簡易檢索 / 詳目顯示

研究生: 宋昀臻
Sung, Yun-Zhen
論文名稱: 利用慣性感測器檢測運動內衣的支撐性
Using inertial measurement unit to measure breast support of sports bra
指導教授: 相子元
Shiang, Tzyy-Yuang
口試委員: 許維君
Hsu, Wei-Chun
沈乾龍
Shen, Chien-Lung
相子元
Shiang, Tzyy-Yuang
口試日期: 2023/01/04
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: 2023
畢業學年度: 111
語文別: 中文
論文頁數: 51
中文關鍵詞: 運動裝備加速度
英文關鍵詞: sport equipment, acceleration
研究方法: 實驗設計法
DOI URL: http://doi.org/10.6345/NTNU202300046
論文種類: 學術論文
相關次數: 點閱:92下載:18
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報
  • 前言: 運動中穿著運動內衣能有效限制胸部位移,減少胸部運動傷害。提升限制胸部位移的能力:支撐性,是為運動內衣設計的主要目標,但一味的將運動內衣朝緊繃、壓迫靠攏並不是最佳解方。另外,過往運動內衣相關文獻多使用3D動態捕捉系統作為主要實驗儀器,但易受制於實驗式環境,慣性感測器(Inertial Measurement Unit, IMU) 近年來已成為許多研究中常使用的實驗儀器,其方便攜帶與傳輸資料,能在不同的環境下進行實驗,使研究環境更貼近實際情況。目的: 本研究參考過去運動內衣相關文獻,設計出自製運動內衣兼具支撐性與舒適度,並驗證IMU與動態捕捉系統有一致的趨勢。方法: 招募12名女性受試者,進行時速6, 8, 10公里跑,各速度收取穩定30秒。採用3D動態捕捉系統與IMU同時檢測自製與市售運動內衣的限制位移能力表現,並於實驗結束後填寫舒適度問卷。方法: 利用胸部相對於軀幹間相對位移變化量,比較不同運動內衣間位移變化量差異,並呈現舒適度量表。另外,檢視動態捕捉系統與慣性感測器相關性,並計算合加速度MAD作為檢測運動內衣支撐性之加速度參數。結果: 三件運動內衣相對位移變化量於垂直軸、前後向無顯著差異,內外側為無襯<市售<有襯;動態捕捉系統與IMU兩系統於垂直軸相關係數r=0.733,成高度相關。合加速度MAD呈現顯著於市售<有襯<無襯。結論: 自製款運動內衣與市售款有相近限制位移能力,且舒適度較佳。慣性感測器可用於觀察胸部整體晃動程度。合加速度MAD可作為未來檢測運動內衣吸收衝擊力之參數。

    Wearing sports bra during exercising would reduce breast movement and prevent
    breast injuries. The ability of breast movement reduction is so called breast support, which is the main strain of sports bra design. However overly compress breast to reach the goal of reducing movement may cause hardly breathing or chafing injuries and feeling discomfort. How to design a kind of product with support function and comfort is a question. In addition, motion capture system was frequently used to determine the breast movement in most previous studies. Although it could identify breast displacement precisely, equipment and lab environment are still limited. Accelerometer is an alternative approach to conveniently test these characteristics. Take different study as reference to design a sports bra with support and comfort function. And compare the self-design product with brand product, observing the performance of the self-design product. Also, to assess the correlation between motion capture system and accelerometer of breast movement during different speeds running while wearing sports bra. Resultant MAD of acceleration were calculated for the difference of vibration during dynamic state. Pearson’s correlation coefficients were calculated to establish the relationships among breast displacement and acceleration. Self-design product got less displacement in Medial-Lateral axis and more comfort score. R value of Pearson’s coefficients is 0.733, high correlation. Resultant MAD of acceleration is higher in self-design (no-paded). Self- design products are more comfort and with well function .MAD could be a new factor of detecting the function of absorbing impact from sports bra.

