Brainâ€“Computer Interfaces - Index of

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168 N. Birbaumer and P. Sauseng 8. N. Birbaumer and L. Cohen, Brain–Computer-Interfaces (BCI): Communication and Restoration of Movement in Paralysis. J Physiol, 579(3), 621–636, (2007). 9. E. Buch, C. Weber, L.G. Cohen, C. Braun, M. Dimyan, T. Ard, J. Mellinger, A. Caria, S. Soekadar, N. Birbaumer, Think to move: a neuromagnetic Brain–Computer interface (BCI) system for chronic stroke. Stroke, 39, 910–917, (2008). 10. A. Caria, R. Veit, R. Sitaram, M. Lotze, N. Weiskopf, W. Grodd, and N. Birbaumer, (2007). Regulation of anterior insular cortex activity using real-time fMRI. NeuroImage, 35, 1238– 1246. 11. R.C. DeCharms, F. Maeda, G.H. Glover, D. Ludlow, J.M. Pauly, D. Soneji, J.D. Gabrieli, and S.C. Mackey, Control over brain activation and pain learned by using real-time functional MRI. Proc Natl Acad Sci, 102(51), 18626–18631, (2005). 12. B.R. Dworkin, and N.E. Miller, Failure to replicate visceral learning in the acute curarized rat preparation. Behav Neurosci, 100, 299–314, (1986). 13. L.A. Farwell and E. Donchin, Talking off the top of your head: toward a mental prosthesis utilizing event-related brain potentials. Electroencephalogr Clin Neurophysiol, 70, 510–523, (1988). 14. L.R. Hochberg, M.D. Serruya, G.M. Friehs, J.A. Mukand, M. Saleh, A.H. Caplan, A. Branner, D. Chen, R.D. Penn, and J.P. Donoghue, Neural ensemble control of prosthetic devices by a human with tetraplegia. Nature, 442, 164–171, (2006). 15. A. Jackson, J. Mavoori, E. Fetz, Long-term motor cortex plasticity induced by an electronic neural implant. Nature, 444, 56–60, (2006). 16. B. Kotchoubey, U. Strehl, C. Uhlmann, S. Holzapfel, M. König, W. Fröscher, V. Blankenhorn, and N. Birbaumer Modification of slow cortical potentials in patients with refractory epilepsy: a controlled outcome study. Epilepsia, 42(3), 406–416, (2001). 17. B. Kotchoubey, A. Kübler, U. Strehl, H. Flor, and N. Birbaumer, Can humans perceive their brain states? Conscious Cogn, 11, 98–113, (2002). 18. A. Kübler, B. Kotchoubey, J. Kaiser, J. Wolpaw, and N. Birbaumer, Brain–Computer communication: unlocking the locked-in. Psychol Bull, 127(3), 358–375, (2001). 19. A. Kübler, S. Winter, A.C. Ludolph, M. Hautzinger, and N. Birbaumer, Severity of depressive symptoms and quality of life in patients with amyotrophic lateral sclerosis. Neurorehabil Neural Repair, 19(3), 182–193, (2005). 20. A. Kübler and N. Birbaumer, Brain–Computer Interfaces and communication in paralysis: Extinction of goal directed thinking in completely paralysed patients. Clin Neurophysiol, 119, 2658–2666, (2008). 21. P. Lang, M. Bradley, and B. Cuthbert, International Affective Picture System (IAPS). The Center for Research in Psychophysiology, University of Florida, Gainesville, Fl, (1999). 22. E.C. Leuthardt, K. Miller, G. Schalk, R.N. Rao, and J.G. Ojemann, Electrocorticography- Based Brain Computer Interface – The Seattle Experience. IEEE Trans Neur Sys Rehab Eng, 14, 194–198, (2006). 23. N. Logothetis, J. Pauls, M. Augath, T. Trinath, and A. Oeltermann, Neurophysiological investigation of the basis of the fMRI signal. Nature, 412, 150–157, (2001). 24. D. Lulé, V. Diekmann, S. Anders, J. Kassubek, A. Kübler, A.C. Ludolph, and N. Birbaumer, Brain responses to emotional stimuli in patients with amyotrophic lateral sclerosis (ALS). J Neurol, 254(4), 519–527, (2007). 25. N. Miller, Learning of visceral and glandular responses. Science, 163, 434–445, (1969). 26. M.A.L. Nicolelis, Actions from thoughts, Nature, 409, 403–407, (2001). 27. M.A. Nicolelis, Brain-machine interfaces to restore motor function and probe neural circuits. Nat Rev Neurosci, 4(5), 417–422, (2003). 28. L.M. Oberman, V.S. Ramachandran, and J.A. Pineda, Modulation of mu suppression in children with autism spectrum disorders in response to familiar or unfamiliar stimuli: the mirror neuron hypothesis. Neuropsychologia, 46, 1558–65, (2008). 29. G. Pfurtscheller, C. Neuper, and N. Birbaumer, Human Brain–Computer Interface (BCI). In Alexa Riehle & Eilon Vaadia (Eds.), Motor cortex in voluntary movements. A distributed system for distributed functions, CRC Press, Boca Raton, FL, pp. 367–401, (2005).
