In this work we present an advanced random forest-based machine learning (ML) model, trained and tested on Geant4 simulations. The developed ML model is designed to improve the performance of the hybrid detector for microdosimetry (HDM), a novel hybrid detector recently introduced to augment the microdosimetric information with the track length of particles traversing the microdosimeter. The present work leads to the following improvements of HDM: (i) the detection efficiency is increased up to 100%, filling not detected particles due to scattering within the tracker or non-active regions, (ii) the track reconstruction algorithm precision. Thanks to the ML models, we were able to reconstruct the microdosimetric spectra of both protons and carbon ions at therapeutic energies, predicting the real track length for every particle detected by the microdosimeter. The ML model results have been extensively studied, focusing on non-accurate predictions of the real track lengths. Such analysis has been used to identify HDM limitations and to understand possible future improvements of both the detector and the ML models.

An exploratory study of machine learning techniques applied to therapeutic energies particle tracking in microdosimetry using the novel hybrid detector for microdosimetry (HDM) / Missiaggia, M.; Pierobon, E.; La Tessa, C.; Cordoni, F. G.. - In: PHYSICS IN MEDICINE & BIOLOGY. - ISSN 1361-6560. - 67:18(2022), p. 185002. [10.1088/1361-6560/ac8af3]

An exploratory study of machine learning techniques applied to therapeutic energies particle tracking in microdosimetry using the novel hybrid detector for microdosimetry (HDM)

Missiaggia M.
Primo
;
Pierobon E.
Secondo
;
La Tessa C.
Penultimo
;
Cordoni F. G.
Ultimo
2022-01-01

Abstract

In this work we present an advanced random forest-based machine learning (ML) model, trained and tested on Geant4 simulations. The developed ML model is designed to improve the performance of the hybrid detector for microdosimetry (HDM), a novel hybrid detector recently introduced to augment the microdosimetric information with the track length of particles traversing the microdosimeter. The present work leads to the following improvements of HDM: (i) the detection efficiency is increased up to 100%, filling not detected particles due to scattering within the tracker or non-active regions, (ii) the track reconstruction algorithm precision. Thanks to the ML models, we were able to reconstruct the microdosimetric spectra of both protons and carbon ions at therapeutic energies, predicting the real track length for every particle detected by the microdosimeter. The ML model results have been extensively studied, focusing on non-accurate predictions of the real track lengths. Such analysis has been used to identify HDM limitations and to understand possible future improvements of both the detector and the ML models.
2022
18
Missiaggia, M.; Pierobon, E.; La Tessa, C.; Cordoni, F. G.
An exploratory study of machine learning techniques applied to therapeutic energies particle tracking in microdosimetry using the novel hybrid detector for microdosimetry (HDM) / Missiaggia, M.; Pierobon, E.; La Tessa, C.; Cordoni, F. G.. - In: PHYSICS IN MEDICINE & BIOLOGY. - ISSN 1361-6560. - 67:18(2022), p. 185002. [10.1088/1361-6560/ac8af3]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11572/377027
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