    中文摘要 i 英文摘要 ii 目次 iii 表次 v 圖次 vi 第壹章 緒論 1 第一節 前言 1 第二節 研究背景 2 第三節 研究目的 4 第五節 研究範圍與限制 4 第六節 名詞操作性定義 4 第七節 研究之重要性 5 第貳章 文獻探討 5 第一節 運動內衣的功能與舒適度 5 第二節 運動內衣的設計特徵 7 第三節 運動內衣的檢測方法與參數選擇 10 第四節 文獻探討總結 11 第參章 研究方法 12 第一節 運動內衣設計 12 第二節 實驗參與者 13 第三節 實驗設備 16 第四節 實驗流程 19 第五節 資料處理 23 第六節 統計分析 26 第肆章 結果 27 第一節 位移變化量檢測運動內衣支撐性 27 第二節 兩系統相關性與加速度參數應用 34 第三節 舒適度評量 36 第伍章 討論與結論 40 第一節 運動內衣支撐性與舒適度 40 第二節 慣性感測器與加速度之應用 42 第三節 結論與建議 45 參考文獻 46 附錄一 受試者實驗需知 49 附錄二 受試者同意書 50 附錄三 受試者基本資料表 51

    Aittasalo, M., Vähä-Ypyä, H., Vasankari, T., Husu, P., Jussila, A.-M., & Sievänen, H.
    (2015). Mean amplitude deviation calculated from raw acceleration data: A novel method for classifying the intensity of adolescents’ physical activity irrespective of accelerometer brand. BMC Sports Science, Medicine and Rehabilitation, 7(1), 18.
    Brisbine, B. R., Steele, J. R., Phillips, E. J., & McGhee, D. E. (2019). The Occurrence,
    Causes and Perceived Performance Effects of Breast Injuries in Elite Female Athletes. Journal of Sports Science & Medicine, 18(3), 569.
    Brisbine, B. R., Steele, J. R., Phillips, E. J., & McGhee, D. E. (2020). Breast pain affects the performance of elite female athletes. Journal of Sports Sciences, 38(5), 528–533.
    Bock, Y., Melgar, D., & Crowell, B. W. (2011). Real-time strong-motion broadband
    displacements from collocated GPS and accelerometers. Bulletin of the Seismological Society of America, 101(6), 2904-2925.
    Chen, X., Gho, S. A., Wang, J., & Steele, J. R. (2016). Effect of sports bra type and gait speed on breast discomfort, bra discomfort and perceived breast movement in Chinese women. Ergonomics, 59(1), 130–142.
    Coltman, C. E., McGhee, D. E., & Steele, J. R. (2015). Bra strap orientations and
    designs to minimise bra strap discomfort and pressure during sport and exercise in women with large breasts. Sports Medicine - Open, 1(1), 21.
    Coltman, C. E., Steele, J. R., & McGhee, D. E. (2018). Which Bra Components Contribute to Incorrect Bra Fit in Women Across a Range of Breast Sizes? Clothing and Textiles Research Journal, 36(2), 78–90.
    Crabolu, M., Pani, D., Raffo, L., Conti, M., & Cereatti, A. (2018). Functional estimation of bony segment lengths using magneto-inertial sensing: Application to the humerus. Plos One, 13(9), e0203861.
    Gillette J. (1975) When and where women are injured in sports. Phys. Sportsmed.
    1975; 3(5):61–3.
    Kamalha, E., Zeng, Y., Mwasiagi, J. I., & Kyatuheire, S. (2013). The Comfort Dimension; a Review of Perception in Clothing. Journal of Sensory Studies, 28(6), 423–444.
    Lawson, L., & Lorentzen, D. (1990). Selected Sports Bras: Comparisons of Comfort and Support. Clothing and Textiles Research Journal, 8(4), 55–60.
    Liu, K., Zhang, L., Zhu, C., Zhao, X., Lu, W., Li, M., & Wang, J. (2019). An analysis of influence factors of sports bra comfort evaluation based on different sizes. The Journal of The Textile Institute, 110(12), 1792–1799.
    Lu, M., Qiu, J., Wang, G., & Dai, X. (2016). Mechanical analysis of breast–bra interaction for sports bra design. Materials Today Communications, 6, 28–36.
    McGhee, D. E., & Steele, J. R. (2010). Optimising breast support in female patients
