Application of Inertial Motion Unit-Based Kinematics to Assess the Effect of Boot Modifications on Ski Jump Landings—A Methodological Study

Kurpiers, Nico; Petrone, Nicola; Supej, Matej; Wisser, Anna; Hansen, Jørn Bindslev; Kersting, Uwe G.

doi:10.3390/s20133805

Cited by 4 publications

(4 citation statements)

References 23 publications

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“…Kinematic and kinetic analysis can provide a clear insight in the complexity of each movement while performing a ski turn, and it also allows comparisons between different types of turns [ 14 , 16 , 17 ]. Biomechanical analysis of winter sports is very challenging due to environmental conditions, which are hard to simulate in laboratory conditions [ 18 ]. Therefore, it is important to use equipment that provides accurate data capture during on-field testing.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, it is important to use equipment that provides accurate data capture during on-field testing. A Xsens motion capture system is used for determining kinematic parameters while performing simple or complex movements and for assessing full body motion [ 10 , 18 , 19 , 20 , 21 ]. Investigators have recently used pressure insoles (Novel, Pedar) during alpine skiing to better understand the relationship between kinematic and kinetic parameters, and their effects on performance, training and mechanisms of injury [ 22 , 23 , 24 , 25 , 26 , 27 ].…”

Section: Introductionmentioning

confidence: 99%

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What Are Kinematic and Kinetic Differences between Short and Parallel Turn in Alpine Skiing?

Bon

Očić

Cigrovski

et al. 2021

IJERPH

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There are numerous programs worldwide adapted for alpine ski beginners and they all share the same primary goal—inclusion of skiing beginners in alpine ski schools. The final elements of ski school taught in the parallel skiing technique are parallel turn and short turn. Synchronized analysis of kinetic and kinematic parameters of the parallel turn (PT) and short turn (ST) was conducted to determine the main biomechanical differences from a standpoint of foot pressure and lower limb angles. Both elements were performed by nine male ski instructors (age 33.4 ± 8.62, height 179.52 ± 5.98 cm, weight 78.6 ± 8.88 kg). Kinetic and kinematic analysis was conducted on 180 turns, 90 for each element. Differences in kinetic and kinematic parameters between parallel and short turns were tested by a paired t-test. The main findings of our study are determined differences in the ratio of pressure distribution on the inside and the outside foot and differences in kinematic parameters of the outside leg between elements. The mentioned analysis can provide an objective insight into the complexity of each element and provide guidelines for teaching process of those elements. This study determined the reasons for higher complexity of ST compared to PT based on the objective evaluation of biomechanical factors.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

What Are Kinematic and Kinetic Differences between Short and Parallel Turn in Alpine Skiing?

Bon

Očić

Cigrovski

et al. 2021

IJERPH

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“…The algorithm was applied to snowboarding and ski jumping, with IMUs mounted directly on the snowboards and skis, and successfully detected 92% and 100% of the jumps respectively. However, alongside traditional skiing and snowboarding, freestyle skiing is becoming more popular since the introduction of slope style as an Olympic discipline [ 25 ]. Therefore, it is crucial for coaches and athletes to distinguish the detection performance for different types of jumps in skiing.…”

Section: Introductionmentioning

confidence: 99%

Development of a simple algorithm to detect big air jumps and jumps during skiing

Kranzinger,

Martinez Alvarez

et al. 2024

PLoS ONE

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Jumping is an important task in skiing, snowboarding, ski jumping, figure skating, volleyball and many other sports. In these examples, jumping tasks are a performance criterion, and therefore detailed insight into them is important for athletes and coaches. Therefore, this paper aims to introduce a simple and easy-to-implement jump detection algorithm for skiing using acceleration data from inertial measurement units attached to ski boots. The algorithm uses the average of the absolute vertical accelerations of the two boots. We provide results for different parameter settings of the algorithm and two types of jumps: Big Air jumps and jumps during skiing. The latter are divided into small (time of flight < 500 ms) and medium (time of flight ≥ 500 ms) jumps. The algorithm detects 100% of Big Air, 94% of medium and 44% of small jumps. In addition, the settings with the highest detection rates also have the highest number of overdetected jumps. To resolve this conflict, a penalty-adjusted score that considers the number of overdetected jumps in the final performance analysis is proposed.

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“…This restrains the applicability of musculoskeletal simulations since not everybody (companies, private individuals, researchers, etc.) working with musculoskeletal human models has access to the required equipment/facilities, or the activities of interest cannot be measured in an optical motion capture setup, e.g., skiing [ 12 ]. In addition, marker occlusion—a state in which a marker is not visible to more than one camera because it is obscured by body parts or other markers—can occur.…”

Section: Introductionmentioning

confidence: 99%

Method for Using IMU-Based Experimental Motion Data in BVH Format for Musculoskeletal Simulations via OpenSim

Wechsler,

Wolf,

Fleischmann

et al. 2023

Sensors

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Biomechanical simulation allows for in silico estimations of biomechanical parameters such as muscle, joint and ligament forces. Experimental kinematic measurements are a prerequisite for musculoskeletal simulations using the inverse kinematics approach. Marker-based optical motion capture systems are frequently used to collect this motion data. As an alternative, IMU-based motion capture systems can be used. These systems allow flexible motion collection without nearly any restriction regarding the environment. However, one limitation with these systems is that there is no universal way to transfer IMU data from arbitrary full-body IMU measurement systems into musculoskeletal simulation software such as OpenSim. Thus, the objective of this study was to enable the transfer of collected motion data, stored as a BVH file, to OpenSim 4.4 to visualize and analyse the motion using musculoskeletal models. By using the concept of virtual markers, the motion saved in the BVH file is transferred to a musculoskeletal model. An experimental study with three participants was conducted to verify our method’s performance. Results show that the present method is capable of (1) transferring body dimensions saved in the BVH file to a generic musculoskeletal model and (2) correctly transferring the motion data saved in the BVH file to a musculoskeletal model in OpenSim 4.4.

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Application of Inertial Motion Unit-Based Kinematics to Assess the Effect of Boot Modifications on Ski Jump Landings—A Methodological Study

Cited by 4 publications

References 23 publications

What Are Kinematic and Kinetic Differences between Short and Parallel Turn in Alpine Skiing?

What Are Kinematic and Kinetic Differences between Short and Parallel Turn in Alpine Skiing?

Development of a simple algorithm to detect big air jumps and jumps during skiing

Method for Using IMU-Based Experimental Motion Data in BVH Format for Musculoskeletal Simulations via OpenSim

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