Electric Wheelchair Control Using Wrist Rotation Based on Analysis of Muscle Fatigue

Rusydi, Muhammad Ilhamdi; Khairiah, Mir'atul; Hadi, Kalputra; Syafii, .; Setiawan, Andri; Reni, Ises; Nugroho, Hanung Adi; Windasari, Noverika

doi:10.1109/access.2022.3208151

Cited by 4 publications

(2 citation statements)

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“…In general, the main goal of smart wheelchairs is to increase the mobility and independence of users with limited mobility. By incorporating advanced technologies such as computer vision and artificial intelligence [32], [58], [59], vision-based autonomous wheelchairs represent a promising approach to achieving this goal. 6) Vision-based smart wheelchairs offer many benefits, but they also have several limitations that can impact their effectiveness and usability.…”

Section: B Achievements and Challengesmentioning

confidence: 99%

Smart Wheelchair Controlled Through a Vision-Based Autonomous System

Masud,

Abdualaziz Almolhis,

Alhazmi

et al. 2024

IEEE Access

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People are preoccupied with their own duties in today's environment, making it tough to oversee and care for disabled people. Paralyzed and disabled people, on the other hand, have a powerful desire to move around freely. Different initiatives have been taken in the past to improve and preserve the self-esteem of such people, and various technologies have also been created to assist them in a better way. The primary advantage of a vision-based autonomous wheelchair is that it can provide greater independence to users with limited mobility. The methodology of other smart wheelchairs varies depending on the specific technology used. Some smart wheelchairs may use sensors to detect obstacles and provide feedback to the user, while others may incorporate GPS and other navigation technologies to assist with indoor and outdoor navigation. Our study proposes a revolutionary implementation of an autonomous system for fully handicapped people, allowing them to drive wheelchairs using just their eyes. The wheelchair's orientation will be determined by the orientation of the eye. The camera will follow the movement of the eyes. Furthermore, sensors will be installed on the front side of the wheelchair to identify any obstacles along its path. The calibration of the camera with the human eye, without obstructing its vision, is the most challenging task in this research, besides controlling the wheels of the wheelchair.

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Section: B Achievements and Challengesmentioning

confidence: 99%

Smart Wheelchair Controlled Through a Vision-Based Autonomous System

Masud,

Abdualaziz Almolhis,

Alhazmi

et al. 2024

IEEE Access

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“…A large contingent of people is physically disabled as a result of health problems or accidents. A smart assistive wheelchair can make a world of difference for people who have neck paralysis, quadriplegia, congenital gait disorders, or finger dependencies [ 2 ].…”

Section: Introductionmentioning

confidence: 99%

Electric powered wheelchair control using user-independent classification methods based on surface electromyography signals

Iqbal,

Zheng,

Chai

et al. 2023

Med Biol Eng Comput

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Wheelchairs are one of the most popular assistive technology (AT) among individuals with motor impairments due to their comfort and mobility. People with finger problems may find it difficult to operate wheelchairs using the conventional joystick control method. Therefore, in this research study, a hand gesture-based control method is developed for operating an electric-powered wheelchair (EPW). This study selected a comfort-based hand position to determine the stop maneuver. An additional exploration was undertaken to investigate four gesture recognition methods: linear regression (LR), regularized linear regression (RLR), decision tree (DT), and multi-class support vector machine (MC-SVM). The first two methods, LR and RLR, have promising accuracy values of 94.85% and 95.88%, respectively, but each new user must be trained. To overcome this limitation, this study explored two user-independent classification methods: MC-SVM and DT. These methods effectively addressed the finger dependency issue and demonstrated remarkable success in recognizing gestures across different users. MC-SVM has about 99.05% of both precision and accuracy, and the DT has about 97.77% accuracy and precision. All six participants were successful in controlling the EPW without any collisions. According to the experimental results, the proposed approach has high accuracy and can address finger dependency issues.

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