Guido Dornhege scite author profile

Noninvasive electroencephalogram (EEG) recordings provide for easy and safe access to human neocortical processes which can be exploited for a brain-computer interface (BCI). At present, however, the use of BCIs is severely limited by low bit-transfer rates. We systematically analyze and develop two recent concepts, both capable of enhancing the information gain from multichannel scalp EEG recordings: 1) the combination of classifiers, each specifically tailored for different physiological phenomena, e.g., slow cortical potential shifts, such as the pre-movement Bereitschaftspotential or differences in spatio-spectral distributions of brain activity (i.e., focal event-related desynchronizations) and 2) behavioral paradigms inducing the subjects to generate one out of several brain states (multiclass approach) which all bare a distinctive spatio-temporal signature well discriminable in the standard scalp EEG. We derive information-theoretic predictions and demonstrate their relevance in experimental data. We will show that a suitably arranged interaction between these concepts can significantly boost BCI performances.

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Machine learning for real-time single-trial EEG-analysis: From brain–computer interfacing to mental state monitoring

Müller

Tangermann²,

Dornhege³

et al. 2008

Journal of Neuroscience Methods

418

229

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Combined Optimization of Spatial and Temporal Filters for Improving Brain-Computer Interfacing

Dornhege¹,

Blankertz²,

Krauledat

et al. 2006

IEEE Trans. Biomed. Eng.

354

211

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Brain-computer interface (BCI) systems create a novel communication channel from the brain to an output device by bypassing conventional motor output pathways of nerves and muscles. Therefore they could provide a new communication and control option for paralyzed patients. Modern BCI technology is essentially based on techniques for the classification of single-trial brain signals. Here we present a novel technique that allows the simultaneous optimization of a spatial and a spectral filter enhancing discriminability rates of multichannel EEG single-trials. The evaluation of 60 experiments involving 22 different subjects demonstrates the significant superiority of the proposed algorithm over to its classical counterpart: the median classification error rate was decreased by 11%. Apart from the enhanced classification, the spatial and/or the spectral filter that are determined by the algorithm can also be used for further analysis of the data, e.g., for source localization of the respective brain rhythms.

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The Berlin brain-computer interface: EEG-based communication without subject training

Blankertz¹,

Dornhege²,

Krauledat³

et al. 2006

IEEE Trans. Neural Syst. Rehabil. Eng.

269

171

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The Berlin Brain-Computer Interface (BBCI) project develops a noninvasive BCI system whose key features are 1) the use of well-established motor competences as control paradigms, 2) high-dimensional features from 128-channel electroencephalogram (EEG), and 3) advanced machine learning techniques. As reported earlier, our experiments demonstrate that very high information transfer rates can be achieved using the readiness potential (RP) when predicting the laterality of upcoming left- versus right-hand movements in healthy subjects. A more recent study showed that the RP similarily accompanies phantom movements in arm amputees, but the signal strength decreases with longer loss of the limb. In a complementary approach, oscillatory features are used to discriminate imagined movements (left hand versus right hand versus foot). In a recent feedback study with six healthy subjects with no or very little experience with BCI control, three subjects achieved an information transfer rate above 35 bits per minute (bpm), and further two subjects above 24 and 15 bpm, while one subject could not achieve any BCI control. These results are encouraging for an EEG-based BCI system in untrained subjects that is independent of peripheral nervous system activity and does not rely on evoked potentials even when compared to results with very well-trained subjects operating other BCI systems.

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Guido Dornhege

The non-invasive Berlin Brain–Computer Interface: Fast acquisition of effective performance in untrained subjects

Boosting bit rates in noninvasive EEG single-trial classifications by feature combination and multiclass paradigms

Machine learning for real-time single-trial EEG-analysis: From brain–computer interfacing to mental state monitoring

Combined Optimization of Spatial and Temporal Filters for Improving Brain-Computer Interfacing

The Berlin brain-computer interface: EEG-based communication without subject training

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