The brain is the last frontier for wearable sensing. Commercially available wearables can monitor your vital signs and physical activity, but few have the ability to monitor what goes on inside your head. With the advent of new wearable and portable neuroimaging technologies, this situation might be about to change, with profound implications for neuroscience and for wearables
One of the most severe limitations of functional neuroimaging techniques, such as magnetoencephalogr...
The application of wearable electronics in the biomedical research and commercial fields has been g...
Wearables as medical technologies are becoming an integral part of personal analytics, measuring phy...
101 pagesConventional EEG devices are usually large headsets that rely on gel-connections or spiky d...
Despite the proliferation of low-cost wearable sensors, until recently we have not been able to moni...
Imaging human brain function with techniques such as magnetoencephalography1 (MEG) typically require...
Brain-computer interfaces (BCIs) allow users to communicate directly with external devices via their...
Brain–computer interfaces (BCIs) provide bidirectional communication between the brain and output de...
Consumer neurotechnology is arriving en masse, even while algorithms for user state estimation are b...
Functional neuroimaging offers a means to understand brain function and dysfunction. Over decades, d...
Neuroscientists accept that we are indeed faced with an overwhelming challenge in understanding how ...
Brain–computer interfaces (BCIs) provide bidirectional communication between the brain and output de...
Abstract Wearable sensors have become more commonly used in everyday basis and powerful in terms of...
Abstract This Perspective offers a concise overview of the current state-of-the-art o...
Wearable technologies are becoming an increasingly popular platform for healthcare services due to t...
One of the most severe limitations of functional neuroimaging techniques, such as magnetoencephalogr...
The application of wearable electronics in the biomedical research and commercial fields has been g...
Wearables as medical technologies are becoming an integral part of personal analytics, measuring phy...
101 pagesConventional EEG devices are usually large headsets that rely on gel-connections or spiky d...
Despite the proliferation of low-cost wearable sensors, until recently we have not been able to moni...
Imaging human brain function with techniques such as magnetoencephalography1 (MEG) typically require...
Brain-computer interfaces (BCIs) allow users to communicate directly with external devices via their...
Brain–computer interfaces (BCIs) provide bidirectional communication between the brain and output de...
Consumer neurotechnology is arriving en masse, even while algorithms for user state estimation are b...
Functional neuroimaging offers a means to understand brain function and dysfunction. Over decades, d...
Neuroscientists accept that we are indeed faced with an overwhelming challenge in understanding how ...
Brain–computer interfaces (BCIs) provide bidirectional communication between the brain and output de...
Abstract Wearable sensors have become more commonly used in everyday basis and powerful in terms of...
Abstract This Perspective offers a concise overview of the current state-of-the-art o...
Wearable technologies are becoming an increasingly popular platform for healthcare services due to t...
One of the most severe limitations of functional neuroimaging techniques, such as magnetoencephalogr...
The application of wearable electronics in the biomedical research and commercial fields has been g...
Wearables as medical technologies are becoming an integral part of personal analytics, measuring phy...