高水平短跑运动员途中跑摆动技术肌肉用力特征及其专项力量训练手段的优化
|
摘要
研究目的:本研究选取以快速力量为代表的短跑途中跑摆动技术环节作为研究动作,运用运动学与表面肌电遥测同步测试方法,分析现代高水平短跑运动员途中跑摆动技术的动作特点和肌肉活动特点,并对短跑途中跑摆动技术部分专项力量训练手段进行筛选,优选出更加符合现代短跑技术要求的专项力量训练手段。
研究方法:运用美国产MotionPro X-4高速摄像机和德国产Biovision16通道无线肌电遥测仪同步采集我国男子高水平短跑运动员途中跑摆动技术及其部分专项力量训练手段的运动学和表面肌电数据。运动学图像采用德国SIMI motion图像解析系统解析,获得各关节角度、角速度数据;原始肌电信号采用DASYlab8.0肌电分析软件进行处理,原始肌电信号经带通滤波,全波整流,获得积分肌电、包络线等参数.
研究结果:
短跑途中跑摆动技术肌肉用力特征研究结果
在完成短跑途中跑摆动技术动作中,摆动腿各肌肉活动的顺序是:阔筋膜张肌-股直肌-胫骨前肌-臀大肌-股后肌群(股二头肌长头、半腱肌)-腓肠肌内外侧头-股四头肌(股内、股外、股直肌)。折叠前摆阶段,以阔筋膜张肌、股直肌为代表的屈髋肌(髂腰肌)是主要用力肌肉;下压着地阶段,臀大肌、股二头肌长头、半腱肌是主要用力肌肉。在短跑途中跑摆动技术的初期:髋关节屈肌群出现强烈的肌电活动,并且阔筋膜张肌有收缩时间早于股直肌,收缩强度大于股直肌的特点;在(支撑腿)垂直支撑时刻后,摆动腿股后肌群(股二头肌长头、半腱肌)的活动明显,其积极活动的时间较长。短跑途中跑摆动技术部分专项力量训练手段的优化
支撑摆腿拉橡皮带练习能够有效锻炼屈髋肌群以及踝背屈肌,但容易形成大腿紧张,大小腿折叠不紧等问题。同时由于伸髋屈膝肌半腱肌参与了活动,半腱肌的这种活动特点是否会影响短跑摆动技术中主动肌与拮抗肌之间的协调性还需要进一步研究。负重仰卧高抬摆腿练习与支撑摆腿拉橡皮带练习相比,负重仰卧高抬摆腿练习摆动腿髋屈伸肌群的时序性、协调性协优于支撑摆腿拉橡皮带练习中摆动腿髋屈伸肌群的协调性,但由于负重仰卧高抬摆腿的动作速度低于短跑途中跑摆动腿的关节速度,应注意把握训练的强度以提高训练质量。
负重车轮跑练习在力量练习的动作形式,动作速度以及肌电活动的模式、主要用力肌肉、时序性、协调性及其活动特点上,均与短跑摆动技术相一致。因此,负重车轮跑是发展短跑专项力量的重要训练手段。俯卧后屈腿拉橡皮带能够发展股后肌群的肌肉力量,但其肌肉活动的性质与短跑摆动技术中股后肌群活动的性质不同,不能作为短跑摆动技术股后肌群专项力量训练的手段。研究结论:在短跑专项力量训练实践中,要注重主要用力肌肉的专项力量训练,在设计、选择专项力量训练手段时,应充分考虑摆动腿由蹬伸末期至另一腿(支撑腿)垂直支撑时刻屈髋肌群的发力特点,应选择大腿由后伸位向体前摆的动作结构为依据;针对双关节肌的专项力量训练而言,应该多挖掘与短跑摆动技术相类似的训练手段、方法,使肌肉收缩特征更贴近于专项动作要求。
Purpose: This study take the fast strength of swinging technique during the sprint asstudy action, and it uses kinematics and surface electromyography test methods toanalyze the swinging technique characteristics and muscle activity features on theway of high-level sprinters. In addition, it sieve part special forces training methods ofswinging technique during sprint out. and it prefer the special forces training methodswhich are more suit the technical requirements of modern sprint.
Methods: It use the MotionPro X—4high speed camera which made in Americaand Biovision16channel wireless surface electromyographic telemetry instrumentwhich made in Germany to collect the kinematics and surface electromyography datesof swinging technique and part special forces training methods on the way of Chinesehigh-level male sprinter. Kinematics image uses the image analysis system whichmade in Germany to analyse the image, and get the dates of every joint angle andangular velocity; the original surface electromyography signal use the DASYlab8.0surface electromyography analysis software to deal with, the original surfaceelectromyography signal pass through the band pass filter, full-wave rectification,seeking integral electromyography and envelope line.
Result:
The study result of swinging technique muscle force characteristics during thesprint
During the finish of swinging technique movement on the way of sprint, at the frontstage of folding up, the representative of hip flexor muscle such as the tensor fascialata and the rectus femoris are the main force muscle; at the stage of pressing down tothe land, the main force muscle are the gluteus maximus, the unit two long head ofbiceps and the semitendinosus muscle. At the stage of swinging, their orders are: thetensor fascia lata-the rectus femoris-the anterior tibial muscle-gluteus maximus-therear thigh muscles (the unit two long head of biceps, the semitendinosus muscle)-within the lateral head of gastrocnemius muscle-unit four biceps (within the unit,stock, and the rectus femoris). At the primary stage of swinging: The flexors of hipjoint show a strong electromyographic activity, and the tensor fascia lata has thecharacteristic of shrinking prior to the rectus femoris, and the strength of shrinking isbigger than the rectus femoris. After the moment of vertical bracing, the activity ofswinging the rear thigh muscles is obvious, and the time of positive activity is longer.
Optimizing the special forces training methods of swinging technique on the wayof sprint
The action of supporting leg with pulling rubber band is an effective way to trainhip flexor muscle and ankle dorsiflexors, but it easily causes many problems such asthe nervous of thigh and loose folding up of thigh and shank. At the same time,because of the hip knee extensor muscle and the semitendinosus muscle take part inthe activities, whether this activity characteristic affects the coordination between active muscle and antagonistic muscle in the swinging technique of sprint, it is stillneed further study. To compared with the action of supporting leg with pulling rubberband, the time sequence and coordination of hip flexor and extensor during themovement of supining leg with load are better than the coordination of hip muscleflexor extensor during the action of supporting leg pull rubber band, but because theaction speed of supining leg with load is lower than the joint speed of swinging leg, itneeds more attention to control the strength of training in order to improve the qualityof training.
The action forms, action speed and the pattern of electromyographic activity, themain force muscle, the time sequence, the coordination plus the activitycharacteristics of force training during the wheel run with load are the same asswinging technique of sprint. Therefore, the wheel run with load is the main trainingmethod of developing special force of sprint. The action of lying leg curl with pullinga rubber band can develop the muscle force of rear thigh muscles and three leg muscle,but the nature of muscle activity is different from the rear thigh muscles' activity ofswinging technique during sprint, so it can't be the training method of rear thighmuscles' special forces of swinging technique during sprint.
