آمار

تعداد نشریات26
تعداد شماره‌ها305
تعداد مقالات2,636
تعداد مشاهده مقاله3,959,974
تعداد دریافت فایل اصل مقاله2,666,974
Hariri, ُSalar, Sadeghi, Heydar, GhiamiRad, Amir, Nikokheslat, Saeed. (1401). Comparing the Dynamic Model of Torque and Angular Velocity in Four Methods of Performing the Judan Mai-Mawashi-Geri Technique by Elite Male Karatekas. سامانه مدیریت نشریات علمی, 6(1), 39-50. doi: 10.22098/jast.2022.1731
ُSalar Hariri; Heydar Sadeghi; Amir GhiamiRad; Saeed Nikokheslat. "Comparing the Dynamic Model of Torque and Angular Velocity in Four Methods of Performing the Judan Mai-Mawashi-Geri Technique by Elite Male Karatekas". سامانه مدیریت نشریات علمی, 6, 1, 1401, 39-50. doi: 10.22098/jast.2022.1731
Hariri, ُSalar, Sadeghi, Heydar, GhiamiRad, Amir, Nikokheslat, Saeed. (1401). 'Comparing the Dynamic Model of Torque and Angular Velocity in Four Methods of Performing the Judan Mai-Mawashi-Geri Technique by Elite Male Karatekas', سامانه مدیریت نشریات علمی, 6(1), pp. 39-50. doi: 10.22098/jast.2022.1731
Hariri, ُSalar, Sadeghi, Heydar, GhiamiRad, Amir, Nikokheslat, Saeed. Comparing the Dynamic Model of Torque and Angular Velocity in Four Methods of Performing the Judan Mai-Mawashi-Geri Technique by Elite Male Karatekas. سامانه مدیریت نشریات علمی, 1401; 6(1): 39-50. doi: 10.22098/jast.2022.1731

Comparing the Dynamic Model of Torque and Angular Velocity in Four Methods of Performing the Judan Mai-Mawashi-Geri Technique by Elite Male Karatekas

Journal of Advanced Sport Technology
دوره 6، شماره 1، تیر 2022، صفحه 39-50    اصل مقاله (1.17 M)
نوع مقاله: Original research papers
شناسه دیجیتال (DOI): 10.22098/jast.2022.1731
نویسندگان
ُSalar Hariri1؛ Heydar Sadeghi* 2؛ Amir GhiamiRad3؛ Saeed Nikokheslat4
1Department of Sport Biomechanics, Central Tehran Branch, Islamic Azad University, Tehran, Iran.
2Department of Sport Biomechanics, Kinesiology Research Center, Kharazmi University, Tehran, Iran.
3Department Motor Behavior, Faculty of Physical Education and Sport Sciences, University of Tabriz, Tabriz, Iran.
4Department of Exercise Physiology, Faculty of Physical Education and Sport Sciences, University of Tabriz, Tabriz, Iran
چکیده
The aim of this study was to compare the dynamic model of torque and angular velocity in four methods of performing the Judan Mai-Mawashi-Geri technique by elite male karatekas. Eighteen elite male kumite practitioners participated in this study with mean and standard deviation age of 24.1±3.5 years, height of 176.2±4.6 cm, and weight of 73.7±6.5 kg. They had 2.5±1.98 years of experience in the national karate team and 2.8±1 years of experience in Iran’s Karate Super League. Six markers were attached to the anatomical points of the hitting foot. Three Hero3 cameras at a speed of 240 frames per second were used for collecting data about four methods of performing the Judan Mai-Mawashi-Geri technique. SkillSpector (version: 1.3.2) was used to obtain the joint coordinates (XY) and MATLAB was used to build the model. The one-way analysis of variance and the Bonferroni post-hoc test (p≤0.05) were used for statistical analysis after ensuring the normality of data distribution. The results showed a significant difference in the maximum torque and maximum angular velocity of the pelvic, knee, and ankle joints in the four methods of performing the Judan Mai-Mawashi-Geri technique. According to the results of the study, while emphasizing the sequential order of torque of the proximal to distal limb joints, we recommend the third method of performing the Judan Mai-Mawashi-Geri technique for an optimal and powerful implementation of this skill since the angular velocity of the knee joint is directly related to the peak velocity of the foot.
