ballistic motion

简明释义

冲击运动

英英释义

例句

1.The video game features realistic physics, including ballistic motion 抛体运动 for projectiles.

这个视频游戏具有现实的物理效果，包括投射物的ballistic motion 抛体运动。

2.The athlete demonstrated perfect technique when launching the javelin, achieving optimal ballistic motion 抛体运动.

这位运动员在投掷标枪时展示了完美的技术，达到了最佳的ballistic motion 抛体运动。

3.In physics class, we learned how to calculate the trajectory of an object in ballistic motion 抛体运动.

在物理课上，我们学习了如何计算物体在ballistic motion 抛体运动中的轨迹。

4.The cannonball followed a typical ballistic motion 抛体运动 after being fired from the cannon.

炮弹在从炮口发射后遵循典型的ballistic motion 抛体运动。

5.Understanding ballistic motion 抛体运动 is crucial for engineers designing missiles.

理解ballistic motion 抛体运动对设计导弹的工程师来说至关重要。

作文

Understanding the concept of ballistic motion is crucial for anyone interested in physics, engineering, or even sports. Ballistic motion refers to the motion of an object that is thrown or projected into the air and is subject only to the forces of gravity and air resistance after its initial launch. This type of motion can be observed in various real-life scenarios, such as a basketball being thrown towards a hoop, a cannonball being fired, or even a rocket being launched into space. To fully grasp ballistic motion, it is essential to consider the factors that influence it. The trajectory of a projectile is determined by its initial velocity, launch angle, and the acceleration due to gravity. For instance, when a basketball player shoots the ball, the angle at which the ball is released significantly affects whether it will go through the hoop. A higher launch angle may allow the ball to clear obstacles, while a lower angle may result in a faster descent.One of the key principles of ballistic motion is that it follows a parabolic path when air resistance is negligible. This means that the path of the projectile can be modeled using quadratic equations, which describe the relationship between the horizontal and vertical components of motion. Understanding this mathematical aspect is vital for engineers who design projectiles or sports equipment, as it allows them to predict how an object will behave in flight.In addition to mathematics, ballistic motion also has practical applications in various fields. In military technology, for example, understanding the principles of ballistic motion is essential for accurately targeting missiles and artillery. Engineers must calculate the optimal angles and velocities to ensure that projectiles hit their intended targets. Similarly, in sports science, coaches and athletes analyze ballistic motion to enhance performance. By studying the mechanics of a jump or throw, they can develop training programs that improve an athlete's efficiency and effectiveness.Moreover, the study of ballistic motion extends beyond simple projectiles. In the realm of aerospace engineering, the principles of ballistic motion are applied to understand the behavior of spacecraft during launch and re-entry. Engineers must account for various forces acting on the spacecraft, including gravitational pull and atmospheric drag, to ensure a safe and successful mission.In conclusion, ballistic motion is a fundamental concept that encompasses a wide range of applications across different fields. From sports to military technology and aerospace engineering, understanding the principles of ballistic motion enables professionals to make informed decisions and predictions about the behavior of projectiles. By delving deeper into this topic, we can appreciate the intricate dance of physics that governs the world around us and harness this knowledge for innovation and progress.

理解弹道运动的概念对于任何对物理学、工程学或甚至体育感兴趣的人来说都是至关重要的。弹道运动指的是一个物体被投掷或发射到空中，并且在初始发射后只受重力和空气阻力影响的运动。这种类型的运动可以在各种现实生活场景中观察到，例如投篮、炮弹发射，甚至火箭发射到太空。要充分掌握弹道运动，必须考虑影响它的因素。抛射物的轨迹由其初始速度、发射角度和重力加速度决定。例如，当篮球运动员投篮时，球释放的角度会显著影响它是否能够进入篮筐。更高的发射角度可能使球能够越过障碍，而较低的角度可能导致球更快下落。弹道运动的一个关键原理是，当空气阻力可以忽略不计时，它遵循抛物线轨迹。这意味着抛射物的路径可以用二次方程建模，这描述了水平和垂直运动分量之间的关系。理解这一数学方面对于设计抛射物或运动器材的工程师至关重要，因为这使他们能够预测物体在飞行中的行为。除了数学，弹道运动在各个领域也有实际应用。例如，在军事技术中，理解弹道运动的原理对于准确瞄准导弹和火炮至关重要。工程师必须计算最佳角度和速度，以确保抛射物击中预定目标。同样，在运动科学中，教练和运动员分析弹道运动以提高表现。通过研究跳跃或投掷的力学，他们可以制定提高运动员效率和效果的训练计划。此外，弹道运动的研究超出了简单的抛射物。在航空航天工程领域，弹道运动的原理被应用于理解航天器在发射和再入过程中的行为。工程师必须考虑作用在航天器上的各种力量，包括重力和大气阻力，以确保任务的安全和成功。总之，弹道运动是一个基本概念，涵盖了不同领域的广泛应用。从体育到军事技术和航空航天工程，理解弹道运动的原理使专业人士能够对抛射物的行为做出明智的决策和预测。通过深入研究这一主题，我们可以欣赏支配我们周围世界的物理学的复杂舞蹈，并利用这一知识推动创新和进步。