OpenDosimeter: Open Hardware Personal X-ray Dosimeter

arXiv - PHYS - Medical Physics Pub Date : 2024-09-16 DOI:arxiv-2409.09993

Norah Ger, Alice Ku, Jasmyn Lopez, N. Robert Bennett, Jia Wang, Grace Ateka, Enoch Anyenda, Matthias Rosezky, Adam S. Wang, Kian Shaker

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Abstract

We present OpenDosimeter (https://opendosimeter.org/), an open hardware solution for real-time personal X-ray dose monitoring based on a scintillation counter. Using an X-ray sensor assembly (LYSO + SiPM) on a custom board powered by a Raspberry Pi Pico, OpenDosimeter provides real-time feedback (1 Hz), data logging (10 hours), and battery-powered operation. One of the core innovations is that we calibrate the device using $^{241}$Am found in ionization smoke detectors. Specifically, we use the $\gamma$-emissions to spectrally calibrate the dosimeter, then calculate the effective dose from X-ray exposure by compensating for the scintillator absorption efficiency and applying energy-to-dose coefficients derived from tabulated data in the ICRP 116 publication. We demonstrate that this transparent approach enables real-time dose rate readings with a linear response between 0.1-1000 $\mu$Sv/h at $\pm$25% accuracy, tested for energies up to 120 keV. The maximum dose rate readings are limited by pile-up effects when approaching count rate saturation ($\sim$77 kcps at $\sim$13 $\mu$s average pulse processing time). The total component cost for making an OpenDosimeter is <\$100, which, combined with its open design (both hardware and software), enables cost-effective local reproducibility on a global scale. This paper complements the open-source documentation by explaining the underlying technology, the algorithm for dose calculation, and areas for future improvement.

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OpenDosimeter：开放式硬件个人 X 射线剂量计

我们介绍 OpenDosimeter (https://opendosimeter.org/)，这是一种基于闪烁计数器的开放式个人 X 射线剂量实时监测解决方案。OpenDosimeter 在由 Raspberry Pi Pico 驱动的定制电路板上使用 X 射线传感器组件（LYSO + SiPM），提供实时反馈（1 Hz）、数据记录（10 小时）和电池供电操作。我们的核心创新之一是使用电离烟雾探测器中的 $^{241}$Am 对设备进行校准。具体来说，我们使用伽马射线发射来对剂量计进行光谱校准，然后通过补偿闪烁体的吸收效率并应用根据国际放射防护委员会第 116 号出版物中的表格数据得出的能量-剂量系数来计算 X 射线照射的有效剂量。我们证明了这种透明的方法能够实现实时剂量率读数，其线性响应在 0.1-1000 $m\$Sv/h 之间，精度为 $/pm$25%，测试能量高达 120 keV。当接近计数率饱和时，最大剂量率读数受到堆积效应的限制（在平均脉冲处理时间为13秒时，最大剂量率为77 kcps）。制作 OpenDosimeter 的总元件成本小于 100 美元，再加上其开放式设计（包括硬件和软件），可以在全球范围内实现具有成本效益的本地可重复性。本文通过解释底层技术、度量计算算法和未来改进领域，对开源文档进行了补充。

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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arXiv - PHYS - Medical Physics

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