doi:10.1002/9783527673148.ch19brain–computer interfaceneuroethicscloningneuromotor prosthesesethicsBCIcybernetic technologybrain‐machine interfacesMcGeeEllen MWiley‐VCH Verlag GmbH & Co. KGaABrain-Computer Interfaces: Ethical and Policy Considerations 411 Ellen M. McGee...
personalized brain–computer interface (pBCI); specific BCI user; customized brain–computer interface (cBCI); general brain–computer interface (gBCI); brain–computer interface (BCI) 1. Introduction Brain–computer interfaces (BCIs) are designed to bypass users’ nerves and muscles to realize ...
Brain–Computer Interface (BCI); Cognitive Vigilance Task (CVT); Multi-Modal Integrated Task (MMIT); stress; distress 1. Introduction 1.1. Quantifying Stress with a BCI System Stress is a common feature in high-pressure environments with high cognitive loading, such as air traffic control centers...
artificial intelligence; machine learning; affective computing; automatic emotion analysis; brain–computer interface; Industry 5.0; occupational stress; burnout; work–life balance; well-being 1. Introduction New times call for new solutions. The threat of depression and professional burnout is a real ...
In modern brain–computer interface (BCI) design, the BCI is a direct link between the brain of a person and a computer [1]. More precisely, BCI is a system that measures and processes the nervous system activity used by a computer to restore and/or replace the natural output of the br...
This article examines state-of-the-art research into the impact of virtual reality (VR) on brain–computer interface (BCI) performance: how the use of virtual reality can affect brain activity and neural plasticity in ways that can improve the performance of brain–computer interfaces in IoT con...
brain–computer interface (BCI); ethics; media; public discourse 1. Introduction The advent of medicine and medical technology has had an immeasurable impact on human history [1]. Medical technology has the potential to cure diseases that may have once been a death sentence, take away ...
Objective: We designed and validated a wireless, low-cost, easy-to-use, mobile, dry-electrode headset for scalp electroencephalography (EEG) recordings for closed-loop brain–computer (BCI) interface and internet-of-things (IoT) applications. Approach: The EEG-based BCI headset was designed from...
Figure 1. The brain–computer interface framework. BCIs can decode neural activity into control commands to trigger wheelchairs [4], prostheses, and many other virtual interface devices. Among the methods of measuring EEG signals, surface EEG is a standard noninvasive technology [5]. Compared wit...
action observation treatment; brain–computer interface; functional electrical stimulation; mirror mechanism; neurorehabilitation 1. Towards Translational, Evidence-Based Approaches in Neurorehabilitation There is increasing demand in neurorehabilitation for approaches aimed at helping patients to recover functions, ...