Efficient Real-Time Isotope Identification on SoC FPGA

Efficient Real-Time Isotope Identification on SoC FPGA

Efficient real-time isotope identification is a critical challenge in nuclear spectroscopy, with important applications such as radiation monitoring, nuclear waste management, and medical imaging. This work presents a novel approach for isotope classification using a System-on-Chip FPGA, integrating...

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Bibliographic Details
Main Authors: Katherine Guerrero-Morejón, José María Hinojo-Montero, Jorge Jiménez-Sánchez, Cristian Rocha-Jácome, Ramón González-Carvajal, Fernando Muñoz-Chavero
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Sensors
Subjects:
nuclear spectroscopy
isotope classification
principal component analysis
random forest
real-time processing
SoC FPGA
Online Access:https://www.mdpi.com/1424-8220/25/12/3758
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Summary:Efficient real-time isotope identification is a critical challenge in nuclear spectroscopy, with important applications such as radiation monitoring, nuclear waste management, and medical imaging. This work presents a novel approach for isotope classification using a System-on-Chip FPGA, integrating hardware-accelerated principal component analysis (PCA) for feature extraction and a software-based random forest classifier. The system leverages the FPGA’s parallel processing capabilities to implement PCA, reducing the dimensionality of digitized nuclear signals and optimizing computational efficiency. A key feature of the design is its ability to perform real-time classification without storing ADC samples, directly processing nuclear pulse data as it is acquired. The extracted features are classified by a random forest model running on the embedded microprocessor. PCA quantization is applied to minimize power consumption and resource usage without compromising accuracy. The experimental validation was conducted using datasets from high-resolution pulse-shape digitization, including closely matched isotope pairs (<sup>12</sup>C/<sup>13</sup>C, <sup>36</sup>Ar/<sup>40</sup>Ar, and <sup>80</sup>Kr/<sup>84</sup>Kr). The results demonstrate that the proposed SoC FPGA system significantly outperforms conventional software-only implementations, reducing latency while maintaining classification accuracy above 98%. This study provides a scalable, precise, and energy-efficient solution for real-time isotope identification.
ISSN:1424-8220

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