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CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING

Yıl 2018, Cilt: 13 Sayı: 1, 27 - 36, 19.01.2018

Öz

Functional near-infrared spectroscopy (fNIRS) is a non-invasive optical
imaging technique used in brain-computer interface (BCI) systems. It is used to
measure deoxyhemoglobin and oxyhemoglobin proportions that occur during a
specific activity in the brain region (motor and visual activity, auditory
stimulus, etc.). In this study, hemodynamic patterns were recorded from 8
participants during mental arithmetic and rest activities. Features have been
extracted for this by using detrended fluctuation analysis, entropy and Hjorth
parameters methods. The distinctive feature vectors obtained after the feature
selection process have been applied to support vector machines (SVM),
multilayer artificial neural networks (MLANN) and k-nearest neighbors (k-NN)
classifiers. As a result, the best classification accuracy was 97.17% when SVM
classifier was used.

Kaynakça

  • 1. Son, I.Y. and Yazici, B., (2006). Near Infrared Imaging and Spectroscopy for Brain Activity Monitoring. In Advances in Sensing with Security Applications, 341-372, Dordrecht, Springer.
  • 2. Herff, C., Heger, D., Putze, F., Hennrich, J., Fortmann, O., and Schultz, T., (2013). Classification of Mental Tasks in the Prefrontal Cortex Using fNIRS. In Engineering in Medicine and Biology Society (EMBC) 35th Annual International Conference of the IEEE, 2160-2163.
  • 3. Kontos, A.P., Huppert, T.J., Beluk, N.H., Elbin, R.J., Henry, L.C., French, J., Dakan S.M., and Collins, M.W., (2014). Brain Activation During Neurocognitive Testing Using Functional Near-Infrared Spectroscopy in Patients Following Concussion Compared to Healthy Controls. Brain imaging and behavior, Volume: 8, Issue: 4, 621-634.
  • 4. McKendrick, R., Parasuraman, R., and Ayaz, H., (2015). Wearable Functional near Infrared Spectroscopy (fNIRS) and Transcranial Direct Current Stimulation (tDCS): Expanding Vistas for Neurocognitive Augmentation. Frontiers in Systems Neuroscience, Volume 9.
  • 5. Bauernfeind, G., Steyrl, D., Brunner, C., and Müller-Putz, G. R., (2014). Single Trial Classification of fNIRS-based Brain-Computer Interface Mental Arithmetic Data: a comparison between different classifiers. In Engineering in Medicine and Biology Society (EMBC) 36th Annual International Conference of the IEEE, 2004-2007.
  • 6. Bauernfeind, G., (2012). Using Functional Near-Infrared Spectroscopy (fNIRS) for Optical Brain-Computer Interface (OBCI) Applications.
  • 7. Hardstone, R., Poil, S.S., Schiavone, G., Jansen, R., Nikulin, V.V., Mansvelder, H.D., and Linkenkaer-Hansen, K., (2012). Detrended Fluctuation Analysis: a Scale-Free View on Neuronal Oscillations. Frontiers in physiology, Volume: 3.
  • 8. Peng, C-K., Hausdorff, J.M., and Goldberger, A.L., (2000). Fractal Mechanisms in Neural Control: Human Heartbeat and Gait Dynamics in Health and Disease. Self-Organized Biological Dynamics and Nonlinear Control, Cambridge, Cambridge University Press.
  • 9. Chen, X., Wong, S.C., Tse, C.K., and Trajković, L., (2009). Detrended Fluctuation Analysis of the TCP-red Algorithm. International Journal of Bifurcation and Chaos, Volume: 19, Issue: 12, 4237-4245.
  • 10. Najarian, K., and Splinter, R., (2005). Biomedical Signal and Image Processing, CRC press.
  • 11. Lesne, A., (2014). Shannon Entropy: A Rigorous Notion at the Crossroads between Probability, Information Theory, Dynamical Systems and Statistical Physics. Mathematical Structures in Computer Science, Volume: 24, Issue: 3.
  • 12. Hjorth, B., (1975). Time Domain Descriptors and Their Relation to a Particular Model for Generation of EEG Activity. Computerized EEG Analysis: CEAN, 3-8.
  • 13. Liu, H., and Motoda, H., (2007). Computational Methods of Feature Selection, CRC Press.
  • 14. Burges, C.J., (1998). A Tutorial on Support Vector Machines for Pattern Recognition. Data Mining and Knowledge Discovery, Volume: 2, Issue: 2, 121-167.
  • 15. Hastie, T., Tibshirani, R., and Friedman, J., (2009). Overview of Supervised Learning. In the Elements of Statistical Learning, 9-41, New York, Springer.
  • 16. Amari, S.I. and Wu, S., (1999). Improving Support Vector Machine Classifiers by Modifying Kernel Functions. Neural Networks, Volume 12, Issue 6, 783-789.
  • 17. Patterson, D.W., (1998). Artificial Neural Networks: Theory and Applications, Prentice Hall PTR.
  • 18. Kotsiantis, S.B., Zaharakis, I., and Pintelas, P., (2007). Supervised Machine Learning: A Review of Classification Techniques, IOS Press.
Yıl 2018, Cilt: 13 Sayı: 1, 27 - 36, 19.01.2018

