A Brain-Controlled Vehicle System Based on Steady State Visual Evoked Potentials

Zhang, Zhao; Han, Shuning; Yi, Huaihai; Ding, Feng; Kang, Feiyu; Sun, Zhe; Solé-Casals, Jordi; Caiafa, César F.

doi:10.1007/s12559-022-10051-1

Cited by 5 publications

(3 citation statements)

References 40 publications

(41 reference statements)

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“…With cognitive AI, machines get trained to be able to think, reason, and make decisions much like humans do! [19][20][21] Although existing research work had restricted scopes due unavailability of real-world datasets and problematic experimental conditions, researchers yielded results using indirect methods like observing subject's typical sleep patterns in the vehicle [22,23,23], or experimented with decreased cognitive response time using alcohol [24,25] or conducted repetitive tasks to elicit tiredness [26,27,27]. When it comes to sleep, there is no such thing as a typical state of being.…”

Section: Literature Surveymentioning

confidence: 99%

Novel welch-transform based enhanced spectro-temporal analysis for cognitive microsleep detection using a single electrode EEG

et al. 2023

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Section: Literature Surveymentioning

confidence: 99%

Novel welch-transform based enhanced spectro-temporal analysis for cognitive microsleep detection using a single electrode EEG

et al. 2023

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“…Brain–computer interfaces (BCIs) based on electroencephalographic (EEG) signals are gaining considerable attention in scientific research and application development [ 1 ] because of technological advances and multidisciplinary studies related to brain signals [ 2 , 3 ]. Many categories of EEG signals can be processed, and countless BCI systems have been developed for ordinary use and clinical applications, for example, in the fields of brain-controlled vehicles [ 4 ], drones [ 5 ], assistive devices [ 6 ], intelligent systems [ 7 ], neurorehabilitation [ 8 ], telemedicine [ 9 ], assistive robots [ 10 ], and wheelchairs [ 11 ], to name but a few. Based on a user’s mental stimulation, event-related potentials (ERPs) are generated externally by cognitive load or auditory, sensory, or visual stimuli.…”

Section: Introductionmentioning

confidence: 99%

Multiclass Classification of Visual Electroencephalogram Based on Channel Selection, Minimum Norm Estimation Algorithm, and Deep Network Architectures

Mwata-Velu,

Zamora,

Vasquez-Gomez

et al. 2024

Sensors

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This work addresses the challenge of classifying multiclass visual EEG signals into 40 classes for brain–computer interface applications using deep learning architectures. The visual multiclass classification approach offers BCI applications a significant advantage since it allows the supervision of more than one BCI interaction, considering that each class label supervises a BCI task. However, because of the nonlinearity and nonstationarity of EEG signals, using multiclass classification based on EEG features remains a significant challenge for BCI systems. In the present work, mutual information-based discriminant channel selection and minimum-norm estimate algorithms were implemented to select discriminant channels and enhance the EEG data. Hence, deep EEGNet and convolutional recurrent neural networks were separately implemented to classify the EEG data for image visualization into 40 labels. Using the k-fold cross-validation approach, average classification accuracies of 94.8% and 89.8% were obtained by implementing the aforementioned network architectures. The satisfactory results obtained with this method offer a new implementation opportunity for multitask embedded BCI applications utilizing a reduced number of both channels (<50%) and network parameters (<110 K).

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“…Medical applications focus on restoring motor functions lost during spinal cord injury through stimulation for brain regeneration and plasticity [ 28 ], another medical application is the substitution of movement through BCI for control or communication, such is the case of [ 29 ]. On the other hand, non-medical applications are used to increase human capabilities and entertainment; such as the case of control of robotic arms and exoskeletons [ 30 ], control of ground vehicles [ 31 ], drones [ 32 ], and games in virtual environments [ 33 ].…”

Section: Introductionmentioning

confidence: 99%

Fog Computing for Control of Cyber-Physical Systems in Industry Using BCI

Rodríguez-Azar,

Mejía-Muñoz,

Cruz-Mejía

et al. 2023

Sensors

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Brain-computer interfaces use signals from the brain, such as EEG, to determine brain states, which in turn can be used to issue commands, for example, to control industrial machinery. While Cloud computing can aid in the creation and operation of industrial multi-user BCI systems, the vast amount of data generated from EEG signals can lead to slow response time and bandwidth problems. Fog computing reduces latency in high-demand computation networks. Hence, this paper introduces a fog computing solution for BCI processing. The solution consists in using fog nodes that incorporate machine learning algorithms to convert EEG signals into commands to control a cyber-physical system. The machine learning module uses a deep learning encoder to generate feature images from EEG signals that are subsequently classified into commands by a random forest. The classification scheme is compared using various classifiers, being the random forest the one that obtained the best performance. Additionally, a comparison was made between the fog computing approach and using only cloud computing through the use of a fog computing simulator. The results indicate that the fog computing method resulted in less latency compared to the solely cloud computing approach.

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A Brain-Controlled Vehicle System Based on Steady State Visual Evoked Potentials

Cited by 5 publications

References 40 publications

Novel welch-transform based enhanced spectro-temporal analysis for cognitive microsleep detection using a single electrode EEG

Novel welch-transform based enhanced spectro-temporal analysis for cognitive microsleep detection using a single electrode EEG

Multiclass Classification of Visual Electroencephalogram Based on Channel Selection, Minimum Norm Estimation Algorithm, and Deep Network Architectures

Fog Computing for Control of Cyber-Physical Systems in Industry Using BCI

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