Exploring Deep Learning Models for EEG Neural Decoding

Laurits Dixen; Stefan Heinrich; Paolo Burelli

doi:10.1007/978-3-031-82487-6_12

Exploring Deep Learning Models for EEG Neural Decoding

Laurits Dixen, Stefan Heinrich, Paolo Burelli

Research output: Conference Article in Proceeding or Book/Report chapter › Article in proceedings › Research › peer-review

Abstract

Neural decoding is an important method in cognitive neuroscience that aims to decode brain representations from recorded neural
activity using a multivariate machine learning model. The THINGS initiative provides a large EEG dataset of 46 subjects watching rapidly
shown images. Here, we test the feasibility of using this method for decoding high-level object features using recent deep learning models. We create a derivative dataset from this of living vs non-living entities test 15 different deep learning models with 5 different architectures and compare to a SOTA linear model. We show that the linear model is not able to solve the decoding task, while almost all the deep learning models are successful, suggesting that in some cases non-linear models are needed to decode neural representations. We also run a comparative study of the models’ performance on individual object categories, and suggest how
artificial neural networks can be used to study brain activity.

Original language	English
Title of host publication	International Symposium on Artificial Intelligence and Neuroscience
Number of pages	13
Publisher	Springer
Publication date	2025
Pages	162-175
DOIs	https://doi.org/10.1007/978-3-031-82487-6_12
Publication status	Published - 2025

Series	Lecture Notes in Computer Science
ISSN	0302-9743

Keywords

EEG
Neural Decoding
Deep Learning
THINGS
Benchmark

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10.1007/978-3-031-82487-6_12

Cite this

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title = "Exploring Deep Learning Models for EEG Neural Decoding",

abstract = "Neural decoding is an important method in cognitive neuroscience that aims to decode brain representations from recorded neuralactivity using a multivariate machine learning model. The THINGS initiative provides a large EEG dataset of 46 subjects watching rapidlyshown images. Here, we test the feasibility of using this method for decoding high-level object features using recent deep learning models. We create a derivative dataset from this of living vs non-living entities test 15 different deep learning models with 5 different architectures and compare to a SOTA linear model. We show that the linear model is not able to solve the decoding task, while almost all the deep learning models are successful, suggesting that in some cases non-linear models are needed to decode neural representations. We also run a comparative study of the models{\textquoteright} performance on individual object categories, and suggest howartificial neural networks can be used to study brain activity.",

keywords = "EEG, Neural Decoding, Deep Learning, THINGS, Benchmark",

author = "Laurits Dixen and Stefan Heinrich and Paolo Burelli",

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Exploring Deep Learning Models for EEG Neural Decoding. / Dixen, Laurits ; Heinrich, Stefan ; Burelli, Paolo.
International Symposium on Artificial Intelligence and Neuroscience. Springer, 2025. p. 162-175 (Lecture Notes in Computer Science).

Research output: Conference Article in Proceeding or Book/Report chapter › Article in proceedings › Research › peer-review

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KW - Benchmark

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Exploring Deep Learning Models for EEG Neural Decoding

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Keywords

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