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Autori principali: Choi, Benjamin J., Milsap, Griffin, Scholl, Clara A., Tenore, Francesco, Ogg, Mattson
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.04967
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author Choi, Benjamin J.
Milsap, Griffin
Scholl, Clara A.
Tenore, Francesco
Ogg, Mattson
author_facet Choi, Benjamin J.
Milsap, Griffin
Scholl, Clara A.
Tenore, Francesco
Ogg, Mattson
contents Current machine learning (ML)-based algorithms for filtering electroencephalography (EEG) time series data face challenges related to cumbersome training times, regularization, and accurate reconstruction. To address these shortcomings, we present an ML filtration algorithm driven by a logistic covariance-targeted adversarial denoising autoencoder (TADA). We hypothesize that the expressivity of a targeted, correlation-driven convolutional autoencoder will enable effective time series filtration while minimizing compute requirements (e.g., runtime, model size). Furthermore, we expect that adversarial training with covariance rescaling will minimize signal degradation. To test this hypothesis, a TADA system prototype was trained and evaluated on the task of removing electromyographic (EMG) noise from EEG data in the EEGdenoiseNet dataset, which includes EMG and EEG data from 67 subjects. The TADA filter surpasses conventional signal filtration algorithms across quantitative metrics (Correlation Coefficient, Temporal RRMSE, Spectral RRMSE), and performs competitively against other deep learning architectures at a reduced model size of less than 400,000 trainable parameters. Further experimentation will be necessary to assess the viability of TADA on a wider range of deployment cases.
format Preprint
id arxiv_https___arxiv_org_abs_2501_04967
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publishDate 2025
record_format arxiv
spellingShingle Targeted Adversarial Denoising Autoencoders (TADA) for Neural Time Series Filtration
Choi, Benjamin J.
Milsap, Griffin
Scholl, Clara A.
Tenore, Francesco
Ogg, Mattson
Machine Learning
Current machine learning (ML)-based algorithms for filtering electroencephalography (EEG) time series data face challenges related to cumbersome training times, regularization, and accurate reconstruction. To address these shortcomings, we present an ML filtration algorithm driven by a logistic covariance-targeted adversarial denoising autoencoder (TADA). We hypothesize that the expressivity of a targeted, correlation-driven convolutional autoencoder will enable effective time series filtration while minimizing compute requirements (e.g., runtime, model size). Furthermore, we expect that adversarial training with covariance rescaling will minimize signal degradation. To test this hypothesis, a TADA system prototype was trained and evaluated on the task of removing electromyographic (EMG) noise from EEG data in the EEGdenoiseNet dataset, which includes EMG and EEG data from 67 subjects. The TADA filter surpasses conventional signal filtration algorithms across quantitative metrics (Correlation Coefficient, Temporal RRMSE, Spectral RRMSE), and performs competitively against other deep learning architectures at a reduced model size of less than 400,000 trainable parameters. Further experimentation will be necessary to assess the viability of TADA on a wider range of deployment cases.
title Targeted Adversarial Denoising Autoencoders (TADA) for Neural Time Series Filtration
topic Machine Learning
url https://arxiv.org/abs/2501.04967