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使用基于拼接的探测器技术和智能重建算法检索质子束信息。

Retrieving Proton Beam Information Using Stitching-Based Detector Technique and Intelligent Reconstruction Algorithms.

作者信息

Hsieh Chi-Wen, Chang Hong-Liang, Huang Yi-Hsiang, Lee Ming-Che, Wang Yu-Jen

机构信息

Department of Electrical Engineering , National Chung Cheng University, Chiayi 621301, Taiwan.

Department of Electrical Engineering, National Chiayi University, Chiayi 600355, Taiwan.

出版信息

Sensors (Basel). 2025 Aug 12;25(16):4985. doi: 10.3390/s25164985.

DOI:10.3390/s25164985
PMID:40871848
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12390188/
Abstract

In view of the great need for quality assurance in radiotherapy, this paper proposes a stitching-based detector (SBD) technique and a set of intelligent algorithms that can reconstruct the information of projected particle beams. The reconstructed information includes the intensity, sigma value, and location of the maximum intensity of the beam under test. To verify the effectiveness of the proposed technique and algorithms, this research study adopts the pencil beam scanning (PBS) form of proton beam therapy (PBT) as an example. Through the SBD technique, it is possible to utilize 128 × 128 ionization chambers, which constitute an ionization plate of 25.6 cm, with an acceptable number of 4096 analog-to-digital converters (ADCs) and a resolution of 0.25 mm. Through simulation, the proposed SBD technique and intelligent algorithms are proven to exhibit satisfactory and practical performance. By using two kinds of maximum intensity definitions, sigma values ranging from 10 to 120, and two definitions in an erroneous case, the maximum error rate is found to be 3.95%, which is satisfactorily low. Through analysis, this research study discovers that most errors occur near the symmetrical and peripheral boundaries. Furthermore, lower sigma values tend to aggravate the error rate because the beam becomes more like an ideal particle, which leads to greater imprecision caused by symmetrical sensor structures as its sigma is reduced. However, because proton beams are normally not projected onto the border region of the sensed area, the error rate in practice can be expected to be even lower. Although this research study adopts PBS PBT as an example, the proposed SBD technique and intelligent algorithms are applicable to any type of particle beam reconstruction in the field of radiotherapy, as long as the particles under analysis follow a Gaussian distribution.

摘要

鉴于放射治疗中对质量保证的巨大需求,本文提出了一种基于拼接的探测器(SBD)技术和一组智能算法,可重建投射粒子束的信息。重建的信息包括被测束流的强度、西格玛值和最大强度位置。为验证所提技术和算法的有效性,本研究以质子束治疗(PBT)的笔形束扫描(PBS)形式为例。通过SBD技术,可以利用128×128个电离室,这些电离室构成一个25.6 cm的电离板,配备4096个模数转换器(ADC),分辨率为0.25 mm。通过模拟,所提SBD技术和智能算法被证明具有令人满意的实际性能。使用两种最大强度定义、西格玛值范围从10到120以及一种错误情况下的两种定义,发现最大错误率为3.95%,该值低到令人满意。通过分析,本研究发现大多数错误发生在对称边界和周边边界附近。此外,较低的西格玛值往往会加剧错误率,因为束流变得更像理想粒子,随着其西格玛值降低,对称传感器结构会导致更大的不精确性。然而,由于质子束通常不会投射到传感区域的边界区域,实际中的错误率预计会更低。尽管本研究以PBS PBT为例,但只要所分析的粒子遵循高斯分布,所提SBD技术和智能算法适用于放射治疗领域的任何类型的粒子束重建。

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