The analysis of the feature’s uniqueness of the electroencephalograph (EEG) signal extracted by continuous wavelet transform (CWT) method against the five BCI wheelchair control indicators has been done. The usage of Friedman method as measuring the uniqueness level of EEG signal features as well as their significance is used in this research. The EEG signals from three subjects that sitting on a regular chair were recorded when they were performing mental commands as seem as controlling a wheelchair with five control indicators. The recorded signals are decomposed by CWT. The absolute mean (|µ|) and the deviation standard (σ) of the CWT decomposition results are used as feature. Then, the uniqueness of |µ| and σ features are analyzed using Friedman Method. Based on the experiment results, it is known that the proposed method is able to map features according to their uniqueness level. The experiment result shows that the highest uniqueness value of |µ| feature from three subjects are 400 (“forward – backward” indicators), 437 (“neutral – turn left” indicators), and 597 (“neutral – turn left” indicators) respectively. While the highest uniqueness value of σ feature from each subjects are 380, 419, and 568 respectively in the same indicator pairs as |µ| feature.

BCI; EEG; CWT; metode Friedman

Venkatasubramanian, V. dan Balaji, R.K. (2009) Non Invasive Brain Computer Interface for Movement Control. in: Proc. World Congr. Eng. Comput. Sci., WCECS, San Fransisco.

Kraus, L. (2017) 2016 Disability Statistics Annual Report. Durham, New Hampshire.

Gneo, M., Severini, G., Conforto, S., Schmid, M., dan D’Alessio, T. (2011) Towards a Brain-Activated and Eye-Controlled Wheelchair. International Journal of Bioelectromagnetism. 13 (1), 44–45.

Al-qaysi, Z.T., Zaidan, B.B., Zaidan, A.A., dan Suzani, M.S. (2018) A review of disability EEG based wheelchair control system: Coherent taxonomy, open challenges and recommendations. Computer Methods and Programs in Biomedicine. 164 221–237.

Kolodziej, M., Majkowski, A., dan Rak, R.J. (2012) Linear discriminant analysis as EEG features reduction technique for brain-computer interfaces. Przeglad Elektrotechniczny. 88 (3A), 28–30.

Pattnaik, P.K. dan Sarraf, J. (2018) Brain Computer Interface issues on hand movement. Journal of King Saud University - Computer and Information Sciences. 30 (1), 18–24.

Abdalsalam M, E., Yusoff, M.Z., Mahmoud, D., Malik, A.S., dan Bahloul, M.R. (2018) Discrimination of four class simple limb motor imagery movements for brain–computer interface. Biomedical Signal Processing and Control. 44 181–190.

Gysels, E., Renevey, P., dan Celka, P. (2005) SVM-based recursive feature elimination to compare phase synchronization computed from broadband and narrowband EEG signals in Brain–Computer Interfaces. Signal Processing. 85 (11), 2178–2189.

Wang, Y., Veluvolu, K.C., dan Lee, M. (2013) Time-frequency analysis of band-limited EEG with BMFLC and Kalman filter for BCI applications. Journal of neuroengineering and rehabilitation. 10 (1), 109.

Ali, S., Ferdous, M.J., Hamid, E., dan Molla, K.I. (2016) Time-Frequency Coherence of Multichannel EEG Signals: Synchrosqueezing Transform Based Analysis. International Journal of Computer Science Trends and Technology. 4 (3), 40–48.

Thomas, E., Fruitet, J., dan Clerc, M. (2013) Combining ERD and ERS features to create a system-paced BCI. Journal of neuroscience methods. 216 (2), 96–103.

Rahul, Y. (2017) A Review on EEG Control Smart Wheel Chair. International Journal of Advanced Research in Computer Science. 8 (9), 501–507.

Krishnan, S. dan Athavale, Y. (2018) Trends in Biomedical Signal Feature Extraction. Biomedical Signal Processing and Control. 43 41–63.

Bostanov, V. (2004) BCI Competition 2003--Data sets Ib and IIb: feature extraction from event-related brain potentials with the continuous wavelet transform and the t-value scalogram. IEEE transactions on bio-medical engineering. 51 (6), 1057–61.

