Usability of Three Electroencephalogram Headsets for Brain–Computer Interfaces: A Within Subject Comparison

Nijboer, Femke; Laar, Bram van de; Gerritsen, Steven; Nijholt, Anton; Poel, Mannes

doi:10.1093/iwc/iwv023

Cited by 57 publications

(41 citation statements)

References 39 publications

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“…It will produce a slight offset, hence a slight inaccuracy. Another alternative is to make separate measures by repeating the recordings with each system (Nijboer et al, 2015), but once again the conditions could not be exactly the same.…”

Section: Introductionmentioning

confidence: 99%

Comparison of an Open-hardware Electroencephalography Amplifier with Medical Grade Device in Brain-computer Interface Applications

Frey

2016

Proceedings of the 3rd International Conference on Physiological Computing Systems

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Abstract:Brain-computer interfaces (BCI) are promising communication devices between humans and machines. BCI based on non-invasive neuroimaging techniques such as electroencephalography (EEG) have many applications, however the dissemination of the technology is limited, in part because of the price of the hardware. In this paper we compare side by side two EEG amplifiers, the consumer grade OpenBCI and the medical grade g.tec g.USBamp. For this purpose, we employed an original montage, based on the simultaneous recording of the same set of electrodes. Two set of recordings were performed. During the first experiment a simple adapter with a direct connection between the amplifiers and the electrodes was used. Then, in a second experiment, we attempted to discard any possible interference that one amplifier could cause to the other by adding "ideal" diodes to the adapter. Both spectral and temporal features were tested -the former with a workload monitoring task, the latter with an visual P300 speller task. Overall, the results suggest that the OpenBCI board -or a similar solution based on the Texas Instrument ADS1299 chip -could be an effective alternative to traditional EEG devices. Even though a medical grade equipment still outperforms the OpenBCI, the latter gives very close EEG readings, resulting in practice in a classification accuracy that may be suitable for popularizing BCI uses.

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Section: Introductionmentioning

confidence: 99%

Comparison of an Open-hardware Electroencephalography Amplifier with Medical Grade Device in Brain-computer Interface Applications

Frey

2016

Proceedings of the 3rd International Conference on Physiological Computing Systems

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“…Nijboer et al [31] reported that a 32-channel Biosemi system produced higher P300-based BCI accuracy than an 8-channel g.Sahara or 14-channel EPOC systems; however, the BioSemi system and the g.Sahara system were comparable when their performances using the same eight electrode sites were compared. Hariston et al [32] compared the EPOC, QUASAR, and B-Alert X-10 (Advanced Brain Monitoring) systems with the BioSemi system, which they considered the gold standard.…”

Section: Recording Methodsmentioning

confidence: 99%

EEG-based brain–computer interfaces

McFarland

Wolpaw

2017

Current Opinion in Biomedical Engineering

205

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Brain-Computer Interfaces (BCIs) are real-time computer-based systems that translate brain signals into useful commands. To date most applications have been demonstrations of proof-of-principle; widespread use by people who could benefit from this technology requires further development. Improvements in current EEG recording technology are needed. Better sensors would be easier to apply, more confortable for the user, and produce higher quality and more stable signals. Although considerable effort has been devoted to evaluating classifiers using public datasets, more attention to real-time signal processing issues and to optimizing the mutually adaptive interaction between the brain and the BCI are essential for improving BCI performance. Further development of applications is also needed, particularly applications of BCI technology to rehabilitation. The design of rehabilitation applications hinges on the nature of BCI control and how it might be used to induce and guide beneficial plasticity in the brain.

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“…Too much pressure may be uncomfortable for the user, whereas insufficient pressure affects the quality of the recording. Users have found that the jell used with typical wet electrodes is unpleasant, but dry electrodes may not yet produce comparable results . BCI performance would be improved by a better signal‐to‐noise ratio than that produced by current sensor technology.…”

Section: Some Characteristics Of Bcismentioning

confidence: 99%

Brain‐computer interfaces for amyotrophic lateral sclerosis

McFarland

2020

Muscle and Nerve

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A brain-computer interface (BCI) is a device that detects signals from the brain and transforms them into useful commands. Researchers have developed BCIs that utilize different kinds of brain signals. These different BCI systems have differing characteristics, such as the amount of training required and the degree to which they are or are not invasive. Much of the research on BCIs to date has involved healthy individuals and evaluation of classification algorithms. Some BCIs have been shown to have potential benefit for users with minimal muscular function as a result of amyotrophic lateral sclerosis. However, there are still several challenges that need to be successfully addressed before BCIs can be clinically useful.amyotrophic lateral sclerosis, brain-computer interface, neuroprosthetics

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Usability of Three Electroencephalogram Headsets for Brain–Computer Interfaces: A Within Subject Comparison

Cited by 57 publications

References 39 publications

Comparison of an Open-hardware Electroencephalography Amplifier with Medical Grade Device in Brain-computer Interface Applications

Comparison of an Open-hardware Electroencephalography Amplifier with Medical Grade Device in Brain-computer Interface Applications

EEG-based brain–computer interfaces

Brain‐computer interfaces for amyotrophic lateral sclerosis

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