Abstract
High precision Global Navigation Satellite System (GNSS) measurements are becoming more and more popular in alpine skiing due to the relatively undemanding setup and excellent performance. However, GNSS provides only single-point measurements that are defined with the antenna placed typically behind the skier's neck. A key issue is how to estimate other more relevant parameters of the skier's body, like the center of mass (COM) and ski trajectories. Previously, these parameters were estimated by modeling the skier's body with an inverted-pendulum model that oversimplified the skier's body. In this study, we propose two machine learning methods that overcome this shortcoming and estimate COM and skis trajectories based on a more faithful approximation of the skier's body with nine degrees-of-freedom. The first method utilizes a well-established approach of artificial neural networks, while the second method is based on a state-of-the-art statistical generalization method. Both methods were evaluated using the reference measurements obtained on a typical giant slalom course and compared with the inverted-pendulum method. Our results outperform the results of commonly used inverted-pendulum methods and demonstrate the applicability of machine learning techniques in biomechanical measurements of alpine skiing.
Highlights
High precision Global Navigation Satellite System technology (GNSS) has been effectively used to support many outdoor measurements in sports [1,2,3], including alpine skiing [4,5,6]
The subjects were informed about the course of the study and were required to sign an informed consent approved by the ethics committee of the Faculty of Sport in Ljubljana
The results were compared to the reference data obtained with the GNSS-IMU setup
Summary
High precision Global Navigation Satellite System technology (GNSS) has been effectively used to support many outdoor measurements in sports [1,2,3], including alpine skiing [4,5,6]. Optical measurement systems consisting of several calibrated cameras require precise calibration, post-processing and can capture motion only in a limited area. This is problematic, especially in sports like alpine skiing. GNSS measurements are usually restricted to capturing a motion of a single point, defined with the location of the GNSS antenna on the skier’s body. The antenna of the GNSS receiver cannot be attached to an arbitrary joint, due to satellite visibility
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