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A cinematographic analysis of cross country skiing flat diagonal stride techniqueMatthews, Margaret Emma, 1950- January 1977 (has links)
No description available.
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A comparison between fitness and performance in cross-country skiersPeterson, Matthew D. January 1984 (has links)
Thesis (M.S.)--University of Wisconsin--Madison, 1984. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 42-45).
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Metabolic cost comparison of cross country skiing between elite and non-elite skiersHarkins, Kenneth J. January 1978 (has links)
Thesis (M.S.)--Wisconsin. / Includes bibliographical references (leaves 36-37).
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The role of upper body power in classical cross-country skiing performanceAlsobrook, Nathan Gabriel. January 1900 (has links)
Thesis (M.S.)--Montana State University--Bozeman, 2005. / Includes bibliographical references (leaves 44-47). Also available online (PDF file) by a subscription to the set or by purchasing the individual file.
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Kinematic analysis of male olympic cross-country skiers using the open field skating techniqueHeagy, Brian S. 15 September 1992 (has links)
The kinematic characteristics of 17 elite male cross-country skiers competing in the 50 km race of the 1992 Winter Olympic Games were determined. Each skier used the open field skating technique, one of four skating techniques used in free technique cross-country ski races. Skiers were filmed by the use of three video cameras, placed at a filming site on a flat portion of the racing course. Digitized data from the video were used to determine selected kinematic parameters which included: cycle velocity; cycle length; cycle rate; center of mass (CM) velocity vector angle; CM lateral displacement; CM lateral velocity; CM horizontal velocity; ski angles; ski edging angles; several types of pole angles; and hip, knee, and trunk angles. Temporal characteristics including strong side and weak side ski and pole phase times were also calculated.
Cycle velocity and cycle length were found to be significantly related as were cycle velocity and the maximum strong side knee angle (r > .48, p < .05). Cycle velocity and the CM velocity vector angle were found to have only a
moderate non-significant relationship as did cycle velocity and the strong and weak side ski angles. For those skiers using the open field skating technique, CM lateral motion (as measured by the CM velocity vector angle and the ski angles) did not seem to be a distinguishing factor between faster and slower skiers, as hypothesized. However, cycle length and the maximum strong side knee angle did seem to distinguish faster from slower skiers. Skiers who covered more distance throughout a cyde tended to have faster cycle velocities. Contributing to this increased distance could have been the thrust of the strong side ski. Skiers with the most strong side knee extension tended to ski the fastest. Thus, it seems that greater leg extension results in greater propulsive forces and greater velocity. / Graduation date: 1993
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The effect of cold ambient conditions on body temperature regulation during exerciseBrooks, Robert Williams. January 1979 (has links)
Thesis (M.S.)--University of Wisconsin--Madison. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 62-65).
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The role of upper body power in classical cross-country skiing performanceAlsobrook, Nathan Gabriel. January 2005 (has links) (PDF)
Thesis (M.S.)--Montana State University--Bozeman, 2005. / Typescript. Chairperson, Graduate Committee: Daniel P. Heil. Includes bibliographical references (leaves 44-47).
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The role of upper body power in classical cross-country skiing performanceAlsobrook, Nathan Gabriel. January 1900 (has links)
Thesis (M.S.)--Montana State University--Bozeman, 2005. / Includes bibliographical references (leaves 44-47).
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The acute physiological responses of elite cross country skiers to exercise at sea level and moderate altitudeDaley, Phillipa J., n/a January 1999 (has links)
Nine Australian male cross country ski team members (19.8±2.5 years,
(X±SD),76.6±6.4kg, 184.8±4.9cm) completed both an incremental maximal exercise
test and a 45 minute time trial performance test using a dryland ski striding technique
with poles on a treadmill. Testing occurred at 610m in a chamber that was supplied
with either an 02 enriched (p02 = 152mmHg) or an N2 enriched (p02 = 132mmHg) gas
mixture to simulate sea level (SL) or 1800m (A) conditions respectively. A 48 hour rest
interval was provided between tests and the testing conditions were randomised,
counterbalanced and double blind. At maximum effort there were significant
differences in V02 max (70.2±4.0 v 61.7±2.9 ml.kg-1.min-1), PaO2 (97.2±12.7 v
77.1±11.2 mmHg) and SaO2 (90.6±4.9 v 77.8±3.9%); but not in HR (194.1±8.1 v
191.7±7.4 bpm), VE (133.1±12.8 v 132.6±11.3 L.min-1 STPD) or [La] (14.2±2.3 v
13.7±3.3 mM) at SL v A. There was a decrease of 7.6% in overall time trial
performance between the conditions (4005±378 v 3702±301 m, p = 0.08), although
performance was significantly lower at A during the latter period of the test, >25
minutes. During the steady state stage of the time trial performance test, (=75% SL
VO2 max) there were no significant differences between SL and A in any of VO2
(52.9±5.9 v 52.1±4.9 ml.kg-'.min-' at 15 minutes for SL and A respectively); HR
(173.1±12.8 v 176.1+10.1 bpm); or [La] (3.0±1.0 v 4.8±2.2 mM). However, there
was a significant reduction in PaO2 between SL (111.2±25.5 mmHg at 15 minutes) and
A (72.6±24.3 mmHg at 15 minutes), resulting in a significant reduction in SaO2
(96.6±1.1 v 84.6±6.8% at 15 minutes) between the conditions. At the end of each lap
of the variable workload stage of the time trial performance test there were significant
reductions in VO2 (65.3±6.9, 64.2±6.3 and 66.4±5.9 v 54.6±5.6, 56.0±4.6 and
57.9±3.2 ml.kg-'.min-1 at 25, 35 and 45 minutes at SL v A); and HR (190.1 ±9.2,
192.4±8.6 and 195.9±7.6 v 181.8±12.4, 186±8.1 and 189.6±9.2 bpm) under A
conditions. There were no significant differences in [La] at the end of each lap of the
time trial performance test between SL and A, although [La] did increase over time
during the test at both SL and A (6.2±2.0, 8.9±2.8 and 10.6±4.1 v 7.6±2.0, 8.4±2.2
and 9.9± 1.8 mM). At the end of each lap of the time trial performance test, there was a
significant reduction in PaO2 (120.9±24.4, 108.8±25.9 and 103.0±23.0 v 86.0±31.4,
94.9±22.3 and 71.1±3.2 mmHg); and SaO2 (94.6±2.4, 94.3±2.4 and 92.3±3.4 v
85.9±5.8, 84.3±6.4 and 81.7±6.1%) and both PaO, and SaO2 decreased over time
during the test at both SL and A. This study has indicated that as well as the extent of
hypoxia induced by altitude, both exercise intensity and duration may impact on the
magnitude of the response to sustained exercise at altitude, such as in cross country ski
racing.
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The effects of training on upper body power in female cross-country skiersDowning, Julie J. 04 June 2002 (has links)
Graduation date: 2003
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