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Main Authors: Wang, Siwen, Zhang, Shitou, Chen, Wan-Lin, Truong, Dung, Jung, Tzyy-Ping
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.23042
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author Wang, Siwen
Zhang, Shitou
Chen, Wan-Lin
Truong, Dung
Jung, Tzyy-Ping
author_facet Wang, Siwen
Zhang, Shitou
Chen, Wan-Lin
Truong, Dung
Jung, Tzyy-Ping
contents Recent advancements in Large Language Models have inspired the development of foundation models across various domains. In this study, we evaluate the efficacy of Large EEG Models (LEMs) by fine-tuning LaBraM, a state-of-the-art foundation EEG model, on a real-world stress classification dataset collected in a graduate classroom. Unlike previous studies that primarily evaluate LEMs using data from controlled clinical settings, our work assesses their applicability to real-world environments. We train a binary classifier that distinguishes between normal and elevated stress states using resting-state EEG data recorded from 18 graduate students during a class session. The best-performing fine-tuned model achieves a balanced accuracy of 90.47% with a 5-second window, significantly outperforming traditional stress classifiers in both accuracy and inference efficiency. We further evaluate the robustness of the fine-tuned LEM under random data shuffling and reduced channel counts. These results demonstrate the capability of LEMs to effectively process real-world EEG data and highlight their potential to revolutionize brain-computer interface applications by shifting the focus from model-centric to data-centric design.
format Preprint
id arxiv_https___arxiv_org_abs_2505_23042
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle From Theory to Application: Fine-Tuning Large EEG Model with Real-World Stress Data
Wang, Siwen
Zhang, Shitou
Chen, Wan-Lin
Truong, Dung
Jung, Tzyy-Ping
Machine Learning
Artificial Intelligence
Recent advancements in Large Language Models have inspired the development of foundation models across various domains. In this study, we evaluate the efficacy of Large EEG Models (LEMs) by fine-tuning LaBraM, a state-of-the-art foundation EEG model, on a real-world stress classification dataset collected in a graduate classroom. Unlike previous studies that primarily evaluate LEMs using data from controlled clinical settings, our work assesses their applicability to real-world environments. We train a binary classifier that distinguishes between normal and elevated stress states using resting-state EEG data recorded from 18 graduate students during a class session. The best-performing fine-tuned model achieves a balanced accuracy of 90.47% with a 5-second window, significantly outperforming traditional stress classifiers in both accuracy and inference efficiency. We further evaluate the robustness of the fine-tuned LEM under random data shuffling and reduced channel counts. These results demonstrate the capability of LEMs to effectively process real-world EEG data and highlight their potential to revolutionize brain-computer interface applications by shifting the focus from model-centric to data-centric design.
title From Theory to Application: Fine-Tuning Large EEG Model with Real-World Stress Data
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2505.23042