Result: During the special forces training of sprint, it need more attention to thespecial forces training of main force muscle, when it comes to design and choose themethods of trainig the special forces, more consideration should be paid to kineticcharacteristics when the swing leg hip flexors pedal from the last phase to the momentof the other leg's vertical bracing. Choosing the activity construction of thigh'sswinging from back position to front position as accordance; in terms of special forcestraining of double joint, it should explore the training methods which are similar tothe swinging technique of sprint in order that the muscle contraction is closer to therequests of special action.
研究方法:运用美国产MotionPro X-4高速摄像机和德国产Biovision16通道无线肌电遥测仪同步采集我国男子高水平短跑运动员途中跑摆动技术及其部分专项力量训练手段的运动学和表面肌电数据。运动学图像采用德国SIMI motion图像解析系统解析,获得各关节角度、角速度数据;原始肌电信号采用DASYlab8.0肌电分析软件进行处理,原始肌电信号经带通滤波,全波整流,获得积分肌电、包络线等参数.
研究结果:
短跑途中跑摆动技术肌肉用力特征研究结果
在完成短跑途中跑摆动技术动作中,摆动腿各肌肉活动的顺序是:阔筋膜张肌-股直肌-胫骨前肌-臀大肌-股后肌群(股二头肌长头、半腱肌)-腓肠肌内外侧头-股四头肌(股内、股外、股直肌)。折叠前摆阶段,以阔筋膜张肌、股直肌为代表的屈髋肌(髂腰肌)是主要用力肌肉;下压着地阶段,臀大肌、股二头肌长头、半腱肌是主要用力肌肉。在短跑途中跑摆动技术的初期:髋关节屈肌群出现强烈的肌电活动,并且阔筋膜张肌有收缩时间早于股直肌,收缩强度大于股直肌的特点;在(支撑腿)垂直支撑时刻后,摆动腿股后肌群(股二头肌长头、半腱肌)的活动明显,其积极活动的时间较长。短跑途中跑摆动技术部分专项力量训练手段的优化
支撑摆腿拉橡皮带练习能够有效锻炼屈髋肌群以及踝背屈肌,但容易形成大腿紧张,大小腿折叠不紧等问题。同时由于伸髋屈膝肌半腱肌参与了活动,半腱肌的这种活动特点是否会影响短跑摆动技术中主动肌与拮抗肌之间的协调性还需要进一步研究。负重仰卧高抬摆腿练习与支撑摆腿拉橡皮带练习相比,负重仰卧高抬摆腿练习摆动腿髋屈伸肌群的时序性、协调性协优于支撑摆腿拉橡皮带练习中摆动腿髋屈伸肌群的协调性,但由于负重仰卧高抬摆腿的动作速度低于短跑途中跑摆动腿的关节速度,应注意把握训练的强度以提高训练质量。
负重车轮跑练习在力量练习的动作形式,动作速度以及肌电活动的模式、主要用力肌肉、时序性、协调性及其活动特点上,均与短跑摆动技术相一致。因此,负重车轮跑是发展短跑专项力量的重要训练手段。俯卧后屈腿拉橡皮带能够发展股后肌群的肌肉力量,但其肌肉活动的性质与短跑摆动技术中股后肌群活动的性质不同,不能作为短跑摆动技术股后肌群专项力量训练的手段。研究结论:在短跑专项力量训练实践中,要注重主要用力肌肉的专项力量训练,在设计、选择专项力量训练手段时,应充分考虑摆动腿由蹬伸末期至另一腿(支撑腿)垂直支撑时刻屈髋肌群的发力特点,应选择大腿由后伸位向体前摆的动作结构为依据;针对双关节肌的专项力量训练而言,应该多挖掘与短跑摆动技术相类似的训练手段、方法,使肌肉收缩特征更贴近于专项动作要求。
Purpose: This study take the fast strength of swinging technique during the sprint asstudy action, and it uses kinematics and surface electromyography test methods toanalyze the swinging technique characteristics and muscle activity features on theway of high-level sprinters. In addition, it sieve part special forces training methods ofswinging technique during sprint out. and it prefer the special forces training methodswhich are more suit the technical requirements of modern sprint.
Methods: It use the MotionPro X—4high speed camera which made in Americaand Biovision16channel wireless surface electromyographic telemetry instrumentwhich made in Germany to collect the kinematics and surface electromyography datesof swinging technique and part special forces training methods on the way of Chinesehigh-level male sprinter. Kinematics image uses the image analysis system whichmade in Germany to analyse the image, and get the dates of every joint angle andangular velocity; the original surface electromyography signal use the DASYlab8.0surface electromyography analysis software to deal with, the original surfaceelectromyography signal pass through the band pass filter, full-wave rectification,seeking integral electromyography and envelope line.
Result:
The study result of swinging technique muscle force characteristics during thesprint
During the finish of swinging technique movement on the way of sprint, at the frontstage of folding up, the representative of hip flexor muscle such as the tensor fascialata and the rectus femoris are the main force muscle; at the stage of pressing down tothe land, the main force muscle are the gluteus maximus, the unit two long head ofbiceps and the semitendinosus muscle. At the stage of swinging, their orders are: thetensor fascia lata-the rectus femoris-the anterior tibial muscle-gluteus maximus-therear thigh muscles (the unit two long head of biceps, the semitendinosus muscle)-within the lateral head of gastrocnemius muscle-unit four biceps (within the unit,stock, and the rectus femoris). At the primary stage of swinging: The flexors of hipjoint show a strong electromyographic activity, and the tensor fascia lata has thecharacteristic of shrinking prior to the rectus femoris, and the strength of shrinking isbigger than the rectus femoris. After the moment of vertical bracing, the activity ofswinging the rear thigh muscles is obvious, and the time of positive activity is longer.
Optimizing the special forces training methods of swinging technique on the wayof sprint
The action of supporting leg with pulling rubber band is an effective way to trainhip flexor muscle and ankle dorsiflexors, but it easily causes many problems such asthe nervous of thigh and loose folding up of thigh and shank. At the same time,because of the hip knee extensor muscle and the semitendinosus muscle take part inthe activities, whether this activity characteristic affects the coordination between active muscle and antagonistic muscle in the swinging technique of sprint, it is stillneed further study. To compared with the action of supporting leg with pulling rubberband, the time sequence and coordination of hip flexor and extensor during themovement of supining leg with load are better than the coordination of hip muscleflexor extensor during the action of supporting leg pull rubber band, but because theaction speed of supining leg with load is lower than the joint speed of swinging leg, itneeds more attention to control the strength of training in order to improve the qualityof training.
The action forms, action speed and the pattern of electromyographic activity, themain force muscle, the time sequence, the coordination plus the activitycharacteristics of force training during the wheel run with load are the same asswinging technique of sprint. Therefore, the wheel run with load is the main trainingmethod of developing special force of sprint. The action of lying leg curl with pullinga rubber band can develop the muscle force of rear thigh muscles and three leg muscle,but the nature of muscle activity is different from the rear thigh muscles' activity ofswinging technique during sprint, so it can't be the training method of rear thighmuscles' special forces of swinging technique during sprint.
