KINEMATIC CHARACTERISTICS OF THE APPROACH RUN ON HANDSPRING VAULT BY HIGH LEVEL MALE GYMNASTS HIGH LEVEL MALE GYMNASTS

Authors

  • Costas Dallas National and Kapodistrian University of Athens, Greece
  • George Dallas National and Kapodistrian University of Athens, Greece
  • Kalenia Papazogonopoulou National and Kapodistrian University of Athens, Greece
  • Apostolos Theodorou National and Kapodistrian University of Athens, Greece

DOI:

https://doi.org/10.52165/sgj.16.3.475-486

Keywords:

Kinematic characteristics, step length, approach run, hurdle step, handspring vault

Abstract

The approach run is a fundamental precondition for successful vault performance, as it enables the gymnast to develop maximum controlled horizontal velocity. The purpose of this study was to investigate the length, frequency, and velocity of steps during the run-up phase (approach run) in the execution of the handspring vault on the vaulting table. Nine high-level male artistic gymnasts, who performed the handspring vault under training conditions, volunteered to participate in the study. Five video cameras—four stationary and one scanning—were used to record the run-up phase, the hurdle step, and the take-off from the springboard. The gymnasts performed six trials of the handspring vault with a three-minute rest between each trial. Results showed that the final step was shorter than the penultimate step, and the penultimate step was longer than the preceding step. Additionally, the gymnasts demonstrated a gradual increase in their run-up velocity, a key requirement for a successful jump, up to the penultimate step. The average step frequency among gymnasts ranged from 3.20 to 4.88 steps per second, while the average step velocity across the six attempts was between 4.03 and 7.37 m/sec. Finally, a gradual increase in the gymnast’s velocity was observed up until the last step, with the final step being shorter than the penultimate step and the penultimate step being longer than the one before it.

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References

Atiković, A. (2012). New regression models to evaluate the relationship between biomechanics of gymnastic vault and initial vault difficulty values. Journal of Human Kinetics, 35, 119-126.

Atiković, A, Smajlović, N. (2011). Relation between vault difficulty values and biomechanical parameters in men's artistic gymnastics. Science of Gymnastics Journal, 3(3): 91-105.

Berg, W. P., & Mark, L. S. (2005). Information for step length adjustment in running. Human Movement Science, 24, 496–531.

Bradshaw, E. (2004). Target‐directed running in gymnastics: a preliminary exploration of vaulting. Sports Biomechanics, 3 (1), 125-144.

Bradshaw, E., Hume, P., Calton, M. & Aisbett, B. (2010). Reliability and variability of day-to-day vault training measures in artistic gymnastics. Sport Biomechanics, 9, 2, 79-97.

Brehmer, S., & Naundorf, F. (2011). Age-related development of run-up velocity on vault. Science of Gymnastics Journal, 3, 19–27.

Dallas, G., & Theodorou, A. (2020). The influence of a hurdle target point on the kinematics of the handspring vault approach run during training. Sports Biomechanics, 19 (4), 467-482.

Čuk, I., & Karacsony, I. (2004). Vault: methods, ideas, curiosities,history: ŠTD Sangvinčki.

Čuk, I., Bricelj, A., Bučar, M., Turšič, B., Atiković, A. (2007). Relations between start value of vault and runway velocity in top level male artistic gymnastics. In N. Smajlović (Eds.), Proceedings Book of 2rd International Scientific Symposium, Sarajevo.

Farana, R., Uchytil, J., Zahradník, D., & Jandačka, D. (2013). Kinematic analysis of "Lou Yun" vaults performed by top level male gymnasts: relationship between kinematic variables and judges' score. Acta Universitatis Palackianae Olomucensis. Gymnica, 43(1), 17-25.

Fernandes, S. M., Carrara, P., Serrao, J.C., Amadio, A. C., & Mochizuki, L. (2016). Kinematic variables of table vault on artistic gymnastics. Biodinamica, 30(1), 97-107.

FIG Code of Points (2022). Code of Points for Men. Federation internationale de gymnastique, Moutier.

Fujihara, T. (2016). Revisiting approach run velocity in gymnastics vaulting. In A. Michiyoshi, E. Yasushi, F. Norihisa, & T. Hideki (Eds.), Proceedings of the 34th Conference of the International Society of Biomechanics in Sports, (pp 593–596). Tsukuba, Japan.

Hay, J. G., & Koh, T. J. (1988). Evaluating the approach in the horizontal jumps. International Journal of Sport Biomechanics, 4, 372–392.

Heinen, T., Vinken, P. M., Jeraj, D., & Velentzas, K. (2013). Movement regulation of handsprings on vault. Research Quarterly for Exercise and Sport, 84, 68–78.

Hunter, J. P., Marshall, R. N., & McNair, P. J. (2004). Interaction of step length and step rate during sprint running. Medicine and Science in Sports and Exercise, 36(2), 261-71.

