Brainâ€“Computer Interfaces - Index of

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110 E.W. Sellers et al. 22. D.J Krusienski, E.W Sellers, D.J McFarland, T.M Vaughan, and J.R. Wolpaw, Toward enhanced P300 speller performance. J Neurosci Methods, 167, 15–21, (2008). 23. A. Kübler, et al., Self-regulation of slow cortical potentials in completely paralyzed human patients. Neurosci Lett, 252, 171–174, (1998). 24. A. Kübler, et al., Patients with ALS can use sensorimotor rhythms to operate a brain-computer interface. Neurology, 64, 1775–1777, (2005). 25. 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(7099) 164–171, (2006, Juli 13). 26. G.R. Mangun, S.A. Hillyard, and S.J. Luck, Electrocortical substrates of visual selective attention, In D. Meyer, and S. Kornblum (Eds.), Attention and performance XIV, MIT Press, Cambridge, MA, pp. 219–243, (1993). 27. D.J. McFarland, D.J. Krusienski, WA. Sarnacki, and J.R. Wolpaw, Emulation of computer mouse control with a noninvasive brain-computer interface. J Neural Eng, 5, 101–110, (2008). 28. D.J. McFarland, D.J. Krusienski, W.A. Sarnacki, and J.R. Wolpaw, Brain-computer interface signal processing at the Wadsworth Center: mu and sensorimotor beta rhythms. Prog Brain Res, 159, 411–419, (2006) 29. D.J. McFarland, L.A. Miner, T.M. Vaughan, and J.R. Wolpaw, Mu and beta rhythm topographies during motor imagery and actual movements. Brain Topogr, 12, (2000). 30. D.J. McFarland, G. W. Neat, R.F. Read, and J.R. Wolpaw, An EEG-based method for graded cursor control. Psychobiology, 21, 77–81, (1993). 31. D.J. McFarland, W.A Sarnacki, T.M Vaughan, and J.R. Wolpaw, Brain-computer interface (BCI) operation: signal and noise during early training sessions. Clin Neurophysiol, 116, 56–62, (2005). 32. D.J. McFarland, W.A. Sarnacki, and J.R. Wolpaw, Brain-computer interface (BCI) operation: optimizing information transfer rates. Biol Psychol, 63, 237–251, (2003). 33. D.J. McFarland, W.A. Sarnacki, and J.R. Wolpaw, Electroencephalographic (EEG) control of three-dimensional movement. Program No. 778.4. Abstract Viewer/Itinerary Planner. Washington, DC: Society for Neuroscience. Online, (2008). 34. D.J. McFarland and J.R. Wolpaw, Sensorimotor rhythm-based brain-computer interface (BCI): Feature selection by regression improves performance, IEEE Trans Neural Syst Rehabil Eng, 13, 372–379, (2005). 35. D.J. McFarland and J.R. Wolpaw, Brain-computer interface operation of robotic and prosthetic devices. IEEE Comput, 41, 52–56, (2008) 36. P. Meinicke, M. Kaper, F. Hoppe, M. Huemann, and H. Ritter, Improving transfer rates in brain computer interface: A case study. Neural Inf Proc Syst, 1107–1114, (2002). 37. K.R. Muller, C.W. Anderson, and G E. Birch, Linear and nonlinear methods for braincomputer interfaces. IEEE Trans Neural Syst Rehabil Eng, 11, 165–169, (2003). 38. F. Nijboer, E.W. Sellers, J. Mellinger, M.A. Jordan, Matuz, T. A. Furdea, U. Mochty, D.J. Krusienski, T.M. Vaughan, J.R. Wolpaw, N. Birbaumer, and A. Kübler, A brain-computer interface for people with amyotrophic lateral sclerosis. Clin Neurophysiol, 119, 1909–1916. (2008). 39. G. Pfurtscheller, D. Flotzinger, and J. Kalcher, Brain-computer interface- a new communication device for handicapped persons. J Microcomput Appl, 16, 293–299, (1993). 40. G. Pfurtscheller, and F.H. Lopes da Silva, Event-related EEG/MEG synchronization and desynchronization: basic principles, Clin Neurophysiol, 110, 1842–1857, (1999). 41. F. Piccione, et al., P300-based brain computer interface: Reliability and performance in healthy and paralysed participants. Clin Neurophysiol, 117, 531–537, (2006). 42. J. Polich, Habituation of P300 from auditory stimuli, Psychobiology, 17, 19–28, (1989). 43. J. Polich, Updating P300: An integrative theory of P3a and P3b. Clinical Neurophysiology, 118, 2128–2148, (2007). 44. W. Pritchard, The psychophysiology of P300. Psychol Bull, 89, 506–540, (1981). 45. E.W. Sellers, et al., A P300 brain-computer interface (BCI) for in-home everyday use, Poster presented at the Society for Neuroscience annual meeting, Atlanta, GA, (2006).
