Key transition technology of ski jumping based on inertial motion unit, kinematics and dynamics

• Published in: Biomedical engineering online Vol. 22; no. 1; p. 21
• Main Authors: Yu, Jinglun, Ma, Xinying, Qi, Shuo, Liang, Zhiqiang, Wei, Zhen, Li, Qi, Ni, Weiguang, Wei, Shutao, Zhang, Shengnian
• Format: Journal Article
• Language: English
• Published: England BioMed Central Ltd 02.03.2023; BioMed Central; BMC
• Subjects: Ankle; Ankle Joint; Athletes; Biomechanical Phenomena; Biomechanics; Cameras; Dynamics; Evaluation; High speed cameras; Humans; IMU; Inertial platforms; Innovations; Insoles; Joints (anatomy); Jumping; Kinematics; Landing behavior; Lower Extremity; Measurement methods; Measurement systems; Motion capture; Physiological aspects; Pressure distribution; Recording; Research methodology; Root-mean-square errors; Ski jumping; Software; Takeoff; Technology; China; IMU; Ski jumping; Measurement systems; Dynamics; Technology; Kinematics
• ISSN: 1475-925X; 1475-925X
• DOI: 10.1186/s12938-023-01087-x

The development and innovation of biomechanical measurement methods provide a solution to the problems in ski jumping research. At present, research on ski jumping mostly focuses on the local technical characteristics of different phases, but studies on the technology transition process are less. This study aims to evaluate a measurement system (i.e. the merging of 2D video recording, inertial measurement unit and wireless pressure insole) that can capture a wide range of sport performance and focus on the key transition technical characteristics. The application validity of the Xsens motion capture system in ski jumping was verified under field conditions by comparing the lower limb joint angles of eight professional ski jumpers during the takeoff phase collected by different motion capture systems (Xsens and Simi high-speed camera). Subsequently, the key transition technical characteristics of eight ski jumpers were captured on the basis of the aforementioned measurement system. Validation results indicated that the joint angle point-by-point curve during the takeoff phase was highly correlated and had excellent agreement (0.966 ≤ r ≤ 0.998, P < 0.001). Joint root-mean-square error (RMSE) differences between model calculations were 5.967° for hip, 6.856° for knee and 4.009° for ankle. Compared with 2D video recording, the Xsens system shows excellent agreement to ski jumping. Furthermore, the established measurement system can effectively capture the key transition technical characteristics of athletes, particularly in the dynamic changes of straight turn into arc in inrun, the adjustment of body posture and ski movement during early flight and landing preparation.