Result: During the special forces training of sprint, it need more attention to thespecial forces training of main force muscle, when it comes to design and choose themethods of trainig the special forces, more consideration should be paid to kineticcharacteristics when the swing leg hip flexors pedal from the last phase to the momentof the other leg's vertical bracing. Choosing the activity construction of thigh'sswinging from back position to front position as accordance; in terms of special forcestraining of double joint, it should explore the training methods which are similar tothe swinging technique of sprint in order that the muscle contraction is closer to therequests of special action.
引文
1文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:339
2王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
3吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
4陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:113
5章国峰.短跑运动员途中跑与部分力量练习手段的下肢肌电特征对比分析[D].北京体育大学硕士学位论文2009:3
6孙俊涛,张萍.少年男子百米运动员速度力量训练手段的优选实验研究[J].竞技.论坛,2010,18(4):40-42
1文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:27
1王志强,吴飞等。对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
2林守任.对我国优秀短跑运动员支撑与摆动动作特征的研究[J].广州体育学院学报.1990(3)
3Ralph mann.A kinetic analysis of sprinting.Medicine and science in sports and exercise[J].1981(5):325-328
徐茂典,吴雪山.短跑途中跑支撑阶段摆动腿某些运动学特征研究[J].北京体育大学学报.2003(1):123
2王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
3转引:王志强.短跑途中跑支撑摆动技术生物力学机制研究[D].上海体育学院博士学位论文,2004:9
1廖爱萍.对中外100m优秀运动员途中跑技术的分析[J].广州体育学院学报,2003,23(2):45.
1曲峰,运动员表面肌电信号与分形.[M].北京:北京体育大学出版社,2008(8):2
2华立君,宋吉锐.排球运动员下肢肌力与肌电特征的相关研究[J].沈阳体育学院学报,2007(8):71
1钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:58
1Klaus Wiemann and Günter Tidow. Relative activity of hip and knee extensors in
sprinting-implications for training[J].Athletics.1995,(3):9
2钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:61
1钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:43
1博姆帕.运动训练理论与方法[M].马铁,译.北京:人民体育出版社,1990:339-330.
2(苏)霍缅科夫.田径教练员教科书[M].赵春方,译.北京:人民体育出版社,1981:41.
3王保成.对短跑技术和专项力量概念的再认识[J].田径,1995(3):15-16.
1Peter Konrad.The ABC of EMG[M].United State,2005:31-33
1文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:27
1曲峰.运动员表面肌电信号与分形[M].北京:北京体育大学出版社,2008:2-5
1Winter DA. Biomechanics and Motor Control of Human Movement,4nd edn.[M]. New York: JohnWiley,2009.
1林江.现代短跑途中跑技术特点分析[J].呼伦贝尔学院学报2008,16(2):114-116
2宫本装.通过下肢肌电观察对短跑途中跑技术和专门力量训练中一些问题的探讨[J].田径,1985,15(2):52-55
2魏书涛,刘宇,钟运健等.短跑支撑期股后肌损伤的动力学分析[J].中国运动医学杂志,2009,28(6):639-643
3钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:56
4章国峰.短跑运动员途中跑与部分力量练习手段的下肢肌电特征对比分析[D].北京:北京体育大学,2009:18-24
5王志强.短跑途中跑支撑摆动技术生物力学机制研究[D].上海体育学院博士学位论文,2004:43
6施宝兴.短跑途中跑运动员支撑腿关节肌肉生物力学特性的研究[D].上海:上海体育学院,2003:42-44
7宫本庄.通过下肢肌电观察对短跑途中跑技术和专门力量训练中一些问题的探讨[J].田径,1985,15(2):52-55.
1魏书涛.短跑过程中下肢动作控制和股后肌损伤机制的环节互动动力学研究[D].上海:上海体育学
院,2011:40-42
2钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:61
3吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
4王延鹏.试用肌电图分析短跑起跑技术肌肉用力特点[J].西安体育学院学报,1995,3(9):85
1孙有平,隋新梅等.基于sEMG的男子旋转推铅球运动员单支撑阶段肌肉用力特征研究[J].体育科学,2010,30(1):48-49
1陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:113
2吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:67-68
3王利斌.对少年短跑运动员快速力量训练手段的研究[D].北京:北京体育大学2005:12
4陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:121
1陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008:91
2陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008:67
3王保成,李鸿江.我国田径运动专项力量训练的现状与分析[J].北京体育师范学院学报,1995,12(2):53-55.
4苏东.短跑力量训练科学化探究[J].北京电力高等专科学校学报,2010(4):152-153.
1陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008:104-108
2李智.对部分男子跳远运动员的部分专项力量训练手段的研究[D].北京:北京体育大学2005:26
1李智.对部分男子跳远运动员的部分专项力量训练手段的研究[D].北京:北京体育大学2005:6
1张洋.对短跑向前摆腿专门力量训练手段的研究[J].技术与改进2005,10(2):8-10
2卢春艳,翟雪峰.通过下肢肌电活动的对比探讨极限强度下摆腿力量训练的方法[J]2001,2(2):83-84
1田亚鸿,李亚君.短跑技术研究新成果及给我们的启示[J].科技信息,2010,33:590
[1]文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:339
[2]王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
[3]吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
[4]陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:113
[5]章国峰.短跑运动员途中跑与部分力量练习手段的下肢肌电特征对比分析[D].北京体育大学硕士学位论文2009:3
[6]文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:27
[7]董广新.对短跑途中跑技术动作周期划分的再认识[J].广州体育学院学报.2000(31):102
[8]王志强,吴飞等。对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
[9]林守任.对我国优秀短跑运动员支撑与摆动动作特征的研究[J].广州体育学院学报.1990(3)
[10] Ralph mann.A kinetic analysis of sprinting.Medicine and science in sportsand exercise[J].1981(5):325-328
[11]徐茂典,吴雪山.短跑途中跑支撑阶段摆动腿某些运动学特征研究[J].北京体育大学学报.2003(1):123
[12]谭泽芹.对短跑途中跑“送髋”技术教学训练效果的探索[J].成都体育学院学报.2009(5):72
[13]王志强.短跑途中跑支撑摆动技术生物力学机制研究对短跑新技术理论的综述与分析[J].武汉体育学院学报,1997(3)
[14]王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
[15]王健.短跑摆动技术分析与力量训练[J].咸宁学院学报.2005(6):117
[16]转引:王志强.短跑途中跑支撑摆动技术生物力学机制研究[D].上海体育学院博士学位论文,2004:9
[17]Josephp.Hunter.Relation Ships Between Ground Reacting Force Impulse andKinematics of Sprint—Running Acceleration[J].JOURNAL OFBIOMECHANICS,2005(21):31-43.
[18]廖爱萍.对中外100m优秀运动员途中跑技术的分析[J].广州体育学院学报,2003,23(2):45.