Kuitunen, S., Komi, P. V., & Kyröläinen, H. (2002). Knee and ankle joint stiffness in sprint running. Medicine and Science in Sports and Exercise, 34(1), 166-173.

Meeuwsen, H., & Magill, R. A. (1987). The role of vision in gait control during gymnastic vaulting. In T. B. Hoshizaki, J. H. Salmela, & B. Peliot (Eds.), Diagnostics. treatment and analysis of gymnastic talent (pp. 137–155). Montreal: Congres Scientifique de Gymnastique de Montreal, Inc.

Mero, A., & Komi, P.V. (1985). Effect of supramaximal velocity on biomechanical variables in sprinting. International Journal of Sport Biomechanics, 1, 240-252.

Milčić, L., Živčić, K., Krističević, T. (2019). Diefferences in vault run-up velocity in elite gymnasts. Science of Gymnastics Journal, 11(2), 201-207.

Penitente, G., Merni, F., Fantozzi, S., & Perretta, N. (2007). Kinematics of the springboard phase in Yurchenko-style vaults. In ISBS-Conference Proceedings Archive.

Plagenhoef, S. (1985). Patterns of human motion: A cinematographic analysis. Englewood Cliffs, NJ: Prentice-Hall.

Prassas, S., Kwon, Y.H., & Sands, W.A. (2006). Biomechanical research in artistic gymnastics: a review. Sports Biomechanics, 5(2), 261-291.

Salo, A. I. T., Bezodis, I. N., Batterham, A. M. & Kerwin, D. G. (2011). Elite sprinting: are athletes individually step frequency or step-length reliant?', Medicine and Science in Sports and Exercise, 43(6), 1055-1062. https://doi.org/10.1249/MSS.0b013e318201f6f8.

Sands, W. A. & McNeal, J. R. (1995). The relationship of vault run speeds and flight duration to score. Technique, 15 (5), 8-10.

Sands, W. A. (2000). Vault run speeds. Technique, 20(4), 1-5.

Takei, Y. (2007). The roche vault performed by elite gymnasts: somersaulting technique, deterministic model, and judges' scores. Journal of Applied Biomechanics, 23(1), 1-11.

Takei, Y. (1988). Techniques used in performing handspring and salto forward tucked in gymnastic vaulting. International Journal of Sport Biomechanics, 4 (3), 260-281.

Takei, Y, Blucker, E.P., Dunn, J.H., Myers, S.A. & Fortney, V.L. (1996). A Three-dimensional analysis of the men’s compulsory vault performed at the 1992 Olympic Games. International Journal of Sport Biomechanics, 12 (2), 237-257.

Tan, Z., Yao, X., Ma, Y., Bi, Y., Gao, Y., Zhao, Y., Yingjun, N. (2023). Run-up speed and jumping ground reaction force of male elite gymnasts on vault in China. Heliyon, 11, p. e21914

Tashiro, K., Takata, Y., Harada, M., Kano, M., & Yanagiya, T. (2008). Comparative studies about kinematics of maximal sprint running and running up in horse vaulting. In: Y.-H. Kwon, J. Shim, J. K. Shim, & I.-S. Shin (Eds.), Scientific Proceedings of the XXVI International Conference on Biomechanics in Sports (p.581), Seoul, Korea: Seoul National University.

Thorstensson, A., & Roberthson, H. (1987). Adaptations to changing speed in human locomotion: speed of transition between walking and running. Acta Physiologica Scandinavica, 131(2), 211-214.

Uzunov, V. (2007). Ideological approach to coaching the front handspring vault. Gym Coach, 1, 18–24.

Van der Eb, J., Filius, M., Rougoor, G., van Niel, C., de Water, J., Coolen, B., de Koning, H. (2012). Optimal velocity profiles for vault. 30th Annual Conference of Biomechanics in Sports – Melbourne 2012.

Veličković, S., Petković, D., & Petković, E. (2011). A case study about differences in characteristics of the approach run approach on the vault between top-class and middle-class gymnasts. Science of Gymnastics Journal, 3, 25–34.

Weyand, P.G., Sternlight, D.B., Bellizzi, M.J., & Wright, S. (2000). Faster top running speeds are achieved with greater ground forces not more rapid leg movements. Journal of Applied Physiology, 89(5), 1991-1999.

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Published

2024-10-30

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How to Cite

Dallas, C., Dallas, G., Papazogonopoulou, K., & Theodorou, A. . (2024). KINEMATIC CHARACTERISTICS OF THE APPROACH RUN ON HANDSPRING VAULT BY HIGH LEVEL MALE GYMNASTS HIGH LEVEL MALE GYMNASTS. Science of Gymnastics Journal, 16(3), 475-486. https://doi.org/10.52165/sgj.16.3.475-486

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