Brainâ€“Computer Interfaces - Index of

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42 J.R. Wolpaw and C.B. Boulay 29. T.M. Vaughan, E.W. Sellers, D.J. McFarland, C.S. Carmack, P. Brunner, P.A. Fudrea, E.M. Braun, S.S. Lee, A. Kübler, S.A. Mackler, D.J. Krusienski, R.N. Miller, and J.R. Wolpaw, Daily use of an EEG-based brain-computer interface by people with ALS: technical requirements and caretaker training. Program No. 414.6. 2007 Abstract Viewer/Itinerary Planner. Society for Neuroscience, Washington, DC, (2007). Online. 30. E.W. Sellers, D.J. Krusienski, D.J. McFarland, T.M. Vaughan, and J.R. Wolpaw, A P300 event-related potential brain-computer interface (BCI): The effects of matrix size and inter stimulus interval on performance. Biol Psychol, 73, 242–252, (2006). 31. A.A. Glover, Onofrj, M.C. M.F. Ghilardi, and I. Bodis-Wollner, P300-like potentials in the normal monkey using classical conditioning and the “oddball” paradigm. Electroencephalogr Clin Neurophysiol, 65, 231–235, (1986). 32. B. Roder, F. Rosler, E. Hennighausen, and F. Nacker, Event-related potentials during auditory and somatosensory discrimination in sighted and blind human subjects. Brain Res, 4, 77–93, (1996). 33. N. Birbaumer, Slow cortical potentials: their origin, meaning, and clinical use. In: G.J.M. van Boxtel and K.B.E. Bocker (Eds.), Brain and behavior past, present, and future, Tilburg Univ Press, Tilburg, pp 25–39, (1997). 34. B. Rockstroh, T. Elbert, A. Canavan, W. Lutzenberger, and N. Birbaumer, Slow cortical potentials and behavior, Urban and Schwarzenberg, Baltimore, MD, (1989). 35. N. Birbaumer, T. Elbert, A.G.M. Canavan, and B. Rockstroh, Slow potentials of the cerebral cortex and behavior. Physiol Rev, 70, 1–41, (1990). 36. N. Birbaumer, T. Hinterberger, A. Kubler, and N. Neumann, The thought-translation device (TTD): neurobehavioral mechanisms and clinical outcome. IEEE Trans Neural Syst Rehabil Eng, 11, 120–123, (2003). 37. T. Elbert, B. Rockstroh, W. Lutzenberger, and N. Birbaumer Biofeedback of slow cortical potentials. I. Electroencephalogr Clin Neurophysiol, 48, 293–301, (1980). 38. W. Lutzenberger, T. Elbert, B. Rockstroh, and N. Birbaumer, Biofeedback of slow cortical potentials. II. Analysis of single event-related slow potentials by time series analysis. Electroencephalogr Clin Neurophysiol 48, 302–311, (1980). 39. M. Pham, T. Hinterberger, N. Neumann, et al., An auditory brain-computer interface based on the self-regulation of slow cortical potentials. Neurorehabil Neural Repair, 19, 206–218, (2005). 40. N. Birbaumer, N. Ghanayim, T. Hinterberger, et al., A spelling device for the paralysed. Nature, 398, 297–298, (1999). 41. E. Niedermeyer, The Normal EEG of the Waking Adult. In: E. Niedermeyer E and F.H.L. da Silva (Eds.), Electroencephalography: Basic principles, clinical applications, and related fields, Williams and Wilkins, Baltimore, pp. 167–192, (2004). 42. P. Fries, D. Nikolic, and W. Singer, The gamma cycle. Trends Neurosci, 30, 309–316, (2007). 43. SM. Montgomery and G. Buzsaki, Gamma oscillations dynamically couple hippocampal CA3 and CA1 regions during memory task performance. Proc Natl Acad Sci USA, 104, 14495–14500, (2007). 44. W. Singer, Neuronal synchrony: a versatile code for the definition of relations? Neuron, 24, 49–65, 111–125, (1999). 45. BJ. Fisch, Fisch and Spehlmann’s third revised and enlarged EEG primer, Elsevier, Amsterdam, (1999). 46. H. Gastaut, Étude electrocorticographique de la réacivité des rythmes rolandiques. Rev Neurol, 87, 176–182, (1952). 47. F.H.L. da Silva, Neural mechanisms underlying brain waves: from neural membranes to networks. Electroencephalogr Clin Neurophysiol, 79, 81–93, (1991). 48. D.J. McFarland L.A. Miner T.M. Vaughan J.R., and Wolpaw Mu and Beta rhythm topographies during motor imagery and actual movements. Brain Topogr 12, 177–186, (2000). 49. G. Pfurtscheller, EEG event-related desynchronization (ERD) and event-related synchronization (ERS). In: E. Niedermeyer and L.F.H. da Silva (Eds.), Electroencephalography: Basic principles, clinical aapplications and related fields. Williams and Wilkins, Baltimore, MD, pp. 958–967, (1999).
