Brainâ€“Computer Interfaces - Index of

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Toward Ubiquitous BCIs 385 31. F.H. Guenther, J.S. Brumberg, E.J. Wright, A. Nieto-Castanon, J.A. Tourville, M. Panko, R. Law, S.A. Siebert, J.L. Bartels, D.S. Andreasen, P. Ehirim, H. Mao, and P.R. Kennedy., A wireless brain-machine interface for real-time speech synthesis. PLoS One, 4(12), e8218, (2009). 32. C. Guger, S. Daban, E. Sellers, C. Holzner, G. Krausz, R. Carabalona, F. Gramatica, and G. Edlinger. How many people are able to control a P300-based brain–computer interface (BCI)? Neurosci Lett, 462, 94–98, (2009). 33. C. Guger, G. Edlinger, W. Harkam, I. Niedermayer, and G. Pfurtscheller, How many people are able to operate an EEG-based brain–computer interface (BCI)? IEEE Trans Neural Syst Rehabil Eng, 11, 145–147, (2003). 34. 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, Neuronal ensemble control of prosthetic devices by a human with tetraplegia. Nature, 442, 164–171, (2006). 35. A. Kübler and K.-R. Müller, An introduction to brain–computer interfacing. In G. Dornhege, J. del R. Millán, T. Hinterberger, D.J. McFarland, and K.-R. Müller, (Eds.), Toward brain– computer interfacing, MIT Press, Cambridge, MA, pp. 1–25, (2007). 36. A. Kübler, N. Neumann, J. Kaiser, B. Kotchoubey, T. Hinterberger, and N. Birbaumer, brain–computer communication: self-regulation of slow cortical potentials for verbal communication. Arch Phys Med Rehabil, 82, 1533–1539, (2001). 37. P.R. Kennedy, R.A. Bakay, M.M. Moore, K. Adams, and J. Goldwaithe, Direct control of a computer from the human central nervous system. IEEE Trans Rehabil Eng, 8(2), 198–202, Jun (2000). 38. J. Kubánek, K.J. Miller, J.G. Ojemann, J.R. Wolpaw, and G. Schalk., Decoding flexion of individual fingers using electrocorticographic signals in humans. J Neural Eng, 6(6), 066001, Dec (2009). 39. K. G. Lambert. Rising rates of depression in today’s society: consideration of the roles of effort-based rewards and enhanced resilience in day-to-day functioning. Neurosci Behav Revi, 30, 497–510, (2006). 40. E.C. Lee; J.C. Woo, J.H. Kim et al. A brain-computer interface method combined with eye tracking for 3D interaction J Neurosci Method, 190(2), 289–298, (2010) 41. R. Leeb, R. Scherer, D. Friedman, F.Y. Lee, C. Keinrath, H. Bischof, M. Slater, and G. Pfurtscheller, Combining BCI and virtual reality: scouting virtual worlds. In G. Dornhege, J. del R. Millán, T. Hinterberger, D.J. McFarland, and K.-R. Müller, (Eds), Toward brain– computer interfacing, chapter 23, MIT Press, Cambridge, MA, pp. 393–408, (2007). 42. A. W. Mahncke, A. Bronstone, and M. M. Merzenich., Brain plasticity and functional losses in the aged: scientific basis for a novel intervention. Progress in brain research: Reprogramming the brain, Elsevier, New York, (2006). 43. D. Marr, Vision, W. H. Freeman, (1982). http://www.nature.com/nature/journal/v317/n6035/ abs/317314a0.html 44. S.G. Mason, A. Bashashati, M. Fatourechi, K.F. Navarro, and G.E. Birch, A comprehensive survey of brain interface technology designs. Ann Biomed Eng, 35, 137–169, (2007). 45. D.J. McFarland, D. J. Krusienski, W. A. Sarnacki, and J. R. Wolpaw, Emulation of computer mouse control with a noninvasive brain–computer interface. J Neural Eng, 5, 101–110, (2008). 46. J. Mellinger, G. Schalk, C. Braun, H. Preissl, W. Rosenstiel, N. Birbaumer, and A. Kübler, An MEG-based brain–computer interface (BCI). NeuroImage, 36, 581–593, (2007). 47. G.R. Müller, C. Neuper, and G. Pfurtscheller, Implementation of a telemonitoring system for the control of an EEG-based brain–computer interface. IEEE Trans Neural Syst Rehabil Eng, 11, 54–59, (2003). 48. K.-R. Müller, M. Tangermann, G. Dornhege, M. Krauledat, G. Curio, and B. Blankertz, Machine learning for real-time single-trial EEG analysis: From brain–computer interfacing to mental state monitoring. J Neurosci Methods, 167, 82–90, (2008). 49. M. M. Moore, Real-world applications for brain–computer interface technology. IEEE Trans Neural Syst Rehabil Eng, 11, 162–165, (2003).
