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Physics-Based Machine Learning Methods for U-235 Forensics Signatures

by Nageswara S Rao, Caleb J Redding, David G Abrecht, Jennifer L Ladd-lively
Publication Type
Conference Paper
Book Title
INMM Annual Meeting Proceedings
Publication Date
Page Numbers
1 to 8
Publisher Location
Illinois, United States of America
Conference Name
65th INMM Annual Meeting
Conference Location
Portland, Oregon, United States of America
Conference Sponsor
INMM
Conference Date
-

Signatures of low-intensity U-235 sources have been recently studied by utilizing a variety of machine learning (ML) classifiers using features derived from gamma spectral measurements collected under structured campaigns. Several ML classifiers, such as ensemble of tress and classification trees, revealed misleadingly-optimistic training error due to over-fitting, and furthermore, their performance is not directly relatable to the physical properties due to their data-driven, opaque designs. We present a regression-based ML method that first estimates the inverse distance to the source and then utilizes a threshold to infer its presence, by representing the background
as a source located at an infinite distance. For the inverse distance estimation, we study the ensemble of trees and Gaussian process regression methods, and a hyper parameter auto-tuning and selection method that employs five regression estimators. These methods avoid the over-fitting observed in several ML classifiers, while providing the classification error nearly comparable to them based on independent test data. Their error is directly related to estimates of the inverse physical distance to source, and the precision of error determines the seperability property that determines the false alarm and missed detection rates. The property of monotonic decrease of the source strength with increasing detector distance combined with Poisson distribution of measurements is utilized to analytically validate these methods by deriving the generalization equations of underlying regression methods.