yawing frequency

简明释义

首摇频率

英英释义

例句

1.During simulations, the yawing frequency was a key parameter for stability analysis.

在模拟过程中，偏航频率是稳定性分析的关键参数。

2.Understanding the yawing frequency is crucial for designing safer aircraft.

理解偏航频率对设计更安全的飞机至关重要。

3.The research focused on the yawing frequency of the vehicle during high-speed turns.

研究集中在车辆在高速转弯时的偏航频率上。

4.Engineers adjusted the yawing frequency of the drone for better maneuverability.

工程师调整了无人机的偏航频率以提高机动性。

5.The ship's yawing frequency was measured to ensure stability in rough waters.

船只的偏航频率被测量以确保在恶劣水域中的稳定性。

作文

In the field of engineering and physics, understanding the dynamics of motion is crucial. One important aspect of this is the concept of yawing frequency, which refers to the rate at which an object rotates around its vertical axis. This phenomenon can be observed in various applications, including aviation, maritime navigation, and even in the design of vehicles. To fully grasp the significance of yawing frequency, it is essential to explore its implications in different contexts.In aviation, for instance, the yawing frequency plays a critical role in the stability and control of an aircraft. When a plane turns, it experiences yaw, which is the side-to-side movement of the nose. The yawing frequency determines how quickly the aircraft can change direction. Pilots must be aware of this frequency to maintain control and ensure a smooth flight. If the yawing frequency is too high, it can lead to instability, making it difficult for the pilot to manage the aircraft effectively.Similarly, in maritime navigation, the yawing frequency is vital for the maneuverability of ships. When a vessel turns, it also experiences yaw, and the frequency at which this occurs can affect its course and speed. A ship with a low yawing frequency may turn slowly, which can be advantageous in tight spaces or during adverse weather conditions. Conversely, a high yawing frequency allows for quicker turns but may compromise stability, especially in rough seas.Moreover, the concept of yawing frequency extends beyond transportation. In the realm of robotics, for example, understanding the yawing frequency of robotic arms or drones is essential for precise movements. Engineers must calculate the optimal yawing frequency to ensure that these machines operate efficiently and accurately. This calculation involves considering factors such as weight, design, and the intended task of the robot.In conclusion, the study of yawing frequency is integral to various fields, from aviation and maritime navigation to robotics and vehicle design. By understanding this concept, engineers and pilots can enhance the performance and safety of their respective crafts. The yawing frequency not only influences the dynamics of motion but also plays a significant role in ensuring stability and control. As technology continues to advance, the importance of comprehending yawing frequency will undoubtedly grow, leading to more innovative designs and improved operational capabilities across multiple industries.

在工程和物理学领域，理解运动的动态至关重要。一个重要的方面是“偏航频率”的概念，它指的是一个物体围绕其垂直轴旋转的速率。这种现象可以在多个应用中观察到，包括航空、海洋导航，甚至车辆设计。要充分理解“偏航频率”的重要性，有必要探讨它在不同背景下的影响。例如，在航空中，“偏航频率”在飞机的稳定性和控制中起着关键作用。当一架飞机转弯时，它会经历偏航，即机头的左右移动。“偏航频率”决定了飞机改变方向的速度。飞行员必须了解这个频率，以保持控制并确保飞行平稳。如果“偏航频率”过高，可能会导致不稳定，使飞行员难以有效管理飞机。同样，在海洋导航中，“偏航频率”对于船只的机动性至关重要。当一艘船转弯时，它也会经历偏航，而这种发生的频率会影响它的航向和速度。一艘“偏航频率”较低的船可能转弯缓慢，这在狭窄空间或恶劣天气条件下是有利的。相反，高“偏航频率”允许更快的转弯，但可能会影响稳定性，特别是在波涛汹涌的海面上。此外，“偏航频率”的概念超越了交通运输。在机器人领域，例如，理解机器人手臂或无人机的“偏航频率”对于精确运动至关重要。工程师必须计算最佳的“偏航频率”，以确保这些机器高效且准确地运行。这个计算涉及考虑重量、设计和机器人的预期任务等因素。总之，研究“偏航频率”对于航空、海洋导航、机器人技术和车辆设计等多个领域都是不可或缺的。通过理解这一概念，工程师和飞行员可以增强各自工艺的性能和安全性。“偏航频率”不仅影响运动的动态，还在确保稳定性和控制方面发挥着重要作用。随着技术的不断进步，理解“偏航频率”的重要性无疑将增长，从而推动多个行业的创新设计和改进操作能力。