齐岩松 , 王一帆 , 吴海贺 , 傅冠达 , 包呼日查 , 徐永胜 . 三维步态运动分析技术在经典式越野滑雪项目中的应用[J]. 科技导报, 2022 , 40(2) : 13 -20 . DOI: 10.3981/j.issn.1000-7857.2022.02.002

[1] 敖英芳. 我国运动医学发展与北京冬奥会和健康中国建设[J]. 北京大学学报(医学版), 2021, 53(5):823-827.
[2] 王佳宁, 敖英芳. 冬季奥运会与主要冬季项目运动损伤[J]. 科技导报, 2020, 38(6):11-24.
[3] Hoffman M D, Clifford P S. Physiological aspects of competitive cross-country skiing[J]. Journal of Sports Sciences, 1992, 10(1):3-27.
[4] Holmberg H C. The elite cross-country skier provides unique insights into human exercise physiology[J]. Scandinavian Journal of Medicine & Science in Sports, 2015, 25(4):100-109.
[5] Smith G A. Biomechanics of crosscountry skiing[J]. Sports Medicine (Auckland, NZ), 1990, 9(5):273-285.
[6] 刘卉, 于冰, 张力文, 等. 竞技体育运动生物力学研究现状与趋势[J]. 医用生物力学, 2021, 36(4):491-501.
[7] Pellegrini B, Zoppirolli C, Bortolan L, et al. Gait models and mechanical energy in three cross-country skiing techniques[J]. The Journal of Experimental Biology, 2014, 217(21):3910-3918.
[8] Nilsson J, Tveit P, Eikrehagen O. Effects of speed on temporal patterns in classical style and freestyle cross-country skiing[J]. Sports Biomechanics, 2004, 3(1):85-107.
[9] Smith G A. Biomechanical analysis of cross-country skiing techniques[J]. Medicine and Science in Sports and Exercise, 1992, 24(9):1015-1022.
[10] Bolger C M, Kocbach J, Hegge A M, et al. Speed and heart-rate profiles in skating and classical cross-country skiing competitions[J]. International Journal of Sports Physiology and Performance, 2015, 10(7):873-880.
[11] Holmberg H C, Lindinger S, Stöggl T, et al. Contribution of the legs to double-poling performance in elite crosscountry skiers[J]. Medicine and Science in Sports and Exercise, 2006, 38(10):1853-1860.
[12] FIS. International Ski Competition Rules(ICR)[EB/OL].[2021-09-20]. Available at http://www.fis-ski.com.
[13] Andersson E, Stöggl T, Pellegrini B, et al. Biomechanical analysis of the herringbone technique as employed by elite cross-country skiers[J]. Scandinavian Journal of Medicine & Science in Sports, 2014, 24(3):542-552.
[14] Sandbakk S B, Supej M, Sandbakk Ø, et al. Downhill turn techniques and associated physical characteristics in cross-country skiers[J]. Scandinavian Journal of Medicine & Science in Sports, 2014, 24(4):708-716.
[15] Mognoni P, Rossi G, Gastaldelli F, et al. Heart rate profiles and energy cost of locomotion during cross-country skiing races[J]. European Journal of Applied Physiology, 2001, 85(1-2):62-67.
[16] Sandbakk O, Ettema G, Leirdal S, et al. Analysis of a sprint ski race and associated laboratory determinants of world-class performance[J]. European Journal of Applied Physiology, 2011, 111(6):947-957.
[17] Bolger C M, Kocbach J, Hegge A M, et al. Speed and heart-rate profiles in skating and classical cross-country skiing competitions[J]. International Journal of Sports Physiology and Performance, 2015, 10(7):873-880.
[18] Sandbakk Ø, Losnegard T, Skattebo Ø, et al. Analysis of classical time-trial performance and technique-specific physiological determinants in elite female cross-country skiers[J]. Frontiers in Physiology, 2016(7):326.
[19] 岳友, 吴海贺, 齐岩松, 等. 不同步态分析系统在骨性关节炎中的应用进展[J]. 科技导报, 2021, 39(22):35-42.
[20] Petersen W, Ellermann A, Zantop T, et al. Biomechanical effect of unloader braces for medial osteoarthritis of the knee:A systematic review (CRD 42015026136)[J]. Archives of Orthopaedic and Trauma Surgery, 2016, 136(5):649-656.
[21] Brand A, Klöpfer-Krämer I, Böttger M, et al. Gait characteristics and functional outcomes during early followup are comparable in patients with calcaneal fractures treated by either the sinus tarsi or the extended lateral approach[J]. Gait & Posture, 2019, 70:190-195.
[22] Segal A D, Orendurff M S, Klute G K, et al. Kinematic and kinetic comparisons of transfemoral amputee gait using C-Leg and Mauch SNS prosthetic knees[J]. Journal of Rehabilitation Research and Development, 2006, 43(7):857-870.
[23] Dugan S A, Bhat K P. Biomechanics and analysis of running gait[J]. Physical Medicine and Rehabilitation Clinics of North America, 2005, 16(3):603-621.
[24] Cairns M A, Burdett R G, Pisciotta J C, et al. A biomechanical analysis of racewalking gait[J]. Medicine and Science in Sports and Exercise, 1986, 18(4):446-453.
[25] Lindinger S J, Göpfert C, Stöggl T, et al. Biomechanical pole and leg characteristics during uphill diagonal roller skiing[J]. Sports Biomechanics, 2009, 8(4):318-333.