Öz


Kaynakça

  • 1. Son, I.Y. and Yazici, B., (2006). Near Infrared Imaging and Spectroscopy for Brain Activity Monitoring. In Advances in Sensing with Security Applications, 341-372, Dordrecht, Springer.
  • 2. Herff, C., Heger, D., Putze, F., Hennrich, J., Fortmann, O., and Schultz, T., (2013). Classification of Mental Tasks in the Prefrontal Cortex Using fNIRS. In Engineering in Medicine and Biology Society (EMBC) 35th Annual International Conference of the IEEE, 2160-2163.
  • 3. Kontos, A.P., Huppert, T.J., Beluk, N.H., Elbin, R.J., Henry, L.C., French, J., Dakan S.M., and Collins, M.W., (2014). Brain Activation During Neurocognitive Testing Using Functional Near-Infrared Spectroscopy in Patients Following Concussion Compared to Healthy Controls. Brain imaging and behavior, Volume: 8, Issue: 4, 621-634.
  • 4. McKendrick, R., Parasuraman, R., and Ayaz, H., (2015). Wearable Functional near Infrared Spectroscopy (fNIRS) and Transcranial Direct Current Stimulation (tDCS): Expanding Vistas for Neurocognitive Augmentation. Frontiers in Systems Neuroscience, Volume 9.
  • 5. Bauernfeind, G., Steyrl, D., Brunner, C., and Müller-Putz, G. R., (2014). Single Trial Classification of fNIRS-based Brain-Computer Interface Mental Arithmetic Data: a comparison between different classifiers. In Engineering in Medicine and Biology Society (EMBC) 36th Annual International Conference of the IEEE, 2004-2007.
  • 6. Bauernfeind, G., (2012). Using Functional Near-Infrared Spectroscopy (fNIRS) for Optical Brain-Computer Interface (OBCI) Applications.
  • 7. Hardstone, R., Poil, S.S., Schiavone, G., Jansen, R., Nikulin, V.V., Mansvelder, H.D., and Linkenkaer-Hansen, K., (2012). Detrended Fluctuation Analysis: a Scale-Free View on Neuronal Oscillations. Frontiers in physiology, Volume: 3.
  • 8. Peng, C-K., Hausdorff, J.M., and Goldberger, A.L., (2000). Fractal Mechanisms in Neural Control: Human Heartbeat and Gait Dynamics in Health and Disease. Self-Organized Biological Dynamics and Nonlinear Control, Cambridge, Cambridge University Press.
  • 9. Chen, X., Wong, S.C., Tse, C.K., and Trajković, L., (2009). Detrended Fluctuation Analysis of the TCP-red Algorithm. International Journal of Bifurcation and Chaos, Volume: 19, Issue: 12, 4237-4245.
  • 10. Najarian, K., and Splinter, R., (2005). Biomedical Signal and Image Processing, CRC press.
  • 11. Lesne, A., (2014). Shannon Entropy: A Rigorous Notion at the Crossroads between Probability, Information Theory, Dynamical Systems and Statistical Physics. Mathematical Structures in Computer Science, Volume: 24, Issue: 3.
  • 12. Hjorth, B., (1975). Time Domain Descriptors and Their Relation to a Particular Model for Generation of EEG Activity. Computerized EEG Analysis: CEAN, 3-8.
  • 13. Liu, H., and Motoda, H., (2007). Computational Methods of Feature Selection, CRC Press.
  • 14. Burges, C.J., (1998). A Tutorial on Support Vector Machines for Pattern Recognition. Data Mining and Knowledge Discovery, Volume: 2, Issue: 2, 121-167.
  • 15. Hastie, T., Tibshirani, R., and Friedman, J., (2009). Overview of Supervised Learning. In the Elements of Statistical Learning, 9-41, New York, Springer.
  • 16. Amari, S.I. and Wu, S., (1999). Improving Support Vector Machine Classifiers by Modifying Kernel Functions. Neural Networks, Volume 12, Issue 6, 783-789.
  • 17. Patterson, D.W., (1998). Artificial Neural Networks: Theory and Applications, Prentice Hall PTR.
  • 18. Kotsiantis, S.B., Zaharakis, I., and Pintelas, P., (2007). Supervised Machine Learning: A Review of Classification Techniques, IOS Press.
Toplam 18 adet kaynakça vardır.

Ayrıntılar

Konular Mühendislik
Bölüm Makaleler
Yazarlar

Funda Kutlu Onay

Cemal Köse

Yayımlanma Tarihi 19 Ocak 2018
Yayımlandığı Sayı Yıl 2018 Cilt: 13 Sayı: 1

Kaynak Göster

APA Kutlu Onay, F., & Köse, C. (2018). CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING. Engineering Sciences, 13(1), 27-36.
AMA Kutlu Onay F, Köse C. CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING. Engineering Sciences. Ocak 2018;13(1):27-36.
Chicago Kutlu Onay, Funda, ve Cemal Köse. “CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING”. Engineering Sciences 13, sy. 1 (Ocak 2018): 27-36.
EndNote Kutlu Onay F, Köse C (01 Ocak 2018) CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING. Engineering Sciences 13 1 27–36.
IEEE F. Kutlu Onay ve C. Köse, “CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING”, Engineering Sciences, c. 13, sy. 1, ss. 27–36, 2018.
ISNAD Kutlu Onay, Funda - Köse, Cemal. “CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING”. Engineering Sciences 13/1 (Ocak 2018), 27-36.
JAMA Kutlu Onay F, Köse C. CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING. Engineering Sciences. 2018;13:27–36.
MLA Kutlu Onay, Funda ve Cemal Köse. “CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING”. Engineering Sciences, c. 13, sy. 1, 2018, ss. 27-36.
Vancouver Kutlu Onay F, Köse C. CLASSIFICATION OF FUNCTIONAL NEAR-INFRARED IMAGING BASED HEMODYNAMIC PATTERNS RECORDED AT MENTAL ARITHMETİC AND RESTING. Engineering Sciences. 2018;13(1):27-36.