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BIOMECHANICAL PERFORMANCE FACTORS O
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AcknowledgmentsI would like to star
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6.1 Conclusion and Future Considera
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83.42º·s and 48.92 º. There was
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List of TablesChapter 4Table 1: Sum
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1.1 The Basics of Water SkiingWater
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deep water start a good performance
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skills in order to be able to ident
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completed their test runs throughou
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1.5 Thesis outlineChapter 2 will pr
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Chapter 2: Literature Review13
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of material can be used as a force
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& Pesty, n.d.; Zang et al., 2004].
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instrumentation system used did not
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allowed them to plot a velocity ver
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Chapter 3: Methods and Instrumentat
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AbstractThere are many challenges w
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is most likely the main reason why
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applicable to dynamic sports [Brodi
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The product chosen that best met th
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ON) that did not require any modifi
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single data collection program that
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Figure 3 - Diagram of slalom course
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for patterns in the data that sugge
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200SU EC ST BTA150Angle (degrees)10
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10050Angle (Degrees)0-50-100-150Pit
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RF communication systems are easily
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The roll profile can be used to det
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Chapter 4: Water Skiing Biomechanic
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AbstractSix advanced slalom skiers
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Recreational and competitive slalom
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Table 1: Summary of human participa
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Figure 2: Diagram of slalom course
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at a rate of 1 Hz (BG-331RGTGT, Mig
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adjusted p-value. (SAS Institue Inc
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Table 3: Summary of completed turns
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Rope load peaks during the cutting
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Peak skier velocity for each turn i
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4 DiscussionThere are several varia
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trend was seen by Runciman (2011) w
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- Page 87 and 88: improve the accuracy that a coach e
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- Page 91 and 92: AbstractWater skiing has received l
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- Page 111 and 112: Figure 12 shows each ski’s overal
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- Page 123 and 124: Chapter 6 - Conclusion and Future C
- Page 125 and 126: The data, in combination with a sta
- Page 127 and 128: Bachmann, E.R. (2000). Inertial and
- Page 129 and 130: Appendices119
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- Page 133: Skiing Background Information6. How
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