[26] Björklund G, Stöggl T, Holmberg H C. Biomechanically influenced differences in O₂ extraction in diagonal skiing:Arm versus leg[J]. Medicine and Science in Sports and Exercise, 2010, 42(10):1899-1908.
[27] Andersson E, Pellegrini B, Sandbakk O, et al. The effects of skiing velocity on mechanical aspects of diagonal cross-country skiing[J]. Sports Biomechanics, 2014, 13(3):267-284.
[28] Hall M, Penfold P. One stride ahead. An expert's guide to cross-country skiing[M]. Winchester:Winchester Press, 1981.
[29] Pellegrini B, Zoppirolli C, Stella F, et al. Biomechanical analysis of the "running" vs. "conventional" diagonal stride uphill techniques as performed by elite crosscountry skiers[J]. Journal of Sport and Health Science, 2020, 18:2095-2546.
[30] Lindinger S. Biomechanics in cross-country skiingMethods and future research questions[C]//Linnamo V, Komi P V, Muller E, et al. Science and nordic skiing. Oxford:Meyer & Meyer Sport, 2007:23-43.
[31] Smith G A. Biomechanics of cross country skiing[C]//Rusko H. Cross country skiing:Olympic handbook of sports medicine. Oxford:Blackwell Publishing, 2002:32-61.
[32] Göpfert C, Holmberg H C, Stöggl T, et al. Biomechanical characteristics and speed adaptation during kick double poling on roller skis in elite cross-country skiers[J]. Sports Biomechanics, 2013, 12(2):154-174.
[33] Nilsson J, Tveit P, Eikrehagen O. Effects of speed on temporal patterns in classical style and freestyle crosscountry skiing[J]. Sports Biomechanics, 2004, 3(1):85-107.
[34] Sandbakk Ø, Holmberg H C. A reappraisal of success factors for Olympic cross-country skiing[J]. International Journal of Sports Physiology and Performance, 2014, 9(1):117-121.
[35] Stöggl T, Holmberg H C. Force interaction and 3D pole movement in double poling[J]. Scandinavian Journal of Medicine & Science in Sports, 2011, 21(6):e393-e404.
[36] Stöggl T, Müller E, Lindinger S. Biomechanical comparison of the double-push technique and the conventional skate skiing technique in cross-country sprint skiing[J]. Journal of Sports Sciences, 2008, 26(11):1225-1233.
[37] Stoggl T, Enqvist J, Muller E, et al. Relationships between body composition, body dimensions, and peak speed in cross-country sprint skiing[J]. Journal of Sports Sciences, 2010, 28(2):161-169.
[38] Lindinger S J, Stöggl T, Müller E, et al. Control of speed during the double poling technique performed by elite cross-country skiers[J]. Medicine and Science in Sports and Exercise, 2009, 41(1):210-220.
[39] Weyand P G, Sandell R F, Prime D N, et al. The biological limits to running speed are imposed from the ground up[J]. Journal of Applied Physiology (Bethesda, Md:1985), 2010, 108(4):950-961.
[40] Stöggl T, Müller E, Ainegren M, et al. General strength and kinetics:Fundamental to sprinting faster in cross country skiing?[J] Scandinavian Journal of Medicine & Science in Sports, 2011, 21(6):791-803.
[41] Zoppirolli C, Pellegrini B, Bortolan L, et al. Energetics and biomechanics of double poling in regional and highlevel cross-country skiers[J]. European Journal of Applied Physiology, 2015, 115(5):969-979.
[42] Welde B, Stöggl T L, Mathisen G E, et al. The pacing strategy and technique of male cross-country skiers with different levels of performance during a 15-km classical race[J]. PloS One, 2017, 12(11):e0187111.
[43] Stöggl T, Welde B, Supej M, et al. Impact of incline, sex and level of performance on kinematics during a distance race in classical cross-country skiing[J]. Journal of Sports Science & Medicine, 2018, 17(1):124-133.
[44] Dahl C, Sandbakk Ø, Danielsen J, et al. The Role of power fluctuations in the preference of diagonal vs. double poling sub-technique at different incline-speed combinations in elite cross-country skiers[J]. Frontiers in Physiology, 2017(8):94.
[45] Danielsen J, Sandbakk Ø, McGhie D, et al. The effect of exercise intensity on joint power and dynamics in ergometer double-poling performed by cross-country skiers[J]. Human Movement Science, 2018, 57:83-93.
[46] Danielsen J, Sandbakk Ø, Holmberg H C, et al. Mechanical energy and propulsion in ergometer double poling by cross-country skiers[J]. Medicine and Science in Sports and Exercise, 2015, 47(12):2586-2594.
[47] Zoppirolli C, Pellegrini B, Modena R, et al. Changes in upper and lower body muscle involvement at increasing double poling velocities:An ecological study[J]. Scandinavian Journal of Medicine & Science in Sports, 2017, 27(11):1292-1299.
[48] Hegge A M, Bucher E, Ettema G, et al. Gender differences in power production, energetic capacity and efficiency of elite cross country skiers during whole body, upper body, and arm poling[J]. European Journal of Applied Physiology, 2016, 116(2):291-300.
[49] Stöggl T L, Holmberg H C. Double-poling biomechanics of elite cross-country skiers:Flat versus Uphill Terrain[J]. Medicine and Science in Sports and Exercise, 2016, 48(8):1580-1589.