Abstract
We present a fundamentally new approach to design and assess wearable motion systems based on biomechanical simulation and sensor data synthesis. We devise a methodology of personal biomechanical models and virtually attach sensor models to body parts, including sensor positions frequently considered for wearable devices. The simulation enables us to synthesise motion sensor data, which is subsequently considered as input for gait marker estimation algorithms. We evaluated our methodology in two case studies, including running athletes and hemiparetic patients. Our analysis shows that running speed affects gait marker estimation performance. Estimation error of stride duration varies between athletes across 834 simulated sensor positions and can soar up to 54%, i.e. 404 ms. In walking patients after stroke, we show that gait marker performance differs between affected and less-affected body sides and optimal sensor positions change over a period of movement therapy intervention. For both case studies, we observe that optimal gait marker estimation performance benefits from personally selected sensor positions and robust algorithms. Our methodology enables wearable designers and algorithm developers to rapidly analyse the design options and create personalised systems where needed, e.g. for patients with movement disorders.
Highlights
We present a fundamentally new approach to design and assess wearable motion systems based on biomechanical simulation and sensor data synthesis
We demonstrated that biomechanical simulation and synthesised motion data can estimate motion-related clinical assessment scores[26], which were comparable to the analysis based on physical, wearable s ensors[27]
We present two case studies to investigate the design space for wearable motion sensor systems: Case Study 1 includes ten healthy athletes running at different speeds, Case Study 2 includes eight hemiparetic stroke survivors, who walk at self-selected speed
Summary
We present a fundamentally new approach to design and assess wearable motion systems based on biomechanical simulation and sensor data synthesis. In walking patients after stroke, we show that gait marker performance differs between affected and less-affected body sides and optimal sensor positions change over a period of movement therapy intervention. For both case studies, we observe that optimal gait marker estimation performance benefits from personally selected sensor positions and robust algorithms. It has been shown that human motion varies among athletes in highly standardised walking sports and that the measurement position on the body could influence signal quality and data features, which in turn renders accurate performance estimation c hallenging[7]. We demonstrated that biomechanical simulation and synthesised motion data can estimate motion-related clinical assessment scores[26], which were comparable to the analysis based on physical, wearable s ensors[27]
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