yawing amplitude

简明释义

首偏荡幅度

英英释义

例句

1.The research focused on minimizing the yawing amplitude 偏航幅度 in drones to improve flight stability.

研究集中在最小化无人机的yawing amplitude 偏航幅度，以提高飞行稳定性。

2.Engineers measured the yawing amplitude 偏航幅度 to ensure the vehicle would perform well on winding roads.

工程师测量了yawing amplitude 偏航幅度，以确保车辆在蜿蜒道路上的表现良好。

3.The pilot adjusted the controls to reduce the yawing amplitude 偏航幅度 of the aircraft during turbulence.

飞行员调整了控制装置，以减少飞机在颠簸期间的yawing amplitude 偏航幅度。

4.High yawing amplitude 偏航幅度 can lead to unpredictable movements in racing cars.

高yawing amplitude 偏航幅度可能导致赛车的不稳定运动。

5.In naval architecture, the yawing amplitude 偏航幅度 of a ship can affect its stability in rough seas.

在船舶设计中，船只的yawing amplitude 偏航幅度 会影响其在恶劣海况下的稳定性。

作文

In the realm of engineering and physics, particularly in the study of dynamics and motion, the term yawing amplitude is often encountered. It refers to the extent to which an object rotates about its vertical axis during motion. This concept is crucial in various fields, including aeronautics, marine navigation, and vehicle dynamics. Understanding yawing amplitude is essential for ensuring stability and control in moving objects, as excessive yaw can lead to loss of control and potentially catastrophic failures.To illustrate the importance of yawing amplitude, let’s consider an example from aviation. An aircraft must maintain a stable flight path to ensure the safety of its passengers and crew. If the yawing amplitude becomes too large, the airplane may begin to oscillate uncontrollably, leading to a phenomenon known as Dutch roll. This oscillation occurs when the aircraft yaws left and right in a repeating pattern, which can be disorienting for pilots and dangerous for passengers. Therefore, engineers design aircraft with specific parameters to manage yawing amplitude, incorporating systems that automatically correct any excessive yawing.Similarly, in maritime navigation, ships must also consider yawing amplitude when maneuvering through rough waters. A vessel that experiences high yawing amplitude may struggle to maintain its course, drifting off path and potentially colliding with other vessels or obstacles. To combat this, modern ships are equipped with advanced stabilization systems that help minimize yawing movements, ensuring a smoother and safer journey across the seas.The concept of yawing amplitude is not limited to large vehicles; it also applies to smaller entities, such as bicycles and motorcycles. Riders must be aware of how their body movements can affect the yawing amplitude of their bikes. For instance, leaning too far in one direction while turning can increase the yaw, causing instability and risking a fall. Hence, understanding the dynamics of yawing amplitude can significantly enhance a rider's performance and safety.Moreover, the study of yawing amplitude extends into robotics and automation. As robots navigate through environments, they must accurately control their yawing movements to avoid obstacles and complete tasks efficiently. Engineers program algorithms that account for yawing amplitude, enabling robots to adjust their paths dynamically based on real-time feedback.In conclusion, the term yawing amplitude encompasses a vital aspect of motion dynamics that affects a wide range of applications, from aviation to maritime travel, cycling, and robotics. By comprehensively understanding yawing amplitude, professionals in these fields can design safer and more efficient systems, enhancing overall performance and safety. Whether in the sky, on the water, or on land, managing yawing amplitude is essential for achieving stability and control in motion.

在工程和物理学的领域，特别是在动力学和运动研究中，术语偏航幅度常常被提及。它指的是物体在运动过程中围绕其垂直轴旋转的程度。这个概念在航空、海洋导航和车辆动态等多个领域至关重要。理解偏航幅度对于确保移动物体的稳定性和控制能力至关重要，因为过大的偏航可能导致失控和潜在的灾难性故障。为了说明偏航幅度的重要性，让我们考虑一个来自航空的例子。飞机必须保持稳定的飞行路径，以确保乘客和机组人员的安全。如果偏航幅度变得过大，飞机可能开始不可控地振荡，导致一种称为荷兰滚动的现象。这种振荡发生在飞机左右偏航时形成重复模式，这对飞行员来说可能会感到迷惑，对乘客来说也很危险。因此，工程师设计飞机时会考虑特定参数来管理偏航幅度，并结合自动修正任何过度偏航的系统。同样，在海洋导航中，船只在穿越波涛汹涌的水域时也必须考虑偏航幅度。经历高偏航幅度的船只可能难以维持航向，漂移偏离轨道，甚至可能与其他船只或障碍物相撞。为此，现代船只配备了先进的稳定系统，以帮助最小化偏航运动，确保更加平稳和安全的航行。偏航幅度的概念不仅限于大型交通工具，它也适用于较小的实体，例如自行车和摩托车。骑行者必须意识到他们的身体动作如何影响自行车的偏航幅度。例如，在转弯时，身体向一侧倾斜过多可能会增加偏航，导致不稳定并有跌倒的风险。因此，理解偏航幅度的动态可以显著提高骑行者的表现和安全性。此外，偏航幅度的研究还扩展到机器人和自动化领域。当机器人在环境中导航时，它们必须准确控制其偏航运动，以避免障碍物并高效完成任务。工程师编写算法，考虑到偏航幅度，使机器人能够根据实时反馈动态调整其路径。总之，术语偏航幅度涵盖了运动动态的一个重要方面，影响着从航空到海洋旅行、自行车和机器人等多个应用领域。通过全面理解偏航幅度，这些领域的专业人士可以设计出更安全、更高效的系统，增强整体性能和安全性。无论是在天空中、在水上还是在陆地上，管理偏航幅度对于实现运动中的稳定性和控制力至关重要。