[19]施宝兴.短跑途中跑运动员支撑腿关节肌肉生物力学特性的研究[D].上海体育学院博士学位论文,2003
[20]钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010
[21]曲峰,运动员表面肌电信号与分形.[M].北京:北京体育大学出版社,2008(8):2
[22]华立君,宋吉锐.排球运动员下肢肌力与肌电特征的相关研究[J].沈阳体育学院学报,2007(8):71
[23]钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:58
[24]Klaus Wiemann and Günter Tidow. Relative activity of hip and knee extensors insprinting-implications for training[J].Athletics.1995,(3):9
[25]钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:43
[26]博姆帕.运动训练理论与方法[M].马铁,译.北京:人民体育出版社,1990:339-330.
[27](苏)霍缅科夫.田径教练员教科书[M].赵春方,译.北京:人民体育出版社,1981:41.
[28]王保成.对短跑技术和专项力量概念的再认识[J].田径,1995(3):15-16.
[29]吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
[30]国家体育总局.中国体育教练员岗位培训教材田径[M].北京:人民体育出版社,1998:243-250
[31]王保成,杨汉雄.竞技体育力量训练指导[M].北京:人民体育出版社,2001
[32]陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008
[33]陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005
[34]王保成,王川.田径运动理论创新探索[M].北京:北京体育大学出版社,2003
[35]卢德明.运动生物力学测量方法[M].北京:北京体育大学出版社,2001
[36]李建设.运动生物力学测量方法[M].北京:北京体育大学出版社,2006
[37]李世明.运动生物力学理论与方法[M].北京:科学出版社,2001
[38]曲峰.运动员表面肌电信号与分形[M].北京:北京体育大学出版社,2008
[39]王清.我国优秀运动员竞技能力状态诊断和检测系统的研究和建立[M].北京:人民体育出版社,2004
[40]王卫星,蔡有志.体能——力量训练指南[M].北京:北京体育大学出版社,2006
[41]茅鹏.运动训练新思路[M].北京:人民体育出版社,1994
[42]马祥海.根据肌肉工作特点对中学生短跑运动员进行力量训练的研究[D].山东师范大学硕士学位论文,2003
[43]黄达武.塑胶跑道对短跑途中跑及其部分专项力量训练手段技术的影响研究[D].武汉体育学院硕士学位论文2006
[44]钟运健.快速跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文2010
[45]场地自行车男子短距离项目专项力量的特征和训练研究[D].上海体育学院博士学位论文
[46]林世行.我国部分优秀女子沙滩排球运动员起跳环节肌电与运动学同步研究分析[D].上海体育学院硕士学位论文2005
[47]范年春.跳深弹性能利用与下肢表面肌电特征研究[D].上海体育学院硕士学位论文2007
[48]刘海瑞.上海市优秀男子拳击运动员后手直拳出拳-击打环节生物力学特征分析[D].上海体育学院硕士学位论文2010
[49]杨文明.背越式跳高起跳技术环节肌肉用力特点研究[D].上海体育学院硕士学位论文2010
[50]王志强.短跑途中跑支撑摆动机制生物力学研究[D].上海体育学院博士学位论文,2004
[51]陈小平.跳水运动员力量训练研究———以清华大学跳水队多年力量训练为例[J].体育科学.2007(8):37-44页
[52]冯树勇,等.田径科技动态[J].国家体育总局科学研究所,2004:(7-8)3-39
[53]王志强,钟大鹏,肖建国.不同水平短跑运动员途中跑支撑反作用力研究[J].武汉体育学院学报.2005(3):42-45
[54]徐茂典,吴雪萍.短跑途中跑支撑阶段摆动腿某些运动学特征研究[J].北京体育大学学报.2003(1):123
[55]伊藤章,孙玉禄.世界一流短跑运动员的疾跑技术[J].].田径科技信息[J].1994,12(5):18-23.
[56]孙为民,孙守正.改进100m途中跑着地技术的实验研究[J].首都体育学院学报,2002,(3):48-51.
[57]王保成,对短跑技术和专项力量的再认识[J].田径1995:314
[58]王延鹏,试用肌电图分析短跑起跑技术肌肉用力特点[J].西安体育学院学报1995(12):384一385
[59]王川等,短跑运动员专项力量练习的设计与选择[J].中国体育科技1999(35):107--8
[60]宫本庄.通过下肢肌电观察对短跑途中跑技术和专门力量训练中一些问题的探讨[J].田径,1985(2):55.
[61]井兰香,刘宇,田石榴.不同负重超等长练习下肢各关节作用分析[J],体育科学,2009,29(5):50-53.
[63]黄达武.软性塑胶跑道对短跑途中跑及其部分专项力量训练手段技术的影响研究[D],武汉体育学院硕士毕业论文,2006.
[64]魏书涛,刘宇,钟运健等.短跑支撑期股后肌损伤的动力学分析[J],中国运动医学杂志,2009,28(6):639-643.
[65]张原.400m跑下肢肌电活动规律探讨[J].武汉体育学院学报.2008,42(6):84-87
[66]Challis JH, Kerwin, DG. An analytical examination of muscle force estimations usingoptimization techniques. Proceedings of the Institution of Mechanical Engineers[J]. Part HJournal of Engineering Medicine,1993,207:139-148.
[67]Chumanov ES, Heiderscheit BC, Thelen DG. The effect of speed and influence of individualmuscles on hamstring mechanics during the swing phase of sprinting[J]. JBiomech,.2007,40(16):3555-62.
[68]Gregor RJ, Abelew TA. Tendon force measurements and movement control: a review[J].Medicine and Science in Sports and Exercise,1994,26:1359-1372.
[69]Mann R. Methods of sprint training from a biomechanical point of view[J]. New Studies inAthletics,1998,13(1)89-90.
[70]Marnix G.J. Gazendam a, At L. Hof. Averaged EMG profiles in jogging and running atdifferent speeds[J]. Gait&Posture,2007,(25):604-614
[71]Mero A, Komi PV. Electromyographic activity in sprinting at speeds ranging fromsub-maximal to supra-maximal[M]. Med Sci Sports Exerc,1987:19:26C274.
[72]Mero A, Komi P, Gregor R. Biomechanics of Sprint Running: A Review[J]. Sports Medicine,1992,13(6):376-392.
[73]Nussbaum MA, Chaffin DB, Martin BJ. A back-propagation neural network model of lumbarmuscle recruitment during moderate static exertions[J]. Journal of Biomechanics,1995,28:1015-1024.
[74]Pandy MG. An analytical framework for quantifying muscular action during human movement.In: Winters, J.M., Woo, S.L.-Y.(Eds.), Multiple Muscle Systems: Biomechanics andMovement Organization[C]. Springer-Verlag, New York.1990:653-662.
[75]Prilutsky BI, Zatsiorsky VM. Optimization-based models of muscle coordination[J]. Exerciseand Sport Sciences Reviews,2002,30:32-38.