کلیدواژه‌ها
Karate؛ Dynamic Model؛ Judan Mai-Mawashi-Geri؛ Torque؛ Angular Velocity
مراجع
  1. Abd Alsamad, T.F., The kinematics analysis of doubles kazami mawashi-geri for heavy weight players under the maximum load in karate. World Journal of Sport Sciences. 2012;7(1):16-19.
  2. Lotfian, S. et al., Assessment of Correlation between Electrogoniometer Measurements and Sports-Specific Movement in Karate Elites. Asian Journal of Sports Medicine. 2014;5(2):115-22.
  3. El-Daly, A., Biokinematical analysis for “mai-mawashi geri” based on two different levels of the competitors body in karate. World Journal of Sport Sciences. 2010;3(3):161-7.
  4. Edwards, D., R. Buckmire, and J. Ortega-Gingrich, A mathematical model of cinematic box-office dynamics with geographic effects. IMA Journal of Management Mathematics. 2014;25(2):233-257.
  5. Hariri, S. and H. Sadeghi, Biomechanical Analysis of Mawashi-Geri Technique in Karate. International Journal of Sport Studies for Health. 2018;1(4):e84349
  6. Toro, A.C., Análisis cinemático de la Mawashi Geri a la cara ejecutada por atletas masculinos venezolanos de karate do Kinematics analysis of the Mawashi Gueri to the face performed by male Venezuelan athletes of karate do Resumen. Revista Con-Ciencias del Deporte. 2018;1(2):156-175.
  7. Mori, S., Y. Ohtani, and K. Imanaka, Reaction times and anticipatory skills of karate athletes. Human Movement Science. 2002;21(2):213-30.
  8. Gavagan, C.J. and M.G.L. Sayers, A biomechanical analysis of the roundhouse kicking technique of expert practitioners: A comparison between the martial arts disciplines of Muay Thai, Karate, and Taekwondo. PLoS One. 2017;12(8):e0182645.
  9. Haj Lotfalian, M., S. Lenjannejadian, and H. Mojtahedi, Kinetic analysis of maximum effort low drive and high drive soccer instep kick via dynamic model. Studies in Sport Medicine. 2014;5(14):59-72.
  10. Khan, T.K.A., T. Morris, and D. Marchant, portable devices for delivering imagery and modelling among netball players, a qualitative study (50-64). Jurnal Sains Sukan & Pendidikan Jasmani. 2015;4(1):50-64.
  11. Barzouka, K., N. Bergeles, and D. Hatziharistos, Effect of simultaneous model observation and self-modeling of volleyball skill acquisition. Perceptual and Motor Skills. 2007;104(1):32-42.
  12. Boyer, E., et al., Video modeling by experts with video feedback to enhance gymnastics skills. Journal of Applied Behavior Analysisl. 2009;42(4):855-60.
  13. Law, B. and A. Rymal, Now hear this: auditory sense may be an undervalued component of effective modeling and imagery interventions in sport. The Open Psychology Journal. 2015;8(1):203-211
  14. Spägele, T., A. Kistner, and A. Gollhofer, Modelling, simulation and optimisation of a human vertical jump. Journal of biomechanics. 1999;32(5):521-30.
  15. Kellis, E. and A. Katis, Biomechanical characteristics and determinants of instep soccer kick. Journal of Sports Science and Medicine. 2007;6(2):154-65.
  16. Cynarski, W.J., W. Wajs, and A. VencesBrito, Improving the movements of basic karate techniques with the use of motion capture and mathematical modeling. The concept of a research project. Ido Movement for Culture. Journal of Martial Arts Anthropology. 2014;1(14):39-53.
  17. PortelaABCDE, B.S., et al., Kinematics analysis of the front kick with and without impact on traditional karate. Archives of Budo Science of Martial Arts and Extreme Sports. 2014;30(10):47-51
  18. Karsai, I., A. Conceição, and L. Takács, Reliability of the 3D Underwater Motion Analysis. Motricidade. 2019;15(1):104-104.