    through correct bra fit. A cross-sectional study. Journal of Science and Medicine in Sport, 13(6), 568–572.
    McGhee, D. E., & Steele, J. R. (2010). Breast Elevation and Compression Decrease Exercise-Induced Breast Discomfort. Medicine & Science in Sports & Exercise, 42(7), 1333–1338.
    McGhee, D. E., & Steele, J. R. (2020). Biomechanics of Breast Support for Active Women. Exercise and Sport Sciences Reviews, 48(3), 99–109.
    McGhee, D. E., Steele, J. R., Zealey, W. J., & Takacs, G. J. (2013). Bra–breast forces generated in women with large breasts while standing and during treadmill running: Implications for sports bra design. Applied Ergonomics, 44(1), 112–118.
    Nolte, K., Burgoyne, S., & Nolte, H. (2016). The effectiveness of a range of sports bras in reducing breast displacement during treadmill running and two-step star jumping.
    Norris, M., Blackmore, T., Horler, B., & Wakefield-Scurr, J. (2021). How the characteristics of sports bras affect their performance. Ergonomics, 64(3), 410–425.
    Risius, D., Milligan, A., Berns, J., Brown, N., & Scurr, J. (2017). Understanding key performance indicators for breast support: An analysis of breast support effects on biomechanical, physiological and subjective measures during running. Journal of Sports Sciences, 35(9), 842–851.
    Scurr, J. C., White, J. L., & Hedger, W. (2010). The effect of breast support on the kinematics of the breast during the running gait cycle. Journal of Sports Sciences, 28(10), 1103–1109.
    Slyper, R., & Hodgins, J. K. (2008). Action Capture with Accelerometers. In Symposium
    on computer animation, 193-199.
    Steven Eyobu, O., & Han, D. (2018). Feature Representation and Data Augmentation for Human Activity Classification Based on Wearable IMU Sensor Data Using a Deep LSTM Neural Network. Sensors, 18(9), 2892.
    Storm, F. A., Buckley, C. J., & Mazzà, C. (2016). Gait event detection in laboratory and real life settings: Accuracy of ankle and waist sensor based methods. Gait & Posture, 50, 42–46.
    Wang, C.-S., Wang, L.-H., Kuo, L.-C., & Su, F.-C. (2017). Comparison of breast motion
    at different levels of support during physical activity. Journal of Human Sport and Exercise, 12(4).
    White, J., Scurr, J., & Hedger, W. (2011). A Comparison of Three-Dimensional Breast
    Displacement and Breast Comfort During Overground and Treadmill Running. Journal of Applied Biomechanics, 27(1), 47–53.
    Xu, S., Wang, J., Gong, H., Yao, X., & Wang, Z. (2021). Female sagging breast dynamic 3D displacement study based on multiple 3-axes accelerometers measuring system. Journal of Engineered Fibers and Fabrics, 16.
    Zhang, S., Yick, K. L., Yip, J., Yu, W., & Tang, K. P. M. (2021). An understanding of bra
    design features to improve bra fit and design for older Chinese women. Textile Research Journal, 91(3-4), 406-420.
    Zhou, J., Yu, W., & Ng, S. (2013). Identifying effective design features of commercial sports bras. Textile Research Journal, 83(14), 1500–1513.
    Zhou, J., Yu, W., & Ng, S.-P. (2012). Studies of three-dimensional trajectories of breast movement for better bra design. Textile Research Journal, 82(3), 242–254.

    下載圖示
    QR CODE