Fundamentals of Biomechanics

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Arellano, R. (1999). Vortices and propulsion. In R. Sanders & J. Linsten (Eds.), SWIMMING: Applied proceedings of the xvii international symposium on biomechanics in sports (Vol. 1, p. 53–66). Perth, WA: Edith Cowan University. Berger, M. A. M., de Groot, G., & Hollander, A. P. (1995). Hydrodynamic drag and lift force on human hand/arm models. Journal of Biomechanics, 28, 125–133. Counsilman, J. E. (1971). The application of Bernoulli's Principle to human propulsion in water. In L. Lewillie and J. Clarys (Eds.), First international symposium on biomechanics of swimming (pp.59–71). Brussels: Université Libre de Bruxelles. McLean, S. P., & Hinrichs, R. N. (2000a). Influence of arm position and lung volume on the center of buoyancy of competitive swimmers. Research Quarterly for Exercise and Sport, 71, 182–189. McLean, S. P., & Hinrichs, R. N. (2000b). Buoyancy, gender, and swimming performance. Journal of Applied Biomechanics, 16, 248–263. WEB LINKS CHAPTER 8: FLUID MECHANICS 211 Mehta, R. D., & Pallis, J. M. (2001b). Sports ball aerodynamics: Effects of velocity, spin and surface roughness. In F. H. Froes, & S. J. Haake (Eds.), Materials and science in sports (pp. 185–197). Warrendale, PA: The Minerals, Metals and Materials Society [TMS]. Mureika, J. R. (2000). The legality of wind and altitude assisted performances in the sprints. New Studies in Athletics, 15(3/4), 53–58. Olds, T. (2001). Modelling of human locomotion: Applications to cycling. Sports Medicine, 31, 497–509. Toussaint, H. M., van den Berg, C., & Beek, W. J. (2002). “Pumped-up propulsion” during front crawl swimming. Medicine and Science in Sports and Exercise, 34, 314–319. Watts, R. G., & Bahill, A. T. (2000). Keep your eye on the ball: The science and folklore of baseball (2nd ed.). New York: W.H. Freeman. Yeadon, M. R. (1997). The biomechanics of human flight. American Journal of Sports Medicine, 25, 575–580. Aerodynamics—NASA educational pages on fluid mechanics. http://www.grc.nasa.gov/WWW/K-12/airplane/short.html Aerodynamics in Tennis—NASA/Cislunar Aerospace project to promote science education through sport science. http://wings.avkids.com/Tennis/Book/index.html Cycling Aerodynamics—cycling page by Smits and Royce of Princeton University. http://www.princeton.edu/~asmits/Bicycle_web/bicycle_aero.html Cycling Aerodynamics and power calculation page. http://www.exploratorium.edu/cycling/aerodynamics1.html Bernoulli vs. Newton—NASA webpage on the competing theories for lift forces in fluids. http://www.grc.nasa.gov/WWW/K-12/airplane/bernnew.html ISBS Coaching Information Service—select swimming link. http://coachesinfo.com/
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Fundamentals of Biomechanics
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Duane Knudson Department of Kinesio
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VI FUNDAMENTALS OF BIOMECHANICS CHA
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VIII FUNDAMENTALS OF BIOMECHANICS R
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X FUNDAMENTALS OF BIOMECHANICS part
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Kinesiology is the scholarly study
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4 FUNDAMENTALS OF BIOMECHANICS beca
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6 FUNDAMENTALS OF BIOMECHANICS Figu
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8 FUNDAMENTALS OF BIOMECHANICS Figu
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34 FUNDAMENTALS OF BIOMECHANICS mor
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PARTII BIOLOGICAL/STRUCTURAL BASES
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46 FUNDAMENTALS OF BIOMECHANICS jou
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48 FUNDAMENTALS OF BIOMECHANICS of
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52 FUNDAMENTALS OF BIOMECHANICS Act
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60 FUNDAMENTALS OF BIOMECHANICS ed
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64 FUNDAMENTALS OF BIOMECHANICS use
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66 FUNDAMENTALS OF BIOMECHANICS exa
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Many professionals interested in hu
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Figure 4.2. Combined loads of (a) b
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ments have another region in their
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that stretch. We will learn in Chap
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esponse of bone is dependent on thi
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outs. We will see in the next secti
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improve performance (De Koning et a
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Interdisciplinary Issue: Speed Runn
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The active tension component of the
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times called active state or excita
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that is immediately followed by con
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elastic mechanisms in the SSC are p
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maximize the time of force applicat
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Regulation of Muscle Force If the m
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peated stimulation of a motor unit
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Proprioception of Muscle Action and
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most movements is the rapid reversa
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duction in skeletal muscle. Journal
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Kinematics is the accurate descript
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erence can get quite complicated. T
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the runner in Figure 5.2 can correc
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Graphs of kinematic variables versu
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ules require that the sprinter have
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Let's consider a quick example of u
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Before we can look at generalizatio
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Figure 5.9. The optimal projection
