A Brain-Robot Interaction System by Fusing Human and Machine Intelligence

This paper presents a new brain-robot interaction system by fusing human and machine intelligence to improve the real-time control performance. This system consists of a hybrid P300 and steady-state visual evoked potential (SSVEP) mode conveying a human being's intention, and the machine intell...

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Bibliographic Details
Published in:IEEE transactions on neural systems and rehabilitation engineering 2019-03, Vol.27 (3), p.533-542
Main Authors: Mao, Xiaoqian, Li, Wei, Lei, Chengwei, Jin, Jing, Duan, Feng, Chen, Sherry
Format: Article
Language:English
Subjects:
Algorithms
Artificial Intelligence
Automation
Brain
Brain robot interaction
Brain-Computer Interfaces
Cameras
Electroencephalography
Event-related potentials
Event-Related Potentials, P300 - physiology
Evoked Potentials, Somatosensory - physiology
Fuzzy Logic
human intelligence
Humanoid
Humanoid robots
Humans
Hybrid systems
Image processing
Image Processing, Computer-Assisted
improved fuzzy color extractor (IFCE)
Intelligence
Machine intelligence
multi-sensor fusion
Multisensor fusion
Robot control
Robot sensing systems
Robotics - methods
Robots
Task analysis
Vision, Ocular - physiology
Visual evoked potentials
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Summary:This paper presents a new brain-robot interaction system by fusing human and machine intelligence to improve the real-time control performance. This system consists of a hybrid P300 and steady-state visual evoked potential (SSVEP) mode conveying a human being's intention, and the machine intelligence combining a fuzzy-logic-based image processing algorithm with multi-sensor fusion technology. A subject selects an object of interest via P300, and the classification algorithm transfers the corresponding parameters to an improved fuzzy color extractor for object extraction. A central vision tracking strategy automatically guides the NAO humanoid robot to the destination selected by the subject intentions represented by brainwaves. During this process, human supervises the system at high level, while machine intelligence assists the robot in accomplishing tasks by analyzing image feeding back from the camera, distance monitoring using out-of-gauge alarms from sonars, and collision detecting from bumper sensors. In this scenario, the SSVEP takes over the situations in which the machine intelligence cannot make decisions. The experimental results show that the subjects can control the robot to a destination of interest, with fewer commands than only using a brain-robot interface. Therefore, the fusion of human and machine intelligence greatly alleviates the brain load and enhances the robot executive efficiency of a brain-robot interaction system.
ISSN:1534-4320
1558-0210
DOI:10.1109/TNSRE.2019.2897323