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相关概念视频

Motion of a Projectile01:23

Motion of a Projectile

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Projectile motion becomes evident when a player kicks the ball into the air. The launch angle, or the angle at which the ball is kicked, plays a crucial role in determining the trajectory of the projectile. As the ball soars through the air, influenced solely by gravity, its motion can be dissected into two independent velocity components: the horizontal and the vertical.
Horizontal motion, governed by the initial kick, maintains a constant velocity throughout the flight of the soccer ball.
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Projectile Motion: Example01:18

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The theory of projectile motion is very useful for players of several sports to improve their performance. For example, a javelin thrower needs to throw their javelin in such a way that it travels as far as possible. The javelin thrower takes a short run-up to increase the initial speed of the javelin. The range of a projectile is at its maximum at a 45° angle so javelin throwers try to angle their throw as close to 45° as possible.
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Force and momentum are intimately related. Force acting over time can change momentum, and Newton's second law of motion can be stated in its most broadly applicable form in terms of momentum. Momentum can be applied to systems where the mass is changing, such as rockets, as well as to systems of constant mass. Also, momentum continues to be a key concept in the study of atomic and subatomic particles in quantum mechanics. One can consider systems with varying mass in some detail; however,...
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Consider a ball of mass m, attached to a massless rod of known length, subjected to a time-dependent torque. If the initial velocity of the mass is known, then the final velocity of the mass for time t can be determined using the principle of angular impulse and momentum.
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Any object that obeys Newton's second law of motion is made up of a large number of infinitesimally small particles. Objects in motion can be as simple as atoms or as complex as gymnasts performing in the Olympics. The motion of such objects is described about a point called the center of mass of the object. The center of mass of an object is a point that acts as if the whole mass is concentrated at that point. The center of mass of an object with a large number of infinitesimally small...
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By definition, a spherically symmetric body has the same moment of inertia about any axis passing through its center of mass. This situation changes if there is no spherical symmetry. Since most rigid bodies are not spherically symmetric, these require special treatment.
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Importance of Jumping Ability in Handball Throwing Speed and Accuracy
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作为球大小的函数,空手投球模式的变化.

Allen W Burton1, Nancy L Greer1, Diane M Wiese1

  • 1the Division of Kinesiology, 1900 University Avenue S.E., University of Minnesota, Minneapolis, MN 55455-0155.

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此摘要是机器生成的。

投球机制对于特定的球尺寸是稳定的,但当球直径超过手宽时会发生变化. 这会影响后摆和前臂部件,这表明需要适合尺寸的训练.

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科学领域:

  • 生物力学 生物力学
  • 人类运动科学科学 人类运动科学

背景情况:

  • 了解投的生物力学对于体育表现和伤害预防至关重要.
  • 以前的研究已经探索了影响投的各种因素,但球尺寸对投组件的具体影响需要进一步调查.

研究的目的:

  • 为了研究不同球大小的投部件的稳定性.
  • 为了确定球体大小的变化如何影响单手手投的动力组件.
  • 为了识别可能改变投模式的关键球径.

主要方法:

  • 参与者 (四个年龄组的男性和女性) 用六种不同直径的聚烯泡球进行了一手手投.
  • 每个大小的球从6.7米的距离扔了四次.
  • 分析了投球运动的五个组成部分的稳定性和不同球大小的变化.

主要成果:

  • 在特定球大小的个体中,投球组件水平通常是稳定的.
  • 组件水平的不稳定性往往表明过渡到一个新的模式 (时间的70.6%).
  • 增加球体大小主要影响了后摆和前臂部件,可能是由于球体直径超过手宽时的抓地难度.

结论:

  • 投球模式受到球大小的影响,当球直径接近或超过手的宽度时,会发生明显的变化.
  • 教练和运动员应在训练中考虑球大小,因为它可以改变基本的投球机制.
  • 一个关键的球直径,大约等于手的宽度,可能需要调整投技术.