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Main Authors: Liu, Haoran, Li, Peng, Liu, Ming-Zhe, Wang, Kai-Ming, Zuo, Zhuo, Liu, Bing-Qi
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2305.18205
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author Liu, Haoran
Li, Peng
Liu, Ming-Zhe
Wang, Kai-Ming
Zuo, Zhuo
Liu, Bing-Qi
author_facet Liu, Haoran
Li, Peng
Liu, Ming-Zhe
Wang, Kai-Ming
Zuo, Zhuo
Liu, Bing-Qi
contents This study utilized the Tempotron, a robust classifier based on a third-generation neural network model, for pulse shape discrimination. By eliminating the need for manual feature extraction, the Tempotron model can process pulse signals directly, generating discrimination results based on prior knowledge. The study performed experiments using GPU acceleration, resulting in over 500 times faster compared to the CPU-based model, and investigated the impact of noise augmentation on the Tempotron performance. Experimental results substantiated that Tempotron serves as a formidable classifier, adept at accomplishing high discrimination accuracy on both AmBe and time-of-flight PuBe datasets. Furthermore, analyzing the neural activity of Tempotron during training shed light on its learning characteristics and aided in selecting its hyperparameters. Moreover, the study addressed the constraints and potential avenues for future development in utilizing the Tempotron for pulse shape discrimination. The dataset used in this study and the GPU-based Tempotron are publicly available on GitHub at https://github.com/HaoranLiu507/TempotronGPU.
format Preprint
id arxiv_https___arxiv_org_abs_2305_18205
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Pulse shape discrimination based on the Tempotron: a powerful classifier on GPU
Liu, Haoran
Li, Peng
Liu, Ming-Zhe
Wang, Kai-Ming
Zuo, Zhuo
Liu, Bing-Qi
Signal Processing
Machine Learning
Nuclear Experiment
This study utilized the Tempotron, a robust classifier based on a third-generation neural network model, for pulse shape discrimination. By eliminating the need for manual feature extraction, the Tempotron model can process pulse signals directly, generating discrimination results based on prior knowledge. The study performed experiments using GPU acceleration, resulting in over 500 times faster compared to the CPU-based model, and investigated the impact of noise augmentation on the Tempotron performance. Experimental results substantiated that Tempotron serves as a formidable classifier, adept at accomplishing high discrimination accuracy on both AmBe and time-of-flight PuBe datasets. Furthermore, analyzing the neural activity of Tempotron during training shed light on its learning characteristics and aided in selecting its hyperparameters. Moreover, the study addressed the constraints and potential avenues for future development in utilizing the Tempotron for pulse shape discrimination. The dataset used in this study and the GPU-based Tempotron are publicly available on GitHub at https://github.com/HaoranLiu507/TempotronGPU.
title Pulse shape discrimination based on the Tempotron: a powerful classifier on GPU
topic Signal Processing
Machine Learning
Nuclear Experiment
url https://arxiv.org/abs/2305.18205