A review of user training methods in brain computer interfaces based on mental tasks

Roc, Aline; Pillette, Léa; Mladenović, Jelena; Benaroch, Camille; N’Kaoua, Bernard; Jeunet, Camille; Lotte, Fabien

doi:10.1088/1741-2552/abca17

Cited by 79 publications

(78 citation statements)

References 268 publications

(552 reference statements)

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“…For the competition day, we needed a previously trained classifier to avoid calibration time. Moreover, recalibrating the classifier everyday could lead to an ever-changing feedback which may be detrimental to user training (Perdikis et al, 2018;Perdikis and Millan, 2020;Roc et al, 2020). Therefore, for the transfer phase (session 12 and subsequent) we calibrated our classifier based on the runs from the previous phase sessions that were the least noisy and the least contaminated by artifacts.…”

Section: Signal Processing and Machine Learningmentioning

confidence: 99%

“…A progressive training seem essential for BCI as its efficiency relies on the users' ability to produce EEG patterns that are stable over time and distinct between the different mental commands (McFarland et al, 2010;Chavarriaga et al, 2016). Although improving users' ability to produce such signals through user training can certainly help the participants in controlling MT-BCI (Lotte and Jeunet, 2015;Perdikis and Millan, 2020;Roc et al, 2020), various sources of variability can lead to large shifts of data distribution between different sessions and consequently between the BCI classifier testing and training sets. Beside the largely unknown phenomena in the activity of neuronal populations which lead to non-stationarity of EEG signal (Kaplan et al, 2005), some variability sources including various environmental noises and changes in users' mental states such as their attention, fatigue or stress level are expected in an actual practice such as the CYBATHLON competition.…”

Section: Introductionmentioning

confidence: 99%

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Long-Term BCI Training of a Tetraplegic User: Adaptive Riemannian Classifiers and User Training

Benaroch

Sadatnejad

Roc

et al. 2021

Front. Hum. Neurosci.

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While often presented as promising assistive technologies for motor-impaired users, electroencephalography (EEG)-based Brain-Computer Interfaces (BCIs) remain barely used outside laboratories due to low reliability in real-life conditions. There is thus a need to design long-term reliable BCIs that can be used outside-of-the-lab by end-users, e.g., severely motor-impaired ones. Therefore, we propose and evaluate the design of a multi-class Mental Task (MT)-based BCI for longitudinal training (20 sessions over 3 months) of a tetraplegic user for the CYBATHLON BCI series 2019. In this BCI championship, tetraplegic pilots are mentally driving a virtual car in a racing video game. We aimed at combining a progressive user MT-BCI training with a newly designed machine learning pipeline based on adaptive Riemannian classifiers shown to be promising for real-life applications. We followed a two step training process: the first 11 sessions served to train the user to control a 2-class MT-BCI by performing either two cognitive tasks (REST and MENTAL SUBTRACTION) or two motor-imagery tasks (LEFT-HAND and RIGHT-HAND). The second training step (9 remaining sessions) applied an adaptive, session-independent Riemannian classifier that combined all 4 MT classes used before. Moreover, as our Riemannian classifier was incrementally updated in an unsupervised way it would capture both within and between-session non-stationarity. Experimental evidences confirm the effectiveness of this approach. Namely, the classification accuracy improved by about 30% at the end of the training compared to initial sessions. We also studied the neural correlates of this performance improvement. Using a newly proposed BCI user learning metric, we could show our user learned to improve his BCI control by producing EEG signals matching increasingly more the BCI classifier training data distribution, rather than by improving his EEG class discrimination. However, the resulting improvement was effective only on synchronous (cue-based) BCI and it did not translate into improved CYBATHLON BCI game performances. For the sake of overcoming this in the future, we unveil possible reasons for these limited gaming performances and identify a number of promising future research directions. Importantly, we also report on the evolution of the user's neurophysiological patterns and user experience throughout the BCI training and competition.

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Section: Signal Processing and Machine Learningmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Long-Term BCI Training of a Tetraplegic User: Adaptive Riemannian Classifiers and User Training

Benaroch

Sadatnejad

Roc

et al. 2021

Front. Hum. Neurosci.