[76]Thelen DG, Chumanov ES, Hoerth DM, Best TM, Swanson SC, Li L, Young M, HeiderscheitBC. Hamstring muscle kinematics during treatmill sprinting[J]. Med Sci Sports Exerc,2005a,37(1):108-14.
[77]Thelen DG, Chunmanov ES, Best TM, Swanson SC, Heiderscheit BC. Simulation of BicepsFemoris Musculotendon Mechanics during the Swing Phase of Sprinting[J]. Med. Sci. SportsExerc,2005b,37:1931-1938.
[78]Winter DA. Biomechanics and Motor Control of Human Movement,4nd edn[M]. New York:John Wiley,2009.
[79]潘慧炬.肌肉力学特性研究进展及其若干问题[J].体育科学.2003(5):129-133
[80]郭庆芳,严庆龄.用多道遥测肌电仪测定田径运动员的肌肉活动[J].体育科学.1985(2):67-69
[81]王健.SEMG信号分析及其应用研究进展[J].体育科学.2000(8):26-28.
[82]卢德明,王云德等.摄影测力遥测肌电的同步测试与分析[J].体育科学.1985(2)
[83]骆建.短跑途中跑着地缓冲技术的生物学特点及作用[J].成都体育学院学报,2000(2)
[84]袁运平.我国高水平男子短跑运动员体能训练理论体系研究[D].北京体育大学博士论文,2002
[85]袁庆成等.对短跑途中跑三维支撑反作用力的实测[J].体育科学.1985(1)
[86]金磊,刘宇等.短跑运动中下肢环节间互动动力学分析[J].Journal of MedicalBiomechanics.2008(3):193-201
[87]孙有平等.基于sEMG的男子旋转推铅球运动员单支撑阶段肌肉用力特征研究[J].体育科学.2010(1):44-49
[88]周家颖等.跳深着地前下肢所测肌肉的表面肌电活动特征研究[J].西安体育学院学报.2008(11):68-72
[89]魏书涛,刘宇等.短跑支撑期股后肌损伤的动力学分析[J].中国运动医学杂志.2009(6):639-643
[90]刘宁宁,章国峰.通过肌电测试对短跑运动员途中跑摆动腿肌肉工作特征的研究[J].运动.2010(8):27-28
[91]朱春.托不同重物跑对短跑途中跑技术和专项力量的影响研究[D].武汉体育学院硕士学位论文.2008
[92]罗炯,金季春.表面肌电的处理方法及在体育科研中的应用前景[J].山东体育学院学报.2005(4):56-59
[93]张贻琪等.肌电、测力、录像同步测试正足背推击踢球技术研究[J].天津体育学院学报.1999(6):50-53
[94] Ryan E.Ross,Nicholas A.Ratamess.The effect of treadmill sprint training and resistancetraining on maximal running velocity and power[J].Journal of Strength and conditioningResearch.2009(2):385-394
[95]Transfeldt E, Robertson D, Bradford D. Ligaments of the lumbosacral spine and their role inpossible extraforaminal spinal nerve entrapment and tethering[J]. J SpinalDisord,1993,6:507-512.
[96]Tsirakos D, Baltzopoulos V, Bartlett R. Inverse optimization: functional and physiologicalconsiderations related to the force-sharing problem[J]. Critical Reviews in BiomedicalEngineering,1997,25:371-407.
[97]Uno Y, Kawato M, Suzuki R. Formation and control of optimal trajectory in human multijointarm movement.Minimum torque-change model[J]. Biological Cybernetics,1989,61:89-101.
[98]van der Helm FCT. A finite element musculoskeletal model of the shoulder mechanism[J].Journal of Biomechanics,1994,27:551-569.
[99]Van Don B. J. Hamstring injuries in sprinting. Ph.D. Dissertation[C]. The University of Iowa,Exercise Science, Iowa City,1998.
[100]Vardaxis V, Hoshizaki TB. Power patterns of the leg during the recovery phase of thesprinting stride for advanced and intermediate sprinters[J]. Int J Sport Biomech,1989,5:33-49.
[101]Vaughan CL, Hay JG, Andrews JG. Closed loop problems in biomechanics:2. Anoptimization approach[J]. Journal of Biomechanics,1982,15:201-210.
[102]Walmsley B, Hodgson JA, Burke RE. Forces produced by medial gastrocnemius and soleusduring locomotion in freely moving cats[J]. Neurophysiology,1978,41:1203-1215.
[177]Weimann K and Tidow G. Relative activity of the hip and knee extensors in sprInting-implications for training[J]. New Studies in Athletics,1995,10(1):29-49.
[103]Weber W, Weber E. Mechanik der menschlichen Gehwerkzeuge [Mechanics of humanlocomotion apparatus][M]. Fisher-Verlag, Gottingen,1936.
[104]Whittlesey SN&Hamill J. An alternative model of the lower extremity during locomotion[J].Journal of Applied Biomechanics,1996,12:269-279.
[105]Winters JM. Study movement selection and synergies via a synthesized neurooptimizationframework[C]. In: Winters, J.M., Crago, P.E.(Eds.), Biomechanics and neural control ofposture and movement. Springer-Verlag, New York,2000:458-474.
[106]Winter DA. Biomechanics and Motor Control of Human Movement,4nd edn[M]. New York:John Wiley,2009.
[107]Woods C, Hawkins RD, Maltby S, et al. The Football Association Medical ResearchProgramme: an audit of injuries in professional football--analysis of hamstring injuries[J]. BrJ Sports Med,2004,38(1):36-41.
[108]Wood G. Biomechanical limitations to sprint running[J]. Medicine and Sports Sciences.1987,25:58-71.
[109]Worrell TW. Factors associated with hamstring injuries. An approach to treatment andpreventative measures[J]. Sports Med,1994,17(5):338-345.
[110]Yamamoto T. Relationship between hamstring strains and leg muscle strength. A follow-upstudy of collegiate track and field athletes[J]. J Sports Med Phys Fitness,1993,33(2):194-199.
[111] STIEF F, KLEINDIENST F I, WIEMEYER J, et al. Inverse dynamic analysis of the lowerextremities during nordic walking, walking, and running [J]. J Appl Biomech,2008,24(4):351-9.
[112] THELEN D G, CHUMANOV E S, BEST T M, et al. Simulation of biceps femorismusculotendon mechanics during the swing phase of sprinting [J]. Med Sci Sports Exerc,2005,37(11):1931-8.
[113] RICARD M D, UGRINOWITSCH C, PARCELL A C, et al. Effects of rate of forcedevelopment on EMG amplitude and frequency [J]. International Journal of SportsMedicine,2005,26(1):66-70.
[114] MCCARTHY PERSSON U, FLEMING H F, CAULFIELD B. The effect of a vastuslateralistape on muscle activity during stair climbing [J]. Man Ther,2009,14(3):330-7.
[115]HAMNER S R, SETH A, DELP S L. Muscle contributions to propulsion and support duringrunning [J]. J Biomech,2010,43(14):2709-16.
[116] BONNEFOY A, DORIOT N, SENK M, et al. A non-invasive protocol to determine thepersonalized moment arms of knee and ankle muscles [J]. J Biomech,2007,40(8):1776-85.