386 B.Z. Allison 50. T.M. Srihari Mukesh, V. Jaganathan, and M. Ramasubba Reddy, A novel multiple frequency stimulation method for steady state VEP based brain computer interfaces. Physiol Measure, 27, 61–71, 2006. 51. N. Neumann, T. Hinterberger, J. Kaiser, U. Leins, N. Birbaumer, and A. Kübler, Automatic processing of self-regulation of slow cortical potentials: evidence from brain–computer communication in paralysed patients. Clin Neurophysiol, 115, 628–635, (2004). 52. C. Neuper, R. Scherer, M. Reiner, and G. Pfurtscheller, Imagery of motor actions: differential effects of kinaesthetic versus visual-motor mode of imagery on single-trial EEG. Brain Res Cogn Brain Res, 25, 668–677, 2005. 53. F. Nijboer, A. Furdea, I. Gunst, J. Mellinger, D.J. McFarland, N. Birbaumer, and A. Kübler. An auditory brain–computer interface (BCI). Neurosci Lett, 167, 43–50, (2008). 54. F. Nijboer, N. Birbaumer, and A. Kübler. The influence of psychological state and motivation on brain-computer interface performance in patients with amyotrophic lateral sclerosis–a longitudinal study. Front Neurosci, 4, (2010) 55. A. Nijholt, D. Tan, G. Pfurtscheller, C. Brunner, J. del R. Millán, B.Z. Allison, B. Graimann, F. Popescu, B. Blankertz, and K.-R. Müller, brain–computer interfacing for intelligent systems. IEEE Intell Syst, 23, 72–79, (2008). 56. V.V. Nikulin, F.U. Hohlefeld, A.M. Jacobs, and G. Curio. Quasi-movements: a novel motorcognitive phenomenon. Neuropsychologia, 46:727–742, (2008). 57. G. Pfurtscheller, B.Z. Allison, C. Brunner, G. Bauernfeind, T. Solis Escalante, R. Scherer, T.O. Zander, G. Müller-Putz, C. Neuper, and N. Birbaumer,. The hybrid BCI. Front Neurosci, 4, 42. doi:10.3389/fnpro.2010.00003, (2010). 58. G. Pfurtscheller, R. Leeb, D. Friedman, and M. Slater, Centrally controlled heart rate changes during mental practice in immersive virtual environment: a case study with a tetraplegic. Int J Psychophysiol, 68, 1–5, (2008). 59. G. Pfurtscheller, G. Müller-Putz, R. Scherer, and C. Neuper, Rehabilitation with brain– computer interface systems. IEEE Comput Mag, 41, 58–65, (2008). 60. G. Pfurtscheller, G.R. Müller-Putz, A. Schlögl, B. Graimann, R. Scherer, R. Leeb, C. Brunner, C. Keinrath, F. Lee, G. Townsend, C. Vidaurre, and C. Neuper, 15 years of BCI research at Graz University of Technology: current projects. IEEE Trans Neural Syst Rehabil Eng, 14, 205–210, (2006). 61. G. Pfurtscheller, T. Solis-Escalante, R. Ortner, P. Linortner, and G.R. Müller-Putz, Self-paced operation of an SSVEP-based orthosis with and without an imagery-based “brain switch”: A feasibility study towards a hybrid BCI. IEEE Trans Neural Syst Rehabil Eng, 18(4), 409–414, Aug (2010). 62. J.A. Pineda, B.Z. Allison, and A. Vankov, The effects of self-movement, observation, and imagination on mu rhythms and readiness potentials (RP’s): toward a brain–computer interface (BCI). IEEE Trans Rehabil Eng, 8(2), 219–222, Jun (2000). 63. J.A. Pineda, D. Brang, E. Hecht, L. Edwards, S. Carey, M. Bacon, C. Futagaki, D. Suk, J. Tom, C. Birnbaum, and A. Rork, Positive behavioral and electrophysiological changes following neurofeedback training in children with autism. Res Autism Spect Disorders, 2(3), 557–581, (2008). 64. J.A. Pineda, D.S. Silverman, A. Vankov, and J. Hestenes, Learning to control brain rhythms: making a brain–computer interface possible. IEEE Trans Neural Syst Rehabil Eng, 11, 181– 184, (2003). 65. F. Popescu, S. Fazli, Y. Badower, B. Blankertz, and K.-R. Müller, Single trial classification of motor imagination using 6 dry EEG electrodes. PLoS ONE, 2, e637, (2007). 66. C. Sannelli, M. Braun, M. Tangermann, and K.-R. Müller, Estimating noise and dimensionality in BCI data sets: Towards illiteracy comprehension. In G.R. Müller-Putz, C. Brunner, R. Leeb, G. Pfurtscheller, and C. Neuper, (Eds.), Proceedings of the 4th International brain– computer Interface Workshop and Training Course 2008, pp. 26–31, Verlag der Technischen Universität Graz, (2008).
