yaw rate control

简明释义

船首摇摆率的控制

英英释义

例句

1.Advanced driver assistance systems often include yaw rate control 偏航率控制 to enhance safety features.

高级驾驶辅助系统通常包含偏航率控制以增强安全功能。

2.To improve maneuverability, the aircraft's autopilot system incorporates yaw rate control 偏航率控制 algorithms.

为了提高机动性，飞机的自动驾驶仪系统采用了偏航率控制算法。

3.In racing, precise yaw rate control 偏航率控制 is essential for maintaining optimal cornering speed.

在赛车中，精确的偏航率控制对于维持最佳过弯速度至关重要。

4.The drone's flight controller uses yaw rate control 偏航率控制 to stabilize its orientation in the air.

无人机的飞行控制器使用偏航率控制来稳定其在空中的方向。

5.The vehicle's stability system utilizes yaw rate control 偏航率控制 to prevent skidding during sharp turns.

车辆的稳定性系统利用偏航率控制来防止在急转弯时打滑。

作文

In the field of automotive engineering, one of the critical aspects that contribute to vehicle stability and safety is the concept of yaw rate control. This term refers to the ability of a vehicle to manage its rotational movement around a vertical axis, which is essential for maintaining control during various driving conditions. When a driver turns the steering wheel, the vehicle experiences a change in direction, leading to a yaw motion that can affect its stability. Effective yaw rate control ensures that the vehicle does not skid or lose traction, especially during sharp turns or when driving on slippery surfaces.The importance of yaw rate control becomes even more apparent when considering the dynamics of high-speed driving. At elevated speeds, a vehicle is more susceptible to losing control due to rapid changes in direction. Advanced systems such as Electronic Stability Control (ESC) utilize yaw rate control to monitor the vehicle's movement and make real-time adjustments to the braking system. By selectively applying brakes to individual wheels, these systems can counteract unwanted yaw motions, helping to keep the vehicle on its intended path.Moreover, yaw rate control plays a significant role in enhancing the performance of vehicles equipped with all-wheel drive (AWD) systems. These systems rely on precise control of each wheel's speed and torque to optimize traction and handling. By integrating yaw rate control algorithms, AWD systems can dynamically adjust power distribution between the front and rear wheels, ensuring that the vehicle maintains stability even in challenging driving conditions.In motorsport, yaw rate control is crucial for achieving optimal performance on the track. Race cars are designed to handle extreme speeds and sharp corners, where the slightest loss of control can lead to disastrous consequences. Engineers meticulously calibrate yaw rate control systems to ensure that drivers can navigate turns with precision while minimizing the risk of oversteering or understeering. This level of control allows racers to push their vehicles to the limit while maintaining safety.Furthermore, the development of autonomous vehicles has brought yaw rate control into the spotlight. As self-driving technology evolves, the ability to manage yaw movements accurately becomes essential for safe navigation. Autonomous systems must continuously assess the vehicle's orientation and make split-second decisions to adjust speed and direction. Integrating sophisticated yaw rate control mechanisms allows these vehicles to respond effectively to dynamic road conditions and obstacles, enhancing overall safety.In conclusion, yaw rate control is a vital component in modern vehicle design, impacting everything from everyday driving to high-performance racing and autonomous navigation. Its ability to manage a vehicle's rotational dynamics significantly contributes to safety and stability, making it an essential focus for engineers and designers alike. As technology continues to advance, the importance of yaw rate control will only increase, paving the way for safer and more efficient vehicles on our roads.

在汽车工程领域，车辆稳定性和安全性的重要方面之一就是偏航率控制的概念。这个术语指的是车辆管理其围绕垂直轴的旋转运动的能力，这对于在各种驾驶条件下保持控制至关重要。当驾驶员转动方向盘时，车辆会经历方向的变化，导致偏航运动，这可能影响其稳定性。有效的偏航率控制确保车辆不会打滑或失去牵引力，特别是在急转弯或在滑溜路面上行驶时。当考虑到高速驾驶的动态特性时，偏航率控制的重要性变得更加明显。在高速行驶时，车辆更容易因为快速的方向变化而失去控制。先进的系统如电子稳定控制（ESC）利用偏航率控制来监测车辆的运动，并实时调整制动系统。通过选择性地对单个车轮施加制动，这些系统可以抵消不必要的偏航运动，帮助车辆保持在预定路径上。此外，偏航率控制在增强配备全轮驱动（AWD）系统的车辆性能方面也发挥着重要作用。这些系统依赖于对每个车轮的速度和扭矩的精确控制，以优化牵引力和操控性。通过集成偏航率控制算法，AWD系统可以动态调整前后车轮之间的动力分配，确保车辆在挑战性的驾驶条件下保持稳定。在赛车运动中，偏航率控制对于在赛道上实现最佳性能至关重要。赛车被设计成能够处理极高的速度和急转弯，其中最轻微的失控都可能导致灾难性的后果。工程师们精心校准偏航率控制系统，以确保驾驶员能够精准地驾驭弯道，同时尽量减少过度转向或不足转向的风险。这种控制水平使赛车手能够在保持安全的同时，将他们的车辆推向极限。此外，自动驾驶汽车的发展使偏航率控制成为焦点。随着自驾技术的发展，准确管理偏航运动的能力对于安全导航至关重要。自动系统必须持续评估车辆的方向，并做出瞬时决策来调整速度和方向。集成复杂的偏航率控制机制使这些车辆能够有效应对动态道路条件和障碍物，从而增强整体安全性。总之，偏航率控制是现代车辆设计中的一个重要组成部分，影响从日常驾驶到高性能赛车和自动导航的一切。其管理车辆旋转动态的能力显著有助于安全和稳定，使其成为工程师和设计师关注的重点。随着技术的不断进步，偏航率控制的重要性只会增加，为我们道路上的更安全、更高效的车辆铺平道路。