2王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
3吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
4陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:113
5章国峰.短跑运动员途中跑与部分力量练习手段的下肢肌电特征对比分析[D].北京体育大学硕士学位论文2009:3
6孙俊涛,张萍.少年男子百米运动员速度力量训练手段的优选实验研究[J].竞技.论坛,2010,18(4):40-42
1文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:27
1王志强,吴飞等。对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
2林守任.对我国优秀短跑运动员支撑与摆动动作特征的研究[J].广州体育学院学报.1990(3)
3Ralph mann.A kinetic analysis of sprinting.Medicine and science in sports and exercise[J].1981(5):325-328
徐茂典,吴雪山.短跑途中跑支撑阶段摆动腿某些运动学特征研究[J].北京体育大学学报.2003(1):123
2王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
3转引:王志强.短跑途中跑支撑摆动技术生物力学机制研究[D].上海体育学院博士学位论文,2004:9
1廖爱萍.对中外100m优秀运动员途中跑技术的分析[J].广州体育学院学报,2003,23(2):45.
1曲峰,运动员表面肌电信号与分形.[M].北京:北京体育大学出版社,2008(8):2
2华立君,宋吉锐.排球运动员下肢肌力与肌电特征的相关研究[J].沈阳体育学院学报,2007(8):71
1钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:58
1Klaus Wiemann and Günter Tidow. Relative activity of hip and knee extensors in
sprinting-implications for training[J].Athletics.1995,(3):9
2钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:61
1钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:43
1博姆帕.运动训练理论与方法[M].马铁,译.北京:人民体育出版社,1990:339-330.
2(苏)霍缅科夫.田径教练员教科书[M].赵春方,译.北京:人民体育出版社,1981:41.
3王保成.对短跑技术和专项力量概念的再认识[J].田径,1995(3):15-16.
1Peter Konrad.The ABC of EMG[M].United State,2005:31-33
1文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:27
1曲峰.运动员表面肌电信号与分形[M].北京:北京体育大学出版社,2008:2-5
1Winter DA. Biomechanics and Motor Control of Human Movement,4nd edn.[M]. New York: JohnWiley,2009.
1林江.现代短跑途中跑技术特点分析[J].呼伦贝尔学院学报2008,16(2):114-116
2宫本装.通过下肢肌电观察对短跑途中跑技术和专门力量训练中一些问题的探讨[J].田径,1985,15(2):52-55
2魏书涛,刘宇,钟运健等.短跑支撑期股后肌损伤的动力学分析[J].中国运动医学杂志,2009,28(6):639-643
3钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:56
4章国峰.短跑运动员途中跑与部分力量练习手段的下肢肌电特征对比分析[D].北京:北京体育大学,2009:18-24
5王志强.短跑途中跑支撑摆动技术生物力学机制研究[D].上海体育学院博士学位论文,2004:43
6施宝兴.短跑途中跑运动员支撑腿关节肌肉生物力学特性的研究[D].上海:上海体育学院,2003:42-44
7宫本庄.通过下肢肌电观察对短跑途中跑技术和专门力量训练中一些问题的探讨[J].田径,1985,15(2):52-55.
1魏书涛.短跑过程中下肢动作控制和股后肌损伤机制的环节互动动力学研究[D].上海:上海体育学
院,2011:40-42
2钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:61
3吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
4王延鹏.试用肌电图分析短跑起跑技术肌肉用力特点[J].西安体育学院学报,1995,3(9):85
1孙有平,隋新梅等.基于sEMG的男子旋转推铅球运动员单支撑阶段肌肉用力特征研究[J].体育科学,2010,30(1):48-49
1陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:113
2吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:67-68
3王利斌.对少年短跑运动员快速力量训练手段的研究[D].北京:北京体育大学2005:12
4陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:121
1陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008:91
2陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008:67
3王保成,李鸿江.我国田径运动专项力量训练的现状与分析[J].北京体育师范学院学报,1995,12(2):53-55.
4苏东.短跑力量训练科学化探究[J].北京电力高等专科学校学报,2010(4):152-153.
1陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008:104-108
2李智.对部分男子跳远运动员的部分专项力量训练手段的研究[D].北京:北京体育大学2005:26
1李智.对部分男子跳远运动员的部分专项力量训练手段的研究[D].北京:北京体育大学2005:6
1张洋.对短跑向前摆腿专门力量训练手段的研究[J].技术与改进2005,10(2):8-10
2卢春艳,翟雪峰.通过下肢肌电活动的对比探讨极限强度下摆腿力量训练的方法[J]2001,2(2):83-84
1田亚鸿,李亚君.短跑技术研究新成果及给我们的启示[J].科技信息,2010,33:590
[1]文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:339
[2]王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
[3]吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
[4]陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005:113
[5]章国峰.短跑运动员途中跑与部分力量练习手段的下肢肌电特征对比分析[D].北京体育大学硕士学位论文2009:3
[6]文超,等.田径运动高级教程(修订版)[M].北京:人民体育出版社,2003:27
[7]董广新.对短跑途中跑技术动作周期划分的再认识[J].广州体育学院学报.2000(31):102
[8]王志强,吴飞等。对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
[9]林守任.对我国优秀短跑运动员支撑与摆动动作特征的研究[J].广州体育学院学报.1990(3)
[10] Ralph mann.A kinetic analysis of sprinting.Medicine and science in sportsand exercise[J].1981(5):325-328
[11]徐茂典,吴雪山.短跑途中跑支撑阶段摆动腿某些运动学特征研究[J].北京体育大学学报.2003(1):123
[12]谭泽芹.对短跑途中跑“送髋”技术教学训练效果的探索[J].成都体育学院学报.2009(5):72
[13]王志强.短跑途中跑支撑摆动技术生物力学机制研究对短跑新技术理论的综述与分析[J].武汉体育学院学报,1997(3)
[14]王志强.对短跑途中跑支撑摆动技术机制研究[J].北京体育大学学报.2003(1):128
[15]王健.短跑摆动技术分析与力量训练[J].咸宁学院学报.2005(6):117
[16]转引:王志强.短跑途中跑支撑摆动技术生物力学机制研究[D].上海体育学院博士学位论文,2004:9
[17]Josephp.Hunter.Relation Ships Between Ground Reacting Force Impulse andKinematics of Sprint—Running Acceleration[J].JOURNAL OFBIOMECHANICS,2005(21):31-43.
[18]廖爱萍.对中外100m优秀运动员途中跑技术的分析[J].广州体育学院学报,2003,23(2):45.
[19]施宝兴.短跑途中跑运动员支撑腿关节肌肉生物力学特性的研究[D].上海体育学院博士学位论文,2003
[20]钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010
[21]曲峰,运动员表面肌电信号与分形.[M].北京:北京体育大学出版社,2008(8):2
[22]华立君,宋吉锐.排球运动员下肢肌力与肌电特征的相关研究[J].沈阳体育学院学报,2007(8):71
[23]钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:58
[24]Klaus Wiemann and Günter Tidow. Relative activity of hip and knee extensors insprinting-implications for training[J].Athletics.1995,(3):9
[25]钟运健.快跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文,2010:43
[26]博姆帕.运动训练理论与方法[M].马铁,译.北京:人民体育出版社,1990:339-330.
