Research on radon concentration measurement value correction based on FASTLOF and NPSO-BP neural network model

IF 1.6 3区物理与天体物理 Q2 NUCLEAR SCIENCE & TECHNOLOGY Radiation Measurements Pub Date : 2024-07-26 DOI:10.1016/j.radmeas.2024.107257

Qi-Bin Luo , Lei Li , Ya-Xin Yang , Chen Fu , Xiao Huang , Hong-Tao Ning , Yong-Peng Wu

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Abstract

To address the issue of decreased measurement accuracy in radon measurement devices due to the effects of temperature and humidity, a method has been proposed for correcting radon measurement readings based on a FASTLOF (Fast Local Outlier Factor) and NPSO-BP (Normalized Particle Swarm Optimization-Back Propagation) neural network model. The study employed the RAD7 portable radon detector and utilized the FASTLOF, NPSO, and BP neural network algorithms to perform data detection and correlation analysis on the environmental temperature, humidity and instrument readings. A correction model for the measurement data was established and trained to enhance the validity of the instrument's readings. Validation and analysis were conducted using data sets, stable radon concentration measurements in HD-6 multifunctional self-controlled radon chamber, and indoor radon measurement experiments. The experimental results indicate that the model can effectively correct radon concentrations, improve the accuracy and stability of the measurement data, with the maximum relative error not exceeding 8.6%, thus meeting monitoring requirements.

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基于 FASTLOF 和 NPSO-BP 神经网络模型的氡浓度测量值修正研究

为了解决由于温度和湿度的影响而导致氡测量设备的测量精度降低的问题，提出了一种基于 FASTLOF（快速局部离群因子）和 NPSO-BP（归一化粒子群优化-反向传播）神经网络模型的氡测量读数校正方法。研究采用了 RAD7 便携式氡检测仪，并利用 FASTLOF、NPSO 和 BP 神经网络算法对环境温度、湿度和仪器读数进行了数据检测和相关性分析。建立并训练了一个测量数据校正模型，以提高仪器读数的有效性。利用数据集、HD-6 多功能自控氡室的稳定氡浓度测量数据和室内氡测量实验进行了验证和分析。实验结果表明，该模型能有效修正氡浓度，提高测量数据的准确性和稳定性，最大相对误差不超过 8.6%，满足监测要求。

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来源期刊

Radiation Measurements 工程技术-核科学技术

CiteScore

4.10

自引率

20.00%

发文量

116

审稿时长

48 days

期刊介绍： The journal seeks to publish papers that present advances in the following areas: spontaneous and stimulated luminescence (including scintillating materials, thermoluminescence, and optically stimulated luminescence); electron spin resonance of natural and synthetic materials; the physics, design and performance of radiation measurements (including computational modelling such as electronic transport simulations); the novel basic aspects of radiation measurement in medical physics. Studies of energy-transfer phenomena, track physics and microdosimetry are also of interest to the journal. Applications relevant to the journal, particularly where they present novel detection techniques, novel analytical approaches or novel materials, include: personal dosimetry (including dosimetric quantities, active/electronic and passive monitoring techniques for photon, neutron and charged-particle exposures); environmental dosimetry (including methodological advances and predictive models related to radon, but generally excluding local survey results of radon where the main aim is to establish the radiation risk to populations); cosmic and high-energy radiation measurements (including dosimetry, space radiation effects, and single event upsets); dosimetry-based archaeological and Quaternary dating; dosimetry-based approaches to thermochronometry; accident and retrospective dosimetry (including activation detectors), and dosimetry and measurements related to medical applications.