  19. Sharifnezhad, A., et al., C3D data based on 2-dimensional images from video camera. Annals of Biomedical Science and Engineering. 2021;5(1):1-5.
  20. Omorczyk, J., et al., Use of biomechanical analysis for technical training in artistic gymnastics using the example of a back handspring. Selected problems of biomechanics of sport and rehabilitatio nvol II. 2014.
  21. Moghaddami, A., et al., Kinematic analysis of the effect of rapid weight loss by sauna on elite wrestlers’ single leg takedown technique. European journal of physical education and sport. 2015;4:197-205.
  22. Silvestre, G., et al., Analysis of the human walking gait with and without external weight added on lower limbs of physically active individuals. Motricidade. 2019;15(1):69-69.
  23. Robertson, D.G.E., et al., Research methods in biomechanics. 2013; Human kinetics.
  24. Winter, D.A., Biomechanics and motor control of human movement. 2009; John Wiley & Sons.
  25. Salimi, A., S. Lenjannejadian, and A.R. Movahedi, A dynamic model for analyzing biomechanical parameters of basketball free throws. Studies in Sport Medicine.2014;5(14):91-108.
  26. Nunome, H., et al., Three-dimensional kinetic analysis of side-foot and instep soccer kicks. Medicine & Science in Sports & Exercise. 2002;34(12):2028-36.
  27. Nunome, H., et al., Segmental dynamics of soccer instep kicking with the preferred and non-preferred leg. Journal of sports sciences. 2006;24(5):529-541.
  28. Luhtanen, P., Kinematics and kinetics of maximal instep kicking in junior soccer players. In Science and Footbal. 1988;4(1):441-445
  29. DRGE, H., EMG activity of theiliopsoas muscle and leg kinetics during the soccer. Scandinavian Journal of Medicine & Science in Sports. 1999;9(4):195-200.
  30. Putnam, C.A., A segment interaction analysis of proximal-to-distal sequential segment motion patterns. Medicine & Science in Sports & Exercise. 1991;23(1):130-44.
  31. Dörge, H.C., et al., EMG activity of the iliopsoas muscle and leg kinetics during the soccer place kick. Scandinavian Journal of Medicine & Science in Sports. 1999;9(4):195-200.
  32. Merk, A. and A. Resnick, Physics of martial arts: Incorporation of angular momentum to model body motion and strikes. Plos one. 2021;16(8):e0255670.
  33. Estevan, I., et al., Comparison of Lower Limb Segments Kinematics in a Taekwondo Kick. An Approach to the Proximal to Distal Motion. Journal of Human Kinetics. 2015;14(47):41-9.
  34. Piemontez, G.R., et al., Cinemática do chute semicircular no karatê: comparação entre as fases de ataque e retorno. Revista da Educação Física/UEM. 2013;24(1):51-59.
  35. Hudson, J.L., Coordination of segments in the vertical jump. Medicine & Science in Sports & Exercise. 1986; 18(2):242-51.
  36. Quinzi, F., et al., Differences in neuromuscular control between impact and no impact roundhouse kick in athletes of different skill levels. Journal of Electromyography and Kinesiology. 2013;23(1):140-50.
  37. De Witt, J.K. and R.N. Hinrichs, Mechanical factors associated with the development of high ball velocity during an instep soccer kick. Sports Biomech. 2012;11(3):382-90.
  38. Levanon, J. and J. Dapena, Comparison of the kinematics of the full-instep and pass kicks in soccer. Medicine & Science in Sports & Exercise. 1998;30(6):917-27.
  39. Amiri-Khorasani, M., N.A.A. Osman, and A. Yusof, Kinematics analysis: number of trials necessary to achieve performance stability during soccer instep kicking. Journal of Human Kinetics. 2010;23(1):15-20.
آمار
تعداد مشاهده مقاله: 291
تعداد دریافت فایل اصل مقاله: 420


سامانه مدیریت نشریات علمی. قدرت گرفته از سیناوب