Abstract
To support stroke survivors in activities of daily living, wearable soft-robotic gloves are being developed. An essential feature for use in daily life is detection of movement intent to trigger actuation without substantial delays. To increase efficacy, the intention to grasp should be detected as soon as possible, while other movements are not detected instead. Therefore, the possibilities to classify reach and grasp movements of stroke survivors, and to detect the intention of grasp movements, were investigated using inertial sensing. Hand and wrist movements of 10 stroke survivors were analyzed during reach and grasp movements using inertial sensing and a Support Vector Machine classifier. The highest mean accuracies of 96.8% and 83.3% were achieved for single- and multi-user classification respectively. Accuracies up to 90% were achieved when using 80% of the movement length, or even only 50% of the movement length after choosing the optimal kernel per person. This would allow for an earlier detection of 300-750ms, but at the expense of accuracy. In conclusion, inertial sensing combined with the Support Vector Machine classifier is a promising method for actuation of grasp-supporting devices to aid stroke survivors in activities of daily living. Online implementation should be investigated in future research.
Highlights
IntroductionI N 2013, 25.7 million people of the world population suffered a stroke [1], of which 77.4% show motor impairments
I N 2013, 25.7 million people of the world population suffered a stroke [1], of which 77.4% show motor impairmentsManuscript received December 21, 2018; revised April 1, 2019 and July 16, 2019; accepted August 6, 2019
Ten chronic stroke survivors were included in this study (Table 2)
Summary
I N 2013, 25.7 million people of the world population suffered a stroke [1], of which 77.4% show motor impairments. Manuscript received December 21, 2018; revised April 1, 2019 and July 16, 2019; accepted August 6, 2019. Date of publication September 19, 2019; date of current version October 8, 2019. B. Sawaryn is with the Department of Biomedical Signals and Systems, University of Twente, 7522 NB Enschede, The Netherlands. Prange-Lasonder is with the Roessingh Research and Development, 7522 AH Enschede, The Netherlands, and with the Department of Biomechanical Engineering, University of Twente, 7522 NB Enschede, The Netherlands
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