angle of deflection
简明释义
方向角
英英释义
The angle of deflection is the angle formed between the original path of an object and its new path after it has been influenced by a force or obstacle. | 偏转角是指物体在受到力或障碍物影响后,其原始路径与新路径之间形成的角度。 |
例句
1.The engineer calculated the angle of deflection 偏转角 to ensure the bridge would withstand high winds.
工程师计算了偏转角 angle of deflection以确保桥梁能承受大风。
2.In the physics lab, we measured the angle of deflection 偏转角 of a beam of light passing through a prism.
在物理实验室,我们测量了光束通过棱镜时的偏转角 angle of deflection。
3.To find the angle of deflection 偏转角, we used a protractor to measure the angle from the original path.
为了找到偏转角 angle of deflection,我们使用量角器测量原始路径的角度。
4.The angle of deflection 偏转角 of the vehicle's suspension system is crucial for stability during turns.
车辆悬挂系统的偏转角 angle of deflection对转弯时的稳定性至关重要。
5.The angle of deflection 偏转角 in an archery shot can greatly affect the accuracy of the arrow.
射箭时的偏转角 angle of deflection会极大影响箭的准确性。
作文
The concept of the angle of deflection is fundamental in various fields of study, including physics, engineering, and even sports. Understanding this concept can enhance our comprehension of how forces interact with objects, leading to practical applications in real-world situations. The angle of deflection refers to the angle at which an object deviates from its original path due to an external force acting upon it. This deviation can occur in numerous scenarios, such as when a ball is thrown, a vehicle turns, or light bends when passing through different mediums.In physics, the angle of deflection is often discussed in the context of projectile motion. When a projectile is launched, it follows a parabolic trajectory influenced by gravity and air resistance. The initial launch angle determines the path, but external factors can cause the projectile to deviate from this path. For instance, wind can create a angle of deflection that alters the projectile's trajectory, resulting in it landing further away or closer than intended. Understanding this angle is crucial for athletes, especially in sports like basketball or soccer, where precision in aiming and adjusting for external conditions can make a significant difference in performance.In engineering, the angle of deflection plays a critical role in structural design and analysis. Engineers must consider how various forces, such as wind or seismic activity, can cause structures to bend or sway. For example, when designing a bridge, engineers calculate the potential angle of deflection to ensure that the structure can withstand these forces without compromising safety. This calculation involves understanding the materials used, the weight they will carry, and the environmental conditions they will face. A well-designed bridge will have a minimal angle of deflection, ensuring stability and longevity.In addition to physics and engineering, the angle of deflection is also significant in sports dynamics. Athletes must be aware of how their movements can lead to changes in direction. For example, a soccer player dribbling the ball must account for the angle of deflection caused by the surface of the field, the ball's spin, and the impact of opposing players. By mastering the ability to predict and manipulate this angle, athletes can improve their skills and increase their chances of success during competitions.Moreover, the angle of deflection is not limited to physical objects; it can also apply to light waves. When light travels from one medium to another, such as from air to water, it changes speed and direction, resulting in a measurable angle of deflection. This phenomenon is known as refraction and is essential in understanding optical devices like lenses and prisms. Scientists and engineers use the principles of refraction to design better glasses, cameras, and other optical instruments, ensuring that light behaves predictably as it passes through different materials.In conclusion, the angle of deflection is a versatile concept that spans multiple disciplines. Whether in physics, engineering, sports, or optics, understanding how and why objects deviate from their intended paths due to external forces is crucial for achieving desired outcomes. By studying and applying the principles related to the angle of deflection, we can enhance our ability to navigate the complexities of the physical world, leading to advancements in technology, improved athletic performance, and a deeper understanding of the forces that shape our environment.
“偏转角”这一概念在物理学、工程学甚至体育等多个研究领域中都具有重要意义。理解这一概念可以增强我们对物体如何与力相互作用的理解,从而在现实世界中产生实际应用。“偏转角”指的是由于外部力量作用于物体时,物体偏离原始路径的角度。这种偏离可以发生在多种场景中,例如当球被投掷、车辆转弯或光线在不同介质中传播时发生弯曲。在物理学中,“偏转角”通常在抛射运动的背景下讨论。当一个抛射物被发射时,它遵循一个抛物线轨迹,受到重力和空气阻力的影响。初始发射角决定了轨迹,但外部因素可能导致抛射物偏离该轨迹。例如,风可以造成一个“偏转角”,使得抛射物的轨迹改变,导致它落地的位置比预期更远或更近。理解这个角度对于运动员来说至关重要,尤其是在篮球或足球等运动中,瞄准和调整外部条件的精确度可以显著影响表现。在工程学中,“偏转角”在结构设计和分析中发挥着关键作用。工程师必须考虑各种力量,如风力或地震活动,如何导致结构弯曲或摇摆。例如,在设计桥梁时,工程师计算潜在的“偏转角”,以确保结构能够承受这些力量而不危及安全。这一计算涉及对所用材料、承载重量和环境条件的理解。设计良好的桥梁将具有最小的“偏转角”,确保其稳定性和耐久性。除了物理学和工程学,“偏转角”在体育动态中也具有重要意义。运动员必须意识到他们的动作如何导致方向的变化。例如,运球的足球运动员必须考虑到场地表面、球的旋转以及对方球员的影响所造成的“偏转角”。通过掌握预测和操控这个角度的能力,运动员可以提高技能,并在比赛中增加成功的机会。此外,“偏转角”不仅限于物理物体;它也适用于光波。当光从一种介质传播到另一种介质时,例如从空气到水时,它的速度和方向会发生变化,导致一个可测量的“偏转角”。这种现象称为折射,对于理解透镜和棱镜等光学设备至关重要。科学家和工程师利用折射原理设计更好的眼镜、相机和其他光学仪器,确保光在不同材料中传播时行为可预测。总之,“偏转角”是一个跨越多个学科的多功能概念。无论是在物理学、工程学、体育还是光学中,理解物体由于外部力量偏离其预定路径的原因和方式对于实现预期结果至关重要。通过研究和应用与“偏转角”相关的原理,我们可以增强应对物理世界复杂性的能力,从而推动技术进步、改善运动表现,以及更深入地理解塑造我们环境的力量。
相关单词
