A machine learning framework for accurate and robust analysis of radiation detector pulses

IF 1.4 3区物理与天体物理 Q3 INSTRUMENTS & INSTRUMENTATION

Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment Pub Date : 2025-09-03 DOI:10.1016/j.nima.2025.170971

Bashir Sadeghi, Dustin Scriven, Aaron Chester, Ronald Fox, Sean Liddick, Giordano Cerizza

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引用次数: 0

Abstract

The microscopic properties of atomic nuclei are used to study various scientific questions. They are essential for understanding the fundamental forces of nature and the chemical evolution of the universe. Detecting decay radiation from radioactive nuclei makes it possible to probe these fundamental nuclear properties. Detector waveform traces may contain additional information about the radiation. Generally, advanced signal processing techniques are needed to extract this additional information, often involving fitting the waveform with model response functions using non-linear least-squares optimization with second-order gradient methods. While this is a powerful technique, it is also computationally expensive, leading to slow processing time, which scales with the volume of data. To address this problem, we have developed a machine learning (ML) approach that infers the characteristics of traces from a model detector response function. In particular, we are interested in classifying whether a single recorded trace consists of one or two pulse constituents and estimating the pulse parameters. Our proposed ML method can precisely extract the pulses’ parameters, such as energy and timing information, and accurately classify the pulse multiplicity of a trace. Unlike non-learning-based approaches, our ML approach uses neural networks that are significantly faster at inference, as they do not require any optimization during this stage. The source code and raw data supporting this work are available at https://github.com/sadeghi-bashir/SAEFit.

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用于精确和鲁棒分析辐射探测器脉冲的机器学习框架

原子核的微观性质被用来研究各种科学问题。它们对于理解自然界的基本力量和宇宙的化学演化是必不可少的。探测放射性原子核的衰变辐射使探测这些基本的核性质成为可能。探测器波形迹线可能包含有关辐射的附加信息。通常，需要先进的信号处理技术来提取这些附加信息，通常涉及使用非线性最小二乘优化和二阶梯度方法将波形与模型响应函数拟合。虽然这是一种强大的技术，但它在计算上也很昂贵，导致处理时间缓慢，并且随着数据量的增加而增加。为了解决这个问题，我们开发了一种机器学习（ML）方法，可以从模型检测器响应函数中推断出轨迹的特征。特别地，我们感兴趣的是分类单个记录的迹线是由一个还是两个脉冲成分组成，并估计脉冲参数。我们提出的机器学习方法可以精确地提取脉冲的能量和时间信息等参数，并准确地分类一条轨迹的脉冲多重性。与非基于学习的方法不同，我们的机器学习方法使用的神经网络在推理方面明显更快，因为它们在此阶段不需要任何优化。支持这项工作的源代码和原始数据可在https://github.com/sadeghi-bashir/SAEFit上获得。

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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来源期刊

Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment 物理-光谱学

CiteScore

3.20

自引率

21.40%

发文量

787

审稿时长

1 months

期刊介绍： Section A of Nuclear Instruments and Methods in Physics Research publishes papers on design, manufacturing and performance of scientific instruments with an emphasis on large scale facilities. This includes the development of particle accelerators, ion sources, beam transport systems and target arrangements as well as the use of secondary phenomena such as synchrotron radiation and free electron lasers. It also includes all types of instrumentation for the detection and spectrometry of radiations from high energy processes and nuclear decays, as well as instrumentation for experiments at nuclear reactors. Specialized electronics for nuclear and other types of spectrometry as well as computerization of measurements and control systems in this area also find their place in the A section. Theoretical as well as experimental papers are accepted.