Development and Validation of an X-ray Imaging Detector for Digital Radiography at Low Resolution

Journal of Nuclear Physics, Material Sciences, Radiation and Applications Pub Date : 2020-02-28 DOI:10.15415/jnp.2020.72023

A. R. Reyes, G. H. Corral, Elsa G. Ordoñez Casanova, H. Mandujano, Uzziel Caldiño Herrera

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Abstract

Digital X-ray detectors are required in different sciences and applications, however many high quality devices are expensive although high-resolution images are not always required. We present an easy way to build a detector capable of forming X-ray digital images and video with a very large area (18×18 cm2). The detector is formed by three main components: scintillator, optics lenses and CCD sensor. Basically, the device converts the X-rays into visible light which is then collected by the CCD sensor. The scintillator is Gadox type, from Carestream®, 18×18 cm2, regular type, lambda 547 nm. The optics lenses are generic, with manual focus and widely visual field. The CCD sensor has a size of 1/3″, 752 × 582 pixels, monochrome, 20 FPS, 12 bits ADC and pixel size of 3.8 μm. With the built detector and an X-ray source, we formed an X-ray imaging detection system to generate digital radiographs of biological or inert objects-examples are given-, as well as real-time X-ray video. Additionally, the spatial resolution limit was measured in terms of Modulation Transfer Function by the method of opaque edge from a lead sheet with a result of 1.1 Lp/mm. Finally using a filter, the focal spot of the X-ray source is measured, resulting in a diameter of 0.9 mm (FWHM).

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低分辨率数字x射线成像探测器的研制与验证

数字x射线探测器在不同的科学和应用中都需要，然而许多高质量的设备都很昂贵，尽管并不总是需要高分辨率的图像。我们提出了一种简单的方法来建立一个探测器，能够形成一个非常大的面积(18×18 cm2)的x射线数字图像和视频。该探测器主要由闪烁体、光学透镜和CCD传感器三部分组成。基本上，该设备将x射线转换成可见光，然后由CCD传感器收集。闪烁体为Gadox型，来自Carestream®，18×18 cm2，常规型，λ 547 nm。光学镜头为通用型，手动对焦，视野宽广。CCD传感器尺寸为1/3″，752 × 582像素，单色，20fps, 12位ADC，像素尺寸为3.8 μm。利用内置的探测器和x射线源，我们形成了一个x射线成像检测系统，以生成生物或惰性物体的数字x射线照片-给出了示例-以及实时x射线视频。此外，采用导联片不透明边缘法，用调制传递函数测量了空间分辨率极限，结果为1.1 Lp/mm。最后利用滤光片测量x射线源的焦点光斑，得到直径0.9 mm (FWHM)。

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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Journal of Nuclear Physics, Material Sciences, Radiation and Applications

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