Biomedical Engineering Principles in SportsGeorge K. Hung, Jani Macari Pallis Springer Science & Business Media, 2012. gada 6. dec. - 513 lappuses Biomedical Engineering Principles in Sports contains in-depth discussions on the fundamental biomechanical and physiological principles underlying the acts of throwing, shooting, hitting, kicking, and tackling in sports, as well as vision training, sports injury, and rehabilitation. The topics include: -Golf ball aerodynamics and golf club design, -Golf swing and putting biomechanics, -Tennis ball aerodynamics and ball- and shoe-surface interactions, -Tennis stroke mechanics and optimizing ball-racket interactions, -Baseball pitching biomechanics and perceptual illusions of batters, -Football forward pass aerodynamics and tackling biomechanics, -Soccer biomechanics, -Basketball aerodynamics and biomechanics, -Vision training in sports, -Children maturation and performance, -Rehabilitation and medical advances in treatment of sports injuries. This book is essential reading for biomedical engineers, physicists, sport scientists, and physiologists who wish to update their knowledge of biomechanical and biomedical principles and their applications to sports. The book can be used in a one-semester Senior or Graduate-level course in Biomechanics, Biomedical Engineering, Sports Technology, Sports Medicine, or Exercise Physiology. In addition, it will be of value to interested athletic laypersons who enjoy watching or participating in sports such as golf, tennis, softball, football, soccer, and basketball. |
Saturs
Chapter 2 Engineering Methodology in Golf Studies | 29 |
Chapter 3 Physics and Mechanics of the Golf Swing | 47 |
Chapter 4 Eye and Head Movements During the GolfPutting Stroke | 74 |
II TENNIS | 96 |
Chapter 5 Tennis Ball Aerodynamics and Dynamics | 97 |
Chapter 6 ShoeSurface Interaction in Tennis | 125 |
Chapter 7 Biomechanics of Tennis Strokes | 153 |
Chapter 8 Optimizing Ball and Racket Interaction | 182 |
Chapter 11 Mechanics of the Forward Pass | 291 |
Chapter 12 Biomechanics of Tackling | 320 |
Chapter 13 Biomechanics and Aerodynamics in Soccer | 333 |
V BASKETBALL | 365 |
Chapter 14 Aerodynamics and Biomechanics of the Free Throw | 366 |
Chapter 15 Make Every Free Throw | 391 |
VI PERFORMANCE ANDREHABILTATION | 405 |
Chapter 16 Vision Training and Sports | 407 |
III BASEBALL | 207 |
Chapter 9 Biomechanics of Pitching | 209 |
Chapter 10 The Rising Fastball and Other Perceptual Illusions ofBatters | 257 |
IV FOOTBALL AND SOCCER | 288 |
Chapter 17 Application of Biomedical Principles to theMaturation of Skill in Children | 434 |
Chapter 18 Medical Advances in the Treatment of Sports Injuries | 451 |
| 505 | |
Citi izdevumi - Skatīt visu
Biomedical Engineering Principles in Sports George K. Hung,Jani Macari Pallis Ierobežota priekšskatīšana - 2004 |
Biomedical Engineering Principles in Sports George K. Hung,Jani Macari Pallis Priekšskatījums nav pieejams - 2012 |
Biomedical Engineering Principles in Sports George K Hung,Jani Macari Pallis Priekšskatījums nav pieejams - 2004 |
Bieži izmantoti vārdi un frāzes
acceleration aerodynamic analysis angular athletes axis backspin ball release ball speed ball velocity baseball pitching basketball batter biomechanical body bone bounce boundary layer cartilage club clubface clubhead collagen curve curveball deformation distance drag coefficient dynamic effect elbow energy eye movements Figure Fleisig flexion flight foot football forehand free throw friction function golf ball golfers grip head hit the ball horizontal impact force increase initial injury internal rotation International Tennis Federation joint kick kinematic kinetic knee Knudson lift lift coefficient lift force ligament load markers maximum measured mechanical motion muscle one-handed parameters performance phase pitchers playing surfaces position pressure putt racket racket speed release angle Reynolds number rising fastball saccadic shaft shoe shooting shot shoulder simulation skills specific spin rate sports medicine swing tendon tennis ball tissue topspin torque trajectory trunk typical vector vertical vision training visual wrist