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研究生: 郭京漢
Ching-Han Kuo
論文名稱: 不同頻率全身震動對下肢運動表現之立即性影響
指導教授: 相子元
Shiang, Tzyy-Yuang
學位類別: 碩士
Master
系所名稱: 運動競技學系
Department of Athletic Performance
論文出版年: 2009
畢業學年度: 97
語文別: 中文
論文頁數: 67
中文關鍵詞: 震動頻率垂直跳平衡
英文關鍵詞: vibration, frequency, CMJ3, BT
論文種類: 學術論文
相關次數: 點閱:211下載:11
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  • 目的: 本研究目的是探討兩種不同頻率(肌梭激發頻率與下肢肌肉共震頻率)全身性震動對於下肢運動表現之立即性影響。方法:本研究以15位一般人為受試者,並依照平衡次序法分別做三組刺激(高頻組:頻率32 Hz、震幅1 mm。低頻組:頻率18 Hz、震幅3 mm。控制組:無震動刺激),分別在震動平台上做60 秒,2 秒1 次的蹲踞訓練,每次訓練五組。刺激前後以測力板擷取連續三次垂直跳與單足閉眼站立平衡,同時以Biopac MP 150 擷取股直肌與股二頭肌肌肉活性做事後探討。結果:研究結果發現,連續三次垂直跳第一跳中,高頻組與低頻組跳躍高度前後測達顯著進步(p<.05),且高頻組進步率最高(5.37%),而肌肉電位三組差異率皆呈現下降的趨勢。連續三次垂直跳第二跳中,低頻組在起跳高度進步幅度最高(17.1%),而股直肌活性差異值最低(-15.4%)。在單足閉眼站立平衡項目中高頻組與低頻組在重心位移速度上進步率皆提升(3.8%與1.9%),控制組則為下降(-2.89%),肌肉電位三組皆呈現下降的趨勢。結論:研究結論為震動組對於連續三次垂直跳之第一跳高度有顯著增進,且高頻組較優異,同時對平衡能力也有增加,控制組則無。

    The aim of this study was to explore the immediate effect of whole body vibration with two different frequencies (muscle spindle stimulus frequency and lower-limb muscle
    resonance frequency) on the sport performance of lower limbs.Fifteen subjects were recruited to participate in this study. Subjects were asked to stand on the vibration plate and three types of stimulus frequency were given to the subjects in the order of (1)high frequency vibration (HFV) group: frequency = 18Hz,amplitude = 3mm; (2)low frequency group (LFV): frequency = 32Hz, amplitude = 1mm;
    (3)control group (CON): no vibration stimulus. While receiving stimulus frequencies, subjects were also doing squat-stand movement in a 60-second cycle (2 seconds per
    squat-stand) and each subject performed 5 cycles for each group. AMTI force plate was applied pre and post tests to measure three consecutive counter movement jumps (CMJ3)
    as well as balance tests (BT) of one leg stance with eyes closed. In addition, Biopac MP 150 was used simultaneously to collect EMG activity of rectus femoris and biceps femoris.The results show that for the first jump of CMJ3, except the CON group, both HFV group and LFV group improved significantly in jump height (p<.05) pre and post tests,
    especially HFV group improved as much as 5.37%. On the other hand, all three groups show a decreasing tendency in EMG activity. For the second jump of CMJ3, LFV group improved the most (17.1%), but also show the greatest decrease in the EMG activity As for BT results--the speed of displacement of body’s center of gravity, HFV group and LFV group increased 3.8% and 1.9% respectively while the CON group decreased by -2.89%. All three groups present a tendency to decrease in EMG activity. We conclude that the
    HFV group and LFV group improved significantly in the first jump of CMJ3 (HFV group improved the most) and their balance abilities have also increased while no improvement
    showed in both tests for the CON group.

