Intelligent Control of the Steering for a Powered Wheelchair Using a Microcomputer

Lecture Notes in Networks and Systems

Langner

et al. 2021

Self Cite

This paper presents a new approach to identify users of shared powered mobility platfroms using One Shot learning algorithm. An electronic circuit is created using a Raspberry Pi and a camera module. Python programming language is used to create a program to control the function of the camera module and conduct One Shot learning to identify users. A user interface containing Start and Stop buttons is created to operate the camera module. If Start is pressed, the Python program will trigger the camera to take a snapshot, then the program will identify the face in that snapshot and perform facial recognition to compare that face with a database of user facial images. If a match was found a message box popped-up showing the user name. Once a user is identified, their settings and preferences can be downloaded to the shared powered mobility platform. If the face in the snapshot did not match any of the user facial images in the data base, a message popped-up showing that user was not found in the database. Practical testing showed the system behaved satisfactorily and successfully detected users. One Shot learning allowed new users to be added to the database without the need to retrain the whole system.

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

One Shot Learning Approach to Identify Drivers

Lecture Notes in Networks and Systems

Langner

et al. 2021

Self Cite

“…Many systems have been created to help with driving and control [1][2][3] and a few have moved from research and development prototypes to become successful and useful devices [4,5]. Semi-autonomous powered wheelchairs [6][7][8] have recently moved out of academic and research institutions [9][10][11] to become available to wheelchair users.…”

Section: Introductionmentioning

confidence: 99%

Control of a Semi-autonomous Powered Wheelchair

Tewkesbury

et al. 2022

J. Phys.: Conf. Ser.

A model reference controller for a powered wheelchair is described. The chair is fitted with sensor systems to assist a disabled user with steering their chair. The controller can cope with varying circumstances and situations. Non-linear terms are compensated for using an adaptive and automatic scheme. Consistent and dependable veer-controll is considered and the system was able to deal with uncertainties, for example changing surfaces, different shifting weights of users, hills, bumps, slopes and differences in tires and wheels. The controller has a quasi-linear closed-loop behaviour and that means that extra outer control loops can be appended later, for example path-following algorithms. An assistive agent was also created so that sperate wheelchairs will be able to communicate with each other in the future.

“…People with disability often used powered mobility for daily activities [5] and researchers have aimed to improve powered mobility using: sensor systems [6], ultrasonics [7] Multiple Criteria Decision Making and ultrasonic sensors [8][9][10][11], Expert Systems [12,13], Rule Based Systems [14], microcomputers and Human Machine Interfaces [15,16], Deep Learning [2,17] and camera modules [18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Intelligent User Interface to Control a Powered Wheelchair Using Infrared Sensors

Lecture Notes in Networks and Systems

Tewkesbury

et al. 2021

Self Cite

This paper presents a new system to steer a powered wheelchair using a Sharp IR sensor and a Raspberry Pi. Interviews with occupational therapists, helpers and carers at Chailey Heritage Foundation/School revealed that clicking noises generated from closing switch contact used to operate powered wheelchairs disturbed the attention and reduced the focus of young wheelchair users having cognitive or physical disability. Also switches often slipped away and became unreachable. The new system replaced lever-switches used to steer powered wheelchairs by an electronic circuit. The circuit consisted of a Sharp IR sensor, Analogue to Digital converter, relays, and a Raspberry Pi. The sharp IR sensor detected movement in its range and the Raspberry Pi interpreted the data and generated commands to steer a powered wheelchair. Two modes were used to overcome the problem of sensors slipping from position: Click to Calibrate and Auto-Calibrate. A technical User Interface was created to modify sensitivity, user and detection settings. Practical testing showed the system behaved satisfactorily. It detected users' voluntary movements and used them to steer a powered wheelchair and overcome the problem of switches slipping from position. Clinical trials will be conducted at Chailey Heritage Foundation.