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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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138 Y. Wang et al. which has been e
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140 Y. Wang et al. After many studi
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142 Y. Wang et al. Left Hand Right
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144 Y. Wang et al. 0-degree 60-degr
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146 Y. Wang et al. 3.1.2 Stimulatio
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148 Y. Wang et al. Foot 1 0.5 Left
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150 Y. Wang et al. be summarized as
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152 Y. Wang et al. Fig. 10 A player
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154 Y. Wang et al. 22. Y. Wang, R.
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156 N. Birbaumer and P. Sauseng C A
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158 N. Birbaumer and P. Sauseng 3 B
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160 N. Birbaumer and P. Sauseng pat
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162 N. Birbaumer and P. Sauseng Fig
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164 N. Birbaumer and P. Sauseng of
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166 N. Birbaumer and P. Sauseng Neu
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168 N. Birbaumer and P. Sauseng 8.
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Non Invasive BCIs for Neuroprosthes
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Brain-Computer Interfaces for Commu
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204 D.M. Taylor and M.E. Stetner mo
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206 D.M. Taylor and M.E. Stetner el
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208 D.M. Taylor and M.E. Stetner ac
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210 D.M. Taylor and M.E. Stetner de
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212 D.M. Taylor and M.E. Stetner Ma
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214 D.M. Taylor and M.E. Stetner pe
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216 D.M. Taylor and M.E. Stetner ev
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218 D.M. Taylor and M.E. Stetner fo
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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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Page 346 and 347: 340 A. Schlögl et al. yk = a1 · y
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Page 362 and 363: Toward Ubiquitous BCIs Brendan Z. A
Page 364 and 365: Toward Ubiquitous BCIs 359 BCI Chal
Page 366 and 367: Toward Ubiquitous BCIs 361 communic
Page 368 and 369: Toward Ubiquitous BCIs 363 facial m
Page 370 and 371: Toward Ubiquitous BCIs 365 The best
Page 372 and 373: Toward Ubiquitous BCIs 367 Across a
Page 374 and 375: Toward Ubiquitous BCIs 369 the ques
Page 376 and 377: Toward Ubiquitous BCIs 371 controll
Page 378 and 379: Toward Ubiquitous BCIs 373 controls
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Page 382 and 383: Toward Ubiquitous BCIs 377 Table 1
Page 384 and 385: Toward Ubiquitous BCIs 379 conversa
Page 386 and 387: Toward Ubiquitous BCIs 381 may down
Page 388 and 389: Toward Ubiquitous BCIs 383 physicis
Page 392 and 393: Toward Ubiquitous BCIs 387 67. G. S
Page 394 and 395: 390 Index 65, 157, 163, 217, 221-23
Page 396 and 397: 392 Index 208, 236, 243, 245, 260-2
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