The Promise of Deep Learning for BCIs: Classification of Motor Imagery EEG using Convolutional Neural Network

Leeuwis, Nikki; Alimardani, Maryam

doi:10.1101/2021.06.18.448960

Cited by 10 publications

(9 citation statements)

References 74 publications

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Section: Future Researchmentioning

confidence: 99%

“…Furthermore, classification scores of low performing users can be improved by incorporating new AI algorithms such as deep learning methods on raw EEG signals instead of the classical machine learning approach that relies on EEG feature extraction (e.g., Stieger et al, 2021;Tibrewal et al, 2021;Zhang et al, 2021). Deep learning models have the advantage of facilitating end-toend learning; they can exploit information from raw data on their own, which is not only computationally more effective but also captures brain activity patterns underlying MI beyond the defined ERD features (Tibrewal et al, 2021). Particularly, in the light of connectivity research, deep learning provides a more holistic analysis of brain activity patterns during MI that extends beyond mu suppression in the sensorimotor area and this can result in a better discriminative power of BCI classifier for the inefficient users.…”

Section: Future Researchmentioning

confidence: 99%

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Functional Connectivity Analysis in Motor-Imagery Brain Computer Interfaces

Leeuwis

Yoon

Alimardani

2021

Front. Hum. Neurosci.

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Motor Imagery BCI systems have a high rate of users that are not capable of modulating their brain activity accurately enough to communicate with the system. Several studies have identified psychological, cognitive, and neurophysiological measures that might explain this MI-BCI inefficiency. Traditional research had focused on mu suppression in the sensorimotor area in order to classify imagery, but this does not reflect the true dynamics that underlie motor imagery. Functional connectivity reflects the interaction between brain regions during the MI task and resting-state network and is a promising tool in improving MI-BCI classification. In this study, 54 novice MI-BCI users were split into two groups based on their accuracy and their functional connectivity was compared in three network scales (Global, Large and Local scale) during the resting-state, left vs. right-hand motor imagery task, and the transition between the two phases. Our comparison of High and Low BCI performers showed that in the alpha band, functional connectivity in the right hemisphere was increased in High compared to Low aptitude MI-BCI users during motor imagery. These findings contribute to the existing literature that indeed connectivity might be a valuable feature in MI-BCI classification and in solving the MI-BCI inefficiency problem.

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Section: Future Researchmentioning

confidence: 99%

Section: Future Researchmentioning

confidence: 99%

Functional Connectivity Analysis in Motor-Imagery Brain Computer Interfaces

Leeuwis

Yoon

Alimardani

2021

Front. Hum. Neurosci.

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“…BCI inefficiency is a significant problem that warrants research effort if these systems are to be useful in the future (Maskeliunas et al, 2016). Recent studies have tried to improve the classification performance of BCI inefficiency subjects using the deep learning method (i.e., convolutional neural network) because they cannot produce stronger contralateral ERD/ERS activity (Zhang et al, 2019b;Stieger et al, 2021;Tibrewal et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Improving Motor Imagery-Based Brain-Computer Interface Performance Based on Sensory Stimulation Training: An Approach Focused on Poorly Performing Users

Park

Kim

et al. 2021

Front. Neurosci.

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The motor imagery (MI)-based brain-computer interface (BCI) is an intuitive interface that provides control over computer applications directly from brain activity. However, it has shown poor performance compared to other BCI systems such as P300 and SSVEP BCI. Thus, this study aimed to improve MI-BCI performance by training participants in MI with the help of sensory inputs from tangible objects (i.e., hard and rough balls), with a focus on poorly performing users. The proposed method is a hybrid of training and imagery, combining motor execution and somatosensory sensation from a ball-type stimulus. Fourteen healthy participants participated in the somatosensory-motor imagery (SMI) experiments (within-subject design) involving EEG data classification with a three-class system (signaling with left hand, right hand, or right foot). In the scenario of controlling a remote robot to move it to the target point, the participants performed MI when faced with a three-way intersection. The SMI condition had a better classification performance than did the MI condition, achieving a 68.88% classification performance averaged over all participants, which was 6.59% larger than that in the MI condition (p < 0.05). In poor performers, the classification performance in SMI was 10.73% larger than in the MI condition (62.18% vs. 51.45%). However, good performers showed a slight performance decrement (0.86%) in the SMI condition compared to the MI condition (80.93% vs. 81.79%). Combining the brain signals from the motor and somatosensory cortex, the proposed hybrid MI-BCI system demonstrated improved classification performance, this phenomenon was predominant in poor performers (eight out of nine subjects). Hybrid MI-BCI systems may significantly contribute to reducing the proportion of BCI-inefficiency users and closing the performance gap with other BCI systems.

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“…Transferring source data from the old MI command makes this algorithm capable of performing efficiently for fewer training samples of the new MI command. However, this method is only suitable for discriminating between two classes [12]. "Discrete Wavelet Transform with Maximum Overlap" method was suggested by Abdul Wahab (2021) to categorize the theta and delta patterns of very low and high frequencies of brain activities during mediation, learning, sleeping or focus mode.…”

Section: Methodsmentioning

confidence: 99%

“…An electroencephalogram or Brain computer-based system measures specific features of an individual's brain signal, which correlates with their intention to affect control. [12] The system then translates such features into control signals to control external devices. Such technology is especially used in the medical field for neuro-muscular disorder patients, such as patients with "Amyotrophic Lateral Sclerosis (ALS), brainstem stroke, brain or spinal cord injury, cerebral palsy, muscular dystrophies, and multiple sclerosis".…”

Section: Introductionmentioning

confidence: 99%

Artificial Intelligence in Motor Imagery-Based Bci Systems: A Narrative

2022

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Artificial intelligence concepts using machine learning models are implemented in medicines to examine medical data and gain insights to improve decision-making. This paper provides a narrative review of “Motor Imagery based brain-computer interface systems”. The essential techniques of machine learning and deep learning are reviewed and compared based on computation and test data accuracy. Various preprocessing and feature extraction techniques are highlighted in this paper, which include FFT-LDA, Wavelet Packet Decomposition (WPD), CSP Algorithm, Fisher ratio algorithm, Discrete Wavelet Transform, and Filter Bank Common Spatial Pattern (FBCSP). This method collects outcomes with multiple perspectives of the MI-BCI and optimizes it. Necessary details of Algorithms applied are also compared to give an insight into Ml techniques.

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The Promise of Deep Learning for BCIs: Classification of Motor Imagery EEG using Convolutional Neural Network

Cited by 10 publications

References 74 publications

Functional Connectivity Analysis in Motor-Imagery Brain Computer Interfaces

Functional Connectivity Analysis in Motor-Imagery Brain Computer Interfaces

Improving Motor Imagery-Based Brain-Computer Interface Performance Based on Sensory Stimulation Training: An Approach Focused on Poorly Performing Users

Artificial Intelligence in Motor Imagery-Based Bci Systems: A Narrative

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