EVALUATION OF ARTIFICIAL NEURAL NETWORKS EFFECTIVENESS FOR UNFOLDING GAMMA-SPECTRUM OF 137CS

A. Nikitin, E. Mischenko, O. Shurankova
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Abstract

Development of machine learning methods for spectrum processing is one of the most promising ways for gamma- spectrometry automation and accuracy improvement. Effectiveness of fully connected and convolution neural networks for quantitative γ-spectrometry analysis using scintillation detector NaI(Tl) and lead shielding is presented in the article. Semi-synthetic spectrums were used for the models training; the semi-synthetic spectrums are in channels additions of random spectrums measured at a short duration. The analysis shows advantages of artificial neural networks compare to the common analytical method of spectrum unfolding. The mean square error of activity evaluation is 2–4 times lower than the common method if measuring time is equal to 100 s. In highly standardized conditions of measuring, the advantages of convolution neural networks appear with increasing radiation source activity. Validation with sources not used in training of neural networks has shown fully connected and convolution neural networks can have advantages over the standard method when activity of γ-radiation source is relatively high.
人工神经网络对137cs γ谱展开的有效性评价
开发用于光谱处理的机器学习方法是提高伽马能谱自动化和准确性的最有前途的方法之一。本文介绍了全连接和卷积神经网络在利用闪烁检测器NaI(Tl)和铅屏蔽进行定量γ光谱分析中的有效性。半合成光谱用于模型训练;半合成光谱是在短时间内测量的随机光谱的信道加法。分析表明,人工神经网络与常用的频谱展开分析方法相比具有优势。当测量时间为100 s时,活度评价的均方误差比常用方法小2-4倍。在高度标准化的测量条件下,随着辐射源活度的增加,卷积神经网络的优势显现出来。对未用于神经网络训练的源的验证表明,当γ辐射源的活度相对较高时,卷积神经网络比标准方法具有完全连接的优势。
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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