    第 壹 章 緒 論 第一節 研究背景-------------------------------------- 1 第二節 研究目的-------------------------------------- 5 第三節 研究假設-------------------------------------- 5 第四節 研究範圍及限制--------------------------------- 5 第五節 名詞解釋及操作性定義--------------------------- 6 第 貳 章 文獻探討 第一節 人體對震動刺激之反應機轉------------------------ 9 第二節 震動刺激之立即效果----------------------------- 10 第三節 震動刺激之長期適應----------------------------- 13 第四節 肌肉自然震動頻率 ------------------------------ 15 第五節 小結 ---------------------------------------- 17 第 叁 章 研究方法與步驟 第一節 實驗對象-------------------------------------- 19 第二節 實驗時間與地點--------------------------------- 19 第三節 實驗儀器與設備--------------------------------- 19 第四節 實驗方法與流程--------------------------------- 21 第五節 資料蒐集與處理--------------------------------- 27 第六節 資料分析-------------------------------------- 33 第 肆 章 結果 第一節 連續三次垂直跳結果----------------------------- 34 第二節 單足閉眼站立平衡結果--------------------------- 48 第 伍 章 討論與結論 第一節 不同震動組別對爆發力之影響---------------------- 52 第二節 不同震動組別對平衡控制力之影響------------------- 53 第三節 不同震動組別對肌肉活化程度之影響-------------=--- 55 第四節 結論----------------------------------------- 59 參考文獻 中文部分-------------------------------------------- 61 英文部分-------------------------------------------- 61 附錄一 受試者同意書---------------------------------------- 67 表目錄 表3-1 震動頻率與刺激時間參照表------------------------ 24 表3-2 平衡次序法------------------------------------ 25 表4-1 不同組別下起跳衝量第一跳之前後側比較------------ 34 表4-2 不同組別下起跳衝量第二跳之前後側比較------------ 35 表4-3 不同組別下起跳衝量第二跳之前後側比較------------ 35 表4-4 不同組別下起跳高度第一跳之前後側比較------------ 37 表4-5 不同組別下起跳高度第二跳之前後側比較------------ 37 表4-6 不同組別下起跳高度第三跳之前後側比較------------ 37 表4-7 不同組別下發力率第一跳之前後側比較-------------- 39 表4-8 不同組別下起跳衝量之差異率比較------------------ 40 表4-9 不同組別下起跳高度之差異率比較------------------ 41 表4-10 不同組別下發力率之差異率比較-------------------- 41 表4-11 不同組別下股直肌EMGrms 第一跳之差異率比較------- 44 表4-12 不同組別下股直肌EMGrms 第二跳之差異率比較------- 44 表4-13 不同組別下股直肌EMGrms 第三跳之差異率比較------- 44 表4-14 不同組別下股二頭肌EMGrms 第一跳之差異率比較----- 46 表4-15 不同組別下股二頭肌EMGrms 第二跳之差異率比較----- 46 表4-16 不同組別下股二頭肌EMGrms 第三跳之差異率比較----- 46 表4-17 不同組別下最大前後位移之前後測比較-------------- 48 表4-18 不同組別下最大左右位移之前後測比較-------------- 48 表4-19 不同組別下重心位移速度之前後測比較-------------- 48 表4-20 不同組別下最大前後位移、最大左右位移、重心位移 速度之進步率比較----------------------------- 50 表4-21 股直肌與股二頭肌單足閉眼站立平衡EMGrms 差異率 結果---------------------------------------- 51 表5-2 Bosco( 2000)對大壓腿功率、EMGrms、垂直跳前後測 結果----------------------------------------- 55 圖目錄 圖1-1 下肢震動刺激平台-------------------------------- 6 圖1-2 蹲踞訓練膝關節角度範圍-------------------------- 7 圖2-1 TVR 反射路徑---------------------------------- 10 圖2-2 機械式上肢訓練機器圖--------------------------- 12 圖2-3 人體各部位共振頻率----------------------------- 16 圖3-1 肌電黏貼位置----------------------------------- 23 圖3-2 反光球黏貼位置--------------------------------- 23 圖3-3 測力板座標系統示意圖---------------------------- 27 圖3-4 測力版Fz 值與重心速度圖------------------------- 28 圖3-5 CMJ3 垂直力-時間關係圖------------------------- 29 圖3-6 測力板與膝關節角度原始資料---------------------- 30 圖3-7 BT 之重心位移原始資料-------------------------- 30 圖3-8 連續三次垂直跳下蹲-起跳分期圖------------------- 32 圖3-9 CMJ3 原始訊號由上至下:股直肌(肌電)、股二頭肌 (肌電)、垂直方向力圖---------------------------- 32 圖3-10 BT 原始訊號由上至下:股直肌(肌電)、股二頭肌 (肌電)、trigger------------------------------- 33 圖4-1 不同組別下起跳衝量第一跳之前後側比較------------- 35 圖4-2 不同組別下起跳衝量第二跳之前後側比較------------ 36 圖4-3 不同組別下起跳衝量第三跳之前後側比較------------ 36 圖4-4 不同組別下起跳高度第一跳之前後側比較------------ 37 圖4-5 不同組別下起跳衝量第二跳之前後側比較------------ 38 圖4-6 不同組別下起跳衝量第三跳之前後側比較------------ 38 圖4-7 不同組別下發力率第一跳之前後側比較-------------- 39 圖4-8 不同組別下起跳衝量第一跳之差異率比較------------ 40 圖4-9 不同組別下起跳衝量第二跳之差異率比較------------ 40 圖4-10 不同組別下起跳衝量第三跳之差異率比較------------ 41 圖4-11 不同組別下起跳高度第一跳之差異率比較------------ 42 圖4-12 不同組別下起跳高度第二跳之差異率比較------------ 42 圖4-13 不同組別下起跳高度第三跳之差異率比較------------ 42 圖4-14 不同組別下發力率第一跳之差異率比較-------------- 43 圖4-15 不同組別下股直肌EMGrms 第一跳之差異率比較------- 45 圖4-16 不同組別下股直肌EMGrms 第二跳之差異率比較------- 45 圖4-17 不同組別下股直肌EMGrms 第三跳之差異率比較------- 45 圖4-18 不同組別下股二頭肌EMGrms 第一跳之差異率比較----- 47 圖4-19 不同組別下股二頭肌EMGrms 第二跳之差異率比較----- 47 圖4-20 不同組別下股二頭肌EMGrms 第三跳之差異率--------- 47 圖4-21 不同組別下最大前後位移之前後測比較-------------- 49 圖4-22 不同組別下最大左右位移之前後測比較-------------- 49 圖4-23 不同組別下重心位移速度之前後測比較-------------- 49 圖4-24 不同組別下最大前後位移、最大左右位移、重心位移 速度之進步率比較----------------------------- 50 圖4-25 股直肌、股二頭肌單足閉眼站立平衡EMGrms 差異率 結果---------------------------------------- 51 圖5-1 右腳足踩踏曲線圖------------------------------- 54 圖5-2 Purkayastha(2006)漸增強度等張肌力、等速肌力之 均分肌電振幅圖--------------------------------- 56

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