Brainâ€“Computer Interfaces - Index of

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62 G. Pfurtscheller and C. Neuper 45. W. Klimesch, Memory processes, brain oscillations and EEG synchronization. J Psychophysiol, 24, 61–100, (1996). 46. F. Hummel, F. Andres, E. Altenmuller, et al., Inhibitory control of acquired motor programmes in the human brain. Brain, 125, 404–420, (2002). 47. E.D. Adrian and B.H. Matthews, The Berger rhythm: Potential changes from the occipital lobes in man. Brain, 57, 355–385, (1934). 48. M.H. Case and R.M. Harper, Somatomotor and visceromotor correlates of operantly conditioned 12–14 c/s sensorimotor cortical activity. Electroencephalogr Clin Neurophysiol, 31, 85–92, (1971). 49. W.N. Kuhlman, Functional topography of the human mu rhythm. Electroencephalogr Clin Neurophysiol, 44, 83–93, (1978). 50. C. Gerloff, J. Hadley, J. Richard, et al., Functional coupling and regional activation of human cortical motor areas during simple, internally paced and externally paced finger movements. Brain, 121, 1513–1531, (1998). 51. Y. Koshino and E. Niedermeyer, Enhancement of rolandic mu rhythm by pattern vision. Electroencephalogr Clin Neurophysiol, 38, 535–538, (1975). 52. N. Kreitmann and J.C. Shaw, Experimental enhancement of alpha activity. Electroencephalogr Clin Neurophysiol, 18, 147–155, (1965). 53. C. Neuper and W. Klimesch, Event-related dynamics of brain oscillations: Elsevier, (2006). 54. W.C. Drevets, H. Burton, T.O. Videen, et al., Blood flow changes in human somatosensory cortex during anticipated stimulation. Nature, 373, 249–252, (1995). 55. F. Hummel, R. Saur, S. Lasogga, et al., To act or not to act. Neural correlates of executive control of learned motor behavior. Neuroimage, 23, 1391–1401, (2004). 56. F. Hummel and C. Gerloff, Interregional long-range and short-range synchrony: a basis for complex sensorimotor processing. Progr Brain Res, 159, 223–236, (2006). 57. R. Salmelin, M. Hamalainen, M. Kajola, et al., Functional segregation of movement related rhythmic activity in the human brain. NeuroImage, 2, 237–243, (1995). 58. G. Pfurtscheller and F.H.L. da Silva, Event-related EEG/MEG synchronization and desynchronization: basic principles. Clin Neurophysiol, 110, 1842–1857, (1999). 59. C. Neuper and G. Pfurtscheller, Evidence for distinct beta resonance frequencies in human EEG related to specific sensorimotor cortical areas. Clin Neurophysiol, 112, 2084–2097, (2001). 60. G.R. Müller, C. Neuper, R. Rupp, et al., Event-related beta EEG changes during wrist movements induced by functional electrical stimulation of forearm muscles in man. Neurosci Lett, 340, 143–147, (2003). 61. G. Pfurtscheller, G. Krausz, and C. Neuper, Mechanical stimulation of the fingertip can induce bursts of beta oscillations in sensorimotor areas. J Clin Neurophysiol, 18, 559–564, (2001). 62. G. Pfurtscheller, C. Neuper, C. Brunner, et al., Beta rebound after different types of motor imagery in man. Neurosci Lett, 378, 156–159, (2005). 63. C. Neuper and G. Pfurtscheller, Motor imagery and ERD, In: G. Pfurtscheller and F. H. L. da Silva (Eds.), Event-related desynchronization. Handbook of electroenceph and clinical neurophysiology, vol. 6, Elsevier, Amsterdam„ pp. 303–325, (1999). 64. W. Singer, Synchronization of cortical activity and its putative role in information processing and learning. Annu Rev Psychophysiol, 55, 349–374, (1993). 65. R. Chen, B. Corwell, and M. Hallett, Modulation of motor cortex excitability by median nerve and digit stimulation. Expert Rev Brain Res, 129, 77–86, (1999). 66. A. Schnitzler, S. Salenius, R. Salmelin, et al., Involvement of primary motor cortex in motor imagery: a neuromagnetic study. NeuroImage, 6, 201–208, (1997). 67. G. Pfurtscheller, M. Wörtz, G.R. Müller, et al., Contrasting behavior of beta event-related synchronization and somatosensory evoked potential after median nerve stimulation during finger manipulation in man. Neurosci Lett, 323, 113–116, (2002). 68. A.P. Georgopoulos, J.F. Kalaska, R. Caminiti, et al., On the relations between the direction of two-dimensional arm movements and cell discharge in primate motor cortex. J NeuroSci Lett, 2, 1527–1537, (1982).