Brain–Computer Interface in Neurorehabilitation 169 30. G. Pfurtscheller, G. Müller-Putz, R. Scherer, and C. Neuper, Rehabilitation with Brain– Computer Interface systems. IEEE Comput Sci, 41, 58–65, (2008). 31. M. Schwartz, F. Andrasik, (Eds.), Biofeedback: A Practitioner’s Guide, 3rd edn, Guilford Press, New York, (2003). 32. G. Schalk, Brain–Computer symbiosis. J Neural Eng, 5, 1–15, (2008). 33. R. Sitaram, H. Zhang, C. Guan, M. Thulasidas, Y. Hoshi, A. Ishikawa, K. Shimizu, and N. Birbaumer, Temporal classification of multi-channel near-infrared spectroscopy signals of motor imagery for developing a Brain–Computer interface. NeuroImage, 34, 1416–1427, (2007). 34. U. Strehl, U. Leins, G. Goth, C. Klinger, T. Hinterberger, and N. Birbaumer, Self-regulation of Slow Cortical Potentials – A new treatment for children with Attention-Deficit/Hyperactivity Disorder. Pediatrics, 118(5), 1530–1540, (2006). 35. S. Waldert, H. Preissl, E. Demandt, C. Braun, N. Birbaumer, A. Aertsen, and C. Mehring, Hand movement direction decoded from MEG and EEG. J Neurosci, 28, 1000–1008, (2008). 36. N. Weiskopf, F. Scharnowsi, R. Veit, R. Goebel, N. Birbaumer, and K. Mathiak, Selfregulation of local brain activity using real-time functional magnetic resonance imaging (fMRI). J Physiol, Paris, 98, 357–373, (2005). 37. B. Wilhelm, M. Jordan, and N. Birbaumer, Communication in locked-in syndrome: effects of imagery on salivary pH. Neurology, 67, 534–535, (2006). 38. J.A. Wilson, E.A. Felton, P.C. Garell, G. Schalk, and J.C. Williams, ECoG factors underlying multimodal control of a Brain–Computer interface. IEEE Trans Neur Sys Rehab Eng, 14, 246–250, (2006). 39. S.L. Wolf, et al., Effect of constraint-induced movement therapy on upper extremity function 3 to 9 months after stroke: The EXCITE randomized clinical trial. Jama, 296(17), 2095–104, (2006).
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THE FRONTIERS COLLECTION
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Bernhard Graimann · Brendan Alliso
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Preface It’s an exciting time to
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Contents Brain-Computer Interfaces:
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Contributors Brendan Allison Instit
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Contributors xi Femke Nijboer Insti
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List of Abbreviations ADHD Attentio
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Brain-Computer Interfaces: A Gentle
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30 J.R. Wolpaw and C.B. Boulay by b
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32 J.R. Wolpaw and C.B. Boulay 2 Br
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34 J.R. Wolpaw and C.B. Boulay Fig.
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36 J.R. Wolpaw and C.B. Boulay Sens
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38 J.R. Wolpaw and C.B. Boulay pote
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40 J.R. Wolpaw and C.B. Boulay EEG-
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42 J.R. Wolpaw and C.B. Boulay 29.
