yawing angle

简明释义

偏荡角

英英释义

例句

1.Adjusting the yawing angle can significantly improve the drone's stability during flight.

调整偏航角可以显著提高无人机在飞行过程中的稳定性。

2.The vehicle's yawing angle needs to be monitored to prevent skidding on wet roads.

车辆的偏航角需要监控，以防止在湿滑路面上打滑。

3.Engineers calculated the optimal yawing angle for the wind turbine to maximize energy output.

工程师计算了风力涡轮机的最佳偏航角以最大化能量输出。

4.The pilot adjusted the yawing angle to ensure a smooth turn during the flight.

飞行员调整了偏航角以确保飞行中的平稳转弯。

5.In robotics, the yawing angle is crucial for navigating through tight spaces.

在机器人技术中，偏航角对在狭窄空间中导航至关重要。

作文

In the field of engineering and physics, particularly in aerodynamics and vehicle dynamics, the concept of the yawing angle plays a crucial role in understanding how objects move through space. The yawing angle refers to the angle between the forward direction of an object and its actual path of movement. This angle is particularly important for vehicles, aircraft, and ships, as it helps in determining their stability and maneuverability. For instance, when a car turns a corner, the yawing angle changes, which can affect the vehicle's grip on the road and its overall handling characteristics.To illustrate the importance of the yawing angle, consider an airplane during takeoff. As the plane accelerates down the runway, it must maintain a specific yawing angle to ensure that it is aligned with the direction of takeoff. If the yawing angle is too great, the plane may veer off course, leading to potential safety hazards. Pilots are trained to monitor and adjust the yawing angle to maintain control of the aircraft, especially during critical phases of flight such as takeoff and landing.Similarly, in marine navigation, the yawing angle is vital for ensuring that ships stay on their intended course. When a ship encounters rough seas or strong winds, the yawing angle can change rapidly, causing the vessel to drift off its path. Navigators must be adept at correcting the yawing angle to maintain a steady course, using techniques such as adjusting the rudder or altering the ship's speed.In addition to its practical applications, the yawing angle also has theoretical implications in the study of motion. Engineers and scientists use mathematical models to predict how changes in the yawing angle will affect an object's trajectory. These models can be complex, taking into account various forces such as friction, drag, and thrust. Understanding the yawing angle allows researchers to design more efficient vehicles and improve safety protocols across different industries.Moreover, advancements in technology have led to the development of systems that automatically adjust the yawing angle for optimal performance. For example, modern cars are equipped with electronic stability control systems that detect when the vehicle is losing traction and automatically adjust the steering to correct the yawing angle. This not only enhances safety but also improves the driving experience by providing better handling and responsiveness.In conclusion, the yawing angle is a fundamental concept in various fields that deal with motion and stability. Whether it is in aviation, maritime navigation, or automotive engineering, understanding and managing the yawing angle is essential for ensuring safe and efficient operation. As technology continues to advance, the ability to measure and adjust the yawing angle accurately will play an increasingly important role in the design and operation of vehicles, ultimately leading to safer and more efficient transportation solutions.

在工程和物理学领域，特别是在空气动力学和车辆动力学中，偏航角的概念在理解物体如何在空间中移动方面起着至关重要的作用。偏航角是指物体的前进方向与其实际运动路径之间的角度。这个角度对于车辆、飞机和船只尤为重要，因为它有助于确定它们的稳定性和机动性。例如，当一辆车转弯时，偏航角会发生变化，这可能会影响车辆在路面上的抓地力以及整体操控特性。为了说明偏航角的重要性，可以考虑飞机在起飞过程中的情况。当飞机在跑道上加速时，必须保持特定的偏航角以确保与起飞方向对齐。如果偏航角过大，飞机可能会偏离航线，从而导致潜在的安全隐患。飞行员接受培训，以监控和调整偏航角，以保持飞机的控制，特别是在起飞和着陆等关键飞行阶段。同样，在海洋导航中，偏航角对于确保船只保持预定航向至关重要。当船只遇到波涛汹涌的海面或强风时，偏航角可能会迅速变化，导致船只偏离航道。导航员必须熟练地纠正偏航角以保持稳定的航向，使用如调整舵或改变船速等技术。除了其实际应用外，偏航角在运动研究中的理论意义也很重要。工程师和科学家利用数学模型预测偏航角的变化将如何影响物体的轨迹。这些模型可能很复杂，需要考虑摩擦、阻力和推力等各种力。理解偏航角使研究人员能够设计出更高效的车辆，并改善各行业的安全协议。此外，技术的进步导致开发出能够自动调整偏航角以实现最佳性能的系统。例如，现代汽车配备了电子稳定控制系统，该系统检测到车辆失去牵引力时，会自动调整方向以纠正偏航角。这不仅增强了安全性，还通过提供更好的操控性和响应性来改善驾驶体验。总之，偏航角是涉及运动和稳定性的各个领域中的一个基本概念。无论是在航空、海洋导航还是汽车工程中，理解和管理偏航角对于确保安全和高效的操作至关重要。随着技术的不断进步，准确测量和调整偏航角的能力将在车辆的设计和操作中发挥越来越重要的作用，最终导致更安全、更高效的交通解决方案。