yawing oscillation

简明释义

首摇

英英释义

例句

1.To reduce yawing oscillation, the design team implemented new stabilization technology.

为了减少偏航振荡，设计团队实施了新的稳定技术。

2.In racing cars, excessive yawing oscillation can lead to loss of control on the track.

在赛车中，过度的偏航振荡可能导致在赛道上失去控制。

3.The aircraft experienced a significant yawing oscillation during the turbulence, causing discomfort to the passengers.

在颠簸期间，飞机经历了显著的偏航振荡，使乘客感到不适。

4.The boat's yawing oscillation made it difficult for the captain to steer straight.

船只的偏航振荡使船长难以直线航行。

5.Engineers are studying the yawing oscillation of the drone to improve its stability in flight.

工程师们正在研究无人机的偏航振荡以提高其飞行稳定性。

作文

In the field of engineering and physics, understanding the dynamics of motion is crucial for designing stable structures and vehicles. One fundamental concept that engineers often encounter is yawing oscillation, which refers to the side-to-side movement of an object around its vertical axis. This phenomenon can be observed in various applications, from aircraft to ships, and even in automobiles. The significance of yawing oscillation lies in its impact on stability and control during movement.For instance, when an airplane takes off or maneuvers through the air, it must maintain a steady course to ensure passenger safety and comfort. If the aircraft experiences excessive yawing oscillation, it can lead to a loss of control, making it difficult for pilots to navigate effectively. This oscillation can be caused by several factors, including wind turbulence, uneven weight distribution, or mechanical failures. Therefore, engineers must carefully analyze and mitigate these oscillations during the design phase.Similarly, ships are also susceptible to yawing oscillation. When navigating through rough waters, a vessel may sway from side to side, which can affect its trajectory and stability. This lateral movement can be particularly dangerous during docking procedures or when sailing in narrow channels. To counteract this, modern ships are equipped with stabilization systems that help minimize yawing oscillation and improve overall safety.In the automotive industry, yawing oscillation plays a significant role in vehicle dynamics. When a car turns sharply, it may experience a yaw motion that causes the rear end to slide out, leading to oversteering. This situation can be particularly hazardous in slippery conditions, such as rain or snow. To enhance vehicle stability, manufacturers have developed advanced traction control systems that detect and adjust for yawing oscillation in real-time, ensuring that drivers maintain control even in challenging conditions.The study of yawing oscillation is not limited to just these examples; it extends to various fields, including robotics and aerospace engineering. In robotics, for instance, maintaining balance and stability during movement is essential for humanoid robots. Engineers must consider how yawing oscillation affects the robot's ability to navigate its environment without tipping over.In conclusion, yawing oscillation is a critical aspect of motion dynamics that engineers must understand to design safe and efficient vehicles and structures. By analyzing the causes and effects of this phenomenon, they can develop solutions to mitigate its impact, thereby enhancing safety and performance across various industries. Whether in the skies, on the seas, or on the roads, managing yawing oscillation is vital for ensuring smooth and controlled movement, ultimately contributing to the advancement of technology and engineering practices.

在工程和物理领域，理解运动的动力学对于设计稳定的结构和车辆至关重要。工程师经常遇到的一个基本概念是偏航振荡，它指的是物体围绕其垂直轴的左右移动。这种现象可以在各种应用中观察到，从飞机到船只，甚至是汽车。偏航振荡的重要性在于它对运动过程中稳定性和控制的影响。例如，当飞机起飞或在空中机动时，必须保持稳定的航向，以确保乘客的安全和舒适。如果飞机经历过度的偏航振荡，可能会导致失去控制，使飞行员难以有效导航。这种振荡可能由多种因素引起，包括风的湍流、不均匀的重量分布或机械故障。因此，工程师必须在设计阶段仔细分析和减轻这些振荡。同样，船只也容易受到偏航振荡的影响。当船只在波涛汹涌的水域中航行时，可能会左右摇摆，这会影响其轨迹和稳定性。这种横向运动在靠泊或在狭窄水道中航行时尤其危险。为了应对这种情况，现代船只配备了稳定系统，帮助最小化偏航振荡，提高整体安全性。在汽车工业中，偏航振荡在车辆动态中发挥着重要作用。当汽车急转弯时，可能会经历一种偏航运动，导致后端滑出，从而导致过度转向。在湿滑条件下，例如雨天或雪天，这种情况可能特别危险。为了增强车辆稳定性，制造商开发了先进的牵引控制系统，可以实时检测和调整偏航振荡，确保驾驶者即使在困难条件下也能保持控制。对于偏航振荡的研究并不仅限于这些例子；它扩展到包括机器人技术和航空航天工程等各个领域。例如，在机器人技术中，保持平衡和稳定在运动过程中对类人机器人至关重要。工程师必须考虑偏航振荡如何影响机器人在不翻倒的情况下导航其环境的能力。总之，偏航振荡是运动动力学中的一个关键方面，工程师必须理解这一点，以设计安全高效的车辆和结构。通过分析这种现象的原因和影响，他们可以开发解决方案来减轻其影响，从而提高各个行业的安全性和性能。无论是在天空、海洋还是道路上，管理偏航振荡对于确保平稳和可控的运动至关重要，最终有助于技术和工程实践的发展。