BCIs in the Laboratory and at Home: The Wadsworth Research Program 111 46. E.W. Sellers et al., Brain-Computer Interface for people with ALS: long-term daily use in the home environment, Program No. 414.5. Abstract Viewer/Itinerary Planner. Washington, DC: Society for Neuroscience. Online, (2007). 47. E.W. Sellers and M. Donchin, A P300-based brain-computer interface: Initial tests by ALS patients, Clinical Neurophysiology. Clin Neurophysiology, 117, 538–548, (2006). 48. E.W Sellers, D.J Krusienski, D.J McFarland, T.M Vaughan, and J.R. Wolpaw, A P300 eventrelated potential brain-computer interface (BCI): The effects of matrix size and inter stimulus interval on performance. Biol Psychol, 73, 242–252, (2006). 49. E.E. Sutter, The brain response interface: communication through visually guided electrical brain responses. J Microcomput Appl, 15, 31–45, (1992). 50. S. Sutton M. Braren J. Zubin, and E.R. John, Evoked-potential correlates of stimulus uncertainty. Science, 150, 1187–1188, (1965). 51. D.M Taylor, S.I Tillery, A.B. Schwartz, Direct cortical control fo 3D reuroprosthetic devices. Science, 296, 1817–1818, (2002). 52. T.M. Vaughan, et al., aily use of an EEG-based brain-computer interface by people with ALS: technical requirements and caretaker training, Program No. 414.6. Abstract Viewer/Itinerary Planner, Society for Neuroscience, Washington, DC, online, (2007). 53. T.M Vaughan D.J. McFarland G. Schalk E. Sellers, and J.R. Wolpaw, Multichannel data from a brain-computer interface (BCI) speller using a P300 (i.e., oddball) protocol, Society for Neuroscience Abstracts, 28, (2003). 54. T.M Vaughan D.J McFarland G. Schalk W.A Sarnacki L. Robinson, and J.R Wolpaw EEGbased brain-computer interface: development of a speller application. Soc Neuroscie Abs, 26, (2001). 55. T.M.Vaughan et al., The Wadsworth BCI research and development program: At home with BCI. IEEE Trans Rehabil Eng, l(14), 229–233, (2006). 56. J.R. Wolpaw, N. Birbaumer, D.J. McFarland, G. Pfurtscheller, and T.M. Vaughan, Braincomputer interfaces for communication and control. Clin Neurophysiol, 113, 767–791, (2002). 57. 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). 58. JR. Wolpaw, et al., Brain-computer interface technology: a review of the first international meeting, IEEE Trans Rehabil Eng, 8, 164–173, (2000). 59. J.R. Wolpaw and D.J. McFarland, Multichannel EEG-based brain-computer communication. Electroencephalogr Clin Neurophysiol, 90, 444–449, (1994). 60. J.R. Wolpaw, D.J. McFarland, G.W. Neat, and C.A. Forneris, An EEG-based brain-computer interface for cursor control. Electroencephalogr Clin Neurophysiol, 78, 252–259, (1991).
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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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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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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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