Hsu, W.-Y. dan Sun, Y.-N. (2009) EEG-based motor imagery analysis using weighted wavelet transform features. Journal of neuroscience methods. 176 (2), 310–8.

Aydemir, Ö. dan Kayikçioğlu, T. (2016) Investigation of the most appropriate mother wavelet for characterizing imaginary EEG signals used in BCI systems. Turkish Journal of Electrical Engineering & Computer Scineces. 24 38–49.

Bostanov, V. (2015) Multivariate assessment of event-related potentials with the t-CWT method. BMC Neuroscience. 16 73.

Hsu, W.-Y. (2015) Motor imagery EEG discrimination using the correlation of wavelet features. Clinical EEG and neuroscience. 46 (2), 94–9.

Simões, M.A.M. (2011) A Virtual Reality Application with a Brain-Computer Interface for Rehabilitation of Social Development in Autism, Universidade De Coimbra, 2011.

Granato, D., de Araújo Calado, V.M., dan Jarvis, B. (2014) Observations on the use of statistical methods in Food Science and Technology. Food Research International. 55 137–149.

Zimmerman, D.W. dan Zumbo, B.D. (1993) Relative Power of the Wilcoxon Test, the Friedman Test, and Repeated-Measures ANOVA on Ranks. The Journal of Experimental Education. 62 (1), 75–86.

Chatfield, M. dan Mander, A. (2009) The Skillings-Mack test (Friedman test when there are missing data). The Stata journal. 9 (2), 299–305.

Eisinga, R., Heskes, T., Pelzer, B., dan Te Grotenhuis, M. (2017) Exact p-values for pairwise comparison of Friedman rank sums, with application to comparing classifiers. BMC bioinformatics. 18 (1), 68.

Porkka, P., Jussila, J., dan Suominen, A. (2008) Using Friedman test for creating comparable group results of nonparametric innovation competence data. in: Proc. Present. Pap. 5th Int. Conf. Innov. Manag., Unu-Merit, Maastricht, the Netherlandshal. 722–728.

Rechy-Ramirez, E.J. dan Hu, H. (2015) Bio-signal based control in assistive robots: a survey. Digital Communications and Networks. 1 (2), 85–101.

Edla, D.R., Mangalorekar, K., Dhavalikar, G., dan Dodia, S. (2018) Classification of EEG data for human mental state analysis using Random Forest Classifier. Procedia Computer Science. 132 (Iccids), 1523–1532.

Wolpaw, J. dan Wolpaw, E.W. (2012) Brain–Computer Interfaces: Principles and Practice. Oxford University Press, New York.

Akila, M., Sekar, K.S., dan Suresh, A. (2015) Smart Brain-Controlled Whellchair and Devices Based on EEG in Low Cost for Disabled Person. International Journal of Computers Communication Networks and Circuit Systems. 1 (1), 291–298.

Browning, G. (2007) Emergenetics: Menyadap Ilmu Kesuksesan Baru. Gramedia, Jakarta.

Siuly, S., Li, Y., dan Zhang, Y. (2016) EEG Signal Analysis and Classification. Springer International Publishing, Cham.

Carvalho, S.N., Costa, T.B.S., Uribe, L.F.S., Soriano, D.C., Yared, G.F.G., Coradine, L.C., et al. (2015) Comparative analysis of strategies for feature extraction and classification in SSVEP BCIs. Biomedical Signal Processing and Control. 21 34–42.

Ahmad, F.K., Awwad Al-Qammaz, A.Y., dan Yusof, Y. (2016) Optimization of Least Squares Support Vector Machine Technique Using Genetic Algorithm for Electroencephalogram Multi-Dimensional Signals. Jurnal Teknologi. 78 (5–10), 107–115.

Torse, D., Desai, V., dan Khanai, R. (2018) Classification of EEG Signals in a Seizure Detection System Using Dual Tree Complex Wavelet Transform and Least Squares Support Vector Machine. International Journal of Image, Graphics and Signal Processing. 10 (1), 56–64.

Neurosky (2009) Brain Wave Signal (EEG) of Neurosky, Inc. Neurosky, San Jose.