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48 G. Pfurtscheller and C. Neuper F
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52 G. Pfurtscheller and C. Neuper r
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54 G. Pfurtscheller and C. Neuper 6
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56 G. Pfurtscheller and C. Neuper B
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66 C. Neuper and G. Pfurtscheller s
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68 C. Neuper and G. Pfurtscheller 2
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70 C. Neuper and G. Pfurtscheller F
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72 C. Neuper and G. Pfurtscheller b
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74 C. Neuper and G. Pfurtscheller E
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80 G. Pfurtscheller et al. mode, th
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82 G. Pfurtscheller et al. Therefor
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84 G. Pfurtscheller et al. A B C 1
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86 G. Pfurtscheller et al. filters
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88 G. Pfurtscheller et al. differen
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90 G. Pfurtscheller et al. In this
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92 G. Pfurtscheller et al. Fig. 8 P
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94 G. Pfurtscheller et al. 10. D. F
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96 G. Pfurtscheller et al. 51. G. P
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98 E.W. Sellers et al. Fig. 1 Three
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100 E.W. Sellers et al. Fig. 3 Two-
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102 E.W. Sellers et al. Fig. 5 Comp
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104 E.W. Sellers et al. Fig. 7 Mont
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106 E.W. Sellers et al. fixation wa
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108 E.W. Sellers et al. 5 SMR-Based
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110 E.W. Sellers et al. 22. D.J Kru
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Detecting Mental States by Machine
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Detecting Mental States by Machine
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BCIs Based on Signals from Between
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242 K.J. Miller and J.G. Ojemann 2
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244 K.J. Miller and J.G. Ojemann ha
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246 K.J. Miller and J.G. Ojemann Fi
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248 K.J. Miller and J.G. Ojemann Fi
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250 K.J. Miller and J.G. Ojemann fo
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252 K.J. Miller and J.G. Ojemann me
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254 K.J. Miller and J.G. Ojemann In
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256 K.J. Miller and J.G. Ojemann ar
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258 K.J. Miller and J.G. Ojemann 26
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260 J. Mellinger and G. Schalk mapp
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262 J. Mellinger and G. Schalk 2 BC
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264 J. Mellinger and G. Schalk Fig.
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266 J. Mellinger and G. Schalk Filt
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268 J. Mellinger and G. Schalk proc
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270 J. Mellinger and G. Schalk exis
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272 J. Mellinger and G. Schalk reco
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274 J. Mellinger and G. Schalk Fig.
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276 J. Mellinger and G. Schalk numb
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278 J. Mellinger and G. Schalk 5. A
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The First Commercial Brain-Computer
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306 Y. Li et al. Fig. 1 Basic desig
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308 Y. Li et al. Fig. 2 A linear tr
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310 Y. Li et al. The large Laplacia
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312 Y. Li et al. components is larg
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314 Y. Li et al. P300-based, and ER
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316 Y. Li et al. 3.3.2 Autoregressi
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318 Y. Li et al. selection as follo
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320 Y. Li et al. 5.1.2 Support Vect
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322 Y. Li et al. is small and the n
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324 Y. Li et al. (ROC) analysis app
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326 Y. Li et al. Fig. 10 The stimul
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328 Y. Li et al. 6. M. Cheng, X. Ga
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330 Y. Li et al. 46. K. Crammer and
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332 A. Schlögl et al. Fig. 1 Schem
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334 A. Schlögl et al. For the rect
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336 A. Schlögl et al. whereby T in
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338 A. Schlögl et al. Fig. 2 State
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340 A. Schlögl et al. yk = a1 · y
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342 A. Schlögl et al. d{i}(x) = ((
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344 A. Schlögl et al. Accordingly,
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346 A. Schlögl et al. not exceed a
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348 A. Schlögl et al. Error [%] RL
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350 A. Schlögl et al. Table 3 Aver
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352 A. Schlögl et al. The extended
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354 A. Schlögl et al. 24. N.G. Pfu
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Toward Ubiquitous BCIs Brendan Z. A
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Toward Ubiquitous BCIs 359 BCI Chal
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Toward Ubiquitous BCIs 361 communic
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Toward Ubiquitous BCIs 363 facial m
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Toward Ubiquitous BCIs 365 The best
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Toward Ubiquitous BCIs 367 Across a
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Toward Ubiquitous BCIs 369 the ques
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Toward Ubiquitous BCIs 371 controll
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Toward Ubiquitous BCIs 373 controls
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Toward Ubiquitous BCIs 375 hair in
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Toward Ubiquitous BCIs 377 Table 1
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Toward Ubiquitous BCIs 379 conversa
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Toward Ubiquitous BCIs 381 may down
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Toward Ubiquitous BCIs 383 physicis
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Toward Ubiquitous BCIs 385 31. F.H.
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Toward Ubiquitous BCIs 387 67. G. S
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390 Index 65, 157, 163, 217, 221-23
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392 Index 208, 236, 243, 245, 260-2
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