Sensitivity of Seizure Pattern Prediction to EEG Signal Compression | ||||
Menoufia Journal of Electronic Engineering Research | ||||
Article 7, Volume 28, Issue 2, July 2019, Page 97-116 | ||||
Document Type: Original Article | ||||
DOI: 10.21608/mjeer.2019.62768 | ||||
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Authors | ||||
Sally El-Gindy* 1; Sami El-Dolil1; Adel El-Fishawy1; El-Sayed El-Rabaie1; Moawad Dessouky1; Fathi Abd El-Samie1; Turky Elotaiby2; Saleh Elshebeily3 | ||||
1Department of Electronics and Electrical Communications Engineering, Faculty of Electronic Engineering, Menoufia University, Menouf, 32952, Egypt. | ||||
2KACST, Kingdom of Saudi Arabia Dept. | ||||
3Electrical Engineering Department, KACST-TIC in Radio Frequency and Photonics for the e-Society (RFTONICS), King Saud University. | ||||
Abstract | ||||
This paper presents a framework for Electroencephalography (EEG) seizure prediction in time domain. Moreover, it studies an efficient lossy EEG signal compression technique and its effect on further processing for seizure prediction in a realistic signal acquisition and compression scenario. Compression of EEG signals are one of the most important solutions in saving speed up signals transfer, reduction of energy transmission and the required memory for storage in addition to reduction costs for storage hardware and network bandwidth. The main objective of this research is to use trigonometric compression techniques including; Discrete Cosine Transform (DCT) and Discrete Sine Transform (DST) algorithms on EEG signals and study the impact of the reconstructed EEG signals on its seizure prediction ability. Simulation results show that the DCT achieves the best prediction results compared with DST technique achieving sensitivity of 95.238% and 85.714% respectively. The proposed approach gives longer prediction times compared to traditional EEG seizure prediction approaches. Therefore, it will help specialists for the prediction of epileptic seizure as earlier as possible. | ||||
References | ||||
0px; "> [1] M. Taplan “Fundamentals of EEG Measurement,” Measurements Science Review, Vol.2, Sec.2, 2002. [2] N. Sriraam “A High – Performance Lossless Compression Scheme for EEG Signals Using Wavelet Transform and Neural Network kit-text-stroke-width: 0px; "> Predictors,” International Journal of Telemedicine and Applications, 8 pages, India, 2012. [3] R., G. M .Kumar and R. Bathla “Data Compression - Lossless and Lossy Techniques,” International Journal of Application or Innovation in Engineering & Management (IJAIEM), Issue 7, 2016. [4] M., A. M. Saeed, T. Ismail and H. Mostafa “Hybrid DCT/RLE Compression Technique with Data Segmentation for Electroencephalography Data,” arXiv: 1804.02713v2 [eess.SP] 18 Apr 2018. [5] J., L. C. B.and J. V. Lorenzo-Gino r “A Wavelet- Packet based algorithm for EEG Signal Compression,” Medical Informatics and the Internet in Medicine, 2004. [6] D., B., V. Jusas, I. Martisius and R. Damasvicius “Fast DCT Algorithm for EEG Data Compression in Embedded System,” Computer Science and Information System, 12(1): 49-62, 2015. [7] K. Sharma and K. Gupta “Lossless Data Compression Techniques and their Performance,” IEEE-International Conference on Computing, Communication and Automation (ICCCA), India, 2017. [8] A., B., T. Bej and S. Agarwal “Comparison Study of lossless Data Compression Algorithms for text Data,” IOSR Journal of Computer engineering, 2013. [9] M. Singh, S. Kumar, S. S. Chouhen and M. Shrivastava “Various Image Compression Techniques: Lossy and Lossless,” International Journal of Computer Application, 142(6):23-26, 2016. [10] https://en.wikipedia.org/wiki/Discrete_cosine_transform. (Access date Feb.11,2017) [11] https://en.wikipedia.org/wiki/Discrete_sine_transform. (Access date Feb.11,2017) | ||||
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