Saved in:
Bibliographic Details
Main Authors: Xu, Xiran, Wang, Bo, Xiao, Boda, Niu, Yadong, Wang, Yiwen, Wu, Xihong, Chen, Jing
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.17024
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909849884819456
author Xu, Xiran
Wang, Bo
Xiao, Boda
Niu, Yadong
Wang, Yiwen
Wu, Xihong
Chen, Jing
author_facet Xu, Xiran
Wang, Bo
Xiao, Boda
Niu, Yadong
Wang, Yiwen
Wu, Xihong
Chen, Jing
contents Researchers have reported high decoding accuracy (>95%) using non-invasive Electroencephalogram (EEG) signals for brain-computer interface (BCI) decoding tasks like image decoding, emotion recognition, auditory spatial attention detection, etc. Since these EEG data were usually collected with well-designed paradigms in labs, the reliability and robustness of the corresponding decoding methods were doubted by some researchers, and they argued that such decoding accuracy was overestimated due to the inherent temporal autocorrelation of EEG signals. However, the coupling between the stimulus-driven neural responses and the EEG temporal autocorrelations makes it difficult to confirm whether this overestimation exists in truth. Furthermore, the underlying pitfalls behind overestimated decoding accuracy have not been fully explained due to a lack of appropriate formulation. In this work, we formulate the pitfall in various EEG decoding tasks in a unified framework. EEG data were recorded from watermelons to remove stimulus-driven neural responses. Labels were assigned to continuous EEG according to the experimental design for EEG recording of several typical datasets, and then the decoding methods were conducted. The results showed the label can be successfully decoded as long as continuous EEG data with the same label were split into training and test sets. Further analysis indicated that high accuracy of various BCI decoding tasks could be achieved by associating labels with EEG intrinsic temporal autocorrelation features. These results underscore the importance of choosing the right experimental designs and data splits in BCI decoding tasks to prevent inflated accuracies due to EEG temporal autocorrelation.
format Preprint
id arxiv_https___arxiv_org_abs_2405_17024
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Beware of Overestimated Decoding Performance Arising from Temporal Autocorrelations in Electroencephalogram Signals
Xu, Xiran
Wang, Bo
Xiao, Boda
Niu, Yadong
Wang, Yiwen
Wu, Xihong
Chen, Jing
Signal Processing
Researchers have reported high decoding accuracy (>95%) using non-invasive Electroencephalogram (EEG) signals for brain-computer interface (BCI) decoding tasks like image decoding, emotion recognition, auditory spatial attention detection, etc. Since these EEG data were usually collected with well-designed paradigms in labs, the reliability and robustness of the corresponding decoding methods were doubted by some researchers, and they argued that such decoding accuracy was overestimated due to the inherent temporal autocorrelation of EEG signals. However, the coupling between the stimulus-driven neural responses and the EEG temporal autocorrelations makes it difficult to confirm whether this overestimation exists in truth. Furthermore, the underlying pitfalls behind overestimated decoding accuracy have not been fully explained due to a lack of appropriate formulation. In this work, we formulate the pitfall in various EEG decoding tasks in a unified framework. EEG data were recorded from watermelons to remove stimulus-driven neural responses. Labels were assigned to continuous EEG according to the experimental design for EEG recording of several typical datasets, and then the decoding methods were conducted. The results showed the label can be successfully decoded as long as continuous EEG data with the same label were split into training and test sets. Further analysis indicated that high accuracy of various BCI decoding tasks could be achieved by associating labels with EEG intrinsic temporal autocorrelation features. These results underscore the importance of choosing the right experimental designs and data splits in BCI decoding tasks to prevent inflated accuracies due to EEG temporal autocorrelation.
title Beware of Overestimated Decoding Performance Arising from Temporal Autocorrelations in Electroencephalogram Signals
topic Signal Processing
url https://arxiv.org/abs/2405.17024