Add to ORKGInternational audienceIn most Brain-Computer Interfaces (BCI) experimental paradigms based on Motor Imageries (MI), subjects perform continuous motor imagery (CMI), i.e. a repetitive and prolonged intention of movement, for a few seconds. To improve efficiency such as detecting faster a motor imagery, the purpose of this study is to show the difference between a discrete motor imagery (DMI), i.e. a single short MI, and a CMI. The results of experiment involving 13 healthy subjects suggest that a DMI generates a robust post-MI event-related synchronization (ERS). Moreover event-related desynchronization (ERD) produced by DMI seems less variable in certain cases compared to a CMI
Movement intention (MI) is the mental state in which it is desired to make an action that implies mo...
<div><p>Event-related desynchronization/synchronization (ERD/S) is an electroencephalogram (EEG) fea...
Motor imagery attenuates EEG µ and β rhythms over sensorimotor cortices. These amplitude changes are...
International audienceIn most Brain-Computer Interfaces (BCI) experimental paradigms based on Motor ...
Motor imagery modifies the neural activity within the primary sensorimotor areas of the cortex in a ...
International audienceMotor imagery (MI) modifies the neural activity within the primary sensorimoto...
International audienceA large number of Brain-Computer Interfaces (BCIs) are based on the detection ...
International audienceLimb movement execution or imagination induce sensorimotor rhythms that can be...
International audienceDespite current research, the relationship between the variability of Event-Re...
One of the most significant challenges in the application of brain-computer interfaces (BCI) is the ...
Electroencephalographic (EEG) event-related desynchronization (ERD) induced by movement imagery or b...
Viable usage of Brain-Computer Interface (BCI) in real-time applications significantly relies on the...
A repetitive movement practice by motor imagery (MI) can influence motor cortical excitability in th...
Motor imagery attenuates EEG µ and β rhythms over sensorimotor cor-tices. These amplitude changes ar...
International audienceNon-invasive Brain-Computer Interfaces (BCIs) based on motor imagery (MI) task...
Movement intention (MI) is the mental state in which it is desired to make an action that implies mo...
<div><p>Event-related desynchronization/synchronization (ERD/S) is an electroencephalogram (EEG) fea...
Motor imagery attenuates EEG µ and β rhythms over sensorimotor cortices. These amplitude changes are...
International audienceIn most Brain-Computer Interfaces (BCI) experimental paradigms based on Motor ...
Motor imagery modifies the neural activity within the primary sensorimotor areas of the cortex in a ...
International audienceMotor imagery (MI) modifies the neural activity within the primary sensorimoto...
International audienceA large number of Brain-Computer Interfaces (BCIs) are based on the detection ...
International audienceLimb movement execution or imagination induce sensorimotor rhythms that can be...
International audienceDespite current research, the relationship between the variability of Event-Re...
One of the most significant challenges in the application of brain-computer interfaces (BCI) is the ...
Electroencephalographic (EEG) event-related desynchronization (ERD) induced by movement imagery or b...
Viable usage of Brain-Computer Interface (BCI) in real-time applications significantly relies on the...
A repetitive movement practice by motor imagery (MI) can influence motor cortical excitability in th...
Motor imagery attenuates EEG µ and β rhythms over sensorimotor cor-tices. These amplitude changes ar...
International audienceNon-invasive Brain-Computer Interfaces (BCIs) based on motor imagery (MI) task...
Movement intention (MI) is the mental state in which it is desired to make an action that implies mo...
<div><p>Event-related desynchronization/synchronization (ERD/S) is an electroencephalogram (EEG) fea...
Motor imagery attenuates EEG µ and β rhythms over sensorimotor cortices. These amplitude changes are...