略了足跟效应的 SID 依赖性特征。当校准和校正的 SID 设置不同时,校正后的射线照片中会残留不均匀的背景。在这项工作中,作者开发了一种强大而有效的计算方法,用于数字 X 射线探测器增益校正,适应 SID 变化的足跟效应,而无需使用物理滤波器、体模、复杂的足跟效应模型或多 SID 校准和插值。
作者提出了 Duo-SID 投影校正方法。在我们的方法中,仅在系统的最小和最大 SID 处进行两次传统的偏移/增益校准,这是典型临床使用中的最小和最大 SID。设计了一种快速迭代分离算法,从最小/最大 SID 校准中提取探测器增益和基础足跟图案。所得的探测器增益与 SID 无关,而基础足跟图案则由最小和最大 SID 进行参数化。任何 SID 的足跟图案都可以通过投影成像原理从最小 SID 基础足跟图案获得。然后使用投影足跟图案和探测器增益图来构建在特定采集 SID 下所需的系统增益。
该方法用于平面场和解剖体模图像校正的评估。与插值和传统增益校准/校正方法相比,该方法表现出了有希望的改进,将校正误差降低了约 70%和 80%。分离算法能够以小于 2%的误差提取探测器增益和足跟图案,Duo-SID 校正图像显示出整个探测器具有吸引人的均匀背景。
在 SID 变化的环境中,Duo-SID 校正方法大大改进了数字 X 射线成像的传统偏移/增益校正。该技术相对简单,可以很容易地整合到多点增益校准/校正技术中。它为预处理数字 X 射线图像提供了一种有价值的工具,以提高乳房 X 线摄影、胸部和心脏射线照相以及自动计算机辅助诊断放射学的图像质量。
