Numeric Prediction of the Detail Visibility in Industrial X-Ray Computed Tomography by Human Observers

e-Journal of Nondestructive Testing Pub Date : 2023-08-01 DOI:10.58286/28437

Uwe Ewert, Frank Herold, Holger Roth, Florian Wohlgemuth

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Abstract

Industrial Computed Tomography (iCT) is applied in industry for flaw detection, flaw evaluation and dimensional measurement. This requires the correct experimental system settings for sufficient visibility and detectability of details and structure elements. This is an essential tool for long term monitoring of the detail sensitivity of CT scanners. The visibility of indications by human observers on a monitor in cross sectional 2D CT-images can be estimated from the square root of the visible flaw area, the Contrast to Noise Ratio (CNR) and the Modulation Transfer Function (MTF). The ASTM guide E 1441 describes a more detailed procedure for the determination of the minimum contrast for the visibility of flaws based on three essential functions for the prediction of the visibility of small circular indications in iCT slice images. This is the Contrast Discrimination Function (CDF), the Modulation Transfer Function (MTF) as described in the latest revision of ASTM E 1695, and the Contrast Detail Diagram (CDD). All these functions analyse the contrast as function of the spatial frequency in digital 2D slice images. The functions do not describe, how to calculate the visibility limit for human observers. The concept for the automated calculation of the visibility limit of circular indications in reconstructed slice images is discussed in this paper. It is finally determined from the intersection point of the MTF with the Contrast Detail Diagram, which is the combination of CDF and MTF, and a physiological factor c. The new measurement procedures for the prediction of the detail visibility by MTF and CDD was tested with test phantoms and be verified by modelling and measurements. A Round Robin test was conducted with more than 10 parties to verify the visibility formula and the procedure for determination of the visibility limit from the combination of these functions. A form factor is considered to compare cylinder holes with pore indications. Conclusions will be reported and recommendations will be given for the determination of the correct physiological factor c.

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人类观察者对工业x射线计算机断层扫描细节可见性的数值预测

工业计算机断层扫描技术(iCT)在工业中应用于缺陷检测、缺陷评价和尺寸测量。这需要正确的实验系统设置，以便对细节和结构元素有足够的可见性和可探测性。这是长期监测CT扫描仪细节灵敏度的重要工具。通过可见缺陷区域的平方根、噪声对比比(CNR)和调制传递函数(MTF)，可以估计人类观察者在监视器上看到的二维横断面ct图像的指示性。ASTM指南E 1441描述了一个更详细的程序，用于确定基于三个基本功能的最小对比度的缺陷可见性，用于预测iCT切片图像中小圆形指示的可见性。这是ASTM E 1695最新版本中描述的对比度辨别函数(CDF)、调制传递函数(MTF)和对比度细节图(CDD)。所有这些函数都将数字二维切片图像的对比度作为空间频率的函数进行分析。函数没有描述如何计算人类观察者的可见极限。本文讨论了重建切片图像中圆形指示可见极限自动计算的概念。最后由MTF与对比细节图的交点，即CDF和MTF的结合，以及一个生理因子c来确定细节可见性。用试验模型对MTF和CDD预测细节可见性的新测量方法进行了测试，并通过建模和测量进行了验证。对10多个参与方进行了一轮循环测试，以验证能见度公式和从这些函数的组合中确定能见度限制的程序。考虑将圆柱孔与孔隙指示进行比较的形状因子。将报告结论并给出确定正确生理因子c的建议。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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e-Journal of Nondestructive Testing

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