• Title/Summary/Keyword: Jump Shot

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Taking a Jump Motion Picture Automatically by using Accelerometer of Smart Phones (스마트폰 가속도계를 이용한 점프동작 자동인식 촬영)

  • Choi, Kyungyoon;Jun, Kyungkoo
    • Journal of KIISE
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    • v.41 no.9
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    • pp.633-641
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    • 2014
  • This paper proposes algorithms to detect jump motion and automatically take a picture when the jump reaches its top. Based on the algorithms, we build jump-shot system by using accelerometer-equipped smart phones. Since the jump motion may vary depending on one's physical condition, gender, and age, it is critical to figure out common features which are independent from such differences. Also it is obvious that the detection algorithm needs to work in real-time because of the short duration of the jump. We propose two different algorithms considering these requirements and develop the system as a smart phone application. Through a series of experiments, we show that the system is able to successfully detect the jump motion and take a picture when it reaches the top.

Kinetic Analysis of Three-Point Jump Shot in Basketball (농구 3득점 점프슛 동작의 운동역학적 분석)

  • Lee, Dong-Jin;Jeong, Ik-Su
    • Korean Journal of Applied Biomechanics
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    • v.20 no.1
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    • pp.49-55
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    • 2010
  • The purpose of the study was to analyze kinetic factors required to the three-point jump shot of the basketball games through 3-D analysis and ground reaction force(GRF) analysis. Six university male players participated in this study. The results of the study were showed that (1) resultant velocity in the center of mass(COM) was $0.84{\pm}0.27\;m/s$ since a player didn't shot a ball in the highest peak and shot ball at the moment of going up forward and vertical movement. Therefore, it is necessary to find a proper timing to shot a ball; (2) the angular velocity was largely increased in upper arm and fore arm out of the upper-limb segments and the hands had the largest angular velocity since the body is in a fixed situation and angular speed is rapidly increased by the wrist' snap with the rapid movement of upper arm and forearm at the time of release a ball; (3) it is judged that a player can shot a ball at the accurate and high release point when the player collects power vertically to the maximum by keeping GRF to the right and the rear in a proper way and by keeping the body's balance so that a large power may not be dispersed.

On the Project of the Sport Biomechanics of IAAF World Championships Daegu 2011 (2011 대구세계육상선수권대회 운동역학 프로젝트 수행 방안)

  • Lee, Joong-Sook;Park, Jong-Jin;Bae, Young-Sang;Chae, Woen-Sik;Ryu, Jae-Kyun;Park, Seung-Bum
    • Korean Journal of Applied Biomechanics
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    • v.20 no.3
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    • pp.253-259
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    • 2010
  • The aim of IAAF's Biomechanics project, initially launched at the 1987 World Championships in Rome, is to support athletes and coaches in the optimization and improvement of their training and competition performance. The IAF and the IAAF supports biomechanical projects, as a service to their Member Federations, starting from the IAAF World Championships in Rome 1987. In 1997, at the IAAF World Championships of Athens. In 1995, at the IAAF World Championships in Goteborg and in co-operation with the Swedish Sport Institute of Karlstad and under the leadership of Anders Bergstrom a biomechanical research on "Throws" was conducted. In 2005, at the IAAF World Championships in Helsinki on 100m - Pole vault, High Jump, Triple Jump, Javelin, under the leadership of Prof. Paavo Komi. The IAAF published the final report in 2008 with a supplement of NSA. In 2007, at the IAAF World Championships of Osaka, in co-operation with Osaka University of Health and Sport Sciences and under the leadership of Prof. Michiyoshi Ae the IAAF received a final report on; short sprint, distance running, high jump, long jump, shot put and javelin. In 2009, at the IAAF World Championships of Berlin, in co-operation with the DLV and the leadership of Helmar Hommel (GER). The purpose of this study is to draw up a plan to perform an effective biomechanics project at 2011 IAAF World championship in Daegu.

Sport Biomechanics Research Project at IAAF World Championships Daegu 2011 (2011 대구세계육상선수권대회 운동역학 프로젝트 수행 경과보고)

  • Bae, Young-Sang;Park, Young-Jin;Park, Jong-Jin;Lee, Joong-Sook;Chae, Woen-Sik;Park, Seung-Bum
    • Korean Journal of Applied Biomechanics
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    • v.21 no.5
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    • pp.503-510
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    • 2011
  • The purpose of this study was to find the biomechanical research project result carried out at 2011 IAAF World championship in Daegu. This project was approved by the International Amateur Athletic Federation(IAAF) and financially supported by the Ministry of Culture, Sports and Tourism(MCST) and, Korea Association of Athletics Federations(KAAF). The total number of the project members was 20, including the members of the Scientific Committee, the Korean Society of Sport Biomechanics(KSSB) and graduate students as assistants. The objective of this project has been to analyze the performance in the track events(100 m, 110 mH) and field events(Long Jump, High Jump, Triple Jump, Pole Vault, Javelin Throw and Shot Put). This project was focused on the biomechanical research only. This kind of analysis has been carried out at major competitions for more than a decade, as it provides coaches and athletes with very useful information as an aid to training programmes and competition preparation. The biomechanical analysis of the top athletes in the world in each specialty serves as a reference for assessing technique and rationalizing the results achieved. The results will be disseminated world-wide and coaches will be in a better position to design training strategies in line with current world trends.

Effect of CrossFit Power Training on TPI OnBaseU Power Test and Golf Performance (크로스핏 파워 트레이닝이 TPI OnBaseU Power Test와 골프 수행력에 미치는 영향)

  • Chang Wook Kim
    • Korean Journal of Applied Biomechanics
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    • v.33 no.4
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    • pp.185-195
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    • 2023
  • Objective: The purpose of this study is to improve TPI OnBaseU Power Test and golf performance by conducting CrossFit power training. Method: Three male golf players from University B participated in this study. They had 3 to 4 years of golf experience and participated in 8 weeks of CrossFit power training. Results: OnBaseU Power Test: There was a lot of improvement in Sit up throw (27.9%) and Chest pass (10.58%), but there was not much improvement in Baseline Toss (R5.9, L9.8%) and Vertical Jump (4.1%). Golf shot data: There was a very statistically significant difference in Club speed, Ball speed, and Total Length, which are related to speed, and there was no difference in Club path and Smash factor, which are related to accuracy and posture. Conclusion: CrossFit power training was effective in improving TPI OnBaseU Power Test and golf performance (Club speed, Ball speed, Total Length).