Dynamics of Sensorimotor Oscillations in a Motor Task 63 69. Z.J. Koles, M.S. Lazar, and S.Z. Zhou, Spatial patterns underlying population differences in the background EEG. Brain Topogr, 2, 275–284, (1990). 70. J. Müller-Gerking, G. Pfurtscheller, and H. Flyvbjerg, Designing optimal spatial filters for single-trial EEG classification in a movement task. Clin Neurophysiol, 110, 787–798, (1999). 71. J. Müller-Gerking, G. Pfurtscheller, and H. Flyvbjerg, Classification of movement-related EEG in a memorized delay task experiment. Clin Neurophysiol, 111, 1353–1365, (2000). 72. G. Pfurtscheller, C. Neuper, H. Ramoser, et al., Visually guided motor imagery activates sensorimotor areas in humans. Neurosci Lett, 269, 153–156, (1999). 73. E. Naito, P.E. Roland, and H.H. Ehrsson, I feel my hand moving: a new role of the primary motor cortex in somatic perception of limb movement, Neuron, 36, 979–988, (2002). 74. J. Annett, Motor imagery: perception or action? Neuropsychologia, 33, 1395–1417, (1995). 75. H.J. Gastaut and J. Bert, EEG changes during cinematographic presentation; moving picture activation of the EEG. Electroencephalogr Clin Neurophysiol, 6, 433–444, (1954). 76. S. Cochin, C. Barthelemy, B. Lejeune, et al., Perception of motion and qEEG activity in human adults. Electroencephalogr Clin Neurophysiol, 107, 287–295, (1998). 77. S.D. Muthukumaraswamy, B.W. Johnson, and N.A. McNair, Mu rhythm modulation during observation of an object-directed grasp. Cogn Brain Res, 19, 195–201, (2004). 78. E.L. Altschuler, A. Vankov, E.M. Hubbard, et al., Mu wave blocking by observation of movement and its possible use as a tool to study theory of other minds. Soc Neurosci Abstr, 26, 68, (2000). 79. G. Pfurtscheller, R.H. Grabner, C. Brunner, et al., Phasic heart rate changes during word translation of different difficulties. Psychophysiology, 44, 807–813, (2007). 80. G. Pfurtscheller, R. Scherer, R. Leeb, et al., Viewing moving objects in Virtual Reality can change the dynamics of sensorimotor EEG rhythms. Presence-Teleop Virt Environ, 16, 111– 118, (2007). 81. J.A. Pineda, The functional significance of mu rhythms: translating seeing and hearing into doing. Brain Res, 50, 57–68, (2005). 82. R. Hari, Action–perception connection and the cortical mu rhythm. Prog Brain Res, 159, 253–260, (2006). 83. V. Gallese, L. Fadiga, L. Fogassi, et al., Action recognition in the premotor cortex. Brain, 119, 593–609, (1996). 84. G. Rizzolatti, L. Fadiga, V. Gallese, et al., Premotor cortex and the recognition of motor actions. Cogn Brain Res, 3, 131–141, (1996). 85. G. Rizzolatti, L. Fogassi, and V. Gallese, Neurophysiological mechanisms underlying the understanding and imitation of action. Nat Rev Neurosci, 2, 661–670, (2001). 86. G. Buccino, F. Binkofski, G.R. Fink, et al., Action observation activates premotor and parietal areas in a somatotopic manner: an fMRI study. Eur J Neurosci, 13, 400–404, (2001). 87. J. Grézes and J. Decety, Functional anatomy of execution, mental simulation, observation, and verb generation of actions: a meta-analysis. Human Brain Mapp, 12, 1–19, (2001). 88. N. Nishitani and R. Hari, Temporal dynamics of cortical representation for action, Proc Natl Acad Sci, 97, 913–918, (2000). 89. J.M. Kilner and C.D. Frith, A possible role for primary motor cortex during action observation, Proc Natl Acad Sci, 104, 8683–8684, (2007). 90. F.L. da Silva, Event-related neural activities: what about phase? Prog Brain Res, 159, 3–17, (2006). 91. R. Hari, N. Forss, S. Avikainen, et al., Activation of human primary motor cortex during action observation: a neuromagnetic study. Proc Natl Acad Sci, 95, 15061–15065, (1998). 92. J. Järveläinen, M. Schürmann, S. Avikainen, et al., Stronger reactivity of the human primary motor cortex during observation of live rather than video motor acts. Neuroreport, 12, 3493– 3495, (2001). 93. G.R. Müller-Putz, R. Scherer, G. Pfurtscheller, et al., Brain-computer interfaces for control of neuroprostheses: from synchronous to asynchronous mode of operation, Biomedizinische Technik, 51, 57–63, (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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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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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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