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Neuroscience based design: Fundamentals and applications

: Sourina, Olga; Liu, Yisi; Hou, Xiyuan; Lim, Wei Lun; Müller-Wittig, Wolfgang K.; Wang, Lipo; Konovessis, Dimitrios; Chen, Chun-Hsien; Ang, Wei Tech


Sourin, Alexei (Ed.):
International Conference on Cyberworlds, CW 2016. Proceedings : 28-30 September 2016, Chongqing, China
Los Alamitos, Calif.: IEEE Computer Society Conference Publishing Services (CPS), 2016
ISBN: 978-1-5090-2303-5
International Conference on Cyberworlds (CW) <2016, Chongqing>
Fraunhofer IDM@NTU ()
human factors; neuroergonomic; Electroencephalography (EEG); emotions; stress; Neurofeedback; product design; Guiding Theme: Digitized Work; Research Area: Human computer interaction (HCI)

Neuroscience-based or neuroscience-informed design is a new application area of Brain-Computer Interaction (BCI). It takes its roots in study of human well-being in architecture, human factors study in engineering and manufacturing including neuroergonomics. In traditional human factors studies and/or well-being study, mental workload, stress, and emotion are obtained through questionnaires that are administered upon completion of some task and/or the whole experiment. Recent advances in BCI research allow for using Electroencephalogram (EEG) based brain state recognition algorithms to assess the interaction between brain and human performance.
We propose and develop an EEG-based system CogniMeter to monitor and analyze human factors measurements of newly designed software/hardware systems and/or working places. Machine learning techniques are applied to the EEG data to recognize levels of mental workload, stress and emotions during each task. The EEG is used as a tool to monitor and record the brain states of subjects during human factors study experiments. We describe two applications of CogniMeter system: human performance assessment in maritime simulator and EEG-based human factors evaluation in Air Traffic Control (ATC) workplace. By utilizing the proposed EEG-based system, true understanding of subjects working patterns can be obtained. Based on the analyses of the objective real time EEG-based data together with the subjective feedback from the subjects, we are able to reliably evaluate current systems/hardware and/or working place design and refine new concepts and design of future systems.