Larsen, E.A. dan Wang, A.I. (2011) Classification of EEG Signals in a Brain- Computer Interface System, Norwegian University of Science and Technology, 2011.

Girase, P.D. dan Deshmukh, M.P. (2016) Mindwave Device Wheelchair Control. International Journal of Science and Research (IJSR). 5 (6), 2172–2176.

Ahn, M., Cho, H., Ahn, S., dan Jun, S.C. (2013) High theta and low alpha powers may be indicative of BCI-illiteracy in motor imagery. PloS one. 8 (11), e80886.

Mohd Azali, N.N. (2015) Classification of EEG Signals for Human Computer Interface (HCI) Application, Universiti Tun Hussein Onn Malaysia., 2015.

Aydemir, Ö. dan Kayikçioğlu, T. (2011) Wavelet Transform Based Classification of Invasive Brain Computer Interface Data Onder. Radioengineering. 20 (1), 31–38.

Karimoi, R.Y., Khalilzadeh, M.A., Hossinezadeh, A.A., dan Karimoi, A.Y. (2014) EEG Signal Classification Using Bayes and Naïve Bayes Classifiers and Extracted Features of Continuous Wavelet Transform. Majlesi Journal of Multimedia Processing. 3 (1), 1–7.

Kumari, M. dan Somani, S.B. (2015) Enhancing the Classification Accuracy of SSVEP Based BCI Using CWT Method Along with ANN. International Journal of Advanced Research in Engineering and Management. 1 (1), 81–89.

Darvishi, S. dan Al-Ani, A. (2007) Brain-Computer Interface Analysis using Continuous Wavelet Transform and Adaptive Neuro-Fuzzy Classifier. in: 2007 29th Annu. Int. Conf. IEEE Eng. Med. Biol. Soc., IEEE, Lyonhal. 3220–3223.

Bassani, T. (2009) Design of A BCI System Using EEG Signal Analysis with Continuous Wavelet Transformation and Naives Bayes Classifier, Pontifical Catholic University of Paraná, 2009.

Castillo-Garcia, J., Hortal, E., Bastos, T., Ianez, E., Caicedo, E., dan Azorin, J. (2015) Active learning for adaptive brain machine interface based on Software Agent. in: 2015 23rd Mediterr. Conf. Control Autom., IEEE, Torremolinoshal. 44–48.

Pereira, D.G., Afonso, A., dan Medeiros, F.M. (2015) Overview of Friedman’s Test and Post-hoc Analysis. Communications in Statistics - Simulation and Computation. 44 (10), 2636–2653.

Ali, Z. dan Bhaskar, S.B. (2016) Basic statistical tools in research and data analysis. Indian journal of anaesthesia. 60 (9), 662–669.

Uyanto, S.S. (2009) Pedoman Analisis Data dengan SPSS. III Graha Ilmu, Yogyakarta.

Santoso, S. (2014) Statistik Nonparametrik: Konsep dan Aplikasi dengan SPSS. PT Elex Media Komputindo, Jakarta.

Bose, R., Khasnobish, A., Bhaduri, S., dan Tibarewala, D.N. (2016) Performance analysis of left and right lower limb movement classification from EEG. in: 2016 3rd Int. Conf. Signal Process. Integr. Networks, IEEE, hal. 174–179.

Pal, M. dan Bandyopadhyay, S. (2016) Many-objective feature selection for motor imagery EEG signals using differential evolution and support vector machine. in: 2016 Int. Conf. Microelectron. Comput. Commun., IEEE, Durgapurhal. 1–6.

Rakshit, A., Khasnobish, A., dan Tibarewala, D.N. (2016) A Naïve Bayesian approach to lower limb classification from EEG signals. in: 2016 2nd Int. Conf. Control. Instrumentation, Energy Commun., IEEE, Kolkatahal. 140–144.

Gupta, A. dan Kumar, D. (2017) Fuzzy clustering-based feature extraction method for mental task classification. Brain Informatics. 4 (2), 135–145.

Celecia Ramos, A. (2017) Multiple Classifier System for Motor Imagery Task Classification, Pontifícia Universidade Católica do Rio de Janeiro, 2017.