[27](苏)霍缅科夫.田径教练员教科书[M].赵春方,译.北京:人民体育出版社,1981:41.
[28]王保成.对短跑技术和专项力量概念的再认识[J].田径,1995(3):15-16.
[29]吕季东.专项力量的测量理论与方法[M].北京:北京体育大学出版社,2007:68
[30]国家体育总局.中国体育教练员岗位培训教材田径[M].北京:人民体育出版社,1998:243-250
[31]王保成,杨汉雄.竞技体育力量训练指导[M].北京:人民体育出版社,2001
[32]陈小平.竞技运动训练实践发展的理论思考[M].北京:北京体育大学出版社,2008
[33]陈小平.当代运动训练热点问题研究[M].北京:北京体育大学出版社,2005
[34]王保成,王川.田径运动理论创新探索[M].北京:北京体育大学出版社,2003
[35]卢德明.运动生物力学测量方法[M].北京:北京体育大学出版社,2001
[36]李建设.运动生物力学测量方法[M].北京:北京体育大学出版社,2006
[37]李世明.运动生物力学理论与方法[M].北京:科学出版社,2001
[38]曲峰.运动员表面肌电信号与分形[M].北京:北京体育大学出版社,2008
[39]王清.我国优秀运动员竞技能力状态诊断和检测系统的研究和建立[M].北京:人民体育出版社,2004
[40]王卫星,蔡有志.体能——力量训练指南[M].北京:北京体育大学出版社,2006
[41]茅鹏.运动训练新思路[M].北京:人民体育出版社,1994
[42]马祥海.根据肌肉工作特点对中学生短跑运动员进行力量训练的研究[D].山东师范大学硕士学位论文,2003
[43]黄达武.塑胶跑道对短跑途中跑及其部分专项力量训练手段技术的影响研究[D].武汉体育学院硕士学位论文2006
[44]钟运健.快速跑时下肢肌肉工作特性及腘绳肌拉伤风险的生物力学研究[D].上海体育学院博士学位论文2010
[45]场地自行车男子短距离项目专项力量的特征和训练研究[D].上海体育学院博士学位论文
[46]林世行.我国部分优秀女子沙滩排球运动员起跳环节肌电与运动学同步研究分析[D].上海体育学院硕士学位论文2005
[47]范年春.跳深弹性能利用与下肢表面肌电特征研究[D].上海体育学院硕士学位论文2007
[48]刘海瑞.上海市优秀男子拳击运动员后手直拳出拳-击打环节生物力学特征分析[D].上海体育学院硕士学位论文2010
[49]杨文明.背越式跳高起跳技术环节肌肉用力特点研究[D].上海体育学院硕士学位论文2010
[50]王志强.短跑途中跑支撑摆动机制生物力学研究[D].上海体育学院博士学位论文,2004
[51]陈小平.跳水运动员力量训练研究———以清华大学跳水队多年力量训练为例[J].体育科学.2007(8):37-44页
[52]冯树勇,等.田径科技动态[J].国家体育总局科学研究所,2004:(7-8)3-39
[53]王志强,钟大鹏,肖建国.不同水平短跑运动员途中跑支撑反作用力研究[J].武汉体育学院学报.2005(3):42-45
[54]徐茂典,吴雪萍.短跑途中跑支撑阶段摆动腿某些运动学特征研究[J].北京体育大学学报.2003(1):123
[55]伊藤章,孙玉禄.世界一流短跑运动员的疾跑技术[J].].田径科技信息[J].1994,12(5):18-23.
[56]孙为民,孙守正.改进100m途中跑着地技术的实验研究[J].首都体育学院学报,2002,(3):48-51.
[57]王保成,对短跑技术和专项力量的再认识[J].田径1995:314
[58]王延鹏,试用肌电图分析短跑起跑技术肌肉用力特点[J].西安体育学院学报1995(12):384一385
[59]王川等,短跑运动员专项力量练习的设计与选择[J].中国体育科技1999(35):107--8
[60]宫本庄.通过下肢肌电观察对短跑途中跑技术和专门力量训练中一些问题的探讨[J].田径,1985(2):55.
[61]井兰香,刘宇,田石榴.不同负重超等长练习下肢各关节作用分析[J],体育科学,2009,29(5):50-53.
[63]黄达武.软性塑胶跑道对短跑途中跑及其部分专项力量训练手段技术的影响研究[D],武汉体育学院硕士毕业论文,2006.
[64]魏书涛,刘宇,钟运健等.短跑支撑期股后肌损伤的动力学分析[J],中国运动医学杂志,2009,28(6):639-643.
[65]张原.400m跑下肢肌电活动规律探讨[J].武汉体育学院学报.2008,42(6):84-87
[66]Challis JH, Kerwin, DG. An analytical examination of muscle force estimations usingoptimization techniques. Proceedings of the Institution of Mechanical Engineers[J]. Part HJournal of Engineering Medicine,1993,207:139-148.
[67]Chumanov ES, Heiderscheit BC, Thelen DG. The effect of speed and influence of individualmuscles on hamstring mechanics during the swing phase of sprinting[J]. JBiomech,.2007,40(16):3555-62.
[68]Gregor RJ, Abelew TA. Tendon force measurements and movement control: a review[J].Medicine and Science in Sports and Exercise,1994,26:1359-1372.
[69]Mann R. Methods of sprint training from a biomechanical point of view[J]. New Studies inAthletics,1998,13(1)89-90.
[70]Marnix G.J. Gazendam a, At L. Hof. Averaged EMG profiles in jogging and running atdifferent speeds[J]. Gait&Posture,2007,(25):604-614
[71]Mero A, Komi PV. Electromyographic activity in sprinting at speeds ranging fromsub-maximal to supra-maximal[M]. Med Sci Sports Exerc,1987:19:26C274.
[72]Mero A, Komi P, Gregor R. Biomechanics of Sprint Running: A Review[J]. Sports Medicine,1992,13(6):376-392.
[73]Nussbaum MA, Chaffin DB, Martin BJ. A back-propagation neural network model of lumbarmuscle recruitment during moderate static exertions[J]. Journal of Biomechanics,1995,28:1015-1024.
[74]Pandy MG. An analytical framework for quantifying muscular action during human movement.In: Winters, J.M., Woo, S.L.-Y.(Eds.), Multiple Muscle Systems: Biomechanics andMovement Organization[C]. Springer-Verlag, New York.1990:653-662.
[75]Prilutsky BI, Zatsiorsky VM. Optimization-based models of muscle coordination[J]. Exerciseand Sport Sciences Reviews,2002,30:32-38.
[76]Thelen DG, Chumanov ES, Hoerth DM, Best TM, Swanson SC, Li L, Young M, HeiderscheitBC. Hamstring muscle kinematics during treatmill sprinting[J]. Med Sci Sports Exerc,2005a,37(1):108-14.
