Eye-Gaze Controlled Wheelchair Based on Deep Learning

Xu, Jingwei; Huang, Zhipei; Liu, L. J.; Li, Xinghua; Wei, Kai

doi:10.3390/s23136239

Cited by 7 publications

(2 citation statements)

References 56 publications

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“…In terms of human-computer interaction between the occupant and the wheelchair, Xu et al designed an intelligent wheelchair with eye-movement control, which acquires the occupant's eye image through a camera and uses deep learning to determine the direction of eye movement, as well as to establish a motion acceleration model for the intelligent wheelchair to improve motion smoothness [15]. Cui et al proposed an intelligent wheelchair posture adjustment method based on action intent recognition, which adjusts the wheelchair posture by investigating the relationship between the force changes on the contact surface between the human body and the wheelchair and the action intent [16].…”

Section: Introductionmentioning

confidence: 99%

Research on Intelligent Wheelchair Multimode Human–Computer Interaction and Assisted Driving Technology

Cui,

Shang,

et al. 2024

Actuators

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The traditional wheelchair focuses on the “human-chair” motor function interaction to ensure the elderly and people with disabilities’ basic travel. For people with visual, hearing, physical disabilities, etc., the current wheelchairs show shortcomings in terms of accessibility and independent travel for this group. Therefore, this paper develops an intelligent wheelchair with multimodal human–computer interaction and autonomous navigation technology. Firstly, it researches the multimodal human–computer interaction technology of occupant gesture recognition, speech recognition, and head posture recognition and proposes a wheelchair control method of three-dimensional head posture mapping the two-dimensional plane. After testing, the average accuracy of the gesture, head posture and voice control modes of the motorized wheelchair proposed in this study reaches more than 95 percent. Secondly, the LiDAR-based smart wheelchair indoor autonomous navigation technology is investigated to realize the autonomous navigation of the wheelchair by constructing an environment map, using A* and DWA algorithms for global and local path planning, and adaptive Monte Carlo simulation algorithms for real-time localization. Experiments show that the position error of the wheelchair is within 10 cm, and the heading angle error is less than 5° during the autonomous navigation. The multimode human–computer interaction and assisted driving technology proposed in this study can partially compensate and replace the functional deficiencies of the disabled population and improve the quality of life of the elderly and disabled population.

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Section: Introductionmentioning

confidence: 99%

Research on Intelligent Wheelchair Multimode Human–Computer Interaction and Assisted Driving Technology

Cui,

Shang,

et al. 2024

Actuators

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“…The electronic brain of the system processes sensor information, automatically generates motor commands and display messages. The control module of the smart wheelchair can consist of a standard wheelchair joystick [2], voice recognition based control [3], facial expressions control [4], and even eye-gaze control [5] etc. The overall architecture of a wheelchair control system is shown in Figure 1.…”

Section: Introductionmentioning

confidence: 99%

Smart Wheelchair Design for Elderly and Disabled People

2023

International Conference on Innovative Academic Studies

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This paper proposes a gesture based wheelchair design using Raspberry Pi. A wheelchair is designed where physically disabled or elderly people can control the wheelchair and a nearby person can see the status message on the LCD. These tasks can be performed using hand gestures. This enables the disabled person to drive the wheelchair and move more efficiently from one place to another. The Raspberry Pi acts as a brain that enables the components to fulfil their tasks. Flex sensors detect hand movements and are transferred as data input to the Raspberry Pi. The motor driver drives the motors. The system status is reflected as a message on the LCD screen and the operations are monitored. In return for four hand movements, the wheelchair can be controlled in forward, left and right directions and stop command. If desired, the design can be edited and the motor movement and LCD screen message can be rearranged for different hand movements. With the advantage of flexible design, personalized needs can be met. This makes the design more flexible and improvable than a joystick-controlled wheelchair and more costeffective than a voice-controlled wheelchair.

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