TY - GEN
T1 - An Extended Computer Aided Diagnosis System for Robust BCI Applications
AU - Yu, Xiaojun
AU - Aziz, Muhammad Zulkifal
AU - Hou, Yiyan
AU - Li, Haopeng
AU - Lv, Jialin
AU - Jamil, Mudasir
N1 - Publisher Copyright:
© 2021 IEEE.
PY - 2021
Y1 - 2021
N2 - Electroencephalogram (EEG) signal processing is the pivotal procedure to decipher meaningful information from the lowkey signals to drive practical applications. This paper investigates an EEG signal processing model, which utilizes three EEG electrode combinations, six feature extraction methods, and seven classification algorithms together with an improved empirical Fourier decomposition (IEFD) for motor imagery (MI) EEG signal analysis. The feasibility of IEFD is further validated on a large GigaDB dataset with 52 participants along with the BCI competition III datasets IVa and IVb. Results reveal that IEFD mechanism yields robust classification outcomes when coupled with 18 electrodes combination, welch PSD features, and multilayer perceptron classifier, and the best classification accuracy of 99.52%, 99.35%, 98.89%, 99.52%, 100%, and 93.19% is achieved for dataset IVa and IVb subjects, respectively. Moreover, the GigaDB dataset yields an average classification accuracy, sensitivity, specificity, and fl-score of 83.84%, 83.71%, 83.98%, and 83.80% accordingly. Results compared with previous studies conclude that the proposed model improves the average classification accuracy by 16.6%. Such promising findings conclude that the proposed IEFD method is robust and adaptive for MI EEG signals classification, independent of subject-To-subject variance for multiple datasets.
AB - Electroencephalogram (EEG) signal processing is the pivotal procedure to decipher meaningful information from the lowkey signals to drive practical applications. This paper investigates an EEG signal processing model, which utilizes three EEG electrode combinations, six feature extraction methods, and seven classification algorithms together with an improved empirical Fourier decomposition (IEFD) for motor imagery (MI) EEG signal analysis. The feasibility of IEFD is further validated on a large GigaDB dataset with 52 participants along with the BCI competition III datasets IVa and IVb. Results reveal that IEFD mechanism yields robust classification outcomes when coupled with 18 electrodes combination, welch PSD features, and multilayer perceptron classifier, and the best classification accuracy of 99.52%, 99.35%, 98.89%, 99.52%, 100%, and 93.19% is achieved for dataset IVa and IVb subjects, respectively. Moreover, the GigaDB dataset yields an average classification accuracy, sensitivity, specificity, and fl-score of 83.84%, 83.71%, 83.98%, and 83.80% accordingly. Results compared with previous studies conclude that the proposed model improves the average classification accuracy by 16.6%. Such promising findings conclude that the proposed IEFD method is robust and adaptive for MI EEG signals classification, independent of subject-To-subject variance for multiple datasets.
KW - biomedical signals processing
KW - Brain-computer interface
KW - electroencephalogram
KW - em-pirical Fourier decomposition
UR - http://www.scopus.com/inward/record.url?scp=85125172979&partnerID=8YFLogxK
U2 - 10.1109/ICICN52636.2021.9673818
DO - 10.1109/ICICN52636.2021.9673818
M3 - 会议稿件
AN - SCOPUS:85125172979
T3 - 2021 IEEE 9th International Conference on Information, Communication and Networks, ICICN 2021
SP - 475
EP - 480
BT - 2021 IEEE 9th International Conference on Information, Communication and Networks, ICICN 2021
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 9th IEEE International Conference on Information, Communication and Networks, ICICN 2021
Y2 - 25 November 2021 through 28 November 2021
ER -