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Literature DB >> 648508

Segmental contribution to forces in vertical jump.

Abstract

Performance of a vertical jump was analyzed with respect to the contribution of the different body segments to the forces acting on the whole body center of gravity. Both cinematograph and force-platform techniques were employed. The data disclosed that the take-off velocity in vertical jumps was caused by the different components as follows: knee extension 56%, plantar flexion 22%, trunk extension 10%, arm swing 10%, and head swing 2%. However, the average take-off velocity of the total performance (3.03 m/s) was only 76% from the theoretical maximum calculated from the segmental analyses. Optimal timing of the segmental performances was calculated to increase this "efficiency" to 84%. Great variance were observed among individuals in the total performance despite the similarities in utilization of the performance of individual segments.

Mesh：

Year: 1978 PMID： 648508 DOI： 10.1007/BF00430076

Source DB: PubMed Journal: Eur J Appl Physiol Occup Physiol ISSN： 0301-5548

4 in total

1. Apparent efficiency and storage of elastic energy in human muscles during exercise.

Authors: E Asmussen; F Bonde-Petersen
Journal: Acta Physiol Scand Date: 1974-12

2. Muscular activity pattern for skilled performance and during learning of a horizontal bar exercise.

Authors: E Kamon; J Gormley
Journal: Ergonomics Date: 1968-07 Impact factor: 2.778

3. Positive work done by a previously stretched muscle.

Authors: G A Cavagna; B Dusman; R Margaria
Journal: J Appl Physiol Date: 1968-01 Impact factor: 3.531

4. Tapping regularity as a measure of perceptual motor load.

Authors: J A Michon
Journal: Ergonomics Date: 1966-09 Impact factor: 2.778

4 in total

17 in total

8. Relationship of Vertical Jump Performance and Ankle Joint Range of Motion: Effect of Knee Joint Angle and Handedness in Young Adult Handball Players.

Authors: Vassilios Panoutsakopoulos; Mariana C Kotzamanidou; Athanasios K Giannakos; Iraklis A Kollias
Journal: Sports (Basel) Date: 2022-05-28

9. Functional performance testing for power and return to sports.

Authors: Robert Manske; Michael Reiman
Journal: Sports Health Date: 2013-05 Impact factor: 3.843

10. Mechanical Impedance and Its Relations to Motor Control, Limb Dynamics, and Motion Biomechanics.

Authors: Joseph Mizrahi
Journal: J Med Biol Eng Date: 2015-01-27 Impact factor: 1.553

Segmental contribution to forces in vertical jump.

1. Apparent efficiency and storage of elastic energy in human muscles during exercise.

2. Muscular activity pattern for skilled performance and during learning of a horizontal bar exercise.

3. Positive work done by a previously stretched muscle.

4. Tapping regularity as a measure of perceptual motor load.

1. The relationship between muscle kinetic parameters and kinematic variables in a complex movement.

2. Muscle Contraction Velocity: A Suitable Approach to Analyze the Functional Adaptations in Elite Soccer Players.

3. Intersegmental moment analysis characterizes the partial correspondence of jumping and jerking.

4. STATIC STRETCHING DOES NOT REDUCE VARIABILITY, JUMP AND SPEED PERFORMANCE.

5. Alterations of Vertical Jump Mechanics after a Half-Marathon Mountain Running Race.

6. A work-energy approach to determine individual joint contributions to vertical jump performance.

7. Relationship between isokinetic performance and ballistic movement.

8. Relationship of Vertical Jump Performance and Ankle Joint Range of Motion: Effect of Knee Joint Angle and Handedness in Young Adult Handball Players.

9. Functional performance testing for power and return to sports.

10. Mechanical Impedance and Its Relations to Motor Control, Limb Dynamics, and Motion Biomechanics.