angle of deflection

简明释义

偏 转角

英英释义

例句

1.The pilot adjusted the aircraft's trajectory based on the angle of deflection 偏转角 caused by wind currents.

飞行员根据风流引起的偏转角 angle of deflection 调整了飞机的航向。

2.The engineer calculated the angle of deflection 偏转角 in the bridge design to ensure it could withstand heavy loads.

工程师计算了桥梁设计中的偏转角 angle of deflection，以确保它能够承受重载。

3.The angle of deflection 偏转角 in the pendulum can affect the period of its swing.

摆的偏转角 angle of deflection 会影响其摆动周期。

4.To improve accuracy, the scientist measured the angle of deflection 偏转角 of light as it passed through the prism.

为了提高准确性，科学家测量了光通过棱镜时的偏转角 angle of deflection。

5.In physics, the angle of deflection 偏转角 helps determine how much a beam will bend under pressure.

在物理学中，偏转角 angle of deflection 有助于确定梁在压力下弯曲的程度。

作文

The concept of the angle of deflection is crucial in various fields, including physics, engineering, and even architecture. It refers to the angle at which a beam or a wave deviates from its original path when it encounters an obstacle or a change in medium. Understanding the angle of deflection can help engineers design safer structures and improve the efficiency of various mechanical systems. For instance, when designing bridges, engineers must calculate how much a bridge will bend under the weight of vehicles. This bending is represented by the angle of deflection, which must be kept within safe limits to ensure the integrity of the structure.In physics, the angle of deflection is often discussed in the context of light waves. When light passes through different materials, such as glass or water, it changes speed and direction. The angle of deflection in this case is determined by the refractive indices of the materials involved. This principle is not only important for understanding how lenses work but also plays a significant role in optical technologies like cameras and microscopes.Moreover, the angle of deflection can also apply to particle physics. When charged particles pass through magnetic or electric fields, they experience a force that alters their trajectory. The degree to which their path changes is quantified by the angle of deflection. This concept is essential for designing particle accelerators and understanding fundamental interactions in quantum physics.In everyday life, we can observe the angle of deflection in action when watching a soccer ball being kicked. The ball does not travel in a straight line; instead, it curves due to the forces acting upon it, including air resistance and the spin imparted by the player's foot. The angle of deflection in this scenario affects how the ball moves, making it an integral part of sports strategies.Furthermore, the angle of deflection can be applied in navigation and aviation. Pilots must account for wind direction and speed, which can cause their flight path to deviate. By understanding the angle of deflection, pilots can adjust their course to reach their destination accurately. Similarly, sailors use this concept to navigate through water, ensuring that they stay on the intended path despite currents and winds.In conclusion, the angle of deflection is a multifaceted concept that spans various disciplines. Whether in the design of physical structures, the manipulation of light, or the navigation of vehicles, understanding this angle is vital for achieving desired outcomes. It highlights the interconnectedness of different scientific principles and their applications in real-world scenarios. As we continue to explore and innovate in technology and science, the angle of deflection will remain a key factor in our understanding and application of physical laws.

“偏转角度”这个概念在物理学、工程学甚至建筑学等多个领域中都至关重要。它指的是当光束或波遇到障碍物或介质变化时，偏离其原始路径的角度。理解“偏转角度”可以帮助工程师设计更安全的结构，并提高各种机械系统的效率。例如，在设计桥梁时，工程师必须计算桥梁在车辆重量作用下会弯曲多少。这种弯曲用“偏转角度”表示，必须保持在安全范围内，以确保结构的完整性。在物理学中，“偏转角度”通常在光波的背景下讨论。当光通过不同的材料，例如玻璃或水时，它的速度和方向会发生变化。在这种情况下，“偏转角度”由所涉及材料的折射率决定。这一原理不仅对于理解透镜的工作原理至关重要，还在相机和显微镜等光学技术中发挥着重要作用。此外，“偏转角度”也适用于粒子物理学。当带电粒子穿过磁场或电场时，它们会受到一种力的作用，从而改变其轨迹。它们的路径变化程度用“偏转角度”来量化。这个概念对于设计粒子加速器以及理解量子物理中的基本相互作用至关重要。在日常生活中，我们可以观察到“偏转角度”的实际应用，例如观看被踢的足球。足球不会沿直线运动；相反，由于空气阻力和球员脚部施加的旋转力，它会弯曲。在这种情况下的“偏转角度”影响着足球的运动，使其成为体育策略的重要组成部分。此外，“偏转角度”在导航和航空中也有应用。飞行员必须考虑风的方向和速度，这可能导致他们的飞行路径发生偏离。通过理解“偏转角度”，飞行员可以调整航线以准确到达目的地。同样，水手利用这个概念在水中导航，确保他们在流动和风的影响下仍能保持在预定路径上。总之，“偏转角度”是一个多面向的概念，跨越了多个学科。无论是在物理结构的设计、光的操控还是交通工具的导航中，理解这个角度对于实现预期结果至关重要。它突显了不同科学原理及其在现实世界场景中的应用之间的相互联系。随着我们继续在技术和科学领域进行探索和创新，“偏转角度”将始终是我们理解和应用物理法则的关键因素。