[77]Thelen DG, Chunmanov ES, Best TM, Swanson SC, Heiderscheit BC. Simulation of BicepsFemoris Musculotendon Mechanics during the Swing Phase of Sprinting[J]. Med. Sci. SportsExerc,2005b,37:1931-1938.
[78]Winter DA. Biomechanics and Motor Control of Human Movement,4nd edn[M]. New York:John Wiley,2009.
[79]潘慧炬.肌肉力学特性研究进展及其若干问题[J].体育科学.2003(5):129-133
[80]郭庆芳,严庆龄.用多道遥测肌电仪测定田径运动员的肌肉活动[J].体育科学.1985(2):67-69
[81]王健.SEMG信号分析及其应用研究进展[J].体育科学.2000(8):26-28.
[82]卢德明,王云德等.摄影测力遥测肌电的同步测试与分析[J].体育科学.1985(2)
[83]骆建.短跑途中跑着地缓冲技术的生物学特点及作用[J].成都体育学院学报,2000(2)
[84]袁运平.我国高水平男子短跑运动员体能训练理论体系研究[D].北京体育大学博士论文,2002
[85]袁庆成等.对短跑途中跑三维支撑反作用力的实测[J].体育科学.1985(1)
[86]金磊,刘宇等.短跑运动中下肢环节间互动动力学分析[J].Journal of MedicalBiomechanics.2008(3):193-201
[87]孙有平等.基于sEMG的男子旋转推铅球运动员单支撑阶段肌肉用力特征研究[J].体育科学.2010(1):44-49
[88]周家颖等.跳深着地前下肢所测肌肉的表面肌电活动特征研究[J].西安体育学院学报.2008(11):68-72
[89]魏书涛,刘宇等.短跑支撑期股后肌损伤的动力学分析[J].中国运动医学杂志.2009(6):639-643
[90]刘宁宁,章国峰.通过肌电测试对短跑运动员途中跑摆动腿肌肉工作特征的研究[J].运动.2010(8):27-28
[91]朱春.托不同重物跑对短跑途中跑技术和专项力量的影响研究[D].武汉体育学院硕士学位论文.2008
[92]罗炯,金季春.表面肌电的处理方法及在体育科研中的应用前景[J].山东体育学院学报.2005(4):56-59
[93]张贻琪等.肌电、测力、录像同步测试正足背推击踢球技术研究[J].天津体育学院学报.1999(6):50-53
[94] Ryan E.Ross,Nicholas A.Ratamess.The effect of treadmill sprint training and resistancetraining on maximal running velocity and power[J].Journal of Strength and conditioningResearch.2009(2):385-394
[95]Transfeldt E, Robertson D, Bradford D. Ligaments of the lumbosacral spine and their role inpossible extraforaminal spinal nerve entrapment and tethering[J]. J SpinalDisord,1993,6:507-512.
[96]Tsirakos D, Baltzopoulos V, Bartlett R. Inverse optimization: functional and physiologicalconsiderations related to the force-sharing problem[J]. Critical Reviews in BiomedicalEngineering,1997,25:371-407.
[97]Uno Y, Kawato M, Suzuki R. Formation and control of optimal trajectory in human multijointarm movement.Minimum torque-change model[J]. Biological Cybernetics,1989,61:89-101.
[98]van der Helm FCT. A finite element musculoskeletal model of the shoulder mechanism[J].Journal of Biomechanics,1994,27:551-569.
[99]Van Don B. J. Hamstring injuries in sprinting. Ph.D. Dissertation[C]. The University of Iowa,Exercise Science, Iowa City,1998.
[100]Vardaxis V, Hoshizaki TB. Power patterns of the leg during the recovery phase of thesprinting stride for advanced and intermediate sprinters[J]. Int J Sport Biomech,1989,5:33-49.
[101]Vaughan CL, Hay JG, Andrews JG. Closed loop problems in biomechanics:2. Anoptimization approach[J]. Journal of Biomechanics,1982,15:201-210.
[102]Walmsley B, Hodgson JA, Burke RE. Forces produced by medial gastrocnemius and soleusduring locomotion in freely moving cats[J]. Neurophysiology,1978,41:1203-1215.
[177]Weimann K and Tidow G. Relative activity of the hip and knee extensors in sprInting-implications for training[J]. New Studies in Athletics,1995,10(1):29-49.
[103]Weber W, Weber E. Mechanik der menschlichen Gehwerkzeuge [Mechanics of humanlocomotion apparatus][M]. Fisher-Verlag, Gottingen,1936.
[104]Whittlesey SN&Hamill J. An alternative model of the lower extremity during locomotion[J].Journal of Applied Biomechanics,1996,12:269-279.
[105]Winters JM. Study movement selection and synergies via a synthesized neurooptimizationframework[C]. In: Winters, J.M., Crago, P.E.(Eds.), Biomechanics and neural control ofposture and movement. Springer-Verlag, New York,2000:458-474.
[106]Winter DA. Biomechanics and Motor Control of Human Movement,4nd edn[M]. New York:John Wiley,2009.
[107]Woods C, Hawkins RD, Maltby S, et al. The Football Association Medical ResearchProgramme: an audit of injuries in professional football--analysis of hamstring injuries[J]. BrJ Sports Med,2004,38(1):36-41.
[108]Wood G. Biomechanical limitations to sprint running[J]. Medicine and Sports Sciences.1987,25:58-71.
[109]Worrell TW. Factors associated with hamstring injuries. An approach to treatment andpreventative measures[J]. Sports Med,1994,17(5):338-345.
[110]Yamamoto T. Relationship between hamstring strains and leg muscle strength. A follow-upstudy of collegiate track and field athletes[J]. J Sports Med Phys Fitness,1993,33(2):194-199.
[111] STIEF F, KLEINDIENST F I, WIEMEYER J, et al. Inverse dynamic analysis of the lowerextremities during nordic walking, walking, and running [J]. J Appl Biomech,2008,24(4):351-9.
[112] THELEN D G, CHUMANOV E S, BEST T M, et al. Simulation of biceps femorismusculotendon mechanics during the swing phase of sprinting [J]. Med Sci Sports Exerc,2005,37(11):1931-8.
[113] RICARD M D, UGRINOWITSCH C, PARCELL A C, et al. Effects of rate of forcedevelopment on EMG amplitude and frequency [J]. International Journal of SportsMedicine,2005,26(1):66-70.
[114] MCCARTHY PERSSON U, FLEMING H F, CAULFIELD B. The effect of a vastuslateralistape on muscle activity during stair climbing [J]. Man Ther,2009,14(3):330-7.
[115]HAMNER S R, SETH A, DELP S L. Muscle contributions to propulsion and support duringrunning [J]. J Biomech,2010,43(14):2709-16.
[116] BONNEFOY A, DORIOT N, SENK M, et al. A non-invasive protocol to determine thepersonalized moment arms of knee and ankle muscles [J]. J Biomech,2007,40(8):1776-85.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |