评估福岛第一核电站分布式源的三维伽马射线成像技术

K. Knecht, D. Hellfeld, R. Pavlovsky, B. Quiter, T. Joshi, T. Torii, Y. Furuta, K. Vetter
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引用次数: 1

摘要

便携式辐射探测系统可以配备环境传感器,通过一种称为场景数据融合(SDF)的方法,允许自由移动的3D伽马射线源映射和成像。上下文传感器提供的场景信息可用于实现3D映射和约束伽马射线图像重建,以提高精度和计算效率。SDF可以成为广泛的放射性和核安全和安保应用的有用工具,例如用于污染修复的辐射测绘。为了演示SDF的应用,我们在2011年3月福岛第一核电站事故后的修复工作中,将一种集成了环境传感器的市售探测器北极灯(Polaris-Lamp)随身携带到一个停车场。为了检测和绘制车辆潜在污染的地图,我们将近距离测绘和康普顿成像技术应用于一系列短期测量中收集的数据,每个测量覆盖停车场的不同区域。邻近映射成功地识别了哪些车辆受到污染,但康普顿成像在分布式污染的基础上进一步提高了对关键车辆特征的强度定位,证明了SDF在未知分布式源环境辐射映射中的实用性。将多个重建图拼接在一起的方法也得到了发展,从而可以创建全球一致的大面积辐射图。这里介绍的工作说明了SDF与环境传感器增强的商业辐射探测和成像系统的效用,该系统以手持便携式格式部署,可以在几分钟内有效地绘制扩展区域并定位辐射污染,这是使用手持便携式辐射探测器或静态部署的伽马射线成像仪的传统方法无法实现的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluating 3D Gamma-ray Imaging Techniques for Distributed Sources at the Fukushima Daiichi Nuclear Power Station
Portable radiation detection systems can be equipped with contextual sensors to allow free-moving 3D gamma-ray source mapping and imaging through a method called scene data fusion (SDF). The scene information provided by the contextual sensors can be used to enable 3D mapping and constrain gamma-ray image reconstruction to improve accuracy and computational efficiency. SDF can be a useful tool in a wide range of radiological and nuclear safety and security applications such as radiation mapping for contamination remediation. To demonstrate SDF for this application, Polaris-Lamp,a commercially available detector that has been integrated with contextual sensors, was hand-carried in a parking lot containing vehicles used during remediation efforts following the March 2011 Fukushima Daiichi Nuclear Power Station accident. In order to detect and map potential contamination of the vehicles, proximity mapping and Compton imaging techniques have been applied to data collected over a series of short measurements, each covering different areas of the parking lot. Proximity mapping successfully identified which vehicles are contaminated, but Compton imaging further improved localization of intensity to key vehicle features on top of distributed contamination, demonstrating the utility of SDF in radiation mapping of unknown distributed source environments. Methods to stitch multiple reconstructions together were also developed, allowing the creation of large area radiation maps that are globally consistent. The work presented here illustrates the utility of SDF with an contextual-sensor enhanced commercial radiation detection and imaging system deployed in a hand-portable format to effectively map extended areas and localize radiological contamination within minutes which is impossible to achieve with conventional means with hand-portable radiation detectors or statically deployed gamma-ray imagers.
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