著者
豊嶋 陵司 桜井 伸二
出版者
一般社団法人 日本体育学会
雑誌
体育学研究 (ISSN:04846710)
巻号頁・発行日
pp.17008, (Released:2018-06-15)
参考文献数
47

This study investigated the relationships between the kinetic factor of the swing leg and step frequency (SF) and step length (SL) during the top speed phase of a sprint. Sixteen male sprinters (age 19.3±0.6 years, height 1.74±0.06 m, weight 66.1±5.2 kg) performed maximum effort 60-m sprints. Video data from the 43.5- to 50-m section of the sprint were collected using a high-speed camera (300 Hz). SF index and SL index were calculated to exclude the influence of body height on the outcomes of interest. Torque and torque power of the hip and knee joints of the right leg were calculated during the swing phase of the right leg. The time of the swing phase of the right leg was normalized so that the take-off of the right foot, touchdown of the left foot, take-off of the left foot, and touchdown of the right foot were 0%, 100%, 200%, and 300%, respectively. For every 5% of normalized time, partial correlation analysis was conducted between the right leg kinetics and SF index (controlling SL index) and SL index (controlling SF index). The SF index was associated with a large hip flexion torque and a large hip extension torque during 10–60% and 250–280% of the swing phase, respectively. Moreover, large peaks of the hip flexion torque and positive power were associated with a high SF index (r = -.718, p <0.01; r = .531, p <0.05, respectively). The SL index was associated with a hip flexion torque during 20–30% of the swing phase, although there was no significant partial correlation between the SL index and peak hip flexion torque (r = -.381, p = .161). In addition, a high SL index was associated with early appearance of the peak hip flexion torque power (r = -.759, p <0.01). In conclusion, throughout the top speed phase of a sprint, a high SF index requires a large torque and hip joint power for the leg swing over a short duration, and a high SL index requires an early increase of hip flexion torque power.
著者
堀内 元 豊嶋 陵司 鈴木 雄貴 桜井 伸二
出版者
一般社団法人 日本体育・スポーツ・健康学会
雑誌
体育学研究 (ISSN:04846710)
巻号頁・発行日
vol.64, no.2, pp.841-854, 2019-12-16 (Released:2019-12-20)
参考文献数
24

The purpose of this study was to clarify the kinematics of the jump floater serve in volleyball to provide basic data for research. The jump floater serve motions of 9 female volleyball players (body height: 174.4±6.2 cm, body weight: 67.7±6.1 kg, age: 23.6±4.6 yr, career: 14.4±5.1 yr) were recorded using a motion capture system with 10 cameras (500 Hz). The three-dimensional coordinates of retro-reflective markers on the volleyball were also collected using a motion capture system. The primary variables examined were the hand velocity of the swing arm at impact, the velocity and angular velocity of the volleyball after impact, the joint angles of the swing arm and torso, and the segment angle of the lower torso during the jump floater serve. The main results were as follows. 1. The speed of the volleyball was about 14 m/s, and the spin of the volleyball was about 1 rps. 2. No significant correlation was found between the number of volleyball rotations around each axis and the impact parameters of the swing hand. 3. The maximal right rotation angle of the torso joint in the jump floater serve was smaller than that of the spike motion. 4. The abduction angle of the shoulder joint at ball impact in the jump floater serve was similar to that of a spike motion. 5. From the end of take back to the middle of the serve motion, the standard deviation in the abduction angle of the shoulder joint was notably large. 6. The maximal external rotation of the shoulder joint was smaller in comparison with a baseball pitch or a tennis serve. 7. The extension angle of the elbow joint at impact was smaller in comparison with the volleyball spike motion.
著者
豊嶋 陵司 桜井 伸二
出版者
一般社団法人 日本体育学会
雑誌
体育学研究 (ISSN:04846710)
巻号頁・発行日
vol.63, no.2, pp.479-493, 2018-12-10 (Released:2018-12-20)
参考文献数
47

This study investigated the relationships between the kinetic factor of the swing leg and step frequency (SF) and step length (SL) during the top speed phase of a sprint. Sixteen male sprinters (age 19.3±0.6 years, height 1.74±0.06 m, weight 66.1±5.2 kg) performed maximum effort 60-m sprints. Video data from the 43.5- to 50-m section of the sprint were collected using a high-speed camera (300 Hz). SF index and SL index were calculated to exclude the influence of body height on the outcomes of interest. Torque and torque power of the hip and knee joints of the right leg were calculated during the swing phase of the right leg. The time of the swing phase of the right leg was normalized so that the take-off of the right foot, touchdown of the left foot, take-off of the left foot, and touchdown of the right foot were 0%, 100%, 200%, and 300%, respectively. For every 5% of normalized time, partial correlation analysis was conducted between the right leg kinetics and SF index (controlling SL index) and SL index (controlling SF index). The SF index was associated with a large hip flexion torque and a large hip extension torque during 10–60% and 250–280% of the swing phase, respectively. Moreover, large peaks of the hip flexion torque and positive power were associated with a high SF index (r = -.718, p <0.01; r = .531, p <0.05, respectively). The SL index was associated with a hip flexion torque during 20–30% of the swing phase, although there was no significant partial correlation between the SL index and peak hip flexion torque (r = -.381, p = .161). In addition, a high SL index was associated with early appearance of the peak hip flexion torque power (r = -.759, p <0.01). In conclusion, throughout the top speed phase of a sprint, a high SF index requires a large torque and hip joint power for the leg swing over a short duration, and a high SL index requires an early increase of hip flexion torque power.
著者
豊嶋 陵司 田内 健二 遠藤 俊典 礒 繁雄 桜井 伸二
出版者
一般社団法人 日本体育学会
雑誌
体育学研究 (ISSN:04846710)
巻号頁・発行日
pp.14062, (Released:2015-04-30)
参考文献数
27
被引用文献数
3 3