Self Cite

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“…In order to improve BCI reliability, it is thus highly relevant to identify, control and manipulate the factors affecting users' states. Among these many factors (e.g., instructions, feedback or exercise design) our literature review presented above suggests that the experimental environment may have a major influence, notably experimenters [42]. Despite the central role that experimenters have in BCI experimental process and the literature regarding the impact of social presence and emotional feedback, no studies had yet been led to evaluate their influence on MI-BCI experimental outcomes, i.e., performances and user-training.…”

Section: Research Hypothesesmentioning

confidence: 99%

Experimenters' Influence on Mental-Imagery based Brain-Computer Interface User Training

Pillette

Roc

N’Kaoua

et al. 2021

International Journal of Human-Computer Studies

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Motor Imagery based Brain-Computer Interfaces (MI-BCIs) enable their users to interact with digital technologies, e.g., neuroprosthesis, by performing motor imagery tasks only, e.g., imagining hand movements, while their brain activity is recorded. To control MI-BCIs, users must train to control their brain activity. During such training, experimenters have a fundamental role, e.g., they motivate participants. However, their influence had never been formally assessed for MI-BCI user training. In other fields, e.g., social psychology, experimenters' gender was found to influence experimental outcomes, e.g., behavioural or neurophysiological measures. ObjectiveOur aim was to evaluate if the experimenters' gender influenced MI-BCI user training outcomes, i.e., performances and user-experience. MethodsWe performed an experiment involving 6 experimenters (3 women) each training 5 women and 5 men (60 participants) to perform right versus left hand MI-BCI tasks over one session.We then studied the training outcomes, i.e., MI-BCI performances and user-experience, according to the experimenters' and subjects' gender. ResultsA significant interaction between experimenters' and participants' gender was found on the evolution of trial-wise performances. Another interaction was found between participants' tension and experimenters' gender on the average performances. ConclusionExperimenters' gender could influence MI-BCI performances depending on participants' gender and tension.

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“…Intense performance fluctuations during and, especially, across BCI sessions [16] and the inability of a large portion of users to get into control of a BCI have been early identified as [17], and still remain today [18], the main obstacles towards deploying BCI technology in real-world scenarios [19]- [23]. SMR-based BCIs are known to be particularly vulnerable to these issues [18], [24]- [27].…”

Section: Introductionmentioning

confidence: 99%

“…(10)(11)(12)(13) Hz) β low(16)(17)(18)(19)(20)(21)(22)(23)(24) β high(24)(25)(26)(27)(28)(29)(30)(31)(32) S1 Evidence of sensorimotor rhythm modulation during coadaptive training. (a) ERD/ERS maps of best performer S1 (right-handed) throughout the session.…”

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confidence: 99%

Post-Adaptation Effects in a Motor Imagery Brain-Computer Interface Online Coadaptive Paradigm

et al. 2021

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Online coadaptive training has been successfully employed to enable people to control motor imagery (MI)-based brain-computer interfaces (BCIs), allowing to completely skip the lengthy and demotivating open-loop calibration stage traditionally applied before closed-loop control. However, practical reasons may often dictate to eventually switch off decoder adaptation and proceed with BCI control under a fixed BCI model, a situation that remains rather unexplored. This work studies the existence and magnitude of potential post-adaptation effects on system performance, subject learning and brain signal modulation stability in a state-of-the-art, coadaptive training regime inspired by a game-like design. The results extracted in a cohort of 20 able-bodied individuals reveal that ceasing classifier adaptation after three runs (approx. 30 min) of a single-session training protocol had no significant impact on any of the examined BCI control and learning aspects in the remaining two runs (about 20 min) with a fixed classifier. Fifteen individuals achieved accuracies that are better than chance level and allowed them to successfully execute the given task. These findings alleviate a major concern regarding the applicability of coadaptive MI BCI training, thus helping to further establish this training approach and allow full exploitation of its benefits.

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A review of user training methods in brain computer interfaces based on mental tasks

Cited by 79 publications

References 268 publications

Long-Term BCI Training of a Tetraplegic User: Adaptive Riemannian Classifiers and User Training

Long-Term BCI Training of a Tetraplegic User: Adaptive Riemannian Classifiers and User Training

Experimenters' Influence on Mental-Imagery based Brain-Computer Interface User Training

Post-Adaptation Effects in a Motor Imagery Brain-Computer Interface Online Coadaptive Paradigm

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