EEG Signal Feature Extraction and Classification for Epilepsy Detection

Dalila Cherifi, Noussaiba Falkoun, Ferial Ouakouak, Larbi Boubchir, Amine Nait-Ali

Abstract


Epilepsy is a neurological disorder of the central nervous system, characterized by sudden seizures caused by abnormal electrical discharges in the brain. Electroencephalogram (EEG) is the most common technique  used for Epilepsy diagnosis.  Generally, it is done by the manual inspection of the EEG recordings of  active seizure periods (ictal). Several techniques have been proposed throughout the years to automate this process. In this study, we have developed three different approaches to extract  features from the filtered EEG signals. The first approach was to extract eight statistical features directly from the time-domain signal. In the second approach, we have used only the frequency domain information by applying the Discrete Cosine Transform (DCT) to the EEG signals then extracting two statistical features from the lower coefficients. In the last approach, we have used a tool that combines both time and frequency domain  information, which is the Discrete Wavelet Transform (DWT). Six different wavelet families have been tested with  their different orders resulting in 37 wavelets. The first three decomposition levels were tested with every wavelet. Instead of feeding the coefficients directly to the classifier, we summarized  them in 16 statistical features. The extracted features are then fed to three different classifiers k-Nearest Neighbor (k-NN), Support Vector Machine (SVM), and Artificial Neural Network (ANN) to perform two binary classification scenarios: healthy versus epileptic(mainly from interictal activity),and seizure-free versus ictal. We have  used a benchmark database, the Bonn database, which consists of five different sets. In the first scenario, we have taken six different combinations of the available data. While in the second scenario, we have taken five combinations. For Epilepsy detection  (healthy vs epileptic), the first approach performed badly. Using the DCT improved the results, but the best accuracies were  obtained with the DWT-based approach. For seizure detection, the three methods performed quite well. However, the third  method had the best performance and was better than many state-of-the-art methods in terms of accuracy. After carrying out  the experiments on the whole EEG signal, we separated the five rhythms and applied the DWT on them with the Daubechies7(db7) wavelet for feature extraction. We have observed that close accuracies to those recorded before can be achieved with only the Delta rhythm in the first scenario (Epilepsy detection) and the Beta rhythm in the second scenario  (seizure detection).


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References


Mayo clinic (n.d.) Epilepsy.

Available at: https://www.mayoclinic.org/diseases-conditions/ epilepsy/diagnosis-treatment/drc-20350098 (Access date: 06-2020).

Gandhi, T., Panigrahi, B. K., & Anand, S. A comparative study of wavelet families for EEG signal classification. Neurocomputing, Vol 74(17), pp. 3051-3057, 2011.

Ullah, I., Hussain, M., Qazi, E. and Aboalsamh, H. An Automated System for Epilepsy Detection using EEG Brain Signals based on Deep Learning Approach. Expert Systems with Applications, Vol.107, pp.61–71, Octobre 2018.

Availableat: http://dx.doi.org/10.1016/j.eswa.2018.04.021.

Nicolaou, N. and Georgia, J. Detection of epileptic electroencephalogram based on permutation entropy and support vector machines. Expert Systems with Applications’, Vol. 39(1), pp. 202-209, 2012.

Available at: https://doi.org/10.1016%2Fj.eswa.2011.07.008

Parvez, M.Z. and Paul, M. Features Extraction and Classification for Ictal and Interictal EEG Signals using EMD and DCT. 15th International Conference on Computer and Information Technology (ICCIT), Chittagong, pp.132-137, Dec., 2012.

Available at: http://dx.doi.org/10.1109/iccitechn.2012.6509719

Bajaj, V. and Pachori, R.B. Epileptic seizure detection based on the instantaneous area of analytic intrinsic mode functions of EEG signals. Biomedical Engineering Letters, Vol.3(1), pp.17–21, 2013.

Sharaf, Ahmed I., Mohamed, A. and El-Henawy, Ibrahim M. An Automated Approach for Epilepsy Detection Based on Tunable Q-Wavelet and Firefly Feature Selection Algorithm. International Journal of Biomedical Imaging. Vol.2018, pp.1–12, Sep.2018.

Martis, R.J., Acharya, U.R., Tan, J.H. et al. Application of intrinsic time-scale decomposition (ITD) to EEG signals for automated seizure prediction. International Journal of Neural Systems. Vol.23(5), pp. 1557–1565, 2013.

Ahammad, N., Fathima, T., & Joseph, P. (2014). Detection of Epileptic Seizure Event and Onset Using EEG. BioMed Research International, pp.1–7, 2014.

Available at: http://dx.doi.org/10.1155/2014/450573

Juárez-Guerra, E., Alarcon-Aquino, V. & Gómez-Gil, P. Epilepsy Seizure Detection in EEG Signals Using Wavelet Transforms and Neural Networks. New Trends in Networking, Computing, E-learning, Systems Sciences, and Engineering, pp.261–269, 2014.

Available at: http://dx.doi.org/10.1007/978-3-319-06764-3_33.

Lasefr, Z., Ayyalasomayajula, S. and Elleithy, K. Epilepsy Seizure Detection Using EEG signals. At Department of Computer Science and Engineering, University of Bridgeport, Bridgeport, CT, USA, 2017.

Peachap, A.B. and Tchiotsop D. (2019). Epileptic seizures detection based on some new Laguerre polynomial wavelets, artificial neural networks and support vector machines. Informatics in Medicine Unlocked, Vol. 16, pp. 100209, 2019.

NEUROTECHEDU (n.d.). Preprocessing.

Available at: http://learn.neurotechedu.com/ preprocessing/ (Access date: 04-2020).

Salomon, D. Data Compression: The Complete Reference, 4th edn. California: Springer, pp. 298-299, 2007.

Sripathi, D. Efficient Implementations of Discrete Wavelet Transforms Using FPGAs, Master thesis, Florida State University, Florida, 2003.

Corinthios,M. Signals, Systems, Transforms, and Digital Signal Processing with MATLAB, USA: CRC Press, pp.1157-1158, 2009.

Expert System. What is Machine Learning? A definition. Available at: https://expert system.com/machine-learning-definition/ (Access date: 06-2020).

Alaliyat, S. Video -based Fall Detection in Elderly's Houses. Master thesis, Gjøvik University College, 2008.

Available at: https://www.researchgate.net/publication/267953942 (Access date: 06-2020).

Zhang, Z. Introduction to machine learning: k-nearest neighbors. Ann Transl Med, Vol. 4(11):218, 2016.

Kantardzic, M. DATA MINING: Concepts, Models, Methods, and Algorithms. 3rd edition. New Jersey : IEEE Press, John Wiley & Sons, Inc. 2020.

Pupale, R. Support Vector Machines(SVM)-An Overview. Available at: https://tow ardsdatascience.com/https-medium-com-pupalerushikesh-svm-f4b42800e989

(Access date: 06-2020).

Wikipedia, the free encyclopedia. Artificial neural network, Available at: https://en. wikipedia.org/wiki/Artificial_neural_network

(Access date: 04-2020).

Available at:

http://epileptologie-bonn.de/cms/front_content.php?idcat=193〈=3&chang elang=3

(Access date: 10-2019).

Siuly S, Li Y, Zhang Y. EEG Signal Analysis and Classification, Techniques and Applications. Book Series Title: Health Information Science. Publisher Springer International Publishing; 2016.




DOI: https://doi.org/10.31449/inf.v46i4.3768

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