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The angular velocities of joints ar
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CHAPTER 5: LINEAR AND ANGULAR KINEM
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formula is to use angular velocity
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a bit of art to the coaching of mov
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11. A softball coach is concerned t
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In the previous chapter we learned
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fast-moving weather system brings a
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inverse dynamics. Other scientists
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y the tackler in Figure 6.5b ends u
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the movement, speed, and load shoul
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Figure 6.8. Any vectors acting on t
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matic decrease in the horizontal co
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(Nigg, Luthi, & Bahlsen, 1989). Epi
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FORCE-TIME PRINCIPLE The applied ma
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Activity: Impulse-Momentum Relation
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approach can convert this energy to
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ity or energy losses of an object r
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work. This dependence on the object
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Interdisciplinary Issue: Efficiency
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and the controversial nature of the
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muscles is clearly indicated. More
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Interdisciplinary Issue: Power in V
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Jorgensen, T. P. (1994). The physic
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170 FUNDAMENTALS OF BIOMECHANICS In
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172 FUNDAMENTALS OF BIOMECHANICS Fi
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176 FUNDAMENTALS OF BIOMECHANICS me
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178 FUNDAMENTALS OF BIOMECHANICS ba
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180 FUNDAMENTALS OF BIOMECHANICS Eq
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182 FUNDAMENTALS OF BIOMECHANICS su
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Page 390: External forces that have a major e
Page 394: Figure 8.2. The center of buoyancy
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Page 406: Figure 8.9. The fluid force acting
Page 410: ecules passing over the top of the
Page 414: layer, allowing it to separate late
Page 418: CHAPTER 8: FLUID MECHANICS 207 Figu
Page 422: of lower ball speed. In tennis the
Page 428: PARTIV APPLICATIONS OF BIOMECHANICS
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Page 452: Coaching athletics also involves te
Page 456: This young player shows good balanc
Page 460: weaknesses in some athlete's exerci
Page 464: QUALITATIVE ANALYSIS OF CATCHING As
Page 468: Dyson, G. (1986). Mechanics of athl
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240 FUNDAMENTALS OF BIOMECHANICS sw
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242 FUNDAMENTALS OF BIOMECHANICS on
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244 FUNDAMENTALS OF BIOMECHANICS ri
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246 FUNDAMENTALS OF BIOMECHANICS 5.
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252 FUNDAMENTALS OF BIOMECHANICS IN
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254 FUNDAMENTALS OF BIOMECHANICS pl
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Aagaard, P. (2003). Training-induce
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Basmajian, J. V., & Wolf, S. L. (Ed
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Chalmers, G. (2002). Do golgi tendo
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Dyson, G. (1986). Mechanics of athl
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ments. Journal of Applied Biomechan
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ing locomotor movements. Exercise a
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sessment. Australian Journal of Phy
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to strength and conditioning. Balti
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Journal of Science and Medicine in
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cur as a function of learning a tim
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Woo (Eds.), Multiple muscle systems
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Schneider, K., Zernicke, R. F., Sch
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cles in the acceleration phase of t
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absolute angle: an angle measured t
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compliance: the ratio of change in
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First Law of Thermodynamics: applic
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kinematic chain: a linkage of rigid
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parallel elastic component: a part
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series elastic component: a part of
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Wolff's Law: bones remodel accordin
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This appendix provides initial answ
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quadriceps groups to extend the kne
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flow of fluid, while lift acts at r
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Rating Principle Body part (inadequ
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310 FUNDAMENTALS OF BIOMECHANICS Ba
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312 FUNDAMENTALS OF BIOMECHANICS F
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314 FUNDAMENTALS OF BIOMECHANICS Ki
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316 FUNDAMENTALS OF BIOMECHANICS Oc
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This section of the book provides a
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