Abstract
In this article, non-invasive hybrid brain–computer interface (hBCI) technologies for improving classification accuracy and increasing the number of commands are reviewed. Hybridization combining more than two modalities is a new trend in brain imaging and prosthesis control. Electroencephalography (EEG), due to its easy use and fast temporal resolution, is most widely utilized in combination with other brain/non-brain signal acquisition modalities, for instance, functional near infrared spectroscopy (fNIRS), electromyography (EMG), electrooculography (EOG), and eye tracker. Three main purposes of hybridization are to increase the number of control commands, improve classification accuracy and reduce the signal detection time. Currently, such combinations of EEG + fNIRS and EEG + EOG are most commonly employed. Four principal components (i.e., hardware, paradigm, classifiers, and features) relevant to accuracy improvement are discussed. In the case of brain signals, motor imagination/movement tasks are combined with cognitive tasks to increase active brain–computer interface (BCI) accuracy. Active and reactive tasks sometimes are combined: motor imagination with steady-state evoked visual potentials (SSVEP) and motor imagination with P300. In the case of reactive tasks, SSVEP is most widely combined with P300 to increase the number of commands. Passive BCIs, however, are rare. After discussing the hardware and strategies involved in the development of hBCI, the second part examines the approaches used to increase the number of control commands and to enhance classification accuracy. The future prospects and the extension of hBCI in real-time applications for daily life scenarios are provided.
Highlights
Electroencephalography (EEG) and functional near infrared spectroscopy endow brain– computer interfaces (BCIs) with their essential and indispensable attributes of non-invasiveness, low cost, and portability
The results showed that training with Motor imagery (MI)-based BCI affects cortical activations, especially with those subjects showing a low BCI performance
Whereas EMG/EOG combined with EEG can be used for control applications, the most significant breakthrough in hybrid brain–computer interface (hBCI) is the design of hybrid EEG–NIRS that can simultaneously decode electrical and hemodynamic brain activities
Summary
Electroencephalography (EEG) and functional near infrared spectroscopy (fNIRS) endow brain– computer interfaces (BCIs) with their essential and indispensable attributes of non-invasiveness, low cost, and portability. The combination of EEG and EOG is important to the improvement of the classification accuracy of BCI systems by artifact removal (Zhang et al, 2010) This combination can be used to increase the number of control commands. The first study on hybrid EEG–NIRS for application to BCI appeared in 2012 (Fazli et al, 2012) It showed that the combination of fNIRS’s features (HbO and HbR) and EEG features increases the classification accuracy. We briefly include the cases in which multiple tasks are detected simultaneously using a single modality, the “hybrid” term is not used This has been done in recent studies on fNIRS, wherein MI and MA tasks have been combined for the generation of multiple BCI commands (Hong et al, 2015; Naseer and Hong, 2015a). Application Application to BCI applications (wheelchair control) Speller paradigm with applications to BCI systems control Turtle movement control Choice selection
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