Brain-based control of car infotainment

April 24, 2020 Β· Declared Dead Β· πŸ› IEEE International Conference on Systems, Man and Cybernetics

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Authors Andrea Bellotti, Sergey Antopolskiy, Anna Marchenkova, Alessia Colucciello, Pietro Avanzini, Giovanni Vecchiato, Jonas Ambeck-Madsen, Luca Ascari arXiv ID 2004.11978 Category cs.HC: Human-Computer Interaction Cross-listed cs.LG, eess.SP, q-bio.NC Citations 4 Venue IEEE International Conference on Systems, Man and Cybernetics Last Checked 4 months ago
Abstract
Nowadays, the possibility to run advanced AI on embedded systems allows natural interaction between humans and machines, especially in the automotive field. We present a custom portable EEG-based Brain-Computer Interface (BCI) that exploits Event-Related Potentials (ERPs) induced with an oddball experimental paradigm to control the infotainment menu of a car. A preliminary evaluation of the system was performed on 10 participants in a standard laboratory setting and while driving on a closed private track. The task consisted of repeated presentations of 6 different menu icons in oddball fashion. Subject-specific models were trained with different machine learning approaches on cerebral data from either only laboratory or driving experiments (in-lab and in-car models) or a combination of the two (hybrid model) to classify EEG responses to target and non-target stimuli. All models were tested on the subjects' last in-car sessions that were not used for the training. Analysis of ERPs amplitude showed statistically significant (p < 0.05) differences between the EEG responses associated with target and non-target icons, both in the laboratory and while driving. Classification Accuracy (CA) was above chance level for all subjects in all training configurations, with a deep CNN trained on the hybrid set achieving the highest scores (mean CA = 53 $\pm$ 12 %, with 16 % chance level for the 6-class discrimination). The ranking of the features importance provided by a classical BCI approach suggests an ERP-based discrimination between target and non-target responses. No statistical differences were observed between the CAs for the in-lab and in-car training sets, nor between the EEG responses in these conditions, indicating that the data collected in the standard laboratory setting could be readily used for a real driving application without a noticeable decrease in performance.
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