2018
DOI: 10.3389/fnhum.2018.00312
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EEG-Based BCI Control Schemes for Lower-Limb Assistive-Robots

Abstract: Over recent years, brain-computer interface (BCI) has emerged as an alternative communication system between the human brain and an output device. Deciphered intents, after detecting electrical signals from the human scalp, are translated into control commands used to operate external devices, computer displays and virtual objects in the real-time. BCI provides an augmentative communication by creating a muscle-free channel between the brain and the output devices, primarily for subjects having neuromotor diso… Show more

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Cited by 190 publications
(101 citation statements)
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References 138 publications
(232 reference statements)
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“…People affected by neurological disorder, stroke, or spinal cord injury (SCI) necessitate a therapeutic goal of motor gait rehabilitation using assistive technologies [1,2]. For lower-limb affectees, to re-gain the dorsiflexion of foot drop is vital [3][4][5].…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation
“…People affected by neurological disorder, stroke, or spinal cord injury (SCI) necessitate a therapeutic goal of motor gait rehabilitation using assistive technologies [1,2]. For lower-limb affectees, to re-gain the dorsiflexion of foot drop is vital [3][4][5].…”
Section: Introductionmentioning
confidence: 99%
“…However, from literature, MI tasks have been preferred over ME ones, to avoid any possibility of proprioceptive feedback. The MI is a covert cognitive process, where the user makes a kinaesthetic imagination of his/her own limb movement without any muscular intervention, also called kinaesthetic motor imagery (KMI) [1,12].…”
Section: Introductionmentioning
confidence: 99%
“…Such devices will have a significant impact on many of EEG's current applications, especially seizure prediction devices [139], event-related potential-based applications like P300 writing systems [140], and image reconstruction using EEG mind-reading algorithms [141]. Besides these, wearable EEG instruments are also anticipated to empower new applications in the future, potentially in the areas of augmented reality [142] and robotics [143].…”
Section: Electroencephalography (Eeg)mentioning
confidence: 99%
“…These provided non-FES aided gait, as opposed to earlier methods that were mainly designed to just provide significantly better trajectory control and to reduce muscle fatigue when compared to FES-only gait. Current and future implementations of this neuro-physiological information have the challenge of overcoming signal variability, classification algorithm robustness, and quantifiable performance feedback indicators (Tariq et al, 2018). Current advances in EMG and EEG analysis have led to broad applications of this control approach in rehabilitation robotics, however these challenges still require solving for these methods to become viable parts of rehabilitation, especially in exoskeleton and orthosis implementations (Ison and Artemiadis, 2014).…”
Section: Exoskeletons and Powered Orthosesmentioning
confidence: 99%