Brain Signals for Brain–Computer Interfaces 43 50. G. Pfurtscheller and A. Berghold, Patterns of cortical activation during planning of voluntary movement. Clin Neurophysiol, 72, 250–258, (1989). 51. G. Pfurtscheller and F.H.L. da Silva, Event-related EEG/MEG synchronization and desynchronization: basic principles. Clin Neurophysiol, 110, 1842–1857, (1999). 52. G. Pfurtscheller and C. Neuper, Motor imagery activates primary sensorimotor area in humans. Neurosci Lett, 239, 65–68, (1997). 53. O. Bai, P. Lin, S. Vorbach, M.K. Floeter, N. Hattori, and M. Hallett, A high performance sensorimotor beta rhythm-based brain-computer interface associated with human natural motor behavior. J Neural Eng, 5, 24–35, (2008). 54. B. Blankertz, G. Dornhege, M. Krauledat, K.R. Muller, and G. Curio, The non-invasive Berlin Brain-Computer Interface: fast acquisition of effective performance in untrained subjects. NeuroImage, 37, 539–550, (2007). 55. F. Cincotti, D. Mattia, F. Aloise, et al., Non-invasive brain-computer interface system: towards its application as assistive technology. Brain Res Bull, 75, 796–803, (2008). 56. A. Kostov and M. Polak, Parallel man-machine training in development of EEG-based cursor control. IEEE Trans Rehab Engin, 8, 203–205, (2000). 57. G. Pfurtscheller, B. Graimann J.E. Huggins, and S.P. Levine, Brain-computer communication based on the dynamics of brain oscillations. Supplements to Clin Neurophysiol, 57, 583–591, (2004). 58. 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). 59. J.R. Wolpaw, D.J. McFarland, G.W. Neat, and C.A. Forneris, An EEG-based brain-computer interface for cursor control. Clin Neurophysiol, 78, 252–259, (1991). 60. 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). 61. D.J. McFarland, T. Lefkowicz, and J.R. Wolpaw, Design and operation of an EEG-based brain-computer interface (BCI) with digital signal processing technology. Beh Res Meth, 29, 337–345, (1997). 62. J.R. Wolpaw, and D.J. McFarland, Control of a two-dimensional movement signal by a noninvasive brain-computer interface in humans. Proc Natl Acad Sci USA, 101, 17849–17854, (2004). 63. J.R. Wolpaw, D.J. McFarland, and T.M. Vaughan, Brain-computer interface research at the Wadsworth Center. IEEE Trans Rehabil Eng 8, 222–226, (2000). 64. L.A. Miner, D.J. McFarland, J.R. Wolpaw, Answering questions with an electroencephalogram-based brain-computer interface. Arch Phys Med Rehabil, 79, 1029–1033, (1998). 65. T.M. Vaughan, D.J. McFarland, G. Schalk, W.A. Sarnacki, L. Robinson, and J.R. Wolpaw, EEG-based brain-computer-interface: development of a speller. Soc Neurosci Abst 27, 167, (2001). 66. J.R. Wolpaw, H. Ramoser, D.J. McFarland, and G. Pfurtscheller, EEG-based communication: improved accuracy by response verification. IEEE Trans Rehab Eng, 6, 326–333, (1998). 67. D.J. McFarland, W.A. Sarnacki, and J.R. Wolpaw, Electroencephalographic (EEG) control of three-dimensional movement. J. Neural Eng., 11, 7(3):036007, (2010). 68. C. Neuper, A. Schlogl, and G. Pfurtscheller, Enhancement of left-right sensorimotor EEG differences during feedback-regulated motor imagery. J Clin Neurophysiol, 16, 373–382, (1999). 69. G. Pfurtscheller D. Flotzinger, and J. Kalcher, Brain-computer interface – a new communication device for handicapped persons. J Microcomput Appl, 16, 293–299, (1993). 70. G. Pfurtscheller, C. Guger, G. Muller, G. Krausz, and C. Neuper, Brain oscillations control hand orthosis in a tetraplegic. Neurosci Lett, 292, 211–214, (2000). 71. G. Pfurtscheller, C. Neuper, C. Guger, et al., Current trends in Graz Brain-Computer Interface (BCI) research. IEEE Trans Rehabil Eng, 8, 216–219, (2000).
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THE FRONTIERS COLLECTION
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Bernhard Graimann · Brendan Alliso
Page 6 and 7: Preface It’s an exciting time to
Page 8 and 9: Contents Brain-Computer Interfaces:
Page 10 and 11: Contributors Brendan Allison Instit
Page 12 and 13: Contributors xi Femke Nijboer Insti
Page 14 and 15: List of Abbreviations ADHD Attentio
Page 16 and 17: Brain-Computer Interfaces: A Gentle
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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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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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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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