The purpose of this study was to clarify the biomechanical factors that influence intra-individual variations in step frequency (SF) and length (SL) during sprint running. One male sprinter participated as a study subject, and performed a 60-m sprint at maximal effort. Experiments were conducted 5 times, with a total number of 14 trials. The ground reaction force and positions of markers attached to the joints were recorded using force plates and a motion capture system. Trials were divided into SF type and SL type depending on the SF/SL ratio, and the kinematic variables and ground reaction force were compared. The main results were as follows.   1)  There were no significant differences in sprint velocity and stance time between the SF type and the SL type.   2)  The flight time of the SL type was longer than that of the SF type.   3)  Vertical components of the ground reaction force and impulse during the stance phase were larger for the SL type than for the SF type.   4)  The thigh angle of the swing leg was larger for the SL type than for the SF type during almost all phases.   5)  The hip joint of the swing leg was flexed to a greater degree during the stance phase and first half of the flight phase for the SL type than for the SF type.   6)  There were no marked differences in the segment and joint angular velocities between the SF type and the SL type.   These results indicate that changes in step frequency and step length with flight time are due to an increase or decrease of vertical impulse. Moreover, it was revealed that vertical impulse is influenced by the thigh angle of the swing leg during the stance phase, rather than by the angular velocity of the swing leg.
著者
豊嶋 陵司 桜井 伸二
出版者
一般社団法人 日本体育学会
雑誌
体育学研究 (ISSN:04846710)
巻号頁・発行日
pp.17126, (Released:2019-02-26)
参考文献数
19

In sprint running, stance time and flight time influence running speed. This study investigated the relationship between flight ratio (= flight time/stance time) and the upper limbs and recovery leg during the top speed phase in sprinting. Sixteen male sprinters (age 19.3±0.6 y, height 1.74±0.06 m, weight 66.1±5.2 kg) performed maximum-effort 60-m sprints. Video data from the 43.5 to 50 m section of the sprint were collected using a high-speed camera (300 Hz). Flight ratio and vertical acceleration force of the upper limbs relative to the sternum and recovery leg relative to the hip were calculated. The data revealed a significant positive correlation between flight ratio and the relative vertical acceleration force of the forward arm, backward arm, and recovery leg at the instant of touchdown (r =.597, .546, .592). The maximum value of the relative vertical acceleration force of the forward arm, backward arm, and recovery leg during the stance phase was not associated with the flight ratio. In contrast, early appearance of the maximum value of the vertical relative acceleration force of the forward arm, backward arm, and recovery leg during the stance phase was associated with a high flight ratio (r = -.553, -.644, -.855). Multiple regression analysis revealed that the high angular velocity and low extension acceleration of the arms and recovery leg at touchdown made a significant contribution to high relative vertical acceleration. In conclusion, rapid swinging and high shortening acceleration of the arms and recovery leg can contribute to a high flight ratio by facilitating a high relative vertical acceleration force.
著者
豊嶋 陵司 田内 健二 遠藤 俊典 礒 繁雄 桜井 伸二
出版者
一般社団法人 日本体育学会
雑誌
体育学研究 (ISSN:04846710)
巻号頁・発行日
vol.60, no.1, pp.197-208, 2015 (Released:2015-06-13)
参考文献数
27
被引用文献数
5 3

The purpose of this study was to clarify the biomechanical factors that influence intra-individual variations in step frequency (SF) and length (SL) during sprint running. One male sprinter participated as a study subject, and performed a 60-m sprint at maximal effort. Experiments were conducted 5 times, with a total number of 14 trials. The ground reaction force and positions of markers attached to the joints were recorded using force plates and a motion capture system. Trials were divided into SF type and SL type depending on the SF/SL ratio, and the kinematic variables and ground reaction force were compared. The main results were as follows.   1)  There were no significant differences in sprint velocity and stance time between the SF type and the SL type.   2)  The flight time of the SL type was longer than that of the SF type.   3)  Vertical components of the ground reaction force and impulse during the stance phase were larger for the SL type than for the SF type.   4)  The thigh angle of the swing leg was larger for the SL type than for the SF type during almost all phases.   5)  The hip joint of the swing leg was flexed to a greater degree during the stance phase and first half of the flight phase for the SL type than for the SF type.   6)  There were no marked differences in the segment and joint angular velocities between the SF type and the SL type.   These results indicate that changes in step frequency and step length with flight time are due to an increase or decrease of vertical impulse. Moreover, it was revealed that vertical impulse is influenced by the thigh angle of the swing leg during the stance phase, rather than by the angular velocity of the swing leg.