Abstract
Complete tetraplegia can deprive a person of hand function. Assistive technologies may improve autonomy but needs for ergonomic interfaces for the user to pilot these devices still persist. Despite the paralysis of their arms, people with tetraplegia may retain residual shoulder movements. In this work we explored these movements as a mean to control assistive devices. We captured shoulder movement with a single inertial sensor and, by training a support vector machine based classifier, we decode such information into user intent. The setup and training process take only a few minutes and so the classifiers can be user specific. We tested the algorithm with 10 able body and 2 spinal cord injury participants. The average classification accuracy was 80% and 84%, respectively. The proposed algorithm is easy to set up, its operation is fully automated, and achieved results are on par with state-of-the-art systems. Assistive devices for persons without hand function present limitations in their user interfaces. Our work presents a novel method to overcome some of these limitations by classifying user movement and decoding it into user intent, all with simple setup and training and no need for manual tuning. We demonstrate its feasibility with experiments with end users, including persons with complete tetraplegia without hand function.
Highlights
I INDIVIDUALS who suffered a spinal cord injury (SCI) often have severe losses of motor functions
This paper presents an intent recognition algorithm using a unique inertial measurement units (IMU) based on residual movements classification for controlling assistive devices by persons with tetraplegia
We have evaluated the system with a group of 10 able body participants and another with 2 participants with complete tetraplegia an no hand function caused by SCI
Summary
I INDIVIDUALS who suffered a spinal cord injury (SCI) often have severe losses of motor functions. Almost 60% of SCIs result in complete or incomplete tetraplegia [1], affecting both lower and upper limbs. For this population, regaining hand function is ranked as the top priority [2]. Different methods have been studied and applied to restore upper limb function after SCI and other injuries, most notably robotic assistance and functional electrical stimulation (FES). The control of either exoskeletons or FES systems by individuals with complete tetraplegia and without hand function is still a challenge. Various alternatives based on voluntary movement detection or voluntary muscle
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