Validation of simulated training sets using a convolutional neural network for isotope identification in urban environments
Luke Lee-Brewin, Ryan Holden, Caroline Shenton-Taylor, Cebastien Joel Guembou Shouop, Cebastien Joel Guembou Shouop, Cebastien Joel Guembou Shouop

TL;DR
This paper validates a method to simulate gamma spectra for isotope identification in urban settings using a convolutional neural network, achieving high accuracy.
Contribution
A validated method for generating simulated gamma spectra datasets for isotope identification in urban environments is introduced.
Findings
A convolutional neural network achieved 96% accuracy on simulated data and 89.8% on real SIGMA dataset spectra.
Five clusters of spectra were identified as containing single isotopes, suitable for training.
The method is validated as effective for generating training data for isotope identification.
Abstract
Real-time isotope identification in urban environments can aid law enforcement by providing additional information about the nature of a potential threat. Neural networks have shown promise in isotope identification but the large range of potential isotopes, activities and shielding in uncontrolled urban environments makes creating a representative training set challenging. In this work, a method of generating gamma spectra datasets without requiring radioactive sources is validated with representative data. Simulated spectra are added to background radiation taken from a large dataset of unlabelled gamma spectra (the SIGMA dataset) collected in London by AWE Nuclear Security Technologies. A testing set of 12748 spectra was extracted from the SIGMA dataset by applying k-means clustering to the 10% of spectra with the highest gross counts. Manual inspection and labelling of a subset of…
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Taxonomy
TopicsNuclear Physics and Applications · Radiation Detection and Scintillator Technologies · Radioactivity and Radon Measurements
