Zhenghui Gu scite author profile

The concept of controlling a wheelchair using brain signals is promising. However, the continuous control of a wheelchair based on unstable and noisy electroencephalogram signals is unreliable and generates a significant mental burden for the user. A feasible solution is to integrate a brain-computer interface (BCI) with automated navigation techniques. This paper presents a brain-controlled intelligent wheelchair with the capability of automatic navigation. Using an autonomous navigation system, candidate destinations and waypoints are automatically generated based on the existing environment. The user selects a destination using a motor imagery (MI)-based or P300-based BCI. According to the determined destination, the navigation system plans a short and safe path and navigates the wheelchair to the destination. During the movement of the wheelchair, the user can issue a stop command with the BCI. Using our system, the mental burden of the user can be substantially alleviated. Furthermore, our system can adapt to changes in the environment. Two experiments based on MI and P300 were conducted to demonstrate the effectiveness of our system.

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Deep learning based on Batch Normalization for P300 signal detection

Liu

et al. 2018

Neurocomputing

206

115

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An asynchronous wheelchair control by hybrid EEG–EOG brain–computer interface

et al. 2014

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Wheelchair control requires multiple degrees of freedom and fast intention detection, which makes electroencephalography (EEG)-based wheelchair control a big challenge. In our previous study, we have achieved direction (turning left and right) and speed (acceleration and deceleration) control of a wheelchair using a hybrid brain-computer interface (BCI) combining motor imagery and P300 potentials. In this paper, we proposed hybrid EEG-EOG BCI, which combines motor imagery, P300 potentials, and eye blinking to implement forward, backward, and stop control of a wheelchair. By performing relevant activities, users (e.g., those with amyotrophic lateral sclerosis and locked-in syndrome) can navigate the wheelchair with seven steering behaviors. Experimental results on four healthy subjects not only demonstrate the efficiency and robustness of our brain-controlled wheelchair system but also indicate that all the four subjects could control the wheelchair spontaneously and efficiently without any other assistance (e.g., an automatic navigation system).

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Enhanced Motor Imagery Training Using a Hybrid BCI With Feedback

Xiao

Wang

et al. 2015

IEEE Trans. Biomed. Eng.

103

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Zhenghui Gu

Control of a Wheelchair in an Indoor Environment Based on a Brain–Computer Interface and Automated Navigation

Deep learning based on Batch Normalization for P300 signal detection

An asynchronous wheelchair control by hybrid EEG–EOG brain–computer interface

Enhanced Motor Imagery Training Using a Hybrid BCI With Feedback

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